The Peter Attia Drive - #66 - Vamsi Mootha, M.D.: Aging, type 2 diabetes, cancer, Alzheimer’s disease, and Parkinson’s disease – do all roads lead to mitochondria?
Episode Date: August 12, 2019In this episode, Dr. Vamsi Mootha, an expert in mitochondrial biology and investigator at the Howard Hughes Medical Institute, shares his breadth of knowledge on the mitochondrion organelle: its histo...ry, function, genome architecture, and his research of rare mitochondrial dysfunction. Vamsi is currently focused on finding clinical treatments for the 300-some identified rare disorders, but in this work there is a wealth of potential implications in the context of longevity and chronic disease. In this conversation, Vamsi elucidates how the latest research could give insight into conditions related to aging, including but not limited to Alzheimer’s disease, Parkinson’s disease, insulin resistance and type 2 diabetes, cancer, and much more. We also explore some of the most exciting potential therapies for mitochondrial diseases such as hypoxia (oxygen deprivation), how exercise affects the mitochondria, the use of hyperbaric chambers for cancer therapy, and the mechanisms by which Metformin might confer longevity benefits in a non-diabetic individual. We discuss: The Broad Institute of MIT and Harvard [8:00]; Vamsi’s academic background [10:30]; Advice for college students and med students considering a career in medicine and/or medical research [15:30]; Vamsi’s focus on mitochondria and mitochondrial disorders [20:00]; The mitochondrial genome: Lineage, endosymbiosis, and reductive evolution [23:15]; How many diseases can be attributed to mitochondrial mutations? [28:45]; Nuclear DNA and mtDNA: Roles, interaction, communication, and biogenesis [31:30]; Which cells have the most mitochondrial DNA? And how often does mitochondria turn-over in a cell? [37:30]; Does ALL of your mitochondrial DNA come from your mother? [40:00]; Mitochondria 101: The powerhouse of the cell, electron transport chain, and the NADH/NAD ratio [44:00]; NAD and NADH: Role in the mitochondria, decline of NAD levels with age, and what it means to age at a mitochondrial level [51:30]; Mitochondrial diseases Vamsi studies in his lab [55:15]; Mitochondria and oxygen: Poor oxygen utilization and excess oxygen contributes to the pathology seen in some of the rare mitogenic diseases [1:02:00]; What VO2 max can tell us about mitochondrial function, insulin resistance, type 2 diabetes, and more [1:10:00]; Can studying mitochondrial disease provide insights into the common forms of aging? [1:18:45]; Could muscle cell inflammation (a signature of aging) be caused by mtDNA damage being confused as foreign bacteria? [1:22:00]; Exercise and mitochondrial health: Is there an optimal exercise strategy to slow the aging process? [1:27:00]; What autophagy means in the context of mitochondria [1:36:15]; Metformin’s impact on exercise and lactate levels [1:40:15]; How might metformin confer longevity benefits? [1:48:15]; Hypoxia as a potential therapeutic option for mitochondrial disease [1:52:45]; Cancer prevention and treatment: hyperbaric oxygen chambers, targeting single carbon metabolism of the mitochondria, and more [2:00:00]; Chronic diseases have altered mitochondria: Evidence for mitochondrial dysfunction causing Parkinson’s disease [2:04:30]; Why Vamsi is very optimistic about the possibility of targeting mitochondrial proteins as therapies [2:09:30]; Is it theoretically possible to genetically engineer a better functioning mitochondria? [2:14:30]; Vamsi’s fantasy experiment in an unconstrained world [2:20:15]; and More. Learn more: https://peterattiamd.com/ Show notes page for this episode: https://peterattiamd.com/vamsimootha/ Subscribe to receive exclusive subscriber-only content: https://peterattiamd.com/subscribe/ Sign up to receive Peter's email newsletter: https://peterattiamd.com/newsletter/ Connect with Peter on Facebook | Twitter | Instagram.
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Hey everyone, welcome to the Peter Atia Drive.
I'm your host, Peter Atia.
The drive is a result of my hunger for optimizing performance, health, longevity, critical thinking,
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to help you live a higher quality, more fulfilling life.
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My guess this week is Dr. Vamsi Muta. Vamsi is a professor of systems biology at the Harvard
Medical School. He has an appointment at the Broad Institute, which is actually where we
met to conduct this interview. We talk a little bit about what makes the Broad so special. He specializes in rare mitochondrial diseases,
as opposed to longevity per se,
something that I love to talk about.
But I think you'll see in this interview,
why it's so interesting to talk to someone
who specializes in rare orphan mitochondrial diseases
about longevity.
His laboratory uses a blend of genomics,
computational biology, biochemical physiology, and systems
biology to study mitochondrial function and dysfunction.
He received his bachelor's in mathematics and computer science at Stanford before going
on to Harvard as part of the joint MIT Harvard program in medical school.
He stayed in Boston to do his training in internal medicine, though as we discussed he now
focuses exclusively on research. stayed in Boston to do his training in internal medicine, though as we discuss, he now focuses
exclusively on research.
He's received more honors and awards than I could name here, but it's always worth mentioning
it when someone is a genius award recipient.
So he won the MacArthur Foundation Award in 2004, which obviously puts him in pretty
rarefied earth.
In this episode, we talk about a lot of things.
We start with, at least for me, one of the best discussions I've ever had on the mitochondria.
You might think at first that some of this recapitulates things that were discussed on previous
podcasts.
You may recall we had a great discussion on the mitochondria with Neve Deepchendel, but
we go a little bit deeper and we talk more about some of the evolutionary pressure around
the mitochondria.
And even though at first you might think,
well, gosh, this seems awfully scientific,
where is the application?
If you stick with it, you're going to see where it comes
and how understanding these rare orphan diseases
that most of us have never heard of
can give us an insight into aging.
We do eventually start to talk about metformin,
which I know many people ask about, and he provides a great insight into, or several great insights into what metformin
may or may not be doing. And again, for at least for me, this was like just the master's
class in mitochondrial biogenesis, electron transport chain, et cetera. Talk about ways
that we can target mitochondrial proteins and complexes to treat disease.
But perhaps the single most insightful and interesting thing that we talked about that
completely blew my mind was the role of hypoxia as a treatment.
I want to repeat that again.
The role of hypoxia, oxygen deprivation as treatment.
Now, we're going to cover this in a way that I think is very interesting, so I don't want to say any more about it, but I do want to add
a disclaimer to this that Vemce and I spoke about after the podcast and I want to
make sure it's here, right? So, Vemce emphasizes that their published research
to date on the beneficial effects of hypoxia and animal models of mitochondrial
disease is still in its early stages, and it's restricted
to animal studies.
It is not yet ready to be applied to humans.
To extend these ideas to humans would be premature and irresponsible since epoxy can have life-threatening
implications.
If and when the concept is extended into humans, it will need to be done so in a clinical
trial setting with the appropriate ethical, ethical regulatory and safety measures in place.
So, would that caveat and without further delay? Please enjoy my conversation with Dr.
Bamsi Mukha.
Bamsi, thank you so much for making time today.
No, absolutely welcome.
Yeah, yeah.
Site unseen, too.
I'm always impressed when people I don't know in advance agree to sit down with me.
I'm kind of honored humbled. So thank you very much.
Thank you for coming in meeting.
Yeah, the Broad is quite an impressive place. Tell folks a little bit about where we are right now
and what makes this unique even within the Hallowed Halls of Boston Biomedical Research Institutes.
Now, I think it's a really exciting place and I've had the pleasure of actually watching it blossom from nothing.
It's really the brainchild of somebody named Eric Lander, who was one of the leaders of
the human genome sequencing project.
And as that was being completed in draft form in 2001, and then in quote finished form
in 2003, he sought the need to create some sort of an entity that would take advantage of
the power of genomics for improving biomedicine. So he created this institute and it's unprecedented
in a lot of ways. It's joint between Harvard and MIT. It involves all of the hospitals here in
Boston. And it's basically an incredible forum where people can get together
and basically pursue projects that they can't pursue on their own, in their own individual laboratories.
There's a big computational theme here. There's a big theme on being systematic in one's approach,
not focused narrowly on the protein that they've studied in the past, but being systematic and
seeing where the data takes you.
And there's a very pervasive theme of collaboration as well.
So Eric has always said that the Broad Institute
is a bit of an experiment,
but now it's been about 15, 16 years,
and I think without a doubt,
it's been a wildly successful experiment.
Do most of you here at the Broad have an appointment elsewhere?
Like I know you spend much of your time at Mass General.
Lots of people here spend, they have an appointment at MIT. Does everybody have an appointment elsewhere. Like I know you spend much of your time at Mass General. Lots of people here spend, you know,
they have an appointment at MIT.
Does everybody have another appointment
outside of the road?
Almost.
So there's almost two types of people that work at the road.
There's some people that are actually
formally employed by the Broad Institute.
And there's others like myself that are employed elsewhere.
In my case, I work at Mass General Hospital
and Howard Hughes Medical Institute.
That's my primary appointment.
My paycheck comes from there.
But then I spend a day a week over here working on collaborative
types of projects that I can't pursue easily in my own
own lab.
There's almost two types of folks over here.
I think one of the neat things about the Broad Institute is,
traditionally, there's this grad student postdoc, assistant
professor, academic track, but how about for all the other people
that want to do research in a nonprofit academic setting,
but aren't interested in applying for R1 grants or teaching.
The Broad actually has an entire research
scientist track as well.
And so you can be employed here as a research scientist,
doing science and funded here and funded here.
And I think that's a very, very different organizational model compared to any other academic
organization.
Let's back up for a moment.
You studied at Stanford where you did, were you a computer science major?
What was your major in undergrad?
I was math and computer science.
Okay.
Got it.
Did you know you wanted to get into biology and medicine?
You know, when I was a kid, I'm an Indian American.
My father is a retired surgeon,
as it turns out my three-older siblings
would end up becoming doctors also.
So I like to joke that we had the medicine gene
in our family.
So growing up, I was convinced I wanted to be a doctor
of some sort, but then in high school,
I fell in love with math.
I did the high school math competitions.
It was pretty good at those.
Did the high school science fair competitions in math? Did well with math. I did the high school math competitions. It was pretty good at those. Did the high school science fair competitions? In math, did well with those. And so I ended
up going to Stanford with the goal of being a math and computer science major. And that's
what I was squarely focused on. And then towards the end of college, when I was looking for research
project, my advisor told me about the work of Sam Carlin. He's a statistician that was
developing some of the underlying methods for bi-molecular sequence analysis. He's a fundamental
mathematician and statistician. And this is like early 90s. Early 90s, that's right. That's
right. So I ended up working on DNA sequence analysis as a college student writing code to try to
analyze DNA and protein sequences. And I fell in love with that.
And then my advisor said, why don't you contemplate a future career in medicine if for no other
reason.
Going to medical schools are great way of learning physiology.
You know, I thought about it from a practical perspective.
I applied simultaneously to PhD programs in mathematical biology, and also applied to MDPD
programs. And then I applied to this program joint between Harvard and MIT. I actually thought
that it was an MDPD program. This is all pre-internet. So I thought it was an MDPD program, but
it wasn't. It was a straight MD program, but it's a joint program between the two institutions.
Yeah, they set aside like a, I remember like 20 students for this.
It was called the H.
HST.
HST program.
That's exactly right.
Yeah, that's right.
So it's a part of the HST program and it was kind of catered to students that had
slightly quantitative backgrounds, math, computer science types of backgrounds.
So it provided a bit of a more gentle introduction to medical school.
I could have used that program.
My first year of medical school was just unbearable.
I mean, it was such a culture shock of,
that don't know if I told the story on the podcast before.
The worst exam I've ever done in my life
from the point when I decided to care about school
was the first semester histology exam in medical school
because I very arrogantly and naively assumed that if I understood the
concepts of histology, I didn't need to memorize anything.
So I took this very pure math approach, which was I could just derive everything in my mind
if I understood the fundamentals.
And that got me a 53% on the final exam in histology,
which like I just sat there looking at this number,
thinking, how is this possible?
Am I the stupidest human being that has ever walked
the face of it?
It was really a wake up call that said,
you know, you're gonna actually just have to start
memorizing things around here.
It's a big culture shock, I think,
when I know you have a background in engineering
and applied math, so very similar to my background,
and it made for a lot of unhappiness for me
also that first semester of medical school.
At least you were in California,
I was facing the Boston winter at the same time
I was facing histology.
That's a good point, I did have that going for me.
So when you finished med school, you did a residency in internal medicine.
You stayed in Boston, correct?
You stayed at the Brigham?
That's right.
That's right.
I've been here now for, it's hard to believe, but about 25 years.
During residency, the Brigham is obviously certainly among the top three most academic medicine
programs in the country.
We're talking to one of your colleagues yesterday and he made the point that when he looked at his class or the cohort of people that entered
medicine at the Brigham, you just fast forward 20 years in there basically, the leaders within
each of the different scientific fields. So I assume that was a pretty deliberate decision
on your part to really preserve sort of academic optionality. You know it.
I think it almost every single one of these junctures.
The nodes, yeah.
Exactly from college to medical school, medical school to residency.
I think maybe I'm just inherently a bit of an indecisive person, but I was unsure as to
whether or not I wanted to do a residency by then I'd fallen in love with basic research.
And the question was, was I going to do a basic science postdoc?
Or was I going to do a residency?
And so just as I did at the previous node, I decided to just apply for both.
So I simultaneously applied for postdoc positions and for residency programs.
That was the era when you would fill out your residency match list with a number two pencil.
Mm-hmm.
So I'd fill it out every day.
I'd listen to how you kind of wrote a number two pencil. So I'd fill it out every day. My Dixon, how you kind of wrote a number two pencil.
I love those things.
So I'd fill it out and then I'd rip it up the next day.
I'd fill it out and rip it up the next day.
And I joke that the only reason I did a residency is because the due date was in even numbers.
On the subject, that's the way you're saying it.
So that said, I want to put you in the spot and ask you a question that I get asked all
the time and frankly, I don't know the answer to it and I feel bad that I always provide
sort of nebulous answers.
But I do get asked a lot by either college students who are contemplating medicine or not
or medical students who are interested in research.
And the question is a variant of one, if you're at the college
node, but you're very interested in medical research, is there benefit to doing an MD?
And then the second order question is, if you're in medical school and you're going to finish,
and you know you want to do research, is there a benefit to doing a residency? Now, I
generally tell people, and if you disagree with me, I hope you say so very loudly.
I generally say if you're in college,
but undecided about medical school or not,
I would say don't do it, pursue the PhD.
If you are in medical school
and presumably at least somewhat interested
in medicine still,
do an internal medicine residency
because there is no substitute for doing that type
of research and at least
having the ability to understand clinically why you're doing it.
So again, do you disagree with that and if so, how would you modify that?
And I'll also get asked this question quite a bit because I think there's a group of people
out there that love science are probably good at clinical medicine if they do it, but they're
also good at research if they do it, but they're also good at
research if they do it.
And maybe they're inherently a little bit risk-averse as well.
So they're always trying to figure out what's the best path for me.
The advice that I had gotten when I was in college was that the reason to go to medical
school if you're interested in research is that it's one of the best curricula for understanding
physiology, how do all of the parts come together and operate?
And trying to understand how an entire living system
operates if you don't go through all of medical school,
if you don't learn anatomy, if you don't learn histology,
if you don't learn cardiovascular physiology,
it's a bit tough.
And so it's a good point you make, right?
Which is in somewhere between 16 and 24 months,
which is the pre-clinical
part of medical school, it's almost impossible to get a more well curated view of the human
body because it's been optimized for that over 100 years.
That's exactly right.
More.
And it's a living system, right?
I mean, you could study yeast, you could study drosophila, but the human is extraordinarily
well investigated.
And you're right, in about two years or so, you have a very intense curriculum studying
one living system, different aspects of it.
So from that perspective, I think it's a great education, it's a broad education for biomedical
research.
At the other node, again, I spent a lot of time thinking about this, and one of my advisors
actually said at least do an internship
because then you'll be licensed.
You can prescribe medicines at that point.
And there is something special about caring for patients.
There's something very special about going through the process
of residency with your colleagues.
And again, you really get to see the human living system
at some of its extremes.
And so I think it's a great way of continuing to learn physiology and pharmacology as well.
So I'm super grateful for the path, of course, and of one experiment,
but I'm really happy that I did medical school and I'm also super happy.
I did the clinical training as well because it completely shaped my research focus as well.
Okay. No, that makes sense.
I generally say the same thing, which is,
I don't regret the path I took, though I'm glad I didn't know in advance what it was going to look like,
because it would have seemed too indirect, but nevertheless.
So, right now you spend virtually all of your time doing research.
Is that correct?
That's right.
When did you stop seeing patients?
It's been about five to six years or so.
Was that a tough decision?
It was tough because we went through this entire medical school and residency process with
the goal of actually seeing patients and caring for them.
The truth is the number of patients I was seeing was asymptoting as a function of time.
Emotionally it was very, very difficult to go to zero.
So even though I was seeing probably one patient a month or so,
five years ago or so, going to zero was actually the harder part.
But at some point I had to just do the math and say there's only a certain
number of hours per day.
I'm running a pretty big research group that's focused on mitochondria
and mitochondrial disorders.
And the long-term goal is to impact these patients.
And so, I'm going to let other people be the ones that care for these patients at the
front line.
I'm going to try to develop new diagnostics and drugs for these patients.
So let's start talking about the mitochondria.
When did you come to the realization that that was the RIE you wanted to focus on and what
is it about the mitochondria that especially drew you in?
So as a first year medical student, I was a little bit unhappy.
You're in Boston. It was cold. There's a lot of memorization that first year,
that first semester in particular. I wasn't sure if I actually made the right decision in coming
to medical school from a math background. And then right in the middle of that first semester,
when we're taking our histology and pathology
class, we have a very, very brief lecture on myopathies, muscle diseases.
And there's one slide that basically indicated that there's a rare form of myopathies that
are due to mutations in the mitochondrial DNA.
Now, truth be told, I don't think I'd appreciate it at that time that we had our own mitochondria
with their own genomes.
And so that immediately fascinated me.
You dig a little bit deeper.
You learn that these are once bacteria.
They're kind of swimming around in our cell, so that's kind of cool.
You see an image of mitochondria in the muscle.
It's just beautiful.
And there's just something that really captivated me.
And I kind of got hooked on that organelle, that first semester of medical school.
And I've told this story to other people, Peter, what would happen was a few weeks later,
my dad's cousin, who is at that time a postdoctoral fellow in the Harvard research,
one of the research hospitals.
She heard that I was unhappy.
So she invited me over to her house in Somerville for a Friday night dinner. So it started to snow. I took the red line all the way
to Somerville. It was a 20-minute walk to her house. By the time I had gotten in, my shoes were
soaked. I was freezing. She immediately looked at me and said, oh my god, you look terrible. And so
she took my coat off. She tried to dry me up, and she started cooking dinner.
And then her boyfriend appeared like an hour later, and now is about eight o'clock or nine
o'clock or so we had dinner together.
And then we found out that the tea had been shut down.
And so not only was I unhappy first year medical student, but now I'm spending Friday night
with my dad's cousin and her boyfriend in Somerville.
And so they create a makeshift bed for me in their living room.
I'm spending the night there at this point.
And I look at the bookshelf and there's a textbook of mitochondrial biology on the bookshelf.
So just a few weeks earlier, I had this initial encounter with the organelle.
I saw this book, so I just took it off the shelf and I I just started reading it. I read about 100 pages that first night. I borrowed it,
and then I basically devoured that book over the course of the next few weeks. I just fell in love
with the organelle at that point and blocked myself, but this is what I want to work on for the rest of my career.
That's an amazing story. I think for people listening, they shouldn't be concerned that they
haven't had that eureka moment. I've heard a lot of amazing scientists talk about their
passion, and not all of them. In fact, most of them don't have such a laser moment like
that. Now, of course, the stories of people that have those moments are even more vivid
in my mind of that, oh my God, I can't think of anything but this. So let's talk a little bit about the mitochondria.
You've already alluded to some of the really interesting features about it.
So let's start with the, well gosh, which one is the most interesting.
Let's just start with the lineage, right?
So how do these bacteria find their way into these eukaryotic cells?
Yeah, this is, I think, one of the most fascinating aspects of the organelles.
So this is a process known as endosympiosis.
So the current theory is that there is an organism probably resembling a modern day
gram-negative rod, something like a ricketsuil species.
That mure...
Folks might not even know what that means.
So gram-negative is just a staining that allows us to identify a type of bacteria.
So you've got
this bacteria that is shaped like a rod, literally. And how does it get its energy prior to
this encounter?
The thinking is that it had a full electron transport chain and was probably capable of
doing aerobic metabolism using things like oxygen as a terminal electron acceptor. And
one of the theories proposes that that had
an electron-transport chain that's not that different
than modern day mitochondria.
The hypothesis is that that somehow merged with
something resembling modern day archia.
So there's three main domains of life.
You have archia, you have bacteria,
and then you have Eukaryotes.
And Eukaryotes have Enucleae, so the hypothesis is that there's an Archaea species, there's
a bacterial species. They form a union of some sort, and this is what gave rise to modern
day Eukaryotic cells, maybe about one and a half billion years ago.
That's kind of remarkable. And is the idea, I mean, what kind of evolutionary
pressure must have been placed to create an entirely new species? It's also binary. It seems
somewhat binary to me. Is it? In other words, when you look at the difference between, I don't know,
say, chimpanzee in an ape or an ape in a human. You can see lots of continuous evolution, you know, Neanderthal, et cetera, et cetera.
What you're describing sounds much more switched on switched off.
Is that the case?
Is this a, or were there lots of iterations that we can't even appreciate today in between
the union and the current paradigm?
As far as we know, endosymbiosis of the mitochondrion
only took place once.
Wow.
So there are lots of eukaryotes,
almost not all, but almost all eukaryotes,
have a mitochondrion.
And if you look at the DNA of those mitochondria
that still have a genome,
the phylogenetic analysis tells us that this was a monophytletic event.
This took place only once.
Now that's not true for something like the chloroplast,
that also arose through serial endosymbiosis,
and that likely took place at least two independent times in evolution.
But for the mitochondrion, it probably only took place once as far as we know.
And the chloroplast, of course, is to a plant effectively what the mitochondria is to an
animal like us.
That's exactly right.
Yeah.
So how many genes do we think that that gram negative rod had?
Great question.
Probably about a thousand to two thousand.
And at the time, the species that it merged with would have had how many for the best of our
guessing probably also few thousand so you had two things that had comparable numbers of genes
Merge and yet today
You or I would have
30,000 20,000 genes
inside the nucleus and we'd have is it 13 genes inside our mitochondria, 13 preserved genes.
So in other words, to a first order approximation, the mitochondria lost all of its genes, but
a deeper dig says, actually it somehow hung onto 13.
Why do you think that was?
This is what we call reductive evolution.
Modern day mitochondria actually represent a mosaic.
So you need about 1,000 proteins total
to make our mitochondria.
And so some of those are attributable
to the original bacterial ancestor.
And others are brand new innovations
that even that original bacteria did not have.
But on the reductive side, approximately 1,000 genes from that
original bacteria have either been lost altogether or have
been transferred to the nuclear genome so that that genome
today is tiny. It's only about 16,000 basis. It encodes
13 proteins. But that's only if you're looking at animals.
There's a lot of different eukaryotes, so there's a lot of mitochondrial diversity.
So you and I still retain 13 proteins that are encoded by our mitochondrial genomes,
but if you look at malaria, it's also eukaryote.
It has a mitochondria, but it's genome only encodes three proteins today.
So that's additional reductive evolution.
What about things like, in a fly's yeast, are they also variable? only encodes three proteins today. So that's additional reductive evolution.
What about things like in a fly's yeast,
are they also variable?
Flies are also animals, and so most animals...
You would put them in the category, yeah.
That's right, so they would have about 13,
sometimes 14 proteins.
But if you look at something like GRD,
which causes a terrible diurel illness, beaver fever,
that's a eukaryotic.
It's actually lost its mitochondrial DNA
all together. I know we talk about 13 proteins. Is it one-to-one mapping or are there genes that are
non-coding or is it? Right, so the mitochondrial genome encodes two ribosomal RNAs,
22 tyrannase, and then 13 proteins. 13 proteins. So, to have 13, we pretty much have a good sense of what the function of each
of these are.
How many diseases that afflict humans result from genetic disorders there?
Inherited mutations that produce dysfunctional proteins.
All right.
There's about 250 different syndromes of the MTDNA of the mitochondrial DNA.
And by syndrome I mean there's a particular mutation
that's associated with a particular clinical phenotype.
But that's only for talking about the mitochondrial
disorders of the MTDNA.
That's right.
Is that a higher or lower frequency
on a probability basis given the number of base pairs?
Because you said something like only what, 16,000 base pairs,
it's relatively tiny.
We have genes in our nuclear genome
that are 10 times that size.
So from a probability basis that you could have 250 mutations
in that 16,000 base pair that would each lead
to these distinct mitochondrial diseases,
is that more or less robust from a DNA perspective than our nuclear DNA?
I don't think we have a good answer to that question.
There's a little bit of an ascertainment bias in clinical medicine.
So when I was going through residency, probably when you're also going through your clinical
training, the answer to almost every single question about mitochondrial disease was maternal inheritance.
And that's because the nuclear genome was sequenced and draft format in 2001, but the mitochondrial DNA was sequenced in 1981.
So, those almost exactly 20 years earlier and it's small.
And so, as soon as you saw patients that had a particular clinical phenotype
that could be a mitochondrial disease,
it was easy to sequence the mitochondrial DNA.
So beginning in 1988,
when two papers were published
reporting their first mutations in the mitochondrial DNA,
it's been relatively straightforward to sequence it
and associate mutations in the MTDNA
with the disease phenotype.
And this is why now there's about 250 of these MTDNA mutation,
clinical phenotype mappings.
The nuclear genome has been a little bit slower to follow since 2001.
In beginning even a little bit before the completion of the genome sequence,
we've now as a community-bene to identify about 300 different genes in the nuclear genome that underly mitochondrial disorders.
And of course, that's 300 different genes, but then there's different alleleic variants
as well.
So I think it's going to be a little while before we can answer your question in a satisfactory
way, but it's a really provocative question.
And one more number to sort of extract from that is, do we have a sense of how many genes
in the nuclear genome are required for mitochondrial function?
So in other words, what's the denominator?
Nuclear wise.
That's actually one of the areas that we focused on heavily in our laboratory.
So beginning soon after the sequencing of the human genome, we knew that the human genome
encodes about 22,000 proteins.
So, an important question is, which of those find their way to the mitochondria?
It's going to be more than 13.
These are elaborate organelles.
So, we used a lot of methods in the early 2000s, things like proteomics, GFP tagging,
microscopy, computation, and we're able to identify about
1100 proteins that are made by the nuclear genome that find their way into the mitochondria.
So those 1100 proteins have to work with those 13 proteins in space and time to do all the
amazing things that the organelle does. How do they communicate? Do we know how expression of MTDNA is coordinated
with nuclear DNA?
It's a really, really interesting question.
So some of the mechanisms are known,
but a lot of mechanisms are not yet known.
So when you exercise, for example,
if you're deconditioned and if you do a combination
of aerobic training and strength training, you can
actually increase the number of mitochondria.
And there's an entire transcriptional program that will turn on all those nuclear genes,
but that same program will also turn on the replication factors that will go into the
organelle and cause the mitochondrial DNA to replicate as well.
So it's a really smart transcriptional program
that sets in response to exercise,
make more of the nuclear encoded components
and make more of the mitochondrial DNA
and make more of the mitochondrial DNA encoded proteins.
So that increases mitochondrial density in a given cell.
So you have a myosidimussel cell.
Do we know what the actual signals are?
They basically instruct the cell to make more DNA.
So what is the input from the exercise? You mentioned two types of exercise, right? Strength training
and aerobic activity. Those have very different physiologic properties. So what is it that
at the physiologic level is leading to this nuclear level? One of the important signals is something called AMP kinase, the change in the ATP to
ADP ratio.
That's known to be one of the activators of this particular transcriptional program that
induces mitochondrial biogenesis.
So this would be a decrease in AMPK activity?
An increase in AMP kinase.
An increase, okay.
So that is basically sensing something like the ATP to ADP.
Racial is going down.
And so when we exercise the ATP levels
are usually pretty nicely defended.
But then what's happening is there's
another reaction that's taking two ADP molecules
making an ATP liberating AMP.
While ATP levels are defended, some of these ratios change, and that can
be sensed, and that's one of the inputs into this program that says, let's make more
mitochondria.
Now, we'll come back to this far down the line, but just because you mentioned it, one
of the effects of a drug called metformin that everybody loves to ask about is it activates
AMPK.
Does that imply that metformin administration
by itself alters mitochondrial density?
So I think when we talk about exercise,
I think AMP activation is generally regarded
as one of the important signals
for mitochondrial biogenesis,
but I don't think it is sufficient.
It's not sufficient, it's necessary though, potentially.
I think it is, but I would need to review some of the older literature to really confirm
that.
So what do you think some of the other signals are?
I think some of the other signals are things like calcium.
And clearly, there's other signals.
There's a couple of disease states as well where we see a massive proliferation of mitochondria.
They're not functioning properly, but there's a massive proliferation of malfunctioning mitochondria. They're not functioning properly, but there's a massive proliferation of malfunctioning
mitochondria. So we're trying to work at some of those signals as well. So as of right now, it's a
bit of an open question as to exactly how the number of mitochondria is sensed and regulated,
but we know some of the inputs. Right. We know crudely what the inputs are, right? Exercise,
as you mentioned, what are some of the other things that even hormonally,
for example, did nutrients play a role?
One of the studies that I was a part of about 10 to 15 years ago
or so show that even things like androgens
and testosterone can actually influence
the amount of mitochondria.
Disuse is a great way of rapidly eliminating mitochondria.
And in terms of nutrients,
NED is an important signal as well.
The transcriptional regulator that I'm talking about, it's called PGC1 alpha,
and upstream of it is something called certi1,
which of course utilizes NED as a co-factor.
So there's a couple of these inputs.
I'm having lunch with David Sinclair later today. So we'll be talking plenty about this.
Absolutely. Absolutely. So I think a couple of these
signals are beginning to emerge. But we're not at that stage right now where
in a pill we can put seven of these things, give it to a patient,
and boom, we can replace exercise. We're not there yet, but it'd be remarkable if we understood the process well enough so
that we could one day.
Yeah, there's been lots of claims of exercising a pill.
I remember the New York Times wrote about something called iris and got they wrote about
it in 2011, 12, and then I saw it again recently.
And it's funny, of course, you see these stories which you realize they're being written
about in such a crude way that you can infer nothing. So you go back and
look at the paper and you realize it's kind of a ridiculous claim at this point. What
is the turnover of mitochondria in a cell? So if you have, let's put some scale to things
for folks. So I'm going to take, I'm going to biopsy one cell from your quadricep, one
muscle cell. How many mitochondria approximately would be in it,
assuming you're a relatively well-conditioned individual?
Talking about the number of mitochondria is a little bit ambiguous
because they're not quantal units.
Mitochondriol constantly undergo fusion and fission.
So at any given state, you can have a different
quote number of mitochondria.
The mitochondrial DNA is a quantal unit. But at any given state, you can have a different, quote, number of mitochondria.
The mitochondrial DNA is a quantal unit.
You can ask how many mitochondrial genomes are there, per nuclear genome in a cell type.
Okay.
So a fiber blast will have a few hundred, maybe a thousand copies of the mitochondrial genome
for each of the...
For each copy of each nuclear genome.
That's right.
But there's a lot of variation.
The highest would be what?
Like a cardiac myocytes or something?
Or a neuron?
The unfertilized egg.
Wow.
It has half a million copies of mitochondrial DNA.
See, I wouldn't have guessed that.
I don't know why.
I could have come up with 10 guesses,
and that would not have been one of them.
It's remarkable.
And dad sperm probably has a few hundred at best.
And I would have guessed the sperm needed more because it's doing the motion, right?
It has to fight to get to the egg.
Part of the reason is that the egg is so big relative to the size of the sperm.
So that's to a first order approximation, the explanatory variable.
But the unfertilized egg is sort of the Olympic gold champion when it comes to MTD molecules.
The Michael Phelps is the Michael Phelps of MTDNA.
That's right.
That's right.
And then red blood cells, of course, have no mitochondrial DNA.
Yeah.
Then what's the turnover look like, right?
So if you have a cardiac myosite that presumably lasts for a long time, you're in an individual,
like these cells are not turning over quickly.
Are they turning over new mitochondria?
Constantly. Is that how often is that mitochondrial DNA churning over? I guess I'm trying to get at is
what's like the half-life of these sort of non-discrete mitochondria?
I think in most non-dividing tissues, the half-life is on the order of a few days.
Wow. So we are cranking out mitochondria. non-dividing tissues to half-life is on the order of a few days.
Wow. So we are cranking out mitochondria.
That's right. That's right. There's differences between dividing cells versus
non-dividing cells. When you have a dividing cell, obviously, as a function of the
eukaryotic cell cycle, you need to double the number of mitochondria and then
you partition that into two, then you double
partition. So dividing cells have very different mitochondrial turnover dynamics than non-dividing
tissues like muscular neurons.
Um, I was like 100 other questions I want to ask, but I also don't want to, I want to
get us back to the beginning so that we can set the framework to ask some of these other
questions. So you alluded to something, right, which was, I believe something that, at least for me,
until very recently, I didn't think was challenged or questioned, which was the origin of, said,
mitochondria being maternal.
So presumably in the early 80s, when we first, we, like I had anything to do with it, when people far smarter than me,
sequenced mitochondrial DNA, given how few the number of genes were, it was not difficult to
realize, hey, this all seems to come from the maternal side, not the paternal side. And as recently as
several years ago, that was considered almost an axiom.
All the DNA in your mitochondria comes from your mother, not your father.
Has that been called into question lately?
Have there been exceptions to that?
I think the textbook teaching is that the mitochondrial DNA is transmitted exclusively
maternally.
And the reason for that is related to...
It comes back to the egg, I'm sure, right?
It gets back to the sexual dimorphisms.
The egg is huge, it has half a million copies of MTDNA.
Dad's sperm is tiny, it only has a few hundred copies of MTDNA.
So by sheer dilution, it's very difficult for dad's MTDNA to get transmitted.
It's outnumbered, half a million to a hundred.
But on top of that, there's actually active mechanisms
that will seek and destroy dad's mitochondria.
So the mitochondria coming from the sperm
are coated with a protein called ubiquitin.
So after fertilization, those mitochondria
are actually actively eliminated by a surveillance program.
So not only is it very difficult for dad's DNA,
MTDNA, to compete with a huge number of
MTDNA molecules from mom, but those that do make it inside are actively destroyed as
well.
So mechanistically, these are the two reasons why MTDNA is passed on almost exclusively
from mom to child.
Now with that said, about 15 years ago, so there's a case report in the New
England Journal of Medicine that took a biopsy of a particular individual, and they saw
MTDN molecules with two different haplotypes, and then they looked at the haplotype of the father,
and they concluded that this was a rare case of paternal transmission.
So that paper from about 15 years ago was sort of the lone exception to this rule that
we accept as an axiom.
And then about a year ago, we're so in 2018, another paper merged, again, claiming that
in a few families there is paternal transmission of MTDNA.
It's a rare event, but this is an
active area of research. Rules are made to be broken, and I think two things. Number one,
I think other people will have to try to replicate these results to make sure that even if
they're rare, they're real and not some sort of a technical artifact. And the number two,
if they're not technical artifacts, I think there's an opportunity
to learn something very, very deep about the mechanisms of maternal transmission.
Right, because that would suggest, based on the explanation for how this takes place,
it's hard to deny that the first one's going to continue to take place, which is just the
stochastic sampling. But you could certainly see scenarios under which the Find and Kill program malfunctions
and therefore you sneak in a little bit of the paternal DNA.
That's right.
And in fact, in one of these papers that was just published in 2018, they speculated that
perhaps there's a mutation on the nuclear genome in that program so that it's possible for dads empty DNA to get transmitted.
Well, that is interesting,
but I think to the first order approximation,
we can still assume that mitochondrial DNA is maternal.
Yes.
So let's talk a little bit about sort of mitochondria 101.
So you're a first year medical student learning
about the mitochondria, here's basically what you learn,
right, you've got this inner membrane, this outer membrane. I forget what the term is, they call it the
powerhouse of the cell or something like that. I know that people who study mitochondria like
yourself and have deep chendelle, who I've interviewed, sort of bristle at the simplicity of such a
term, but the idea is all things being equal as cell takes in glucose, free fatty acid, substrate
for energy.
And let's start with the glucose, because we'll probably spend more time talking about
glucose today.
Through what I can't even remember, 10 steps, we turn glucose into pyruvate, more or less.
We then basically have a choice.
A cell has a choice based on the availability of oxygen and the rate
at which ATP is being demanded. So if oxygen is scarce relative to ATP demand, you can
take an inefficient route, but at least you guarantee to get some ATP, which is you can
turn the pyruvate into lactate. And lactate itself is interesting, and maybe we can talk about it, but you generate some ATP.
If the demand for ATP is not as great, and there's sufficient cellular oxygen,
you can take that pyruvate and make acetylCoA, and that acetylCoA,
then becomes one of the substrates leading into this thing called the electron transport chain you alluded to.
Walk us through what happens in that latter scenario.
I like to think of the mitochondria as being the key place where there's energy transformations.
So in order for us to sell the work, it needs energy.
But in the same way that in order to live our lives, we need to have one type of battery
for our iPhone, a different type of a battery for our laptop, to have one type of battery for our iPhone,
a different type of a battery for our laptop,
a different type of a battery for our automobile.
We need energy packaged in different ways.
So, this is sort of the charm of the mitochondria,
and what it does is it's gonna take fats
and carbohydrates and proteins,
and it's gonna break it up almost like a kuzin art,
and as it's breaking it up, it's going to harness the electrons, and
that's what's called an electromotive force. That's one type of energy, so you're
probably familiar with things like the NADH to NAD ratio. That's basically an
electron carrier. So that's one form of energy. In certain times of enzymes can
be powered directly by NADH and NH. and an A.D. But
then that can also be converted to a gradient, a voltage across the inner membrane, a different
type of an energy form, and that energy form can be used to drive transport.
So let's explain what that means to people. So everybody knows what a battery looks like.
Like literally a Duracell battery
that you stick into whatever your kid's toy.
And that's typically about 1.5 volts, right?
A nine volt battery gets its name
because it has nine volts.
But everyone recognizes it as the goofy square one.
We take this, I think, for granted,
because we sort of have these backgrounds
in math or engineering and stuff.
But I think for the average person, it's helpful to understand what voltage means.
And you just alluded to it, right?
It's a potential, it's a gradient that is created by disproportionate placement of electrons.
And it's only with that that you can generate power.
So why does a battery die?
Why is it that, let's pretend I'm still using a Walkman.
I put my 2.1.5 volt AA batteries in my Walkman.
At some point it stops working.
Why?
At some point it's not gonna be able to hold charge.
And so I'm probably more familiar with the mitochondrial battery
than I am with the Dorisal battery.
But when you have nicely functioning mitochondria,
you can charge them, you can create a nice voltage
that can be used for work.
You can dissipate it, you can recharge it,
but at some point when it gets older,
when the membrane is a little bit leakier,
when it can't, it'll stop holding charge.
So it's that ability to keep a difference in charge across the membranes
that is the same reason your little 1.5 volt battery in your Walkman. I love that I'm
saying Walkman by the way. There's half the people listening to this won't actually
know what that means. Or then nine volt battery in your smoke detector or frankly the fancy,
I don't even know how many volts a Tesla battery is. It's like 12 volts I'm guessing or something
like that in an electric vehicle, whatever.
But there's a reason you have to keep charging these, but at some point, even when you charge them,
they cease to work, if it's rechargeable.
And you're actually saying, look, think of a mitochondria as partially being a battery.
That's right. That's only one form of energy, right?
So that's taking chemical to electric.
That's exactly right. And so you can have an electro-motor force,
you can have a proton motor force,
and then you can dissipate that battery
to basically catalyze a formation of ATP,
which most people know is the energy form
that's used to power muscle when you exercise.
So the mitochondria is doing all of these elaborate
energy transformations from
electrical potentials, proton potentials, phosphorylation potentials, and different enzymes
and processes and machines in your cells will use one or the other.
This is so exciting. I've tried to have this discussion with my daughter who's 10 and
she's not quite at the point where she sees why I think this
is amazing, but she's almost at that point where I guess you can look at a piece of food
on the plate and explain why eating that is essential. Where is the energy in that food?
So maybe we'll use this as sort of the example to go full cycle. So you are looking at a Cheerio on your plate, right?
Now that Cheerio is mostly carbohydrates, so we'll simplify this.
And it's got glucose in it, it's probably got more complex carbohydrates in it, but at
a molecular level, it's a lot of carbons joined to hydrogens, carbons joined to carbons
joined to oxygens and oxygens joined to hydrogens. That's probably most of the bonds,
correct? So bonds contain energy. There's chemical energy there. Which of those bonds would
be the most energetic? Probably the carbon hydrogen? In total number, just given the ubiquity of it, right?
A carbon hydrogen has more energy than a carbon carbon, I am guessing.
I'm not too sure.
I think that's the case.
In the show notes, we'll list what the potential energy is in each of those bonds.
But nevertheless, you go through this process of actually eating the thing.
You put it in your mouth, you break it down.
Mechanically, you've broken it by the time it exits your stomach.
But it's really once it gets absorbed out of the bloodstream that you begin this chemical
process of breaking those bonds.
And then you get something for free, right?
When you break those bonds, that's when you're getting the energy to create this electron
gradient, which you then use at the end to basically do this one thing you alluded to,
which is phosphorylate the ATP, so that energy gradient allows you to then put a phosphate back onto
an ADP. That's the most obvious one from food. You talked about NAD and NADH. Can you say a little
bit more about what those are and how they fit into this in particular in the mitochondria?
Again, the classical teaching is that NAD is an electron carrier. When you have two electrons, it's going to be in what's called the NADH form.
And if you don't have those two electrons, it's in the oxidized form, which is the NAD form.
That's another way of holding the energy that can catalyze reactions. What we're learning
over the last few years is that in addition to this role as an electron carrier, the NAD itself
can be used as a substrate for other reactions. Outside of the mitochondria or inside. Outside of
its role as an electron carrier. Okay, and that biggest role for that is in these,
we'll come, I guess we'll, we'll allude to it, but there are these complexes in the mitochondria.
But that's still as a redux carrier. So the electrons go from the NADH or transfer to the
electron transfer chain, and that's basically a wire that's going to conduct the electron
until they hit oxygen and make water. That's a downhill process.
And during that downhill process,
these protons are pumped across the inner membrane,
generating about 150 millivolts,
and that can then be used to do work,
including catalyzing the conversion of ADP to ATP.
And that's what we call oxidative phosphorylation.
Yep. But then talk about the other example
that you were using there.
And this is a newer area of biomedicine.
And actually, David Sinclair has worked in this area
quite a bit.
But everything that I just told you
relates to electrons coming on and off of NED.
So when we talk about the NED to NED ratio,
that's sort of the redox potential.
But that NEDule, it can also participate
as a substrate in certain chemical reactions.
So sir two ends use NAD?
Exactly.
Sir two ends, some of the DNA damage response pathways, the parts, they'll actually use the
NAD as a co-factor.
So that's important because it's possible in certain states. When you have a damaged
cell, for example, if you have a cell with damaged DNA, that NAD can decline very, very rapidly.
It's an electron carrier. So you're actually losing the ability to carry some of this charge now.
This is interesting, right? Because observations are, as we age, these NAD levels decline,
is that due to greater demand for it, is it due to production and production?
And of course, the clinical question that everybody asks is, is there benefit to replacing it?
What's really interesting is there's a couple of different signatures of the aging process.
So if you buy up seed muscle from individuals of varying ages, you'll see a gradual decline in the NAD content.
If you quantify the amount of mitochondria using any of the different metrics, you'll see
a decline. If you look at things like VO2 max and skeletal muscle, as a function of age,
you'll see a gradual decline. So there's this gradual decline in NAD
and in mitochondrial activity as a function of age.
And I think the big question in the field is
do you just have an old and sick tissue?
So you have sick mitochondria
or will targeting the mitochondria
actually somehow alleviate
age associated decline in tissue function.
This is such an interesting question and something that probably until a year ago I don't think
I spent enough time thinking about, which is what does it mean to age at the level of the
mitochondria?
And what are the implications of it?
And perhaps most importantly, what can be done to slow the implications of it, and perhaps most importantly,
what can be done to slow the rate of aging.
Now, you study a problem at sort of a different node,
which is you are looking very specifically at diseases
that most people haven't actually heard of,
and I don't want to say you're not interested
in those diseases per se because you are, but they're
basically a gateway for something else. So later on in this podcast, the spectra will come back to
more of this mitochondrial fitness, health, inflammation, my topology. There are many other topics
I want to explore with you. But let's now, having laid the groundwork go back and talk about your work
and what you're learning. So give me an example of some of the diseases
that you study in your lab.
We've historically placed a lot of emphasis
on a very large collection of individually rare
inborn areas of mitochondrial metabolism.
These are typically single gene disorders.
They can be due to recessive mutations in the nuclear genome, or they
can be due to mutations in the mitochondrial genome. But at the end of the day, there's
a component of the mitochondria that's defective at birth. And so what we just spoke about
is the fact that as all of us age, there's a gradual decline in the activity of mitochondria.
The big question in the field is whether that's cause or consequence.
These other 300 rare monogenic disorders of mitochondria, there's no doubt, there's
no question.
The gene did the randomization for you.
You know cause and effect.
That's exactly right.
The mitochondria is defective at birth, and now we can actually evaluate what the consequences.
Now you said about 300.
What is the phenotypic spectrum?
How many of these, for example, are fatal within the first year of life?
They tend to follow a bimodal distribution, the recessive mutations in the nuclear genome.
They tend to present early in infancy within the first few weeks or months of life.
The mutations in the mitochondrial genome, those tend
to present a little bit later in life.
Wow.
So let's focus on the latter group for a moment.
I mean, unless you prefer to start with the former, which one do you spend more time
looking at?
We spend a little bit more time on the nuclear.
Okay.
Because they present earlier, and presumably they're more severe.
That's right.
Okay.
So give me an example of what some of those mutations are and what their phenotype is.
One of the clinical syndromes that we study is something called lees syndrome.
So, there's about 80 different genes that can be mutated to give rise to this clinical
syndrome, which is basically a subacute degeneration of the green matter.
It's a very rapid neurodegeneration.
It's a terrible, terrible disease.
And what age are people when they start to experience this neurodegeneration. It's a terrible, terrible disease. And what age are people when they start to experience this neurodegeneration?
So most of these kids are actually born developmentally, okay?
Wow.
And then within the first couple of months of life, there's some sort of a stressor. Sometimes
it's some sort of an infection, sometimes it's dehydration that'll put them into a neurometabolic
crisis. And at that point, if you look at their brain MRIs,
you'll see lesions in the brain stem,
the basal ganglia, sometimes the spinal cord,
corresponding to regions of necrosis.
Wow, so quickly fatal.
And what did you learn?
I mean, you have one syndrome,
but there are many pads that produce it.
What's the, are there common threads
to the genetic insults
that lead to this awful phenotype?
No, great question.
That's exactly what we're trying to figure out.
So thanks to genetics, we've not been able to...
We as a community, I mean, have been able to map out genes
in the nuclear genome, some of these are in the MTDNA,
but at the end, we get this thing called the syndrome.
And we're trying to figure out what exactly isn't
about the broken mitochondria that gives rise to this phenotype. And honestly, we don't know what
the full answer is right now, but it's a very, very active area of research right now.
It might be naive, but just listening to you describe this, I can't help but think,
can we learn something about Alzheimer's disease or other forms of neurodegeneration, which I think many people
are starting to argue are basically neuronal energy crises.
So there are lots of insults, right?
You can have an accumulation of toxin.
You can have an insulin resistance, frankly, you can have microvascular disease.
All of these things are predisposing people
to neurodegeneration,
and something that they could all have in common
is depletion of energy to the neuron,
which would be perhaps the most sensitive cell
to an energy reduction.
I mean, anybody can think about that for a moment
if you know somebody who's lost their ability
to breathe for a period of time.
Usually the thing we care about the most is their brain
because that's the first thing that you suffer from
when you have a hypoxic event.
So is that based on Lee's Center?
Is that the explanation for why you're potentially
seeing it disproportionately in the brain
versus skeletal muscle?
Is it just the sensitivity of the brain to
energy withdrawal? Or do you think there's something specific about the mitochondria in neurons?
Mitochondral disorders can actually impact almost any organ system, and so lease syndrome represents
one type of clinical manifestation of mitochondrial disease, but there's another set of disorders that impact the skeletal muscle as well.
I think at this point we don't know why mutations in one subunit of the electron
transpor chain gives rise to brain disease, a mutation in the neighboring subunit of the same protein complex.
That's equally evolutionarily conserved.erved will give rise to muscle disease.
Wow.
There's a massive nonlinearity over here that we simply don't understand right now.
So if there is one and only one silver lining in these awful diseases, it's that scientists
will have no shortage of questions to ask for decades to come.
No, I think this is a super active area of research right now.
In part, fueled by the link between mitochondrial decline and aging, so that's such a complicated
problem.
You know, trying to understand why a car breaks down after being in service for 25 years,
it's hard.
Is it some fan belt break to the battery, stop charging, did the tire deflate?
It's kind of hard to know why an entire car breaks down after 25 years. In these rare
mitochondrous disorders, we have 300 different forms of that automobile that was almost broken
at birth, if that makes sense. We study them in
part because these patients need new treatments and therapies and so that's
enough of a motivation for us but we also do expect that a subset of them by
studying them will inform what's happening in a more common form of aging.
Your lab studies oxygen but not necessarily in the way that most people
commonly think about it. Most people when they think of oxygen and mitochondria, something that comes to mind pretty quickly is Ross.
Absolutely.
I spoke with the friend of mine, Navdeep Chendelle, and we spoke a lot about Ross.
And now I've had a great take on it, which was, look, we think of Ross typically only in the negative.
And they do lots of negative things.
But they may also be a signaling molecule,
and therefore an essential thing. Talk to me about the lens through which your group looks at oxygen.
So remember a while ago you asked a very, very astute question. You have these 80 different genes
when they're mutated. They give rise to this thing called lease syndrome, which is a different type of a
neurodegeneration. What does that pathology pathogenesis look like? The traditional dogma
for mitochondrial pathogenesis is that when the powerhouse of the cell is broken, there's
not enough ATP, and there's a power failure. That's the traditional dogma. And without
a doubt, there's truth to that in some instances. What we've discovered is that in addition to producing ATP, mitochondria are also consumers
of oxygen. Most of the oxygen that you breathe, Peter, is being consumed by your mitochondria.
When a patient has a birth defect in the mitochondria. In addition to not being able to produce
sufficient ATP, they also have excess oxygen as well. So oxygen delivery tends to be patent
in these patients, but the utilization ends up being poor.
And oxygen, just asking for people to understand, how does oxygen even get to the mitochondria?
So we all understand that we're breathing air that has oxygen and let's even go one step further
and just take it for granted that there's a gradient in the lung that allows oxygen to get into
hemoglobin to a red blood cell. Now that you have a fully loaded red blood cell in an arterial
that enters a capillary, how many things have to happen for oxygen to get into the mitochondria specifically, not just the cell? Oxygen is not particularly soluble in water or fluids,
and so we have an oxygen carrying protein called hemoglobin that's found in our red blood cells,
and so in the lungs, all of the red blood cells in the hemoglobin get loaded with oxygen,
and now these red blood cells are delivered to peripheral tissues and the
oxygen gets extracted from the fluid and as the fluid gets depleted in oxygen, the hemoglobin
will basically offload its oxygen. And so there's certain tissues that become extremely,
extremely hypoxic. So the oxygen will get extracted by a tissue largely by diffusion.
And the mitochondria is basically consuming most of this oxygen.
So a cell that is sitting there doesn't require an active transportor to get oxygen across
its outer membrane.
So it just diffuses across.
That's right.
And when oxygen enters the cytoplasm, how does it get over to the mitochondria?
Depending on the cell type, but it either diffuses.
How does it know that the mitochondria is the place it needs to go?
Well, it's being consumed, so it's a little bit of a sink basically.
So that's what I want to understand.
There are lots of places oxygen could hang out, so what is the force that is drawing it
into the mitochondria?
Is it simply utilization that basically creates a vacuum?
That's right.
That's right.
Now, in certain tissues like skeletal muscle and heart,
we have other oxygen carriers in the tissue.
Things like myoglobin are oxygen carriers.
So they're almost little buffers of oxygen that are
in the tissue.
They're more like loaders, right?
I think of them as like another storage
for oxygen inside, yeah.
That's right.
But that still has to get off the myoglobin
and get sucked into the mitochondria effectively, right? That's right. So it's another to get off the myoglobin and get sucked into the mitochondria effectively,
right?
That's right.
So it's another little storehouse, if you will.
It's another buffer of oxygen so that when you're exercising, for example, you may not
want to be oxygen limited.
So you have a little extra oxygen in your myoglobin.
But basically your mitochondria is where most of your oxygen is being consumed.
So it's a sink.
And so that's the reason that we have gradients inside of ourselves.
It's amazing. I've never really even thought about it this way, but it's sort of interesting to think
at how efficiently the body disposes of carbon dioxide, because as you alluded to earlier,
the end of that downhill gradient is a final path of electronic acceptance generating H2O and CO2, both of which
we manage to largely off-gas.
So, somehow those things have to exit the mitochondria, weasel out of the cell across the gradient and go
back to, well, in the case of CO2, get back to the hemoglobin molecule and get carried
back.
It's like there's a lot of things going on here. Well, so one of the things that we're discovering
by studying these rare diseases, and this happened because of a CRISPR screen that we did a
couple of years ago. But what we've now discovered is that one of the consequences of mitochondrial
dysfunction is excess unused oxygen. So in other words, if a mitochondrion is failing to do its job, you will be failing to utilize oxygen.
Therefore, you would see an excess accumulation of oxygen.
That's right. And we believe this is our hypothesis now. It's that some of that excess unused oxygen
is what is contributing to the pathology that we see in some of these rare diseases.
It's a very different type of an idea. It's not all about the ATP. It's about excess unused oxygen. And we're not necessarily invoking reactive oxygen.
Yeah, I was just about to say, is it through free radicals or is it actually oxygen to oxygen, no extra
electron oxygen?
This is dioxygen, toxicity that we're talking about.
The way that I like to think about it is that if you have an automobile that's outside
and it's rusting, it's rusting in part because the oxygen is directly oxidizing iron.
You may produce a radical, but that's not the phenomenon.
So the car outside is not rusting because of too much super oxide, or hydrogen peroxide.
It's direct oxidation of iron centers by oxygen.
And so one of our hypotheses is that enzymes are tuned to operate within a particular oxygen range.
And when the mitochondria is not functioning properly, oxygen levels rise, that excess
dioxygen can now oxidize enzymes that will damage them as a consequence.
So it's a very, very different way of thinking about mitochondrial pathogenesis.
Now, why doesn't the body correct for that and note that, well, the oxygen in the mitochondria
is not being utilized as quickly as my evolutionary prediction would allow, but therefore we're
going to, there's less gradient pressure.
So I'm going to off-gas, I'm going to offload less oxygen to the cell with subsequent
trips through, through like in other
words, you almost think this would have been corrected in a few milliseconds.
Well, I think it a healthy human that's exactly right.
We have pretty solid matching of oxygen delivery and oxygen utilization, but we're talking
about patients that have broken mitochondria.
So this is one of the things that we're actually trying to investigate.
One of the ways that Ron Haller at the University of Texas Southwestern Medical Center has
proposed diagnosing patients with mitochondrial diseases to put them on a treadmill, measure
their oxygen extraction, and patients with mitochondrial myopathy will often have high
venous oxygen.
Let's explain that to people because we're going to talk about VO2 max and you alluded to it.
So most people associate that test
with sort of peak athletic performance.
But let's talk about what it looks like.
If I came into your lab and you were doing this,
you'd hook me up to a device.
You'd put me on a treadmill.
You'd make me, you know, just have to do some work
to stress the system.
You'd plug my nose and put a little miserable device
in my mouth,
basically creating a seal that would prevent me from being able to get oxygen
or dispose of carbon dioxide in any place other than the gas chamber that is attached
to the tube going into my mouth.
You'd put me at the, you know, you'd ramp up the speed of the treadmill
and you would be measuring essentially two things.
The amount of oxygen you're putting in, and if it's room air, we sort of know what that
is.
But more importantly, the concentration of oxygen coming out, and that difference is what
you're talking about.
It's that extraction.
Now, what happens in a normal person when you do this?
So, Peter, we actually don't do these types of studies in that humans.
Yeah.
But what one does this, yeah, what would normally happen is what would you be measuring
as a normal person works harder and harder in the difference between provided oxygen and
returned oxygen.
So again, we don't do these types of studies, but in these types of physiological studies
that people like Ron Haller, other cardiologists will perform, they'll look at cardiac output,
as well as the oxygen tensions on the arterial
and venous signs.
And so by looking at all of these numbers,
you can actually figure out quantitatively
the number of O2 molecules being delivered,
as well as those that are being extracted
versus those that are being returned to the venous system.
And so you sort of do a mass balance
on oxygen effectively?
That's exactly right, That's exactly right.
That's exactly right.
And as it turns out, in these patients with inherited mitochondrial disease, for some
reason, the cardiac output is high, the extraction is low in a healthy individual.
Usually, the homeostasis is such that you're not going to be delivering more oxygen than
you really need, so that homeostasis somehow broke in in these patients with...
So that patient would actually have a very high lactate level as well,
because if they're able to produce the cardiac output,
but they're not doing it with oxidative phosphorylation,
they're using their escape valve.
So they're going to disproportionately have high lactate levels relative to a healthy individual. That's right. So Ron Haller
would actually argue that a high lactate in combination with a high
venous oxygen is suggestive of a mitochondrial myopathy. There's a researcher
at the University of Colorado who is looking into this very phenomenon as an
early indicator of type two diabetes.
And it's really fascinating.
I'm going to be going out there to spend some time with them this summer.
They've made the observation that in the early stages of insulin resistance, the muscle,
the skeletal muscle in particular becomes inefficient at oxfoss.
So you start to see even at baseline, even a person sitting at rest, their lactate
levels could be twice as high as that of a fit individual. And of course, he came to
this through the thinking that if you want to understand that disease of the mitochondria,
look at the exact opposite. Look at the fittest people in the world. Look at, you know,
the endurance athletes and ask the question, what do their mitochondria do well? And then what becomes
the polar opposite of that? And in disease, now what you're describing is the most extreme
example I've ever heard of this, right? Absolutely. What you're describing is actually
very consistent with a series of papers that were published probably in 2003 and 2004,
including by myself and collaboration with Laf group and David Elchilder, Ron Khan, who
used to be the president of the Jocelyn, as well as Jerry Schulman from Yale, and Sri
Kumar Nyer at Mayo Clinic.
All of us had sort of papers at the same time.
David Elchilder is here, right?
David Elchilder used to be here. He's now at Vertex, but he's one of the papers at the same time. David Altchiller is here, right? David Altchiller used to be here.
He's now at Vertex, but he's one of the founders
of the Broad Institute.
But all of us had papers published at about the same time
that showed that if you take skeletal muscle
from pre-diabetics, healthy individuals
that have a family history of diabetes,
but are still healthy, they'll all have a reduced number of mitochondria, the
expression of those 1000 genes required for mitochondria.
It's just a little bit lower.
If you look at any one gene, it's not significant, but if you
look at the entire pathway, the entire pathway is down, the
VO2 max is down.
So there's a series of papers back in 2003, 2004 that led to the
mitochondrial hypothesis for type 2 diabetes. The big question still to this date, almost 15,
16 years later is, is that actually causal for the diabetes or is it just an early epiphenomenon?
There's something else, X, that lies upstream of the amount of mitochondria and independently
the predisposition to diabetes or is that a part of the causal path?
That's still unanswered to the state.
And there's nothing in a Mendelian randomization that can answer that question.
So as you probably know, these types of methods are only now becoming possible.
So we're trying to work on those types of projects right now.
You need large numbers of heavily genotyped individuals.
You all need to have nice biomarkers or proxies for mitochondrial function.
So those are some of the types of things we're trying now.
Because it comes up from times to time, do you mind just explaining how Mendelian randomization
works and why it's so powerful?
Again, this is not an area of my expertise.
Others are much more expert at it than I am.
But the analogy that they'll often use in describing a Mendelian randomization
is a little bit like a drug trial.
So in a drug trial, what you'll do is you'll take individuals and you'll randomize them either to a drug arm or a placebo arm,
and then you'll look for an outcome.
There's an intervention which is the assignment
of a drug or the placebo.
And then you can actually check to see whether the outcome
is correlated to that particular intervention.
And if you see an effect, now that effect
is attributable to that intervention.
Because the decision to give the intervention versus the placebo was done randomly.
If you didn't do it randomly, you can't make that assertion.
That's right.
That's right.
Now, in a Mendelian randomization experiment, the idea is that there's a randomization
that took place at birth.
And so if you look at something like LDL levels, for example, an important question is, are
LDL levels causal for heart attack?
Or are these simply correlative for heart attack?
So thanks to genetics, we have a lot of genetic variants that can help explain the population
variation in LDL levels.
Once you have a good solid genetic instrument,
now what we can do is we can take a very large number of individuals
and we can actually draw a bell curve for what their genetic LDL levels must look like.
We haven't measured LDL in them, but from the genetics,
you can actually come up with a bell curve in the population.
And now you can say, let's take this tail, they've been randomized to a high genetic level
of LDL versus this tail, a low genetic level of LDL.
Now, let's see what the outcomes are.
And based on the statistics, based on the patterns of correlation, you can then make the inference
that the LDL is their causal for heart attack
or there's no evidence for causality. I am a not an MR Mendelian randomization
jock, but my recollection in reading some of the papers about this is the one place
that either as an investigator or a consumer of this science where you have to force yourself to look closely as you can be fooled if the
randomization of genes, meaning if the genes that you're looking at can also control
something else that is related to the disease, that could have a counterbalancing effect,
is that correct?
That's one place where one has to be quite cautious.
I think there's multiple places where, I mean, as soon as you have feedback loops,
you can get phenomenon called reverse causation.
You can have your genetic instrument also has to be
really, really good.
So again, this is not my area of expertise.
So it has to be pursued with care for sure.
So there's probably going to be a fair number
of false positive results for all true positive results
from endilian randomization studies.
Yeah, but it is interesting.
I would love to see the MR when it's done for this particular question.
Because again, the implications are significant, both from the standpoint of preventing chronic
disease or risk reduction in chronic disease, but also as we try to approach the
question the way that you phrase that a moment ago, which I really liked, which is everybody
kind of has the gushed all of that car that just sort of breaks down.
And sometimes it's attributable to a catastrophic failure.
Sometimes you blow the head gasket in the car and it dies at that moment
and it just becomes economically not feasible to put a new head gasket on. Other times it just
gets harder and harder to start until it's just not worth driving anymore. So taking this to humans,
how important is mitochondrial health to that process?
In other words, does it become more often than not one of the drivers of this feeling,
this lack of robustness, this lack of stability within the organism?
And it seems to me that it's on the short list of candidates, right?
I mean, when this process goes awry, you are interrupting one of the more fundamental
systems in human biology that affects almost every cell in the body, right?
Absolutely.
I think it kind of cuts both ways because I think when other processes in the cell fail,
I think the mitochondria is at risk for also failing. So it's a highly reactive organelle as well, if that makes sense.
It's going to be a tough question to fully answer.
And this is why we like these rare genetic disorders because they teach us about the pathology
pathogenesis of the organelle in a few defined modes.
And the big question for our field is, which of those rare diseases,
which of those rare forms of pathogenesis,
bears any relevance to the common form of wear and tear aging?
So there may be a small subset of rare diseases
where the fan belt is broken at birth, right?
But it may be the case that the fan belt, as it turns out,
is so resilient, you never have to change it, and it's rarely the cause of a car breaking down.
But it could be the case that it's actually the spark plug, right?
It could be the case that there are certain birth defects with the spark plug, as she
is not working at birth.
And as it turns out, with wear and tear aging, spark plugs have to be replaced. And so we have 300 different
forms of monogenic mitochondrial disease. Right. You have 300 single point of failures to study.
And that gives you a beautiful picture of what it looks like. Some of these are going to bear no
relevance to the common form of aging. That's just going to be a fact.
But the hope is that a small number of these will bear some relevance to the common form of aging.
And just to be clear, we care about these diseases just because these are terrible diseases,
and we need therapies for them. And so that alone is motivation for our work in this area.
But it's also our hope that studying some of them will provide insights into the common form of aging as well.
You talked earlier about signatures of time
and another one of these signatures of time
is inflammation within muscle cells.
There was a paper that came out about a year ago
that used sting to basically block the ability of a cell
to sense breakdown in mitochondrial DNA.
Are you familiar with this work?
I'm a little bit familiar with the sting pathway.
My understanding, it's been about a year since I read this, maybe a bit less, was that
serially if you study muscles as they age, you see more and more inflammation.
So the question is, what is drawing inflammatory cells into muscle as we age?
And the hypothesis was going back to something you talked about earlier.
The DNA of mitochondria is bacterial in origin.
And therefore, if you have a loose fragment of nuclear DNA in the cell,
it shouldn't be especially immunogenic.
But if you have a loose fragment of bacterial DNA in a cell, that should actually be especially immunogenic. But if you have a loose fragment of bacterial DNA in a cell,
that should actually be quite immunogenic.
Our immune systems would think of that as foreign.
So the hypothesis was what if the increase in inflammation
we see is due to greater and greater mitochondrial damage
that is leading to more and more exposure
of mitochondrial DNA.
And I believe to test that, it used sting.
And remind me, I think sting actually blocks
the ability of the cell to sense the mitochondrial DNA.
Is that correct?
Not just mitochondrial DNA,
but I think it's a general nucleic acid sensor.
And so there could be different sources.
I think it could block the sensing of DNA period.
I think ordinarily it's designed to sense
the DNA
of incoming viruses or incoming pathogens.
But you could imagine that if a mitochondria ruptures
that same DNA nucleic acids can also be sensed,
and you're right, because the mitochondria
used to be a bacteria, a lot of the components inside
of our mitochondria resemble that of modern day bacteria and can be very
Immunogenic. I don't know if you've followed. There's a study that came out of the Bethes rule deaconus a few years ago on
sterile crush injury and as a former surgeon you probably
appreciate it, but the observation was that when you had an enclosed crush injury
So the skin has not been spread. There's a massive inflammatory response. So this
investigator was actually trying to figure out what the inflammatory nitus was, did a lot of
fractionation, and ultimately figured out that there was some mitochondrial derived molecules.
And I believe that they found that the mitochondrial DNA, as well as something called
formulated peptidesides are highly inflammatory.
So, remember those 13 proteins that are made by the MTDNA, the translation of those 13
proteins resembles the translation of bacterial proteins.
And bacterial protein translation doesn't begin with a methanol tyranny.
It begins with a formal methanol tyranny.
Remember this F metapyde?
Yeah, yeah, yeah.
This is like, my God, I feel like I'm back in medical school.
Just for no other reason than for me to remember that.
Let's go through that.
So your DNA makes your messenger RNA.
Your messenger RNA then moves over to be translated and to actually have the amino acids put
in place to resemble the code that's being said.
So talk about where the meth terminal
and shows up there.
In you and I, in you, Carriots,
protein translation begins with a methionine residue.
In bacteria, it's not a simple methionine,
but it's a modified molecule.
It's called formal methionine.
And first order approximation,
it's almost a signature of a bacterial derived protein.
And we actually have receptors that are designed to detect formulated peptides.
It's a sign of some sort of an infection.
As it turns out, our mitochondria have bacterial origins, as we have discussed earlier.
These 13 proteins, they still begin with the formal methyning.
Presumably, they can get away with it under normal circumstances because they reside within
the mitochondria.
That's right.
They're protected and shielded from the immune system.
That's right.
So in certain injuries, right, this can actually escape and it can basically activate the
same inflammatory pathways that we have that are ordinarily designed to detect incoming
pathogens.
I can't wait to actually find that paper.
So that was who is the author on that?
I forget his name, but he's from the Bethesional Deaconus.
Okay, it was like.
It was like, oh, two, oh, three ish.
No, no, no, no, this is probably within the last,
a lot, five years later.
Okay, well, we'll find that paper and link to it.
But basically that paper and the paper
I was referring to from about a year ago,
which I think was in science,
both point to a similar conclusion, which is
you can have a profound inflammatory response by simply damaging the mitochondria, and both
of them would point to consistent plausible explanations, which are the body confusing
the contents for bacterial contents.
I think it's a very reasonable hypothesis.
Which then begs the question, if we believe that the aging inflammation phenotype is not
beneficial, how do we prevent mitochondrial breakdown as we age?
I mean, this becomes one of the key aging questions, right?
If you believe that, and again, I don't know what the best analogy is, but Spark Plug failure plays a role more often than not in the overall
picture of decline. The longer you can protect those things, preserve those things, the better.
Another way to evaluating the causality question is if we had a drug that could somehow we Juvenate mitochondria,
then you could ask the question, does directly intervening on this organelle retard the aging process?
And unfortunately, as of right now, we don't have that type of a magic bullet,
but exercise is one of the best ways of turning over bad mitochondria
and inducing the biogenesis of good mitochondria.
But the challenge, of course, is exercise does lots of things.
A lot of things, yeah.
Now, that said, we always,
this is one of the differences between,
I think, being a scientist and a doctor.
When you're wearing your doctor hat,
you just have to know what to do for that patient
in that moment, and it's a luxury to know how and why it works.
Right? So when we think about the importance of exercise, I've always
found that ironic that I probably classify or qualify as an exercise addict,
like in the true unhealthy sense of the word, you know, I probably meet all the
criteria of addiction and all of that stuff. But, you know, I probably meet all the criteria of addiction
and all of that stuff.
But up until recently, I don't think I really
appreciated the value of exercise.
I think it was honestly just something I did
out of my neurotic pathology,
but I actually, I think if asked would have said
that nutrition played a much greater role in health, nutrition played a much greater role in health, sleep
played a much greater role in health, and that exercise, you know, I mean, it's great,
but you know, if you, I'd rather you eat well than exercise a lot, or something to that
effect, I'm certainly revisiting that.
And of course, I also find it silly to do these so-or-0 some games like it has to be one
or the other, presumably doing all of these things well as the optimal strategy.
But the deeper I look at, exercise.
And I'd love to know your framework for this because I'm still trying to create one.
I'm putting exercise very loosely into three buckets.
Strength training.
Very specific aerobic training.
So this would be maximum mitochondrial output with minimal
generation of lactate and then anaerobic training where you are basically demanding ATP at such
a rate that you are really running through that lactate production pathway. Do you think that's
a reasonable framework of buckets of exercise? Do you divide them even more granularly as you think
about it mechanistically? We're really not exercise physiologists. I don't think I can comment and
personally do you think of it in a way like that?
I think that's very reasonable. You know just in hearing you talk. I mean again, we're not aging researchers, but
It's all ask you a question if that's okay. Has anyone actually you know people have given metformin demise?
They've given rapimise and demise, but has anyone given mice those three flavors of exercise to determine what the
impact is on longevity?
Yeah, I believe those experiments have been done and I believe all of them show benefit.
I'd have to go back and look at the literature in mice.
In fact, I'm in the process of just starting to work on that chapter
in a book that I'm writing.
The problem is I generally bias against heavy mice literature,
but you at least have the advantage of control.
So the short answer is definitely each of those as a medication.
Right, if you think of each of those as a pill,
each of those produce a medication, right? If you think of each of those as a pill, each of those produce a longevity phenotype, where it gets challenging, I think, in humans is,
well, I think there are so many ways to die when you get old that, for example, accidental
death would rank in the top five causes of death for people over the age of 60. Now the type of accident
can change around, but by the time you're in your eighth or ninth decade, falling becomes
such a significant cause of death due to the frailty of the individual that some of that
exercise, for example, strength training almost assuredly offers protection
from that type of death.
So the question is, I think it's a little hard to tease out how much of that benefit is
in the cardiometabolic side versus otherwise.
The other thing that's really challenging and studying humans is we don't have really
good prospective studies in anything that resembles a longevity phenotype.
So you are now stuck using something
I think I recently described
as the most cereval trash ever shot into civilization,
which is epidemiologic questionnaires
to try to impute based on you telling me
how you've exercised over the past 10 years,
how that's going to predict your longevity phenotype.
And again, the problem there is the dose matters, the specificity, the quantity, the quality,
these things matter, and they're very difficult to tease out from these retrospective views.
So I think the evidence is very compelling that exercise matters.
And that's maybe less the question I'm interested in.
I think what I'd love to gain insights into, and we may have to rely on non-human models,
is just as we now can tailor a drug to do something very specific,
can we tailor our exercise to be as optimal as possible?
So if you took an individual who said, Peter, look, I'm willing to exercise five hours
a week or I'm willing to exercise 10 hours a week, but I'm not going to be a professional
athlete.
How do I take those five hours a week or 10 hours a week or whatever it is and make the
best use of it to impact
all causes of mortality, meaning reduction of the risk of atherosclerotic disease, cancer,
neoplasm, neurodegenerative disease, and accidental death from strengthening the exoskeleton.
So that's clinically the question I'm most interested in as it pertains to exercise,
but I'm convinced that at the center of that question is understanding the role of exercise in mitochondrial health. I think this is a very important piece of the puzzle.
And certainly much more important than I appreciated even two years ago. I think what you describe about these age-appropriate or age-acknowledged declines in VO2 max, mitochondrial
density, mitochondrial efficiency, Venus-O2 concentration, I think there's something really
important there.
And even if exercise is affecting something upstream that is affecting that, at least we
have a great proxy through which to measure.
I think there's going to end up being a lot of really interesting nonlinear dynamics of mitochondria as a function of age, as a function of exercise.
There's a few vignettes I'll share as you probably know. If you don't use your skeletal muscle, you lose lean muscle mass, you lose your mitochondria very quickly.
How quickly?
You have measurable defects in the VO2 max after 10 days of hospitalized bed rest, and to
recover the VO2 max that you lose in 10 days, it takes about six weeks or so.
Oh my gosh.
Yeah, I knew it was bad.
I didn't know it was that bad.
So there's quite a bit of hysteresis over here, quite a bit of hysteresis.
So it's going to be complex and non-linear.
The programs that turn on mitochondria during exercise,
they're really elaborate.
And the idea that you're replacing it in a pill,
it may end up being kind of naive.
I think that exercise does so many things.
Simultaneously, it's like 17 different inputs
into the system.
And it may be the case that it's only
if those 17 inputs are provided with the right dynamics and the right off-rates that you get properly functioning more mitochondria.
In certain disease states, some of the muscle disorders that I study, the ragged red fiber that you may remember from your board exams, the ragged red fiber represents an accumulation
of poorly functioning mitochondria.
So I think that if you try to bottle up
just two of these factors or three of these factors,
we may be able to produce more malfunctioning mitochondria,
but it could be the case that we've evolved
to require 17 inputs provided at the right time and place
in order to get proper mitobyogenesis.
It's a really, really smart program.
This PTC went out of a program because it simultaneously turns on mitochondrial biogenesis,
while also turning on some of the autophagy programs.
And so you're actually turning over your bad mitochondria while you're turning on your
good mitochondria simultaneously.
And that's what happens with exercise.
Well, let's, you read my mind, and I don't know if you could read my little notes.
I'm taking over here because as we're talking, I'm making little notes.
The things I want to ask you, and that's exactly where I want it to go, which was, let's talk
about what a topogy means in the context of mitochondria.
So people who listen to this podcast know that I'm a big fan of fasting, periodic fasting, because even though
we don't have great ways to measure autophagy clinically, I think we have pretty good evidence
that periods of really strict fasting, meaning exclusively consuming water, for some period
of time.
My hypothesis is three to seven days, produces meaningful autophagy.
But how does exercise impact that based on what you've seen in the mitochondria?
So I don't know too much about fasting, but when you do have proper exercise regimes,
what we observe is that there are transcriptional programs with multiple inputs,
some of which we discussed earlier, but those are probably not sufficient.
That will basically turn on all 1,000 of those proteins to produce
more mitochondria.
But that same program is also saying, hey, let's turn over some of the previously produced
mitochondria.
So it's a very, very smart system.
It's not going to just produce more good mitochondria in the presence of bad mitos.
It'll actually cleanse the system as well.
And remind me what you said.
Now you already answered this, I apologize.
When you look at cells that are not turning over quickly,
so myocytes, neurons, what did you say was the approximate turnover
of mitochondria?
Probably a few days.
A few days, unbelievable.
So it's just, this is an unbelievable amount of work
to create the new and systematically and selectively discard and recycle the old.
That's right. That's right. And the signals given that you like exercise, I'll tell you one study
that I thought was really provocative and maybe you already know it, but it came from, I think
Michael Ristow and Ron Khan about 10 to 12 years ago in PNAS. Do you know this study?
I don't. I don't think I do, but keep going.
It's a human study.
Okay.
They, two by two matrix, they randomized humans
either to exercise or no exercise and antioxidants.
Or no antioxidants.
Oh yes, okay, I know this study, but please keep going.
No, this is great.
So which of the four quadrants do you think is best?
I know the answer, so I want you to, yeah, you keep going.
Yeah, so most people would probably guess.
Most people would say exercise with antioxidants must be the optimal health.
Absolutely. And what the study showed, that was a little bit counterintuitive, is that
antioxidants on top of exercise almost prevents or erases some of the beneficial effects of exercise.
And the authors concluded that things like reactive oxious and species are probably
playing an important signaling role as well that helps in the adaptation.
You need some of those sparks in order to turn on new programs that are net beneficial.
So if you erase those
sparks, you actually prevent the full benefit of exercise. So just another reason why the entire
system is so complicated. I mean, I think investigating exercise, and again, we don't do that. That's not
a core scientific focus of our laboratory, but so many diseases, ultimately, their risk is reduced
by exercise. So studying it as it
should be a very important objective for all of us. It's so interesting because
that is a great example. I'm glad you brought that up. And Nav and I, though we
didn't talk about that study, we talked a lot about this issue of blocking
Ross and how if one has cancer, for example, the evidence is becoming pretty
clear that the last thing
you want to do in a cancer patient is give them an antioxidant as sort of anti-dogmatic
as that would seem, because the Ross actually play an important role in selectively targeting
a cancer cell versus a non-cancer cell.
Listening to these discussions makes you almost wonder how in the world does any drug
show up with a benefit
in longevity?
It's almost a miracle that rapamycin can so ubiquitously across so many species extend
life.
When as you point out, most of the things that do the heavy lifting in longevity have 17 prongs that can't be replicated by a single molecule. I mean, it just,
it seems impossible. The one that has me very interested right now, and I can, I don't
know how much you've studied this. My guess is, even if you haven't just your peripheral
knowledge, we'll exceed that of anybody's, is metformin. So again, I think most people
listening to this podcast know a lot about it,
I had an interview with near bars, I'm also having lunch with today, and near certainly one of
the world's experts on this topic. So we had a great discussion of all of the benefits of metformin.
Don't think it's really disputable how big those benefits are in people who have diabetes. I think
that is becoming very clear. And then by extension
in people who are insulin resistant, what I think is not entirely clear and I think is
the purpose of what Near is hoping to study with tame is if you took a non-diabetic, non-insulin
resistant individual and gave them metformin, will you enhance their longevity phenotype?
And the one area that I'm most interested in this question is what is the impact of metformin
on the ability of exercise to improve the phenotype?
And that's something that just on a personal level I've been experimenting with a lot.
So doing a lot of lactate testing on myself with and without metformin and using lactate as a proxy
for mitochondrial function.
So we were talking about this a little bit before,
but just for the listeners of what I do is
take a resting lactate level.
I shouldn't be using any more ATP
than I'm using at this moment.
What is my level of lactate?
Then on a bicycle that allows me to control the wattage
to the nearest watt, basically move
in five or ten watt increments slowly, you know, spend ten minutes at this wattage.
Go up by five for ten minutes, go up by five for ten minutes, and keep measuring lactate
levels.
And you generate a performance curve, an LPC, lactate performance curve, and you do this
with and without metformin,
you see a difference.
The question is, does that difference matter clinically,
and is it possible that metformin is actually not helping
in the context of exercise?
Are you seeing that in the presence of metformin,
if you are exercising, you're producing less lactate
or more?
I'm seeing more lactate in the presence of metformin.
Now, again, this is an end of one study on myself,
but it makes sense that you could,
I mean, that's a plausible.
How are you measuring your lactate using blood in the finger?
Yeah.
We should do metabolomics on you.
I mean, with our new instrumentation,
we can measure not just lactate,
but literally,
measure everything into the template.
It gives a little bit more of a comprehensive snapshot of all of your
metabolites.
So could we get an IRB to do that easily?
Let's do it.
Let's do it.
I'm all in.
So we could do it.
We could do an on metformin, off metformin snapshot because so here's my
crude thinking on this is if metformin is inhibiting complex one,
it wouldn't be beyond the realm of possibility that the body might preferentially not shuttle pyruvate into the mitochondria. I mean, it's still doing so to a great extent. But if it's
disproportionately now keeping pyruvate outside and turning it into lactate, that could drive up
lactate levels. The thing that surprised me into lactate that could drive up lactate levels.
The thing that surprised me the most is how high my resting lactate levels seem to be.
I mean, I remember before I started taking metformin, you would barely check a resting
lactate level, but it was usually below one millimolar.
Now my resting lactate level on metformin is typically between one and two millimolar.
It's about two X.
And I'm doing this in as painful and, but hopefully valid away as one can do it, which I'm using
two separate meters, checked in duplicate on the third drop of blood.
Like I'm trying to be as systematic as possible.
Anyone listening to this who wants to do this, I just want to warn you in advance before
you get started.
Lactate meters are upsetingly expensive and the strips are the racket.
I mean, they'll sell you the device for $300 and each strip costs you about $5.
So, every time I do one of these dumb tests, which I typically do about once a week, it's
like dinner in a movie for five people.
But you have to be amazing to see what a broader sequence of
metabolomics looks like to understand is there something that's happening? And by the way,
then the next question is, do that in somebody who has diabetes and see if you see an improvement
or a reduction in performance. You measured your fasting, resting lactate before you started
metformin. Do you know if it went up after you started metformin
and then it went back down again or?
Well, so that's an interesting question.
So before I started taking metformin,
I would do lactate testing, but I was interested
in a different question.
So it's not an apples to apples comparison.
We always had a resting lactate just because you wanted
to basically calibrate the machine
and make sure your machine was working.
But generally when we did what was called this LPC, the lactate performance curve, it was
mostly geared towards identifying a different position on the curve, which is very crudely
done, but you do a series of efforts at different power outputs or in a swimming pool at different
speeds or on a track, different running velocities.
And you'll notice that the curve is non-linear.
So it starts like this, I'm sort of drawing, it goes flat, and then it starts to shoot
up very quickly towards a verticalism.
That can be approximated by two linear curves, and the intersection of that curve is generally
a person's lactate threshold.
And that's different, that's usually a higher number than two millimolar.
Let's just say to make the math easy, that usually is in about the four millimolar range.
And it's that point where that corresponds to on the x-axis, that output is generally
about the fastest velocity or output a person can hold for a certain type of race that
we're interested in studying.
So I have infinite numbers of those data for myself back in the days long before I took them at
Foreman, but it was undeniable how low my lactate levels started. So I at least have that data point.
I think that's really interesting. We published a paper in PNAS a couple of years ago where we placed either
healthy individuals or patients with mitochondrial disease on a treadmill
Did a 10 minute exercise test and then drew their blood at rest peak exercise and post recovery
Just to look at the metabolism response to exercise
So of course we get lactate and the mitochondria patients, some of whom have complex one deficiency,
not because of a metformin because of a genetic deficiency. They begin with a high
resting lactate and there's a parallel rise in their lactate that parallels what happens to a
healthy human and it stays high parallel with the healthy individual post recovery.
Do you remember offhand how high their resting lactates were relative to the non-insulted?
It was single digit
Millimolar it wasn't sky high. I want to say something like two three four millimolar
But we should look that up just to confirm
But it'd be interesting to see this is purely science now talking to you is whether we could repeat that exact same study
Not with genetic complex wind deficiency, but with...
But induced...
Right, exactly.
You know, a lot of people ask me about metformin and aging, and again, we don't do real
aging research in our lab.
We hope to be able to impact that through some of our work.
And I'm hoping that my questions are like prompting you to celebrate your...
Yeah, you've got all these amazing tools to study it, right? Absolutely. It really is a space that really captures anyone's imagination. But if you ask
me how I think metformin is working, I think it's probably related to the body's homostatic
response to complex one inhibition. So, of course, metformin hits complex one. I think that's undeniable. It may
have other targets, but without a doubt, it hits complex one. When complex one has been blocked,
the body senses it, and there's a feedback loop. There's a homeostatic response, and that's
probably what if net protective or helpful, and it may be the case that
throwing a wrench in a complex one, it turns on 15 of those 17 inputs that you need to
sort of rejuvenate, not just your mitochondria, but other parts of your cell as well.
I think there's some really interesting experiments and worms, as you probably know, there's quite
a bit of worm longevity work, and there's early studies by
my MGH colleague Gary Ravkin, as well as Cynthia Kenyon, who was at UCSF and is an hour calico. They did RNA-I screens to basically look for genes which when disrupted would lead to
a longevity phenotype, and one of the genes sets that was most associated with a lungevadyfinotype was the mitochondrial
electron transport chain.
At the same time, one of the gene sets that was associated with a drastically reduced
lifespan was the mitochondrial electron transport chain.
You can ask the question, there's a different subset of genes, obviously.
There's about 90 genes total required for electron
transfer chain and oxidative phosphorylation.
So the question is, why do loss of some of them
lead to longevity and why do loss of others
lead to a shortened lifespan?
One hypothesis is that it's just the strength of the allele.
If you, some of those RNAIs really wiped out
the electron transfer chain, probably led to early death of the worm.
But if you just gently block the electron transfer chain
with the right RNAI alleles, perhaps mimicking what
metformin does, you do get a longevity phenotype.
So, A hypothesis in the field, I'm not alone, but I think
there's others in the field that think that maybe one of
the ways that metformin works is, sure, it does block the electron transfer chain,
but then it comes back and causes an entire adaptive or a homeostatic response that is not
adaptive at the whole organism level. I'm not going to put you on the spot and ask you if you
think people should take metformin. I think the broader question is, do you think based on what you've seen in
the ETC models that it's quite possible that a drug like metformin can be beneficial to
some and harmful to others?
Oh, I think without a doubt, I mean, we know that metformin is useful for type 2 diabetes. So I think it's a fact
that for a subset of the population, metformin is helpful and beneficial. You know, in a rare subset
of cases, you can actually have fatal lactic acidosis from drugs related to metformin, things
like fenformin, which is more potent. That's exactly right. That gets back to this idea of
the potency or the
elilic strength of inhibition of the electron transport chain. But if you took that acute toxicity
aside, I mean, I think this is really the question I've now become fixated on. If you take somebody who
is already maximizing the benefits of exercise, nutrition, sleep, these things that I think the more we look at them,
the more powerful they are. It's one thing to say the addition of metformin offers minimal
benefit or incremental benefit. It would be another thing if you're more in the Ross category
that you alluded to earlier. Is this actually undoing some of the benefit?
That's why I actually think that the experiment that you and I just discussed a few minutes
ago, trying to see what the cross-product of exercise in that form and look like, I think
it could be totally fascinating.
Is it going to look like the Ron Con study from a decade ago where there is at least one
experiment out there that suggests that.
But again, I don't know how deep they looked at this.
This is a very
interesting idea. I'm the only drawback of this idea means I have to keep coming back to Boston.
But now we're entering the right time of year to do it. So that's fine. So changing years
around the role of hypoxia is a therapeutic. I mean, based on what you see in the mitochondria,
how do you see that as a potential therapeutic option? This is something that we're really excited about on the preclinical level, and I really
want to emphasize this Peter because oxygen follows the Goldilocks principle, right?
I mean, too little is absolutely fatal, deadly.
What we're discovering is that too much, in certain instances, genetic backgrounds can
be damaging as well. And so all of our work to date has been focused in preclinical models.
One of the things that we are discovering in these rare mitochondrial disorders is that
a lot of the ATP levels are actually nicely defended by glycolysis.
And so although the textbook dogma is that a lot of these disorders or disorders of energy
deficiency, under resting conditions ATP levels are okay, but what we're observing is high
unused oxygen.
And the important question is, how can we now try to interdict and somehow try to reduce
the delivery of oxygen?
So, at least in our mouse models, we're using hypoxia chambers. We actually dilute the air
that the mice breathe with nitrogen. We use some of the devices that the sports industry has created
nitrogen generators, face masks, tents. We place the mice in those apparatus, dilute the air with
nitrogen. And then we evaluate the impact. And at least in some, not all some of our mouse models of myodizzees, the benefits are
striking.
Let's explain again just why this is so profound, right?
So going back to the model you described earlier, in a subset of clinical scenarios where
mitochondrial function for lack of a better word is impaired, you're seeing a much higher level of oxygen return to
the lungs, despite a high output of energy, imputing that their mitochondria simply aren't
working.
That high amount of oxygen itself can be problematic, so you're saying, well, rather than putting
you in an environment where the ambient oxygen concentration is 21% we're
going to lower that. How much do you lower that to by the way in these tents with the mice?
At sea level we're typically breathing about 21% oxygen. We reduce it down to about 11%.
How is that? I don't know much about my altitudes but that strikes me as really low. Is that
like the top of Mount Everest low? It's not Everest. It's probably base camp.
So it's 18,000 feet.
Everest is what, 7%, maybe?
Exactly, exactly.
So we're talking about certain parts of Bolivia.
We're talking about Montblanc.
Yeah, yeah.
But my brother's been to base camp
and he did something really funny,
which is something only my brother would do.
He typed out a series of questions for himself
that at sea level, the answers to which are
patent-ly obvious, 10 questions, and at 10,000 feet and 15,000 feet, and then at base camp is 18,
and then I think when he was there, they ended up not being able to cross the ice walls,
but they could still get to like 21,000, and then again at 21,000 feet, he would video himself
answering these questions. And it was actually quite interesting, not just the
huffing and puffing that invariably goes into it, but the length of time it took him to think
of the answers, which when you consider the fact that he was answering the same questions
and over and over again, it should have been the opposite. It should have been easier and easier
and easier to come up with what year did such and such happen or whatever. That's no joke, right?
I mean, that's still for many people quite a deficit. So how did they improve? Earlier in the conversation, we're talking about this disease called
leesendrum. So we have a mouse model of leesendrum. It's actually due to a loss of one of the subunits
of complex one. So it's a recessive loss of one of the nuclear subunits of a complex
one. And this mouse is born looking okay, it's
developmentally okay. But then right around day 30, 35, it starts looking sick. And by
D55, it'll basically fulfill our hospitals. Euthanasia criteria, it's lost body weight,
it's become hypothermic, it's very, very sick. It has lesions on brain MRI.
Is there anything in its periphery that looks lesioned or is all of the insult to the brain?
This initial cause of death is probably brain-driven, and if you look carefully, other tissues are affected as well.
So that's what happens at 21% oxygen.
There's a very stereotyped trajectory.
These uniformly fatal at about day 55 or day 60. If these mice are grown at 11% instead of 21%,
they now survive to about a median of one year.
Oh my God. So you've restored them to half their normal lifespan.
That's right.
And what's their function level?
How do they interact?
Or do they act like normal mice up until then?
When we were doing these experiments,
a very talented former graduate student, she's now
at UCSF and our lab manager over at MGH, they're doing these experiments.
They actually thought that there was a genotyping error because the mice looked so good.
We actually thought that we'd misgenotyped them.
And so they looked great.
They put on body weight, they put on body temperature.
So the results are striking.
But again, I want to emphasize that this is all an
animal model still. If you're a parent who one day has a child born with this condition,
to think that the answer could be your child instead of living a few months, could live into
their 40s or 50s by moving to a part of the world, which would be the easiest way to accomplish this.
I don't think it would make sense to live at sea level and wear an oxygen deprivation mask
for your entire life.
But if the answer is, guess what?
You're going to go be a Sherpa.
I mean, that's unbelievable to think of.
I mean, I would not have predicted that at all based on what we've discussed, that it
could be that strong, in effect.
Well, what's interesting is, in the the past people that she proposed hyperbaric
Oxygen as a way of rejuvenating that one's mitochondria. That's what I would have stupidly suggested also, which is wait a minute, we got to try harder to get that oxygen in there. Let's go hyperbic.
So have you done that in the mice and the mice die even faster under hyperbaric conditions?
So we didn't try hyperbaric because that's higher pressure, but we just tried hyperoxygen.
Okay, okay. So we went up to 55%, which is what is often given in the operating room as an example,
the mice will die within a few days of exposure to 55% oxygen.
So there's something about having...
And what about hyperbaric at 21%?
We haven't tried that yet, but just hyperoxic at 55%.
These mice will die within a few days of exposure.
Peter, within a few days of us publishing that paper, we actually got phone calls from across
a country of cases where patients that were on the outpatient had been placed in hyperbaric
chambers, and then they actually ended up, you know, in some cases, dying within 24 hours
or going blind in a good eye within
24 hours.
And so I think there's some anecdotes that suggest that super high oxygen levels on a broken
electron transport chain can be very damaging in humans as well.
Well, this is sort of interesting, right?
Because on the cancer front, people have talked about hyperbaric oxygen being a very potent
tool because the mitochondria of
cancer cells are going to be defective on balance relative to the non-cancer cells.
That's, again, outside of your wheelhouse, but how do you think about hyperbarics in terms
of a tool to selectively target cancer mitochondria?
We're super excited about it, and in fact, we're really not a cancer biology lab, but
there is a subset, a very, very rare subset of tumors where we're currently exploring that idea.
I think others have thought about trying to starve cancers of their oxygen and glucose.
Our idea is the exact opposite. Maybe in certain instances you want to flood them with oxygen.
Do you have a sense of which cancers in humans might be more or less susceptible to that pressure?
We're looking into that now, but it's going to be a rare subset of cancers where there may be some mitochondrial mutations to begin with.
So in other words, it might be less about the given histology and more.
So, you know, it's funny. It's Hector Keath Lerady recently and this is a great example of targeted therapy in cancer, right?
Imagine you have your tumor, you get it sequenced and you realize, oh, look, you, you have a tumor whose mitochondria are especially weak, you are a great candidate for hyperbaric oxygen.
Person B over here, the mitochondria in your cancer cell look perfectly fine. Hyperbaric oxygen, if anything is not going to do, at best it's going to do nothing at worst, it might actually harm your other cells. We've looked a little bit into this literature. We have an oncologist in our laboratory that's looking in this direction.
And hyperbaric oxygen has definitely been proposed as a cancer therapy in the past, but
there have been mixed signals, and exactly as you're seeing it, maybe the case that if
you know how to precisely target it, maybe you'll see a real signal.
Anything else in your work, have you thinking about cancer?
This is a great example.
Is there anything else that you think about with respect to what you've learned and how
it pertains to cancer prevention or treatment?
We had a series of projects about five, six years ago or so where some of the guys in
the laboratory were looking at sort of omic data sets from large numbers of cancers
just asking, what are the most consistently altered metabolic
pathways in cancer? So there's about 1,500 metabolic enzymes encoded by the human genome,
which one is the most up-regulated or down-regulated across all cancers? And that pan-cancer analysis,
it wasn't a mitochondria-focused analysis to be clear, but it revealed a few mitochondrial enzymes in the folate pathway
that are the most consistently up-regulated enzymes across all cancers. So the mitochondria is the
powerhouse of the cell. It does produce ATP, but it's also a bicemthetic machine as well. So there's
a few pathways within the organelle that are designed to produce one carbon units
for growth, folates, things like that.
That pathway was highly, highly upregulated.
It gave rise to the seductive idea that maybe mitochondria are not being used for energy
in cancer, but rather espyceynthetic machines for cancer.
So, that was an idea that, you know that we and others stumbled upon about five,
six years ago or so, but it's not an active area of research in our lab.
Well, it's interesting because it's very consistent with other hypotheses that the
Warberg effect is less a deficit of the cancer cell due to defective mitochondria or
inability to undergo oxphosphine, and maybe the warberg effect
is the result of a cancer cell wanting to get a higher throughput of substrate to foster
growth.
Obviously, Matt Vanderhiden was the author on a paper that talked about that several years
ago about 2009.
It hadn't heard the folate story, so that's kind of yet another really interesting point,
single carbon biology is pretty interesting stuff.
That's right.
That's right.
And several investigators like Josh Rebinovets, David Sabatini, are groups.
I had dinner with David last night.
Great.
We were actually talking about single carbon metabolism and the challenges of it.
I went to med school with Josh, by the way.
Oh, wow.
Oh, wow.
Okay.
So actually, the three of us about five, six years ago or so,
we all had sort of independently stumbled upon this mitochondrial pathway as being dramatically
upregulated, Josh with metabolomics, David with RNAi, us with computation. And I think to this
date, there's a lot of data that supports the idea that this is upregulated in cancers. Now,
whether targeting it is going to be beneficial,
that's an open question still. But without a doubt, this is one of the pathways that is
powerfully upregulated in cancer states. On the topic of cancer, and we've talked about
these other chronic diseases, but it doesn't really appear that there is a chronic disease
in which the mitochondria remain normal. If you look at cancer, if you look at Alzheimer's disease, if you look at atherosclerosis,
and if you look at types of diabetes,
all of these diseases have mitochondrial signatures
that differ from what we would consider healthy.
Well, it gets back to the opening parts of the discussion
where we said that if you take any age at tissue,
it's gonna be associated with dysfunctional mitochondria.
And if you take diabetic muscle,
if you take Alzheimer's brain, Parkinson's brain, you're gonna see dysfunctional mitochondria. And if you take diabetic muscle, if you take Alzheimer's brain, Parkinson's brain,
you're gonna see dysfunctional mitochondria.
And this is why it gets back to,
is it cause or effect,
or is it gonna be some complex,
nonlinear combination of cause and effect?
And this is where using that system's biology approach
or trying to gain insights from these rare diseases
may inform a subset,
but not all of these.
As you think that for Parkinson's,
the causal hypothesis is pretty compelling
out of all of these disorders.
Say more about that because I don't know anything
about Parkinson's that I didn't learn in medical school,
which if I recall is more to do with dopamine secretion
out of a part of the brain that the substantial niagra is that it, where you basically lose
that tropics.
Those tropics.
Yeah, and so the patients that maybe start out with genetically fewer of those, because
there's a distribution of how many you get, maybe the one's most susceptible.
I'd never thought of that as a problem that shows up in the mitochondria, so expand on
that.
Again, we have two classes of disorders, right?
We have sort of common complex diseases and we have monogenic diseases.
And the big question is, does the pathology we see in the rare monogenic forms bear any
relevance, right, to the common forms of disease?
It's funny.
I mean, the way we're talking about it, your hands are showing it in a way
that I think is representative, right?
You had your one hand out over here
and you said, like, these are the very simple,
monogenic diseases.
Most people have never heard of them.
They're typically quite brutal,
but they kill relatively few people.
On the other hand, you have, there's a divide, right?
That's right.
And it's quite discontinuous, isn't it?
Well, also on this side,
the prevalence of these monogenic mitochondrial disorders
is about 1 in 4,000,
but then as you cross the continuum,
the prevalence is one.
Yeah, exactly.
And then you have these other disorders
like type 2 diabetes and Parkinson's and Alzheimer's
that it's not one in one,
but it's also not one in 4,000.
So you're saying Parkinson's may be the closest example that you can think of that's spanning
this these two worlds?
I think so.
I think so.
I want to hear more about this.
Well, I think there's a couple of reasons.
One is if you take the common form of Parkinson's disease, and if you take some of the postmortem
material, if you buy up, see that, or if you take postmortem material, and you look, you
let you see mitochondrial lesions, you'll see an increase in the mutation burden in the mitochondrial genome, you'll
see complex one deficiency.
Already we're seeing some of the molecular features of mitochondrial dysfunction, but
perhaps even more compelling is that there are some toxin forms of Parkinson's, certain
types of herbicides and insecticides are actually
toxic to complex one.
So you're saying there are people who have Parkinson's and I apologize for my ignorance
on this, where they don't actually have a dopamine deficiency in the brain, but they
have a Parkinson's-like phenotype purely from an insult to their mitochondria from say
a toxin.
Right.
So in these instances, what we think has happened is that because of
a environmental pesticide or insecticide, the mitochondria has been
poisoned in some of these dopamine, ergic neurons, and those neurons actually
die. So there is a dopamine loss.
I see. I see. Okay.
But the root cause is the toxin.
The mitochondria. Okay.
That's right. So that's toxin evidence where we know that a direct toxin. The mitocondria. That's right. That's right. So, that's toxin evidence where we know that a direct toxin to the mitocondrian inhumans
can give rise to a Parkinsonian like disease in mouse models.
If you give a high dose of rotinone, it's a complex one poison.
Okay.
And this actually gets back to the metformin.
Exactly.
So, if you infuse into a mouse,
wrote known which is a very potent.
More potent than fenforma.
Yes.
And there's some potential off target effects as well.
Like micromolar or millimolar potents.
Micromolar potents.
Wow.
It may hit other things like microtubules as well,
but it definitely hits complex one of electron
transpiraching.
That's been used as a model of Parkinson's disease
in rats and in mice. And so I think between the toxin evidence, the fact that sporadic forms of
Parkinson's disease can be associated with complex wind deficiency or mitochondrial mutations,
I think helps to support the idea that mitochondrial dysfunction
can play maybe in the causal path for Parkinson's disease.
Are you optimistic that we are going to be able to target mitochondrial proteins as therapies?
I mean, the more I listen to this, the less optimistic I am truthfully, just because of the exceptions, being exceptions
and not rules.
I'm actually pretty wildly optimistic.
Okay, this great, because I'm coming away like discouraged,
like there are too many moving pieces
to be able to use a single molecule.
So are you thinking of stacking molecules
or tell me where your optimism comes from?
Well, it comes from the fact that five years ago in some of these mouse models or cellular models,
we had zero ways of alleviating mitochondrial disease in a dish or in a mouse. Now we have in our
laboratory, we can use, again, in a preclinical way, we can use hypoxia and it actually helps
to restore cellular function
and longevity and health span in mouse models of myodizzees.
We're using other approaches that are evolutionarily inspired.
We call these protein prostheses where we take proteins from other organisms, from other
kingdoms of life.
We transplant them into human cells with mitochondrial disease, and we can effectively rescue the cells.
And so, how do you, how do you
transfect all the cells? Are you just saying that you're just doing this ex vivo?
This is all ex vivo right now, right?
But still, that's a proof of concept. That's very powerful.
I mean, nowadays we have nucleic acid therapeutics, gene therapeutics, protein therapeutics.
So, so giving an example of one of the protein prosthetics.
Getting back to the earlier part of the conversation, we spoke about the fact that the electron
transport chain was probably one of the earliest features of the early eukaryotes, probably
resembling the electron transport chain of bacteria that can do oxidative phosphorylation,
but then during reductive evolution, certain organisms lost parts of their
electron transport chain. Now, there are certain organisms that have lost their entire electron
transport chain, and we think that one of the ways that they're able to survive is that they
gained a new protein that basically complements part of the activity of the electron transport
chain. So we've identified some of those proteins.
If we place those proteins in a human cell,
you can poison the mitochondria
any of five different ways,
and the cell will still proliferate
because it has that protein that evolutionarily,
we believe, allowed that organism to lose its ETC
to begin with.
Does that make sense?
Yeah, it just seems too good to be true. Well, this is why we call it a prosthesis.
It's not 100% fix of the solution.
What it does is it probably corrects part of the redox imbalance in the electron
transfer chain, but not the full proton pumping capabilities.
Yeah, so play this forward.
You now could argue another treatment for type 2 diabetes is in addition to making the
changes we're going to make, right? Because I still believe deep down that you can cure
type 2 diabetes with corrective exercise and nutrition and sleep. I think if you get
those three things fully optimized, type 2 diabetes goes away with the exception of the late
stage cases where the pancreas no longer works.
But what if you could add another layer to that, which is oh by the way here's some mitochondrial prostheses?
That's exactly right. It's not going to fix all of the functions electron-transition.
But it can become additive to other things. That's right. That's right.
That's one of the ideas that we're exploring right now. Can we actually, in the context of things like fatty liver and diabetes, can we use some of these mitochondrial protein prostheses to either augment or bypass some
of the broken functions of mitochondria to restore function?
I don't know if you've ever thought of this because the idea just popped into my head
when you said mitochondrial protein prostheses.
Have you ever thought just in sort of random sci-fi,
like thinking of the opposite,
which is performance enhancing prostheses
from mitochondria?
I mean, if you think about the efforts
that athletes can go to enhance aerobic performance,
the most obvious of these, of course,
is blood-doping and use of EPO,
which simply deliver more oxygen to the system.
But in 30 years, will people be talking about genetic cheating, where mitochondrial performance
and function has been enhanced?
Well, it's funny because the sports industry is so often, I mean, the sort of underground
illicit sports world of doping, often is so ahead of the medical world.
It's actually pretty amazing.
Yeah, it really is. I mean, one of the compounds, it's like medical world, it's actually pretty amazing. Yeah, it really is.
I mean, one of the compounds, it's like Epo, it's called FG4592, it's a small molecule
that blocks one of the prolyl hydroxylases.
This tricks the system into thinking that it's hypoxic and you end up producing more
Epo.
That drug was in clinical trials and before the drug was even approved, it was being used by cyclists, which is already
amazing. But what's also even more amazing is that the anti-doping agency knew to look
for drugs that were not yet even approved by the FDA in some of these athletes. And so
it's like the set red queen where everyone has to stay ahead of everybody else.
Yeah, it's an arms race.
Do you think like theoretically there are ways to enhance performance through, again, I'm not a huge advocate on genetic engineering. I still think it's so there's so much sci-fi and
the limitations of actually getting a virus that could be taken up ubiquitously. But putting that
aside for a moment, could you engineer a better mitochondria?
Could one, I mean, I don't want to put you on the spot,
but could one engineer an even better mitochondria?
How much waste is in the system?
I, it's funny, I haven't,
if I ever did this exercise, it's so long ago
that I don't recall, but from an engineering perspective,
how much room for improvement is there?
I think it's gonna take a while
before things like that are possible,
and I gather from this conversation that you while before things like that are possible. And I gather
from this conversation that you like me like automobiles. And so if you have an engine,
the way to enhance it is to turbocharged it. But turbocharged it is not taking one spark plug
out and replacing it with another spark plug. It's going to be changing the way air flows through
it in his recycle. So you have like 17 different things.
You have a turbocharger, you put it on top, but there's like 17 other things that you
have to alter so that the entire system connects up, you have impedance matching, you have
airflow matching, so that in the end you have a better performing automobile.
I think something analogous applies to mitochondria.
It's not going to be just one thing that you can turn on.
If you want to try to, the system is already pretty optimized, right?
And so if you just change one thing, it's probably not going to, you can break it.
Yeah, you can break it with one thing, but it's hard to enhance with one thing.
That's actually a great way to just think about biology in general.
It's pretty easy to break it at a single point, cyanide.
I think the most extreme example, right?
Detro detoxin.
So easy to kill and break at a single molecule,
which comes back to a point I made earlier.
It's mind-boggling when something like rapamycin works.
Right.
Again, I don't, I mean, mean you had dinner with David last night.
So he's clearly one of the world's authorities on rapamycin and its function.
But at least if we go to metformin, the only way that I can conceive that it could
have this total body impact is if it's doing something that then causes the entire
system to respond.
Even when we talk about statins,
every medical student in the country knows
that statins are life-saving.
Every single medical student in the country knows
that statins hit HMG COI reductase.
But why is that like saying?
Right.
Is there other things that it's doing
that are also important beyond the reduction of LDL?
The way that statins work, my understanding is that sure statins directly target HMG COA
reductase.
But then what ends up happening is because you're not producing so much sterols, you turn
on an entire SREBP transcriptional program.
Right, and you bring more receptors to the surface of the liver, that's right.
More of the statin efficacy is due to the LDL clearance than the reduction of cholesterol synthesis. That's exactly right. But there might even be
benefits beyond that, is my point. In some argue, there are actually a whole camp of LDL denialists
who can't deny the efficacy of the drug. And so the sort of hypothesis is, well, all of the statin
benefit doesn't come through the LDL reduction, through the mechanism you describe.
The unintended consequences of the wrong way of saying it, but the non-obvious consequence,
but it could be some of the anti-inflammatory benefits that come from it or the endothelial protective benefits.
But the point is that there's an entire response to hitting H&G Coa reductase.
And a consequence of that program is that you have more sterile productions.
So in the end, the amount of cholesterol that you're producing is kind of balanced. You've
inhibited it, but you've turned on more the ends. I'm so comparable. But you've turned
on these other 17 switches as well at the same time, one of which is the LDL receptor,
which helps to clear LDL levels. There may be other things as well
that are turned on that are net beneficial.
So I think physiological systems are so complicated,
trying to identify all 17 of those things
and turning them on at the same time.
In general, I think is gonna be hard,
even in the next 30 years.
But it may be the case that some of the interventions
are, you know, what people refer to.
Do you think of this as, like let's look at the interventions are, you know, what people refer to. Do you think of this as, like, let's look at the three examples you've just used,
a statin, metformin, and rapamycin.
None of those are pure, I mean, they're synthesized today, but they are all
derivatives of naturally occurring compounds. I'm sitting here as you're
telling this story, trying to think of examples of purely synthesized, denovomolecules that
have such benefit.
And there may be examples, but it seems less obvious.
Do you think it's a coincidence that some of the most potent agents that we have in medicine,
which by definition, it seems, are the ones that have to do multi-pronged inputs tend to
come from naturally occurring substances? Does that just speak to our co-pronged inputs tend to come from naturally occurring substances.
Does that just speak to our co-evolution with these things?
No, absolutely.
I think there's been this arms race, right?
The bacteria are fighting these fungi
and the fungi are fighting these plants.
And so there's all sorts of small molecules
that are designed to throw wrenches
into other mitochondria or translational programs
or nutrient sensing programs.
So natural products are remarkable chemistries and they've evolved over hundreds of millions of
years to target physiological systems. And so I'm a huge fan of natural products and the biology that
they expose. This is so interesting.
We'll close with the question that's admittedly kind of a tough question.
So I apologize for putting you on the spot and no qualms if you can't come up with a good
or great answer.
But when you think about the world you want to explore here, with the questions that you
want to ask, so much of what happens even at the level that you're at is still
constrained by resources. Have you ever had the thought experiment or the sort of fantasy of
what if you were in a totally resource unconstraint world. So you never had to apply for another grant.
In fact, you were given some lump sum of money that was beyond what you could imagine. And even just
from an IRB standpoint, there was nothing that stood in your way of doing kind of something that was still ethical, but maybe today would be logistically too challenging.
Do you have a sense of what questions you would want to probe, but specifically what experiment
or set of experiments you would do in this dream state? It's a tough question. It sounds like
you're basically asking me not to be limited by anything except my own imagination. And I think so often in biomedical research, that is what limits
us. But it's a great question, Peter. One experiment that would be kind of a fun experiment
to try is really motivated by your recent work on oxygen. So what we've observed is that at least in pre-clinical
models when you have severe mitochondrial decline, breathing thinner air appears to be beneficial.
Now how I'd in the common form of aging when there's a subtle decline in mitochondrial activity
when there's a subtle decline in mitochondrial activity,
is there excess unused oxygen? And will breathing thinner air be beneficial?
And given that I'm not resource limited,
I mean, wouldn't it be cool
if we could construct a Ritzkrelton hotel
or condominium at 16,000 feet.
That's extremely comfortable
and perhaps another Ritz Carlton
that looks identical at the plains.
And we could take a very large cohort,
not five, not 10, but thousands of people
that live at either the plains
or at the high altitude for many, many months. And we try to evaluate whether
there are any biomarkers of aging age associated disorders that actually improve under thin air.
Maybe they become worse under thin air, but it would be something like a crossover experiment that
would allow us to test the idea that thin air may be beneficial for chronic
diseases?
I love that idea.
That is elegant because one, you could do that.
You answer the question, right, which is in a resource, an unconstrained world, like that's
tens of millions of dollars.
What allow you to do that?
Call it hundreds of millions of dollars.
You could do that longitudinally.
And your intervention is elegant in that it is,
it's going to touch lots of things.
That's interesting.
So 16,000 feet.
So following up on that, have you done
or contemplated doing the less beautiful version
of that in mice, where, or, or, I'm sort of disdainful of mice,
but maybe rats or something that's less in bread,
where you have models of type 2 diabetes,
but they're genetically born with normal mitochondria.
Has that experiment been done?
We're doing those types of experiments now.
And of course, our focus is on some of these rare genetic mitochondrial diseases, but
we're going into some of these other conditions, more common conditions that are also associated
with mitochondrial dysfunction.
So those are currently ongoing. When we get back to that dream experiment, what is interesting
Peter is experiments like that have actually taken place in humans and they can be natural
experiments. And one of the experiments, there's just one paper from the early 1970s, that was published by the Indian Army.
It was the Indian Army reporting on the health outcomes of a huge number of their troops,
who India historically had border disputes with China.
I think it was in the 1960s.
India deployed more than 100,000 troops on the Indo-China border.
And don't quote me on the numbers, but about 25,000
of these people were at extremely high altitude, and another 100,000 or so were at the planes.
They were there for about five to seven years or so, and of course the food that they ate,
the temperature, the activity, all of these were different between low and high altitudes, but one of the
variables that was different was oxygen. And after I think it was seven years, the Indian army
actually wrote this paper, it's only been cited a few, like maybe 20 times or so. They reported the
long-term health consequences. And what they showed is that death from things like infections were much higher acutely
upon going to high altitude.
But if you look at chronic diseases like incidents of diabetes, stroke, cardiovascular
disease, they were much reduced in the high altitude arm.
Even after they returned to the planes?
I think the study...
Or only as long as they stayed at the altitude.
Only as long as they stayed in the altitude.
I don't think they had long-term follow-up actually,
but it's this type of data that actually makes me wonder
whether what we're observing in some of these
rare forms of mitochondria dysfunction
and the interaction of mitochondria with oxygen.
Perhaps some of it could bear relevance
to more common conditions as well.
Super interesting. Thank you. Keep going on, but I've been generous with your time, especially to a total stranger.
This is really helpful. I want to thank you for the work you're doing, and I want to thank you for taking the time to explain it to me and to a few people listening.
Thank you so much. This has been a lot of fun for me. You can find all of this information and more
at peteratiamd.com forward slash podcast.
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