The Peter Attia Drive - #33 - Rudy Leibel, M.D.: Finding the obesity gene and discovering leptin
Episode Date: December 17, 2018In this episode, Dr. Rudy Leibel, an expert in Clinical Molecular Genetics and Genomics at Columbia University, discusses his role in the remarkable scientific story of discovering leptin. He also get...s into the genetics of obesity, as well as a broader discussion of the causes and effects of obesity, energy expenditure, and metabolism. We discuss: Rudy’s background, interest in obesity, and trying to understand the role and impact of adipose tissue [4:15]; Finding the first evidence of leptin by studying obese mice [23:30]; Zucker rats, and the push/pull theories of obesity [34:45]; A breakthrough in obesity research, and closing in on leptin [45:45]; Understanding leptin in humans [1:03:30]; What Prader–Willi syndrome teaches us about body weight regulation [1:09:45]; Leptin and the broad condition of obesity, metabolic consequences of weight reduction, and Peter’s self-experiments [1:18:00]; How is appetite being regulated? [1:29:45]; Are there epigenetic consequences of being obese? [1:37:00]; What makes low-carb diets so effective at obesity reduction? [1:46:15]; What did Rudy believe 10 years ago that he no longer believes to be true? [1:55:15]; Rudy’s dream study of the FTO gene [1:57:15]; What the hell does insulin resistance actually mean? [2:08:30]; and More. Learn more at www.PeterAttiaMD.com Connect with Peter on Facebook | Twitter | Instagram.
Transcript
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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,
along with a few other obsessions along the way. I've spent the last several years working
with some of the most successful top performing individuals in the world, and this podcast
is my attempt to synthesize what I've learned along the way to help you
live a higher quality, more fulfilling life.
If you enjoy this podcast, you can find more information on today's episode and other
topics at peteratia-md.com.
Hey, welcome to this episode of The Drive.
On this episode, I interview an amazing scientist and a very dear friend, Dr. Rudy Libel.
Rudy's a professor at Columbia University, where his work has focused primarily on type
two diabetes and obesity.
I've known Rudy for quite a while, probably about six years now, maybe a little longer.
We worked together very closely back at the Nutrition Science Initiative where he was
one of the very important collaborators in one of the more theoretical experiments that
we did.
Rudy and I have always just had a ton of fun, just hanging out over great meals and great
wine and great beer, talking about science, and so I thought it might be fun to try to reproduce
some of those discussions here. Couple things. First, we recorded this on a Friday afternoon on the
Upper East Side and you'll probably notice a little more noise than usual just on account of
the street noise. So apologies for that. Second point is we spend quite a bit of time, probably about the first hour and
10 hour and 15 minutes just talking about the discovery of leptin for which Rudy played arguably
the single most important role. Obviously many people played a role in the discovery of leptin,
but you know in many ways Rudy was sort of the chief architect of that and certainly inside
of the scientific community he is largely regarded as that, though unfortunately, history may write that story a little bit differently.
So for those of you listening to this who don't really, really get off on geeky science and
knowing the nuts and bolts of all of the experiments and how one found this gene and the difference
between a southern blot and a northern blot
and a DNA sequence, you might just want to skip to about an hour 15 when we get to the other
stuff.
But that said, if you really are interested in science, I think there's a lot to be gained
from listening to these discussions because, you know, that's certainly something I plan
to do a lot of is interview scientists and part of that is kind of understanding their
stories.
Again, a lot of what we talk about in this post is technical.
I'm hopeful that in the show notes we'll be able to provide a lot of sort of a necessary
glossary to make it a little easier to ingest.
I don't do a great job.
I apologize of trying to clarify terms.
Occasionally, I remember that not everybody knows what hyperphasia means and I explain
that that means eating too much.
But again, I apologize for that and just look to the show notes if you want clarification
on anything.
We get into a lot of discussion around obesity, the genetics of obesity and the regulation
of obesity.
How much of this is regulated centrally, meaning in the brain versus peripherally, everywhere
outside of the brain.
We talk a lot about energy expenditure, and for those of you who are really interested
in this science, Rudy gives a great explanation
of the two techniques that are used
to measure energy expenditure,
known as indirect calorimetry and doubly labeled water.
We talk about a number of genes that are known
to predispose to obesity, some very acutely
and some very crudely, like the FTO gene.
And we of course talk a lot about insulin resistance,
which in many ways is sort of a bit of a paradox because on the one hand if you're insulin resistant you technically shouldn't be able to get fat.
But of course many insulin resistant people are able to get fat. They do accumulate out of post tissue.
What else can I say about this? I guess those are kind of the most important things I'd say to guide you.
So in summary, if you really don't want to hear about how leptin was discovered skip to an hour 15,
if you do sit back and relax, the other highlight of this was it was the first time I ever gave
Rudy a topo chico, he loved it and I think I've got another convert. So anyway, hope you enjoy this
and without further ado, here is my lovely discussion with the amazing Dr. Rudy Labe.
All right Rudy, how are you? I'm very well, thank you.
Thanks so much for trekking over to the east side.
Well thanks for inviting me.
This will be one of the first times in a while that we hang out without a drink,
including my favorite beer, which you're one of the few people I've shared it with.
Exactly. I don't tell anybody what that beer is because I and I just found 19
bottles of it in Florida last week. So I'm pretty psyched about that. I'll
continue to share with you of course. Still in Florida. No, it's actually in San Diego
right now. Yeah, just arrived. There's so much I want to talk about. I don't
almost don't even know where to begin. I'm guessing that a number of the people listening to this
won't actually know who you are necessarily, but I think by the end of this, they'll be
super interested in learning more about you. During the introduction, I will have explained
sort of a lot of stuff about you, but tell me a little bit about what you do and more importantly,
why you do it. I've been very interested since, oh, past 30 years or so, in the biology of the
regulation of body weight in both animals and humans, but the studies of
animals are designed primarily to shed light on what's the basis for the control of body weight in humans.
I'm a physician and have been interested in the clinical problem of obesity for even longer than I've been doing research on it.
And I have taken over the years various approaches beginning with studies of human adipose tissue, aspirated using various
needles from various subcutaneous depots and humans, meaning around the rear end and in the front
of the abdomen, and then became very interested in the genetics of obesity and have done some studies trying to identify various genes
that are related to that and continue to do so.
And have also done a large number of studies
in mice designed to look at this problem.
And very recently, or at least within the past five
or 10 years, have begun to focus on the use of stem cells to try to understand
again the biology of brain cells that regulate body weight and the cells and the pancreas
that produce insulin because obesity and diabetes go hand in hand clinically and this is not
an accident. They're very tightly related in a number of really very interesting ways.
So that my studies of obesity have led more or less and extraily towards the study of
diabetes as well.
So now my laboratory really does some of both.
And you're at Columbia now, you're a Rockefeller before that, but originally you were in Boston, correct?
That's correct.
My clinical training, I'm trained as a pediatrician
and an endocrinologist, and that training took place
in Boston at both the Massachusetts General Hospital
and the Children's Hospital.
And then for five or six years,
I worked at both the mass general and a community hospital
in Boston area, the Cambridge City Hospital.
Again, doing both general pediatrics
and some endocrinology.
So what got you interested in obesity?
I was interested in obesity,
or at least in the part of the brain
that regulates body weight,
even as a medical student.
We didn't study it specifically.
It wasn't emphasized the role of the hypothalamus, which turns out to be very important in that regard,
but I had the opportunity as a medical student, actually, a first-year medical student,
to work at the Walter Reed Army Institute of Research with a neuroscientist named Harvey
Carton, who was a physician who was interested actually in the study of bird brains, and he
took me on for a summer, actually ended up being two summers to work in his laboratory,
primarily helping with histological studies
of the bird brain, but the laboratory that he was in was run by a man named Wally J.H.
Nauta, who was recognized at the time and subsequently perhaps even more so as one of the great
neuroanatomists with regard to the hypothalamus. So actually I was indoctrinated a bit just by hanging around the other people who were working there, including Dr.
Carton, in terms of the importance of the hypothalamus in a number of areas of physiology.
Where does the hypothalamus sit in relation to the pituitary or even more grossly like other main structures in the brain.
Yeah, I think you can sort of picture it as lying between or being triangulated in a sense,
or at the cross hairs of a line drawn between the eyes and the side of the forehead,
and it's situated just above the pituitary gland if you know where that is.
Yeah, which is sort of behind the optochiosum.
Yes, that's correct.
And it's the very small organ, or at least it's a very small part of the brain, about
the tip of the small finger, but does play a role in the regulation of many important
physiological functions, including things like blood pressure, body temperature,
and from my point of view, very importantly, body weight, and also increasingly apparent that it
plays an important role in blood sugar control as well. So it's been known for many, many years as
being a critical part of the brain, a so-called vegetative brain, not under conscious control,
work that's gone on over the past 30, 40, 50 years
has increasingly raised the level of sophistication
with which we understand the function
of that part of the brain.
About 21 years ago, or maybe 20 years ago,
whenever it was, but early in medical school,
I remember when we did neuroanatomy,
the professor said, if you have to sacrifice
any part of your brain and you're sort of prioritizing,
the last thing you wanna sacrifice is the hypothalamus.
If you're only allowed to keep a couple
square centimeters of brain, keep the hypothalamus.
You know, I mean, we could get into the weeds,
or exactly.
That's a poor man's problem.
That's right.
Right, I think that would be important.
The other thing you'd want to hang on to
is the part of the brain that regulates respiration,
because even with the hypothalamus,
if you're not breathing, you're not gonna get very far,
but I agree.
I think he was excluding the brain stem for this.
The hypothalamus is right up there.
At some point, I want to come back to what I want to have you tell us all about zucker
rats because that's sort of what got me interested in this idea of how can this part of the brain
when subjected to so many different types of insults and lesions produce
so many, I mean, seemingly wild and disparate phenotypes that seem so out of whack. But before
we go there, let's go back to European, you're a junior pediatrician schlepping along,
taking care of overweight kids. And we're in the, what the late 70s, what time of year
is this, what time of year life is this?
Yeah, we're in the mid 70s, what time of year is this? What time of year life is this? Yeah, we're in the mid 70s.
Mid 70s.
So there's not that many obese kids, are there?
They're planning.
Still in back then, yeah.
Yeah.
So what are you doing for them?
How are you helping them?
So back in that day, the conventional view
was that obesity was largely due to imbalances of hormones,
at least potentially, in addition to whatever
other sort of behavioral issues might be implicated.
But almost in all children with obesity were referred, if it was significant and severe
enough, to either an endocrinologist or a psychiatrist.
That was sort of the bifurcation point
for a referral of these children.
I don't think either the endocrinologist
or the psychiatrist really could do very much
for these children.
I certainly couldn't.
And it was an evening in the fall in the city of Cambridge
in a small office that I used for the very small number
of referrals that I actually saw.
Most of my time was spent with the medical students trying to teach them various aspects
of pediatrics.
But one evening I saw a young boy about seven or eight years old with his mother and examined
him, weighed him, so forth, and determined it's quite clear that he was very obese. He had no other stigma of the sorts of things that we look for,
meaning very severe problems with thyroid or adrenal gland,
which can sometimes produce severe obesity.
And he didn't have any of this stigma of the single genetic type of disorders
that were known about at the time, like Pr like Prada Willy Syndrome or Part A Beetle.
And I said to the mother, your son has severe obesity.
I can't tell you what the ideology of it is.
It's clear that there's something going on.
There's problems that we don't really fully understand or understand very well at all.
And my only advice is to try to restrict the number of calories that he eats and
increase his physical activity, which is, I think, unobjectionable advice in any circumstance like that.
And the mother turned to the boy and said,
Randall, let's get out of here.
This doctor doesn't know shit.
I love that you remember his name too.
Oh yes, I do remember his name.
And she took him by the hand and they left.
And I remember sitting behind the desk
and thinking to myself, Randall's mother, you've got a point.
And it was that experience actually.
I'd been interested in some of the physiological aspects of obesity and adipose tissue that
led me to decide that if I was going to do anything about this, I was going to have
to train myself to do the kind of research that might be helpful in terms of understanding the disease.
And it was shortly after that that I actually moved in New York to the Rockefeller to begin to
try to do those kinds of experiments. And that story, which obviously we've discussed before,
and I get such a kick out of it, but at the same time it's actually a remarkable example of something
that medicine is a privilege. It gives you a privilege, and it's up to you to do anything with it, but at the same time, it's actually a remarkable example of something that medicine is a privileged, it gives you a privilege and it's up to you to do anything with it, right?
Which is patients generally provide the appropriate physician with the right level of humility.
And I think, look, it's a testament to you that you sort of could reflect on what Randall's
mom said, because I think there are other people who couldn't, right?
There are other people who could say, well, screw you.
That's the advice I've got and that's like the best I can do.
And, you know, it wouldn't skip a beat kind of moving on.
But when I talk to a lot of great physician scientists, that seems to be the one thing that
they all have in common.
They may have many things in common, but this one is important, which is it's the ability
to sort of pause on your tracks and say, wait a minute.
There is a clinical situation, and I cannot, for the life of me is a clinical situation and I cannot for the life of
me explain it, and I have to know the answer. So it's so amazing that one chance encounter like
that basically altered the entire course of your career and put you on this path to do some really
amazing stuff as we'll, I think, discuss in the next hour or so. I think you're probably right that one of the great I think privileges of a medical education
is that it does give you a very broad perspective on the human condition if you want to call it that
all the way from psychological issues to very fundamental biological ones. And physicians as a group do have this, as you pointed out,
rather unique opportunity to look at a problem that afflicts human beings. Sometimes at the level of
basic metabolism and endocrinology, other times on a more systemic or even social level. And I'm sure you could name some of the names of people
who have operated all these levels.
But I think you're right.
I've always felt that it was really somehow
an enormous opportunity and a gift to be able to pursue
this down to the level that I've been able to do
in the past 30 years or so.
And I must say, in addition to whatever my previous training and experience did to make
that possible, I also have to acknowledge that my family was very supportive in terms
of allowing me to basically back out of a more classical sort of academic
medical track and retrain myself to the level that I thought was required in order to do this
research or basically move from a very nice home in Brookline, Massachusetts to an 800 square foot apartment in Manhattan with a wife and two small children and lived there for 15 or 16 years
while I sort of got my act together.
There's plenty of great research that can happen at Harvard.
Why did you come to New York?
I came to New York actually after looking around
in the Boston area for someone who could mentor me
in this kind of activity.
And it turned out, I mean, there's some interesting stories about that.
But the advice that I got from the people who were not in a position to help me in the
way that I thought I needed help was that I might consider going to the Rockefeller and
working with a position scientist named Jules Hirsch, who at the time was very interested in the biology
of adipose tissue from a number of perspectives.
And I had actually communicated with Dr. Hirsch
in the literature by commenting on some of the work
that he had done with regard to adipocytes
and signals that might come from adipocytes
that affect potentially food intake and body weight.
This was an area that he was quite interested in.
And I was, too, based on some of the thinking
I had done about it while I was in the training in Boston.
And he and I actually had had a communication
in the literature on some of the work that he had done.
And I went actually to visit his laboratory.
And while I was in New York for an entirely different reason,
and it was very shortly after that that I moved.
Which is another great example of the types of common threads
we see in great scientists,
whether they be scientists or physician scientists,
which is mentorship, right?
Again, every person I talk to who's done
something remarkable in science can point
to mentors, a mentor or mentors, and obviously for you, Jewels was probably the most important
mentor I'm guessing.
That's right. I had very important other mentors in the area of clinical medicine, and the
one who trained me in endocrinology and individual, again, a physician scientist, more clinically-oriented,
named Jack Crawford, himself was very interested
in the role of body fat and its interaction
with other physiological systems in the body,
most notably the onset of puberty.
And it was he that actually put me in contact
with another scientist at Harvard named Rose Frisch,
who also was very interested in why, for example,
young women who lost weight as a result of anorexia
or more commonly in her experience
due to very vigorous physical training
for things like distance running or bicycling,
swimming became a
menorgic. In other words, their period stopped. And Rose was very curious about
why this was and whether there was a communication between fat and parts of
the brain that regulate the canadal axis, which is the hypothalamus again. And I
remember having many conversations with Rose about where the
signal might be coming from. She thought it actually might be coming from adipose tissue adipocytes
in the bone marrow. And it was always encouraging me to study bone marrow as a source of whatever
this signal might be. So what year did you arrive at Rockefeller? 1978 at that point in time was the adipose tissue was it was adipose cell where they was this regarded as an inert sort of
storage depot for fatty acid or was it considered an endocrine organ like what was the state of thinking about fat?
at that time the view of
the role of adipose tissue was very strongly in the direction of the sort of form or characterization that you made, which is that it was a passive depot
for fat in the form of storing free fatty acids as triglycerides so that they were hydrophobic so that you could
pack a lot of calories into an organ or into a cell without having a lot of water there. So it's
a very efficient way of storing energy, actually, as you know, up to probably around nine calories per program. And its role as a signaling device or an endocrine organ was really people were
thinking about it, but there was no firm evidence in this regard. Other than I think the increasing
sense that the size of the adipose mass was doing something to the levels of circulating insulin.
That somehow insulin rises when the fat mass rises and the mechanism...
Or the relationship of the two.
Not the other way around.
Was it clear which direction?
So at the time, I think the view was pretty much that as fat mass increases the concentration
of insulin rises to meet the consequences of so-called insulin
resistance, which occurred not only in adipose tissue, but maybe more importantly in liver
and muscle, and so that there was some relationship between fat mass and this endocrine, but fat mass is a secretory organ itself of molecules that might
have some of these effects was really a pretty new idea that nobody really had any direct
at least at the time evidence for. Obviously, we're going to get to the story of leptin, which I think
is just another great example of incredible persistence, an incredible focus and drive.
But obviously before getting to the punchline, which occurred several decades later, what
was your first insight into a hormone that would go on to be leptin?
Where did you first figure this?
That there was something that was being secreted by fat cells. I think the first evidence in this regard, or at least some of the most important evidence,
came from experiments that were done by an investigator at the Jackson Laboratories in Maine,
named Douglas Coleman. Coleman was a biochemist, physiologist, who was interested in some of the rare mouse mutations
that led to very severe obesity.
And he was one of the first to study the OB-OB or OB's mouse, which was a spontaneous mutation that arose in the Jackson colony.
And he also was one of the close students of another mutation that arose there a number
of years later in the so-called diabetes or DB gene.
So what was the phenotype of this OB-OB mouse?
The OB-OB mouse was... That's not to be confused with the OB-1 canobimouse, that's a very different phenotype of this OB-OB mouse. The OB-OB mouse was... That's not to be confused with the OB-1
canobie mouse, that's a very different phenotype. That's correct. Yeah. The OB-OB mouse was noted to be
very severely obese, very early in life, so these animals were clearly obese by the time shortly after weaning, which is
three or four weeks of age. You could tell that they were obese. And if you left them alone and
let them eat as much as they wanted, they would eat up to the point of becoming pretty heroically
obese, meaning these animals could reach weights of is breed the parents, and they would be able
to get up to 60 or 70 grams per day.
So, the way they would breed these animals is breed the parents, and they would be able
to get up to 60 or 70 grams per day.
So, how did they keep breeding them?
So the way they would breed these animals
is breed the parents, the heterozygous animals
that were able to generate.
They'll get two heteroes to make hummus.
Correct.
So the phenotype centered around hyperphasia?
It's centered around two phenotypes, actually,
that Dr. Coleman was able to show.
Primarily, the obesity was due to hyperfagia,
but he also was able to demonstrate by a mechanism.
Sorry, I should just clarify for listeners.
That means excess of appetite.
Yes, by excess food intake.
That was the primary cause of their obesity.
But he also, by using a technique called pear feeding,
where he would only feed the animal,
the amount that a normal weight animal would eat,
that those animals tended to store more of their excess calories as fat.
We sometimes refer to this as partitioning.
And by another set of experimental maneuvers was able to show that their metabolic rate was slower.
So these animals had what you might call a trifecta for obesity.
They ate more, spent less, and whatever they stored
was preferentially stored as fat.
And these were fascinating animals.
I mean, people tried for many years
to figure out what was wrong with them.
And they had many metabolic consequences of their obesity.
But nothing about their physiology necessarily with them and they had many metabolic consequences of their obesity, but nothing
about their physiology necessarily pointed to what the primary mechanism was, where the
genetics clearly indicated that this was a single gene or very likely to be a single.
And this of course is long before you've got your PCR technology that can very easily help
you sequence this. So two questions though, lifespan was what?
lifespan not severely affected actually, they could live to a fairly normal
lifespan somewhat shortened to- two and a half, three years.
Not quite, they don't last quite that long, but certainly up to 18 months or two
years. Important to note because of the question of whether fat makes something or not,
Coleman not only observed these OB mice, but also the second mutation that arose later at the Jackson Lab
and was named the diabetes mouse.
That's because that animal looked a lot like an OB mouse, but got diabetes very early in life, unlike the
OB mouse, which seemed to be obese, but not necessarily particularly diabetes prone.
And it was clear that the mutation in the gene, again, another single gene that caused
the diabetes mouse was not the OB gene.
It was on a different chromosome.
Coleman was able to show that. So here you had animals that looked a great deal
like each other, at least in terms of the overeating and the low energy
expenditure. One was prone to get diabetes and the other not. And what Coleman
ultimately did was to join the circulation
of the OB mouse to a wild type animal
and the DB or diabetes mouse to a wild type animal using.
It's like a live parabiosis.
It's a lot, that's the technical term for it
is a parabiosis.
And he showed that if you hooked an OB mouse up
to a wild type mouse in this way, that the OB mouse would correct its
hyperfagia, its excess food intake, and actually begin to lose weight.
So something presumably in the wild type mouse, some humoral factor, some hormones, some something,
must have been missing in the OB-OB mouse that when given to it corrected its phenotype.
Correct.
And then what happened when you did the parabiosis
with the DB mouse?
With the DB mouse, you got the opposite situation
where the wild type animal began to lose weight
and actually stopped eating and would die
of starvation, basically.
Whereas the DB mouse just went
merrily on its way eating and remaining obese. So Coleman thought, based on these
two experiments, that maybe the OB mouse was missing something that the
wild type mouse produced. And the DB mouse that looked an awful lot like an
OB mouse was missing the ability
to respond to whatever that molecule or molecules were that were required to regulate body weight.
And this was around the time that it was becoming clear that hormones had receptors that were
specific to those hormones like thyroid, insulin, growth hormone. So Coleman hypothesized that the OB mouse was missing what we refer to as the ligand,
the circulating hormone, and the DB mouse was missing the receptor for it.
And it turns out that Dr. Coleman was right.
Everything you've just said was known by what point in time.
I would say by the late 1970s.
Okay, so just as you're coming on the scene, the whipper snapper who doesn't know shit.
Yes.
The guy up in Jackson, up in Maine knows this, and you can't wait to get all over this.
Correct.
So, I began by actually studying adipose tissue to see whether there was something that might be
regulated by adipose tissue that would fit in this sort of general category of something that
might produce a signal or might be related to the anatomy of the adipose tissue. At the time,
Jewels Hirsch was particularly interested in the fact that
it appeared that what happens when people get obese is that their fat cells expand up to a
sort of maximum size, and then new fat cells begin to appear, whether they were made de novo or
had been resting in the area of the other adipocytes wasn't clear at the time, but what happens as people
get more and more obese is that more and more fat cells are recruited so that if you look
at a very obese individual, they have what is referred to in the literature as hyperplastic
adipose tissue, they have more fat cells.
And jewels had actually figured out a way to count the fat cells of a human being.
And you can look under a microscope and see how big the fat cells are.
So he was very interested in what it is that permits a big fat cell to call up, if you
will, the other fat cells that are going to be needed once it reaches a critical size.
And whether these fat cells were generating something that might act like a signal.
Are there any organelles inside a fat cell?
Oh yeah, fat cell has the complete repertoire of organelles that any other cell does.
So it's got a regular, quote unquote, regular nucleus.
It's got mitochondria.
Oh yeah.
Yeah, it's got the whole, it's just, its cytoplasm is dominated by these lipid droplets.
It's designed to be able to hold these huge lipid droplets, but otherwise is a perfectly
respectable cell, has all the other components.
And what jewels had been doing along with another investigator in the lab, my name, herb
fowse, was extrapating adipose tissue from rats.
They were working primarily with rats.
Although there were some OB mice around, I'd actually seen those when I was at Harvard
in Boston, endocrinologists, you trained me, you just talked to me about them.
But jewels and herb were extropating adipose tissue depots from rats and looking to see
what happened and one of the things that they were struck by
Is that when they took a fat pad out if they waited long enough and just let the animal eat whatever wanted to eat it would eat
It's way back up to restoring that fat pad through denovo creation of more fat cells
So you leave you leave the capsule of the depot there and it is able to generate new fat cells and
they fill up and they don't fill up to three times the size that they were before they
go right back to the appropriate size for that depot.
And one of the things that jewels and herb were very interested in is how does the animal,
what how does the animal know that it should eat a little bit more to be able to generate
the fat that's been extirpated?
And did this experiment only work when you started with obese rats or did it work if you
took a lean rat as well?
It worked with lean rats just as well.
As a matter of fact, most of the work they did was with
lean rats, or not genetically obese. Now speaking of rats, you explained to us what the OBOB and the
DB, DB, DBOB, what about the Zucker rat, which preceded a lot of this stuff, but had some interesting and
similar features, right? Right. So the Zucker Rat was discovered or identified, if you will, by a woman named
Lois Zucker, her name to her and her husband. And it had characteristics very similar to
these mice that we were talking about, the OB and the DB mice. They were hyperfagic.
They appeared to have a little bit lower energy expenditure and would become hugely obese.
I mean, these animals got up to heroic size. Yeah, we're going to include some pictures of the
Zucker mice in this, in the notes of the rats. That's where the Zucker rats in this show.
Got very, again, got very obese, and many, many studies were done of the Zucker rat trying to,
and many, many studies were done of the zuccer rat trying to, again, understand what the mechanism behind its obesity was. Again, it appeared to be due to a single gene. In other words, like the OB or DB mouse,
there was a single mutant gene when the animal had two copies of the abnormal or low activity gene, the animals would become
very obese. And one of the reigning hypotheses about the Zuckerrat, again at
around the late 70s, early 80s, was that the fat itself was making too much of
an enzyme called lipoprotein lipase. This is an enzyme which is produced by adipose tissue,
by adipocytes, which breaks down circulating triglycerides
and allows the free fatty acids that are released
to be taken up by the adipocytes.
And the glycerol backbone, so to speak,
remains in the circulation.
So the idea was that the zucker rat, for some reason, had hyperactive, lipoprotein lipase,
and the adipose tissue was acting like a vacuum cleaner, in a sense.
It was sucking up the circulating fat, the triglyceride, and storing it, and that's
how the animals got obese.
And in association with that observation was the idea that maybe the process of sucking
up substrate from the circulation does something to drive or increase food intake.
So this was, model was often referred to as a pull model for the development of obesity. That is that the adipose
tissue was actually acting as a pulling mechanism for substrate, which was in turn affecting food
intake, so the animal got fat that way. So the animal was effectively starving. Even though it
stored an unbelievable amount of energy, it was disproportionately taking those circulating metabolic
fuels and putting them into storage so that if you buy this idea that something is sensing
energy availability, that would naturally drive the hyperphasia, right?
Correct.
And the other model, the one more consistent, say, with the OB or the DB mouse was the so-called push model, which is that
fat cells were being filled up because the brain itself had a...
Was pushing.
...pushing the substrate.
So these push pole models were very much discussed in terms of what they said about where
the primary mechanisms might be for the control of body weight. Was it the adipose
tissue that was basically begging for more fuel and sucking it in and causing the animal
to eat that way, or was there something going on in the primarily in the brain that was
influencing the food intake and the adipose tissue was being packed from the outside?
And like all good problems in medicine, there's examples of both that are quite elegant,
right? I mean, that's sort of the challenge of this is when you look at this in experimental
models, you could find very elegant examples of each, correct?
You could find elegant examples that pointed in the direction of both of these. It was interesting. I mean, it was the whole issue of lipoprotein lipase
suggested that, again, this model, the Zuckarrat,
it was used to support this idea that LPL,
as it was referred to, was critical in this regard.
But it was known that individuals who had total lipoprotein
lipase deficiency, and there are such individuals
on a genetic basis, had very, very high levels of circulating triglyceride.
I mean, these can be life threatening in terms of the levels that are reached, but they had
perfectly normal adipose tissue. So this suggested that maybe LPL wasn't critical or
absolute- Meaning you would expect those patients
to have sky high triglycerides and be emaciated.
Yes, and they weren't, and they aren't.
So this was already sort of a question
about the lipoprotein lipase.
And we know that those patients
were completely deficient in LPL.
Yes.
Does that mean they had no LPL on their muscle cells as well?
So the individuals who are totally deficient in LPL have no LPL on any cell time.
It's hard to imagine how they function.
Does that mean they're completely dependent on glycolysis?
They are able to take up the fatty acids.
They don't need the LPL to break down the triglycerine.
They do fine.
I mean, in terms of being able to,
there's nothing wrong with their manipulation
or movement of fatty acid.
And that's probably why they have normal adipose tissue
and normal muscle.
So when it's interesting, the history of this,
and just to mention this, we now know what the Zucker mutation is.
And one of the earliest experiments I did at Rockefeller
or one of the relatively early experiments
is we tried to map the position of the Zucker Obesity
gene in the same way that we were already
trying to map where and ultimately clone the OB and DB gene
for pretty obvious reasons at this point that we wanted to figure out what the signal and whether there was a
receptor for this and as part of this work a
student who worked with me and Gary Truett made a map of the position of the Zucker gene
which we did by crossing the Zucker rats with another strain of rats so that we could make what's referred to as a genetic map.
And tell me how that works because everything I've ever done with genes came after we had the luxury of
real-time PCR and we just, you know, my generation had it so easy. You guys like when I hear stories about people doing
You guys, when I hear stories about people doing positional gene stuff 40, 50 years ago, I'm like, wow, that's incredible.
Tell me technically, what were you actually doing to positionally isolate that?
The way these experiments are done, it's pretty much the same principle, is that you take
in the case of rats and mice, which you have this luxury, you can cross one strain of mouse or rat
to another strain of mouse or rat,
and then look for signposts of genetic variation
along the entire genome of the animal.
And each strain has different sequences of DNA.
Major differences are in the so-called non-coding region.
Some of the differences are in coding regions.
And back then, we used a technique called Southern Blotting
to look for basically putting down signposts
on the DNA of an animal to figure out where the differences
between the strains
Resided and by
monitoring the
Obesity of the animal and knowing which strain was actually carrying the
Gene that we didn't know what it was, but we know what strain it came from in this case the Zuckerstrain
we could actually mark the
DNA of these animals that had been interbred
and figure out where the zucker chromosome, the zucker genetic markers were segregating
as the formal term for this along with the level of obesity of the animal.
So we would look for correlation of region which has the zucker
genetic variation with the obesity of the animals because if you do these crosses in the way that I describe
you get some obese you're gonna get in some non obese animals and then by relating where the sequences are
corresponding to the
strain from which you know the obesity gene must have come.
You can actually narrow the region of the genome down to the area that must contain the gene.
I mean, and this was a qualitative assessment, not so much a quantitative assessment, right?
So the quantitative assessment is the animal obese or not obese? You absolutely have to get this right
because the obese animal has in this particular model two copies of the mutant gene that's
producing the obesity. And if it's not obese, it has one or zero copies. And you need to
be absolutely clear what the phenotypus, so to speak, of the animal is,
and then if you put these markers down, these signposts down,
you can define an interval in which that gene must reside.
So it's actually, it's in a sense,
it's quantitative at the level of the phenotypics.
So the best you could do is say this is on 17p or 17q.
That's like the level of resolution you can get out of this.
Yes.
What happened when they did a parabiosis with a zucker rat?
Did anyone do that?
There have been parabiosis experiments done with rats, but they've generally done these
in a slightly different way from the way you
asked the question.
And those studies have, again, supported the idea that the zucker rat may be overproducing
like the DB mouse, the product which is suppressive of food intake.
And as a matter of fact, when we were trying to clone these genes, I actually took blood
out of Zucker Rats and injected it into DB mice to see whether or not I could slow down
their food intake.
Because at one time we were worried that we might not be able to get the gene by mapping
and would have to try to isolate the product out of the blood of an animal. But the Zucker Rat studies supported the idea that the same is the mice.
So we'll fast forward now into the late 70s or early 80s.
You're working mostly now in the lab.
Your clinical responsibilities have shrunk significantly, right?
So at the time I was doing these experiments, I had some experiments still going on, you
know, clinical practice at all, but I was studying humans in the clinical research center
at Rockefeller looking at the effects of weight loss and weight gain on energy metabolism
in these individuals. Again, beginning to try to understand what it is
that's regulating body weight in a human,
the idea being that if you reduce the body weight
of a human down by 10 or 20%,
what happens to them metabolically
that might be consistent with some of these things
that had been seen in mice that would suggest that
again in humans there's regulatory pathways that are there in order to regulate the amount
of stored energy.
So my time was basically split between doing these studies of humans who were in the clinical
research center for long periods of time, when we would study the metabolic consequences of perturbing their body weight, the other was spent trying
to identify these genes to try to clone the genes.
So how did that progress through the 80s as you were working to try to identify specifically
the OB-OB gene?
And again, the reason you were pretty confident that it was a single gene
was just based on the breeding pattern. Yes, the breeding pattern clearly indicated that this was
a single. Because it was sort of Mendelian. Yes, absolutely Mendelian. So so-called
autosomal recessive Mendelian, as is the DB mouse and the Zucker rat. So what we did is what I basically described for the rats.
Why was it harder for the mice? To clone the gene? Yes.
I, it was not harder. No, no, I think it was equally difficult. What I was describing
is when we didn't actually sort of finish that part of the conversation, we did make a map
of where the Zucker gene was located in the rat, but we didn't clone
the gene out of the rat at that time.
What that experiment showed is that what was interesting, apropos, this lipoprotein
lipase hypothesis is that the zucker gene was in a part of the rat genome entirely separate
from where the LPL gene was located. So from that experiment
alone, we knew that it couldn't be LPL as the causal mechanism of the zucker rat. We
didn't know what it was, but we could pretty we could clearly identify what it wasn't, because if the gene is not in the location that is
segregating with the phenotype, it's not the gene. This was hard for people, I think,
to understand, or at least to accept at the time. There's still, I think, was not full
appreciation of what an experiment like that representsents which is basically an unequivocal falsifying experiment that is if it if it isn't in the place where the gene
Must be then it can't be the gene. I mean it's a
Syligism yeah, and you don't get a lot of those in science. No, you don't get especially in biology
right and so this early, this was one of the
proofs that at least we knew one gene that it wasn't. It wasn't. And then to sort of back then,
to your question, we used a very similar strategy, an identical strategy with the mice. We crossed
the mice to strains that were different from the strain on which the mutation existed. And by doing that, we're able to make maps of the region
where the gene was located.
And I was actually known for other reasons.
Coleman had figured it out.
He knew which chromosome these genes were on.
So we at least had that as a sort of initial guide,
but what the gene was or how it worked was obviously entirely unknown.
What was Coleman's training?
Coleman was trained as a biochemist at the University of Wisconsin, I think.
And we actually consulted with Dr. Coleman Doug very early on,
as a matter of fact, very early on in the process, about which strains of mice might be appropriate as so-called
counter-strains, that is mice that would be used to enable these maps to be made. And he was
extremely helpful. I mean, he used to come down, we would talk to him, go visit him and at Jackson,
on at least one occasion, met with him in Philadelphia. So he loved the collaboration.
He loved it.
He was very encouraging of that.
He always said that he wasn't sort of O. Coront with regard to the tools of so-called
molecular genetics.
But in fact, I and Jeff Friedman, who was the other sort of PI on this project, neither
of us was expert in molecular genetics.
So we sort of had to train ourselves to do this as did the students who worked with us on
this project.
So when did Jeff enter the lab?
I got to know Jeff because he rotated as a resident, actually, at New York Hospital
through Jules's lab to work with another investigator there. So I got to know him when he
rotated through, but he and I started this project after he entered the PhD program. He was a
physician and then went on to get a PhD at Rockefeller in a different laboratory, but he and I started the project to clone these genes together. About what year was that?
1985 or 2006, I guess, and, you know, 86 probably.
But with the major steps that took place starting around the mid-80s,
that were kind of like the essential... I mean, I think one of the things that's just hard for people to understand is
how much you have to fail in science.
I mean, it sounds simple, right?
We want to clone a gene.
And yet in that era, that was very hard to do.
Right.
There were efforts underway at around the same time to clone the gene for Huntington's
disease and cystic fibrosis, muscular dystrophy to name a few.
Other single gene disorders.
Other single gene disorders.
And for a number of reasons, genes that are on sex chromosomes may be a little bit easier
to handle in this regard.
But the same tools were being used, the so-called Southern Blotting, putting down markers across
the genome using this rather tedious technique of having to put the DNA down on a blood
of some kind, and then exposing it with radioactively tagged reagents to be able to find these individual
markers.
This was a tedious process.
One thing that helped with the mice is that there existed a chromosome in mice
So these are called Robert Sonia chromosomes in which you have two chromosomes joined to each other and there was a so-called
Robert Sonia chromosome that had both chromosome four and chromosome six of the mouse attached to each other
We knew based on Doug Coleman's work that the OB gene was on chromosome 6 and the DB gene
was on chromosome 4.
And one of the students who came to work on this project, very early young man named Nate
Bajari, who came over from New York Hospital as a medical student and spent time on this project
and then went on to get a PhD working on it.
He took glass needles, if you can believe this, and dissected out under a microscope the
rough regions of the chromosome 6 and 4 that we knew must have the gene in them and made from those needle-dicecated
chromosome fragments other markers that we could put down on the
DNA from these mice that we had intercross to make a finer and finer map of the region
In which the gene must reside and otherwise this was identical to the zucker strategy in which we very carefully looked at see whether a mouse was obese or not. And again, these are mentalizing phenotypes, but we had to be absolutely sure what the phenotype of the mouse was.
And then we could use the DNA from the obese animal to make a finer and finer map around the region where the gene must reside.
I don't even understand how that would work. What resolution of a microscope would you need to be tweaking chromosomes?
Chromosomes aren't that small. I mean, you can see a chromosome quite easily with a high-powered...
Just a light...
Yeah, like microscope.
But having the steady hands to be able to...
And the patience to be able to do this
was quite an achievement. I would say was Sinekwanone without which this project wouldn't have been
done at the time. We didn't have the tools, some of the ones that you already mentioned,
available. So we had to try to identify additional signposts, if you will, in the region of the two genes
that we were primarily interested in.
That is the OB and the DB gene.
At the time you're basically thinking,
look, we're looking for a gene for a hormone,
we're probably looking for a gene for a receptor.
So a ligand receptor.
Did you have an expectation that those would be
on the same chromosome,
or would that be completely unnecessary?
No, we knew that they absolutely weren't.
No, no, I knew you knew that they weren't, but would you expect that?
For example, the thyroid is T4 and TSH or T4 and TR, you know, the thyroid receptor or TSH
and TFR, are they necessarily?
No.
No, no relationship.
No, no.
So the function doesn't require that the genes be in proximity to each other.
And if they are, it's almost always just a coincidence. Got it. So what was the kind of critical breakthrough
that led to the cloning of this gene? So what was done basically was to make the map as fine as we could using the reagents that I mentioned to you and some others that we were able to get hold of and using computer programs to put these data together in such a way as to be able to generate as fine a map of the region around this gene as we could.
region around this gene as we could. And then what was done was to go into the region that must contain the gene and
begin to look for
expressed meaning that the DNA was transcribed
transcripts that were being read off of this part of the DNA and
by taking the transcripts that came off and putting them against various organs from the OB or the DB mouse, we would look for transcripts that were specifically altered
in the animals that were mutant for the gene. So you would expect, you might ordinarily expect maybe
the level of the gene that we were looking for
would be very low in the organ that was affected.
And again, even though we know now it was adipose tissue
and there was certainly reasons to think
that might be where the OB gene was.
When we did these experiments,
we actually looked at every organ in the animal,
brain, thyroid, muscle, adipose
tissue, anything we could get our hands on. We actually dissected it out almost everything
out of a mouse to look to see where the deficiency or the excess might be. Sometimes genes, transcripts,
are overexpressed, although they're not functionally competent. And actually, at a visit to the Jackson Labs when Doug Coleman was retiring, one of the
investigators there asked me if I would like to have, or we would like to have mice that
appeared to have the OB mutation but a different mouse.
So the original mutation occurred
in the mouse that was identified at Jax
in the early 1950s.
This was a new mutation that had arisen,
and almost certainly wouldn't be identical
to the one that had arisen earlier.
But was similar in phenotypes?
Absolutely identical in phenotype.
So I got those mice and we took them to Rockefeller.
What did you call them? Two J's. So the OB, the first mutation we refer to as one J,
that's just the nomenclature and the second one was OB, two J. And we took the OB organs out of
the one J's and the two J's and ran these transcripts against them using the technique called northern
blotting at the time.
Not to be confused with western blotting.
Not to be confused with western blotting.
So northern blotting is looking actually at RNA.
It turned out that the two J was extremely valuable animal because those animals didn't
express any of what turned out to be the leptin transcript,
whereas the one J's actually overexpressed it.
But it was functionally inadequate, functionally inactive.
But the transcript was increased, again, for reasons having to do with the molecular biology
of how these systems work.
But when we saw that there was one animal that had
at very low level and the other very high,
this was a smoking gun, so to speak.
This was the evidence that that piece of the genome
was actually a part of the OB gene.
So ultimately where did this ligand, where did it show up?
The OB gene showed up almost solely, virtually solely, I mean, in adipose tissue.
Fully consistent with the idea that adipose tissue was producing something that was picked
up in Doug's parabiosis experiments.
Which chromosome?
Chromosome 6 of the mouse. it's chromosome seven of the human. We actually knew that because we could put the orthologues of the mouse chains down on human DNA.
And so just like we did with the Zuckarrat, we actually knew where the the gene was. Do mice have 23 pairs of chromosomes? They have, yes, 23, 23, including the sex.
So what name was given to this? I mean, it's referred to as the OB gene or the name that was given
to the protein is leptin, which was, the name was chosen because that suggested that whatever this was, it had an effect to lighten the body weight of an animal.
So now you have it that the fat cell secretes leptin and the OB mouse can't make leptin,
correct? Correct. And the DB mouse makes all the leptin in the world.
This wasn't known at the time because the first gene to be cloned was the OB gene and the fact that the DB gene was the receptor was actually
learned in two ways one by
taking the OB protein and putting it down on what's called an expression library from part of the brain, the corroid plexus.
Wait, sorry to interrupt one thing, really I apologize.
Did they ever do parabiosis between the OB and the DB?
Yes.
That was done as well.
Okay.
Because that would, that should fix the OB.
It did.
But not the DB.
Correct.
Okay.
Which is another great and elegant example that one of them had the ligand deficiency, the
other had the receptor deficiency.
God, Mendelian genetics are freaking awesome when they work.
Yeah, well, so that was one of the reasons for using these animals is that you could use the genetics
to really help to narrow down the region where these genes had to be located.
If it were a polygenic disturbance, it's really, it's a whole different order of business. So, basically
the DB gene was, or the protein that was nominated to be the DB gene was pulled out of a
library of, what's called an expression library of coroid plexus by using the OB protein
as a probe to see what it stuck to. And that gene that was pulled out of the corrod plexus in that way,
we then took and mapped into the DB crosses that we had
and showed that that, if you will, nominated gene mapped right in the right place for the DB gene.
Which was on chromosome 4 and
about. Correct. And it also turned out that that gene, the DB gene, the left
and receptor, is the mutant in the zucca rat, which we showed by cloning the gene
then out of the zucca rat, knowing where it was. So this was hailed as one of the
most important insights and breakthroughs in all of obesity
research.
This was what, 1994?
And then the DBGN a year or two later.
What was your expectation at the time?
What type of hope did you hold out for the discovery of the gene, but perhaps more importantly
the protein that it coded for. So there were different schools of thought with regard to what this
protein actually did. I think one view was that if you
saw this as a protein that suppresses food intake, which it definitely does
in an OB mouse. If you give it to an OB mouse, you can basically, quote, cure the
animal. And if you give it in very high doses to a mouse, it will suppress its food intake.
So one view was that this was a weight-suppressing hormone. The other view, which was taken by
Jeff Flyer, who was at Harvard at the time, later became Dean, he's still at Harvard.
Stream St. Chua, who was working on this project or had worked on it, and myself, was that
the protein was actually more important in its deficiency state as a signal to the brain
that you didn't have enough energy to survive under circumstances of
a fast or to have enough energy on board to successfully complete a pregnancy.
So one view was that very high levels would normally suppress body weight, although it
was hard to imagine it to have a...
Evolutionarily, that was not a natural state.
That's correct.
So that's why we're wondering right from the beginning, why would nature invent something
that would make more sense that nature would say here's a hormone that if it's low is a kick in the pants to eat.
That's correct. Or and maybe other things, right, maybe prevent you from getting pregnant. Yes. And that's I think turned out to be the correct model for how this hormone.
its primary mechanism of action is that it is there to tell the brain that you don't have enough fat. And in an OB mouse you don't make the hormone leptin, so
the brain thinks you don't have any fat. And in the DB mouse it doesn't receive
the signal from the perfectly adequate amounts, actually high levels of
leptin, so that the animal again thinks that it's starving. Are there human conditions that mimic the OB and DB condition of the mice?
Yes. So there are humans, there are handful of humans who have mutations of the OB gene
and or obese and have many of the phenotypic characteristics of a...
And these are patients that you've cured with this. You give these patients leptin and
you cure them. Yes. They're curable by giving leptin.
And they're a handful again of individuals
with leptin receptor mutations, which are comparable.
How do you help those patients?
Those that leptin won't help.
You can't treat them with leptin.
And there is no effective intervention
for those people at this time.
Although there are drugs that are being developed
that are designed to act downstream of some of the actions
of leptin that might, if you could,
rectify the activity there, for example,
at a receptor called the melanocortin IV receptor,
that would presumably or possibly help
to rectify the phenotype of those individuals, although
at present, it's not a proven effective intervention. It might turn out to be.
I mean, wasn't long after the discovery of leptin that what drug company came in?
Amjit. So Amjit obviously bought the rights to do this, thinking this could be a blockbuster
obesity drug. It turned out not to be because unless you had a leptin deficiency, it didn't seem to help
much, right?
Correct.
There was a major trial of the use of leptin as a therapeutic agent in obese individuals
and neither the obese individuals or the lean individuals who were in the study as controls responded very
much to raising blood levels as much as 10 fold above where they were
normally located in those individuals. So I just did a blood draw. I've been doing a blood draw on myself every seven days because I'm doing, you know me, yeah, that's just the should I do. So my left and level last Friday was two or
less than two, the cutoff was two. So I have a low level of leptin level last Friday was two, or less than two, the cutoff was two.
So I have a low level of leptin.
So if you gave me enough leptin
to raise my serum levels to levels
that I rarely see clinically,
like when I check leptin levels on patients,
which I always do,
I always wanna see leptin, I wanna see adipinectin,
I wanna see insulin, I wanna see nepha, FFA, et cetera.
It's very unusual that I'll see a leptin level, even in an overweight patient,
more than about 40 or 50.
So if you took me and you gave me that much leptin,
do you think it would regulate or depress my appetite in any way?
Well, first of all, your leptin is low now because you're not eating.
So oh, this is even, this is back when I was eating too.
Right.
So leptin is very highly correlated with body fat at any level of body fat if you
stop eating if you restrict calories the level of leptin will drop within what period of time.
Within 12 18 hours it'll drop by 50% or so if we check a leptin level on a patient in the morning
following a 12 hour fast we can assume that that's about half what their fed leptin level on a patient in the morning following a 12 hour fast we can assume that that's about half what their fed left it depends on what they've been
eating 12 may be a little short in that context so to be safe I would say 24
okay but it'll start down within 12 hours so a 12 hour fast will give you a
leptin level which is not what it would be if you were to draw it when the
patient is so let's say my fed level is two or three or four.
My fasting level is less than two.
If you inject me with an F leptin such that,
let's just say my level was now 100.
The level that you would see in the highest
fed obese patient, what would that do to me?
Based on the studies that have been done,
the so-called leptin trial, not very much.
So interesting.
You might have some, at least in some of these individuals, there was some reduction in body weight, but not very significant.
Through the mechanism of reducing intake?
Yeah, primarily, apparently, yes.
Although there weren't detailed formal studies of food intake done in those experiments.
Now, going back to the DBs, who obviously have in many ways a worse problem, earlier you alluded to
Prader-Willie. What is the genetic defect in Prader-Willie? And what's the phenotype?
So Prader-Willie is a genetic disorder in which rather than having a single gene affected,
there is a region of the genome which is in most instances not all, but the majority of instances
deleted. So there's a region of chromosome 15 in which there is a large deletion that is a region that has normally 20 or so genes in it.
And when deleted, when the paternal, the father's copy of this interval is deleted,
the individual becomes, has a very characteristic phenotype.
The maternal, the mother's copy, is not expressed. This is called an imprinted region of the genome, which again for technical reasons. The only one
chromosome expresses the genes from that interval. And in the Prater-Willie region, the maternal
genes are silenced. So they're there, but they're not expressed. And if you'd say... The mom could be a silent carrier.
The mom could be a silent carrier is not the right term.
Almost all of these individuals are,
it's all of these individuals are the result of spontaneous
deletions that occur after conception.
So it's not trans-ho- Genic and you can have, so the one
example that is in my world that I
get is familial hypercholestralemia.
It's a phenotypic description. There
are at least 2,000 known mutations,
distinct mutations, that can produce
the same phenotype. So in that case, no
one really, I don't want to say nobody
cares, but it's a lot less interesting to try to map out each and every one of the genes
that can lead to familial hypercholestralemia. It's more important to understand the phenotype
and how to treat it. I'm guessing Praetor-Willey is not quite that diverse, but is it safe
to say if I'm understanding correctly that you could have two patients with Praetor-Willey
that will have different genes.
There are rare instances of Prairie or Willie in which the number of genes
deleted rather than being that large interval that I mentioned include only
three genes, but they're still in the region which is deleted in the large
deletion patients. So they're necessary and sufficient genes?
We think that those, that smaller region probably has the necessary and sufficient genes,
although again there's debate in the field about this.
The children though who are affected with this disorder have very characteristic phenotypes.
They actually don't grow well, they don't feed well early in life, they actually
have failure to thrive.
They don't, they're floppy and hard to feed and not very responsive in terms of ingestive
behaviors.
And then again for reasons that are entirely unknown at this point, between the ages of four,
five, three years of age, they become
hyperfagic.
They again, drive to eat becomes very, very strong.
These are some of the most tragic stories I've ever heard.
These children, who I've never taken, I'm not a pediatrician, so I've never taken care
of them, but I've talked to parents of children.
They have to lock the refrigerators.
I even had one parent tell me that they actually have
to lock the bathroom because the child is so hungry,
so hyperphasic that he would go into the bathroom
to try to eat out of the toilet.
It's true that in the majority of instances,
these children require very close scrutiny
of their access to food.
And in many instances, parents or the caretakers
have to resort to locking up whatever food is in the what otherwise be available to the
children. But I think it's important to point out that there are ways of managing this
disorder, which has other characteristics. There are many endocrine disturbances that go along with it,
including actually growth hormone deficiency,
and administration of growth hormone to these children
and various other interventions that require
a great deal of parental attention.
No doubt about that.
Some of the severity of the disease is manageable
at a clinical level,
with very high levels of scrutiny by the people who are taking care of them, so that not all
children with preterwillie will necessarily become hugely obese or suffer the consequences of
severe obesity. This is one of those things where I hope I know there are folks out there trying to
raise money to do clinical trials in this because
Anacdotally again, there are these very interesting stories the first I ever heard of this was probably four years ago
I was giving a talk. I don't even remember where it was it was in Chicago, but I can't even recall the audience, but afterwards
A woman came up to me and I was giving a talk about I don't know longevity like it wasn't an obesity
to me and I was giving a talk about, I don't know, longevity, like it wasn't an obesity specific talk or anything like that.
But a woman came up to me and introduced herself and said her son had prayed her willy
and, you know, was going off the rails, etc. and at about the age of seven or eight, she
put him on a ketogenic diet.
And it corrected the phenotype, including the cognitive developmental part, which often
accompanies this.
She then, I guess, since that time had formed
kind of a support group, and you had more and more
of these parents that were putting their
Prader-Willie kids onto ketogenic diets.
Again, it's very difficult to draw much of a conclusion
when you don't have controlled data,
and you have obviously the selection biases
that go into these things, but it struck me
as very interesting.
Do the Prater-Willie kids,
are they hyperinslinemic?
They are hyperinslinemic to the level
that would be anticipated based on their degree
of adiposity.
And in some research that we've done very recently
using some of the stem cell techniques,
or at least using stem cells that I alluded to much earlier, we've got some evidence that
suggests that one of the major consequences of deleting this region of the chromosome chromosome 15 by mechanisms that are somewhat complicated,
influence the expression of an enzyme called proconvertase 1.
And this enzyme is critical for the processing of many of the hormones
and neuropeptides that are made in the body.
They virtually all hormones and neuroropeptides are made as pro
hormones, that is precursor hormones, that are then processed by proconvertase 1. And that
is what produces or generates the mature form of the hormone or neuropeptide. And we
think actually that the phenotype, many of the phenotypes of the Praetor-Willie patients
may in fact be due to a deficiency or underactivity of proconvertase 1, which is not in the interval
where this deletion occurs, but is influenced downstream by one or another of the genes in
that interval.
And it's relevant in the question of insulin
because insulin is processed by proconvertase.
So some of the...
That's where the CPAPTOD gets cleaved out of the pre-hormone.
That's correct. So some of the hyperinsulinemia
of the Praetor-Willi might be proinsulin.
And insulin has biological activity
but much lower than native insulin. And insulin, pro insulin has biological activity, but much lower than native insulin.
And so if this turns out to be the case, then it might be possible to rectify some of the
Prada-Willie phenotypes by being able to increase the activity of pro convertase one
pharmacologically or by other means. So there's all this incredible work, all this incredible molecular biology and molecular
genetics that's identified, leptin deficiency, leptoreceptor deficiencies, the cluster of
defects that lead to Prader-Willie.
And yet the question is, how much do these things tell us about the more broad condition
of obesity that afflicts,
I don't even know the stats,
I don't really keep track of this stuff anymore,
but I don't know what,
a third of Americans are probably obese now.
So I'll tell you, an interesting perspective
on that question, as I mentioned it earlier,
while we were doing the efforts to clone these genes,
I was studying
patients in the clinical research center with Jules Hirsch, Mike Rosenbaum,
longstanding associates. And what we were doing is looking at the metabolic
consequences of weight reduction and showing that if you reduce the body weight
of a human by 10%, 20%, you get a reduction in energy expenditure, which is greater than what you would
predict from the loss of just body size. In other words, their metabolic rate didn't reduce
just to support the new reduced weight. It reduced even further, which would almost try to return
them to a heavier weight. Right. So they had a disproportionate reduction in energy expenditure and some of the data suggested
that the major change in energy expenditure was not in resting metabolic rate, but in
the energy cost of low levels of physical activity, of muscle work, so to speak, but at
very low levels of activity.
And we went on to show that, as you would expect, based on a lot of what we've been talking
about, the leptin levels were low in these individuals, low but proportional to the reduced
amount of body fat.
So one hypothesis that we had is that this reduction in energy expenditure was in fact a
reflection of the fact that the body was sensing the reduction in energy expenditure was in fact a reflection of the fact that
the body was sensing the reduction in low in leptin and interpreting that as a starvation
state. That is, for that individual, that new lower body weight represented a threat, if
you will, to survival or reproduction. And we've done experiments subsequently in which
we've injected leptin into those individuals.
None of them has a genetic vision of leptin juice.
It just weight-reduced normal individuals.
We've put leptin back into them by injection
to raise the blood level back to where it was
before they lost their body weight.
So these are very low doses of leptin.
And that intervention will restore their energy expenditure
back to where it was before they lost the body weight,
even though they're now still maintaining the lower body weight.
So put this in some quantitative terms for me.
That infusion of lepnen gave them
how many more cake hell per day in energy expenditure,
all things equal between movement activity, et cetera.
We're talking about 100 K-cal a day,
like what kind of a delta are you producing?
Two or three hundred, because these are big people to start with.
And that's a huge delta.
Right.
And we could show that that effect is primarily
being conveyed through skeletal muscle.
So what happens is that the muscle becomes less efficient if you want to think about it that way
after the left in administration.
So there are two ways that we broadly in the research setting measure energy expenditure,
indirect calorimetry and doubly labeled water.
Can you spend a second explaining each of those?
So indirect calorimetry is really classical physics, if you will,
in which the rate of oxygen consumption and the rate of carbon dioxide are measured in a number of ways.
The most frequent is to put a mask or hood over the head of the individual in whom the measurement
is made and simply use gas sensors and flow meters to quantify the amount of oxygen consumed
and CO2 released.
And from that information, one can quite easily calculate how many K-cals of energy are
being expended to correlate, if you will, to account for the
amount of oxygen consumed in the CO2 produced.
And by looking at the ratio of those two, one can even get an indication of the kind of
fuel that's being burned to support the metabolic rate.
So the V and the bell just spitted out, so can, if they're, when we'll link to all
of this stuff, but the RQ or the respiratory quotient is the ratio of CO2 produced or VCO2
divided by the amount of oxygen consumed or the V02.
And that'll vary sort of between, you know, typically about 0.7 and 1, right?
Correct.
You can see it outside of those ranges.
The lower it is, the more they're partitioning
and drawing from fat.
The higher it is, the more they're drawing from glycogen.
Correct.
And if I still remember my weird coefficients,
energy expenditure is something to the effect
of 3.94 times the VO2 plus 1.11 times the VCO2.
Your memory is better than mine, but I can't recite
you the weird way, you know, top of my head. Well, your memory's better than mine, but I can't recite you
the weird equation off top of my head.
You know, it's really funny.
About five years ago, I asked Kevin Hall to send me
the derivation of it, and it was so great to get this page,
two pages of differential equations.
So I could go through and actually see how the weird
coefficients were described, which of course then led
to the inevitable question that you and I have talked about in the past, were described, which of course then led to the inevitable question
that you and I have talked about in the past,
which is, do those coefficients hold
in the presence of radical dietary change,
such as a very, very low-fat, high carbohydrate diet
or the opposite?
So then, if that's how indirect calorimetry works,
and of course, by the way, these things happen
in metabolic chambers, that's the ultimate way to do it,
where you can put a person into a room and the room
itself has all of these sensors embedded in it. Right. And that it's exactly the same principle,
but they're the individuals not restricted in terms of their motion other than in the room
that they're in. So you can get exactly the same information, but over much longer period of time.
I mean, you can do it for days. There was a point when I wanted to build one of these at my home.
I was so obsessed with knowing every...
I wanted to know, like, my VO2 and VCO2 almost every minute of the day.
And then I found out I would cost at least 5 million to build one and realized I couldn't
build one, but I thought, boy, if I ever make enough money to build one of those, that's
a great fun.
That's like, that's fun for the whole family, if you really stop to think about
it.
I mean, who wouldn't want to go sit in the metabolic chamber on the weekend just kicking
it, watching football?
We just built one of these actually at Columbia and it's quite a, you're right, it's not only
expensive, but requires a great deal of attention to things like leaks and air flow and you know,
I broke one once doing what?
So you'll recall I used to spend time in these chambers and I guess I exceeded the level
of CO2 production that it was sort of calibrated for because I was on my bicycle and I was riding
pretty vigorously and the CO2 sensor broke and it's one of those things where you don't get a big red flag.
It was just after the fact that data didn't make sense.
And this is where you appreciate what you're saying,
which is the engineering in this thing is amazing.
And so you got to pour through,
the longest spreadsheets in the world
to start to look for where the mistakes are.
But it's really beautiful stuff.
And there's not many of these in the country.
Like there's obviously Colombia has some NIH,
has some TRI, has some pennington, has some baler,
has some, I mean, not many.
Like you said, the tricky to construct
and require high level of attention
to their maintenance and operation.
It's not just like going down in your basement
and measuring your RQ, though. So how does doubly labeled water work, which I also have had the privilege of ingesting?
So doubly labeled water is a technique which uses two isotopes of water, which is H2O.
In one, the oxygen is a heavier version of the normal or the more prevalent oxygen molecule.
And the other, the hydrogen is a heavy atom, as opposed to the more prevalent kind of hydrogen
in the environment.
And what you do is you can give these as a mixture.
You have to know exactly how much of each one you've given, but you can give these as a mixture. You have to know exactly how much of each one you've given,
but you can give this as a drink, basically,
of what amounts to heavy isotope labeled water.
And then look at the relative concentration
of these two isotopes.
You can do it in blood, you can do it in urine,
we often do it in both.
And the difference in the rate of excretion of the so-called O18 water, the heavy isotope
of water, which is oxygen is born out both in urine, but also in the expired air of an
individual, it as carbon dioxide, and the H2O, which comes out by non-respiratory
means, you can actually get a measure of how much CO2 the individual is producing, and
you can use that and the nature of the diet that the individual is on to back calculate from what would be the RQ back to the
consumption.
So you would use the FQ, basically.
Yes, correct.
So the FQ is if you stuck the person's food into a bomb calorimeter, burned it, that
would produce the RQ.
So the limitation of this is a couple of things.
One, the patient's got to be weight stable, right? This starts to fall
flat when they're losing or gaining tremendous amounts of weight. And two, you have to prep a pretty
darn good idea what they're eating. So each of these methods, ingenious and completely distinct,
both have huge limitations. The former, of course, requires an artificial environment. They don't
get to be free living, and you can't really study them for that long.
But the latter, where they can be free living, and you can study them for two weeks at a time with a single ingestion of the doubly labeled water,
you better make sure that they're not gaining in losing weight, and you better make sure you know exactly what they're reading.
And in an ideal world, it better be the same thing almost every day, right? And in general, because of the issues that you just mentioned, I think most investigators in this field prefer,
at least in terms of its nominal accuracy, the room calorimeter over the doubly labeled water,
but the doubly labeled water does have the virtue,
as you pointed out, of being applicable over much longer periods of time so that you can
get integrated idea of how much energy an individual is expending over literally days or even
weeks. What's sometimes done is to redose the individual at some point in the experiment and simply continue it.
When I did this, I did several days in several chambers and then separately did the LW.
I was kind of amazed at how closely they overlapped. Of course, it was hard to replicate my chamber
activity in the real world because there's so much more movement outside of the chamber,
but they were surprisingly in line, which is interesting because at the time I was on the ketogenic
diet, which there's a lot of things that could be changing there. So, I want to go back to something
that we kind of got into a little bit, but to me it's one of the most fascinating discussions slash debates, which is the idea of appetite being
regulated centrally versus peripherally.
And you and I have had some incredible dinners having these discussions.
And I've always found your perspectives to be interesting because I think few people
are more qualified to talk about that in that they know so much about
both.
I mean, in many ways, leptin at its inception was really viewed as a peripheral way to
regulate appetite.
So let me explain what I mean by that for the listener.
When you're hungry, is this all being driven by what your brain is saying?
Is it possible that somewhere outside of the brain,
which we refer to as the periphery, your liver, your fat cells, your muscles, the level of blood
glucose that's circulating, is there some other signal? It's kind of interesting that
here we are in the year 2018, and it's still not entirely clear where appetite is regulated.
clear where appetite is regulated. So how has your thinking on this topic evolved through your own immense knowledge of both the central and peripheral components of
appetite? You want to take a sip of that Topotchiko before you try to answer that?
For the listener, I've introduced Rudy to Topotchiko today, so he's one sip into it,
he declared that the finest bottled water. I would describe the system from high altitude as the following.
That there are CNS, central nervous system mechanisms.
They're not all in the hypothalamus, but many of them are, and many of those that aren't
do interact with the hypothalamus, and that that can be regarded, that organ or set of cells can be regarded as
the integrating center for basically the reception of signals that are of relevance to how an
organism ought to respond to its environment in terms of food intake and also for control of some of the aspects of energy
expenditure that are not necessarily under voluntary control, such as autonomic nervous system.
And what's coming into that system is, I think, broader than we had originally anticipated.
So clearly, Lepton is an example of a hormone
that's secreted from adipose tissue,
but there are many other peptides,
actually, or hormones that come out of adipose tissue.
There are neural signals that are now being identified.
That is nerve-borne signals that look like they're coming
out of and going into adipose tissue
that may be playing a much more important role than we had sort of previously appreciated.
The gastrointestinal track, which for obvious reasons, is a very relevant aspect of the system,
originally was, I think, regarded pretty much the way that adipose tissue was. It's a tube that absorbed your calories and didn't really participate actively in the
regulation of that aspect of biology.
Clearly, the advent of various surgeries for control of body weight have indicated that
that sort of premise is incorrect.
That is that there are very powerful influences of the gastrointestinal track, which are brought out by some of the
surgeries that are done. And it's now very clear that the gastrointestinal track, at many
levels, is communicating with the brain, both by products that it secretes and by direct neural input, probably primarily,
but not entirely by the vagus nerve into the brainstem
and then further up into the brain.
So just taking that as a sort of very broad picture,
it's much clearer now that there is no sort of single definitive part of the biology of
an individual which is dictating this very complex system.
It's really a product of the interaction of these peripheral signals as you refer to
them, including metabolites such as glucose and free fatty acids and so forth and the central nervous system,
not just the hypothalamus but areas of like the brain stem, the amygdala, the frontal cortex,
there's many other areas of the brain that interact with these signals to influence both the
behaviors and the unconscious, if you will, the vegetative responses that ultimately go into the regulation of body weight.
So I think it's obviously a very complex and over-determined system, and it's as complex as it is. But I think what it clearly does is it introduces all sorts of possibilities for mischief with
regard to body weight regulation, starting in the frontal cortex where decisions are made,
at least with regard to some aspects of this, all the way down into the colon where you've
got large numbers of bacteria that are producing things,
metabolites and
molecules themselves that again we're only just beginning to understand.
So we're not only talking about a regulatory system that has all of these elements,
but a bunch of organisms literally living within us that are influencing it in ways that I don't think we've really
fully understood. The miracle is actually when you think about all the ways that it could go wrong, that it doesn't go
wrong any more than it actually does. And it looks to me like the major problem in terms of the obesity
that you referred to earlier that's increasing has to do a great deal with the environment and what people are being exposed to.
That's very novel with regard to the system. I mean this system was not designed for the regulation of metabolism and body weight in an environment in which with a cell, you can bring literally as many calories as you want
into your living room without getting up off your behind.
So we're dealing with an organism which has its very complex
and beautiful system designed to regulate various aspects
of the biology which is now in an environment which is entirely
at least in many
regards, novel to the system.
And it fails in the sense that there's a lot more obesity than there was prior to the
environment that we've been able to create.
But it's not totally dysregulated.
I think people are just now regulating their body weight
at somewhat higher levels than they were in other circumstances.
Again, I don't follow the statistics.
I'm just not something I'm paying huge attention to.
But are the rates of obesity plateauing
or are they still increasing?
Or is it the curve concave up or concave down?
So several years ago, it looked like the rates
were either slowing down or level.
Now it looks like maybe they're continuing to inch up,
but not as rapidly as they were, say a decade ago.
So there's been some relenting of the rate of increase,
excuse me, an obesity in both adults and children, but it looks like
it's still rising, although at a lower rate.
Do you have concern that there are epigenetic implications of this, that 10,000 years ago,
the prevalence of obesity, again, largely probably driven by the environment that made it
pretty hard to become obese.
Not just in terms of food availability
in terms of absolute calories,
but presumably the types of calories that were available.
I mean, I think my recollection is that 10,000 years ago,
nothing came in a package, right?
As far as we know.
So we didn't have pop tarts,
we didn't have breakfast cereal, we didn't have orange juice, we didn't have pop tarts, we didn't have breakfast cereal, we didn't have orange juice,
we didn't have french fries and whatever else are the culprit potentials.
So if Johnny got a set of genes that were slightly suboptimal, Johnny Jr. probably got
some of those suboptimal genes, but there was nothing being imprinted on the genome that was being transmitted
to generations.
And I mean, what do you think about this idea that we could be reaching kind of a dangerous
point in the evolution of our species where children, maybe during critical windows of development,
if exposed to, you know, again, in my opinion, it's probably a lot of the sort
of really highly refined crap, high amounts of fructose that we're seeing with the Nafel D,
that this is setting them up for a real problem later in life. It's going to make it a lot
harder, not just for them to lose weight one day, but also for their offspring. Is there
any evidence of that. I think there is evidence that's, I'm not so sure I would use the term imprinting.
That has sort of specific biological meaning and implications.
I mean, we could talk about that in a minute, but if what you're saying is, are there perhaps
critical periods of development in a child,
in which if the child is caused to become more obese,
then he or she might be in some other environment
that that will leave a mark on the regulatory system
that will then cause that individual
to want to sustain or maintain a higher body weight.
I think the answer is probably, or at least possibly, yes.
That is that there may be critical periods in human development.
Certainly, I think the data are also available to some extent
in animal studies that suggest that if you manipulate body weight or some of these systems
at critical periods of development, you end up with an animal which is more likely to
be obese as an adult than if you hadn't done that.
And exactly what the molecular and neuroanatomical or other physiological consequences of that manipulation are that lead to the
maintenance of a higher body weight. This is obviously a critical area of study. It's actually
something that people in my lab are quite interested in. That is whether we can impose
by dietary or other manipulations a higher body weight or a higher
sustained body weight in an animal by early manipulations either by diet or endocrine
manipulations.
And I think the answer is probably yes, but what is the consequence of that in terms
of the regulatory elements that we were talking about, we don't
yet know.
Another aspect or another perspective on this is the following question.
If you manipulate the metabolism of a pregnant animal or human, what are the consequences
of that on the developing brain or physiology of the fetus?
I mean, there's evidence now that a mother who is hyperinsulinemic or has gestational diabetes
is increasing the child's risk of obesity. Is that not the case? There are data that suggests that
it's registry data, so it's hard to know. Right. But that obesity in a pregnant woman does confer by, again, by mechanisms that we don't
understand, higher risk of obesity in her offspring.
Although, I'd love to see it stratified by a hyperinsolennemic versus nonhyperinsolennemic
obesity, because I feel like I remember reading that it also seems to be dependent on the gestational
stage.
In other words, when the dorsal and ventral buds of the pancreas are forming, which I can't
even remember when that is, maybe weeks, seven, eight, nine, something like that, those
are very critical windows, right?
That's when eyelid cell formation is taking place.
And nutrient exposure or insulin exposure during that period of time could have a more
profound effect than say late in the third trimester where perhaps it's not as effective. Again,
I don't follow this literature, so I don't want it to sound like a complete moron.
And the last time I really paid attention to this stuff was probably four years ago, and it was
again largely registry-based data, so very difficult to know cause versus effect.
Again, the literature, as you sort of implied, is wobbly on this point, but I'll just tell you
about a couple of experiments, actually, that we've done one to answer to address this question of
hyperinsulinemia in a dam, in a pregnant animal, and its effects on the
fetus. We were able to do an experiment in which we were interested in separating the
issue of high body weight and atoposity from the effect of insulin itself. And so we actually
used a genetic model of hyperinsulinemia and were able to make the dams
hyperinsulinemic without being obese. So these are perfectly normal body weight dams that were very
hyperinsulinemic and the pups that they were carrying. Some of those pups had no abnormality of
any insulin-related genes. So they were what we would call wild-type pups being incubated
in a hyperinsulinemic dam.
And we were very interested to see what the consequences would be
on the metabolism and body weight of these animals.
And very interestingly, these animals showed transient elevations
of body weight and body fat when they were in what I guess we would describe as
adolescent period of a mouse which tended to revert back to normal over time. You could definitely see
an effect in the body weight and metabolism of the mouse, but it appeared to be transient.
And to be clear, the mother was euglycemic?
The mother was euglycemic.
Euglycemic, but hyper-insulent.
That's a tough needle to thread, my friend.
Yes.
So again, it's the power of genetics, so we could do that.
So these kind of experiments, we also looked at the brains of these animals,
and there were some very subtle differences in the way the hypothalamic cells,
the numbers of different types of hypothalamic cells, the numbers of different types of hypothalamic cells, which suggested in sort of support of the inference of your implication of your question,
there are consequences of these metabolic states of the dam that can influence the subsequent
development of the pup. Even if the pup doesn't have the genetic ideology that led to the
derangement, if you want to call it that, and the dam. We've more recently been doing some experiments
along these lines looking at leptin in a similar way, and again, can see evidence of influence,
long-term influence, of manipulations of leptin in this way, which again suggests that these transient periods of exposure
at various levels or various periods of development can have long-term consequences for organisms
that don't themselves have any primary abnormality of these genes or their functions.
So I think this probably supports the notion that there are things going
on in the environment that are not reversible once the environment is necessarily reversed.
That is, the exposure to the environment may change the biology in such a way that even when
the insult, if you want to call it that, is removed. The biology is permanently impacted.
We've spent a long time talking about low carbohydrate diets.
You were part of one of the studies that was funded by a newsy.
And while the study that you were a major part of was not a diet study, so I wasn't really
looking at diets, it used diets as a tool to ask questions.
Clinically we know that low carbohydrate diets are very effective. I think it would be very
difficult for people to dispute that at this point in time.
Interesting question, if you're Rudy Leibol, is why? What do you think? Why do these
diets seem so effective for so many people? Let's not even get into the fancy stuff about the diabetes reversal and stuff like that,
where I think the results are especially pronounced, but just in terms of obesity reduction.
Why do you think these things work?
I guess my view of this is that to the extent that diet composition has an effect on body weight, which clearly it can, that this is the result of the interaction
of the components of the diet with aspects of the regulatory control of food intake.
And I guess the way I described this is the sort of hedonic aspects of the food that's being ingested will influence
the drive to ingest that particular food.
I think individuals differ in terms of their sensitivity or susceptibility to diets of
different composition.
And there clearly are some individuals who, when fed or offered or imposed diets that have pretty radical compositional differences will respond very well.
In other words, there are people who respond well to high carb diets, there are that it's primarily some aspect of the hedonics of these diets,
if you want to call it that, that's driving the favorable response.
I know, and I'm sure you and I have discussed this many, many times, there are individuals
who view the diet composition as having, in addition to what effects I just described, also an impact
on energy homeostasis itself, meaning that the composition of the diet can influence the
degree of caloric expenditure per unit of calories ingested. I'm not a sort of strong proponent
of that view. I guess I try to remain agnostic about it, but my
bias, if you want to call it that, from my experience, is that that's right. Diet composition
can have an effect on body weight. It doesn't do so by effects primarily, or maybe at all, on energy
expenditure per se, but can have pretty striking effects
on an individual's desire to eat those calories delivered
in that form.
And so there's two ways to think about that, right?
Again, if you leave the energy expenditure side away,
on the intake side, is it the case
that a low carbohydrate diet, as you say,
it's purely a hedonic issue, people just,
when they're on these diets, they're just not as hungry because, I don't know,
the food is not as diverse or not as palatable.
An alternative viewpoint is they eat a lot less because they're eating themselves more.
In other words, the way I try to explain this to my patients when we're talking about nutrition
is you want a differentiate between exogenous and endogenous calories.
So most people walk around if they're weight stable, purely subsiding and endogenous calories. So, you know, most people walk around
if they're weight stable, purely subsiding on exogenous calories. But if you want to lose weight by
definition, you must start to consume endogenous calories. You have to start eating yourself.
And this gets back to the question of the regulation of body weight peripherally if you are eating yourself can the CNS figure that out and say hey
We've got all this like policies going on. We've we're liberating all of this fat out of a fat cell
That's energy fantastic. I will
Program the system you need less exogenously
So those are two kind of very different ideas, right?
The one is just hey this food is boring and doesn't taste great.
I'm just going to eat less of it.
Personally, I don't find that theory as appealing because having worked with so many patients
that do this, if that were the case, I'd suspect they'd be more hungry.
But yet, they don't seem to be very hungry, which is, I think for most people, the only thing
that's intolerable over long periods of time is hunger.
You look back at the Ansel Keys starvation experiments.
Those guys weren't really like, you know, what they were eating, like what, maybe 1600
calories a day, but they were losing their minds.
These guys lost their minds on 1600 calories per day.
So, starvation is clearly an unacceptable state in the long run. I gotta be honest with
you, I'm glad I don't work on this problem. I'm much more interested in just trying to figure
out this other easy problem of longevity. But this obesity thing is a real bear. Because
at the same time, as much success as I've seen for people on low carbohydrate diets, I also
know that they don't work for everybody. And therein lies the challenge of why?
Why would something...
I mean, again, it's a naive question in the sense that you've just spent the last two
hours explaining some of the most complex biology of obesity.
Why should everyone respond to the same treatment?
But it does.
It really frustrates me that there are certain patients in which,
no matter what one does, or no matter what they do. I think patients that try really, really hard
and can't lose weight, I find that to be a very frustrating clinical problem.
So, I guess maybe I should rephrase the way I answered your question, and that is to say that I believe that the composition of the diet can influence aspects of
ingestive behavior. I
Emphasize the hedonic aspect, but I'm certainly open to the possibility that if you feed a diet of
you know divergent
composition, you will definitely have some influence.
I mean, this is well documented on the substrates that are in the circulation as a result of
feeding that diet.
Those substrates themselves metabolize, you were mentioning fatty acid, but many other
things change.
May themselves have a effect on the drive to eat.
I'm sympathetic to that idea.
Exactly in any given individual who does or doesn't respond to a specific diet,
which of the mechanisms,
whether it's occurring at the level of the taste of the diet or some of the metabolic consequences of the diet, I would say to the extent that
somebody is successful in losing weight on that diet, A, they have to be a negative energy
balance. That is, there's no way that they can eat the number of calories that they're
expending and lose weight. So they need to be a negative energy balance. And, I mean,
that's just a given. And then the mechanism by which the diet composition influences the success of their ability
to sustain a hypochaloric state, which as you pointed out, is uncomfortable.
From open to the possibility that it could be at any level of the sort of neural circuitry
that regulates food intake.
It could be very proximal in terms of taste aspects, but it could also be some of the mechanisms
that you mention.
I think that's perfectly reasonable.
How that works, as you pointed out, is a tough nut to figure out.
And I think, like you said, there are individuals
who respond very well to diets of quite divergent composition,
but they have to be taking less calories than they are spending.
Right, and that's an easy thing to do mathematically.
It's a very hard thing to do clinically, because again,
I think patients can tolerate a lot,
but I don't think people
can tolerate hunger for very long.
I think to ask somebody to be constantly hungry is a losing proposition, and that's why
I believe clinically low carbohydrate diets seem to be more satiating.
And again, whether they're satiating because of something in their composition or whether
they're just satiating because you end up eating more of yourself.
I mean, I've seen lots of patients who, and this has even been published, who on 16,
1700 calories a day of a ketogenic diet seemed completely fine, and yet, Ansel Keese's
patients at 1,400, 1,500, 1,600 calories of basically very high carbohydrate diet, very
low fat diets, lost
their minds.
What did you believe 10 years ago that you don't believe today to be true?
I think over the past decade, the field of the sort of neuroscience of body weight regulation
or ingested behavior and energy expenditure has expanded the role of other elements in the
central nervous system beyond what began as our very intense focus on the hypothalamus.
Partly, that's historical, and for reasons having to do with the tractability of some of the
cell types and mechanisms in the hypothalamus. but I would say the biggest change in my thinking about this has been that these
superhypothelamic
aspects of the central nervous system again starting with the cortex and working down have a
much stronger, I think, ultimate impact on this regulatory system than the way I perceived it a
Decade ago. And what this does is it the way I perceived it a decade ago.
And what this does is it opens up, I think, a lot of very interesting aspects of the biology
that maybe we weren't either capable of or didn't focus on adequately, part of which actually
is in response to the point you were just raising.
That is, what is the effect of die composition on hunger and so forth. It's
almost certainly an aspect of this sort of view of the broader central nervous system impact on
ingested behavior than just the hypothalamus you know my
mentor Jules Hirsch, I think who unfortunately passed away three years ago. He would agree with this.
I mean, he always, I think, was suspicious of focusing,
you know, slavishly, if you will, on the hypothalamus as the center
for all of this. He always, I think, had a much broader perspective
on some of the psycho-effective aspects as he would describe him of ingestive
behavior. And I think he would see the sort of flowering of broader view of some of these regulatory
aspects of food intake to other parts of the central nervous system. He would say,
I told you so. And he was right. I think he's looking down at you saying that. Yeah, he's probably saying love other stuff too.
If we get way of a magic wand and not only were resources unlimited, but more importantly,
any of the technical considerations that make this type of study challenging were just
humiliated, what's the dream experiment you would want to do? If you got one more shot at this,
you could spend the rest of your career
doing a dream experiment with infinite resources,
infinite subject participation, screw the ethics,
there's no IRB, you've got a bunch of clones out of Westworld,
you can do whatever the hell you want,
what experiment do you want to do?
To once, to take your final kick at this problem.
There is a gene that was identified now 10, 12 years ago.
FTO?
Yes.
You tested me for this?
Yes.
I was negative.
Right.
It was identified by Mark McCarthy and some other investigators in Great Britain as sending the strongest
genetic signal for obesity or elevated body fat, not severe effect, but the strongest
statistical signal ever detected in humans.
It remains the same.
The prevalence of the variants that are associated with higher body fat are very high in the general
population. So there are a lot of these variants that are of this gene that are contributing to
human obesity, not of the severity, certainly of the OB or the monocortin IV receptor.
There are various schools of thought about how this gene is doing it. The interesting
thing is that the variation in the gene that is conferring the risk of obesity is variation
in what we call non-coding part of the genome. So as people will know, a small fraction of
the genome, 2 or 3 percent actually encodes the proteins that are made that we've been
talking about actually.
The rest of it is regulatory parts and elements that we don't understand very well.
The variants that are implicated for the FTO gene actually are in the non-coding region.
We know exactly where they are.
It's not a mystery where they are, but they're
in non-coding. They're in the first intron, so to speak, of this chain. The mechanism by which
this very, very common variant leads to subtle increases in body fatness, in a large number of
individuals, to me, this is a very intriguing question.
There are some that view the effect as being conveyed through what's called browning
of adipose tissue, increasing the energy expenditure of adipose tissue.
There are others like myself who think it's affecting central nervous system circuits
that affect food intake, but the mechanism, at least in terms of the central nervous system, is really unknown.
The primary phenotype that's seen in these individuals who do or don't have the, what we call the risk variance, is food intake.
I mean, if you measure their food intake very carefully in a lab, you can see that the individuals with the variants will eat slightly
more. They actually may have a slight preference for fatier, higher fat foods than individuals
who don't, but what exactly is going on in the central nervous system is not clear. They
have actually, in one study, pretty characteristic, functional magnetic resonance imaging differences among
individuals who do or don't have this variant, but the mechanism is unknown.
This is something which has intrigued me now for eight or ten years.
That's the experiment I would love to do.
I mean, we're actually trying to do it.
Tell me specifically what the actual experiment is.
But before you do that, I want to make sure I'm, and this is going to be an oversimplified analogy, but what you're basically
saying is there's a genetic marker effectively that creates or identifies those who are predisposed
in a high nutrient environment to overeat. So even though our ancestors would have had these
genes, the reason, or never mind our ancestors, even though 100 years would have had these genes, the reason, or it never mind our ancestors, even though a hundred years ago or 50 years ago this gene still existed probably at the same prevalence,
you didn't have the food environment to poor fuel on that fire.
Now, just to push back a little bit, isn't that sort of like saying,
we've got all these people getting lung cancer. It only started when they started smoking,
and you know, only one in ten of these smokers are getting lung cancer, it only started when they started smoking. And you know, only one in 10 of these smokers are getting lung cancer.
There's a gene that might be predisposing them to lung cancer.
So you're basically saying, I want to look at the problem of
why are certain people susceptible to an environmental trigger?
Versus what's the environmental trigger.
In the case of smoking, it was so obvious.
It was the goddamn cigarettes. In the case of smoking, it was so obvious. It was the goddamn cigarettes.
In the case of obesity, it's a little more complicated.
Correct.
So what's the experiment you would do?
So the experiment that I would do,
and actually we're trying to do these now,
is to actually look in animals in whom the variance
of the genes that we think are affected by this,
even though the intronic region is not encoding anything,
we think it's affecting genes that do encode something,
and we think we know at least what one of those genes is,
and what I would like to see is what the consequences
of these variants are on the functional activity of the system that we think is mediating the effects of these genes.
Because, again, for reasons that are quite technical, I think that one of the major impacts of this gene, or these variants in this gene, is actually on the structure of the nervous system.
So I think their impact is occurring early
in the development of the brain.
And that what it's doing is changing the circuitry slightly
in a very maybe subtle way, probably subtle way,
that favors the increased food intake that you just described.
And the implication of this is very relevant to some of the things we were just talking about earlier.
That is, can the environment impose permanent signatures on the feeding circuits, so to speak?
And this is, I think, a prime candidate in that regard. permanent signatures on the feeding circuits, so to speak.
And this is, I think, a prime candidate in that regard.
And the virtue of the FTO study that we've been talking about
is that we know at least enough about the genetics
and some of the mechanisms that we can design the experiments
primarily, but not totally, in mice, to be able to look
precisely at where the changes are occurring. We now just coming online or the tools to look at
the circuits as they are acting physiologically. We can activate these circuits in the brain of an animal by using various neurophysiological and
neurogenetic techniques that will, I think, permit us to see where the
structural consequences of these variants reside. And my guess is that that
would give us an insight into the sort of prevalent genetic susceptibility
or one of the prevalent genetics.
What would we do with that information?
Let's assume you had all of that information.
How does that take obesity from 35% to 5%?
Well, you're asking somebody who is not an epidemiologist
and you know, some of us do what we know how to do
or what we have to do.
You're a hammer, you look for a nail. You're a hammer, or what we have to do. I have a hammer you look for now.
I have a real look for nails.
So I'm a hammer looking for the nail of whether or not
I can show a gene which alters the structure
of the central nervous system in a developing organism
in such a way as to make it susceptible to the environment.
The animals that we have studied
where we've manipulated this gene
definitely are sensitive to the environment in the sense that they will
choose or eat more of a high fat diet than a
normal, you know, how many such snips are there in humans?
There are
at least a half a dozen snPs in the first intron.
In the first intron alone.
But that's where they all are.
That's where they all are.
That's where they all are.
And what is the prevalence
into the best of our knowledge
of people today who have at least
one of these SNPs in that first intron?
60%.
So 60% of the population
would be at least somewhat susceptible to obesity.
Yeah. Which is, you know, sort of fits with what we see because the effect size of this genetic
variation is not on or off. It just widens, I think, the or increases the susceptibility
to whatever it is in the environment that's doing this.
Are there pharmacologic things that could be done to combat this?
Well, we don't know what it is.
Because we don't know what the, we don't have to approach.
It's so much more complicated because it's non-coding.
Correct.
But that's what fascinates me about it.
And I think it's producing something in the central nervous system,
which is structural and consequence, at least in part.
And that's why I'm fascinated by it. something in the central nervous system, which is structural and consequence, at least in part,
and that's why I'm fascinated by it.
Because what this means is that if you have this predisposition, it may change the nature of your central nervous system
structurally in such a way as to make you either more or less.
If you take just hypothetically an animal that's born with these introns, with this pattern
of introns, and you could magically use CRISPR and you could delete them and edit them
and make them a wild type again, do you fix the phenotype?
Because if not, that would certainly point to something early on in neurologic development,
right?
Yes, you do.
So we can do that kind of thing.
You've done that experiment?
Yeah.
And we've also done experiment.
And sorry, it did or did not fix the Phoenix. Fix is it. Okay, so that means that it's has an
influence that transcends development, right? That it's part of development. I mean, because the
fix occurs at the at the level of the fertilization of the all all all nauseous. You never fixed it post.
Not fixed it post. fixed it post okay right so
Rudy you're never gonna stop working are you well if I gotta figure this out
I'll have to stay at it for a little bit longer there are a lot of other things
I want to talk with you about maybe we'll just spend a couple minutes there's
something else I want to talk about which is the most complicated topic ever
insulin resistance what the hell does insulin resistance mean?
How can an insulin resistant person be fat?
When by definition, insulin needs to tell the adipocyte
to take up the free fatty acid as triglyceride.
So does insulin resistance mean
insulin resistance of the muscle?
Insulin resistance of the liver,
but insulin sensitivity of the adipose height,
what does that mean?
The metabolic disposition of glucose, for example,
is obviously, or maybe not so, obviously,
it's not primarily via adipose tissue.
I mean, glucose when it gets into this circulation
and is removed or taken up, it's mostly in the muscle.
Yes, it's mostly in the muscle. Yes, it's mostly in the muscle.
So to the extent that insulin resistance is functionally denominated by elevated blood glucose,
it would seem to be the muscle or the primary defect. To be the muscle, which is the primary defect.
Now, the mechanism of the insulin resistance of muscle, I mean,
this is an area that's not one that I work in primarily, but there are appears to be
that what's going on at the sort of distal end of the insulin resistance path
is that the glucose transporters are not getting to the surface.
They're not responding to insulin the way that they do an a non-insulin resistant person.
And when the insulin transporters, the glucose transporters don't get to the muscle, get
to the surface of the muscle cell, they can't transport glucose. So at a molecular level, depending on exactly whose model of this you look at, there's
something wrong with the transmission of the signal from the insulin receptor into the
cell to send the glue transporter up.
Right.
Exactly what that defect is, again, depends on who you talk to or what mechanism is invoked.
That appears to be at least on one level, the sort of primary problem.
So what's happening in the liver?
You know, when we do an old glucose tolerance test, the reason we do it for such a short
period of time, relatively speaking, aside from who wants to keep a patient in the lab
forever is, you pretty much eliminate the novel glycogenesis or you eliminate DNL, right?
So you're basically looking it uptake by muscle, but there's some being taken up by the liver.
And I don't know that I understand fully aside from capacity, right?
The liver has a relatively small capacity for glycogen relative to the muscles.
What else determines that partitioning of how much glucose
in the bloodstream is going into the muscle versus the liver,
and then ultimately anything that exceeds those capacities
will then undergo DNL and the endomodolic
progenic pathway will produce addition free fatty acid?
And again, what does it mean to be insulin resistant
in the liver?
So it's interesting, you know, the liver,
if you want to look at it this way,
there's sort of two major metabolic things going,
and there are a lot of things going on the liver,
but as far as what we're talking about,
one is the ability to make lipid, to synthesize lipid,
and the other is the ability to make or take up glycogen,
to release or take up glycogen.
They are differentially sensitive to insulin,
suppression or enhancement if you want to look at it that way. And what happens, I mean,
just again, at a biochemical level, is you can get insulin resistant in the liver to the
suppression of gluconeogenesis while you maintain sensitivity to the effect of insulin
on the...
Denive a life of genesis.
Yes.
That's the worst outcome.
Yes.
But that's what happens.
I mean, that's the state...
How is that regularly?
How is that regularly?
...in many individuals who have issues with regard to insulin homeostasis if you want to
describe it that way?
Yes.
So for the listener, what we're basically saying is the Doomsday scenario would be your
muscles become resistant to the signaling of insulin and they don't put these glute
transporters up there and you don't bring glucose into your muscle.
Yeah, but why that happens actually.
In other words, what is it about becoming obese that is actually doing something to skeletal muscle.
What if it's the reverse?
Well, it may be.
I mean, again, this is an area of somewhat hot debate,
but one possibility, I guess, is that there's something
that happens to adipose tissue when you store
whatever for that individual is an excess amount of lipid
that's producing another molecule or some other mechanism
by which muscle is affected with regard to its insulin sensitivity.
The other possibility, which I think again, many people think is at least partly relevant,
is that when you increase the amount of lipid in your adipose tissue, you also increase the amount of lipid in your muscle.
The fact that's in your muscle,
actually the marbling of your own muscle,
and that that itself has an effect on glucose homostasis.
So there's a whole, what does Gerald Schumann think of this?
Doesn't he have an idea that it starts in the liver?
Isn't that his view?
So Gerald Schumann has done a lot of work on the mechanism
by which insulin affects glucose transport in muscle.
I don't wanna speak for him.
I mean, in terms of what he thinks about this,
but he certainly is one of the people
who I think has advanced the field
in terms of understanding why, for example,
ambient fatty acids seems to suppress glucose uptake
and muscle.
This was originally described by Randall.
And just to be clear, that's not Randall the patient.
That's correct.
Not that you didn't know shit about.
Not it spelled differently also.
So I think what Gerald Schulman has done is to advance our understanding of a very I think
compelling mechanism by which high levels of ambient fatty acid themselves might suppress
insulin signaling. Some of that fatty acid could in fact come from
lipid that's stored in the muscle as opposed to lipid or fatty acids
that are in the circulatory.
But there are these two different phenotypes, right?
You know, when you look at K-hills 40-day fasted subjects,
their free fatty acids were through the roof.
Their insulin was very low.
Their glucose was very low.
Their ketones were very high.
It's interesting to know, would you call them insulin-sensitive
or insulin-resistant, right?
Because probably if you call them insulin sensitive or insulin resistant?
Because probably if you challenge them with glucose immediately, they would have hyperglycemia.
Physiologically, their muscles probably would, in the short moment, say, hey, I don't want
this stuff, save every gram of that for the brain.
But presumably, if you refed them carbs for three days, they'd probably be as insulin sensitive
as they'd ever been.
Right.
So, I mean, this is one of the reasons why I think you're right, but the, I think maybe
what Shulman or Randall would say is that the reason for the lack of response to the transport
of glucose is that the system has now been down set by virtue of the high ambient free fatty
acids and it may take some time to that. time to that you said you're thinking that could be the short-term signal correct and that and that takes time
That's why again, I don't do this for living. I mean you would know this but why people are encouraged not to
Restrict their carbohydrates prior to having glucose tolerance test
For example because you can manipulate the system in a way that you just mentioned.
Rudy, I could sit here and talk about this stuff all night long, but your wife will probably be
pissed off that I kept you here all night. So maybe not, maybe she's actually enjoying the fact that
you're here. This has been super interesting. You're really one of the most thoughtful people I've
ever spoken to on this topic. And I think there are a lot of areas where we don't necessarily see eye to eye clinically,
which again, that sounds like a much more harsh statement than it is.
I just think we look at the world a little differently on some level, but you're a hammer.
You're a hammer looking for a nail, and I'm kind of a general contractor looking for
everything in sight.
I mean, I think it's interesting.
I think your FTO example is a great example.
I mean, if I were tackling this problem and I'm glad I'm not, I'd be wanting to understand
the environmental trigger.
Is it the cigarette that's causing lung cancer?
You're trying to solve a different problem, which is, why is it that only some people get
lung cancer when they smoke?
And those people before the adage of the invention of cigarettes would have never got lung cancer,
but now that these cigarettes are here,
probably can't do much about it.
Let's figure out who they are.
And not just for that reason.
I mean, just as an intellectual question,
I find it very intriguing,
but knowledge of whatever would lead a person
who smokes not to get lung cancer,
it would be very nice to know what that is.
That whatever that biology is for many, many reasons,
not just related necessarily to lung cancer.
And I see the issue of the consequences
of a genetic variant very prevalent in the population,
which predisposes some individuals
to the environmental consequences and others.
Not if we knew what that mechanism is,
there's no reason to believe that at some point
we might not be able to manipulate it.
Not only in service of those who have the genetic variant,
but others who might benefit from knowledge of the circuitry.
Yeah, I mean, that makes a lot of sense.
And you've given me some great pearls over the years.
I remember you, I think it that makes a lot of sense. And you've given me some great pearls over the years.
I remember, I think it was one night at dinner
when you and me, Mike Rosenbaum, were playing paddy cakes
and it somehow came up that in your 10 to 20% weight-reduced
subjects, a little bit of T3 could overcome some of the deficit.
And I remember having this eureka moment
because I was like, wait a minute.
All these patients, I see that lose weight
have a reverse T3 spike.
That would exactly explain why giving them T3,
rather than T4 would address the problem.
You give a patient with high reverse T3, T4,
you're just, you're making them worse,
but you give them T3, you can bypass it.
So I'm incredibly grateful to you, to your work,
and for your friendship. So thank you very much. Well, I like it grateful to you, to your work, and for your friendship.
So thank you very much.
Thank you.
Thank you.
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