Dr. David Linden: Life, Death & the Neuroscience of Your Unique Experience

Welcome to the huberman live podcast where we discuss science and science based tools for everyday life. I'm Andrew huberman and I'm a professor of neurobiology and Ophthalmology at Stanford school of medicine. Today, my guest is dr. David Linden, dr. David Linden as a professor of neuroscience at Johns Hopkins school of medicine. His laboratory has studied neuroplasticity. That is how Connections in the Brain Change in response to experience much of that work focused on.

A structure called the cerebellum, which is also sometimes referred to as the mini brain, because it looks like a mini brain in the bottom and back of the human brain. And it's responsible for an enormous number of basic functions that we use in everyday

life, including

our motor behavior. That is our ability to walk and talk. But also dance play instruments and it's responsible for an enormous number of basic functions that we use in everyday life, including our sense of balance. Our ability to learn new motor behaviors as well as our sense of timing.

We will discuss the cerebellum in what it does. But dr. David Linton will also teach us about the important sense of touch as well as what makes us different as individuals. The reason today's discussion and Compass has so many important topics. Is that dr. David Linden's laboratory has focused on many of those topics and he is also the author of five. Excellent popular books about Neuroscience that focus on, for instance, our sense of pleasure, and where it originates from and what controls it in the brain, as well as our sense of touch.

Much. And today we start off our discussion by talking about the recent discovery of a set of neurons that have been known about for a long period of time. But that only recently have been characterized that are involved in sensual touch in particular and it's a fascinating conversation. I assure you in addition to that dr. David Linden informs us about what makes us individuals, how each, and every one of us, perceives the same things differently. And it's an absolutely fascinating conversation, which tells you for instance, why some of you think a

Is putrid, indeed smells like vomit. Whereas others perhaps are not bothered by that smell and why others still are attracted to that smell or something that you look at or something that you hear. We also talked about nature versus nurture and how we come to be who we are, not just through our genes and epigenetics. But also through our early childhood experience and adult experience, and then in the latter, third of our conversation, we shift to talking about the so-called Mind Body Connection and the

the science, underlying how our thoughts inform our bodily health or lack thereof as well as how the organs of our body control, the chemicals hormones and thoughts within our brain. Then we shifted discussing dr. David Linden himself and the fact that in 2020, he was diagnosed with a form of heart cancer that led his Physicians to tell him that he had six to 12 months to live now obviously, because he was in our studio to record this conversation, he has outlived that

Sis. But he lives day-to-day with the knowledge that his death may very well come soon. Although it isn't clear exactly. When that day will come of course he tells us how the initial prognosis of his cancer as well as outliving that prognosis has informed his day-to-day life, as well as his thinking and his relationships and that leads to a very direct and frankly, emotional conversation that includes advice on how all of us can get the most out of our daily living. And

Out of our overall life. It's an extremely powerful conversation that I believe everyone regardless of age or health status can benefit from and it's one that makes clear. That not only is dr. David Linden a spectacular scientist but also a spectacular educator, a spectacular, popular writer a spectacular Family Man. Including husband and father and friend to many people and his colleagues. But he is also a courageous and spectacularly, generous human being before we begin.

I'd like to emphasize that this podcast is separate from my teaching and research rules at Stanford. It is however, part of my desire and effort to bring zero cost to Consumer information about science and science related tools to the general public in keeping with that theme. I'd like to thank the sponsors of today's podcast. Our first sponsor is rokka rokka makes eyeglasses and sunglasses that are of the absolute highest quality. The company was founded by two All-American, swimmers from Stanford and everything about Roca eyeglasses and sunglasses were designed with performance in mind.

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Free month for carrying out this survey, you can find the link to the survey in the show, notes for this podcast episode and on our website huberman lab.com. So if you would be so kind as to take a few minutes to fill out the survey and help us continue with bringing you the best possible content here at The huberman Lab podcast. And as always, thank you for your interest in science and now for my discussion with dr. David Linden Professor Linden welcome. Thanks so much for having me. I'm looking forward to our conversation, and we have a lot to

Talk about we do lots of different aspects of science, lots of different aspects of personal journey and what you're confronting. Now as it relates to your health and your future. I want to start off with a question that I learned from the one. And only the great Karl deisseroth, who was the first guest on this podcast, my colleague at Stanford. And for those of you that don't recognize Carl's name, he is a absolute Phenom. He's a

Say active clinical psychiatrist. So he's an MD and he also is a bioengineer who's developed a lot of the modern tools for probing the brain. And any time I've met with Carl, the first thing he says, is what do you most excited about lately? That's a good question. It is. So I'm going to steal that approach and say, what do you most excited about lately? Well, very, very lately. The most interesting thing that

Run in Neuroscience, is the answer to a scientific problem that I think is really dear to a lot of people's hearts and that is what are the nerve endings in the genitals that are responsible for sexual sensation. And you know, if you think about it, right, people can feel sexy from being touched on lots of different parts of the body but there's something special about the jungle.

Miles, doesn't matter. Male or female or intersex, or gay, or straight, or bi, or whatever you are. You know, the genitals are a hotspot, and why? And you'd think, as biologists, we know this by now, this would be something we could just answer, but but it's been a mystery for a long time. And if you go back to to 1860, there was a German neuroanatomist name Krause, and he cut thin sections of tissue from the penis.

The clitoris and he looked at them under the microscope and he saw a particular kind of nerve ending there that has since been called the Krause corpuscle. And there were lots of them in these two places. And so he thought, well maybe this is the cellular basis of sexual sensation. Maybe these are the particular nerve endings that are responsible for this but

There were some things that that were in favor of that and some not. So these nerve endings are also in some other places that people can find more or less sexy like they're in the nipples and they're on the lips and they're in the anus, all places that get popular in in that domain but they're also in places like the cornea or the lining of the joints. So distribution doesn't quite make sense and so it

Never known. And so if you wanted to really test as a scientist, whether these nerve endings are responsible, you want to record their electrical signals, while the genitals are being touched, you'd want to inactivate these cells and see if you could interfere with SNAP with sexual sensation and this in a preprint from David guilty is group at. Harvard is just what they have been able to do in mice. They found a way to label and record from

and activate and inactivate artificially the Krause corpuscles. And so you see a nerve endings in the skin, it could be conveying all kinds of information. It could be tuned for hot or cold or for rich or for pain or Fuller in or for inflammation or for mechanical sensation, stretching vibration indentation and sure enough. When they recorded from these Krause corpuscles they really are.

Chemical sensors as you would expect if they were involved in sexual sensation. So that was good. And then the other thing that they did is they try to artificially, turn them on. And so the way they did that is they use genetic tricks to express one of Carl. Dicers Oaths, a molecule that activates neurons when they're when blue light is Shone on them and they found that if they express this, artificial protein.

Seen in the crowd cells in a, in a male Mouse and then shine, blue light, the mouse gets an erection. Alright. So far so good. What happens if you turn them off? Well, it should turn them off in a male Mouse. It's just as interested in females when they're in heat, but it won't mount and thrust, and ejaculate as much. And if you turn them off in a female Mouse, during the time of her cycle, where she would normally be sexually receptive,

If you find that she is much less interested. She's much less likely to let him Mount. She is much less likely to let him finish. So this is the remarkable results that finally, after all these years since 1860 now we know what the nerve endings are that convey sexual sensation and like all good science. Then you know there are a lot of questions.

That are really interesting to our everyday lives. Like, you know, people like different things in bed and have different propensity for orgasm or, or like like to be touched in different ways. Well, is part of that reason because of individual variation in their Krauss corpuscle structure. We know that sexual sensation diminishes with aging is that in part, because Krause corpuscle density is lost

From the skin of the genitals and that's a reasonable idea because we know for example, that fine touch sensors in the fingertips so called Merkel and meissner endings also named after German anatomist, like so many things are, are also lost with age. So that's a reasonable idea. So so this finding from grantees Lab is opened up a whole world of science and I've been my, let my own lab doesn't work on touch, but I've been a fan boy of touch for

For, for many many years mostly because where I work at Johns Hopkins, Medical School. There have been many terrific touch researchers. It's been a world center for it and I hear about it over lunch and I got all fired up. So years ago, I wrote a book about it, I still follow the field and this is the most interesting thing in that field recently. And as I recall ginty was your neighbor at Hopkins, before he moved to Harvard. That's right. That's right. He was one of the ones ginty Stephen Chow Michael.

To Reno Shin Jang, dong there have been a number of world leaders among in the cellular basis of touch sensation at Hopkins. Do you recall if in the preprint that you were describing there was an experiment where they activated these Krause corpuscles in females. It's funny, you should mention that I sent that exact email to David guilty and they said they are in the process of doing that right now and they don't quite know yet. And so I asked

Him. I said, so, for example, is erection of the clitoris, even a thing in mice. He said, well, we're really not sure. So, we're activating the crowd score, puzzles and female mice, and we're just kind of staring at it and looking and see if anything happens just there, you know, does the, you know, does the the body change shape? Is there a color change? They don't even quite know what it is they're looking for because it's that much on the Leading Edge of things but it's a good question or perhaps the female mice would be more willing to mate.

Outside of the usual time frame of receptivity, if these Krause corpuscles are stimulated, that's possible. My suggestion, my guess would be not because I think that the hormonal regulation of receptivity is like a sledgehammer and very hard to overcome but they might be more willing to continue mating or make for a longer during their fertile time. And I just want to remind people because we had a guest

recently dr. Veena Malik who's a urologist reproductive and sexual health expert. She's an MD and she made clear that the the clitoris and the penis come from the same embryonic origin. They are analogous tissues. In different individuals. I do have one more question about this sexual touch thing.

These are peripheral nerves, right? So, these are not of the brain and spinal cord. They are in what we call the periphery. And my understanding is that peripheral neurons regenerate and can remodel themselves extensively in ways that neurons within the brain and spinal cord, tend to remodel less, especially as one gets older out of the so-called critical period. Is it possible that these cross Corpus schools and their patterns of innovation?

The genitals change according to the stimulation that people experience. In other words is sexual sensation, experience dependent. That is a great question. And so we don't know because monitoring this in people is not technically possible, Right? It requires cadaver tissue so you can only do it once in animals. It

It will be possible and it could be for a couple of different reasons. And other words, it could be. I think what you're imagining is that there's actual structural plasticity. If you looked at these crowds corpuscles or that you would actually see them changing their shape, or their size, or their, or their density as a result of experience. But what can also happen is phenomenal, like desensitization that is to say when they're stimulation for

A long time, then the receptors transiently can become less sensitive to touch, and it's well known for particularly in males, that that chronic masturbation can produce desensitization of sexual sensation in the penis. And that could be as a result of a physical change, a morphological change in the crowds corpuscles, but it's more likely to

to be a change in their function that you wouldn't be able to Simply see by looking at an outline of their structure in the microscope. Such an interesting topic, Thanks for opening, things up with with that. And I'll have to check out this preprint. I'm also a huge fan of David guarantees work. And and colleagues, there are many people involved in that domain of work. Of course, I'd like to talk about your recent book and the sort of underlying basis of what.

LED you to write it? And what intrigued you about this idea of human individuality the book unique is one that will provide a link to in the show. No captions. And it's a very interesting idea that we are all different especially coming from a neuroscientist who were trained at least similarly, it to learn that sure. The bumps and ripples of the brain and the fine wiring of the brain is different and we are all unique and different, we have different shapes.

Take a morphologies. But focusing on human individuality is not something that modern Neuroscience or classic Neuroscience has really done much of its really focused on how people do X or people do. Why this way tell us about unique and tell us about human individuality. Yeah, well, I mean, you're absolutely right. So, when I look at the experiments, my own lab, how do we do them? Well, we work on mice. Do we work on mice with genetic variation?

We work on highly inbred mice that are designed to be as genetically similar to each other as possible. And then we raise them basically in prism in little little cells, which may not be a good idea and we try to give them as similar experience as possible. They are given toys and food and water but I agree. It resembles a prison of sorts. They aren't free to roam. They're not. They have nothing like the experience of a wild mouse. Let me put it that way there.

And and yes, there are as you said correctly. There are plenty of experiments where there is enrichments, from mice, and they loved it. So, for example, in our lab, when we put running wheels in, the cages are mice and let them run overnight, they're active at night. Your average Mouse will run two kilometers in a night for a little tiny Mouse. And some of the mice are so intense, they will run 20 kilometers. Imagine

A mouse doing 20K but it will happen. They really, really like it. They don't like being in prison. They want to exercise and the really bored. So yes to get back to your general point. So much of science is designed to try to find general principles of a function of the brain of physiology of genetics and to ignore individual variation.

Individual variation is so important to our human experience. And actually is so important to to the process of evolution and natural selection and how how species make their way in the world. That that it's, it's something that that requires a lot of attention. And to me, what's really fascinating is that when you look at the variation in the way

A sense organs function. It's almost a miracle that we can agree on a common reality at all even within the human species. And this is true of more of some senses. More than others. Obviously, in your world in the retina, we have various kinds of loss of color vision that are well-known and some other more complicated phenomena having to do with.

Months in the perception of motion or form, but the place where this really happens is in the olfactory system. So we have approximately 400 functional receptors for different odorant molecules smells in our nose and if you sequence the genomes of many people you find that the

That the, the DNA that encodes, for these odorant receptors is unusually variable from Individual to individual. As a matter of fact, if you take two different people on average, they will have functional differences in 30% of their odor receptors. And if you do as Leslie vas, all and her colleagues did at Rockefeller University.

Give odor tests where they give people different things to smell and then they dilute them and find the threshold which they can detect them. You find enormous changes from People to People both in term in general terms, some people are just better smeller's than others. But in terms of individual odors as well there's some odors that some people can't detect and other people smell one way. For example, there is a there's a secrete a hormone called Andres.

Steen own androstenone there some people who can't smell it at all, for some people, it smells like rather Pleasant, like cut grass. And for some people, it smells foul like your owners sweat and it just depends on genetic variation in one particular odorant receptor sorry to interrupt another phenomenal researcher who studies olfaction among other things? Catherine, duloc.

Um, I once heard say that some people have a gene that for them makes the smell of microwave popcorn, they experience that smell as vomit. And other people who lack this Gene like the smell of microwave popcorn or at least for them, it's not aversive so it can really be a binary response. Well, it can actually that's a very particular funny case. So the remedy

relevant chemical there is butyric acid and also I swivel Eric acid and so there are researchers, I think Rachel Hertz is one of them who have given a mixture of these two chemicals to people. And they say this is parmesan cheese, they go yeah that's parmesan cheese and if they give it to other people and say this is vomit. They'll go. Oh yeah, that's vomit. And if they tell people, they give them one vial and say this is parmesan cheese in them.

I'll get another one. It says vomiting. Oh, yeah. And then they say, well, actually we fooled, you was the same vial. This it. No you didn't. You must have made a mistake. There are convinced that they couldn't have been the same thing. So this points out, not only is their genetic variation. That is responsible for around individuals, perceive odor. But we are incredibly suggestible in terms of odors and we, we are

very dependent upon them in terms of cultural context. And this can be this can be learned and and this is Central to our Humanity in the sense that, that we humans are what I like to call the anti pandas pandas live in one spot in in southern China and they eat one thing bamboo and that's it, humans are the opposite. Humans can live in any

Whole niche in the world from the tropics to the polls and humans, eat a wide wide wide variety of foods. And as a result it means that we have to have a very plastic olfactory system that have to be very few things that we find in Nate Lee. Reverse of their only, a handful of odors rotting meat. Odors molecules with the evocative names like cadaverine and putrescine are things that even babies

When their newborn find aversive but other things happen that they need to be learned. For example, pretty much. Every adult finds poop odors unpleasant but babies happily happily play with their own poop. They have to learn that that's disgusting. It's not because babies have a different nose, it's because they have to learn cultural not innate. It is not innate. They're only a few innate odor. Aversion

And a few innate Taste of versions that were were born with, and the other things are elaborated, culturally and we can think about this in terms of how we talk about, odors. So for example, we might say, vanilla smells sweet.

Well that's weird. That's like those are two different senses. How can something smells sweet? That's like saying it sounds read right? It's a statement about synesthesia, right? And but but how did it come to pass and do people say that vanilla smells sweet everywhere in the world? Well, the answer is no. So in places in the world, where vanilla is used with sugar in in sweet foods like desserts. Then people say that a vanilla smell sweet or mint. Similarly,

Ah smells sweet if it is typically used together with sugar. But if you go to a place like like Vietnam, where mint is mostly used in Savory dishes, people won't say that mint, smells sweet. So there's a parrot Association there that at least at our level of conscious understanding feeds back on to what we call.

Olfactory or smell perception. But really, it's a must be a parent Association at some point in development. Yeah, it is, it absolutely is a dissociation and it's something that goes on continually through your life, right? I mean, lots of people, for example, have stories of foods that they wouldn't eat as a child but they came to like as an adult's. A good example of that is coffee. A lot of people have to overcome bitter or version.

To, to become coffee aficionados. So, you know, this, this feeds into the more, the more General theme that

There is no, pure perception, perception is inference. It's not like there is a purely objective world that can somehow make its way through the senses and we can perceive that as the truth, all of our perception. Through all of our senses, both the outward pointing senses of the world like smell and taste and sight and hearing and the inward pointing senses like,

And is my stomach full and things like that. All of them are based on experience and expectation and the situation of the moment, as many of, you know, I've been taking a G1 daily since 2012. So I'm delighted that they're sponsoring the podcast. A G1 is a vitamin mineral probiotic drink. That's designed to me all of your foundational nutrition needs now. Of course, I try to get enough servings of vitamins and minerals through whole food sources that include vegetables and fruits.

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Special offer they'll give you five free travel packs. Plus a year supply of vitamin D3 K to again that's drink. AG one.com. Hubermann are there any examples of uniqueness of visual perception that come to mind? I recently did a social media post that involve. It was essentially three rings. A blue ring a red ring and a blue ring in the center or perhaps it was the other way around. Excuse me. It was

Red blue red and I asked which ring is in front or they all at the in the same plane. Now, of course, it's a two-dimensional image and interestingly it splits out into about thirds, some people see the blue ring in front quite a bit other. See a red ring out in front other, see them all in the same plane and this we think has to do with differences. In two things between individuals, one is the distribution.

You know, the cone photoreceptors which we know is essentially random between individuals, maybe even between the two eyes and then, and that gives rise to this phenomenon of chromatic aberration, which is the displacement of the visual image, according to the wavelength of the light and we won't get into the physics of it. Now I'll soon do a post that hopefully distills it in a manner. That simple enough, that people understand. But clearly some people see certain colors in front of others and the person, right?

Next to them could see the opposite color in front and others. Say what are you talking about all the colors are exactly the same plane of vision. So that's the one that I know I'm guessing, you know, some others and perhaps some more robust ones. Well I think, you know, perhaps this is maybe not what you had in mind. But one way in which experience modifies the visual world has to do with, how much light you're exposed to

In the first five years or so of your life. And so kids that don't get outside are much more likely to be myopic and it actually is nutted nearsighted. Yes, when they grow up, then kids who got outside and we now know that at least part of the story is that light seems to stimulate the

section of a class of molecules called trophic factors that you're well-acquainted with that actually change the shape of the eyeball. So it's not really the structure of the retina, or the lens of the cornea. The actual degree of elongation of the eyeball changes changing the way the the retinas, it's relative to the limbs and that seems to be light dependent early in life and which gives rise to two.

Higher incidence of myopia. And and to me this is really well. First of all, it's news, you can use, you should get your kids outside for absolute. All kinds of reasons you should get outside to especially in the morning set that circadian rhythm guy. I know that's a famous huberman esca point. They're gonna be putting me in the grave David and I'm going to be telling people to or it'll maybe I'll be on my Tombstone, say get get sunlight in your eyes. You got his specially on, especially on cloudy days because there is still

No sunlight, even if you can't see the physical object of the sun on cloudy days. Well, you know, I think this whole idea of having traits that are dependent upon early, life experience is fascinating because there are a number of situations where you would guess that something is genetic. But it isn't. It's actually dependent on early life experience and there's a there's an amazing story about this.

In to do, with the early days of World War Two. So in the early days of World, War 2, the Japanese Army, just swept through Asia. They defeated the, the British and Malaysia and Singapore. They overrun Thailand and Burma and they were knocking on the gates of India and everything was going great except the Japanese Army had a problem. There were an enormous number of their soldiers who became incapacitated with heatstroke. They got their core.

Sure, got too hot and when the Army doctors examine them, they found this was much more likely to happen in soldiers, who came from the northern part of Japan Hokkaido. Where it's where it snows in the winter as opposed to the southern part of Japan. Like you shoot, which is a semi tropical environment and the classical explanation. The biologists like us would guess would say. Oh, all right, well, this is

And genetically over many years, you have a family that's been in Kyushu for many generations. And you've selected for Gene variants that allow you to tolerate the heat better and we know actually what this is. So if you're more heat tolerant, it's because you have more of a particular class of sweat gland called the eccrine. Sweat glands, the sort of saltwater, sweat glands, not the Le Petit stinky armpits sweat, glands called the African ones, the Akron ones, you have a higher

Fraction of them that are innervated, meaning that the signals from your brain. That's a your core is too hot. Can then make you sweat. So the total density of sweat glands between northern and southern soldiers in Japan wasn't different, but the southern soldiers tend to have a higher degree of innovation. All right, so so okay well this happened genetically over many generations but if you look at those rare cases where you have soldiers from a long-established northern family and their parents moved,

And they grew up in the southern location. They had high sweat gland innervation. They were wealthy tolerant conversely. If you had a well-established, Southern Kyushu family and they moved to Hokkaido and then have their child that child developed the northern sweat gland, innervation pattern. So meaning less nerve, innervation of those sweat glands. As you mentioned before, just as many sweat glands, just less nerve innervation there for those sweat glands could not be activated.

Ooh, they couldn't dump heat as well. Their heat tolerance was lower, you're exactly right. And and what's what's wonderful is that this gives an advantage that you can't get through Evolution and that it can happen right away and this in one generation right evolutionary change is slow, right? And you can adapt as a species and as a family over over many, many, many generations. But when you have a phenomenon,

That is set by early life experience. Well, then you can benefit from that early life experience within your own life. It's not that your great-great great-great-great. Grandchildren will ultimately benefit. You benefit another wonderful example of this comes from field, mice voles, and we were talking earlier about how we both worked with the scientist nerves, Booker out at Berkeley. Who is a specialist in

In in voles and what people found is that if you take wild-caught field mice, and you have pregnant mothers and you have them in the lab, but you manipulate the lights so that you have artificial spring. In other words, day length is getting longer day after day during the pregnancy then what happens is when their pups were born.

It will have a low density of fur anticipating summer temperatures.

If you however put them in artificial fall, where day length is getting shorter, they will be born. Now, with high density of for anticipating winter temperatures and of course you can do this no matter what the season actually is in the world by manipulating these lights in the lab. And so, like the sweating Japanese soldiers, this is a great example of early life plasticity. And

Sort of trait that if you ask someone, they would probably guess is heritable. But actually is not thanks for mentioning our visitor, who has you also mentioned was an adviser to us both who's done, incredible work in circadian, biology seasonal, rhythms hormones, and behavior. I have such reverence for Irv. And the experiment you mentioned made me smile wide because it's but one of gosh, maybe hundreds of incredible study so if people are interested in seasonal rhythms and circadian

Ian rhythms, and biology of the most interesting kind. Definitely, check out Irving's occurs work at Berkeley. I'll provide a link to his PubMed there. Since we've been taking a tour of individual variation in olfactory perception, visual perception and now heat tolerance. I have to ask, are you aware of any examples off the top of your head in the auditory domain that particularly intrigued you?

Yeah, well, I would say one really interesting example, has to do with perfect pitch. So, Perfect Pitch as a trait that is to say, you have the ability to, to hear, a note played and say, oh, that's a c-sharp, right? This is a pretty rare trait. So even if you look among highly trained, musicians, if you went to Peabody conservatory, at my University, Johns, Hopkins, and tested people. There, you would find a higher incidence

So Perfect Pitch, then you would in the general population but still maybe one in ten trained musicians have perfect pitch and parenthetically having Perfect Pitch. Doesn't necessarily make you a better musician, but it's an interesting phenomena. And so the question is well, is perfect pitch heritable? And the answer is when you look at twin studies where which is what we use to estimate heritability, the answer is its kind of low.

If there's a heritable component, but it accounts for my recollection is on the, on the order of 30, 40 percent of the variability in Perfect Pitch. However, if people receive ear training, starting at a young age, the chance that they will develop Perfect Pitch, can improve drastically in your book unique. Do you cover aspects of human individuality? That extend beyond the

Cept action domain into the cognitive domain. Well, yeah, absolutely. And you know, I think I think it's good to set the stage here. If we're going to be talking about heritability and human individuality and and so if I can go off on a little bit of a riff for the benefit of your of your listeners and viewers here, he's so if you look at human traits whether they are behavioral traits like shyness.

Or very straightforward. Morphological traits like height. What you tend to find is that there are very few traits that are entirely heritable where all their variability can be predicted based on the gene variants you get from your mother and father and there are a few traits that are absolutely unhearable but that most fall in between. So let me give an example. Everyone in the world has either wet

Dry earwax and it turns out that this is determined by variation. In the single Gene, the name of the gene is boring. It's a b c, C11. It's a ion transporter and there is a variation in this Gene gives rise to either wet or dry earwax. It doesn't matter how your parents raised you, it doesn't matter what foods. You ate, growing up, doesn't matter what? What diseases your mother had when you were in the womb,

Umm, it's 100% heritable. Well, does this mean that a b c? C11 we should call it the earwax type Gene? Well, no, because it's not there just for that like this. This Gene is expressed in cells and all parts of the body, doing all kinds of things earwax is just something that we notice genes don't code for traits, they code for proteins and so we have to be careful about how we refer to them in that way.

For example, the wet earwax G of variant of the abcc. 11 Jean also, confers a slightly higher risk for breast cancer. So clearly it's not just for earwax it's for a bunch of things. Most of which we don't yet know about, but in the case of earwax, this trade is 100% heritable. At the other end of the scale speech accent is 0%, terrible. It is entirely

Be dependent upon the speech that you experience in your childhood. And interestingly it's the speech of your peers more than the speech of your family, which is why the children of immigrants sound like the place where they wound up, not like their parents and there is no evidence for any degree of heritability. Now, just to be clear, I'm talking about speech accent, like whether you have a high or a low voice or it's nasal or more or less resident, these are physical things having to do with the vocal,

Back then they are in part heritable. Okay, so we've got one thing, that's 100% heritable. One thing is 0% heritable, but where do most Things Fall? Most Things fall in the middle? One of the most heritable traits that we know about in humans, is height and in the United States. Height is about 85% heritable, 85 percent of the variation, in the trait of height can be explained by what

You inherit from your mother and your father. Well, what's the rest? Well it's nutrition. It's the diseases you fought off. It's also random variation which we'll talk about a lot later. Now you might say OK. Well that's an estimate for people. In the u.s. is this true all over the world? Will know if you go to a place where people routinely don't get enough nutrition and are routinely

Fighting off infectious diseases. Like, this is been studied in rural Bolivia, for example, a rural India, now height is no longer 85% heritable. It's only 50% terrible. Why? Because people in these situations where they don't get enough nourishment, where they're fighting off these diseases, can't live up to their genetic potential for height if you want.