Huberman Lab - The Biology of Aggression, Mating, & Arousal | Dr. David Anderson
Episode Date: September 12, 2022My guest is David Anderson, PhD, a world expert in the science of sexual behavior, violent aggression, fear and other motivated states. Dr. Anderson is a Professor of Biology at the California Institu...te of Technology (Caltech), a member of the National Academy of Sciences and an investigator with the Howard Hughes Medical Institute (HHMI). We discuss how states of mind (and body) arise and persist and how they probably better explain human behavior than emotions per se. We also discuss the many kinds of arousal that create varying levels of pressure for certain behaviors to emerge. We discuss different types of violent aggression and how they are impacted by biological sex, gender, context, prior experience, and hormones, and the neural interconnectedness of fear, aggression and sexual behavior. We also discuss peptides and their role in social isolation-induced anxiety and aggression. Dr. Anderson also describes novel, potentially powerful therapeutics for mental health. This episode should interest anyone wanting to learn more about mental health, human emotions, sexual and/or violent behavior. For the full show notes, visit hubermanlab.com. Thank you to our sponsors AG1: https://athleticgreens.com/huberman LMNT: https://drinklmnt.com/hubermanlab Waking Up: https://wakingup.com/huberman Momentous: https://livemomentous.com/huberman Timestamps (00:00:00) Dr. David Anderson, Emotions & Aggression (00:03:49) Sponsors: LMNT (00:08:10) Emotions vs. States (00:10:36) Dimensions of States: Persistence, Intensity & Generalization (00:14:38) Arousal & Valence (00:18:11) Aggression, Optogenetics & Stimulating Aggression in Mice, VMH (00:24:42) Aggression Types: Offensive, Defensive & Predatory (00:29:20) Evolution & Development of Defensive vs. Offensive Behaviors, Fear (00:35:38) Hydraulic Pressures for States & Homeostasis (00:37:24) Sponsor: AG1 (00:39:46) Hydraulic Pressure & Aggression (00:44:50) Balancing Fear & Aggression (00:48:31) Aggression & Hormones: Estrogen, Progesterone & Testosterone (00:52:33) Female Aggression, Motherhood (00:59:48) Mating & Aggressive Behaviors (01:05:10) Neurobiology of Sexual Fetishes (01:10:06) Temperature, Mating Behavior & Aggression (01:15:25) Mounting: Sexual Behavior or Dominance? (01:20:59) Females & Male-Type Mounting Behavior (01:24:40) PAG (Periaqueductal Gray) Brain Region: Pain Modulation & Fear (01:30:38) Tachykinins & Social Isolation: Anxiety, Fear & Aggression (01:43:49) Brain, Body & Emotions; Somatic Marker Hypothesis & Vagus Nerve (01:52:52) Zero-Cost Support, YouTube Feedback, Spotify & Apple Reviews, Sponsors, Momentous Supplements, AG1 (Athletic Greens), Instagram, Twitter, Neural Network Newsletter, Huberman Lab Clips Disclaimer Learn more about your ad choices. Visit megaphone.fm/adchoices
Transcript
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Welcome to the Huberman Lab 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 Anderson. Dr. Anderson is a professor of biology at the California Institute of Technology, often commonly referred to as Caltech University.
Dr. Anderson's research focuses on emotions and states of mind and body, and indeed he emphasizes how emotion,
like happiness, sadness, anger, and so on,
are actually subcategories of what are generally governed
by states.
That is, things that are occurring in the nervous system
in our brain and in the connections between brain and body
that dictate whether or not we feel good about how we are feeling
and that drive our behaviors, that is bias us to be in action
or inaction and strongly influence the way we interpret
our experience and our surroundings.
Today, Dr. Anderson teaches us, for instance,
why people become aggressive and why that aggression
can sometimes take the form of rage.
Also talk about sexual behavior
and the boundaries and overlap
between aggression and sexual behavior.
And that discussion about aggression and sexual behavior
also starts to focus on particular aspects
of neural circuits and states of mind and body
that govern things like, for instance,
male-male aggression versus male-female aggression
versus female-female aggression.
So today you will learn a lot about the biological mechanism
that govern why we feel the way we feel.
Indeed, Dr. Anderson is an author
of a terrific new popular book entitled,
The Nature of the Beast, How Emotions Guide Us.
I've read this book several times now.
I can tell you it contains so many gems
that are firmly grounded in the scientific research.
In fact, a lot of what's in the book
contrasts with many of the common myths
about emotions and biology.
So whether or not you're a therapist
or you're a biologist or you're simply just somebody interested
in why we feel the way we feel
and why we act the way we feel,
I cannot recommend the book highly enough.
Again, the title is The Nature of the Beast,
How Emotions Guide Us.
Today's discussion also ventures into topics
such as mental health and mental illness.
And some of the exciting discoveries
that have been made by Dr. Anderson's laboratory
and other laboratories identifying specific peptides,
that is small proteins that can govern
whether or not people feel anxious or less anxious,
aggressive or less aggressive.
This is an important area of research
that has direct implications
for much of what we read about in the news,
both unfortunate and fortunate events
and that will no doubt drive the future
of mental health treatments.
Dr. Anderson is considered one of the most pioneering
and important researchers in neurobiology of our time.
Indeed, he is a member of the National Academy of Sciences
and a Howard Hughes Medical Institute investigator.
I've mentioned the HHMI once or twice before
when we've had other HHMI guests on this podcast,
but for those of you that are not familiar,
the Howard Hughes Medical Institute funds
a small number of investigators doing particularly
high risk, high benefit work.
And it is an extremely competitive process
to identify those Howard Hughes investigators.
They're essentially appointed.
And then every five years, they have to compete
against one another and against a new incoming flock
of would-be HHMI investigators to get another five years of funding.
They are literally given a grade every five years
as to whether or not they can continue, not continue,
or whether or not they should worry about being funded
for an extended period of time.
Dr. Anderson has been an investigator,
with the Howard Hughes Medical Institute since 1989.
Before we begin, I'd like to emphasize
that this podcast is separate from my teaching
and research roles 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.
And now for my discussion with Dr. David Anderson.
David, great to be here and great to finally sit down
and chat with you.
Great to be here too.
Thank you so much.
Yeah, I have a ton of questions,
but I want to start with something fairly basic,
but that I'm aware is a pretty vast landscape.
And that's the difference between emotions and states,
if indeed there is a difference,
and how we should think about emotions.
What are they?
They have all these names, happiness, sadness, depression, anger, rage.
How should we think about them?
And why might states be at least as useful a thing to think about,
if not more useful?
That's great. First, the short answer to your question is that I see emotions as a type of internal state
in the sense that arousal is also a type of internal state, motivation is a type of internal state,
sleep is a type of internal state. And the simplest way I think of internal states is that,
as you've shown in your own work, they change the input to output transformation of the brain.
when you're asleep, you don't hear something that you would hear if you were awake,
unless it's a really, really loud noise.
So from that broad perspective, I see emotion as a class of state that controls behavior.
The reason I think it's useful to think about it as a state is it puts the focus on it as a neurobiological process,
rather than as a psychological process.
and this gets around all of the definitional problems that people have with the word emotion,
where many people equate emotion with feeling,
which is a subjective sense that we can only study in humans
because to find out what someone's feeling, you have to ask them
and people are the only animals that can talk that we can understand.
So that's how I think about emotion.
It's the, if you think of an iceberg, it's the part of the iceberg that's below the surface of the water.
The feeling part is the tip that's sort of floating above the surface of your consciousness.
Not that that isn't important, it is, but you have to understand consciousness if you want to understand feelings.
And we're not ready to study that in animals yet.
And so that's how I think about it.
What are the different components of a state?
you mentioned arousal as a key component.
What are some of the other features of states that represent this,
as you so beautifully put in your book,
that represent below the tip of the iceberg?
Right, right.
So you can break states up into different facets,
or people would call them dimensions.
And so there have been people who have thought of emotions
as having just really two dimensions,
an arousal dimension,
how intense is it,
and also a valence dimension,
which is, is it positive or negative, good or bad?
Ralph Adolph and I have tried to expand that a little bit
to think about components of emotion,
particularly those that distinguish emotion states
from motivational states,
because they are very closely related.
related. One of those important properties is persistence. And this is something that distinguishes
state-driven behaviors from simple reflexes. Reflexes tend to terminate when the stimulus turns off,
like the doctor hitting your knee with a hammer. It initiates with the stimulus onset, and it
terminates with the stimulus offset. Emotions tend to outlast often the stimulus that evoke
them. If you're walking along a trail here in Southern California, you hear a rattlesnake rattling,
you're going to jump in the air, but your heart is going to continue to beat and your palms sweat
and your mouth is going to be dry for a while after it's slithered off in the bush and you're
going to be hypervigilant. If you see something that even remotely looks snake-like, a stick,
you're going to stop and jump. So persistence is an important feature of, of, of, you know,
emotion states. Not all states have persistence. So, for example, you think about hunger. Once you've
eaten, the state is gone. You're not hungry anymore. But if you're really angry and you get into a
fight with somebody, even after the fight is over, you may remain riled up for a long time and it takes
you a while to calm down. And that may have to do with the arousal dimension or some other part of it.
And then generalization is an important component of emotion states that make them, if they have been triggered in one situation, they can apply to another situation.
And my favorite example of that is you come home from work and your kid is screaming.
If you had a good day at work, you might pick it up and soothe it.
And if you had a bad day at work, you might react.
react very differently to it and scream at it.
And so that's a generalization of the state that was triggered at work by something your boss
said to you to a completely different interaction.
And again, that's something that distinguishes emotion states from motivation states.
Motivation states are really specific.
Find and eat food, obtain and consume water.
And they're involved in homeostatic maintenance.
So states are very multifaceted and just asking questions about how these components of states are encoded.
Like what makes a state persist?
What gives a state a positive or a negative valence?
How do you crank up or crank down the intensity of the state?
It just opens up a whole bunch of questions that you can ask in the brain with the kinds of tools we have.
have now. You mentioned arousal a few times and you mentioned valence. Realizing that there are
these other aspects of states, I'd like to just talk about arousal a little bit more and valence
because at a very basic level, it seems to me that arousal, we can be very alert and pissed off,
stressed, worried, you have insomnia. We can also be very alert and be quite happy. So the valence flips.
we can be very
people can be sexually aroused
people can be aroused
in all sorts of ways
is there any
simple or simpleish
neurochemical signature
that can flip valence
so for instance
is there any way
that we can safely say
that arousal with
some additional dopamine
release is going to be
of positive valence
and arousal with
very low dopamine
is going to be of negative valence
I would be reluctant to say that it's a chemical flip.
I would say it's more likely to be a circuit flip, different circuits being engaged,
and it might be that a given neurochemical, even dopamine, is involved in both positively valence derousal and negatively valence derousal.
That's why people think about these as different axes.
So I think the interesting question that you touch,
on is is arousal something that is just completely generic in the brain or are there actually
different kinds of arousal that are specific to different behaviors? And you raise a question,
you know, sexual arousal feels different from aggressive arousal, for example. And we actually
published a paper on this back in 2009 in fruit flies where we found some evidence for two
types of arousal states, one of which is sleep-wake arousal. You're more aroused when you wake up
than when you're asleep. And flies show that. And the other is a startle response, an arousal response
to a mechanical stimulus, a noxious mechanical stimulus. If you puff air on flies, kind of like
trying to swat the wasp away from your burger picnic table, they come back more and more and more
vigorously, and we were able to dissect this and show that although both of those forms of
arousal required dopamine, they were exerted through completely separable neural circuits
in the fly. And so that really put, number one, the emphasis on it's the circuit that determines
the type of arousal, but also that arousal isn't unitary, that there are behavior-specific forms of
arousal. And I think the jury is still out as to whether there is such a thing as completely
generalized arousal or not. I think some people would argue there is, but I think more attention
needs to be paid to this question of domain-specific or behavior-specific forms of arousal.
It's a super interesting idea because I always thought of arousal as along a continuum. Like,
you need to be in a panic attack at the one end of the extreme where you can be in a coma.
and then somewhere in the middle, you're alert and calm,
but then this issue of valence, really, as you say, presents this opportunity
that really there might be multiple circuits for arousal
or multiple mechanisms that would include neurochemicals
as well as different neural pathways.
So I'd like to talk a bit about a state,
if it is indeed a state, which is aggression.
Your labs worked extensively on this.
And if you would, could you highlight some of the key findings,
there, which brain areas that are involved,
the beautiful work of Diyu Lin and others in your lab,
that point to the idea that indeed there are kind of switches in the brain,
but that thinking of switches for aggression might be too simple.
How should we think about aggression?
And I'll just sort of skew the question a bit more
by saying, we see lots of different kinds of aggression.
This terrible school shoe,
shooting down in Texas recently, clearly an act that included aggression, and yet you could imagine
that's a very different type of aggression than a, you know, an all-outrage or a controlled aggression.
You know, there's a lot of variation there. So what are your thoughts on aggression, how it's
generated the neural circuit mechanisms and some of the variation in what we call aggression?
Yeah, this is a great question, and it's a large area. I would say that the, first of all,
the word aggression in my mind refers more to a description of behavior than it does to an internal state.
Aggression could reflect an internal state that we would call anger in humans or could reflect fear or it could reflect hunger if it's predatory aggression.
And so this gets at the issue that you raised of the different types of aggression that aggression that
exist. The work that Diya did when she was in my lab that really broke open the field to the application
of modern genetic tools for studying circuits and mice is that she found a way to evoke
aggression in mice using optogenetics to activate specific neurons in a region of the hypothalamus,
the ventrometrial hypothalamus, VMH, which people had been studying and looking at for decades,
following first the work of in Katz, the famous Nobel Prize-winning work of Walter Hess,
and then followed by work done by Meno Crook in the Netherlands, in rats,
where they would stick electrical wires into the brain and send electric.
currents into the brain, and they could trigger a placid cat to suddenly bear its teeth, hiss,
and almost strike out at the experimenter, and they could trigger rats to fight with each other.
And even in Hess's original experiments, he describes two types of aggression that he evokes from cats
depending on where in the hypothalamus he puts his electrode, one of which he calls.
calls defensive rage. That's the ears laid back, teeth-beared, and hissing. And the other one
is predatory aggression, where the cat has its ears forward and it's like batting with its
paw at a mouse-like object like it wants to catch it and eat it. So he already had at that
stage some information about segregation in the brain of different forms of aggression. So fast forward
to 2008, 2009 when Diya came to the lab.
And we had started working on aggression and fruit flies.
And I wanted to bring it into mice so that we could apply genetic tools.
And we started by having Diya, who was an electrophysiologist, just repeat the electrical
stimulation of the ventrometrial hypothalamus in the mouse, just like people had done.
in rats, in cats, in hamsters, even in monkeys.
And she could not get that experiment to work over 40 different trials.
It just didn't work.
What she got instead was fear behaviors.
She got freezing, cornering, and crouching.
And finally, in desperation, and we got a lot of input from Men O'Crook on this,
he really was mystified.
Why doesn't it work in mice?
we realized why there had been no paper on brain-stimulated aggression in mice in 50 years
because the experiment doesn't work.
And the one bit of credit I can claim there is I convinced Diute to try optogenetics
because it just had sort of come into use deep in the brain from Carl Dice Roth and others work.
and I thought maybe because it could be directed more specifically to a region of the brain
and types of cells than optogenetic stimulates, then electrical stimulation, it might work.
And Diya said, never going to work.
If it doesn't work with electricity, why should it work with optogenetics?
And the fact is that it did work, and we were able to trigger aggression in this region
using optogenetic stimulation of ventrometrial hypothalamus.
And in retrospect, I think the reason that we were seeing all these fear behaviors
is because right at the upper part,
if you think of ventrometrial hypothalamus like a pair sitting on the ground,
the fat part of the pair near the ground is where the aggression neurons are,
but the upper part of the pair has fear neurons.
And it could be because it's so small in a mouse, when you inject electrical current anywhere in the pair, it flows up through the entire pair and it activates the fear circuits and those totally dominate aggression.
And so that's why we were never able to see any fighting with electrical stimulation, whereas when you use optogenetics, you confine the stimulation just to the region where you've implanted the channel.
adoption gene into those neurons. And so in fast forward from that from a lot of work from
Diya now on her own at NYU and with her postdoc Anna Grette Faulkner there is as well as work
of other people. There's evidence that the type of fighting that we were that we elicit when we
stimulate VMH is offensive aggression that is actually rewarding to.
male mice. They like it. They like it. Male mice will
learn to poke their nose or press a bar to get the opportunity to beat up a subordinate
male mouse. And in more recent experiments, if you activate those neurons and the mouse
has a chance to be in one of two compartments in a box, they will gravitate towards the
compartment where those neurons are activated. It has a positive valence. And when I went
to this field and I was thinking, well, what goes on in my brain and my body when I'm furious?
It certainly doesn't feel like a rewarding experience. It's not something that I would want to
repeat because it feels good when I'm in that state. It doesn't feel good at all when I'm in that
state. And it is still, I think, a mystery as to where that type of aggression, which is more
defensive aggression, the kind of aggression you feel if you're being attacked,
or if you've been cheated by somebody, where that is encoded in the brain and how that works,
still, I think, is a very important mystery that we haven't solved.
And predatory aggression there has been some progress on.
So mice show predatory aggression.
They use that to catch crickets that they eat, and that involves different circuits
than the ventromedial hypothalamic circuits.
So it's become clear that if you want to call it the same,
state of aggressiveness is multifaceted. It depends on the type of aggression, and it involves
different sorts of circuits. There is, there's a paper suggesting that there might be a final
common pathway for all aggression in a region, which is one of my favorites. It's called the
substantia enomenata, the substance with no name. You know, I like...
Anatomists are so creative. Yes. Or the nuclear.
ambiguous, you know, or the Zona in Serta, these are places that no one can think of what they are.
Anyhow, that might be a final common pathway for predatory aggression and offensive and
defensive aggression, but it can be really hard to tell just from looking at a mouse fight,
whether it's engaged in offensive or defensive aggression. We've tried to take that apart
using machine learning analysis of behavior. But in rats, for example, it's much
clearer when the animal is engaged in offensive versus defensive aggression. They direct their
bites at different parts of the opponent's body. In particular. Offensive aggression is flank directed.
Defensive aggression goes for the neck, goes for the throat. I've seen some nature specials
where in a very barbaric way, at least to me, it seems like hyenas will try and go after the reproductive
axis, they'll go after testicles and penis and they basically want to, it seems they want to
limit future breeding potential. Or create pain. Right, or create pain or both. Yeah. I mean,
in terms of offensive aggression and your reflection that it doesn't feel good, I mean, I can say,
I know some people who really enjoy fighting, I have a relative who's a lawyer. He loves to argue and
fight. I don't think of him as physically aggressive. In fact, he's not, but loves to fight and
loves to prosecute and go after people and he's pretty effective at it. I have a friend, former
military special operations and very calm guy had a great career in the military special operations
and he'll quite plainly say, I love to fight. It's one of my great joys. He really enjoyed his
work. And also respected the other side because they offered the opportunity to test that.
that and to experience that joy.
So in a kind of bizarre way to somebody like me
who I'll certainly defend my stance if I need to,
but I certainly don't consider myself somebody
who offensively goes after people just to go after them.
There's no quote unquote dopamine hit here,
acknowledging that dopamine does many things, of course.
I have a couple of questions about the way you describe the circuitry.
I should say the way the circuitry is arranged.
And of course, we don't know
because we weren't consulted that the design
phase, but why do you think there would be such a close positioning of neurons that can elicit
such divergent states and behaviors? I mean, you're talking about this pear-shaped structure
where the neurons that generate fear are cheek to jowl with the neurons that generate offensive
aggression of all things. It's like putting the neurons that control swallowing next to the neurons
that control vomiting.
It just seems to me that on the one hand, this is the way that neural circuits are often arranged,
and yet to me it's always been perplexing as to why this would be the case.
Yeah, I think that is a very profound question, and I've wondered about that a lot.
If you think from an evolutionary perspective, it might have been the case that defensive behaviors and fear
arose before offensive aggression,
because animals first and foremost
have to defend themselves from predation by other animals.
And maybe it's only when they're comfortable
with having warded off predation and made themselves safe,
that they can start to think about who's going to be
the alpha male in my group here.
And so it could be that if you think that brain
regions and cell populations evolved by duplication and modification of pre-existing cell populations.
That might be the way that those regions wound up next to each other.
And developmentally, they start out from a common pool of precursors that expresses the same gene,
the fear neurons and the aggression neurons.
And then with development, it gets shut off in the aggression neurons and maintain.
in the fear neurons.
Now, that view says, oh, it's just an accident of evolution and development, but I think there must be
a functional part as well.
So one thing we know about offensive aggression is that strong fear shuts it down, whereas
defensive aggression, at least in rats, is actually enhanced by fear.
It's one of the big differences between defensive aggression and offensive aggression.
And you think about it, if you think about it, if you think about it, if you think
about it, if offensive aggression is rewarding and pleasurable, if you start to get really scared,
that tends to take the fun out of it. And maybe these two regions are close to each other
to facilitate inhibition of aggression by the fear neurons. We know for a fact that if we
deliberately stimulate those fear neurons at the top of the pair, when two animals are involved
in a fight, it just stops the fight, dead in its tracks, and they go off into the corner
and freeze. So at least hierarchically, it seems like fear is the dominant behavior over offensive
aggression. And how that inhibition would work is not clear because all these neurons are pretty
much excitatory. They're almost all glutametergic. And so one of the interesting questions for the
future is how exactly does fear dominate over and shut down offensive aggression in the brain? How does
that work? Is it all circuitry? Are there chemicals involved? What's the mechanism and when is it called
into play? But I think that's the way I tend to think about why these neurons are all mixed up together.
And it's not just fight and freezing or fight and flight. There are also metabolic neurons that are
mixed together in VMH as well. Controlling bodywide metabolism? Yeah. There are neurons there that
respond to glucose. When glucose goes up in your bloodstream, they're activated. And VMH has a whole
history in the field of obesity, because if you destroy it in a rat, you get a fat rat. So the way
most of the world thinks about VMH is they think about, oh, that's the thing that keeps you from
getting fat. It's the anti-obesity area. But in the area of social behavior, we see it as a center for
control of aggression and fear behaviors. And again, why these neurons and these functions,
I like to call them the four Fs, feeding, freezing, fighting, and mating, that they all seem to
be closely intermingled with each other, maybe because crosstalk between them is very important
to help the animal's brain decide what behavior to prioritize and what behavior to shut down
at any given moment. One of the things that we will do is link
to the incredible videos of these mice that have selective stimulation of neurons in the VMH,
daews and the other studies that you've done.
Whenever I teach, I show those videos at some point with the caveats and warnings that are
required when one is about to see a video of a mouse trying to mate with another mouse or mating
with another mouse, and they seem both to be quite happy about the mating experience,
at least as far as we know as observers of mice.
And then upon stimulation of those VMH neurons,
one of the mice essentially tries to kill the other mouse.
And then when that stimulation is stopped,
they basically go back to hanging out.
They don't go right back to mating.
There's some reconciliation, clearly, that needs to happen first, we assume.
But it's just so striking.
I think equally striking is the video
where the mouse is alone in there with the glove.
the VMH neurons are stimulated and the mouse goes into a rage.
It looks like it wants to kill the glove, basically.
So striking, I encourage people to go watch those
because it really puts a tremendous amount of color
on what we're describing.
And it's just the idea that there are switches in the brain
to me really became clear upon seeing that.
One of the concepts, excuse me,
one of the concepts that you've raised in your lectures before
and that I think was Hess's idea,
is this idea of a sort of hydrate.
hydraulic pressure.
Or maybe it was Conrad, Conrad, I can't speak now, excuse me,
Conrad Lorenz, Martin, who talked about a kind of hydraulic pressure towards behavior.
I'm fascinated by this idea of hydraulic pressure because I don't consider myself a hot-tempered person,
but I am familiar with the fact that when I lose my temper, it takes quite a while for me to simmer down.
I can't think about anything else.
I don't want to think about anything else.
In fact, trying to think about anything else becomes aversive.
to me, which to me underscores this notion of prioritization of the different states and potentially
conflicting states. What do you think funnels into this idea of hydraulic pressure toward a state?
And why is it perhaps that sometimes we can be very angry and if we succeed in winning an argument,
all of a sudden it will subside? Because clearly that means that there are external influences.
It's a complex space here that we're creating. I realize,
I'm creating a bit of a cloud, and I'm doing it on purpose, because to me, the idea of a hydraulic
pressure towards a state, like sleep, there's a sleep pressure, there's a pressure towards a great,
that all makes sense. But what's involved? Is it too multifactorial to actually separate out the
variables? But what's really driving hydraulic pressure toward a given state?
Yeah. So, really important question. I think one way that is helpful, at least for me, to break
this question apart and think about it, is to distinguish homeostatic behaviors that is need-based
behaviors where the pressure is built up because of a need, like, I'm hungry, I need to eat,
I'm thirsty, I need to drink, I'm hot, I need to get to a cold place. It's basically the thermostat
model of your brain. You have a set point, and then if the temperature gets too hot, you turn on the AC,
and if the temperature gets too cold,
you turn on the heater
and you put yourself back to the set point.
I don't think that's how aggression works.
It's not that we all go around, at least subjectively.
I don't go around with an accumulating need to fight,
which I then look for something to an excuse to release it.
Now, maybe there are people that do that
and they go out and look for bar fights to get into...
Or Twitter.
Yeah, or Twitter.
Twitter seems to do it.
I'm sort of half-joking because Twitter seems to draw a reasonably sized crowd of people that are there for combat of some sort, even though the total intellectual power of any of their comments is about that of a cap gun.
They seem to really like to fire off that cap gun.
But I agree.
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Yeah.
So you can think of this accumulated hydraulic pressure,
either being based on something that you were deprived of,
creating an accumulating need,
or something that you want to do,
building up a drive or a pressure to do that.
And the natural way to think about that,
at least for me,
is as gradual increases in neural activity,
in a particular region of the brain.
And so, for example, in the area of the hypothalamus that controls feeding,
Scott Stearnson and others have shown that the hungrier you get,
the higher the level of activity in that region in the brain,
and then when you eat, boom, the activity goes right back down again.
And that state is actually negatively valence.
So it's like the animal, quote unquote,
feels increasingly uncomfortable, just like we feel increasingly uncomfortable, the hungrier we are,
and then when we eat, it taps it down. But there is this increased activity. And I think in the
case of aggression, our data and others show that the more strongly you drive this region of the
brain optogenetically, the more of just a hair trigger you need to set the animal off to get it
to fight. Now, the interesting thing,
is that if there is nothing for the animal to attack,
it doesn't really do much when you're stimulating this region.
It sort of wanders around the cage a little bit more,
but it will not actually show overt attack
unless you put something in front of it.
And the same thing is true for the areas
we've described that control mating behavior.
This is what Lindsay is working on.
You can stimulate those areas
until you're blue in the face,
and the mouse just sort of wanders around.
But if you put another mouse in, wham, he will try to mount that mouse.
If you put a cumquot in the cage, he'll try to mount the cumquot.
And so it becomes a sort of any port in the storm.
So there is this idea that the drive is building up pressure
that somehow needs to be released where that pressure is actually being exerted.
if you accept that it's increased activity in some circuit or circuits someplace,
what is it pushing up against that needs something else to sort of unplug it in the Lorentz
hydraulic model?
That is you don't see the behavior until you release a valve on this bucket and let the
accumulated pressure flow out.
And that's one of the things we're trying to study in the context of the mating behavior
as well, how does the information that there's an object in front of you come together with this
drive state that is generated by stimulating these neurons in the hypothalamus to say,
okay, pull the trigger and go, it's time to mate, it's time to attack. And we're just starting
to get some insights into that now. Fascinating. And I should mention people, Dr. Anderson mentioned
Lindsay, Lindsay, is a former graduate student of mine that's now a postdoc in David's lab. And I haven't
caught up with her recently to hear about these experiments, but they sound fascinating. I would love to
spend some time on this issue of why is it that a mouse won't attack nothing, but it'll attack
even a glove or and why it will only try and mate if there's another mouse to mate with.
It's actually, I think fortunately for you, you're not spending a lot of time on Twitter and
Instagram or YouTube, but there's this whole online community that exists now.
As far as I know, it's almost exclusively young males
who are obsessed with this idea.
I'll just say it has a name.
It's called no fap of no masturbation
as a way to maintain their motivation
to go out and actually seek mates
because of the ready availability of online pornography.
There's probably a much larger population
of young males that are never actually going out
and seeking mates because they're getting porn addicted, et cetera.
This is actually a serious issue
that came up in our episode with Anna Lemke,
I wrote the book Dopamine Nation,
because of the availability of pornography,
there's a whole social context
that's being created around this,
and genuine addiction.
So humans are not like the mice,
or mice are not like the humans.
Humans seem to resolve the issue on their own
in ways that might actually impede
seeking and finding of sexual partners
and or long-term mates.
So a serious issue there, I raise it as a serious issue
that I hear a lot about,
because I get asked hundreds, if not thousands,
of questions about this.
Is there any physiological basis
for what they call nofap.
And I never actually replied because there's no data.
But what you're raising here is a very interesting mechanistic scenario
that can, as you mentioned, is being explored.
So what do we know about the internal state of a mouse
whose VMH is being stimulated or a mouse whose other brain region
that can stimulate the desire to mate?
what do we know about the internal state of that a mouse if it's just alone in the cage wandering
around? Is it wandering around really wanting to mate and really wanting to fight? Of course,
don't know. But is its heart rate up? Is it blood pressure up? Is it wishing that there was
pornography? Is it something's going on, presumably, that's different than prior to that
stimulation and is it arousal and what do you think it is about the visual or olfactory perception
of a con-specific that ungates this tremendous repertoire behaviors right that that that is a central
question i can say at least with respect to the fear neurons that sit on top of the aggression neurons
we know that when those neurons are activated optogenetically in the same way we would activate
the aggression neurons that there's clearly an arousal process that's occurring.
You can see the pupils dilate in the animal.
There is an increase in stress hormone release into the bloodstream.
We've shown that.
Heart rate goes up.
So in addition to the drive to actually freeze, which is what those animals do,
there is autonomic arousal and neuroendocrine activation of stress responses.
And some of that is probably shared by the aggression neurons and the mating neurons,
although we haven't investigated it in as much detail.
But I wouldn't be surprised because they project to many of the same regions that the fear neurons project to,
which is an interesting issue in the context to discuss later maybe in the context of why we're
comfortable with mental illnesses that are based on maladaptations of fear, but not mental
illnesses that are based on maladaptations of aggression if they have pretty similar circuits in the
brain. But that's how I would imagine there is an arousal dimension, as you say. There are stress
hormones that are activated. These regions, VMH projects to about 30 different regions in the brain,
and it gets input from about 30 different regions. So I kind of see it as both an antenna and a
Broadcasting Center. It's like a satellite dish that takes in information from different sensory
modalities, smell, maybe vision, mechanical, mechanosensation. And then it sort of synthesizes and
integrates that into a fairly low dimensional, as the computational people call it, a representation
of this pressure to attack. And it broadcast that all over the brain to trigger all these systems
that have to be brought into play
if the animal is going to engage in aggression.
Because aggression is a very risky thing
for an animal to engage in.
It could wind up losing
and it could wind up getting killed.
And so its brain constantly has to make a cost-benefit analysis
of whether to continue on that path
or to back off as well.
And I think that part of this broadcasting function
of this region is engaging all these other brain
domains that play a role in this kind of cost-benefit analysis. I want to talk more about mating
behavior, but as a segue to that, as we're talking about aggression and mating behavior, I think
hormones. And whenever there's an opportunity on this podcast to shatter a common myth, I grab it.
One of the common myths that's out there, and I think that persists, is that testosterone makes
animals and humans aggressive, and estrogen makes animals placid and kind or emotional.
And as we both know, nothing could be further from the truth, although there's some truth to the
idea that these hormones are all involved. Robert Sapolsky supplied some information to me
when he came on this podcast that if you give people exogenous testosterone, it tends to make
them more of the way they were before. If they were a jerk before, they'll become more of a jerk.
if they were very altruistic, they'll become more altruistic.
And then eventually I pointed out, you'll aromatize that testosterone and estrogen,
and you'll start getting opposite effects.
So it's a murky space.
It's not straightforward.
But if I'm not mistaken, testosterone plays a role in generating aggression.
However, the specific hormones that are involved in generating aggression via VMH are things
other than testosterone.
Can you tell us a little bit more about that?
because there's some interesting surprises in there.
Yeah, that's a really important question.
So when we finally identified the neurons in VMH
that control aggression with a molecular marker,
we found out that that marker was the estrogen receptor.
So that might strike you as a little strange.
Why should aggression-promoting neurons in male mice
be labeled with the estrogen receptor?
Other labs have shown that the estrogen receptor in adult male mice is necessary for aggression.
If you knock out the gene in VMH, they don't fight.
And it's been shown, and a lot of this has work from your colleague, Nirao Shah, at Stanford,
who is one of my former PhD students, that if you castrate a mouse and it loses the ability to fight,
not only can you rescue fighting with a testosterone implant, but you can rescue it with an estrogen
implant. So you can bypass completely the requirement for testosterone to restore aggressiveness to
the mice. And as you say, it's because many of the effects of testosterone, although not all,
many of them are mediated by its conversion to estrogen, by a process called aromatization.
it's carried out by an enzyme called aromatase.
In fact, people may have, most of your listeners may have heard of aromatase,
because aromatase inhibitors are widely used in female humans as adjuvant chemotherapy for breast cancer.
They are a way of reducing the production of estrogen by preventing testosterone from being converted into estrogen.
And in fact, there are a lot of animal experiments showing if you give male,
aromatase inhibitors.
They stop fighting as well as also stop being sexually active.
And so that's one of the counterintuitive ideas.
And Nero has shown that progesterone also seems to play a role in aggression because
these aggression neurons also express the progesterone receptor.
So here are two hormones that are classically thought of as female reproductive hormones.
This is what goes up and goes down during the estrus cycle,
estrogen and progesterone,
and yet they're playing a very important role
in controlling aggression in male mice
and presumably in male humans as well.
Fascinating.
So estrogen is doing many more things
than I think most people believe.
And testosterone is doing maybe different
and fewer things in some cases and more in others.
I've known some aggressive females over the time I've been alive.
What's involved in female aggression that's unique from the pathways that generate male aggression?
Great, great question.
So we and other labs have studied this in both mice and also in fruit flies.
So one thing in mice that distinguishes aggression in females from males is that male mice are pretty much ready to fight at the drop of a hat.
Female mice only fight when they are nurturing and nursing their pups after they've delivered a litter.
And there is a window there where they become hyper aggressive.
And then after their pups are weaned, that aggressiveness goes away.
So this is pretty remarkable that you take a virgin female mouse and expose it to a male.
and her response is to become sexually receptive
and to mate with him.
And now you let her have her pups
and you put the same male or another male mouse in the cage with her
and instead of trying to mate with him, she attacks him.
So there is some presumably hormonal
and also neuronal switch that's occurring in the brain
that switches the response of the female
from sex to aggression
when she goes from virginity to maternity.
And we recently showed in a paper, this is work from one of my students,
among you Liu, that within VMH and females,
there are two clearly divisible subsets of estrogen receptor neurons.
And she showed that one of those subsets controls fighting
and the other one controls mating.
And in fact, if you stimulate the fighting-specific subset in a virgin,
you can get the virgin to attack,
which is something that we were never able to do before.
And if you stimulate the mating one, you enhance mating.
The reason we could never get these results
when we stimulated the whole population of estrogen receptor neurons
is that these effects are opposite and they cancel out.
And so it turns out that if you measure the activity
of the fighting and the mating neurons going from a virgin
to a maternal female,
The aggression neurons are very low in their activity in the virgin,
but once the female has pups,
the activation ability of those neurons goes way up,
and the mating neurons stay the same.
So if you think of the balance between them like a seesaw,
in the virgin, there is more activity in the mating neurons than in the fighting neurons,
whereas in the nursing mother,
there's more activity or more activation in the other way around, the fighting neurons and the
mating. Did I say fighting and mating in the first? Mating neurons dominate fighting in the virgin.
Fighting neurons dominate mating in the mother. So that's a really cool observation and it's not
something that happens in males and we don't know what causes that or controls that.
interestingly, this gets into the whole issue of neurons that are present in females but not in males.
So the field is known for a long time that male and female fruit flies have sex-specific neurons.
And most of the neurons that we've identified in fruit flies that control fighting in males are male-specific.
They're not found in the female brain.
but recently we discovered a set of female-specific fighting neurons in the female brain,
together with a couple of other laboratories.
Now, they do share one common population of neurons in both male and female flies
that in females activates the female-specific fighting neurons,
and in males activates the male-specific fighting neurons.
So it's kind of a hierarchy with this common neuron on top.
And in mice, we discovered that there are male-specific neurons in VMH, and those neurons are
activated during male aggression.
Now, the neurons that are active in females when females fight in VMH are not sex-specific.
So they are also found in males.
So this is already showing you some complexity.
The male mouse VMH has both male-specific aggression neurons and genomes.
Neuric aggression neurons.
And then the female VMH, the mating cells, are only found in females.
They are female-specific and not found in the male brain.
And so we're trying to find out what these sex-specific populations of neurons are doing,
but that indicates that that is some of the mechanism by which different sexes show
different behaviors.
I'm fixated on this transition from the virgin female mouse to the maternal female mouse.
I have a couple of questions about whether or not.
not, for instance, the transition is governed by the presence of pups. So, for instance, if you take
a virgin female, she'll mate with a male. Once she's had pups, she'll try and fight that male or
presumably another intruder female, right? Equally towards females and male intruders.
Does that require the presence of her pups? Meaning, if you were to take those pups and give them to
another mother, does she revert to the more virgin-like behavior? Is it related to, is it triggered by
lactation, or could it actually be triggered by the mating behavior itself? Because it's possible
for the virgin to become a non-virgin, but not actually have a litter of pups.
Right. Those are all great questions, and we don't know the answer to most of them. What I can say
is that a nursing mother doesn't have to have her pups with her in the cage in order to attack
an intruder male or an intruder female. She is just in a state. She is just in a state,
of brain that makes her aggressive to any intruder. And those aggression neurons in that
female's brain are activated by both male and female intruders equally. Whereas in male mice,
the aggression neurons are only ever activated by males, not by females, because males are
never supposed to attack females. They're only supposed to mate with them. So that's another
difference in how those neurons are tuned to signals from different cons specifics. Does it require
lactation? I don't know the answer to that. I think there are some experiments where people have
tried to classical experiments, people have tried to reproduce the changes in hormones that
occur during pregnancy in female rats to see if it can make them aggressive. And some of those
manipulations do to some extent, but there's a whole biology there that remains to be explored
about how much of this is hormones, how much of this is circuitry and electricity, and how much of
it is other factors that we haven't identified yet. I don't want to anthropomorphize, but,
well, I'll just ask the question. So the other day I was watching ferrets mate, right?
They're mustelids and they're mating behavior. I guess I didn't.
say why I was watching this. Doesn't matter. It simply doesn't matter. But if one observes the mating
behaviors of different animals, we know that there's a tremendous range of mating behaviors in humans.
There can be no aggressive component. There could be aggressive component. Humans have all sorts
of kinks and fetishes and behaviors, and most of which probably has never been documented because
most of this happens in private. And here I always say on this podcast, anytime we're talking about
sexual behavior in humans, we're always making the presumption that it's consensual age
appropriate, context appropriate, and species appropriate. Let's say we're talking about a lot of
different species. With that said, just to set context, I was watching this video of ferrets mating
and it's quite violent actually. There's a lot of neck biting, there's a lot of squealing.
If I were going to project an anthropomorphize, I'd say it's not really clear they both want to
be there. One would make that assumption. And of course, we don't know. We have no idea.
This could be the ritual.
it seems to me that there is some crossover of aggression and mating behavior circuitry during the act of mating.
And do you think that reflects this sort of stew of competing neurons that are prioritizing in real time?
Because, of course, as states, they have persistence, as you point out, and you can imagine that states overlapping four different states, the motivational drive to mate, the motivational drive to mate, the motivational
drive to get away from this experience, the motivational drive, to eat at some point,
to defecate at some point. All of these things are competing. And what we're really seeing is a
bias in probabilities. But when you look at mating behavior of various animals, you see an aggressive
component sometimes, but not always. Is it species specific? Is it context specific? And more generally,
do you think that there is cross-stalk between these different neuronal populations and the animal
itself might be kind of confused about what's going on. Right. Great, great questions. I can't really
speak to the issue of whether this is species specific because I'm not a naturalist or a zoologist.
I've seen like you have in the wild, for example, lions when they mate, I've seen them in Africa.
There's often a biting component of that as well. One of the things that surprised us when we
identified neurons in VMVL that control aggression in males is that,
within that population, there is a subset of neurons that is activated by females during
male-female mating encounters. Now, you don't generally think of mouse sex as rough sex,
but there is a lot of what superficially looks like violent behavior sometimes, especially if
the female rejects the male and runs away. And there's some evidence that,
those female selective neurons in VMH are part of the mating behavior. If you shut them down,
the animals don't mate as effectively as they otherwise would. What happens when you stimulate
them, we don't yet know because we don't have a way to specifically do that without activating
the male aggression neurons. But I think they must be there for a reason because VMH,
is not traditionally the brain region to which male sexual behavior has been assigned.
That's another area called the medial preoptic area.
And there we have shown that there are neurons that definitely stimulate mating behavior.
In fact, if we activate those mating neurons in a male while it's in the middle of attacking
another male, it will stop fighting, start singing to that male and start to try to mount that
male until we shut those neurons off. So those are the make love not war neurons and VMH are the make
war not love neurons and there are dense interconnections between these two nuclei which are very
close to each other in the brain. And we've shown that some of those connections are mutually
inhibitory to prevent the animal from attacking a mate that it's supposed to be mating with or to
prevent it from mating with an animal it's supposed to be attacking, but it's also possible that
there are some cooperative interactions between those structures as well as antagonistic interactions
and the balance of whether it's the cooperative or antagonistic interactions that are firing at any
given moment in a mating encounter, as you suggest, may determine whether a moment of a moment of
of coital bliss among two lions may suddenly turn into a snap or a growl and a bearing of fangs.
We don't know that, but certainly the substrate, the wiring is there for that to happen.
I'm sure people's minds are running wild with all this.
I'll just use this as an opportunity to raise something.
I've wondered about for far too long, which is I have a friend who's a psychiatrist who works on the treatment of fetishes.
This is not a psychiatrist that I was treated by.
I don't just point that out.
But they mentioned something very interesting to me long ago,
which is that when you look at true fetishes
and what meets the criteria for fetish,
that there does seem to be some,
what one would think would be competing circuitry
that suddenly becomes aligned.
For instance, avoidance of feces, dead bodies, feet,
things that are very infectious,
typically those states and of disgust are antagonistic to states of desire, as one would
hope is present during sexual behavior.
Fetishes often involve exactly those things that are aversive, feet, dead bodies,
disgusting things to most people.
And true fetishes in the pathologic sense exist when people have a basically a requirement
for thinking about or even the presence of those ordinarily disgusting things in order to become
sexually aroused. As if the circuitry has crossed over. And the statement that rung in my mind was
people don't develop fetishes to mailboxes or to the color red or to random objects and things.
They develop fetishes to things that are highly infectious and counter reproductive appetitive
states. So I find that interesting. I don't know if you have any reflections on that as to
why that might be. I'm tempted to ask whether or not you've ever observed a fetish-like behavior in
mice. But I find it fascinating that you have this area of the brain that's so highly
conserved the hypothalamus in which you have these dense populations intermixed and that
the addition of a forebrain, especially in humans, that can think and make decisions could in some
ways facilitate the expression of these primitive behaviors but could also complicate the expression
of primitive behaviors. Right. I would agree. I think,
One way of looking at fetishes from a neurobiological standpoint is that they represent a kind of
appetitive conditioning where something that is natively aversive or disgusting by being repeatedly
paired with a rewarding experience changes its valence, its sign, so that now it somehow produces
is the anticipation of reward the next time a person sees it. I don't know how, I don't know
that literature in animals. So I don't know if you could condition a mouse to eat feces, for example,
although there are animals that are naturally coprophagic. That is, and maybe mice do that
occasionally, I'm not sure. But that is one way to think about it. And that could certainly involve
in humans, the more recently of all parts.
of the brain, the cortex that is sort of orchestrating both what behaviors are happening and
whether reward states are turning on in association with those behaviors that are happening.
And that's the part that I think is difficult and challenging to study in a mouse,
but certainly bears thinking about because it's a really interesting, again, sort of counterintuitive.
aspect, again, like rough sex, people that want to have fighting or violence or aggressiveness
in order to be sexually aroused and fetishes.
And in fact, when we made that discovery initially, it raised the question in my mind
whether some people that are serial rapists, for example, and engage in sexual violence
might in some level have their wires crossed in some way that these states that are
supposed to be pretty much separated and mutually antagonistic are not and are actually more rewarding
and reinforcing. I think it's going to be a long time before we have figured it out. But when you
think about it, there is no treatment that we have for a violent sexual offender that eliminates the
violence, but not the sexual desire and sexual urge. Whether it's physical castration,
or chemical castration, it eliminates both.
Definitely an area that I think, well, human neuroscience in general needs a lot of tools, right,
in terms of how to probe and manipulate neural circuitry.
I'd love to turn to this area that you mentioned, the medial preoptic area.
I'm fascinated by it because just as within the VMH, you have these neurons for mating
and fighting or aggression.
My understanding is medial preoptic area contains neurons.
for mating, but also for temperature regulation.
And perhaps I'm making too much of a leap here,
but I've always wondered about this phrase, in heat.
Certainly the menstrual and or estrus cycle in females
is related to changes in body temperature.
In fact, measuring body temperature is one way
that women can fairly reliably predict ovulation, et cetera.
Although additional, this is not a show about contraception,
please rely on multiple methods as necessary.
Don't use this discussion as you're,
guide for contraception based on temperature. But if you stimulate certain neurons in the medial
preoptic area, you can trigger dramatic changes in body temperature and or mating behavior.
What's the relationship, if any, between temperature and mating, or do we simply not know?
I don't know what the relationship is between temperature and mating neurons in the preoptic area.
I suspect that they are different populations of neurons
because it's become pretty clear
that the preoptic area has many different subsets of neurons
that are specifically active during different behaviors,
even different phases of mating behavior.
So there are mounting neurons,
they're intramission, thrusting neurons,
and ejaculation neurons and sniffing neurons.
Wait, wait.
So I think I've heard this before,
but I just want to make sure
that people get this. I want to make sure I get this.
So you're telling me within medial preoptic area,
there are specific neurons that if you stimulate them
will make males thrust as if they're mating.
No. So this is not based on stimulation experiments.
It's based on imaging experiments right now,
that we see when we look in the preoptic area
at what neurons are active during different phases of aggression,
we see that there are different neurons that are,
active during sniffing, mounting, thrusting, and ejaculation. And they become repeatedly activated
each time the animal goes through that cycle. During mating. During the mating cycle. There are also
some neurons there that are active during aggression, which are distinct. And we don't know
whether those neurons are there to promote aggression or to inhibit mating when animals are
fighting. We have some evidence that suggests it may be the latter, but we don't know for sure yet.
The thermosensitive neurons are really interesting because you mention the phrase in heat,
and then in the context of aggression, you talk about hot-blooded people or hot heads.
There's just recently a paper showing there are thermoregulatory neurons in VMH as well.
So all of these homeostatic systems for metabolic control and temperature control are interoperative,
intermingled in these nuclei, these zones that control these basic survival behaviors like mating
and aggression and predator defense. And I would imagine that the thermoregulation is tightly
connected to energy expenditure and that again these neurons are mixed together to facilitate
integration of all these signals by the brain in some way that we don't understand.
to maintain the proper balance between energy conservation and energy consumption during this
particular behavior or that behavior.
I mean, I've always been fascinated by the question, why is it that violence goes up in
the summertime when the temperatures are high?
Does it really have something to do with the idea that increased temperature increases
violence?
It seems hard to believe because we're homeothermic and we're,
pretty much stay around 98.6 Fahrenheit.
It could be other social reasons why that happens.
People are outside out on the street bumping into each other.
But I think there could well be something
that ties thermal regulation to aggressiveness
as well as to mating behavior.
Fascinating, yeah.
I asked in the hopes that in maybe in the years to come,
your lab will parse some of the temperature
relationships. And I realize it could be also regulated by hormones in general. So it's tapping into
two systems for completely different reasons. But anyway, an area that intrigues me because of this
notion of hot-headedness or cool, calm, and collected. And also the fact that I probably should
have asked about this earlier, that arousal itself is tethered to the whole mating and reproductive
process. I mean, without a sort of seesawing back between the sympathetic and parasympathetic, you know,
Rousal, relaxed states, there is no mating that will take place.
So it's fascinating the way these different competing forces and seesaws operate.
Several times during the discussion so far, we've hit on this idea that the same behavior can reflect different states
and different states can converge on multiple behaviors as well.
You had a paper not long ago about mounting behavior, which I found fascinating.
Maybe you could tell us about that result.
Because to me, it really speaks to the fact that mounting behavior can, in one context, be sexual and in another context, actually be related to, we presume, dominance.
And I think that my friends who practice jujitsu will say, they, when I talk about that result, they say, of course, you know, mounting the other person and dominating them.
There's nothing sexual about it.
It's about overtaking them physically, literally being on their next side, as opposed to,
on their own, lying on their own back.
Just fascinating, very primitive, and yet, I think speaks to this idea that mounting behavior
might be one of the most fundamental ways in which animals and perhaps even humans express
dominance and or sexual interactions.
Yep.
That's a fascinating question, and it was harder to figure out than you might have thought.
So there's been this debate for a long time in the field when you see.
to male mice mounting each other.
Is this homosexual behavior?
Is this a case of mistaken sexual identification?
Or is this dominance behavior?
And if you train an AI algorithm to try to distinguish male-male mounting from male-female
mounting, it does not do a very good job because motorically, those behaviors look so
similar. And so how did we wind up figuring out that most male-male-male mounting is dominance-mounting?
There are two important clues. One is the context. And so male-male-mail mounting tends to be more
prominent among mice when they haven't had a lot of fighting experience. And then as they become more
experienced in fighting, they will show relatively less mounting towards the other male and more
attack. And they'll transition quickly from mounting to attack. And so the mounting is always seen
in this context of an overall aggressive interaction. And then the second thing, which believe it or not,
was suggested by a computational theoretical person in my lab, Anne Kennedy, who now is her own lab at
Northwestern, she said, well, males are known to sing when they mount females, ultrasonic vocalizations.
Why don't you see what kinds of songs they're singing when they're mounting males?
Maybe it's a different kind of song.
Well, what we found out is they don't sing at all when they're mounting a male.
So you can easily distinguish whether mounting behavior by a male mouse is reproductive
or agonistic, aggressive, according to whether it's accompanied by ultrasonic vocalizations or not.
And it turns out that different brain regions are maximally active during these different types of mounting.
So VMH, the aggression locus, is actually active during dominance mounting,
and you can stimulate mounting if you, dominant mounting, if you weakly activate VM.
whereas MPOA is most strongly activated during sexual mounting, and that's always accompanied
by the ultrasonic vocalization.
So this shows how difficult and dangerous it can be to try to infer an animal state or intent
or emotion from the behavior that it's exhibiting, because the same behavior can mean very
different things depending on the context or the interaction with the animal.
And I would say even more so with when that animal,
as a human or is multiple humans.
That's right.
And there are many examples.
You know, animals show chasing to obtain food, a prey animal that they're going to kill and
eat, and they show chasing to obtain a mate that they're going to have sex with.
And so the intent of the chasing is completely different.
And we don't know in all these cases whether there are separate circuits or common circuits
that are being activated.
I'm obsessed with dogs and dog breeds and et cetera, et cetera.
And one thing I can tell you is that female dogs will mount and thrust.
We had a female pit bull mix, a very sweet dog.
But in observing her, it convinced me that one can never assume that male dogs are more aggressive than female dogs.
It turns out in talking to people where it was quite skilled at dog genetics and dog breeding,
that there's a dominance hierarchy within a litter
and it crosses over male-female delineations.
So you can get a female in the litter
that's very dominant and a male that's very subordinate
and no one really knows what relates to.
This is also why little dogs sometimes
will get right up in the face of a big Doberman pincher
and just start barking,
which is an idiotic thing for it to do,
but they can be dominant over a much larger dog.
Very strange to me anyway.
Female female mount.
Do you observe it in mice?
Are there known circuits?
And what evokes female-female mounting or female-to-male mounting if it occurs?
Good.
Yes, there is female.
There are clear examples of females displaying male-type mounting behavior towards other females.
We see this most commonly in the lab where we are housing females with their sisters, say, three or four in a cage.
we take one out and we have her mate with a male where the male's doing the mounting.
Now we take that female and we put her back in the cage with her litter mates and she starts mounting them.
Now what the function of that is, if it has any function or what it means, what's driving it, we don't know.
But we do know that if we stimulate the neurons of control mounting in males in the medial preoption.
area, if we stimulate that same population in females, it evokes male-type mounting towards either
a male or a female target. In fact, we have a movie where we have a female that has just been
mounted by a male, so the male's on top and she's underneath, and we stimulate that region of
MPOA and the female, and she crawls out from underneath the male who has just mounted her,
circles around behind him and climbs up on top of him and starts to try to mount him and thrust at him.
That has a name online. It's called a switch.
Is that right?
Don't ask me how I know that.
Okay.
But it's a pretty, yeah, it's a term that you hear.
You also hear the term topping from the bottom, which it sounds like that is a literal topping from the bottom.
That's more of a psychological phrase from what I hear.
I have friends that are educating me in this language.
mostly because I find this kind of neurobiological discussion fascinating.
At some point, right, I attempt in my mind to superimpose observations
from the online communities that I'm told about and asked about to this.
But I should point out it's always dangerous.
And in fact, inappropriate to make a one-to-one link.
Humans are, they maintain all the same neural circuitry and pathways
that we're talking about today in mice.
but that forebrain does allow for context, et cetera.
Yep.
So what the function is of female mounting,
I don't know, it could be a type of dominance display.
It's hard to measure that
because people haven't worked on female dominance hierarchies
to the same extent that they've worked on male dominance hierarchies,
but it indicates that the circuits for male-type mounting
are there in female.
as early work from Catherine Dulaq suggested some years ago.
Fascinating.
Fascinating.
I love that paper because as you pointed out for Chase,
you know, for mounting behavior, you know, we see it and we think one thing specifically.
And after hearing this result, actually, I'm not a big fan of fight sports.
I watch them occasionally because friends are into them.
But I've seen boxing matches, MMA matches where at the end of a round,
if someone felt that they dominated,
they will do the unsportsman-like thing
of thrusting on the back of the other person
before they get off, almost like I dominated you.
So mimicking sexual-like behavior,
but there's no reason to think that it's sexual,
but they're sending a message of dominance
is what implies.
I'd love to talk about something slightly off from this circuitry,
but I think that's related to the circuitry,
at least in some way, which is this structure
that I've always been fascinated by,
and I can't figure out what the hell it's for,
because it seems to be involved in everything,
which is the PAG, the periacqueductal gray,
which is a little bit further back in the brain
for people that don't know.
It's been studied in the context of pain.
It's been studied in the context of the so-called lordosis response,
the receptivity or arching of the back of the female
to receive intramission and mating from the male.
How should we think about PAG?
Clearly, it can't be involved in everything.
I'm guessing it's at least as complex as some of these other regions.
that we've been talking about, different types of neurons controlling different things.
But how does PAG play into this?
In particular, I want to know, is there some mechanism of pain modulation and control
during fighting and or mating?
And the reason I ask is that while I'm not a combat sports person years ago,
I did a little bit of martial arts.
And it always was impressive to me how little it hurt to get punched during a fight
and how much it hurt afterwards.
Right?
So there clearly is some endogenous pain control that then wears off and then you feel beat up.
Yep.
Or at least in my case, I felt beat up.
What's PAG doing vis-a-vis pain and what's pain doing vis-a-vis these other behaviors?
Good.
Good.
So I think of PAG like a old-fashioned telephone switchboard where there are calls coming in and then the cables have to be punched into the right hole to get the
information to be routed to the right recipient on the other end of it, because pretty much every
type of innate behavior you can think of has had the PAG implicated. And there's a whole literature
showing the involvement of the PAG in fear, different regions of the PAG, the dorsal PAG is involved
in panic-like behavior, running away, the ventral PAG is involved in freezing behavior. Both
the MPOA and VM send projections to the PAG to different regions of the PAG.
So in cross-section, I hate to say this, but in cross-section, the PAG kind of looks like the water
in a toilet when you're standing over an open toilet bowl.
And if you imagine a clock face projected onto that, it's like the PAG has sectors from one to 12,
maybe even more of them,
and in each of those sectors,
you find different neurons
from the hypothalamus are projecting.
So it could turn out
that there is a topographic arrangement
along the dorsal ventral axis of the PAG
and the medialateral axis of the PAG
that determines the type of behavior
that will be emitted
when neurons in that region are stimulated.
And I think sort of all of the evidence
is pointing in that direction,
but by no means has it been massive?
out. Now, the thing that you mentioned about it not hurting when you got beat up during martial
arts, there is a well-known phenomenon called fear-induced analgesia, where when an animal is in a high
state of fear, like if it's trying to defend itself, there is a suppression of pain responses.
And I'm not sure completely about the mechanisms and how well that's understood, but for example,
the adrenal gland has a peptide in it that is released from the adrenal medulla, which controls
the fight or flight responses, and that peptide has analgesic activities.
Now, whether...
It's called bovine adrenal medullary peptide of 22 amino acid residues.
only know about it because it activates a receptor that we discovered many years ago that's involved
in pain. And we thought it promoted pain, but it turns out that this actually inhibits pain.
It's like an endogenous analgesic. Whether this is happening, this type of analgesia is happening
when an animal is engaged in offensive aggression or in mating behavior, I don't know. But it certainly is
possible. And I don't know whether these analgesic mechanisms are happening in the PAG. They could also
be happening a little further down in the spinal cord. The PAG is really continuous with the spinal cord.
If you just follow it down towards the tail of an animal, you will wind up in the spinal cord.
And so it could be that there are influences acting at many levels on pain in the PAG and in the spinal cord as well.
and it may well be known
I just don't know it
I want to distinguish clearly
between things that are not known
that I know are unknown
which is in a fairly small area
where I have expertise
from things that may be known
but I'm ignorant of them
because I just don't have
a broad enough knowledge base to know that
sure we appreciate those delineations
thank you
I think this description of it
is an old-fashioned telephone switchboard
and now every time
look into the toilet, I'll think about the peri-aqueductal gray.
And every time I see an image of peri-aqueductal gray, I think about a toilet.
That is an excellent description because, in fact, I drew a circle with a little thing at the bottom.
Well, I'll put a post or link to a picture of PAG and you'll understand why David and I are chuckling
here because indeed it looks like a toilet when staring into a toilet.
Tell us about Tachy Kynen.
I've talked about this a couple times on different podcast episodes because of its relationship
to social isolation.
And in part because the podcast was launched
during a time when there was more social isolation,
my understanding is that Tachykinen,
and you'll tell us what it is in a moment,
is present in flies and mice and in humans
and may do similar things in those species.
That's right.
So Tachykinen refers to a family of related neuropeptides.
So these are brain chemicals.
They're different from dopamine and serotonin in that they're not small organic molecules.
They're actually short pieces of protein that are directly encoded by genes that are active in specific neurons and not in others.
And when those neurons are active, those neuropeptides are released together with classical transmitters like glutamate, whatever.
Tachycinins have been famously implicated in pain,
particularly tachykinin 1, which is called substance P, one of the original pain modulating.
This is something that promotes inflammatory pain.
But there are other tachykinin genes.
In mice, there are two.
In humans, I think there are three.
And in Drosophila, there is one.
And the way we got into tachycinins is from studying aggression in flies, we thought, since neuropeper
Neuropeptides have this remarkable parallel evolutionary conservation of structure and function
like neuropeptide Y controls feeding in worms, in flies, and mice, and in people.
Oxytocin-like peptides control reproduction in worms and mice and in people.
We thought we might find peptides that control aggression in flies and in people.
And so we did a screen, unbiased screen of peptides and found indeed that one of the tachykinins,
Drosophila tachykinin, those neurons, when you activate them, strongly promote aggression.
And it depends on the release of tachycinin.
Now, the interesting thing is that in flies, just like in people and practically any other social animal that shows aggression,
social isolation increases aggressiveness.
So putting a violent prisoner in solitary confinement is absolutely the worst, most counterproductive thing you could do to them.
And indeed, we found in flies that social isolation increases the level of tachycinin in the brain.
And if we shut that gene down, it prevents the isolation from increasing aggression.
So since my lab also works on mice, it was natural to see whether tachycinins might be upregulmonary.
in social isolation and whether they play a role in aggression.
And this is work done by a former postdoc,
Moriel Zelikovsky, now at University of Salt Lake City in Utah.
And she found remarkably that when mice are socially isolated for two weeks,
there is this massive upregulation of tachycinin 2 in their brain.
In fact, if you tag the peptide with a green fluorescent protein from a jellyfish,
genetically. The brain looks green when the mice are socially isolated because there's so much of
this stuff released. And she went on to show that that increase in tachy-kinen is responsible for the
effect of social isolation to increase aggressiveness and to increase fear and to increase anxiety.
And in fact, there are drugs that block the receptor for tachy-kynin, which were tested in humans,
and abandoned because they had no efficacy in the tests that they were analyzed for.
If you give those drugs to a socially isolated mouse, it blocks all of the effects of social
isolation. It blocks the aggression. It blocks the increased fear and the increased anxiety.
And that Moriel described it, the mice just looked chill. It's not a sedative, which is really
important. It's not that the mice are going to sleep. Most remarkably,
is once you socially isolate a mouse and it becomes aggressive,
you can never put it back in its cage with its brothers from its litter
because it will kill them all overnight.
But if you give it this drug, which is called osanatant,
that blocks Tachykinen too,
that mouse can be returned to the cage with its brothers
and will not attack them and seems to be happy about that for the rest of the time.
So this is an incredibly powerful effect of this drug,
and I've been really interested in trying to get pharmaceutical companies
to test this drug, which has a really good safety profile in humans,
in testing it in people who are subjected to social isolation stress
or bereavement stress.
And this is one of the areas where I learned an eye-opening lesson
as a basic scientist who naively thought that if you make a discovery and it has
translational applications to humans that pharmaceutical companies are going to be falling all over
themselves to try it. And they are not interested because once burned twice shy. These drugs
were tested for efficacy in schizophrenia. I have no idea why. There's very little preclinical
data to suggest that. Not surprisingly, they failed. When a drug fails in clinical trials in phase
three, it costs $100 million to the company that carried out that clinical trial. So there's a huge
slag heap of discarded pharmaceuticals, many of them inhibitors of neuropeptide action, that could be
useful in other indications, such as the one we discovered, but there's a huge economic disincentive
for pharmaceutical companies to test them again because the conclusion that they drew from all
these failed tests, particularly in the 2010s and before that, is that the reason they failed
is because animal experiments with drugs don't predict how humans will respond to.
of the drugs. And therefore, we shouldn't try to extrapolate from any other data that we get from
animal experiments, mouse or rat experiments to humans, because they'll lead us down the wrong
track. And I think that that is probably wrong. In some cases, it may be right, but in other
cases, there's good reason to think because these brain regions and molecules are so evolutionarily
conserved, that they ought to be playing a similar role in humans. In fact, there is a paper
showing that in humans that have a borderline personality disorder, there is a strong correlation
between their self-reported level of aggressiveness and serum levels of a tachy-kinin, in this case,
Tachykinin 1, as detected by radioimmune assay. This is work of Emil Koucaro, who's
a clinical psychiatrist at the University of Chicago. So there is a smoking gun in the case of humans as
well. And I was actually trying to interest a pharmaceutical company that was testing these drugs
actually for treatment of hot flashes in females, in humans, where there is actually good
animal data to think that it might be useful. But I realized that this clinical trial was
going on during the COVID pandemic.
And I approached him and said, look, nature may have actually done for you the experiment
that I want you to do because some of the people who are getting drug or placebo are going
to have been socially isolated and some of them will have not.
Why don't you get them to fill out questionnaires and see whether the ones who are given
the drug and socially isolated felt less stressed and less anxious than the ones who were not
socially isolated and they would not touch it because they're in the middle of a clinical trial
for a different indication for this drug and they have to report any observation that they make
about that drug in their patient population. So if they were to ask these questions and get an
unfavorable answer, oh my God, I felt even worse when I took this drug and I was isolated,
they would be obliged to report that to the FDA,
and that could torpedo the chances for the drug being approved
in the thing that it was in clinical trials for.
So it's better not to ask and not to know
than it is to try to find out more information
that could lead to another clinical indication.
So I remain convinced that this family of drugs
could have very powerful uses in treating some forms
of stress-induced anxiety or aggressiveness in humans,
but it's just very difficult for economic reasons
to find a way to get somebody to test that.
Yeah, a true shame that these companies won't do this,
and especially given the fact that many of these drugs exist
and their safety profiles are established,
because that's always a serious consideration
when embarking on a clinical trial.
Perhaps in hearing this discussion,
someone out there will understand
the key importance of this and we'll reach out to us. We'll provide ways to do that to get such a
study going in humans. Because I think if enough laboratories ran small-scale clinical trials,
pharma certainly would perk up their ears, right? I mean, they're so strategic sometimes to their own.
I mean, I would just, I would like to say also, I'd like to see this tested on pets. I mean,
there's a huge number of pets right now that are suffering separation anxiety because,
Humans bought them to keep them company during the COVID pandemic.
And now they're home alone.
And if this thing works in mice, there's certainly a higher chance.
It's going to work in dogs or in cats than it is going to work in humans.
And if it did, that would be even more encouragement to continue along those lines.
People sometimes forget that although we work on animals and we ultimately want to understand humans,
we care about how our results apply to the welfare of animals.
as well, and particularly domestic pets, which is a billion, multi-billion dollar industry in this
country. So if there's ways that they can be made to feel better when they're separated from
their owners, that would certainly be a good thing. Absolutely. We will put out the call.
We are putting out the call. And I know for sure there will be a response. Just underscoring what
we've been talking about even more, every time we hear about a school shooting, like in Texas,
recently or I happened to be in New York during the time
when there was a subway shooting.
For whatever reason, I listened to the book
about Columbine that went into a very detailed way
about the origin of those boys and that committed that.
And every single time, there's the person who commits those acts
is socially isolated.
As far as I know, there might be some exceptions there.
And sometimes this crosses over with other mental health issues,
but sometimes no, no apparent mental health issues.
health issues. So social isolation clearly drives powerful neurochemical and neurobiological changes.
I really hope that tachykinin 1 and 2, those are the main ones in humans, will be explored
in more detail. Also, I didn't know that tachykindin 1 is Substance P and substance P and substance B and
is tackykindin 1. Tachykinin 1 is the gene name and tachykinin 2 in humans is called Neurokinen
B. That's the name of the protein. I just refer to it by the gene name because it makes it easier and I
have to keep remembering two names for each thing.
And I, if I'm not mistaken, you see your, you put yourself in the company of geneticists
because of your original training was in genetics immunology and areas related to that.
It was in cell biology and I didn't actually have formal training in genetics as a graduate
student, but I think I'm a geneticist at heart.
That's just the way I like to think about things.
And when I started working on flies, that sort of I came out of the closet as a geneticist,
doesn't work. Wonderful. As long as we're talking about humans, I'd love to get your thoughts about
human studies of emotion. I know you wrote this book with Ralph Adolfs. You have this new book,
which will provide a link to which I've read front to back twice. It's phenomenal. I've mentioned it
before on the podcast. It's really, there are books that are worth reading and then there are books
that are important. And I think this book is truly important for the general population to read
and understand. And neuroscientists should read and understand the contents because we as a culture,
are way off in terms of how we think about emotions and states and behaviors.
So we'll put a link to that. It's really worth the time and energy to read it.
And it's written beautifully, I should say, very accessible even for non-scientists.
There's a heat map diagram in that book that I think about.
This is a heat map diagram of subjective reports that people gave of where they
experience an emotion or a feeling, a somatic feeling in their body or in their body or in their
their head or both when they are angry, sad, calm, lonely, et cetera, et cetera.
And I wouldn't want people to think that those heat maps were generated by any
physiological measurement because they were not.
And yet, I don't think we can have a discussion about emotions and states and the sorts
of behaviors that we're talking about today without thinking about the body also.
Yep.
And I'm not coming to this as a Northern California mind body.
I've been to Esselin once.
I didn't go in the baths.
I went there, I gave a talk and I left.
It is very beautiful.
If anyone wants to know what it looks like,
I think that final scene of Mad Men is shot at Esselin.
It's a very beautiful place.
And yet, mind body is a neurobiological construct
because the nervous system extends
through the out of the cranial vault
and into the spinal cord and body and back and forth.
Okay.
How should we think about the body
and in terms of states?
And at some point,
I'd love for you to comment on that heat map experiment,
because it does seem that there's some regularity
as to where people experience emotions.
When people are in a rage, for instance,
they seem to feel it both in their gut and in their head,
it seems, on average.
And people love to extrapolate to gut intuition
or that the chakras or anger is in the stomach
and this goes to Eastern medicine, et cetera.
How should we think about mind-body in the context of states?
and think about it as scientists, maybe even as neuroscientists or geneticists.
Good.
So for the answer to the first question about the heat maps and people associating certain parts of their body with certain emotional feelings,
this goes back to something called the somatic marker hypothesis that was proposed by Antonio Demosio,
who is a neurologist at USC,
the idea that our subjective feeling of a particular emotion
is in part associated with a sensation of something happening
in a particular part of our body.
The gut, the heart, I don't see the liver invoked very much
in emotional characterization.
But a gall and the gall.
somebody having a lot of gall. I don't know why I make a fist when I say that, but I'm guessing the gallbladder
is shaped like a fist. That's right. And, you know, if there is a physiology underlying these heat maps,
it could reflect increased blood flow to these different structures. And that in turn reflects what you were
talking about, that is emotion is definitely involves communication between the brain and the body,
and it's bidirectional communication. And it's mediating. And it's mediated.
by the peripheral nervous system, the sympathetic and the parasympathetic nervous system,
which control heart rate, for example, blood vessel, blood pressure, and those neurons
receive input from the hypothalamus and other blood brain regions, central brain regions,
that control their activity. And when the brain is put in a particular state, it activates
sympathetic and parasympathetic neurons, which have effects on the heart and on blood pressure,
and these in turn feed back onto the brain through the sensory system. And a large part of this
bidirectional communication is also mediated through the vagus nerve, which many of your
listeners and viewers may have heard about because it's become a topic of intense activity now. People have
known for a long time. So the vagus nerve is a bundle of nerve fibers that comes out basically of your
skull, out of the central nervous system, and then sends fibers in to your heart, your gut,
all sorts of visceral organs. So when you have a, and that information is both, you used the
words earlier in our discussion, afferent and even.
So the vagal fibers sense things that are happening in the body.
So the reason you feel your stomach hide up in knots if you're tense is that those vagal fibers
are sensing the contraction of the gut muscles.
And they're also afference, which means that information coming out of the brain can influence
those peripheral organs as well.
And there's work from a number of labs just in the last six months or so where people are starting to decode the components of the different fibers in the vagus nerve.
And it's amazing how much specificity is.
There are specific vagal nerves that go to the lung, that control breathing responses, that go to the gut, that go to other organs.
it's almost like a set of color-coded lines, labeled lines for those things.
And now how those vagal afference play a role in the playing out of emotion states
is a fascinating question that people are just beginning to scrape the surface of.
But I think what's exciting now is that people are going to be developing tools
that will allow us to turn on or turn off specific subsets of five.
fibers within the vagus nerve and ask how that affects particular emotional behaviors.
So you're absolutely right.
This brain-body connection is critical, not just for the gut, but for the heart, for the lungs,
for all kinds of other parts of your body.
And Darwin recognized that as well.
And I think it's a central feature of emotion state.
And I think what underlies are subjective feelings of an emotion.
Incredible.
David, I have to say as a true fan of the work that your lab has been doing over so many decades,
and first of all, I was delighted when you stopped working on stem cells,
not because you weren't doing incredible work there,
but because I saw a talk where you showed a movie of an octopus spitting out,
or not spitting, but squirting out a bunch of ink and escaping,
and you said you were going to work on things of the sort that we're talking about today,
fear, aggression, mating behaviors, social behaviors.
It's been incredible to see the work that you're like.
lab is done. And I know I speak on behalf of, I know I speak on behalf of a tremendous number of people
and I say thank you for taking time out of your important schedule to share with us what you've
learned. My last question is a simple one, which is, will you come back and talk to us again in
the future about the additional work that's sure to come? I would be happy to do that.
And I really have appreciated your questions. They're all, they've all been right on the money.
you've hit all of the critical, important issues in this field,
and you've uncovered what is known, the little bit is known,
and how much is not known.
And I think it's important to emphasize the unknown things
because that's what the next generation of neuroscientists has to solve.
And so I hope this will help to attract young people into this field
because it's so important, particularly for our understanding of mental illness,
and mental health and psychiatry,
we've got to figure out how emotion systems are controlled
in a causal way if we ever want to improve
the psychiatric treatments that we have now.
And that's going to require the next generation
of people coming into the field.
Absolutely.
I second that.
Well, thank you.
It's been a delight.
Thank you.
Great.
Really appreciate it.
Thank you for joining me today for my discussion
with Dr. David Anderson.
Please also be sure to check out his new book,
The Nature of the Beast, How Emotions Guide Us.
It's a truly masterful exploration
of the biology and psychology
behind what we call emotions and states of mind and body.
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