Animal Behavior - CrashCourse Biology #25

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Behavior is action in response to a stimulus.

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My cat Cameo is now responding to both an external stimulus

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the sound of a bag of treats, and an internal stimulus

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her hunger, or at least her insatiable desire for treats.

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Sometimes animal behavior can seem really far out,

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but if you look closely enough,

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you can see how all behavior serves a purpose

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to help an animal mate, eat, avoid predators, and raise young.

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And since behaviors can come with advantages like these,

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natural selection acts on them just as it acts on physical traits

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ensuring the success of animals who engage

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in beneficial behaviors, while weeding out those that do stupid,

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dangerous or otherwise unhelpful stuff.

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The most beneficial behaviors are those that make an animal

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better at doing the only two things in the world that matter:

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eating and sex.

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Still, that doesn't mean all behavior is about

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just looking out for number one.

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It turns out some advantageous behavior

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is actually pretty selfless.

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More on that in a minute.

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But first, behavior is really just a product of a pair of factors:

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Morphology, or the physical structure of an animal

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and physiology, or the function of that morphology.

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Now, an animal's behavior is obviously limited

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by what its body is capable of doing

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for example, Cameo does not have opposable thumbs,

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so, much as she would like to get into the treat bag,

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by herself, she cannot.

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This limitation is strictly hereditary

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no cats can open treat bags with their thumbs

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because no cats have opposable thumbs.

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Though some cats do have thumbs.

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In the same way that a penguin can't fly to escape a predator;

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or a gazelle can't reach the same leaves as a giraffe can.

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Similarly, behavior is constrained by an animal's physiology.

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Like, Cameo's built for chasing down little critters

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and eating meat, not beds of lettuce.

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This is because her physiology, everything from her teeth

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to her digestive system, are geared for eating meat.

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If she pounced on and ate every blade of grass she came across...

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let's just say I would not want to be in charge of that litter box.

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Now the traits that make up an animal's morphology

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and physiology are often heritable,

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so we generally talk about selection acting on those traits.

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But as natural selection hones these traits,

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it's really selecting their associated behaviors.

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It's the USE of the trait,

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using wings and feathers to escape predators,

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or using a long neck to reach leaves,

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that provides the evolutionary advantage.

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Still, that doesn't mean all behavior is coded

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in an animal's genes

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some behaviors are learned.

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And even for animals that learn how to do things,

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natural selection has favored brain structures

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that are capable of learning.

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So one way or another,

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most behaviors have some genetic underpinning,

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and we call those behaviors adaptive.

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Problem is, it's not always obvious

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what the evolutionary advantages are for some of the nutty things

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that animals do.

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Like, why does a snapping turtle always stick out its tongue?

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How does a tiny Siberian hamster find its mate,

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miles across the unforgiving tundra?

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Why does a bower bird collect piles of garbage?

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To answer questions like those,

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we have to figure out what stimulus causes these behaviors,

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and what functions the behaviors serve.

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To do this, I'm going to need the help of one of the first

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animal behavior scientists ever, or ethologists, Niko Tinbergen.

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Tinbergen developed a set of four questions

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aimed at understanding animal behavior.

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The questions focus on how a behavior occurs,

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and why natural selection has favored this particular behavior.

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Determining how a behavior occurs actually involves two questions:

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One: what stimulus causes it?

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And two: what does the animal's body do

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in response to that stimulus?

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These are the causes that are closest

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to the specific behavior we're looking at,

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so they're called the proximate causes.

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In the case of the male Siberian hamster,

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the stimulus is a delicious smelling pheromone

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that the sexy female hamster releases when she's ready to mate.

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The male hamster's response, of course, is to scuttle,

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surprisingly quickly, over several miles if necessary

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to find and mate with her.

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So the proximate cause of this behavior

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was that the girl hamster signaled that she was ready to knock boots,

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and the male ran like crazy to get to the boot-knockin'.

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Asking the more complex question of why natural selection

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has favored this behavior requires asking two more questions:

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One: what about this behavior helps this animal survive

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and/or reproduce?

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And two: what is the evolutionary history of this behavior?

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These, as you can tell, are bigger-picture questions,

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and they show us the ultimate causes of the behavior.

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The answer to the first question, of course,

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is that the ability of a male hamster to detect and respond

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to the pheromones of an ovulating female is directly linked

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to his reproductive success!

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As for the second question, you can also see that male hamsters

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with superior pheromone detectors will be able to find females

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more successfully than other male hamsters,

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and thereby produce more offspring.

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So natural selection has honed this particular physical ability

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and behavior over generations of hamsters.

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So, who would have thought to ask these questions in the first place?

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And where's my chair?

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Niko Tinbergen was one third of a trifecta

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of revolutionary ethologists in the 20th century.

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Along with Austrians Karl von Frisch and Konrad Lorenz,

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he provided a foundation for studying animal behavior

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and applied these ideas to the study of specific behaviors

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and for that all three shared the Nobel Prize in 1973.

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You may have seen the famous photos of young graylag geese

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following obediently in a line behind a man.

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That was Lorenz, and his experiments

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first conducted in the 1930s introduced the world to imprinting,

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the formation of social bonds in infant animals,

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and the behavior that includes both learned and innate components.

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When he observed newly hatched ducklings and geese,

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he discovered that waterfowl in particular

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had no innate recognition of their mothers.

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In the case of graylag geese, he found the imprinting stimulus

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to be any nearby object moving away from the young!

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So when incubator-hatched goslings spent

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their first hours with Lorenz,

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not only did they follow him,

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but they showed no recognition of their real mother

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or other adults in their species!

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Unfortunately, Lorenz was also a member of the Nazi party

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from 1938 to 1943.

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And in response to some of his studies

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on degenerative features that arose in hybrid geese,

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Lorenz warned that it took only a small amount

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of "tainted blood" to have an influence on a "pure-blooded" race.

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Unsurprisingly, Nazi party leaders were quick to draw

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some insane conclusions from Lorenz's behavioral studies

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in the cause of what they called race hygiene.

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Lorenz never denied his Nazi affiliation

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but spent years trying to distance himself from the party

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and apologizing for getting caught up in that evil.

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Now how exactly does natural selection act

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on behavior out there in the world?

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That's where we turn to those two types of behavior

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that are the only things in the world that matter:

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eating and sex-having.

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Behavior associated with finding and eating food

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is known as foraging, which you've heard of,

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and natural selection can act on behaviors that allow animals

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to exploit food sources

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while using the least amount of energy possible

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this sweet spot is known as the optimal foraging model.

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And the alligator snapping turtle has optimal foraging

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all figured out.

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Rather than running around hunting down its prey,

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it simply sits in the water, and food comes to him.

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See, the alligator snapping turtle has a long, pink tongue

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divided into two segments, making it look like a tasty worm

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to a passing fish.

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In response to the stimulus of a passing fish,

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it sticks out its tongue out and wiggles it.

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Natural selection has, over many generations,

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acted not only on turtles with pinker and more wiggly tongues

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to catch more fish, it's also acted on those that best know how

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and when to wiggle those tongues to get the most food.

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So it's selecting both the physical trait

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and the behavior that best exploits it.

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And what could be sexier than a turtle's wiggly tongue dance?

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Well, how about sex?

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As we saw with our friend the horny Siberian hamster,

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some behaviors and their associated physical features

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are adapted to allow an animal to reproduce more,

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simply by being better at finding mates.

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But many times, animals of the same species live close together

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or in groups, and determining who in what group gets to mate

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creates some interesting behaviors and features.

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This is what sexual selection, is all about.

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Often, males of a species will find and defend a desirable habitat

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to raise young in, and females will choose a male

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based on their territory.

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But what about those species, and there are many of them,

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where the female picks a male not because of that,

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but because of how he dances, or even weirder,

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how much junk he's collected?

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Take the male bower bird.

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He builds an elaborate hut, or bower, out of twigs

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and bits of grass, then spends an enormous amount of time

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collecting stuff, sometimes piles of berries,

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and sometimes piles of pretty, blue, plastic crap.

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Ethologists believe that he's collecting the stuff

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to attract the female to check out his elaborate house.

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Once the female's been enticed to take a closer look,

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the male starts to sing songs and dance around,

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often mimicking other species, inside of his little house for her.

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Females will inspect a number of these bowers

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before choosing who to mate with.

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Now, doing more complex dances and having more blue objects

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in your bower scores bigger with females.

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And ethologists have shown that a higher level of problem solving,

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or intelligence, in males correlates

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to both of these activities.

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So yeah, it took some brawn to build that bower

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and collect all that junk, but chicks also dig nerds

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who can learn dances!

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So the bowerbird's brain is evolving in response

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to sexual selection by females.

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This intelligence likely also translates

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into other helpful behaviors like avoiding predators.

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So thanks to the evolution of behavior,

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we're really good at taking care of our nutritional and sexual needs.

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But what's confused scientists for a long time

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is why animals often look after others' needs.

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For instance, vampire bats in South America will literally

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regurgitate blood into the mouths of members of its clan

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who didn't get a meal that night.

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How do you explain animals who act altruistically like that?

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We actually did a whole SciShow episode on this very subject

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but basically, we can thank British scientist William Hamilton

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for coming up with an equation to explain how natural selection

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can simultaneously make animals fit and allow for

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the evolution of altruism.

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Hamilton found that the evolution of altruism

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was best understood at the level of larger communities,

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especially extended animal families.

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Basically, altruism can evolve if the benefit of a behavior

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is greater than its cost on an individual,

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because it helped the individual's relatives enough

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to make it worth it.

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Hamilton called this inclusive fitness,

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expanding Darwin's definition of fitness

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basically, how many babies somebody's making

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to include the offspring of relatives.

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So I guess the only question left is,

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if I forget to feed you two,

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who is going to regurgitate blood into the other one's mouth?

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Yeah, there's probably a reason that only happens with bats.

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Thank you for watching this episode of Crash Course Biology.

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Thank you to Cameo for being such a good kitty.

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Yeah, she finally gets her treats.

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There's a table of contents, of course.

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If you want to reinforce any of the knowledge that you gained today.

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If you have questions or ideas for us you can get in touch

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with us on Facebook or Twitter, or of course, in the comments below.

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We'll see you next time.