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By this point in the biology playlist,
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you're probably wondering a very natural question,
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how is gender determined in an organism?
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And it's not an obvious answer,because throughout the animal kingdom,
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it's actually determined in different ways.
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In some creatures,especially some types of reptiles,it's environmental
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Not all reptiles,but certain cases of it.
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It could be maybe the temperature in which the
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embryo develops will dictate whether it turns into a male or female
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or other environmental factors.
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And in other types of animals,especially mammals,
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of which we are one example,it's a genetic basis.
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And so your next question is,hey,Sal,so--
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let me write this down,in mammals it's genetic--
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so,OK,maybe they're different alleles,a male or a female allele.
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But then you're like,hey,but there's so many different characteristics
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that differentiate a man from a woman.
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Maybe it would have to be a whole set of genes
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that have to work together.
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And to some degree,your second answer would be more correct.
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It's even more than just a set of genes.
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It's actually whole chromosomes determine it.
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So let me draw a nucleus.That's going to be my nucleus.
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And this is going to be the nucleus for a man.
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So 22 of the pairs of chromosomes
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are just regular non-sex-determining chromosomes.
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So I could just do,that's one of the homologous,2,4,6,8,10,12,14.
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I can just keep going.And eventually you have 22 pairs.
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So these 22 pairs right there,they're called autosomal.
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And those are just our standard pairs of chromosomes
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that code for different things.
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Each of these right here is a homologous pair,homologous,
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which we learned before you get one from each of your parents.
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They don't necessarily code for the same thing,
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for the same versions of the genes,but they code for the same genes.
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If eye color is on this gene,it's also on that gene,
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on the other gene of the homologous pair.
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Although you might have different versions of eye color
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on either one and that determines what you display.
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But these are just kind of the standard genes
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that have nothing to do with our gender.
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And then you have these two other special chromosomes.
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I'll do this one.
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It'll be a long brown one,and then I'll do a short blue one.
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And the first thing you'll notice is that they don't look homologous.
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How could they code for the same thing
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when the blue one is short and the brown one's long?
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And that's true.They aren't homologous.
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And these we'll call our sex-determining chromosomes.
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And the long one right here,
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it's been the convention to call that the x chromosome.
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Let me scroll down a little bit.
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And the blue one right there,we refer to that as the y chromosome.
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And to figure out whether something is a male or a female,
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it's a pretty simple system.
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If you've got a y chromosome,you are a male.
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So let me write that down.
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So this nucleus that I drew just here--
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obviously you could have the whole broader cell all around here--
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this is the nucleus for a man.
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So if you have an x chromosome--
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and we'll talk about in a second
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why you can only get that from your mom--
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an x chromosome from your mom and a y chromosome from your dad,
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you will be a male.
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If you get an x chromosome from your mom
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and an x chromosome from your dad,you're going to be a female.
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And so we could actually even draw a Punnett square.
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This is almost a trivially easy Punnett square,
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but it kind of shows what all of the different possibilities are.
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So let's say this is your mom's genotype
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for her sex-determining chromosome.
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She's got two x's.
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That's what makes her your mom and not your dad.
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And then your dad has an x and a y--
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I should do it in capital--and has a Y chromosome.
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And we can do a Punnett square.
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What are all the different combinations of offspring?
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Well,your mom could give this X chromosome,
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in conjunction with this X chromosome from your dad.
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This would produce a female.
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Your mom could give this other X chromosome with that X chromosome.
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That would be a female as well.
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Well,your mom's always going to be donating an X chromosome.
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And then your dad is going to donate either the X or the Y.
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So in this case,it'll be the Y chromosome.
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So these would be female,and those would be male.
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And it works out nicely that half are female and half are male.
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But a very interesting and somewhat ironic fact
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might pop out at you when you see this.
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what determines whether someone is
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or Who determines whether their offspring are male or female?
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Is it the mom or the dad?
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Well,the mom always donates an X chromosome,
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so in no way does- what the haploid genetic makeup of the mom's eggs
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of the gamete from the female,
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in no way does that determine the gender of the offspring.
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It's all determined by whether--let me just draw a bunch of--
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dad's got a lot of sperm,and they're all racing towards the egg.
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And some of them have an X chromosome in them
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and some of them have a Y chromosome in them.
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And obviously they have others.
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And obviously if this guy up here wins the race.
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Or maybe I should say this girl.If she wins the race,
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then the fertilized egg will develop into a female.
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If this sperm wins the race,
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then the fertilized egg will develop into a male.
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And the reason why I said it's ironic is throughout history,
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and probably the most famous example of this is Henry the VIII.
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I mean it's not just the case with kings.
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It's probably true,because most of our civilization is male dominated,
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that you've had these men who are obsessed with producing a male heir
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to kind of take over the family name.
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And,in the case of Henry the VIII,take over a country.
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And they become very disappointed and they tend to blame their wives
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when the wives keep producing females,but it's all their fault.
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Henry the VIII,I mean the most famous case was with Ann Boleyn.
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I'm not an expert here,but the general notion is that
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he became upset with her that she wasn't producing a male heir.
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And then he found a reason to get her essentially decapitated,
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even though it was all his fault.
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He was maybe producing a lot more sperm
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that looked like that than was looking like this.
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He eventually does produce a male heir so he was--
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and if we assume that it was his child--
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then obviously he was producing some of these,but for the most part,
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it was all Henry the VIII's fault.
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So that's why I say there's a little bit of irony here.
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Is that the people doing the blame are the people
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to blame for the lack of a male heir?
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Now one question that might immediately pop up in your head is,
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Sal,is everything on these chromosomes
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related to just our sex-determining traits
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or are there other stuff on them?
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So let me draw some chromosomes.
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So let's say that's an X chromosome and this is a Y chromosome.
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Now the X chromosome,it does code for a lot more things,
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although it is kind of famously gene poor.
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It codes for on the order of 1,500 genes.
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And the Y chromosome,it's the most gene poor of all the chromosomes.
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It only codes for on the order of 78 genes.
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I just looked this up,but who knows if it's exactly 78.
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But what it tells you is it does very little
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other than determining what the gender is.
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And the way it determines that,
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it does have one gene on it called the SRY gene.
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You don't have to know that.
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SRY,that plays a role in the development of testes
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or the male sexual organ.So if you have this around,
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this gene right here can start coding for things
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that will eventually lead to the development of the testicles.
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And if you don't have that around,that won't happen,
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so you'll end up with a female.
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And I'm making gross oversimplifications here.
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But everything I've dealt with so far,OK,
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this clearly plays a role in determining sex.
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But you do have other traits on these genes.
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And the famous cases all deal with specific disorders.
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So,for example,color blindness.
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The genes,or the mutations I should say.
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So the mutations that cause color blindness.
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Red-green color blindness,which I did in green,
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which is maybe a little bit inappropriate.
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Color blindness and also hemophilia.
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This is an inability of your blood to clot.
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Actually, there's several types of hemophilia.
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But hemophilia is an inability for your blood to clot properly.
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And both of these are mutations on the X chromosome.
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And they're recessive mutations.So what does that mean?
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It means both of your X chromosomes have to have--
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let's take the case for hemophilia--
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both of your X chromosomes have to have the hemophilia mutation
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in order for you to show the phenotype of having hemophilia.
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So,for example,if there's a woman,
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and let's say this is her genotype.
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She has one regular X chromosome
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and then she has one X chromosome that has the--
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I'll put a little superscript there for hemophilia--
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she has the hemophilia mutation.She's just going to be a carrier.
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Her phenotype right here is going to be no hemophilia.
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She'll have no problem clotting her blood.
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The only way that a woman could be a hemophiliac is
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if she gets two versions of this,
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because this is a recessive mutation.
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Now this individual will have hemophilia.
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Now men,they only have one X chromosome.
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So for a man to exhibit hemophilia to have this phenotype,
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he just needs it only on the one X chromosome he has.
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And then the other one's a Y chromosome.
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So this man will have hemophilia.
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So a natural question should be arising is, hey, you know this guy--
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let's just say that this is a relatively infrequent mutation
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that arises on an X chromosome--
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the question is who's more likely to have hemophilia?
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A male or a female?
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All else equal,who's more likely to have it?
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Well if this is a relatively infrequent allele,a female,
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in order to display it,has to get two versions of it.
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So let's say that the frequency of it--
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and I looked it up before this video--
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roughly they say between 1 in 5,000 to 10,000 men exhibit hemophilia.
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So let's say that the allele frequency of this is 1 in 7,000,
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the frequency of Xh,the hemophilia version of the X chromosome.
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And that's why 1 in 7,000 men display it,
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because it's completely determined whether--
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there's a 1 in 7,000 chance that
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this X chromosome they get is the hemophilia version.
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Who cares what the Y chromosome they get is, cause
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that essentially doesn't code at all for the blood clotting factors
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and all of the things that drive hemophilia.
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Now,for a woman to get hemophilia,what has to happen?
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She has to have two X chromosomes with the mutation.
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Well the probability of each of them having the mutation is 1 in 7,000
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So the probability of her having hemophilia is
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1 in 7,000 times 1 in 7,000,or that's 1 in what,49 million.
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So as you can imagine,the incidence of hemophilia in women
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is much lower than the incidence of hemophilia in men.
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And in general for any sex-linked trait, if it's recessive,
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if it's a recessive sex-linked trait,which means men,
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if they have it,they're going to show it,
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because they don't have another X chromosome to dominate it.
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Or for women to show it, she has to have both versions of it.
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The incidence in men is going to be,
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so let's say that m is the incidence in men.I'm spelling badly.
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Then the incidence in women will be what?
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You could view this as the allele frequency
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of that mutation on the X chromosome.
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So women have to get two versions of it.
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So the woman's frequency is m squared.
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And you might say,hey,that looks like a bigger number.
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I'm squaring it. But you have to remember that these numbers,
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the frequency is less than 1,
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so in the case of hemophilia,that was 1 in 7,000.
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So if you square 1 in 7,000,you get 1 in 49 million.
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Anyway,hopefully you found that interesting
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and now you know how we all become men and women.
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And even better you know whom to blame when some of these, I guess,
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male-focused parents are having trouble getting their son.
