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We've gone over the general idea behind mitosis and meiosis.
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It's a good idea in this video to go a little bit more in detail.
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I've already done a video on mitosis,
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and in this one,we'll go into the details of meiosis.
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Just as a review,mitosis,you start with a diploid cell,
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and you end up with two diploid cells.
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Essentially, it just duplicates itself.And formally,
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mitosis is really the process of the duplication of the nucleus,
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but it normally ends up with two entire cells.
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Cytokinesis takes place.So this is mitosis.
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We have a video on it where we go into the phases of it:
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prophase,metaphase,anaphase and telophase.
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Mitosis occurs in pretty much all of our somatic cells
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as our skin cells replicate,and our hair cells
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and all the tissue in our body as it duplicates itself,
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it goes through mitosis.
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Meiosis occurs in the germ cells and it's used essentially to
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produce gametes to facilitate sexual reproduction.
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So if I start off with a diploid cell,
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and that's my diploid cell right there,this would be a germ cell.
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It's not just any cell in the body.It's a germ cell.
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It could undergo mitosis to produce more germ cells,
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but we'll talk about how it produces the gametes.
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It actually goes under two rounds.
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They're combined,called meiosis,
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but the first round you could call it meiosis 1,so I'll call that M1.
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I'm not talking about the money supply here.
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And in the first round of meiosis,
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this diploid cell essentially splits into two haploid cells.
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So if you started off with 43 chromosomes,
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you formally have 23 chromosomes in each one,
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or you can almost view it if you have 23 pairs here,
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each have two chromosomes,those pairs get split into this stage.
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And then in meiosis 2,
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these things get split in a mechanism very similar to mitosis.
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We'll see that when we actually go through the phases.
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In fact,the prophase,metaphase,anaphase,telophase
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also exist in each of these phases of meiosis.
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So let me just draw the end product.
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The end product is you have four cells and each of them are haploid.
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And you could already see,this process right here,
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you essentially split up your chromosomes,
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because you end up with half in each one,but here,
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you start with N and you end up with two chromosomes that each have N,
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so it's very similar to this.You preserve the number of chromosomes.
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So let's delve into the details of how it all happens.
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So all cells spend most of their time in interphase.
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Interphase is just a time when the cell is
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living and transcribing and doing what it needs to do.
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But just like in mitosis,
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one key thing does happen during the interphase, and actually,
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it happens during the same thing, the S phase of the interphase.
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So if that's my cell,that's my nucleus right here.
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And I'm going to draw it as chromosomes,but you have to remember that
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when we're outside of mitosis or meiosis formally,
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the chromosomes are all unwound,
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and they exist as chromatin,which we've talked about before.
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It's kind of the unwound state of the DNA.
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But I'm going to draw them wound up
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because I need to show you that they replicate.
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Now,I'm going to be a little careful here.
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In the mitosis video,I just had two chromosomes.
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They replicated and then they split apart.
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When we talk about meiosis,
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we have to be careful to show the homologous pairs.
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So let's say that I have two homologous pairs.
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So let's say I have--let me do it in appropriate colors.
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So this is the one I got from my dad.
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This is the one I got from my mom. They're homologous.
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And let's say that I have another one that I got from my dad.
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Let me do it in blue.
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Actually,maybe I should do all the ones from my dad in this color.
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Maybe it's a little bit longer. You get the idea.
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And then a homologous one for my mom that's also a little bit longer.
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Now,during the S phase of the interphase--
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and this is just like what happens in mitosis,
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so you can almost view it as it always happens during interphase.
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It doesn't happen in either meiosis or mitosis.
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You have replication of your DNA.
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So each of these from the homologous pair--and remember,
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homologous pairs mean that they're not identical chromosomes,
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but they do code for the same genes.
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They might have different versions or different alleles
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for a gene or for a certain trait,
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but they code essentially for the same kind of stuff.
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Now,replication of these,
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so each of these chromosomes in this pair replicate.
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So that one from my dad replicates like this,
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it replicates and it's connected by a centromere,
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and the one from my mom replicates like that,
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and it's connected by a centromere like that,
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and then the other one does as well.
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That's the shorter one.
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Oh,that's the longer one,actually.
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That's the longer one.
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I should be a little bit more explicit in
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which one's shorter and longer.
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The one from my mom does the same thing.
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This is in the S phase of interphase.
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We haven't entered the actual cell division yet.
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And the same thing is true--
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and this is kind of a little bit of a sideshow--of the centrosomes.
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And we saw in the mitosis video that these are involved in
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kind of eventually creating the microtubule structure
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in pulling everything apart,
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but you'll have one centrosome that's hanging out here,
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and then it facilitates its own replication,
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so then you have two centrosomes.
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So this is all occurring in the interphase,
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and particularly in the S part of the interphase,not the growth part.
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But once that's happens,we're ready--
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in fact,we're ready for either mitosis or meiosis,
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but we're going to do meiosis now.This is a germ cell.
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So what happens is we enter into prophase I.
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So if you remember,in my--let me write this down
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because I think it's important.
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In mitosis you have prophase,metaphase, anaphase and telophase.
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I won't keep writing phase down.PMAT.
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In meiosis,you experience these in each stage,
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so you have to prophase I,followed by metaphase I,
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followed by anaphase I,followed by telophase I.
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Then after you've done meiosis 1,then it all happens again.
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You have prophase II,followed by metaphase II,
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followed by anaphase II,followed by telophase.
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So if you really just want to memorize the names,
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which you unfortunately have to do in this,
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especially if you're going to get tested on it,
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although it's not that important to kind of understand the concept of
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what's happening, you just have to remember
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prophase,metaphase,anaphase,telophase,
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and it'll really cover everything.
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You just after memorize in meiosis,it's happening twice.
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And what's happening is a little bit different,
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and that's what I really want to focus on here.
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So let's enter prophase I of meiosis I.
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So let me call this prophase I.So what's going to happen?
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So just like in prophase and mitosis,
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a couple of things start happening.
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Your nuclear envelope starts disappearing.
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The centromeres--sorry,not centromeres.
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I'm getting confused now.The centrosomes.
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The centromeres are these things connecting these sister chromatids.
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The centrosomes start facilitating the development of the spindles,
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and they start pushing apart a little bit from the spindles.
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They start pushing apart
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and going to opposite sides of the chromosomes.
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And this is the really important thing in prophase I.
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And actually,I'll make this point.
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Remember,in interface,even though I drew it this way,
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they don't exist in this state,the actual chromosomes.
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They exist more in a chromatin state.
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So if I were to really draw it,it would look like this.
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The chromosomes,it would all be all over the place,and it actually
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would be very difficult to actually see it in a microscope.
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It would just be a big mess of proteins and of histones,
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which are proteins,and the actual DNA.
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And that's what's actually referred to as the chromatin.
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Now,in prophase,that starts to form into the chromosomes.
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It starts to have a little bit of structure,and this is
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completely analogous to what happens in prophase in mitosis.
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Now,the one interesting thing that happens
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is that the homologous pairs line up.And actually,
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I drew it like that over here and maybe I should just cut and paste it
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Let me just do that.
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If I just cut and paste that,
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although I said that the nucleus is disappearing,
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so let me get rid of the nucleus.I already said that.
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The nucleus is slowly disassembling.
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The proteins are coming apart during this prophase I.
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I won't draw the whole cell,
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because what's interesting here is happening at the nuclear,
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or what once was the nucleus level.
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So the interesting thing here that's different from mitosis
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is that the homologous pairs line up next to each other.
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Not only do they line up,but they can actually share--
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they can actually have genetic recombination.
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So you have these points where analogous--
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or I guess you could say homologous-- points
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on two of these chromosomes will cross over each other.
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So let me draw that in detail.
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So let me just focus on maybe these two right here.
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So I have one chromosome from my dad,
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and it's made up of two chromatids,
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so it's already replicated,
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but we only consider it one chromosome,
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and then I have one from my mom in green.
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I'm going to draw it like that.
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One from my mom in green,and it also has two chromatids.
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Sometimes this is called a tetrad
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because it has four chromatids in it,
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but it's in a pair of homologous chromosomes.
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These are the centromeres,of course.
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What happens is you have crossing over,
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and it's a surprisingly organized process.
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When I say organized,it crosses over at a homologous point.
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It crosses over at a point where,
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for the most part,you're exchanging similar genes.
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It's not like one is getting two versions of a gene
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and the other is getting two versions of another gene.
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You're changing in a way that
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both chromosomes are still coding for the different genes,
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but they're getting different versions of those genes
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or different alleles, which are just versions of those genes.
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So once this is done,
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the ones from my father are now not completely from my father,
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so it might look something like this.
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Let me see,it'll look like this.
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The one from my father now has this little bit from my mother,
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and the one from my--oh,no,my mother's chromosome is green--
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a little bit from my mother,
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and the one from my mother has a little bit from my father.
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And this is really amazing because it shows you that
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this is so favorable for creating variation in a population
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that it has really become a formal part of the meiosis process.
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It happens so frequently.This isn't just some random fluke,
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and it happens in a reasonably organized way.
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It actually happens at a point
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where it doesn't kind of create junk genes.
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Because you can imagine,this cut-off point,which is called a chiasma,
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it could have happened in the middle of some gene,
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and it could have created some random noise,
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and it could have broken down some protein development
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in the future or who knows what.But it doesn't happen that way.
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It happens in a reasonably organized way,
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which kind of speaks to the idea that it's part of the process.
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So in prophase I,you also have this happening.
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So once that happens
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you could have this guy's got a little bit of that chromatid
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and then this guy's got a little bit of that chromatid.
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So all of this stuff happens in prophase I.
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You have this crossing over.
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The nuclear envelope starts to disassemble,
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and then all of these guys align and the chromatin starts
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forming into these more tightly wound structures of chromosomes.
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And really,that's all--when we talk about even mitosis,
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that's where a lot of the action really took place.
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Once that happens,then we're ready to enter into the metaphase I,
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so let's go down to metaphase I.
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In metaphase I--let me just copy and paste what I've already done--
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the nuclear envelope is now gone.
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The centrosomes have gone to opposite sides of the cell itself.
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Maybe I should draw the entire cell now that there's no nucleus.
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Let me erase the nucleus a little bit better than I've done.
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Let me erase all of that.
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And,of course,we have the spindles fibers that have been
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generated by now with the help of the centrosomes.
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And some of them,as we learned,
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this is exactly what happened in mitosis.
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They attach to the kinetochores,
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which are attached to the centromeres of these chromosomes.
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Now,what's interesting here is that they each attach--
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so this guy's going to attach to--
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and actually,let me do something interesting here.
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Instead of doing it this way,because I want to show that
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all my dad's chromosomes don't go to one side
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and all my mom's chromosomes don't go to the other side.
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So instead of drawing these two guys like this,
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let me see if I can flip them.Let me see.
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Let me just flip them the other way.
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Whether or not which direction they're flipped is completely random,
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and that's what adds to the variation.
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As we said before,sexual reproduction is key
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to introducing variation into a population.
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So that's the mom's and that's the dad's.They don't have to.
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All of the ones from my dad might have ended up on one side
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and all of them from my mom might end up on one side,
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although when you're talking about 23 pairs,
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the probability becomes a lot,lot lower.
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So this is one from my dad.Of course,it has some centromeres.
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Let me draw that there.
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And so these microspindles,some of them attach to kinetochores,
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which are these protein structures on the centromeres.
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And this is just like metaphase.
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It's very similar to metaphase in mitosis.
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This is called metaphase I,and everything aligns.
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Now we're going to enter anaphase I.
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Now,anaphase I is interesting,because remember,
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in mitosis in anaphase,the actual chromatids,
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the sister chromatids separated from each other.
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That's not the case in anaphase I here in meiosis.
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So when we enter anaphase I,
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you have just the homologous pairs separate,
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so the chromatids stay with their sister chromatids.
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So on this side,you'll have these to go there.
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While I have the green out,let me see if I can draw this respectably.
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I have the purple.It's a little bit shorter version here.
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He's got a little bit of a stub of green there.
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This guy's got little stub of purple there.
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And then they have this longer purple chromosome here.
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This is anaphase I.
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They're being pulled apart,but they're being pulled apart--
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the homologous pair is being pulled apart,
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not the actual chromosomes,not the chromatids.
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So let me just draw this.
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So then you have your microtubules.
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Some are connected to these kinetochores.You have your centromeres.
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Of course,all of this is occurring within the cell
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and these are getting pulled apart.
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So it's analogous to anaphase in mitosis,
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but the key difference is you're pulling apart homologous pairs.
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You're not actually splitting the chromosomes
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into their constituent chromatids,and that's key.
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And if you forget that,you can review the mitosis video.
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So this is anaphase I.
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And then as you could imagine,telophase I is essentially
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once these guys are at their respective ends of the cell--
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it's getting tiring redrawing all of these,
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but I guess it gives you time to let it all sink in.
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So these guys are now at the left end of the cell
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and these guys are now at the right end of the cell.
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Now,the microtubules start to disassemble.
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So maybe they're there a little bit,but they're disassembling.
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You still have your centromeres here and they're at opposite poles.
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And to some degree,in the early part of telophase,
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they're still pushing the cell apart,
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and at the same time,you have cytokinesis happening.
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So by the end of telophase I,
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you have the actual cytoplasm splitting during telophase right there,
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and the nuclear envelope is forming.
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You can almost view it as the opposite of prophase.
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The nuclear envelope is forming,and by the end of telophase I,
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it will have completely divided.So this is telophase I.
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Now,notice:we started off with a diploid cell,right?
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It had two pairs of homologous chromosome,but it had four chromosomes.
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Now,each cell only has two chromosomes.
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Essentially,each cell got one of the pair of each
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of those homologous pairs,but it was done randomly,
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and that's where a lot of the variation is introduced.
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Now,once we're at this stage,
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each of these cells now undergo meiosis II,
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which is actually very similar to mitosis.And sometimes,
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there's actually an in-between stage called interphase II,
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where the cell kind of rests and whatever else,
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and actually the centromeres now have to duplicate again.
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So these two cells--I've drawn them separately--
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let's see what happens next.
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So let's say that the centromere--actually,I shouldn't have drawn
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the centromere inside the nucleus like that.
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The centromere's going to be outside the nucleus,
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outside of the newly formed nucleus there and there.
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And then it'll actually replicate itself at this point as well.
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So now we have two cells.
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Let me just cut and paste what I have.I have this one,
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this chromosome right here.
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It's got this little green stub there
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and then I have this longer fully green chromosome there.
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Now,this guy,he's got this little purple stub here.
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Let me draw this whole purple chromosome there.
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Then this guy has one chromatid like that and one chromatid like that.
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Now,when we enter prophase II,
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what do you think is going to happen?Well,just like before,
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you have your nuclear envelope that formed in telophase I.
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It's kind of a temporary thing.It starts to disintegrate again.
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And then you have your centromeres.
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They start pushing apart so now I had two centromeres.
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They replicated,and now they start pushing apart
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while they generate their little spindles.
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They push apart in opposite directions.
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Now,this is happening in two cells,of course.
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They go in opposite directions
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while they generate their spindle fibers.
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And let me make it very clear that
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this is two cells we're talking about.
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That's one of them and that's the second of them.
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Now it's going to enter metaphase II,
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which is analogous to metaphase I,or metaphase in mitosis,
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where the chromosomes get lined up.
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Let me draw it this way.
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So now the centromeres,they've migrated to the two poles of the cell.
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So those are my centromeres.
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I have all of my spindles fibers.
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Oh,sorry,did I call those centromeres? The centrosomes.
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I don't know how long I've been calling them centromeres.
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These are centrosomes,and my brain keeps confusing them.
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The centromeres,and maybe this'll help you
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not do what I just did,the centromeres are the things
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that are connecting the two sister chromatids.
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Those are centromeres.
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Centrosomes are the things that are pushing back the--
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that generate the spindle fibers.
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The chromosomes line up during metaphase.
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Metaphase always involves the lining up of chromosomes
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so that one--let me just draw it.So I have that and that.
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This one's got a purple guy,too.
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This guy's got a purple guy,a long purple guy,
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and then there's a little stub for the other guy.
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This guy's got a long green guy and this guy's got a little green stub
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and then this is the short green guy right there.
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And,of course,they're being aligned.
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Some of these spindle fibers have been attached
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to the centromeres or the kinetochores that are on the centromeres
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that connect these two chromatids,these sister chromatids.
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And,of course,we don't have a nuclear membrane anymore,
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and these are,of course,two separate cells.
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And then you can guess what happens in anaphase II.
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It's just like anaphase in mitosis.
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These things get pulled apart by the kinetochore microtubules,
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while the other microtubules keep growing
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and push and these two things further apart.
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So let me show that.And they the key here:
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this is the difference between anaphase II and anaphase I.
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Anaphase I,the homologous pairs were broken up,
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but the chromosomes themselves were not.
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Now,in anaphase II,we don't have homologous pairs.
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We just have chromatid pairs,sister chromatids.
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Now,those are separated,which is very similar to anaphase in mitosis.
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So now,this guy gets pulled in that direction
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so it look something like this.
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The drawing here is the hardest part of this video.
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So that guy gets pulled there.
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That guy's getting pulled in that direction.
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He's got that little green stub on him.
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And then you have one green guy
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getting pulled in that direction with the longer chromosome.
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And then one of the other longer is getting pulled in that direction,
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and it's all by these microtubules
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connected at the kinetochore structures
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by a centrosome as kind of the coordinating body.
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It's all being pulled apart.
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Anaphase has always involved the pulling apart of
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the chromosomes or pulling apart of something.
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Let me put it that way.
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And it's happening on this side of the cell as well.
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Of course, this is all one cell.
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And just like in mitosis,
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as soon as the sister chromatids are split apart,
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they are now referred to as chromosomes,or sister chromosomes.
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And,of course,this is happening twice.
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This is also happening in the other cell.
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The other cell's a little bit cleaner.
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It didn't have that crossover occur.
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So you have the longer purple one.
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He gets split up into two chromatids,
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which we are now calling chromosomes,or sister chromosomes.
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And then this guy up here,he gets split up into this short green,
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and then there's a--let me do it this way--this short green,
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and he's got a little purple stub on it right there.And,of course,
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it's all being pulled away by the same idea,by the centrosomes.
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I want to make sure I get that word right.
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I'm afraid whether I used centromeres
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for the whole first part of the video,
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but hopefully,my confusion will help you from getting confused
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because you'll realize that it's a pitfall to fall into.
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So that's anaphase.Everything is getting pulled apart.
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And then you can imagine what telophase II is.
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In fact,I won't even redraw it.
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Telophase II,these things get pulled apart even more,
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so this is telophase II.
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They get pulled apart even more.The cell elongates.
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You start having this cleavage occur right here.
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So at the same time that in telophase II these get pulled part,
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you have the cytokinesis.
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The tubules start disintegrating
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and then you have a nucleus that forms around these.
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So what is the end result of all of these?
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Well,that guy's going to turn into a nucleus
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that has this purple dude with a little green stub,
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and then a long green guy,and then he's got his nuclear membrane.
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And,of course,there's the entire cytoplasm in the rest of the cell.
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The other person that was his kind of partner in this meiosis II,
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he's going to have a short purple and a long green.
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He has a nuclear membrane,and,
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of course,it has cytoplasm around it.
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And then on this side,you have something similar happening.
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You see this first guy,
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this first one right here has two long purple ones.
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They get separated.
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So let me see,you have one long purple in that cell
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and you have another long purple in this cell.
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In that top one,you have a short green one,
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and in this bottom,you have a short green one
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that had got a little bit of one of my dad's--
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a homologous part of one of my dad's chromosomes on it.
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And,of course,these also have nuclear membranes, nuclear membranes,
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and,of course,it has a cytoplasm in the rest of the cell,
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which we'll learn more about all those other things.
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So what we see here is that
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we went from a diploid starting way--where did we start?
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We started up here with a diploid germ cell,
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and we went through two stages of division.
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The first stage split up homologous pairs,
-
but it started over with that crossing over,
-
that genetic combination,which is a key feature of meiosis,
-
which adds a lot a variation to a species or to a gene pool.
-
And then the second phase separated the sister chromatids,
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just like what happens in mitosis.
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And we end up with four haploid cells
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because they have half the contingency of chromosomes,
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and these are called gametes.
