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- [Voiceover] In the last video,
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we had just started to get into meiosis,
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and to be more precise, meiosis I,
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and to be even more precise
than that, prophase I,
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but we spent a good bit
of time on prophase I
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because some interesting things happened.
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Some things happened just
like prophase in mitosis where
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the nuclear envelope disappears
or starts to disappear,
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you have the chromosomes
going into their dense form
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that has kinda this classic shape that you
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could see from a microscope,
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but what was unique or
what was interesting
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about meiosis I and
prophase I in particular
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is that you have this
chromosomal crossover,
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that is a pretty typical
thing to happen in meiosis I,
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and it tends to happen
in a fairly clean way
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where homologous sections
of these homologous pairs
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crossover, so these
sections of the chromosome
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tend to code for the same genes.
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They're just different
variants of those same genes.
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They might have different alleles,
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and then once again, this
just adds more variation
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as we get into sexual reproduction,
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so it's a kind of neat
thing that happens here.
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But now let's continue with meiosis,
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and in particular meiosis
I, and you could guess
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what the next phase is going to be called.
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It is metaphase I, metaphase, metaphase I,
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and it has some similarities
with metaphase in mitosis.
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So in metaphase I, let me draw my cell,
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so this is the cellular
membrane right over there.
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I have my centrosomes,
which are now going to play
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more significant roles.
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The nuclear membrane is now gone,
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and just like in metaphase in mitosis,
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my chromosomes are going to line up
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along the, here I'll draw it,
kind of this up, down axis.
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So let's do that.
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So you have this one right over here.
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This is one chromosome,
two sister chromatids,
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and we had the chromosomal crossover,
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so it has a little bit of pink here.
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I'm gonna take a little bit of time
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to switch colors a little
bit more frequently.
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And then you have the one,
at least most of which
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you got from your mother,
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yeah but there's been a little bit
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of chromosomal crossover here as well.
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So let me draw that.
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Let me draw that.
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And then you have this one,
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and just for the sake of,
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so you have this one, this
chromosome from your father.
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It has replicated, so it's
now two sister chromatids.
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And this one from your mother,
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and I'm not gonna show the
chromosomal crossover here.
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Maybe it didn't happen over here.
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No homologous recombination over here.
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So these are, I guess, shorter.
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Now let me draw the centromeres.
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The centromeres I started
doing in this blue color.
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So the centromeres, the centromeres,
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and then the centrosomes,
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you have these microtubules that start,
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they can push the centrosomes
away from each other.
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But they also attach at the
kinetochores to the chromosomes,
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to the chromosomes, just like that.
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And these are, the microtubules,
you'll see people talk
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about oh these connect, and they're able
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to move things around,
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but I find this incredible
that you just have
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a bunch of proteins through
just kind of chemical
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and thermodynamic processes,
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are able to do really interesting things
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like move chromosomes to
different parts of the cell,
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so that we eventually can
get these gametes that can
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participate in sexual reproduction.
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This is an amazing thing,
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and it's developed over
billions of years of evolution,
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but it's just mind boggling
to think about the complexity,
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and not all of this is
completely understood
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exactly how all of this works.
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I mean you have these
kind of motor proteins
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that help move the chromosomes
along, these microtubules
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can elongate and shorten
in interesting ways.
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So it's a really fascinating process.
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But anyway, this is what's
happening in metaphase I.
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Now you can probably guess
what happens after that.
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We then move to anaphase I.
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So let me, we now go to anaphase I.
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I'll write that over here.
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Anaphase, anaphase I,
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and just like anaphase in mitosis,
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over here, the chromosomes
start getting pulled apart,
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except for one significant difference,
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and this is actually a very
significant difference.
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In mitosis, the sister
chromatids get pulled apart.
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The sister chromatids get pulled apart
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to become two daughter chromosomes.
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That does not happen in anaphase I.
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In anaphase I, the sister
chromatids stay together.
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It's the homologous pairs
that get pulled apart.
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So let me draw that.
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So this homologous pair
up here gets pulled apart.
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The two sister chromatids do
not get pulled apart here.
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So you have this one is
getting pulled onto this side.
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So this one's getting
pulled onto this side.
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It has a little bit from the original,
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so a little bit of that right over there.
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And then you have this one
getting pulled on this side.
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So draw it the best I can, the colors,
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alright, so it looks like that,
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although it's nice to have,
it's kinda easy to keep track of
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cause these switch colors like that.
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And then you have this one
getting pulled on this side.
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This one getting pulled on this side.
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And finally finally this one
getting pulled onto that side.
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And let me draw the centrosomes.
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So that's my, oops, centrosome,
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and once again, it's pulling,
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or I guess you could say the
chromosomes are being moved
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and these things are
pushing each other apart.
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The two centrosomes might be pushing apart
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to get to the opposite
ends of the actual cell,
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but they're bringing,
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there's all sorts of
interesting mechanisms
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that are bringing along
these microtubules,
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bringing the chromosomes,
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once again splitting the homologous pairs.
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And how they split is random.
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You know, this pink one could
have been on the right side,
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this orange one could have
been on the left side,
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or vice versa, and once again,
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this adds more variation
amongst the gametes,
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so even all of the resulting
gametes that get produced,
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they all will have different
genetic information.
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So this is anaphase I.
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You're pulling these apart, and
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then you could imagine what
happens in telophase I.
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So telophase I, telophase, telophase I.
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Telophase I, and this is fairly analogous
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to what happens in mitosis in telophase.
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So now you have your
cytokinesis is beginning,
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and actually, it might even begin earlier,
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in mitosis it happens
as early as anaphase,
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at least the cytokinesis is starting,
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but you're starting to see that.
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The homologous pairs
are fully split apart,
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and they're at opposite ends,
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and actually they can begin to unravel
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into their chromatin state,
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so this one began to unravel
into its chromatin state.
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It has a little bit of the magenta.
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Oops, it has a little bit of
the magenta right over here.
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This is unravelling as well.
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This is unravelling like that,
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once it gets into its chromatin state.
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The cellular, and let me
do the other ones as well.
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So this is this one right over here.
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It's beginning to unravel.
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This one over here, beginning to unravel.
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It's got a bit of orange on it.
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It's got a little bit of orange on it.
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The nuclear membrane begins to form again.
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The nuclear membrane begins to form again.
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In some ways, it's reversing
what happened in prophase I
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where the nuclear membrane disappeared,
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and the chromosomes condensed.
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And let me draw, let me
draw the centrosomes,
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which are outside the nuclear
membrane, just like that.
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And the microtubules are also dissolving.
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The microtubules are also dissolving.
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And you have your cytokinesis.
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So your cytokinesis, so these separate.
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These separate into two cells.
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So once again, when we did the overview
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of meiosis, we said look,
the first phase of meisosis,
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you go from a diploid germ
cell to two haploid cells.
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And these aren't quite
our end product yet.
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This right over here, what
we have just gone through,
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what we have just gone through,
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all of this combined that
we have just gone through,
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this is meiosis I.
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And in the next video, we're
gonna go through meiosis II.
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Whoops, I didn't mean to do that.
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This is, so let's see,
all of this is meiosis I.
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Let me write that in a
different color, in bold.
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So this is all meiosis, meiosis I here,
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and you can see each of these cells now
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have a haploid number.
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They now have a haploid, haploid number
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of two chromosomes each.
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Now each of those two chromosomes
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do have two sister chromatids,
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and as we'll see in meiosis II,
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which is very similar to mitosis,
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is going to split up the sister chromatids
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from each of these chromosomes,
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which gives us two daughter chromosomes.
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So we're gonna see that over here.
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So your haploid number here is two.
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You have two chromosomes here and
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you have two chromosomes there.
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And we'll explore meiosis
II in the next video.
Khan Academy
