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  • Hi. It's Mr. Andersen and welcome to Biology Essentials video 28. This is on

  • the cell cycle, mitosis and meiosis. In other words how we go from one cell to all the cells,

  • the trillions of cells inside our body. Meiosis is important because that's how we make sex

  • cells. Now let me digress a little bit. This is a whipped tail lizard from the desert southwest

  • and what's interesting about this is that it's a female lizard and when it wants to

  • make more lizards it will simply use mitosis to make an exact copy of a cell inside its

  • body. It's called parthenogenesis or virgin birth and it will make a brand new, a number

  • of baby lizards and they're all females. So they don't have males. It's rare to not have

  • males. It's rare to not have meiosis and the reason why is that all the whipped tail lizards

  • are genetically the same. But it works. And if you live in a fairly stable environment

  • it tends to work. Now we're not going to go into the specifics of mitosis and meiosis.

  • You can look, I've got videos on each of those that talks about the different phases. What

  • I want to talk about this is in general what do mitosis and meiosis do and how does the

  • cell cycle work and how is it controlled. And so a diploid cell is going to be a typical

  • human cell, or a typical cell inside an organism. It's going to be 2n and what that means is

  • it has 2 complete sets of chromosomes. So for example in humans 2n=46. That means we

  • have 23 pair of chromosomes. And so the goal of the cell cycle in mitosis is to make a

  • copy of that cell in other words to make a diploid cell. That diploid cell can enter

  • into the cell cycle again, make more cells and more cells and more cells. And so the

  • way that we make new cells in our body or replace cells that are damaged is mitosis.

  • In meiosis we're going to take a normal diploid cell and we're actually going to make a haploid

  • cell, we're going to make sperm and egg. So in humans n now equals 23. Now if we were

  • to just stop there, we wouldn't have diploid cells anymore, but fertilization where egg

  • meets sperm is going to combine those two cells to make a diploid cell and now that

  • diploid cell can enter into the cell cycle again. And so we've got kind of two loops.

  • We've got the mitosis loop and the meiosis loop. Mitosis is used to make all the cells

  • in our body, meiosis just makes gametes, or sex cells. I also in this video want to talk

  • about how we control the creation of diploid cells. So it may be better to come from here

  • and how we use cyclin, an example of that would be mitosis promoting factor (MPF) to

  • control the cell cycle in where it is and where it's headed next. Now if you're talking

  • about cell cycle the best place to watch, or start is with videos of actually cells

  • dividing. And so this is a cell undergoing division. So we start with one cell and it

  • makes an exact copy of itself. Now when you're watching it, let me go back a second, on these

  • first two videos what you don't see is everything that actually happens before the cell makes

  • a copy of itself. In other words before the cell is actually able to divide, it has to

  • duplicate all of the DNA and all of the machinery of the cell. This last one we're looking actually

  • inside the cell itself. And so the cell division actually has two parts to it. Part one is

  • going to be the division of the nucleus, and we call that in general mitosis. And then

  • after we've divided the nucleus you'll see the chromosomes actually separate here. Then

  • we actually have the division of the rest of it and that's called cytokinesis. Cytokinesis

  • is the break apart of all of the other parts of the cell, so the machinery of the cell,

  • the mitochondria, cytoplasm, things like that. And so let me see if I can start that up.

  • So first of all, there we go, first we have the division of the nucleus. You can see the

  • chromosomes pulling apart and then you have cytokinesis or the division of the cell itself.

  • And so all mitosis is is one cell forming two cells. And those two cells are identical

  • to that first cell. And that's how we go from that first fertilized egg inside us to the

  • trillion of cells we have inside an adult body. So when you're replacing cells in your

  • body you're doing it through mitosis. So let's look at the cell cycle. And so what happens

  • is you'll have a cell enter into this. So a cell's going to look like this. It's going

  • to enter into the cell cycle as one cell. Let me make a little better arrow. And then

  • it's eventually going to exit out as two cells, each of those cells remember could go back

  • into the cell cycle and so this is how we make all the cells in our body. Now I've heard

  • that a lot of the dust in a room actually are dead skin cells. And this is what skin

  • looks like. So skin is going to be creating new cells. They are going to migrate up to

  • the surface and then we're eventually going to lose skin cells at the top. But we keep

  • replacing those cells and to do that we use the cell cycle. So let's look at the parts

  • of the cell cycle. If we start first with that cell entering in, the first thing it'll

  • do is it'll actually enter into the G1phase. G1 phase the cell is actually going to grow.

  • It's going to get bigger and bigger and bigger and bigger. We then enter into the S phase.

  • During the S phase, we're going to actually, using DNA replication, we're going to copy

  • all of the DNA inside a cell. It then goes into the G2 or the growth 2 phase where it

  • continues to grow and gets ready for division of the actual cell. And so G1, S and G2 are

  • all part of what's called Interphase. And if you look at a cell, it's generally in interphase.

  • It's growing, it's copying its DNA, it's growing or maybe it's just working, it's doing what

  • a normal cell does. And so most of the life of a cell is in interphase. It's in these

  • three, G1, S and G2 and the actual copying of the nucleus and copying of the cell, this

  • mitotic phase is actually going to be really, really small. If it never divides again, it'll

  • actually stall out in something called the G0 phase. And so we've got cells inside our

  • body, you're heard of this maybe, cells of the central nervous system, muscle cells for

  • example, that never copy themselves during your whole life time. They're in what's called

  • the G0 phase or they're just waiting. And they're not going to make divisions. And so

  • how does a cell know when it's time to divide? And when it should go on and when it shouldn't?

  • The best analogy I can think of is it works kind of like an hour glass clock. And so there

  • are little proteins inside a cell and as those proteins accumulate throughout the life of

  • the cell eventually you get a critical number of these proteins at the bottom, and once

  • we have enough of those then it actually tells the cell to advance to the next stage. And

  • those proteins are called cyclins. And so let's look at what cyclins look like. A cyclin,

  • I'll represent it here, it's simply a protein. But if we look here at the G1 phase, the S

  • phase, the G2 phase and mitosis there's a set of cyclins or a set of these different

  • types of proteins and what they're going to do is they're going to build up. And so cyclin

  • A and B are ones that I'm really familiar with. Cyclin A will actually build up during

  • the S phase and then it'll drop off right as the cell divides, as it goes into this

  • mitotic phase. And so cyclins will actually accumulate and so those are like the sands

  • through an hourglass. They're going to get more and more and more and more cyclins as

  • a cell goes through the cell cycle. Now the other chemical that I want to talk about is

  • something called CDK. CDK is simply a cyclin dependent kinase and a kinase is simply going

  • to be a chemical that can speed up actions within a cell. And so CDKs are found in all

  • living organisms. And you can actually take CDKs from a yeast and put them in our cells

  • and they work just as fine. So they show homology through evolution. And so cyclin dependent

  • kinase, if you look at their name, are simply dependent upon cyclin. And so I made a little

  • animation of how that works. And so a typical cell in your body is going to have a bunch

  • of CDKs in it or cyclin dependent kinases and so we could say this is like right here.

  • But throughout the life of the cell, the cell is going to start building up and accumulating

  • larger amounts of cyclin. So the amount of cyclin is going to get larger and larger and

  • larger. So eventually what happens is the cyclin is going to fit into the cyclin dependent

  • kinases. Now we have an activated CDK cyclin complex. What does that mean? We have something,

  • a protein, that's able to do things. So now you can think of we've like mustered this

  • army and now the army is ready to do something. And so what does it do? Well, we're right

  • here, so we're just about to enter into the M phase, so we're just about to do mitosis

  • and so what these cyclin dependent kinases do is they act on the cell itself. A specific

  • type of CDK is called the mitosis promoting factor or MPF and what that does is when it

  • builds up enough of these cyclin dependent kinases, they're actually going to work on

  • the cell. So one thing they'll do is they'll actually break apart the nucleus. So we're

  • able to start dividing that cell. Another thing that CDKs will do is they'll actually

  • work on the microtubules that build this spindle. And so all of these together will work on

  • pushing that cell into the mitotic phase or into this next step of the cell cycle. The

  • neat thing about each of these is that after they've actually done that they'll actually

  • gobble themselves up. They'll disappear and then the whole cycle begins over again. Okay.

  • So if we kind of talk big picture about what happens in the cell cycle, a typical cell

  • right here is going to be, let's say this is a typical cell, a typical cell right here

  • is actually going to be 2n, it's diploid. You have one chromosome from mom, one chromosome

  • from dad. So in this case it's going to be 2n=2. It's then going to duplicate itself.

  • So during the S phase it's going to make copies of itself and so at this point right here

  • we'd actually have a 4n cell. It's made copies of that. And at this point we can either take

  • the path of mitosis or the path of meiosis. And so in the path of mitosis, that'll simply

  • split in half and now we'll have two 2n cells. And if you look at these two 2n cells they're

  • exactly the same as that first cell. So this is what's happening to the chromosomes. If

  • we look at that 4n cell as it goes into meiosis it'll actually line up. It will split in half

  • and then it will split in half again. And so what you have is actually n cells. Those

  • are called haploid cells and we have four of those in meiosis. And so the cell cycle

  • will take a diploid cell make two diploid cells in mitosis or make four haploid cells

  • in meiosis. That got a little messy so let's look at it in a little more detail. So mitosis

  • is how we replace cells in the body. Cells that are broken, cells that are broken down,

  • cells that we need to replace, we do that through mitosis. Or when we want to grow how

  • do we go from a very small organism to a very large organism? It's just making more cells.

  • And so this would be a real, to make it simple, we're going to start with a simple cell. This

  • is going to be a 2n, it's diploid, but 2n=2. So this would be that first parent cell. It

  • will then duplicate all of the DNA. So now we have this characteristic shape. It has

  • two sides to it and this side and that side are copies. That's what happened during the

  • S phase. They'll then meet in the middle. They'll divide in half, so this would be our

  • mitosis phase and now we have two diploid cells. And if you look at those cells, they're

  • exactly the same as the original cell. And each of those are 2n=2. So that's mitosis.

  • What happens to these 2n cells. Well, they can enter into the cell cycle again and it

  • goes over and over and over again. In meiosis what happens is a little more detailed. Remember

  • meiosis only deals with making sex cells in reproduction. And so in this case to make

  • it, to show you meiosis I had to increase the number of cells, or chromosomes. In this

  • case 2n=4. In other words we have two chromosomes from mom, two chromosomes from dad. So they'll

  • copy themselves, so now we actually have a 4n cell at this point, but since we're doing

  • meiosis, this is where actually crossing over occurs. And so parts of this chromosome will

  • swap places with this chromosome and vice versa. What that gives us is variability in

  • all of the sperm and the egg. They'll divide in half. Now we have 2n cells and then we'll

  • eventually have n cells equals 2. And so we started with 2n=4 and now we have n=2. Each

  • of these four things in a male become a sperm and in a female one of them will become an

  • egg and the other ones will actually form what are called polar bodies.

  • And so what do we get after meiosis? Well we get sperm and we get egg. And we can then

  • go from these original n=2 to a 2n=4 zygote. And so now we're back to a diploid cell and

  • that diploid cell can enter into the cell cycle. This is a zygote to make more cells

  • and eventually makes sex cells to make the next generation. So that's cell cycle, mitosis,

  • meiosis and I hope that's helpful.

Hi. It's Mr. Andersen and welcome to Biology Essentials video 28. This is on

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細胞周期・有糸分裂・減数分裂 (Cell Cycle, Mitosis and Meiosis)

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    Cheng-Hong Liu に公開 2021 年 01 月 14 日
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