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  • I'm gonna draw for you the heart

  • And we're actually gonna do a little zooming in now,

  • taking a look at exactly what happens, both in the wall of the heart

  • but also going even further in. So, let's start with the heart

  • heart wall. What were you to see if you were to zoom in? You'd see

  • heart cells. And this is kind of a heart cell with some branches here.

  • And you remember that heart cells, besides just having branches

  • is very distinct looking. Sometimes it has one, but sometimes it has

  • two nuclei. Now let's say we were to zoom in again.

  • on this heart cell. What would we see if we kind of went further?

  • Well, you know that there are lots and lots and lots of proteins inside these

  • heart cells, and the ones that we've usually been concerning ourselves with

  • are the actin and myosin

  • and these are kind of the classic cell proteins that allow

  • it to contract. So, it might look a little bit like

  • this, right, with our actins kind of spaced out a little bit from each other.

  • I'll label it as I go. This is an actin.

  • And, in the middle of the actin. And in the middle of the actin, you've got myosin.

  • Right? So you've got this purple myosin.

  • And it looks maybe something like this, with the little myosin heads.

  • coming off of it. And you've got some on both sides.

  • And these myosins are going to be tethered to

  • the wall. Right? This wall at the end, and I'll draw that

  • tethering with green, kind of like that.

  • And this is basically, this is titin.

  • Titin is kind of what keeps the myosin from

  • floating away. And you can think of it as "Well, what happens over time

  • is that these myosins and actins are gonna start

  • binding", right? They're gonna start binding, and we call these

  • actin/myosin crossbridges, or you might hear different terms, but basically

  • the two are interacting with each other.

  • And what the myosin is gonna want to do, is it's gonna want to yank

  • this way, right? It's gonna want to bind the actin like this.

  • and yank it that way.

  • In fact, all these little myosins are gonna

  • kind of act the same way, they're gonna wanna yank the

  • actin in the same direction. And in the same way, you've got

  • pulling in the opposite way. You've got pulling towards the middle.

  • basically. So if this were to work, what would happen?

  • Well, at the edges, at the end here, we call these guys z disks.

  • Z-discs. You might have heard the term 'z-line', because it looks like

  • because it looks like a line under a microscope. But if you actually zoom in,

  • and you go up close to it, it's basically a disc of protein. Right?

  • So these z-discs, if our

  • actins and myosins and indeed interacting and tugging on

  • one another, the way that we think that they should

  • these are going to be pulled inward. It's almost like kind of bringing

  • a wall in towards the center. You can kind of think of it that way.

  • You can kind of think of the actin as a rope hanging off the end of this

  • z-disc. And the myosin is literally

  • got it's hands on it, yanking on the rope and tugging on the z-disc.

  • In fact, lots and lots of myosin are doing it all at once.

  • Kind of in unison. So that's why these discs get moved toward

  • the center. And when they get moved toward the center, we literally call that 'contraction' of the cell.

  • Or cell contraction. And so these actin ropes

  • uh, if you want to keep thinking of it in that way,

  • aren't going to be cut or shrunk or anything. They're going to stay the same length.

  • But these z-discs seem to be brought closer together.

  • the entire thing looks a litte bit more crowded, because the myosin has brought everything to the center.

  • So that's cell contraction.

  • Now, I'm gonna actually take a further zoom-in. Let's say you

  • actually wanted to zoom in

  • to something like this, this white box. Kind of take a look at what that might look like.

  • Let's see that. I'm gonna make a little bit of space. Let's just keep that scene like that.

  • Let me start my drawing the actin, it's gonna look something like this.

  • And I'm gonna try to keep it somewhat consistent, and we're gonna see what it is that

  • draw along the way. So we've got our actin and we've got our myocin.

  • And our myosin, I'm gonna orient kind of in the same direction as our actin. It's gonna look something like this.

  • Let's say it's one head there. And let's say we've got our second head there.

  • So we've got our myosin. And of course our myosin is gonna continue in really in both directions, but the majority of the myosin is gonna be that way.

  • So we've got our actin and we've got our myosin, and the story from the previous picture ends there, but we know that we've got our myosin

  • actin binding sites are gonna be kind abound up

  • by trophomyosin. Trophomyosin is gonna be snaking its through. Looks a little bit like that. And it's basically gonna be sitting in all

  • binding sites that myosin really can't get in there. And in fact, there's also

  • another protein. We talked about the fact that there's another protein called troponin.

  • And troponin is also kind of in the same area I'm actually gonna draw troponin like this.

  • You might be thinking "Why am I drawing troponin in three parts? Why is there a little crescent shaped thing and two little circles?"

  • And actually, troponin, even though previously we've talked about troponin as one protien,

  • this whole thing. It's probably more commonly known as 'troponin complex', instead of just the one word 'troponin'.

  • It's actually a complex of proteins. And there are three to be precise. There's troponin-C over here.

  • I, and T right over here. And if that's not clear, let me put it over on the side here.

  • So there's Troponin-C, troponin-I, and troponin-T. And in yellow we've got our tropomyosin. So now our picture is looking a little bit more accurate, right?

  • Now we've got all of this stuff going on, with the tropomyosin getting in the way of our

  • myosin head. Now, what's gonna make that troponin complex move

  • away? What's gonna kind of clear space for our myosin head? Well, we know

  • that it's gonna be calcium. And I'm gonna draw calcium here, binding to which part of the troponin complex?

  • Troponin c! C, like calcium.

  • Is what's gonna bind the calcium. So troponin c is gonna bind the calcium.

  • And once it does, once the calcium is down there, it now can scooch

  • the tropomyosin out of the way.

  • So, now the tropomyosin (I'm gonna draw this in green arrows), is basically

  • schooched out of the way, and the myosin head is very happy.

  • 'Cuz it can

  • bind finally to the actin.

  • Now, if there's no calcium. Like you can see in our friend to the right,

  • this troponin is not gonna bind to the calcium.

  • So the tropomyosin is not moved out of the way, it's in the way.

  • And at the end of the day, the myosin is gonna be sad! Because it cannot bind to that actin.

  • So you can see now, from a myosin standpoint, it likes when calcium is around.

  • Because that means it can do work.

  • Now let me clear a little more space for us, and I'm gonna bring up one final point.

  • I mean, if we think that a happy myosin head is a working myosin head, if we take

  • that approach, it's a little bit like I guess getting a job! Right, it makes everyone happy when they get a job.

  • when they're employed. And myosin heads are no different, they want to be employed.

  • So how do you employ myosin heads? How do you get more jobs for myosin heads?

  • Well, there are basically two strategies for increasing what we call 'inotropine',

  • basically getting more myosin heads working. So two strategies, let's go through them one by one.

  • So the first strategy would be what? Well, you could affect the amount of calcium.

  • You could get more calcium around. That would be one strategy.

  • And the other strategy might be: you could have the troponin c

  • Remember, the troponin c is part of the complex that's binding the calcium,

  • You could get troponin c to be more sensitive to calcium.

  • And I'm gonna put that in quotes. What do I mean by 'sensitive'?

  • Essentially, you're saying that troponin c could change

  • its shape or its confirmation to bind the calcium that's already around more easily.

  • Basically, you're binding calcium more easily. But I wanted to put the word

  • 'sensitive' because sometimes you'll see that word, and you'll wonder what it means.

  • So bind calcium more easily. So these are the two basic strategies.

  • And you could imagine increasing in one strategy, increasing the calcium, b

  • but leaving the sensitivity of troponin c the same.

  • Really, not changing how easily it will bind calcium.

  • And the overall effect is more myosin heads are working!

  • So more myosin heads are working.

  • That would the overall effect.

  • And you could flip it around. You could say

  • Maybe you have the same amount of calcium, maybe you don't actually increase the calcium,

  • but you do make troponin c bind the calcium that is there more readily.

  • Or more easily. Well, in that siutation, you also get more myosin heads working.

  • So in either scenario, in either strategy, you're going to get more

  • myosin heads working. And so these are the two basic strategies for inotropy.

I'm gonna draw for you the heart

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カルシウムがミオシンを働かせる (Calcium Puts Myosin to Work)

  • 42 9
    Cheng-Hong Liu に公開 2021 年 01 月 14 日
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