ATP & Respiration: Crash Course Biology #7

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Oh, hello there. I'm at the gym. I don't know why you're here, but I'm going to do some

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pushups, so you can join me on the floor if you want.

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Now, I'm not doing this to show off or anything. I'm actually doing this for science.

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[pained grunt]

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You see what happened there?

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My arms moved, my shoulders moved, my back and stomach muscles moved, my heart pumped

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blood to all those different places. Pretty neat, huh?

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Well, it turns out that how we make and use energy is a lot like sports or other kinds of exercise

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It can be hard work and a little bit complicated but if you do it right, it can come with some

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tremendous payoffs.

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But unlike hitting a ball with a stick, it's so marvelously complicated and awesome that

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we're still unraveling the mysteries of how it all works. And it all starts with a

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marvelous molecule that is one of you best friends: ATP.

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Today I'm talking about energy and the process our cells, and other animal cells, go through

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to provide themselves with power.

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Cellular respiration is how we derive energy from the food we eat--specifically from glucose,

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since most of what we eat ends up as glucose.

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Here's the chemical formula for one molecule of glucose [C6H12O6]. In order to turn this

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glucose into energy, we're going to need to add some oxygen. Six molecules of it, to be exact.

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Through cellular respiration, we're going to turn that glucose and oxygen into 6 molecules

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of CO2, 6 molecules of water and some energy that we can use for doing all our push ups.

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So that's all well and good, but here's the thing: We can't just use that energy

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to run a marathon or something. First our bodies have to turn that energy into a really

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specific form of stored energy called ATP, or adenosine triphosphate. You've heard

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me talk about this before. People often refer to ATP as the "currency" of biological energy.

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Think of it as an American dollar--it's what you need to do business in the U.S. You

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can't just walk into Best Buy with a handful of Chinese yen or Indian rupees and expect

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to be able to buy anything with them, even though they are technically money. Same goes

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with energy: In order to be able to use it, our cells need energy to be transferred into

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adenosine triphosphate to be able to grow, move, create electrical impulses in our nerves

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and brains. Everything. A while back, for instance, we talked about how cells use ATP

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to transport some kinds of materials in and out of its membranes; to jog your memory about

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that you can watch it right here.

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Now before we see how ATP is put together, let's look at how cells cash in on the energy

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that's stashed in there.

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Well, adenosine triphosphate is made up of an nitrogenous base called adenine with a

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sugar called ribose and three phosphate groups attached to it:

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Now one thing you need to know about these 3 phosphate groups is that they are super

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uncomfortable sitting together in a row like that -- like 3 kids on the bus who hate each

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other all sharing the same seat.

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So, because the phosphate groups are such terrible company for each other, ATP is able

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to do this this nifty trick where it shoots one of the phosphates groups off the end of

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the seat, creating ADP, or adenosine diphosphate (because now there are just two kids sitting

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on the bus seat). In this reaction, when the third jerk kid is kicked off the seat, energy is released.

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And since there are a lot of water molecules just floating around nearby, an OH pairing

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-- that's called a hydroxide -- from some H2O comes over and takes the place of that

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third phosphate group. And everybody is much happier.

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By the way? When you use water to break down a compound like this, it's called hydrolysis

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-- hydro for water and lysis, from the Greek word for "separate."

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So now that you know how ATP is spent, let's see how it's minted -- nice and new -- by

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cellular respiration.

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Like I said, it all starts with oxygen and glucose. In fact, textbooks make a point of

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saying that through cellular respiration, one molecule of glucose can yield a bit of

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heat and 38 molecules of ATP. Now, it's worth noting that this number is kind of a best

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case scenario. Usually it's more like 29-30 ATPs, but whatever -- people are still studying

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this stuff, so let's stick with that 38 number.

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Now cellular respiration isn't something that just happens all at once -- glucose is

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transformed into ATPs over 3 separate stages: glycolysis, the Krebs Cycle, and the electron

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transport chain. Traditionally these stages are described as coming one after the other,

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but really everything in a cell is kinda happening all at the same time.

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But let's start with the first step: glycolysis, or the breaking down of the glucose.

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Glucose, of course, is a sugar--you know this because it's got an "ose" at the end

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of it. And glycolysis is just the breaking up of glucose's 6 carbon ring into two 3-carbon

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molecules called pyruvic acids or pyruvate molecules.

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Now in order to explain how exactly glycolysis works, I'd need about an hour of your time,

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and a giant cast of finger puppets each playing a different enzyme, and though it would pain

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me to do it, I'd have to use words like phosphoglucoisomerase.

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But one simple way of explaining it is this: If you wanna make money, you gotta spend money.

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Glycolysis needs the investment of 2 ATPs in order to work, and in the end it generates

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4 ATPs, for a net profit, if you will, of 2 ATPs.

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In addition to those 4 ATPs, glycolysis also results in 2 pyruvates and 2 super-energy-rich

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morsels called NADH, which are sort of the love-children of a B vitamin called NAD+ pairing

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with energized electrons and a hydrogen to create storehouses of energy that will later

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be tapped to make ATP.

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To help us keep track of all of the awesome stuff we're making here, let's keep score?

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So far we've created 2 molecules of ATP and 2 molecules of NADH, which will be used

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to power more ATP production later.

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Now, a word about oxygen. Like I mentioned, oxygen is necessary for the overall process

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of cellular respiration. But not every stage of it. Glycolysis, for example, can take place

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without oxygen, which makes it an anaerobic process.

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In the absence of oxygen, the pyruvates formed through glycolysis get rerouted into a process

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called fermentation. If there's no oxygen in the cell, it needs more of that NAD+ to

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keep the glycolysis process going. So fermentation frees up some NAD+, which happens to create

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some interesting by products.

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For instance, in some organisms, like yeasts, the product of fermentation is ethyl alcohol,

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which is the same thing as all of this lovely stuff. But luckily for our day-to-day productivity,

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our muscles don't make alcohol when they don't get enough oxygen. If that were the

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case, working out would make us drunk, which actually would be pretty awesome, but instead

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of ethyl alcohol, they make lactic acid. Which is what makes you feel sore after that workout

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that kicked your butt.

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So, your muscles used up all the oxygen they had, and they had to kick into anaerobic respiration

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in order to get the energy that they needed, and so you have all this lactic acid building

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up in your muscle tissue.

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Back to the score. Now we've made 2 molecules of ATP through glycolysis, but your cells

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really need the oxygen in order to make the other 30-some molecules they need.

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That's because the next two stages of cellular respiration -- the Krebs Cycle and the electron transport

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chain, are both aerobic processes, which means they require oxygen.

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And so we find ourselves at the next step in cellular respiration after glycolosis:

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the Krebs Cycle.

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So, while glycolysis occurs in the cytoplasm, or the fluid medium within the cell that all

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the organelles hang out in, the Krebs Cycle happens across the inner membrane of the mitochondria,

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which are generally considered the power centers of the cell. The Krebs Cycle takes the products

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of glycolysis -- those carbon-rich pyruvates -- and reworks them to create another 2 ATPs

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per glucose molecule, plus some energy in a couple of other forms, which I'll talk

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about in a minute. Here's how:

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First, one of the pyruvates is oxidized, which basically means it's combined with oxygen.

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One of the carbons off the three-carbon chain bonds with an oxygen molecule and leaves the

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cell as CO2. What's left is a two-carbon compound called acetyl coenzyme A, or acetyl

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coA. Then, another NAD+ comes along, picks up a hydrogen and becomes NADH. So our two

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pyruvates create another 2 molecules of NADH to be used later.

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As in glycolysis, and really all life, enzymes are essential here; they're proteins that

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bring together the stuff that needs to react with each other, and they bring it together

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in just the right way. These enzymes bring together a phosphate with ADP, to create another

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ATP molecule for each pyruvate. Enzymes also help join the acetyl coA and a 4-carbon molecule

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called oxaloacetic acid.

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I think that's how you pronounce it.

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Together they form a 6-carbon molecule called citric acid, and I'm certain that's how you

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pronounce that one because that's the stuff that's in orange juice.

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Fun fact: The Krebs Cycle is also known as the Citric Acid Cycle because of this very

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byproduct. But it's usually referred to by the name of the man who figured it all out:

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Hans Krebs, an ear nose and throat surgeon who fled Nazi Germany to teach biochemistry

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at Cambridge, where he discovered this incredibly complex cycle in 1937. For being such a total

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freaking genius, he was awarded the Nobel Prize in Medicine in 1953.

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Anyway, the citric acid is then oxidized over a bunch of intricate steps, cutting carbons

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off left and right, to eventually get back to oxaloacetic acid, which is what makes the

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Krebs Cycle a cycle. And as the carbons get cleaved off the citric acid, there are leftovers

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in the form of CO2 or carbon dioxide , which are exhaled by the cell, and eventually by

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you. You and I, as we continue our existence as people, are exhaling the products of the

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Krebs Cycle right now. Good work.

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This video, by the way, I'm using a lot of ATPs making it.

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Now, each time a carbon comes off the citric acid, some energy is made, but it's not

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ATP. It's stored in a whole different kind of molecular package. This is where we go

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back to NAD+ and its sort of colleague FAD.

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NAD+ and FAD are both chummy little enzymes that are related to B vitamins, derivatives

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of Niacin and Riboflavin, which you might have seen in the vitamin aisle. These B vitamins

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are good at holding on to high energy electrons and keeping that energy until it can get released

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later in the electron transport chain. In fact, they're so good at it that they show

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up in a lot of those high energy-vitamin powders the kids are taking these days.

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NAD+s and FADs are like batteries, big awkward batteries that pick up hydrogen and energized

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electrons from each pyruvate, which in effect charges them up. The addition of hydrogen

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turns them into NADH and FADH2, respectively.

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Each pyruvate yeilds 3 NADHs and 1 FADH2 per cycle, and since each glucose has been broken

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down into two pyruvates, that means each glucose molecule can produce 6 NADHs and 2 FADH2s.

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The main purpose of the Krebs Cycle is to make these powerhouses for the next and final

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step, the Electron Transport Chain.

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And now's the time when you're saying, "Sweet pyruvate sandwiches, Hank, aren't we supposed

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to be making ATP? Let's make it happen, Capt'n! What's the holdup?"

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Well friends, your patience has paid off, because when it comes to ATPs, the electron

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transport chain is the real moneymaker. In a very efficient cell, it can net a whopping

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34 ATPs.

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So, remember all those NADHs and FADH2s we made in the Krebs Cycle? Well, their electrons

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are going to provide the energy that will work as a pump along a chain of channel proteins

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across the inner membrane of the mitochondria where the Krebs Cycle occurred. These proteins

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will swap these electrons to send hydrogen protons from inside the very center of the

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mitochondria, across its inner membrane to the outer compartment of the mitochondria.

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But once they're out, the protons want to get back to the other side of the inner membrane,

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because there's a lot of other protons out there, and as we've learned, nature always

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tends to seek a nice, peaceful balance on either side of a membrane. So all of these

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anxious protons are allowed back in through a special protein called ATP synthase. And

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the energy of this proton flow drives this crazy spinning mechanism that squeezes some

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ADP and some phosphates together to form ATP. So, the electrons from the 10 NADHs that came

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out of the Krebs Cycle have just enough energy to produce roughly 3 ATPs each.

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And we can't forget our friends the FADH2s. We have two of them and they make 2 ATPs each.

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And voila! That is how animal cells the world over make ATP through cellular respiration.

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Now just to check, let's reset our ATP counter and do the math for a single glucose molecule

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once again:

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We made 2 ATPs for each pyruvate during glycolysis.

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We made 2 in the Krebs Cycle.

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And then during the electron transport chain we made about 34 in the electron transport chain.

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And that's just for one molecule of glucose. Imagine how much your body makes and uses

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every single day.

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Don't spend it all in one place now! You can go back and watch any parts of this episode

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that you didn't quite get and I really want to do this quickly because I'm getting very tired.

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If you want to ask us questions you can see us in the YouTube comments below and of course,

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you can connect with us on Facebook or Twitter.

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[manly grunt]