ATP & Respiration: Crash Course Biology #7

CrashCourse
12 Mar 201213:25

Summary

TLDRThis script delves into the science of energy production in our bodies through cellular respiration. It explains how glucose and oxygen are converted into ATP, the 'currency' of biological energy, via three stages: glycolysis, the Krebs Cycle, and the electron transport chain. The process is likened to a complex financial system, with ATP acting as the required 'currency' for cellular activities. The explanation simplifies the biochemical process, making it accessible and engaging, and highlights the importance of oxygen in aerobic respiration and the production of lactic acid during anaerobic respiration.

Takeaways

  • πŸ‹οΈβ€β™‚οΈ The script discusses the process of cellular respiration, which is how our cells derive energy from the food we eat, specifically glucose.
  • πŸ”¬ Cellular respiration requires oxygen and glucose to produce ATP (adenosine triphosphate), which is the primary form of stored energy in cells.
  • 🌐 ATP is often referred to as the 'currency' of biological energy, similar to how money is used in an economy.
  • πŸ’ͺ The script uses the analogy of doing pushups to illustrate how muscles use ATP for energy, highlighting the importance of ATP in muscle movement and other bodily functions.
  • πŸ”‹ ATP is made up of adenine, ribose, and three phosphate groups. The release of energy from ATP occurs when one phosphate group is removed, forming ADP (adenosine diphosphate).
  • πŸ”„ Cellular respiration involves three main stages: glycolysis, the Krebs Cycle, and the electron transport chain. These stages convert glucose and oxygen into ATP, CO2, and water.
  • 🌱 Glycolysis is an anaerobic process that can occur without oxygen, breaking down glucose into pyruvate molecules and generating a small amount of ATP and NADH.
  • πŸ‡ The Krebs Cycle takes place in the mitochondria and uses the products of glycolysis to produce additional ATP, NADH, and FADH2, which are used in the electron transport chain.
  • πŸ’‘ The electron transport chain is the most efficient part of cellular respiration, generating a significant amount of ATP by using the electrons from NADH and FADH2 to pump protons across the mitochondrial membrane.
  • πŸƒβ€β™‚οΈ Lactic acid is produced during anaerobic respiration when muscles do not have enough oxygen, leading to muscle soreness after intense exercise.
  • 🌟 The script emphasizes the complexity and marvel of cellular respiration, highlighting that it is still an area of ongoing scientific study and discovery.

Q & A

  • What is the main purpose of cellular respiration?

    -The main purpose of cellular respiration is to derive energy from the food we eat, specifically from glucose, by converting it into ATP, which is used for various cellular activities.

  • What is ATP and why is it important for our cells?

    -ATP, or adenosine triphosphate, is a molecule that stores and provides energy for various cellular functions. It is often referred to as the 'currency' of biological energy because cells require ATP to perform work, such as growth, movement, and the creation of electrical impulses in nerves and brains.

  • How does the body convert glucose into a usable form of energy?

    -The body converts glucose into a usable form of energy through a process called cellular respiration, which involves three stages: glycolysis, the Krebs Cycle, and the electron transport chain. This process ultimately produces ATP, CO2, and water.

  • What is the role of oxygen in cellular respiration?

    -Oxygen plays a crucial role in cellular respiration, particularly in the latter stages of the process. It is required for the Krebs Cycle and the electron transport chain, which are aerobic processes that help generate the majority of ATP.

  • What happens during glycolysis and what is its net gain in terms of ATP?

    -During glycolysis, glucose is broken down into two pyruvate molecules. This process requires an initial investment of 2 ATPs but generates a net gain of 2 ATPs, along with 2 NADH molecules.

  • What is fermentation and how does it differ from aerobic respiration?

    -Fermentation is an anaerobic process that occurs when oxygen is not available. It reroutes pyruvates into a different pathway to regenerate NAD+, which is necessary for glycolysis to continue. Unlike aerobic respiration, fermentation does not produce a significant amount of ATP and results in the production of byproducts like lactic acid or ethanol.

  • What is the Krebs Cycle and where does it take place within the cell?

    -The Krebs Cycle, also known as the Citric Acid Cycle, is a series of chemical reactions that occur within the mitochondria. It takes the products of glycolysis, pyruvates, and further breaks them down to produce CO2, ATP, NADH, and FADH2.

  • What is the significance of the electron transport chain in ATP production?

    -The electron transport chain is the final stage of cellular respiration and is the most significant in terms of ATP production. It uses the electrons from NADH and FADH2 to create a proton gradient, which drives the synthesis of ATP through a process called oxidative phosphorylation.

  • How does the body manage to produce energy when oxygen is scarce during intense exercise?

    -When oxygen is scarce, such as during intense exercise, the body resorts to anaerobic respiration, specifically fermentation, to produce energy. This process is less efficient and results in the buildup of lactic acid, which can cause muscle soreness.

  • What is the relationship between the number of ATP molecules produced and the stages of cellular respiration?

    -The number of ATP molecules produced varies across the stages of cellular respiration. Glycolysis produces a net of 2 ATPs, the Krebs Cycle produces approximately 2 ATPs per glucose molecule, and the electron transport chain can produce around 34 ATPs, making it the most efficient stage for ATP production.

  • Why is the Krebs Cycle also known as the Citric Acid Cycle?

    -The Krebs Cycle is also known as the Citric Acid Cycle because one of the intermediate products in the cycle is citric acid, which is commonly found in citrus fruits like oranges.

Outlines

00:00

πŸ’ͺ Introduction to Cellular Respiration and ATP

The script begins with an introduction to cellular respiration and the role of ATP as the 'currency' of biological energy. It explains that cellular respiration is the process by which cells derive energy from glucose and oxygen, highlighting the conversion of glucose and oxygen into CO2, water, and ATP. The video aims to unravel the complexities of energy production in cells, starting with the basic molecule ATP, which is essential for various cellular functions, including muscle movement and nerve impulses.

05:00

πŸ”¬ Glycolysis and the Production of ATP and NADH

This paragraph delves into the first stage of cellular respiration, glycolysis, which is the breakdown of glucose into pyruvate molecules. It emphasizes the investment of 2 ATPs to generate 4 ATPs, resulting in a net gain of 2 ATPs. Additionally, it discusses the creation of NADH, an energy-rich molecule, through the combination of NAD+ with energized electrons and hydrogen. The paragraph also touches on the anaerobic process of fermentation that occurs in the absence of oxygen, leading to the production of lactic acid in muscles, which causes post-exercise soreness.

10:04

πŸŒ€ The Krebs Cycle and the Generation of More ATP and NADH/FADH2

The script continues with an explanation of the Krebs Cycle, which takes place in the mitochondria and involves the oxidation of pyruvate to produce acetyl coenzyme A (acetyl CoA), CO2, and NADH. It details the cycle's role in generating 2 more ATPs per glucose molecule and the creation of additional NADH and FADH2, which are essential for the subsequent electron transport chain. The Krebs Cycle is also known as the Citric Acid Cycle, and the paragraph provides a brief history of its discovery by Hans Krebs, highlighting its importance in cellular energy production.

⚑️ The Electron Transport Chain and ATP Synthesis

The final paragraph focuses on the electron transport chain, the most efficient stage in ATP production. It describes how the electrons from NADH and FADH2 act as a pump, moving hydrogen protons across the mitochondrial membrane and creating a gradient that drives the synthesis of ATP through a process known as chemiosmosis. The paragraph explains the role of ATP synthase in this process and quantifies the ATP yield from the electrons of NADH and FADH2, concluding with a tally of ATP produced from a single glucose molecule through the entire cellular respiration process.

Mindmap

Keywords

πŸ’‘ATP

ATP, or adenosine triphosphate, is a crucial molecule in cellular energy transfer. It is often referred to as the 'currency' of biological energy. In the video, ATP is described as a specific form of stored energy that cells use to perform various functions, such as muscle movement and nerve impulses. The script illustrates that ATP is essential for cellular respiration, where it is produced through a series of biochemical reactions involving glucose and oxygen.

πŸ’‘Cellular Respiration

Cellular respiration is the process by which cells derive energy from the food they consume, specifically from glucose. The video explains that this process involves the conversion of glucose and oxygen into carbon dioxide, water, and ATP. It is central to the video's theme as it is the primary mechanism through which cells generate the energy needed for various biological activities.

πŸ’‘Glucose

Glucose is a simple sugar that serves as the primary source of energy for cells. In the context of the video, glucose is depicted as the starting material in cellular respiration, where it is broken down to produce ATP. The script mentions that most of what we eat ends up as glucose, highlighting its importance in energy metabolism.

πŸ’‘Oxygen

Oxygen is a vital component in the process of cellular respiration. The video script emphasizes that oxygen is necessary for the complete breakdown of glucose into ATP. It is also noted that while glycolysis can occur without oxygen, the subsequent stages of cellular respiration, such as the Krebs Cycle and the electron transport chain, require oxygen.

πŸ’‘Glycolysis

Glycolysis is the initial stage of cellular respiration where glucose is broken down into two molecules of pyruvate. The video describes glycolysis as an anaerobic process that does not require oxygen and can generate a net profit of 2 ATPs. It is a key step in the energy production pathway highlighted in the script.

πŸ’‘Krebs Cycle

The Krebs Cycle, also known as the Citric Acid Cycle, is a central part of cellular respiration that occurs in the mitochondria. The video script explains that this cycle takes the products of glycolysis (pyruvates) and further oxidizes them to produce ATP, NADH, and FADH2. It is crucial for generating the energy-rich molecules that power the electron transport chain.

πŸ’‘Electron Transport Chain

The electron transport chain is the final stage of cellular respiration, where the most ATP is produced. The video script describes it as a series of proteins that use the electrons from NADH and FADH2 to pump hydrogen protons across the mitochondrial membrane, creating a proton gradient that drives ATP synthesis.

πŸ’‘NADH and FADH2

NADH and FADH2 are high-energy electron carriers produced during the Krebs Cycle. The video script explains that these molecules are essential for the electron transport chain, where they donate their electrons to create a proton gradient that ultimately leads to ATP synthesis. They are depicted as 'batteries' that store energy until it is needed.

πŸ’‘Hydrolysis

Hydrolysis is the process of breaking down a compound using water. In the context of the video, hydrolysis is used to describe how ATP is broken down into ADP and a phosphate group, releasing energy in the process. This is a key reaction in the utilization of ATP for cellular activities.

πŸ’‘Fermentation

Fermentation is an anaerobic process that occurs in the absence of oxygen. The video script mentions that fermentation can lead to the production of substances like ethyl alcohol in yeast or lactic acid in muscles, which can cause soreness after intense exercise. It is an alternative pathway for energy production when oxygen is limited.

πŸ’‘Proton Gradient

A proton gradient is a concentration difference of hydrogen ions across a membrane. In the video, the proton gradient is created by the electron transport chain and is essential for ATP synthesis. The script explains that the flow of protons back across the membrane through ATP synthase drives the formation of ATP.

Highlights

Introduction to the concept of cellular respiration and its role in deriving energy from glucose.

Chemical formula of glucose [C6H12O6] and its transformation into energy with the addition of oxygen.

ATP as the 'currency' of biological energy and its comparison to an American dollar.

The structure of ATP, composed of adenine, ribose, and three phosphate groups.

The release of energy through the hydrolysis of ATP to ADP.

The three stages of cellular respiration: glycolysis, the Krebs Cycle, and the electron transport chain.

Glycolysis as an anaerobic process that can occur without oxygen.

The net production of 2 ATPs and 2 NADHs during glycolysis.

The role of oxygen in the Krebs Cycle and the electron transport chain.

The Krebs Cycle's function in transforming pyruvate into ATP, NADH, and FADH2.

The Nobel Prize awarded to Hans Krebs for his discovery of the Krebs Cycle.

The electron transport chain as the most efficient ATP producer in cellular respiration.

The process of proton flow and ATP synthesis in the electron transport chain.

The total ATP yield from one molecule of glucose through cellular respiration.

The practical implications of cellular respiration in everyday life and during exercise.

The production of lactic acid as a byproduct of anaerobic respiration and its link to muscle soreness.

The importance of B vitamins in the Krebs Cycle and their presence in energy-vitamin products.

Transcripts

play00:00

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

play00:06

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

play00:08

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

play00:13

[pained grunt]

play00:14

You see what happened there?

play00:16

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

play00:21

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

play00:23

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

play00:28

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

play00:32

tremendous payoffs.

play00:33

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

play00:37

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

play00:40

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

play00:54

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

play00:59

to provide themselves with power.

play01:01

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

play01:06

since most of what we eat ends up as glucose.

play01:09

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

play01:13

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

play01:18

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

play01:22

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

play01:29

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

play01:33

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

play01:37

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

play01:43

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

play01:48

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

play01:53

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

play01:58

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

play02:03

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

play02:07

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

play02:12

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

play02:17

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

play02:22

that you can watch it right here.

play02:23

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

play02:29

that's stashed in there.

play02:30

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

play02:35

sugar called ribose and three phosphate groups attached to it:

play02:39

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

play02:43

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

play02:48

other all sharing the same seat.

play02:50

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

play02:54

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

play02:57

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

play03:03

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

play03:08

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

play03:12

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

play03:16

third phosphate group. And everybody is much happier.

play03:19

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

play03:23

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

play03:26

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

play03:31

cellular respiration.

play03:33

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

play03:38

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

play03:43

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

play03:48

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

play03:53

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

play03:55

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

play03:59

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

play04:05

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

play04:10

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

play04:13

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

play04:18

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

play04:23

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

play04:28

molecules called pyruvic acids or pyruvate molecules.

play04:31

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

play04:36

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

play04:41

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

play04:44

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

play04:51

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

play04:56

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

play05:00

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

play05:07

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

play05:13

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

play05:19

be tapped to make ATP.

play05:21

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

play05:25

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

play05:31

to power more ATP production later.

play05:33

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

play05:38

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

play05:43

without oxygen, which makes it an anaerobic process.

play05:46

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

play05:51

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

play05:56

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

play06:01

some interesting by products.

play06:03

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

play06:09

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

play06:15

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

play06:19

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

play06:24

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

play06:30

that kicked your butt.

play06:31

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

play06:35

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

play06:40

up in your muscle tissue.

play06:45

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

play06:52

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

play06:56

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

play07:01

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

play07:06

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

play07:12

the Krebs Cycle.

play07:13

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

play07:17

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

play07:23

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

play07:27

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

play07:33

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

play07:38

about in a minute. Here's how:

play07:39

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

play07:43

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

play07:47

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

play07:53

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

play07:59

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

play08:03

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

play08:09

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

play08:13

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

play08:19

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

play08:25

called oxaloacetic acid.

play08:27

I think that's how you pronounce it.

play08:30

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

play08:35

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

play08:44

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

play08:48

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

play08:55

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

play09:01

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

play09:07

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

play09:11

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

play09:17

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

play09:22

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

play09:28

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

play09:34

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

play09:41

Krebs Cycle right now. Good work.

play09:44

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

play09:49

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

play09:54

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

play09:59

back to NAD+ and its sort of colleague FAD.

play10:04

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

play10:09

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

play10:13

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

play10:18

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

play10:22

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

play10:27

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

play10:32

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

play10:37

turns them into NADH and FADH2, respectively.

play10:40

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

play10:49

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

play10:56

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

play11:02

step, the Electron Transport Chain.

play11:04

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

play11:09

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

play11:12

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

play11:17

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

play11:22

34 ATPs.

play11:23

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

play11:29

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

play11:34

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

play11:39

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

play11:44

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

play11:47

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

play11:52

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

play11:57

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

play12:02

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

play12:07

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

play12:11

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

play12:17

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

play12:22

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

play12:28

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

play12:34

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

play12:39

once again:

play12:40

We made 2 ATPs for each pyruvate during glycolysis.

play12:44

We made 2 in the Krebs Cycle.

play12:45

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

play12:49

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

play12:56

every single day.

play12:57

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

play13:02

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

play13:08

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

play13:12

you can connect with us on Facebook or Twitter.

play13:15

[manly grunt]

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Related Tags
Cellular RespirationEnergy ProductionATPGlycolysisKrebs CycleElectron TransportBiological EnergyMitochondriaAnaerobic ProcessFermentation