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AP®︎/College Biology
Course: AP®︎/College Biology > Unit 3
Lesson 5: Cellular respiration- Cellular respiration introduction
- Introduction to cellular respiration and redox
- Steps of cellular respiration
- Overview of cellular respiration
- Oxidative phosphorylation and the electron transport chain
- Oxidative phosphorylation
- Fermentation and anaerobic respiration
- ATP synthase
- Cellular respiration
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Oxidative phosphorylation and the electron transport chain
Oxidative phosphorylation produces ATP (energy) in our cells. NADH, a molecule produced during cellular respiration, gets oxidized and releases electrons. These electrons pass through a series of acceptors in the electron transport chain, releasing energy. This energy pumps hydrogen protons across a membrane, creating a gradient. Finally, the enzyme ATP synthase uses this gradient to produce ATP.
Want to join the conversation?
How does the ADP and Pi get into the matrix to begin with?(17 votes)
There are two transport systems in the inner mitochondrial membrane. To get ADP in and at the same time ATP out of the matrix there is the ADP/ATP-Antiporter (translocase) and to get Pi in you need a symporter which tranports both Pi and one proton into the matrix.(18 votes)
In all the videos there is usage of the term "NADH" and "NAD+".
Are NADH equals NADPH and NAD+ equals NADP+?(11 votes)
NAD+ and NADP+ are two different coenzymes. NADP+ has an extra phosphate group attached and is the coenzyme that is invovled in photosynthesis. NAD+ is the coenzyme involved in cellular respiration.(23 votes)
so in total of the 3 stages(glycolysis,kerb, and etc) only 6 atps,10 NADH, and 2 FADH are produced?(1 vote)
glycolysis, the link reaction and the krebs cycle produce 10 NADH, 2 FADH2 (which are turned into NAD+ and FAD in the ETC and reused) and 4 ATP
the electron transport chain uses the 10 NADH and 2 FADH2 to produce 34 ATP
so in total 38 ATP are produced (however irl it's usually less, 38 would be the best case scenario)(21 votes)
Is ATP synthase and ATPase the same thing?(7 votes)- ATP synthase is a type of ATPase.
An ATPase generally uses the breakdown of ATP to ADP and Pi to drive another reaction. Transmembrane ATPases often use ATP hydrolysis to pump ions against their concentration gradients. ATP synthase is like one of these acting in reverse, where H+ ions flow down an electrochemical (concentration and charge) gradient to drive production of ATP.(10 votes)
- For the ETC, why can't we just use some other electron acceptor than oxygen, like flouride or something?(7 votes)
Some microorganisms do use different electron acceptors, but they often live in anaerobic environments.
A big part of why oxygen is used is availability — oxygen is the most abundant element in the earth's crust§ and second most abundant in the atmosphere. It also occurs in easily accessible forms (O₂ (g) and water).
Fluorine is much less common and is generally not accessible.
(Note you couldn't use fluoride since that is already reduced!)
Fluorine has two other problems.
First, which would you prefer to be exposed to F₂ (g) or O₂ (g)?
Second, think about what the end product of the ETC is —now what would happen if you replaced oxygen with fluorine‽
§https://en.wikipedia.org/wiki/Abundance_of_elements_in_Earth%27s_crust(6 votes)
- For the hydrogen protons to cross the phospholipid bilayer, wouldn't there need to be some kind of facilitated diffusion because they are polar?(5 votes)
ATP synthase has two subunits. The F0 subunit is embedded in the inner mitochondrial membrane, whereas the remainder (F1 subunit) resides in the matrix. The F0 is a hydrophobic segment that spans the inner mitochondrial membrane, so F0 contains the proton channel of the complex. So basically, ATP synthase has a subunit, F0, which IS the channel for the transport of H+ from the intermembrane space back into the matrix. (High [H+] ---> low [H+](8 votes)
I have some questions:
Can someone explain how exactly energy is released when an electron acceptor along the ETC accepts the two electrons?
Also, I am confused about where 2H+ comes from in the equation at2:37. I understand that the 2 electrons are a result of the oxidation of NADH and oxygen is the acceptor, but where does the 2H+ come from?
And, finally, when "oxygen is reduced" in the equation, how is the resulting water molecule used? What happens to it? Or is the produced energy the only relevant product of the ETC?(4 votes)- Some of the energy isn't released but used to move "protons" from the matrix to intermembrane space across the inner mitochondrial membrane (IMM). This "proton" gradient is what drives oxidative phosphorylation. The rest just ends up as heat.
As far as I can tell the hydrogen ions come from hydronium (H₃O⁺), which is naturally present in all aqueous solutions. Note that "consuming" H⁺ in the matrix increases the "proton" gradient across the IMM, so this helps with energy production.
Water is the waste product of this reaction, in most cases its contribution to the organisms water needs is small (e.g. ≤10% in humans). However, some organisms (camels are the example I know), store a large amount of fat (in their humps). They then break down the fats, which feed into the Krebs cycle and oxidative phosphorylation — the water produced by this is thought to be essential to their survival.
Does that help?(5 votes)
- Which process happens first the electron transport chain or the Oxidative phosphorylation?(4 votes)
They happen simultaneously. The proton gradient created by the electron transport chain is used by ATP synthase to produce ATP which is oxidative phosphorylation.(5 votes)
- what is the place where ect take place(2 votes)
It takes place in the membrane of the mitochondria. The protein pumps protons to one side of the membrane to keep a gradient to power ATP synthase.(8 votes)
@2:49What is Sal saying? The captions just say 'mumbles'.(3 votes)
He just keeps correcting himself(4 votes)
2:37Video transcript
- When we looked at glycolysis and the conversion of Pyruvate to Acetyl-CoA and then the
Krebs or the Citric acid Cycle, we were sometimes directly producing ATPs but we were also doing a lot
of reduction of NAD to NADH, and we later said that NADH, that that can later be oxidized, too, and that energy from that oxidation, that energy that's
released from the electrons can be used to actually create ATP, and NADH is the main character here, but there are other
coenzymes that are involved, like coenzyme Q, and you
see that right over here. And what I want to talk
about in this video is the process by which we
actually are able to produce ATP from the oxidation of these coenzymes, and that process is what we call Oxidative Phosphorylation. Oxidative, Oxidative Phosphorylation. Now the main player, when we're talking about cellular respiration
and Oxidative Phosphorylation, is NADH. NADH, in the process of being oxidized to NAD, so it gets oxidized to N... it gets oxidized to NAD,
which has a positive charge, I often call it NAD+, but let's
think about what this says. If we just look at this
reaction from the point of view of NADH being oxidized, remember, oxidation is losing electrons, so NAD+, and then you're gonna have plus a hydrogen proton plus, you're going to have two electrons, plus two electrons. So this is what's happening when NADH is being oxidized into NAD, so this is Oxidation right over here. Let me do this in another color. So this is Oxidation, and
this process of Oxidation, if these electrons get the
appropriate acceptor molecule, it can release a lot of energy, and the eventual acceptor
of those electrons, and I can show the corresponding
reduction reaction, is we have two electrons, two electrons plus two hydrogen protons, or really, just two
protons, a hydrogen nucleus is just a proton, it
doesn't have a neutron for the main isotope of hydrogen. So two protons plus half of an oxygen molecule yielding, you put all of these
two, all of these three, all of these things
together, I should say, and you are going to get a water molecule. So you can think of it as the oxygen being the final acceptor of the electrons, and oxygen likes to be doing oxid-- likes to oxidize things, that's where the whole
word Oxidation comes from. So here, (mumbles) oxygen likes to be reduced. It likes to hog electrons, so this is oxygen is being reduced. Oxygen, Oxygen reduced. So if you just directly
transferred these electrons from our NADH to the Oxygen, it would release a lot of energy but it would release so much energy that you wouldn't be able
to capture most of it. You wouldn't be able to use
it to actually do useful work, and so the process of
Oxidative Phosphorylation is all about doing this
at a series of steps and we do it by
transferring these electrons from one electron acceptor
to another electron acceptor, and every time we do that,
we release some energy, and then that energy can be,
in a more controlled way, be used to actually do
work, and in this case, that work is pumping hydrogen protons across a membrane, and then
that gradient that forms can actually be used to generate ATP, so let's talk through
it a little bit more. So we're gonna go, these electrons, they're gonna be transferred, and I won't go into all of the details, this is to just give you a
high-level overview of it. They're going to be transferred
to different acceptors which then transfer it
to another acceptor, so it might go to a Coenzyme, Coenzyme Q, and a Cytochrome, Cytochrome C, and it keeps
going to different things, eventually getting to this
state right over here, where those electrons can be accepted by the oxygen to actually form the
water, and the process, every step of the way,
energy is being released. Energy is being released, and this energy, as we
will see in a second, is being used to pump hydrogen protons across a membrane, and we're
gonna use that gradient to actually drive the production of ATP. So let's think about
that a little bit more. So let's zoom in on, on a mitochondria. So this is mitochondria. Let's say that's our mitochondria, and let me draw the inner membrane and then, these folds
in the inner membrane, the singular for them is crista. If we're talking about plurals, cristae. So we have these folds in the inner, in the inner membrane right over here. So just to be clear, what's going on, this is the outer membrane, outer membrane. That is the inner
membrane, inner membrane. The space between the outer
and the inner membrane, the space right over here, that is the intermembrane space. Intermembrane, membrane space. And then the space inside
the inner membrane, let me make that sure you
can read that space properly, this space over here, this is the Matrix. This is the Matrix, and
that is the location of our Citric acid Cycle
or our Krebs Cycle, and I can symbolize that
with this little cycle, we have a cycle going on here. And so that's where the bulk
of the NADH is being produced. Now we also talked about
some other coenzymes. In some books or classes,
you might hear about FAD being reduced to FADH2,
which can then be oxidized as part of Oxidative Phosphorylation. Other times, well actually,
that's going to be attached to an enzyme, and then that FADH2 is used to reduce
Coenzyme Q to produce QH2, and then that participates
in Oxidative Phosphorylation, so you could think about
either one of these. I'll focus on QH2. Well, why should we focus on NADH because it's all a similar process? FADH2 or QH2 enters a little bit later down this process, so they don't produce as much energy but they still can be
used to help produce ATP, but anyway, our Citric acid Cycle, which we have shown in previous videos, that occurring in the matrix, and now let me do a little zoom in here, let me do a zoom in. So if I were to zoom in, let's say, let me do this in a color that we can see, so if I were to zoom in right over there, let's show this fold
in the inner membrane, and it's very, and let's make it clear that this is, like all of these membranes, these are all phospholipid bilayers, so, let me draw, let me do the same
color that I did in the, the actual diagram. So, we have... all these, we have a
bilayer of phospholipids and I'm clearly not drawing
any of this stuff to scale, so, almost done. All right, just to make it clear. And you have these enzymes that go across the phospholipid bilayer, and these enzymes are, and these protein complexes
are actually what facilitate Oxidative Phosphorylation and this chain of enzymes, this chain of proteins, is
what we call the electron, or what we call the
electron transport chain. So we draw that. So maybe this is one protein, and I'm just drawing them
as kind of these abstract... You could refer to the
electron transport chain as these proteins or you could
view it as this process of these electrons going from
one acceptor to another, eventually making its way
all the way to the oxygen. So that might be one protein, this is another protein right over here. I'll just do a couple, and this is really about
a high-level overview, and what's happening is as the, and this is
just gonna be a very high-level simplification of it, as you have your, let's say initially, your NADH comes in, so your NADH comes in, and it donates the
protons and the electrons and then it become NAD+, so it just became oxidized, those electrons will go to an acceptor which then gets transferred
to another acceptor then get transferred to another acceptor, and it goes through this
electron transport chain and as that energy is released, that energy is used to pump
hydrogen protons from the Matrix so this side right over here,
the left side right over here, this is the Matrix. This is where our Citric
acid Cycle occurs, so we have protons being pumped out, so we have these protons being pumped out as we release energy, as we go from one electron acceptor to another electron acceptor, and so electrons are going
from higher energy states and they're releasing
energy as they go down this kind of a, towards more
and more electronegative things and they feel more
comfortable with the water than they feel, than
they felt with the NADH, and by doing so, by these
electrons going down that gradient, I guess you could say, or maybe a better way, from going from a, a higher energy state
to a lower energy state, we are creating this proton gradient, so the concentration of protons on the right side of this membrane, just to be clear where this is. This space right over here,
this is right over there, that's the intermembrane space where the hydrogen proton
concentration is building up. Now, this is stored
energy because this is a electrochemical gradient,
all this positive charge, they want to get away from each other, they want to go to this less
positive Matrix right over here and also, just you have
a higher concentration of hydrogens and just natural diffusion. They would want to go down
their concentration gradient into the Matrix. There's less of the protons here. There's less of the protons in the Matrix than there are in the intermembrane space, and so, that's the opportunity
to now take that energy and produce ATP with them, and the way that this
happens, the way this happens, let me extend my membrane a little bit, that's a different color, so let me extend my membrane a little bit, is using a protein called ATP synthase. ATP synthase is actually a
protein complex, I should say. So ATP synthase, really an enzyme, and ATP synthase goes across... It's actually a fascinating,
fascinating molecule. I'll show a better
diagram of it in a second, but your ATP synthase
goes across the membrane, it actually has a fairly
mechanical structure where it has a bit of a housing and it has an axle in the housing, so it looks, maybe, something like this, and it actually has something, you can view this as a, as a thing that maybe holds it together, so it's going across the membrane, I'll show a better
diagram of it in a second. So then, of course, the
membrane continues on, the membrane continues
on, and what happens is it allows these hydrogen protons to flow down their
electrochemical gradient, so these hydrogen protons go down and they actually cause the axle to spin, and so maybe I'll draw it this way. They actually cause the axle to spin as they go down their electrochemical gradient, and as this axle spins,
this axle is not the smooth, it's not like it's made
out of metal or something, it's made out of amino
acids, so it's got this, it's all bumpy and all the rest, so it looks something like this, and what happens is you have ADPs, you have ADPs that get lodged in here, so let's say that's an ADP,
and then a phosphate group, and they have actually
three different sites where this can happen, so that's an ADP and a phosphate group, and there's another site
that I'm not drawing, but as this thing rotates, it essentially keeps changing
the confirmation protein and jams the phosphate group into the ADP which takes energy and
locks them into place to form the ATP. When they form the ATP, they no longer attach to the active site and they let go. So you have this, actually, this mechanical motor, you can view this almost like
a turbine, a water turbine. The water goes through
it and then that energy is used to generate electricity. Here, hydrogen protons go down their electrochemical gradient, that rotary motion is then
used to jam phosphate groups onto ADPs to form ATPs, and so this is the actual
ATP production going on. And to get a better appreciation for what's going on, this is going on in your body right now, this is going on in my body, otherwise I wouldn't be able to talk. This is how I'm generating my energy. This is a more accurate depiction of ATP synthase right over here, and based on this diagram, this is our... let me make sure I... So this right over here, I'm having trouble drawing on this, let me see if I can... So this part right over here, this area right over there, that's our intermembrane space. This right over here is our, this over here is our Matrix. This membrane, this is
a phospholipid bilayer, so if I wanted, I could draw
the bilayer of phospholipids right over here, and this is our inner membrane or we could say this is a
fold in the inner membrane, this could be on our crista, and so the hydrogen protons, they build up in the intermembrane space because of the electron transport chain, and then they flow down their electrochemical gradient, turn this rotor, and then they cause the
creation of the ATPs over here, so you have ADP plus a phosphate group and then you produce your ATP. So this is fascinating, this is going on in
the cells of your body, this is going on as we speak. It's not some abstract thing
that is somehow separate from your reality. This is what is making
your reality possible. So hopefully, you get a
nice appreciation for this. I mean, we spent a lot of time talking about cellular respiration, we spent a lot of time talking about, OK, we can produce some ATPs directly through glycolysis and
through the Citric acid Cycle, but mostly, most of the energy is because of the reduction
of these coenzymes and especially, NAD to NADH, and then in Oxidative Phosphorylation and the electron transport chain, we use the Oxidation of the NADH to pump hydrogen protons from the Matrix to the intermembrane space, and then let them go back through, through the ATP synthase
which jams the phosphate into the ADP to produce the ATP, which is our biological
currency of energy.