Alright. Step 1 of the citric acid cycle is carried out by citrate synthase and notice that nice negative delta G. Remember, this is one of those driving steps of the citric acid cycle. In the process of this reaction, we have our acetyl CoA interacting with oxaloacetate. We add water in, we bump off that CoA. See you later. And we are left with citrate right here.
Now, the following reaction, reaction number 2, is carried out by aconitase. And you might notice that it is listed as having a positive delta. Notice though that that's the Δ′°. At actual cellular conditions, this ΔG is closer to 0. It's a readily reversible reaction. Here, citrate is turned into this enzymatic intermediate, cis-aconitate, which you can see right here in the middle, and ultimately it's turned into isocitrate. During this process, we remove water and then we actually add water back in. That is why it's sometimes called the Ferris wheel; it is kind of like doing a turn.
What is interesting to note, and also important to note about this reaction, is that citrate is prochiral. What that means is that, even though it's not actually a chiral molecule, it behaves as if it were chiral and that's because aconitase binds citrate in one orientation. It just happens this way; you don't need to know why this is, but just notice that citrate is a symmetric molecule. So this is not a chiral center. However, right here is always where this double bond is going to be formed. Citrate wouldn't go in in the other orientation and have it be formed there. It just happens that way and we call that property prochiral, meaning not actually chiral but behaving as if it were chiral.
Something about aconitase that's interesting to note is that it contains these iron-sulfur complexes, which are actually held into the enzyme by cysteine residues. This is not going to be the last time we talk about iron-sulfur complexes. Those are going to come up in the next review when we talk about the electron transport chain because there are a ton of them in there. What's cool about aconitase, in terms of these iron-sulfur complexes, is that it's actually an iron response regulatory molecule. When there is a lack of iron, it changes its shape due to this lack; it can actually bind RNA. If it binds RNA, it will turn on and off various genes. What's going to happen is when iron is high in the blood, ferritin, this molecule, is going to be produced. And when iron is low in the blood, this molecule, transferrin, is going to be produced. Aconitase has this auxiliary function; it's not just an enzyme that's part of the citric acid cycle, and again, this continues the theme that biology recycles things. It always finds new purposes for old creations. It's always innovating.
The third reaction of the citric acid cycle is carried out by isocitrate dehydrogenase. We are going to take isocitrate and form alpha-ketoglutarate (alpha KG). I'm just abbreviating it that way because I'm being lazy. A couple of interesting notes about this reaction: as we've already said, it generates NADH and releases a CO2. Definitely important to note. Here is our CO2 that's coming off. So that is our released CO2, and that makes this enzyme an oxidative decarboxylase. Notice how we are oxidizing that alcohol. It uses NAD+ or NADP+ as the electron acceptor. However, for us, for humans, we're going to be using NAD+ to generate NADH. It also uses manganese as a cofactor. Although it's a dehydrogenase, it does not use other molecules such as TPP, lipoate, FAD, and CoA like pyruvate dehydrogenase does. However, alpha-ketoglutarate dehydrogenase, which we will talk about in just a moment, uses all this stuff. That's why I point out here that isocitrate doesn't use it. Pyruvate dehydrogenase and alpha-ketoglutarate dehydrogenase do use these molecules. So, don't go thinking all dehydrogenases use those same molecules.
With that, let's flip the page.
