Coenzymes in Metabolism: Study with Video Lessons, Practice Problems & Examples

Now, Coenzymes are important in metabolic reactions. We're going to say the driving force of Catabolism is the oxidation of molecules in order to release energy. We're going to say this is accomplished by Coenzymes cycling between their oxidized and reduced forms. Now, here we're going to say the reduced forms act as electron carriers that carry energy that is ultimately passed to bonds of ATP. If we take a look here, we're going to say that we have substrate a.

And to show its reduced form and remember, reduction here is in terms of having hydrogen or not, gaining hydrogen or not. So this substrate a would be the reduced form of it. To show that, we just show a Hydrogen on it. Here, it undergoes Oxidation where it will lose its Hydrogen. So if this thing here is losing its Hydrogen, where is it going?

Well, if it's losing its H, it's handing it over to the Coenzyme. Here the Coenzyme in its Oxidized form doesn't have it, but it gets reduced in this process and now it's in its reduced form. The coenzyme is the carrier of the electrons in the form of this hydrogen component. That hydrogen is not only H, it's the electrons in the bond with it. That reduced form can then take itself, become oxidized back to its oxidized form.

When it becomes oxidized, it's basically handing over its H to substrate b. Substrate b gains that H and now we have it in its reduced form here. So, basically, these coenzymes are kind of acting as a carrier. They're taking electrons from one molecule and handing them over to another one later on. This again ultimately is to help us to create lots and lots of ATP at the end.

So as we progress through our topics, we'll see how this exactly is done.

Here in this example, it says consider the reaction given below and correctly identify the oxidizing agent. Remember, your oxidizing agent is what's been reduced. And what's been reduced has gained electrons, or in this case, Hydrogen with those electrons. And remember, when we're looking at oxidizing agents or reducing agents, those are the reactants. We look at the product side to see where the electrons went, but then we look back at the reactant to determine, okay, this was reduced and this was oxidized.

If we take a look here, we have malate as a reactant and then over here, we have oxaloacetate. Here we have NAD+ which is a coenzyme. But if we look, NAD+ in this form as a reactant but then over here, it has gained a Hydrogen. And not only a Hydrogen but electrons. That's why it's neutral now.

So we're going to say NAD+ gained electrons in Hydrogen and so it was reduced, and therefore it's the oxidizing agent. Now, this question doesn't ask this, but we could also say that Malate had an alcohol group here. This alcohol group was oxidized into a ketone portion here. Remember, we learned this several chapters ago that alcohols can be oxidized into carbonyl groups C=O. So this thing was oxidized.

Therefore, it's the reducing agent. The question doesn't ask this, but we're just trying to cover everything to see the difference. But again, for this particular one, the oxidizing agent would be NAD+.

So, Nicotinamide Adenine Dinucleotide or NAD. We're going to say here the Nicotinamide group of NAD⁺ is the site of reduction that is seeking to become neutral. So we want to lose that charge. If we look here at NAD⁺, it's oxidized form. Nitrogen, remember, when it makes 4 bonds, it's positively charged.

We're trying to remove this positive charge here. We're going to say the reduction occurs by accepting 2 electrons. We have 2 electrons here. And we're going to say here to gain 1 hydrogen. So here, we're going to gain the hydrogen.

The hydrogen will be gained right here. And, initially, we're going to start with 2 hydrogens. We used 1 to attach it to our structure to create NADH, the reduced form, so there'd be one left. Now, here are the results of the reduction of NAD⁺ to NADH. If we take a look here, the way this works is that both of these H⁺ have no electrons whatsoever.

And we're going to say here that 2 of these electrons would bind to one of these H⁺. So 2 electrons plus the 1 H⁺ would give us an H^-. Gain those 2 electrons. It's this H^- that is attaching itself to this site right here. By attaching it to that site there, that's how it's connected to it.

And attaching there causes a shifting of our pi bonds. That's why the structure now looks like this. Nitrogen here is no longer making 4 bonds so it's no longer positively charged. It has a lone pair on it though. Again, it's not important to see how these Pi bonds move around through resonance.

What's important to understand here is that we're going to have this being the site where the H^- attaches. So it's important to know you have NAD⁺ + 2 electrons + 2 H⁺ giving us this structure being able to show the structure. And that's the reduced form. And then having 1 H⁺ left over as a product. Right?

So that's what we should take away from this particular example reaction.

Everyone, let's take a look at the following example. It asks, which of the following correctly identifies the molecules in the given reaction? Here we have lactate reacting with NAD⁺. Remember, NAD⁺ represents our coenzyme, and lactate dehydrogenase is our enzyme.

Through this process, we are able to change lactate to pyruvate. We also have NADH plus H⁺ being produced. Now let's look at our options. We have lactate being discussed within all our options. We have NAD⁺, and we have pyruvate.

Alright. So let's take a look at what they're talking about. So our substrate, which will be our reactant of lactate. So lactate is our substrate. So option b is out, as it's not an enzyme. Then if we look at lactate, lactate has an alcohol group here. And if we look at the product side, that alcohol group has been changed into a carbonyl group. We know that this indicates an oxidation has occurred, so that would mean that lactate represents the reduced substrate that we have, and pyruvate must represent the oxidized form of it.

If we review, the only option that has lactate as a reduced substrate would be option d. Pyruvate is the oxidized form of it, so that's why it's termed an oxidized substrate. And then NAD⁺, like we said earlier, represents a coenzyme. Here it is oxidized because it is going to gain H − here at the end to become NADH, so this must be its oxidized form. This will represent its reduced form.

Remember, in a redox reaction, something is oxidized, and something is reduced. Lactate was oxidized, and then NAD⁺ was reduced. So out of all our options, the answer is option d at the end.

When it comes to the oxidation with NAD⁺, remember that the Nicotinamide group of NAD⁺ is the site of reduction. We're going to say that a basic residue, denoted as b, of an enzyme abstracts an H⁺ from the hydroxyl group of a substrate. What happens here is that the hydride transfers to NAD⁺. If we take a look, we have our residue, basic residue. It would abstract this hydrogen here.

Oxygen would hold on to the electrons to make a double bond here, and at the same time, this hydride ion would leave and attach itself to this carbon of NAD⁺, causing a movement of this pi bond here and a movement of this pi bond to the nitrogen. As a consequence of this, our substrate is now oxidized, and we have a carbonyl here, and then NAD⁺ is reduced to NADH. So here goes the hydrogen, the hydride ion that attached, the pi bond moved here, and then the other pi bond became a lone pair on the nitrogen here. This is how we look at when it comes to NAD⁺ oxidizing our substrate and as a consequence being reduced to NADH.

In this example, it says, reduction of oxaloacetate to malate is facilitated by NADH. Proposal mechanism for this reaction. So we know how to oxidize using NAD⁺. This is just going to be the opposite direction now. We're going to reduce now with NADH.

We're going to have our residue. Let's say this residue has a hydrogen on it, which will come into play later on. What we're going to happen here is we're going to take this lone pair, move it here to make a pi bond. Moving this here to make another pi bond. This is going to leave as a hydride ion and attack this carbonyl carbon.

This pi bond would break, grabbing this hydrogen from our residue. The bond breaks and here, this residue holds on to the electrons. So what we wind up making now, we're reducing oxaloacetate. We're going to make malate over here. So here this carbonyl carbon is now has a hydrogen and an OH.

It's still connected to this carboxylate group. It's connected to this CH₂ group, and then this other carboxylate group. And then here we'd say that NADH changes into NAD⁺. Okay. Now if we wanted to show that, let's actually draw it out so we can see.

Yeah. So we have that. This nitrogen is making 4 bonds now. So it's going to be positively charged. Remember this is NAD⁺.

And then we have this 1 hydrogen here. Okay. So that's how we go from our reactants to our products within this given reaction.

So FAD is called Flavin Adenine Dinucleotide. And we're going to say the flavin group of FAD is the site of reduction that has 2 hydrogen atoms added to its nitrogen atoms. Now, here we're going to say the reduction occurs by adding 2 electrons to 2 H⁺ in order to form 2 new covalent bonds. The result of this is the reduction of FAD to FADH₂. So here we have our oxidized form of the flavon portion of FAD.

We're reacting 2 electrons and 2 H⁺ here. And when we reduce this FAD, we get FADH₂. The 2 hydrogens that we gain, 1 is added here and 1 is added here. Notice that there is a shifting of our pi bonds in order to do this. What's most important is to understand that reduction is happening at this nitrogen and this nitrogen and we have the transformation of FAD to FADH₂.

In this example question, it says, select the correct statement. When FAD is reduced, it gains 2 hydrogen atoms and 2 electrons, forming FADH. Here, this would not be true; remember, it forms FADH₂. FAD represents an oxidized form of the coenzyme and acts as an oxidizing agent. Alright.

So let's think about this. We said FAD is the oxidized form. That's true. FAD is also one of our common coenzymes. FAD is reduced to FADH₂.

Alright. So we're going to say that FAD is reduced. It's going to be reduced. And if you're going to be reduced, what does that mean? That means that you are the oxidizing agent.

Remember, the agent is the opposite. So this statement is true. Let's look at the other ones. FADH represents an oxidized form of the coenzyme and acts as a reducing agent. FADH₂ is not the oxidized form.

Well, first of all, it's not FADH, it's FADH₂. FADH₂ represents the reduced form. So this is wrong for a few reasons. Reduction of FAD occurs at the adenine portion of the molecule. No.

It happens at the flavin portion of the molecule, so this is wrong. So, out of all our options, the answer at the end is b.

Now, here we're going to say that coenzyme A is a coenzyme of synthase and it has a high energy thiol bond, so SH bond. It carries an Acetyl group to the Krebs Cycle for energy production by oxidation. If we take a look here, this whole structure represents Coenzyme A. Coenzyme A is made up of 3 portions. We have our ADP portion right here, which is Adenosine Diphosphate.

Then we have here Pantothenic acid. Pantothenic acid, another common name for it is vitamin B5. So that would be this portion right here. And then finally, we have our Aminoethane Thiol portion, which is this nitrogen portion with these 2 CH₂s and then the SH at the end. Again, it's the SH group that has a high energy bond.

Then hydrogen can be removed from this structure. So, just remember, Coenzyme A is just yet another simple type of coenzyme that exists.

Now here, which of the following statements correctly describes Coenzyme A? Here we have to select all that apply. Firstly, when an Acetyl group is released from Acetyl S CoA, it produces here just our CoA with our thiol group. But we're removing this Acetyl group here and we replace it with a hydrogen. This is true.

Vitamin B is present in the active site of our coenzyme A. No, that's not the active site. It's the Aminoethanethiol portion, the portion that has the SH group that has the high energy bond. The primary role of CoA is to oxidize fatty acids.

No, that's not its primary role. Its primary role is to carry an Acetyl group to the Krebs Cycle for it to become oxidized and generate energy. Coenzyme A is composed of Pantothenic acid, which is vitamin B5, Aminoethanol, and ADP. Yes.

These are the three major components of our coenzyme A. So here, the only two answers that are true are options a and d.