BioC 3021 Notes - Lipid Metabolism PDF

Summary

This document is a set of lecture notes covering lipid metabolism. It includes various slides on topics such as the overview of catabolism, lipid metabolism summary, lipid digestion, and more. The notes are written in a clear and concise way.

Full Transcript

BioC 3021 Notes Robert Roon

Lecture 18: Lipid Metabolism

Slide 1. Overview of Catabolism.
We are now going to consider the left wing of the catabolism
diagram. (I always like to start on the left rather than the right for
reasons I will not expound upon here.) We are going to look at
lipid catabolism, starting with triacylglycerols. The
triacylglycerols provide another source of energy for living cells.
Quantitatively, triacylglycerols constitute the most important
energy store in humans. Remember that carbohydrates stored as
glycogen constitutes less than one day’s supply of energy. In
contrast, the fats stored as triacylglycerols contain on an average
enough energy to fuel basal metabolism in humans for one or two
months.

Slide 2. Lipid Metabolism Summary
The general pattern of lipid metabolism is summarized on this slide.
When energy is needed, lipid catabolism occurs. The
triacylglycerols from the diet or from lipid stores can be broken
down by lipases to fatty acids and glycerol. The fatty acid
components of triacylglycerols are converted to acetylCoA by the
b-oxidation pathway. The acetylCoA can enter the TCA cycle or
can serve as a starting material for a number of biosynthetic
pathways. The glycerol component is integrated into glycolysis or
gluconeogenesis by a short series of reactions that feed into these
pathways.

On the anabolism side, lipid biosynthesis occurs when there is
excess energy. The fatty acids can be synthesized from acetylCoA,
and glycerol can be produced from glycolysis intermediates. The
two components can be combined in ATP-dependent reactions to
form triacylglycerols.

Slide 3. Lipid Digestion in the Lumen of the Intestine.
Most dietary lipids are ingested as triacylglycerol compounds. The

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dietary lipids are emulsified in the intestine by bile acids secreted
from the gall bladder. Pancreatic lipases hydrolyze the
triacylglycerols into free fatty acids and 2-monoglycerides in the
lumen of the intestine.

Slide 4. The Digestion and Absorption of Triacylglycerols.
This diagram shows the pathway of dietary triacylglycerol
digestion from the lumen of the intestine to the lymph system.

-The triacylglycerols are hydrolyzed into free fatty acids and 2-
monoglycerides in the lumen of the intestine.
-The 2-monoglycerides and fatty acids are transported into the
enterocytes, where they are reassembled into triacylglycerols and
packaged into large chylomicron complexes.
-The chylomicrons are exported from the cell and transported in
the lymph system to adipocyte cells.
-The adipocytes store the lipid as triacylglycerols until there is a
need for energy.

Slide 5. Photomicrograph of an Adipocyte Cell.
A photomicrograph of an adipocyte cell reveals that the lipids are
stored in large vacuoles, which take up the majority of cell volume.
The vacuoles are so large that they sometimes displace the nucleus
to the periphery of the cell.

Slide 6. Scanning Electron Micrograph of an Adipocyte Cell.
Another look at an adipocyte using a scanning electron microscope
reveals the same spherical shape with a bulging nucleus on one
side of the cell.

Slide 7. Lipid Mobilization in Adipose Tissue.
In adipose tissue, the hydrolysis of stored triacylglycerol molecules
is initiated by hormones such as adrenaline, glucagon, and ACTH.
The triacylglycerol lipase is activated by an enzymatic cascade that
is triggered by a hormone binding to the appropriate receptor.

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After cleavage of the first fatty acid by the triacylglycerol lipase,
the second and third fatty acids are also removed from the diacyl-
and monoacylglycerol molecules. If this reaction takes place in
adipose tissue, the fatty acids are released into the blood and are
carried to other tissues in a complex that includes the blood protein
albumin. Some of the glycerol is also released into the blood and
can feed into glycolysis or gluconeogenesis in other tissues.

Slide 8. Glycerol Is Converted to Glycolysis or
Gluconeogenesis Intermediates.
The glycerol that is released from adipose tissue is taken up in
other tissues, where it is integrated into glycolysis or
gluconeogenesis by a two step pathway. First, an ATP-dependent
kinase reaction yields glycerol 3-phosphate. Then, the glycerol 3-
phosphate is oxidized to dihydroxyacetone phosphate by an NAD+
dependent dehydrogenase.

Slide 9. Acyl vs Acetyl Group
This is a good time to distinguish between two terms that are used
to designate functional groups that are derived from carboxylic
acids. The term acetyl specifically refers to a two carbon group
with carbonyl and methyl function. Acetyl groups can be viewed
as derivatives of acetic acid. The term acyl is more broadly
defined and encompasses a range of homologous carboxylic acid
derivatives. This includes the acetyl group plus other carboxylic
acid derivatives that have one or many methylene groups.

Slide 10. Fatty Acid Activation.
Fatty acids are carried in the blood from adipose tissues in
association with serum albumin protein. The fatty acids are taken
into the cytosol of target cells, where they are activated by being
converted to acylCoA derivatives. The conversion of a fatty acid
into an acylCoA intermediate is a thermodynamically unfavorable
process, because the acylCoA is a thioester derivative. Thioesters
have a very high energy of hydrolysis, which means it takes a lot

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of energy to make them starting with a carboxylic acid.

To make the acylCoA derivative, the fatty acid is first activated
using ATP. The intermediates in the process are inorganic
pyrophosphate and a fatty acyl adenylate. (The pyrophosphate is
cleaved to two inorganic phosphates with the release of energy, a
pattern that we have previously noted, which contributes to the
overall thermodynamic favorability of the reaction.) The acyl
adenylate intermediate is a mixed acid anhydride with a high
energy of hydrolysis. When it is swapped for CoA in the next step,
the reaction is thermodynamically neutral. The formation of the
acyl adenylate intermediate thus provides a way of using ATP to
facilitate the synthesis of a high energy CoA product from a free
fatty acid and CoA.

Slide 11. Fatty Acyl Transport from Cytosol to Mitochondria.
Fatty acylCoA derivatives are synthesized in the cytosol of the cell,
but the oxidation of such derivatives takes place in the matrix of
the mitochondria. An elaborate little dance must take place to get
the fatty acylCoA into the mitochondrial matrix. In the cytosol,
the activated CoA derivative is first transferred to carnitine, a polar
carrier molecule. The fatty acyl carnitine derivative is then
transported through the mitochondrial inner membrane into the
matrix. In the matrix, the fatty acyl group is transferred from
carnitine back to CoA.

Slide 12. Fatty Acyl Transfer from CoA to Carnitine.
The transfer of a fatty acyl group from fatty acylCoA to carnitine
occurs in the cytosol and is catalyzed by an acyl transferase
enzyme. The reaction is energetically neutral, and thus is
reversible. The fatty acyl group is transferred from the thiol group
of CoA to a hydroxyl group (noted in red) on carnitine.

Slide 13. Carnitine Cycle.
The overall carnitine cycle is outlined on this slide. The activated

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CoA derivative is first transferred to carnitine. The fatty acyl
carnitine derivative is then transported through the mitochondrial
membrane into the matrix. In the matrix, the fatty acyl group is
transferred from carnitine back to CoA. Then the carnitine is
transported back into the cytosol. The transporter that
accomplishes this exchange process is an integral membrane
protein. It is an antiporter that exchanges an acyl carnitine for a
free carnitine—the acyl carnitine comes into the matrix, and the
free carnitine goes back out into the cytosol on the same transport
protein.

Slide 14. The β-Oxidation Cycle.
One whole cycle of β-oxidation is illustrated on this slide. The
process begins with a fatty acylCoA derivative with n carbon
atoms, and it ends with a fatty acyl derivative with n minus two
carbon atoms. The two missing carbon atoms are released as
acetylCoA. These oxidation cycles are repeated—each cycle
shortening the fatty acylCoA by two carbons and releasing an
acetylCoA. In the final cycle, a four carbon acylCoA
(butyrylCoA) is converted to two molecules of acetylCoA.

The β-oxidation process starts with an oxidation-reduction reaction.
In the reaction, catalyzed by an acylCoA dehydrogenase, a
saturated acylCoA is converted to an unsaturated product. The
new double bond, which is in the trans configuration, is introduced
between the α and β carbons (coded in red). The cofactor in the
reaction is FAD, which is reduced to FADH2.

The second reaction involves the addition of water to the double
bond, forming a hydroxyl group on the β carbon. The reaction is
catalyzed by enol-CoA hydratase. Note that the carbon carrying
the hydroxyl group is now a new chiral center in the L-form.

In the third step, the hydroxyl group is oxidized to a ketone

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coupled to the reduction of NAD+ to NADH. The enzyme that
catalyzes the reaction is L-3-hydroxyacyl CoA dehydrogenase.

The final step in the cycle is catalyzed by β-ketothiolase. In this
reaction, a CoA molecule (coded in green) attacks the β carbon of
the fatty acylCoA. The fatty acylCoA loses two carbons that are
released as acetylCoA. The thiolytic cleavage is facilitated by the
presence of the carbonyl group on the β carbon of the acylCoA.
That β carbon becomes the site of attachment of the incoming CoA
molecule to the shortened fatty acylCoA.

The major fate of the acetylCoA from β -oxidation is entry into the
TCA cycle. Because the acetylCoA is produced in the matrix of
the mitochondria and is used by the TCA cycle in the same place,
that process is facilitated.

Slide 15. Compare β-Oxidation and TCA cycle.
Here is another example of the potential of “learning by analogy”.
The β-oxidation pathway and the TCA cycle both use common
reactions that occur in the same sequence. That sequence is:

-AcylCoA dehydrogenase for β-oxidation vs. succinate
dehydrogenase for the TCA cycle. Both reactions use FAD as a
cofactor and convert a single bond into a double bond.
-EnolCoA hydratase vs. fumarase. Both reactions add water to a
double bond to produce a hydroxyl group.
-3-L-hydroxy-acylCoA dehydrogenase vs. L-malate
dehydrogenase. Both reactions use NAD+ to convert a hydroxyl
group to a ketone.

The point is, that nature has given students of biochemistry a gift
here. You do not have to learn two completely different pathways.
If you memorized the TCA cycle, then learning β-oxidation should
be “duck soup”, because it is essentially the same pathway with

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slightly different surrounding structures.

Slide 16. ATP Yield from Fatty Acid Oxidation.
The oxidation of fatty acids is a catabolic process that has the goal
of producing energy. So the question arises, “How much ATP can
you get from the oxidation of a fatty acid?” And as luck would
have it, we are here to answer our own question.

We can divide the answer into two parts.

-One cycle of β-oxidation yields 4 ATP’s--1.5 ATP’s for the
FADH2 and 2.5 ATP’s for the NADH.

In a round of β-oxidation, there is one acetylCoA produced. The
acetylCoA enters the TCA cycle and yields 10 ATP’s--7.5 ATP’s
from the 3 NADH’s, 1.5 ATP’s from the FADH2, and one ATP
equivalent from GTP.

Slide 17. Total ATP Produced from Stearate.
Let’s look at the complete oxidation of a fatty acid to carbon
dioxide. We arbitrarily pick stearic acid (18 carbons, no double
bonds) as the starting material.

-It costs 2 ATP equivalents to activate stearic acid to the acylCoA
derivative. (Remember that in that reaction, ATP is converted to
AMP and inorganic pyrophosphate. That is the energy equivalent
of 2 ATP’s going to ADP and Pi.) Those two ATP equivalents
constitute the only energy expended in the process.
-There are 8 rounds of β-oxidation, with each round producing 4
ATP’s, so this phase yields a total of 32 ATP’s. (You might be
tempted to think that there are 9 rounds of β-oxidation from a C-18
fatty acid, but remember that the eighth round, starting with a four
carbon acylCoA, produces two acetylCoA’s.)

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-There are 9 acetylCoA’s fed into the TCA cycle, and each one
produces 10 ATP’s for a total of 90 ATP’s.

Minus 2, plus 32, plus 90 gives you a net yield of 120 ATP’s.
WOW!

Slide 18. Caloric Content of Carbohydrate vs. Fat.
Now you will probably be asking another question (And if you
don’t, we will again ask it for you.). That is, how do carbohydrates
and fats compare as sources of energy? The answer is that fats are
more energy rich than carbohydrates. When we calculate the
moles of ATP produced per gram, it turns out that glucose
produces 0.17 mol/g, and stearate produces 0.42 mol/g. That
converts to 4 kcal/g for glucose and 9 kcal/g for stearate. In
general, on a per gram basis, fats produce more than twice the
energy as carbohydrates. This reflects the fact that fats are more
highly reduced than carbohydrates, and a more reduced compound
typically yields more energy in biological oxidation reactions.

Slide 19. Enoyl-CoA Isomerase.
Up until now, we have only considered the β-oxidation of
saturated fatty acids. There are some minor complications in the
oxidation of unsaturated fatty acids. We will use the oxidation of
oleic acid (an 18-carbon fatty acid with one cis double bond) as an
example. This fatty acid has its double bond between carbons 9
and 10. The first three rounds of β-oxidation proceed normally,
because all the bonds are saturated. However, on round four, cis-
Δ3-enoyl-CoA is the substrate. The problem with cis- Δ3-enoyl-
CoA is that its cis- Δ3 double bond should be trans- Δ2 in order for
oxidation to continue. The enzyme enoyl-CoA isomerase makes
that conversion, and from there on β-oxidation can proceed
normally.

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Because the oleate was already unsaturated, there will be one less
FADH2 produced than for the equivalent saturated fatty acid. The
consequence is that the unsaturated compound will yield 1.5 less
ATP’s than its saturated analog.

Slide 20. Isomerization of a Cis-Δ 4 Double Bond.
Another complication arises in the oxidation of linoleic acid, a C-
18 fatty acid that has two double bonds. The first double bond
occurs between carbons 9 and 10 and is treated to the same
isomerization sequence as shown on the previous slide. At the
second double bond, a cis- Δ4-enoyl-CoA is the substrate. The
conversion of the cis- Δ4 into the trans- Δ2 bond takes three
reactions. Two reactions convert the cis- Δ4 double bond to a trans-
Δ3. Then an enol-CoA isomerase converts the trans- Δ3 double
bond to a trans- Δ2. And with that, we will leave fatty acid
oxidation.

Slide 21. Structure of Propionyl CoA.
Most fatty acids contain an even number of carbon atoms, and
produce the two carbon compound acetyl CoA as the only
oxidation product. However, there are a significant number of
fatty acids that contain an odd number of carbons. During the β-
oxidation process, these odd-chain fatty acids produce acetyl CoA
until the last cycle. In the last cycle, the products are one molecule
of acetyl CoA and one molecule of the three carbon compound
propionyl CoA. There is a special metabolic pathway for the
breakdown of propionyl CoA.

Slide 22. Propionyl CoA (C3) is Converted to Succinyl CoA
(C4).
The propionyl CoA is integrated into mainstream metabolism by
conversion to an intermediate of the TCA cycle, succinyl CoA.
This process requires three metabolic steps.

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-In the first step, propionyl CoA is carboxylated by a biotin-
dependent enzyme to yield D-methylmalonyl CoA.
-The second reaction converts the carboxylated product from D- to
L-methylmalonyl CoA.
-In the third reaction, a vitamin B12 dependent enzyme catalyzes
the isomerization of L-methylmalonyl CoA to succinyl CoA.

Slide 23. The Structure of Coenzyme B12.
This figure shows the structure of coenzyme B12. The cofactor
has a polyporphyrin ring system similar to that of the hemes, but
the central metal ion in B12 is cobalt. Vitamin B12 dependent
enzymes generally catalyze very exotic isomerization reactions, in
which carbon atoms are moved from one place to another.

Slide 24. Ketone Body Formation.
Ketone bodies are produced when there is a need for energy in
various tissues, or when the rate of the TCA cycle is inadequate to
utilize all of the acetylCoA produced by fatty acid oxidation.

Slide 25. Production of Ketone Bodies from Acetyl CoA.
Under most conditions, acetyl CoA is produced from glycolysis
and fatty acid oxidation at a rate that can be accommodated by the
TCA cycle. Under these circumstances, most of the acetyl CoA is
converted to carbon dioxide.

The acetyl CoA is diverted from the TCA cycle to the formation of
ketone bodies (short chain fatty acids) as a normal part of
metabolism, when there is a specific need for extra energy in
various tissues, such as heart muscle. The production of ketone
bodies also occurs when the rate of the TCA cycle is inadequate to
utilize all of the acetylCoA produced by fatty acid oxidation. Such
conditions include starvation, uncontrolled diabetes, or as a result
of some low carbohydrate diets in which fatty acids are released
very rapidly.

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Slide 26. Conversion of Acetyl CoA to Ketone Bodies.
There are three products of acetyl CoA metabolism that are
collectively referred to as ketone bodies. These metabolites are
acetoacetate, β-hydroxybutyrate, and acetone.

Slide 27. Ketone Body Synthesis Steps 1 and 2.
In the first two steps of ketone body synthesis, two units of acetyl
CoA react to form acetoacetylCoA, and a third acetyl CoA unit
reacts to produce HMG-CoA. These are also the first two steps in
cholesterol biosynthesis.

Slide 28. Ketone Body Synthesis Steps 3 and 4.
In the third step of ketone body synthesis, an acetyl CoA unit is
then removed from HMG-CoA, releasing acetoacetate. The
acetoacetate is converted enzymatically into β-hydroxybutyrate,
and is decarboxylated nonenzymatically to give acetone.

Slide 29. Overview of Catabolism.
As we start our study of the synthesis of fatty acids, we take one
last look at this chart of catabolism. We use this figure to remind
you that every pathway has to release energy, or it would not
proceed in the forward direction. We have just looked at β-
oxidation of fatty acids, and we know that the catabolic pathway
that converts fatty acids to acetylCoA releases energy. Now, some
of the energy in fatty acids gets trapped as FADH2 and NADH, and
those reduced nucleotides eventually yield ATP. However, in
addition to forming reduced nucleotides, some energy is released
as heat. That is the consequence of the pathway being
thermodynamically favorable (having a negative DG).

OK! So, if the β-oxidation pathway is thermodynamically
favorable (as it has to be), and the pathway for fatty acid
biosynthesis is also thermodynamically favorable (as it also has to

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be), and the two pathways connect the same two compounds...
THEN the two pathways have to have some differences. That is,
there must be some way to introduce extra energy into the
biosynthetic pathway so that it is energy releasing, which it would
not be if it were the exact reversal of the β-oxidation pathway.
Keep this in mind as we look at the biosynthesis of fatty acids.

Slide 30. Comparison of Fatty Acid Biosynthesis vs. β-
Oxidation.
This table shows a number of differences between fatty acid
biosynthesis and β-oxidation. Three of these differences
contribute to the favorable thermodynamics of both pathways. The
differences that change the energetics are:

- Fatty acid synthesis involves a biotin dependent carboxylation
reaction, but β-oxidation does not.
- A malonic acid derivative is a participant in fatty acid
biosynthesis, but not in β-oxidation.
- All of the oxidation-reduction reactions in fatty acid biosynthesis
use NADH, but one of the oxidation-reduction steps in β-oxidation
uses FAD+.

In addition to the energy related differences, there are other
contrasts between the two systems.

- As the name implies, β-oxidation involves oxidation, while fatty
acid synthesis involves reduction.
- The acyl carrier for β-oxidation is CoA, but for fatty acid
synthesis, it is an acyl carrier protein (ACP).
- The hydroxyl intermediates in the two processes have a different
chirality.

Slide 31. The β-Oxidation Cycle.

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Take another look at the β-oxidation cycle. If we were to run the β-
oxidation cycle backwards, there would be a sequence in which:

-AcetylCoA condenses with an acylCoA to form a β-ketone.
-The β-ketone is reduced to a hydroxyl group by a dehydrogenase.
-The hydroxyl group is dehydrated to form a double bond by a
(de)hydratase.
-The double bond is reduced to a single bond by a dehydrogenase.

That is essentially the sequence that we will now see in fatty acid
biosynthesis.

Slide 32. Fatty Acid Biosynthesis.
The sequence of reactions for the β-oxidation cycle running
backwards is the same as the sequence for fatty acid biosynthesis
running in the forward direction. In the biosynthesis process:

-MalonylACP (the replacement for acetylCoA) condenses with an
acylACP derivative to form a β-ketone.
-The β-ketone is reduced to a hydroxyl group by a reductase.
-The hydroxyl group is dehydrated to form a double bond by a
dehydratase.
-The double bond is reduced to a single bond by a reductase.

Slide 33. Comparison of CoA and Acyl Carrier Protein.
On this slide, we compare the structure of CoA with the acyl
carrier protein. The interesting thing is, that the working ends of
both molecules, near the thiol groups, are identical. At the
opposite end away from the thiol group, CoA has an ADP residue,
whereas the acyl carrier protein has a small protein (molecular
weight about 10,000 daltons.) The attachment to the protein
portion of ACP is through a serine hydroxyl group.

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Slide 34. AcetylCoA Carboxylase.
In the first step of fatty acid biosynthesis, acetylCoA is
carboxylated to form malonylCoA. The reaction is catalyzed by
acetylCoA carboxylase. The acetylCoA carboxylase enzyme
contains a covalently bound coenzyme, biotin, which serves as a
carrier of an activated bicarbonate molecule. The reaction takes
place in two stages. In the first stage, bicarbonate becomes
covalently attached to the coenzyme to form a carboxybiotin
intermediate. The attachment of bicarbonate to the biotin
coenzyme is coupled to the cleavage of ATP to ADP and Pi. In the
second stage of the reaction, the activated carboxyl group is
transferred from biotin to acetylCoA to form malonylCoA.

The formation of malonylCoA contributes toward making fatty
acid biosynthesis an energy releasing process. The carboxyl group
that is added to acetylCoA to form malonylCoA will be released
during a subsequent step in the biosynthetic pathway. That
decarboxylation is an energy releasing reaction, and it will help
make the overall pathway thermodynamically favorable.

Slide 35. Conversion of CoA Derivatives to ACP Derivatives.
The second step of fatty acid biosynthesis actually consists of two
parallel reactions. In one of these reactions, an acetyl group is
transferred from acetylCoA to an acyl carrier protein by an acetyl
transacylase enzyme. In the other reaction, a malonyl group is
transferred from malonylCoA to an acyl carrier protein by a
malonyl transacylase enzyme. The products of these reactions,
acetylACP and malonylACP, will react with each other in the next
step.

Slide 36. Fatty Acid Synthesis.
The complete cycle of fatty acid biosynthesis is outlined on this
slide. There are four steps in this biosynthetic cycle, and as we saw
before, these steps mimic the reversal of the β-oxidation cycle.

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In the first reaction, catalyzed by a condensing enzyme,
malonylACP reacts with acetylACP to give a four carbon β-
ketoacylACP product. There are a lot of things happening in this
seemingly simple reaction. First, a two carbon compound and a
three carbon compound are condensing with each other to form a
four carbon compound. Wait! Two and three equal five, not four.
What happened to the fifth carbon atom? It turns out that, in the
process of forming the condensation product, a carbon dioxide was
released from the malonylACP. That not only accounts for the
fifth carbon, but also explains where some of the energy comes
from to make this reaction proceed toward product. The release of
carbon dioxide is usually thermodynamically favorable, and this
reaction is no exception to that rule. So, carbon dioxide release
helps to drive this reaction toward completion. That explains why
the acetylCoA was carboxylated to malonylCoA in the first
place—not to add an extra carbon to the pathway, but to provide
some additional energy, giving the overall pathway a negative DG.

There is one additional feature of the first reaction that contributes
to its favorable thermodynamics. In the process of forming the
four carbon product, an ACP molecule is released. That ACP was
attached to the acetyl group by a thioester bond, which has a high
energy of hydrolysis. When the thioester bond is broken, energy is
released as heat. Thus, that bond cleavage contributes towards the
negative ΔG of the overall reaction.

In the second reaction, the β-ketone group is reduced to an alcohol
with NADPH serving as the reductant. That reaction is catalyzed
by β-ketoacyl-ACP reductase. The use of NADPH in this reaction
is typical of what occurs in anabolic oxidation-reduction reactions.
Remember that NADH is generally used to generate ATP, and
NADPH is used as a reductant in biosynthetic reactions. The
hydroxyl group that is produced in this reaction is in the D-
configuration. In β-oxidation cycle, the equivalent hydroxyl

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intermediate was of the L-configuration.

The third step involves a dehydration reaction. The elements of
water are removed, creating a trans carbon-carbon double bond.
The enzyme catalyzing this reaction is 3-hydroxyacyl-ACP
dehydratase.

In the final step of the cycle, enoyl-ACP reductase uses NADPH to
reduce the double bond to a single bond. The product is a four
carbon butyryl-ACP. That four carbon acyl-ACP can go on to
condense with a malonylACP to initiate a second round of
biosynthesis—the product of which would be a six carbon acyl-
ACP. Each succeeding round of biosynthesis elongates the acyl-
ACP by two carbon atoms. Because fatty acid biosynthesis occurs
two carbons at a time, most naturally occurring fatty acids have an
even number of carbon atoms.

Slide 37. The Glyoxylate Cycle
For the most part, we are focusing on mammalian biochemistry in
this course, but we will now consider a process that does not take
place in mammals. It is called the glyoxylate cycle. The
glyoxylate cycle is an anabolic metabolic pathway occurring in
plants, and several microorganisms, such as E. coli and yeast.
This cycle enables organisms to use acetylCoA for the net
synthesis of carbohydrates. It is absent in animals including
humans. Its absence explains why humans can synthesize glucose
from pyruvate and TCA cycle intermediates, but not from
acetylCoA.

Slide 38. Glyoxylate Cycle Reactions with Complete TCA
Cycle Intermediates.
The glyoxylate cycle makes use of many of the reactions of the
TCA cycle, but it adds two new reactions. Those two additional
reactions are shown here in the middle of the complete TCA cycle.

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Slide 39. Glyoxylate Cycle Reactions.
On this slide, we have removed the TCA cycle reactions that are
not involved in the glyoxylate cycle. The first reaction that is
unique to the glyoxylate cycle is catalyzed by isocitrate lyase.
That reaction cleaves isocitrate into glyoxylate and succinate. The
second unique reaction is catalyzed by malate synthase. In that
reaction, glyoxylate condenses with acetylCoA to produce malate.
When we combine these two reactions with other reactions of the
TCA cycle, we get two four carbon products—succinate and
malate—and both of these products can go on in the TCA cycle to
produce any of the other four, or five, or six carbon intermediates.

The genius of the glyoxylate pathway is that it provides a
mechanism by which two-carbon acetylCoA units can produce
four-carbon products. The glyoxylate cycle facilitates the net
fixation of two-carbon reactants into four-carbon products—
something that cannot be accomplished by the TCA cycle acting
alone. Furthermore, one of the TCA cycle intermediates,
oxaloacetate, can be used to produce phosphoenolpyruvate, and
phosphoenolpyruvate can yield glucose via gluconeogenesis. The
bottom line is, that bacteria can make glucose from acetylCoA.

Mammals do not have the enzymes of the glyoxylate cycle.
Without the two glyoxylate cycle enzymes, the TCA cycle absorbs
the two carbons of acetylCoA and releases them both as carbon
dioxide—there is no net fixation of the two carbons of acetate into
four carbon products. That means there is something that can be
achieved by a lowly bacterium, but not by a mighty mammal. We
and all other mammals are unable to carry out the net synthesis of
TCA cycle intermediates from acetylCoA. Furthermore, and of
extreme importance, is the fact that mammals cannot accomplish
the net synthesis of glucose from acetylCoA. In fact, any
compound that yields acetate or acetylCoA as its only product
cannot be used as a net source of glucose. That can cause
problems during fasting or starvation, because the major energy

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storage compounds in mammals are triacylglycerols. Critical
levels of glucose must be maintained during starvation, but the
fatty acids released from triacylglycerols cannot contribute to
glucose synthesis. They can only produce acetylCoA.

Slide 40 Cholesterol Biosynthesis
We now turn to a consideration of cholesterol, which is the good
guy/bad guy of lipids. Cholesterol has many necessary functions,
including serving as an essential membrane component and as a
precursor of steroid hormones and bile acids. On the other hand,
cholesterol esters that accumulate in the arteries of old guys like
me are the villains that cause atherosclerosis, leading to heart
attacks and strokes.

Slide 41. Origin of the Carbon Atoms of Cholesterol.
The diagram shows that all of the carbons of cholesterol are
derived from acetylCoA—the red carbons from the carboxyl group,
and the black carbons from the methyl group. Cholesterol has
three six-membered rings and one five-membered ring, none of
which are aromatic.

Slide 42. Summary of Cholesterol Biosynthesis.
This diagram breaks the pathway of cholesterol biosynthesis into
four arbitrary stages. Although it is not shown here, each of those
stages involves multiple steps catalyzed by many different
enzymes. The first stage begins with the two carbon compound,
acetylCoA, and ends with a six carbon intermediate, mevalonate.
The second stage begins with mevalonate and ends with a five
carbon activated isoprene analog, isopentenyl-pyrophosphate.
Next, in stage three, six isopentenyl-pyrophosphate units are
polymerized to give a 30-carbon intermediate, squalene. And
finally in stage four, squalene is converted to cholesterol by a
series of rearrangements and ring closure reactions.

Slide 43. Pathway from AcetylCoA to Mevalonate.

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BioC 3021 Notes Robert Roon

We mentioned before that acetylCoA occurs at a branch point in
metabolism. In this case, it serves as the precursor of cholesterol.
In the first reaction, two molecules of acetylCoA condense to form
acetoacetylCoA. The acetoacetylCoA can then react with a third
molecule of acetylCoA to give 3-hydroxy-3-methylglutaryl-CoA.
The thioester carbonyl group of 3-hydroxy-3-methylglutaryl-CoA
is then reduced to an alcohol yielding mevalonate. Notice that it
takes two molecules of NADPH to convert the thioester (which is
the equivalent of a carboxyl group) to an alcohol. That is a four
electron reduction, hence the need for two molecules of NADPH.
In the process, a CoA molecule is released. The driving force for
this series of reactions is the release of two CoA units and the
conversion of two NADPH molecules to NADP+.

Slide 44. Conversion of Mevalonate to Geranyl Pyrophosphate.
In the next series of reactions, the mevalonate is first converted to
a pyrophosphate derivative. That takes two ATP’s going to ADP.
The next reaction involves an ATP dependent dehydration and
decarboxylation. Wow! All that stuff happening in one reaction—
I am not going to burden you with the mechanism, primarily
because I don’t know how it works—else I would happily burden
you, and it would have very little effect on my conscience. The
end result is a nice little five-carbon compound isopentenyl
pyrophosphate, which has a carbon-carbon double bond at one end.
Next, there is an isomerization of that new double bond. At that
point, two five-carbon dimethylallyl pyrophosphate molecules
condense to form a ten-carbon product, geranyl pyrophosphate,
with the release of an inorganic pyrophosphate. This series of
reactions is energized by the cleavage of three molecules of ATP, a
decarboxylation reaction, and the release of a pyrophosphate. I am
sure that the pyrophosphate is promptly cleaved to two inorganic
phosphates to give the pathway a further boost.

Slide 45. Formation of Farnesyl Pyrophosphate.
In the next reaction, a ten carbon geranyl pyrophosphate condenses

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BioC 3021 Notes Robert Roon

with a five-carbon isopentenyl pyrophosphate to give a fifteen-
carbon farnesyl pyrophosphate. An inorganic pyrophosphate
molecule is released in the process, and its cleavage would again
promote the forward reaction.

Slide 46. Conversion of Farnesyl Pyrophosphate to Cholesterol.
This slide summarizes the rest of the pathway, and thank goodness,
most of the action takes place off the slide. I am really sick of this
pathway by this point. In essence, two fifteen-carbon farnesyl
pyrophosphate molecules condense to give a thirty-carbon product,
squalene. Then there are a series of reactions that bond various
carbon atoms together to form three fused six-membered rings and
a fused five membered ring. Somewhere along the line, three
carbons are lost as carbon dioxide, a double bond is introduced into
one of the six-membered rings, and one of the rings is
hydroxylated. We are left with the final 27 carbons of
cholesterol—three fused six membered rings, one fused five
membered ring, and an eight-carbon hydrocarbon side chain. This
final phase of the pathway is energized by NADPH oxidation,
pyrophosphate release, and some other stuff which will remain
anonymous.

Slide 47. Steroid Hormones Derived from Cholesterol.
Here, we see some of the good guy features of cholesterol. It is a
necessary precursor of steroid hormones including progesterone,
testosterone, and estradiol.

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