Lipid Metabolism PDF

Summary

This document provides a detailed overview of lipid metabolism, focusing on different aspects such as fatty acid synthesis, triglyceride metabolism, fatty acid oxidation, regulation, and the metabolism of ketone bodies and cholesterol. The document also discusses the significance of these metabolic processes in various biological contexts.

Full Transcript

MODULE 2
4 BIOCHEMISTRY OF FAT AND NSAIDS
5 LIPID METABOLISM

1
5

LIPID METABOLISM

2
 LIPID METABOLISM
— CONTENTS —

I. OVERVIEW LIPID METABOLISM VI. METABOLISM OF KETONE BODIES
What are ketone bodies?
II. FATTY ACID SYNTHESIS Synthesis of ketone bodies
Synthesis of palmitate Fates of ketone bodies
Regulation of acetyl-CoA carboxylase Pools of HMG-CoA
Energetics of fatty acid synthesis
VII. METABOLISM OF CHOLESTEROL
III. METABOLISM OF TRIGLYCERIDES Synthesis of cholesterol
Synthesis of triacylglycerides Fates of cholesterol
Regulation of triacylglyceride metabolism Regulation of cholesterol biosynthesis
Hormonal regulation
IV. FATTY ACID OXIDATION Ubiquitination and degradation
Transport of fatty acids to mitochondria Transcriptional regulation
Regulation of acyl-CoA synthetase
Energetics of b-oxidation

V. COORDINATED REGULATION OF FATTY ACID
SYNTHESIS AND DEGRADATION
High carbohydrate meal
Fasting

3
 5. LIPID METABOLISM
– LEARNING OBJECTIVES –

Discuss the allosteric and hormonal (insulin and glucagon)

regulation of fatty acid synthesis and degradation

Explain the hormonal (insulin and glucagon) regulation of fatty

acid metabolism under fasting and after a high-carbohydrate diet

Define metabolism of ketone bodies, tissue-specific sources, and

distinguish between ketogenic- and ketolytic tissues

Identify the enzyme in cholesterol metabolism that is a target for

cholesterol-reducing drugs

Outline the different levels of regulation of HMG-CoA reductase

4
 I. THE THREE STAGES OF INTERMEDIATE METABOLISM
PROTEINS CARBOHYDRATES LIPIDS

Glycolysis Gluconeogenesis
Glycogenolysis Glycogenesis
Stage I

amino acids hexoses glycerol
pentoses +
fatty acids

Triglyceride
deamination

synthesis
oxidation glycolysis β-oxidation

s is
n

tihse
tino
Stage II
ANABOLISM
CATABOLISM

0xiadtaio

syens
idth
pyruvate

-oid

acyn
b

ox

ttdy S
b-
Triglycerides
cholesterol

Facai
tty
Cholesterol

Fa
Synthesis
acetyl-CoA
Ketone
Synthesis
Ketone
bodies

TCA
Stage III
respiratory
chain

ATP

NH3 H2O CO2 4
 LIPID METABOLISM
— OVERVIEW —

+ GLYCEROL-P
TRIGLYCERIDES FATTY ACID MITOCHONDRIA
TRIGLYCERIDE SYNTHESIS

FATTY ACID BIOSYNTHESIS

β-OXIDATION
CHOLESTEROL HMG-CoA ACETYL-COA HMG-CoA KETONE BODIES
CHOLESTEROL BIOSYNTHESIS KETOGENESIS

CYTOSOL

6
 II. FATTY ACID SYNTHESIS

+ GLYCEROL-P
TRIGLYCERIDES FATTY ACID MITOCHONDRIA
TRIGLYCERIDE SYNTHESIS

FATTY ACID BIOSYNTHESIS

β-OXIDATION
CHOLESTEROL HMG-CoA ACETYL-COA HMG-CoA KETONE BODIES
CHOLESTEROL BIOSYNTHESIS KETOGENESIS

CYTOSOL

7
 II. SYNTHESIS OF FATTY ACIDS
Synthesis of Palmitate (16:0). The synthesis of fatty acids occurs in cytosol and
requires supply of acetyl-CoA and NADPH (pentose phosphate pathway). The
major pool of acetyl-CoA occurs in mitochondria; transfer of acetyl-CoA to
cytosol occurs via citrate. Once in cytosol, ATP-citrate lyase metabolizes
citrate to acetyl-CoA and oxaloacetate:
citrate + ATP + CoA ® acetyl-CoA + ADP + oxaloacetate
CYTOSOL MITOCHONDRIA

ATP
citrate citrate CoA
ADP + Pi
CoA citrate citrate
lyase synthase oxaloacetate
oxaloacetate

glucose acetyl-CoA acetyl-CoA
pentose
phosphate
pathway fatty
NADPH acid
synthesis

fatty acids
8
 II. SYNTHESIS OF FATTY ACIDS
Synthesis of Palmitate (16:0). The catalytic machinery for fatty acid synthesis: acetyl-
CoA carboxylase and fatty acid synthase. The first step in fatty acid biosynthesis is
catalyzed by acetyl-CoA carboxylase (ACC) and generates malonyl-CoA: this is the
commitment, irreversible step, and control of fatty acid synthesis; the enzyme is
activated by citrate (the donor of acetyl-CoA units) and inhibited by palmitoyl-CoA (the
SH
product). SH |
acetyl-CoA |
Acetyl-CoA provides all the carbons carboxylase ACP
FAS
for fatty acids synthesis by a sequen- megacomplex

ADP
tial addition of acetyl-CoA to the Pi
CO2
carboxyl end of the growing chain. O ATP O
|| ||
This sequence of reactions is catalyz- CH3–C–SCoA –OOC–CH –C–SCoA
2
acetyl-CoA
ed by fatty acid synthase (FAS). carboxylase

citrate acyl-CoA
9
 II. SYNTHESIS OF FATTY ACIDS
Synthesis of Palmitate (16:0). Acetyl-CoA carboxylase (ACC) is also regulated by
hormones: insulin and glucagon. The overall effect of glucagon is inhibition of the
enzyme: glucagon elicits the generation of the second messenger cAMP that activates
PKA, which phosphorylates acetyl-CoA carboxylase. The phosphorylated form of the
enzyme is inactive.
P
acetyl-CoA
carboxylase
(phosphorylated)
(inactive)
activate site glucagon

regulation
regulation

hormonal
hormonal

GLUCAGON PKA phosphatase 1 INSULIN

(non-phosphorylated)
(active)
O acetyl-CoA O
|| carboxylase ||
CH3–C–SCoA –OOC–CH –C–SCoA
2

citrate acyl-CoA
allosteric
regulation
10
 II. SYNTHESIS OF FATTY ACIDS
Synthesis of Palmitate (16:0). The catalytic machinery for fatty acid synthesis: acetyl-
CoA carboxylase and fatty acid synthase. Malonyl-CoA and acetyl-CoA bind to a
component of fatty acid synthase (the acyl carrier protein or ACP): once malonyl-CoA is
formed it condenses with a molecule of acetyl-CoA; both malonyl-CoA and acetyl-CoA
units are bound to an acyl carrier protein (acetyl transferase and malonyl transferase),
which is a component of the multifunctional fatty acid synthase
acetyl acetyl malonyl group
group group C H2—COOH
C H3 C H3 |
| | C =O
C =O C =O |
SH | SH | S
SH | S | S |
| | |

FAS FAS FAS
C H3
| C H2—COOH
C =O HS-CoA |
| C =O HS-CoA
S –CoA |
S–CoA
ADP Pi
acetyl-CoA
carboxylase
CO2 ATP
C H3
|
C =O
|
S –CoA 11
 acetyl malonyl group
group
C H3
|
C H2—COOH
|
C =O
Synthesis of Palmitate (16:0)
C =O |
S
The catalytic machinery for fatty acid synthesis
|
S |
|

FAS

C H3
  The first step is the condensation of an activated acyl group
| condensation
C =O decarboxylation
|
C
CO2 (an acetyl group is the first acyl group) and two carbons
|
C =O
| SH
|
derived from malonyl-CoA, with the elimination of CO2
S
|
from the malonyl group. The net effect is extension of the
FAS
acyl chain by two carbons.
 The product of the first reaction, a keto-acyl derivative, is
NADPH
C H3
| 
H– C –OH reduction

reduced to an alcohol (hydroxy-acyl) by a reductase activity
|
C NADP+
|
C =O
SH
S
|
|
| within fatty acid synthase and from reducing equivalents
FAS from NADPH
C H3
H– C
|   Elimination of H2O from the hydroxyl-acyl intermediate
dehydration
||
C –H
|
C =O
H2O creates a double bond; the reaction is catalyzed by the
SH
S
|
|
|
dehydratase activity of fatty acid synthase.
FAS

 The double bond is reduced by a reductase activity within
C H3
|
CH2
 NADPH

| reduction
C H2
|
C =O NADP+ fatty acid synthase at expense of reducing equivalents from
| SH
S
|
|
NADPH
FAS
12
 II. SYNTHESIS OF FATTY ACIDS
Energetics of fatty acid biosynthesis
The only step in which ATP is consumed in fatty acid biosynthesis is the reaction
catalyzed by acetyl-CoA carboxylase. For example, palmitate has 16 carbons (16:0);
hence, 8 molecules of acetyl-CoA will be required to form the 16-carbon palmitate.
O
||
CH3–C–SCoA 2 NADPH
SH
CO2 + ATP SH |
acetyl-CoA |
carboxylase palmitate
ADP (16:0)
HSCoA + Pi
FAS

O
||
–OOC–CH –C–SCoA
2

2 NADP+
ATP used NADPH used

8 acetyl-CoA + 7 ATP + 14 NADPH → palmitate + 7 ADP + 7 Pi + 14 NADP+ + 8 HsCoA
13
 FATTY ACID SYNTHESIS

+ GLYCEROL-P
TRIGLYCERIDES FATTY ACID
TRIGLYCERIDE SYNTHESIS

FATTY ACID BIOSYNTHESIS
INSULIN

β-OXIDATION
CITRATE
ACYL-COA
ACC
GLUCAGON
FAS

CHOLESTEROL HMG-CoA ACETYL-COA HMG-CoA KETONE BODIES
KETOGENESIS
CHOLESTEROL BIOSYNTHESIS

14
 WHY METABOLISM OF CARBOHYDRATES AND LIPIDS?
SIGNIFICANCE:
STARVE-FEED CYCLE
DIABETES
OBESITY
ATHEROSCLEROSIS
CELL SIGNALING
ALZHEIMER’S DISEASE

[lactate]
insulin [pyruvate]
glucagon

HYPOXIA
b cells a cells

FATTY ACID SYNTHESIS

Pancreas
15
 III. METABOLISM OF TRIACYLGLYCERIDES

+ GLYCEROL-P
TRIGLYCERIDES FATTY ACID
TRIGLYCERIDE SYNTHESIS

FATTY ACID BIOSYNTHESIS
INSULIN

β-OXIDATION
CITRATE
ACYL-COA
ACC
GLUCAGON
FAS

CHOLESTEROL HMG-CoA ACETYL-COA HMG-CoA KETONE BODIES
CHOLESTEROL BIOSYNTHESIS KETOGENESIS

16
 III. METABOLISM OF TRIACYLGLYCERIDES

Synthesis of triacylglycerides

Triacylglycerides are a major form of storage of fatty acids in liver and adipose

tissue, which represent the major pools for long-term energy storage in humans.

Triacylglycerols are synthesized from fatty acyl CoA and glycerol-3P. The latter

originates from glucose metabolism (i.e., the reduction of dihydroxyacetone

phosphate to glycerol-3P).

acyl-CoA synthase
acyl-CoA acyltransferase TRIACYLGLYCEROLS
lipases acyl-CoA
glycerol-P glycerol
synthesis degradation

17
 O fatty acid
||
III. METABOLISM OF TRIACYLGLYCERIDES
R–C–OH glucose
ATP + CoASH
acyl-CoA
synthetase glycolysis
PPi + AMP
originated from Glucose
O CH2OH
|| |
fatty acyl CoA R–C–SCoA HO– C –H glycerol-P
|
CH2–O–Pi
acyltransferase O
||
HSCoA CH2O–C–R
|
HO– C –H
O |
|| C H2–O–Pi
R–C–SCoA
acyltransferase
HSCoA O O
|| ||
O CH2O–C–R O CH2O–C–R
|| | phosphatase || |
R–C–O– C –H R–C–O– C –H
| |
CH2–O–Pi CH2–OH
phosphatidic acid Pi O diacylglycerol
||
R–C–SCoA
acyltransferase
HSCoA
O
||
O CH2O–C–R
|| |
R–C–O– C –H O
| ||
triacylglycerol C H2 –O–C–R
18
 III. METABOLISM OF TRIACYLGLYCERIDES
Regulation of triacylglyceride metabolism. Adipose tissue contains hormone-sensitive

lipase (HSL) that removes fatty acids from triacylglycerols. Fatty acids and glycerol

produced by lipases in adipose tissue are released to circulating blood: fatty acids are

bound to serum albumin and transported to tissues for use. Glycerol returns to the

liver, where is converted into dihydroxyacetone-P and enters the glycolytic pathway.
albumin albumin
fatty acids albumin|
albumin fatty
fatty acids | acids
fatty acids

glycerol
glycerol
adipocytes
Hormone-Sensitive
adipocytes glucose
Lipase
Hormone-Sensitive
glucose
Lipase

19
III. METABOLISM OF TRIACYLGLYCERIDES glucagon
epinephrine
Regulation of triacylglyceride metabolism receptor
Adipose tissue triacylgycerols are mobilized
AC
and transported to energy-requiring tissues. caffeine
ATP theophiline
Glucagon and epinephrine are lipolytic
phospho-
hormones that activate the formation of cAMP AMP
diesterase
cAMP and PKA activation, which phos-
phorylates (activates) the hormone-sensitive insulin
HSL
lipase (HSL), thus facilitating breakdown of
inactive
triacyl-glycerols (TG). PKA phosphatase insulin
Insulin is an antilipolytic hormone that active
insulin
inhibits the hormone-sensitive lipase (upon HSL P

activation of the protein phosphatase 1), thus
TG
reducing the release not only of free fatty
acids but of glycerol as well. fatty acids
glycerol
Adipose tissue is much more sensitive to insulin than are many other tissues, which
points to adipose tissue as a major site of insulin action in vivo.
20
 III. METABOLISM OF TRIACYLGLYCERIDES

GLUCAGON INSULIN

HSL
+ GLYCEROL-P
TRIGLYCERIDES FATTY ACID
TRIGLYCERIDE SYNTHESIS

FATTY ACID BIOSYNTHESIS
INSULIN

β-OXIDATION
CITRATE
ACYL-COA
ACC
GLUCAGON
FAS

CHOLESTEROL HMG-CoA ACETYL-COA HMG-CoA KETONE BODIES
CHOLESTEROL BIOSYNTHESIS KETOGENESIS

21
 WHY METABOLISM OF CARBOHYDRATES AND LIPIDS?
SIGNIFICANCE:
STARVE-FEED CYCLE
DIABETES
OBESITY
ATHEROSCLEROSIS
CELL SIGNALING
ALZHEIMER’S DISEASE

[lactate]
insulin [pyruvate]
glucagon

HYPOXIA REGULATION OF HSL
b cells a cells

Pancreas
22
 IV. FATTY ACID OXIDATION

GLUCAGON INSULIN

HSL
+ GLYCEROL-P
TRIGLYCERIDES FATTY ACID
TRIGLYCERIDE SYNTHESIS

FATTY ACID BIOSYNTHESIS
INSULIN

β-OXIDATION
CITRATE
ACYL-COA
ACC
GLUCAGON
FAS

CHOLESTEROL HMG-CoA ACETYL-COA HMG-CoA KETONE BODIES
CHOLESTEROL BIOSYNTHESIS KETOGENESIS

23
 IV. FATTY ACID OXIDATION
Fatty acids are used for energy production in mitochondria through the

formation of NADH and FADH2 that donate electrons to the respiratory

chain, thus resulting in ATP formation. Brain tissue oxidizes fatty acids to a

minimal degree if at all, whereas cardiac and skeletal muscle depend heavily
on fatty acids as a major energy source. fatty acid
O
Fatty acid oxidation or b-oxidation ||
R–C–OH
requires activation of fatty acids to a fatty ATP + CoASH
acyl-CoA
acyl-CoA. This is the same process as in synthetase
PPi + AMP
the activation of fatty acids for synthesis
malonyl-CoA
of triglycerides by the enzyme acyl-CoA O
||
synthetase, which is inhibited by R–C–SCoA
fatty acyl CoA
malonyl-CoA.
24
IV. FATTY ACID OXIDATION fatty acid malonyl-CoA
acyl-CoA fatty HS-CoA
Transport of fatty acid to mitochondria synthase acyl-CoA
β α
and b-oxidation
(C16) R—CH2—CH2—CH2—C—SCoA
||
CPT I
O
The inner membrane is impermeable to
acyl-CoA
dehydrogenase FAD
FADH acyl-carnitine
CoA; transport of fatty-acyl CoA requires
2 carnitine
H
(C R—CH —C — C —C—SCoA
carnitine palmitoyl
16) transferase-1
2
H || (CPT-I) CPT II
O
on the outer membrane and2 carnitine
enoyl-CoA H O
hydratase
fatty
palmitoyl transferase-2 OH
(CPT-II) on the acyl-CoA HS-CoA
|
(C16) R—CH2—CH—CH2—C—SCoA
matrix side of the inner membrane).|| β-oxidation

O
mitochondrial matrix b-
β-hydroxyacyl-CoA NAD+
Once in thedehydrogenase C14 acetyl-CoA + FADH2 + NADH
NADH C12 acetyl-CoA + FADH2 + NADH
oxidation of fatty acids
O entails several
|| C10 acetyl-CoA + FADH2 + NADH
(C16) R—CH2—C—CH2—C—SCoA
passes with formation of acetyl-CoA, || C8 acetyl-CoA + FADH2 + NADH
O
acyl-CoA
FADH2, and NADH in each pass.
acetyltransferase HSCoA
C6 acetyl-CoA + FADH2 + NADH
(thiolase) C4 acetyl-CoA + FADH2 + NADH
O
||
(C14) R—CH2—C—SCoA + CH3—C—SCoA acetyl-CoA
|| 25
O
 IV. FATTY ACID OXIDATION

GLUCAGON INSULIN

HSL
+ GLYCEROL-P
TRIGLYCERIDES FATTY ACID
TRIGLYCERIDE SYNTHESIS

FATTY ACID BIOSYNTHESIS
INSULIN

β-OXIDATION
CITRATE
ACYL-COA
ACC ACS
GLUCAGON
FAS CPTI MALONYL-COA

CHOLESTEROL HMG-CoA ACETYL-COA HMG-CoA KETONE BODIES
CHOLESTEROL BIOSYNTHESIS KETOGENESIS

26
 V. COORDINATED REGULATION OF FATTY ACID SYNTHESIS AND DEGRADATION
Regulation of fatty acid metabolism in a high carbohydrate meal b-oxidation of fatty acids is
unnecessary and is therefore downregulated. A high-carbohydrate meal:
 raises blood glucose level;  triggers the release of insulin;  insulin-dependent protein
phosphatase 1 activates ACC (acetyl-CoA carboxylase);  ACC catalyzes the formation of
malonyl-CoA;  malonyl-CoA inhibits carnitine acyltransferase I (CPT I), thus preventing
fatty acid entry into the mitochondrial matrix.
dietary ① high blood
carbohydrates glucose

P ② OMM
acetyl-CoA
carboxylase INSULIN
(phosphorylated)
(inactive) ➂
glucose
protein kinase phosphatase 1
glycolysis

(non-phosphorylated)
(active)
acetyl-CoA fatty acyl HSCoA
O O HSCoA carnitine
|| carboxylase ||
CH3–C–SCoA –OOC–CH –C–SCoA
2
➄ CPT I CPT II
PDH acetyl-CoA ➃ malonyl-CoA
fatty carnitine fatty
acyl-CoA acyl-CoA

β-oxidation
fatty acids NADH
CYTOPLASM MITOCHONDRIA acetyl-CoA
27
 V. COORDINATED REGULATION OF FATTY ACID SYNTHESIS AND DEGRADATION
Regulation of fatty acid metabolism during fasting When blood glucose levels drop between
meals:  glucagon is released; cAMP-dependent PKA activation;  PKA phosphorylates
and inactivates ACC;  malonyl-CoA levels fall and the inhibition of fatty acid entry into
mitochondria is relieved. Fatty acids enter the mitochondrial matrix to become the major
fuel. Because glucagon also triggers the mobilization of fatty acids in adipose tissue, a
supply
low bloodof fatty acids begins arriving in the blood.
low blood
glucose
glucose low blood
① glucose P OMM
① acetyl-CoA P OMM
GLUCAGON carboxylase
acetyl-CoA
GLUCAGON carboxylase
(phosphorylated)
② ➃
(inactive)
(phosphorylated)
② ➃
(inactive)

cAMP PKA phosphatase 1
➂
cAMP PKA phosphatase 1
➂
(non-phosphorylated)
(active)
(non-phosphorylated)
acetyl-CoA(active) fatty acyl HSCoA
O O HSCoA
carnitinefatty acyl
|| O carboxylase
acetyl-CoA || O HSCoA HSCoA
➄ carnitine
CH3–C–SCoA|| –OOC–CH –C–SCoA
carboxylase 2 ||
➄ x CPT I CPT II
CH3–C–SCoA
acetyl-CoA
acetyl-CoA
malonyl-CoA
–OOC–CH –C–SCoA
2
malonyl-CoA fatty x CPT I CPT II
fatty
carnitine
acyl-CoA fatty carnitine acyl-CoA fatty
acyl-CoA acyl-CoA
β-oxidation
β-oxidation
fatty acids NADH
fatty acids CYTOPLASM MITOCHONDRIA acetyl-CoA NADH
CYTOPLASM MITOCHONDRIA acetyl-CoA28
 WHY METABOLISM OF CARBOHYDRATES AND LIPIDS?
SIGNIFICANCE:
STARVE-FEED CYCLE
DIABETES
OBESITY
ATHEROSCLEROSIS
CELL SIGNALING
ALZHEIMER’S DISEASE

[lactate]
insulin [pyruvate]
glucagon

HYPOXIA
b cells a cells

Pancreas COORDINATED REGULATION OF FATTY
ACID SYNTHESIS AND DEGRADATION
29
 VI. METABOLISM OF KETONE BODIES

GLUCAGON INSULIN

HSL
+ GLYCEROL-P
TRIGLYCERIDES FATTY ACID
TRIGLYCERIDE SYNTHESIS

FATTY ACID BIOSYNTHESIS
INSULIN

β-OXIDATION
CITRATE
ACYL-COA
ACC ACS
GLUCAGON
FAS CPTI MALONYL-COA

CHOLESTEROL HMG-CoA ACETYL-COA HMG-CoA KETONE BODIES
CHOLESTEROL BIOSYNTHESIS KETOGENESIS
 VI. METABOLISM OF KETONE BODIES
What are ketone bodies? There are three types of ketone bodies: acetone, acetoacetate, and
D-b-hydroxybutyrate, the three of them derived from acetyl-CoA:

H
O | O

||

||
H3C—C—CH3 H3C—C—CH2—C H3C—C—CH2—C
|| || OH | OH

|

|
O O OH
acetone acetoacetate b-hydroxybutyrate

Ketone bodies are not synthesized from the metabolism of fatty acids or as intermediates in
fatty acid metabolism. Ketone bodies are always synthesized from the building unit, acetyl-
CoA.

31
 VI. METABOLISM OF KETONE BODIES O O
CH3—C CH3—C
Formation of ketone bodies (ketogenesis) from acetyl- S-CoA S-CoA

CoA. Healthy, well-nourished individuals produce ketone thiolase
HS-CoA
O
bodies at a low rate. Ketone body synthesis occurs in mito- CH3—C—CH2—C
||
O S-CoA
acetoacetyl-CoA
chondria. When acetyl-CoA accumulates (starvation or
acetyl-CoA
HMG-CoA
synthase
diabetes), thiolase catalyzes the condensation of two HS-CoA

OH
acetyl-CoA molecules to acetoacetyl-CoA. Addition of O
| O
C—CH2—C—CH2—C
HO | S-CoA
another acetyl-CoA to acetoacetyl-CoA –catalyzed by CH3
β-hydroxy-β-methylglutaryl-CoA
(HMG-CoA)
HMG-CoA synthase– yields b-hydroxy-b-methylglutaryl-
HMG-CoA acetyl-CoA
lyase
CoA (HMG-CoA) that is also an intermediate of sterol O
CH3—C—CH2—C
biosynthesis, but the enzyme that forms HMG-CoA ||
O OH
acetoacetate acetoacetate D-β-hydroxybutyrate
decarbosylase dehydrogenase
in that pathway is cytosolic. HMG-CoA lyase is CO2 NADH OH O
NAD+ |
CH3—C—CH3 CH3—C—CH2—C
present only in the mitochondrial matrix. ||
O H
|
OH
acetone D-β-hydroxybutyrate

32
 VI. METABOLISM OF KETONE BODIES
Fates of ketone bodies
Ketone bodies are formed in the mitochondrial matrix in the liver; they diffuse
to blood and are transported to peripheral tissues:

LIVER EXTRAHEPATIC TISSUES

glucose fatty acids glucose fatty acids

lungs
acetyl-CoA (acetone) acetyl-CoA

tricarboxylic ketone ketone ketone tricarboxylic
acid cycle bodies bodies bodies acid cycle

KETOGENESIS KETOLYSIS
urine

33
 VI. METABOLISM OF KETONE BODIES OH O
|
CH3—C—CH2—C
Fates of ketone bodies: b-hydroxybutyrate, synthesiz- |
OH
H
D-β-hydroxybutyrate
ed in liver, is transferred to extrahepatic tissues, where
NAD+
it is first oxidized to acetoacetate by b-hydroxybutyr- β-hydroxybutyrate
dehydrogenase
NADH
ate dehydrogenase; succinyl-CoA transferase (SCOT) O
CH3—C—CH2—C
||
catalyzes the conversion of acetoacetate to aceto- O OH
acetoacetate

acetyl-CoA, which is -cleaved into 2 acetyl-CoA succinyl-CoA
succinyl-CoA
transferase
molecules by the action of thiolase. (SCOT) succinate

O
Liver does not contain the enzymes needed to CH3—C—CH2—C
||
O S-CoA
metabolize ketone bodies (ketolysis). Hence, liver is a acetoacetyl-CoA

source of ketone bodies (ketogenesis), whereas HSCoA
thiolase
extrahepatic tissues (heart, skeletal muscle, brain,
O O
CH3—C CH3—C
kidney cortex) use ketone bodies as an energy source S-CoA S-CoA
acetyl-CoA acetyl-CoA
(ketolysis).
34
 acetyl-CoA
VI. METABOLISM OF KETONE BODIES
There are two pools of HMG-CoA
acetoacetyl-CoA
There are two pools of HMG-CoA:

the mitochondrial pool is used for the synthesis
β-hydroxymethylglutaryl-CoA
of ketone bodies (HMG-CoA)
the cytosolic pool is used for the synthesis of

cholesterol
mitochondria cytosol

ketone bodies cholesterol

35
 VII. METABOLISM OF CHOLESTEROL

GLUCAGON INSULIN

HSL
+ GLYCEROL-P
TRIGLYCERIDES FATTY ACID
TRIGLYCERIDE SYNTHESIS

FATTY ACID BIOSYNTHESIS
INSULIN

β-OXIDATION
CITRATE
ACYL-COA
ACC ACS
GLUCAGON
FAS CPTI MALONYL-COA

CHOLESTEROL HMG-CoA ACETYL-COA HMG-CoA KETONE BODIES
CHOLESTEROL BIOSYNTHESIS KETOGENESIS

36
 2 CH3—C=O
2 CH3—C=O |
VII. METABOLISM OF CHOLESTEROL acetyl-CoA
| SCoA
acetyl-CoA SCoA
Synthesis of cholesterol : regulatory elements in the syn- thiolase HSCoA
thiolase HSCoA
thesis of cholesterol and targets for cholesterol-reducing O
O ||
|| CH3—C—CH2—C=O
drugs. CH3—C—CH2—C=O |
acetoacetyl-CoA
| SCoA
acetoacetyl-CoA SCoA
Thiolase catalyzes the condensation of 2 acetyl-CoA to CH —C=O
CH3—C=O
|
HMG-CoA 3
| SCoA
acetoacetyl-CoA HMG-CoA synthaseSCoA
synthase HSCoA
HSCoA –
HMG-CoA synthase catalyzes the condensation of a COO
COO– |
| CH2
third acetyl-CoA to yield b-hydroxy-b-methylglutaryl- CH2 |
| H3C–C–OH
H3C–C–OH |
CoA (HMG-CoA) Both reactions are reversible and do | CH 2
CH2 |
| C=O
not commit to the synthesis of cholesterol. β-hydroxymethylglutaryl-CoA
C=O |
β-hydroxymethylglutaryl-CoA (HMG-CoA)
| SCoA
(HMG-CoA) SCoA
HMG-CoA reductase, an integral membrane protein of 2 NADPH
2
HMG-CoANADPH
the smooth endoplasmic reticulum, catalyzes the HMG-CoA reductase
reductase 2 NADP
2 NADP+ + HSCo
conversion of HMG-CoA to mevalonate (NADPH + COO
HSCoA–
COO– |
| CH2
donate two reducing equivalents). This is the CH2 |
| H3C–C–OH
H3C–C–OH |
committed step and is the major point of regulation on | CH 2
CH2 |
| CH2OH
the pathway of cholesterol. mevalonate
mevalonate
CH OH
2 37
 3 CH3–COO–
VII. METABOLISM OF CHOLESTEROL acetyl-CoA
1
Synthesis of cholesterol. Cholesterol is synthesized
CH3
|
from acetyl-CoA in four steps: –OOC—CH —C—CH —CH —OH
2 2 2
|
OH mevalonate
1 Three acetate units (2 carbons) condense to
2

generate a six-carbon intermediate (mevalonate) CH3 O O
| || ||
CH2=C—CH2—CH2—O—P—O—P—O–
2 Mevalonate is converted into activated isoprene |
O–
|
O–
3 isoprene
units
3 Polymerization of six 5-carbon isoprene units to
form the 30-carbon linear structure of squalene
squalene
4 Cyclization of squalene forms the four rings of the 4

steroid nucleus, and further redox changes,
removal of methyl groups, leads to the final
cholesterol
product, cholesterol HO

38
 VII. METABOLISM OF CHOLESTEROL
Fates of cholesterol. Cholesterol biosynthesis occurs largely in the liver and is
exported from this tissue in two forms: bile acids and cholesteryl esters. The
former are relatively hydrophilic and aid in lipid digestion; the formation of the
latter is catalyzed by acyl-CoA-cholesterol acyl transferase (ACAT) that
catalyzes the transfer of an activated fatty acid (acyl-CoA) to cholesterol:

ACAT

O O
|| ||
HO R–C–SCoA R–C–O

HS-CoA
This reaction converts cholesterol into a completely hydrophobic form:
cholesteryl esters are the major form of cholesterol in plasma lipoproteins:
30% is found as free cholesterol and 70% as cholesteryl esters.

39
 VII. METABOLISM OF CHOLESTEROL

Regulation of cholesterol biosynthesis

The synthesis of cholesterol is regulated at three levels:

a. Hormonal regulation of HMG-CoA reductase

b. Ubiquitination and degradation of HMG-CoA reductase

c. Transcriptional regulation – protein levels

40
 VII. METABOLISM OF CHOLESTEROL
a. Hormonal regulation of HMG-CoA reductase acetyl-CoA
INSULIN
In humans, cholesterol production is regulated
by the intracellular cholesterol concentration phosphatase
β-hydroxymethyl-
glutaryl-CoA
and by the hormones glucagon and insulin.
Glucagon stimulates the phosphorylation (inac- HMG-CoA HMG-CoA
reductase reductase
tivation) of HMG-CoA reductase. Insulin P inactive active

stimulates the dephosphorylation (activation) of mevalonate

HMG-CoA reductase by activating the protein kinase

phosphatase 1, thus favoring the synthesis of GLUCAGON

cholesterol.
cholesteryl cholesterol
HMG-CoA reductase is allosterically inhibited esters ACAT (intracellular)

by the intracellular levels of cholesterol, which
also activate acyl-cholesterol-acyl-transferase
LDL-cholesterol
(ACAT), thus increasing the concentration of (extracellular)

cholesterol esters.
41
 WHY METABOLISM OF CARBOHYDRATES AND LIPIDS?
SIGNIFICANCE:
STARVE-FEED CYCLE
DIABETES
OBESITY
ATHEROSCLEROSIS
CELL SIGNALING
ALZHEIMER’S DISEASE

[lactate]
insulin [pyruvate]
glucagon

HYPOXIA
b cells a cells

ENDOCRINE REGULATION OF
CHOLESTEROL SYNTHESIS
Pancreas
42
 VII. METABOLISM OF CHOLESTEROL
Toll-like receptor TNFα
b. Ubiquitination and degradation of HMG-CoAIL1reductase
receptor
TNFα receptor
Cholesterol biosynthesis is regulated by ubiquitination (Ub). HMG-CoA reductase

contains a sterol-binding domain, to which cholesterol (the final product) binds and
IκB
triggers ubiquitination of the protein, thereby preparing it for degradation by the
nemo
activated
α P
proteasome. Another protein in the ERIKK
membrane is Insig
β P (Insulin-induced gene) that
complex
binds to HMG-CoA reductase and mediates the ubiquitination (Ub) and subsequent

degradation by the proteasome. P

NADP+ NADP+
sterol-binding
Mevalonate domain Mevalonate cholesterol
ubiquitination
proteasome
Ub degraded
proteasomeHMG-CoA

ai c
HMG-CoA HMG-CoA
ai c

ai c

m ti
m ti

m ti

do taly
reductase
do taly

do taly

n
n

n

NADPH

ca
ca

ca

Insig proteasome
cytosol Thr295–P Thr295–P
GSK3! Insig
ER PGC-1" PGC-1" PGC-1"
cholesterol Insig-mediated proteosomal
lumen binding ATP ubiquitination degradation
nuclear
ADP
membrane
NUCLEUS 43
nucleus degraded
 VII. METABOLISM OF CHOLESTEROL
c. Transcriptional regulation – protein levels
The membrane-bound transcription factor Sterol Regulatory Element Binding
Protein (SREBP) is the principal regulator of cholesterol synthesis and uptake. In
humans, SREBP is bound to SCAP (SREBP Cleavage Activating Protein) in the endo-
endoplasmic reticulum (ER).
ER INSIG (INSulin-Induced Gene)
SREBP SCAP INSIG SREBP SCAP is a key component of homeo-
static regulation by controlling
both the activity of SREBP and
the sterol-dependent degrada-
✂
✂
GOLGI tion degradation of HMG-CoA
reductase.

target genes NUCLEUS
SRE
HMG-CoA Reductase
LDL receptor 44
 REGULATION OF CHOLESTEROL SYNTHESIS
c. Transcriptional regulation
ER
 In the presence of cholesterol, the
SREBP SCAP INSIG SREBP SCAP
two proteins SREBP and SCAP are PRESENCE OF ABSENCE OF

CHOLESTEROL CHOLESTEROL
retained in the ER by binding to 
INSIG ✂
 In the absence of cholesterol, INSIG no longer ✂
GOLGI

binds to SREBP-SCAP and SREBP-SCAP trans-

locates to Golgi.
 In Golgi, the transcription factor domain of
SREBP (SRE) is released from the membrane by 
proteolytic cleavage catalyzed by proteases. SRE
target genes
HMG-CoA Reductase
NUCLEUS

LDL receptor
 SRE translocates to the nucleus and activates
target genes such as HMG-CoA reductase and the
LDL receptor.

45
 VII. METABOLISM OF CHOLESTEROL
GLUCAGON INSULIN

HSL
+ GLYCEROL-P
TRIGLYCERIDES FATTY ACID
TRIGLYCERIDE SYNTHESIS

FATTY ACID BIOSYNTHESIS
INSULIN

β-OXIDATION
CITRATE
ACYL-COA
ACC
GLUCAGON
FAS

HMG-COA
CHOLESTEROL HMG-CoA ACETYL-COA HMG-CoA KETONE BODIES
REDUCTASE
CHOLESTEROL BIOSYNTHESIS KETOGENESIS

INSULIN CHOLESTEROL
SREBP MEVALONATE
GLUCAGON
UBIQUITINATION

46
 5. LIPID METABOLISM
GROUP PROJECT
Description
Insulin regulates carbohydrate and lipid metabolism by acting on protein phosphatase 1.
INSULIN
Steps
Please review your class notes and phosphorylase a P
PHOSPHATASE
phosphorylase b (–) glycogenolysis
glycogenolysis
handouts and identify the sites of insulin active inactive

action
Complete the scheme below according glycogen synthase
D P
PHOSPHATASE glycogen synthase
I glycogenesis
glycogenesis

to the first example (glycogenolysis) by inactive active

identifying how the insulin-activated
acetyl-CoA PHOSPHATASE acetyl-CoA
enzyme stimulates (+) or inhibits (–) carboxylase P carboxylase fatty acid
fattysynthesis
acid synthesis

inactive active
glycogenesis, fatty acid synthesis, tri-
glyceride metabolism, cholesterol syn-
hormone-sensitive PHOSPHATASE hormone-sensitive triglyceride degradation
triglyceride metabolism
thesis, and pyruvate metabolism lipase P lipase antilipolytic
active inactive
Mention at least 3 metabolic pathways
in which glucagon antagonizes insulin PHOSPHATASE
HMG-CoA HMG-CoA cholesterol synthesis
reductase P reductase cholesterol synthesis
inactive active
Evaluation
Submit the report via Brightspace PHOSPHATASE
PDH P PDH pyruvate metabolism
pyruvate metabolism
inactive active