Endocrine Regulation Of Glycogen Metabolism PDF

Summary

This document provides an overview of endocrine regulation of glycogen metabolism, focusing on the processes of glycogenolysis and glycogenesis. It details the roles of hormones, enzymes, and specific tissues in these metabolic pathways.

Full Transcript

2

2. ENDOCRINE REGULATION

1
 2. CARBOHYDRATE METABOLISM I
– CONTENT –
VIII. Glycogenolysis XI. Receptors and tissue-specific outcomes
Regulation of glycogen phosphorylase a and b Epinephrine and a-adrenergic receptor
Clinical correlations Epinephrine and b-adrenergic receptor
von Gierske’s disease (Type I) Glucagon and glucagon receptor
McArdle’s disease (Type V) XII. Tissue-specific carbohydrate metabolism
Fanconi-Bickel’s syndrome (Type XVI) Erythrocytes
IX. Glycogenesis Brain
Regulation of glycogen synthase D and I Muscle
X. Endocrine Regulation of glycogen metabolism Adipose Tissue
Epinephrine/Glucagon Liver
cAMP- and PKA-driven pathways
Integration with co-regulatory enzymes of
glycogen metabolism
Insulin
The insulin receptor
Insulin signaling on glycogen metabolism
Integration with co-regulatory enzymes of
glycogen metabolism
2
 2. CARBOHYDRATE METABOLISM II
– LEARNING OBJECTIVES –
Evaluate the co-regulatory mechanisms of glycogenesis and
glycogenolysis based on their two key enzymes
Analyze the epinephrine regulation of glycogen metabolism based
on the three main actions of PKA
Integrate the epinephrine regulation into the co-regulatory
mechanisms of glycogenesis and glycogenolysis
Recognize the functional aspects of the insulin receptor and
analyze the effects of insulin on glycogen metabolism
Integrate the insulin regulation into the co-regulatory mechanisms
of glycogenesis and glycogenolysis
Identify the genetic deficiencies inherent in glycogen metabolism
and their outcomes
Distinguish the major pathways of carbohydrate metabolism in a
tissue-specific manner
3
 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
4
 VIII. GLYCOGENOLYSIS

Glycogen

Anabolism
Glycogenolysis Glycogenesis

Pentose Phosphate
GLUCOSE Ribose-5-P
Pathway

Glycolysis Gluconeogenesis
Catabolism

Pyruvate

5
 VIII. GLYCOGENOLYSIS
Glycogen is the major storage form of carbohydrate in animals (corresponds to starch in
plants). The function of glycogen in muscle is to act as a readily available source of
glucose for glycolysis within the muscle itself. Liver glycogen is largely concerned with
export of glucose for maintenance of glycemia.
Glycogen is degraded to glucose units by the activity of glycogen phosphorylase, that
catalyzes by phosphorolysis the release of glucose-1P from glycogen ([glucose]n):
[glucose]n + Pi → [glucose]n–1 + glucose-1P
Phosphoglucomutase catalyzes the conver- 6 CH
2OH
6 CH
2OH
6 CH
2OH
6 CH
2OH
5 5 5 5
sion of glucose-1P to glucose-6P, which 4
1
4
1
4
1
4
1

O O O
enters the glycolytic pathway. 3 2 3 2 3 2 3 2
[glucose]n

6 CH
2OPO3
2– 6 CH
2OH HPO42–
5 5 glycogen
phospho- 1 phosphorylase
4 4
glucomutase
3 2 1 3 2 OPO32–
glucose-6P glucose-1P

6 CH
2OH
6 CH
2OH
6 CH
2OH
5 5 5
1 1 1
4 4
O O
3 2 3 2 3 2
6 [glucose]n–1
 VIII. GLYCOGENOLYSIS
Glycogen phosphorylase occurs in two forms: the active form or glycogen
phosphorylase–a and the inactive form or glycogen phosphorylase–b.
Phosphorylase–a consists of four subunits: each subunit is phosphorylated. Protein
phosphatase 1 removes the phosphate groups of glycogen-
gen phosphorylase-a to yield glyco- 6 CH OH
2
6 CH OH
2
6 CH
2OH
6 CH
2OH
5 5 5 5
1 1 1 1 [glucose]n
gen phosphorylase–b, which consists 4 4 4 4

O O O
of two dimers and is converted back 3 2 3 2 3 2 3 2

protein phosphatase 1
to glycogen phosphorylase–a by
4 H2O
phosphorylase kinase. 4 Pi
HPO42– P P
6 CH
2OH
5 glycogen
1 phosphorylase
4 P phosphorylase b
P
OPO3 2– phosphorylase a
3 2 4 ADP
glucose-1P 4 ATP

2– phosphorylase kinase
6 CH
2OH
6 CH
2OPO3
5 5
1 phospho- 1 6 CH
2OH
6 CH
2OH
6 CH
2OH
4 4 5 5
5
glucomutase 1 1 1 [glucose]n–1
3 2 OPO32– 3 2 4 4
glucose-1P glucose-6P O O
3 2 3 2 3 2

7
 VIII. GLYCOGENOLYSIS
Fates of Glucose-6P from Glycogen Metabolism in Muscle and Liver
Glucose-6-phosphate from glycogen and by the action of glycogen phosphorylase and
phosphoglucomutase has different fates depending on whether glucose-6P is in liver or muscle.
Because liver contains glucose-6-phosphatase, glucose is dephosphorylated and exported into
plasma. P P
Muscle does not contain glucose-6-phosphatase,
hence, glucose-6P is converted via glycolysis to
P P
lactate. glycogen
phosphorylase a
[glucose]n [glucose]n–1
Pi
glucose-1P
phospho-
glucomutase

lactate glucose-6P glucose
glycolysis glucose-6P
phosphatase

Muscle Liver

8
 VIII. GLYCOGENOLYSIS
— SUMMARY —
Pi
H 2O
[glucose]n
protein
phosphatase
1

phosphorylase
phosphorylasebb Pi
P
b a
phosphorylase a
Glu-1P

phosphorylase
kinase
[glucose]n–1
ATP
ADP

9
 VIII. GLYGENOLYSIS
– CLINICAL CORRELATIONS –
Type I or von Gierke’s disease: the activity of glucose-6-
phosphatase is either extremely low or entirely absent in
liver, intestinal mucosa, and kidney. This disease is
characterized by large amounts of unavailable glycogen
in liver and kidney and by hypoglycemia. Hypoglycemia
is a consequence of the glucose-6-phosphatase
deficiency, the enzyme required to obtain glucose from
liver glycogen and gluconeogenesis; lactic acidemia
occurs because liver cannot use lactate for glucose
synthesis.

Glucose-6-Pase glucose
liver X
glucose glucose
Gluconeogenesis

Glycolysis

pyruvate pyruvate

lactate lactate
muscle
lactate

10
 VIII. GLYCOGENOLYSIS
– CLINICAL CORRELATIONS –
Type V or McArdle’s disease consists of a deficiency

of phosphorylase activity in muscle. Patients exhibit

markedly diminished tolerance to exercise and painful

muscle cramps, because muscle glycogen stores are

not available to the exercising muscle. Muscles are

likely damaged because of the inadequate energy

supply and glycogen accumulation.

11
 VIII. GLYCOGENOLYSIS
– CLINICAL CORRELATIONS –
[GLUCOSE]n
Type XI or Fanconi-Bickel syndrome consists of a
deficiency of GLUT2; hence, liver cannot be Pi
GLYCOGEN
PHOSPHORYLASE
[GLUCOSE]n–1
involved in regulation of glycemia because it
cannot release glucose into the bloodstream. The GLUCOSE-1P
disease proceeds with accumulation of glycogen
PHOSPHOGLUCO-
and severe hypoglycemia. Because this is a genetic MUTASE

disease, treatment is only of symptoms through
GLUCOSE-6P
adequate diets.
H 2O
GLUCOSE-6-
PHOSPHATASE
Pi
Fanconi-Bickel
syndrome
X GLUT2

GLUCOSE

12
 IX. GLYCOGENESIS

Glycogen

Anabolism
Glycogenolysis Glycogenesis

Pentose Phosphate
GLUCOSE Ribose-5-P
Pathway

Glycolysis Gluconeogenesis
Catabolism

Pyruvate

13
 IX. GLYCOGEN SYNTHESIS: GLYCOGENESIS

Overview

The biosynthesis of glycogen takes place in three sequential steps:

a. Isomerization of glucose-6-phosphate to glucose-1-phosphate

b. Activation of glucose-1-phosphate to UDP-glucose

c. Transfer of the glucosyl residue in UDP-glucose to an amylose chain

14
 IX. GLYCOGENESIS
The Three Sequential Steps of Glycogenesis
a. Isomerization of glucose-6-phosphate to glucose-1-phosphate is catalyzed
by phosphoglucomutase, a freely reversible reaction:
6 CH 2– 6 CH
2OPO3 2OH
5 5
1 phospho- 1
4 4
glucomutase
3 2 3 2 OPO32–
glucose-6P glucose-1P

b. Activation of glucose-1-P to UDP-glucose – The glucosyl donor (glucose-
1P) for glycogen synthesis is activated as UDP-glucose in a reaction
catalyzed by glucose-P-uridyl transferase:
Glucose-1P + UTP → UDP-glucose + PPi
O O
BASE

BASE
N N

O N O N
O O O O O
|| || || || ||
–O—P—O—P—O—P—O—CH
2 O glucose
–O—P—O—P—O—P—O—CH
2 O
| | | | |
O– O– O– O– O–

HO OH HO OH
RIBOSE RIBOSE

UMP UDP-glucose
UDP
UTP
15
 IX. GLYCOGENESIS
c. Transfer of the glucosyl reside in UDP-glucose to an amylose chain – The
glucosyl group of UDP-glucose is transferred to the terminal glucose residue at
the non-reducing end of an amylose chain to form an a(1→4) glycosidic
linkage. The reaction is catalyzed by glycogen synthase
6 CH
2OH
6 CH
2OH
6 CH
2OH
6 CH
2OH

1 1 1 1
4 4 4 4

O O O
[glucose]n
CH2OH

4

O—UDP
UDP-Glucose glycogen
synthetase

UDP

6 CH
2OH
6 CH
2OH
6 CH
2OH
6 CH
2OH

1 1 1 1
4 4 4 4

O O O
[glucose]n+1
16
 IX. GLYCOGENESIS
Glycogen synthase occurs in two forms: the phosphorylated form is inactive by
itself, although it is allosterically stimulated by glucose-6-phosphate and is,
therefore, called D or Dependent form (Glycogen synthase D). Glycogen
synthase D can be converted to the active form, glycogen synthase I, by protein
Pi
phosphatase 1 (I for Indepen-
H2O
dent form, because it does not [glucose]n
protein
require glucose-6P as an allo- phosphatase
1
steric regulator). Conversely, glycogen synthase D
UDP
(inactive) P
glycogen synthase I can be Glu-6P
I D
inactivated to glycogen synth- UDP-Glucose glycogen synthase I
(active) cAMP
ase D by protein kinase A,
protein kinase A
(PKA), which, in turn, is allo- (PKA)
[glucose]n–1
sterically activated by cAMP
ATP
(cyclic AMP ). ADP

17
 IX. GLYCOGENESIS
— SUMMARY —

Pi
H2O
[glucose]n
protein
phosphatase
1

UDP glycogen synthase D
(inactive) P
Glu-6P
I D
UDP-Glucose glycogen synthase I
(active) cAMP

protein kinase A
(PKA)
[glucose]n–1
ATP
ADP

18
 IX. REGULATORY STEPS OF GLYCOGENOLYSIS AND GLYCOGENESIS
Glycogen phosphorylase and glycogen synthase are the regulatory enzymes in
glycogenolysis and glycogenesis, respectively. The enzymes are activated /
inactivated by mechanisms involving phosphorylation / dephosphorylation
reactions that are critical for the regulation of cell signaling pathways.
Pi Pi
H2O H2O
[glucose]n
protein protein
phosphatase phosphatase
1 1
UDP glycogen synthase D
phosphorylase b P Pi (inactive) P
a Glu-6P
b UDP-Glucose
I D
phosphorylase a
glycogen synthase I
Glu-1P (active) cAMP

phosphorylase protein kinase A
kinase (PKA)
[glucose]n–1
ATP ATP
ADP ADP

19
OVERVIEW OF THE MAIN CARBOHYDRATE METABOLIC PATHWAYS
[GLUCOSE]n

GLYCOGENESIS
GLYCOGENOLYSIS GLYCOGEN GLYCOGEN
PHOSPHORYLASE SYNTHASE

ANABOLISM
CATABOLISM

GLUCOSE-1-P

GLUCOSE-6-P

GLUCONEOGENESIS
GLYCOLYSIS

PHOSPHOFRUCTO PHOSPHOFRUCTO
KINASE PHOSPHATASE

PYRUVATE

20
 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM

Liver has a large capacity for storing glycogen; in a well-fed individual, the

content of glycogen in liver accounts for ~10% of the liver weight. Liver

glycogen functions as a glucose reserve in order to maintain blood glucose

concentrations, thus furnishing fuel to other tissues

Muscle stores less glycogen (~1% of total muscle weight). Muscle stores

glycogen as a fuel reserve for the production of energy to support muscle work.

21
 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM
Hyperglycemic and Hypoglycemic Hormones
Superimposed on the allosteric controls over glycogen synthase and glycogen
phosphorylase, is another set of controls involving regulation by hormones,
particularly by
Epinephrine and Glucagon
Insulin
Basic principles:
The responsive target cells for any hormone contain specific hormone
receptors, which are specialized proteins capable of binding the hormone
molecule with high specificity and affinity. The receptors for epinephrine,
glucagon, and insulin are located on the cell surface.
The binding of the hormone to its specific receptor causes the formation of an
intracellular messenger molecule, which stimulates or depresses some
biochemical activity of the target tissue.
22
 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM
EPINEPHRINE

Secretion of epinephrine by the adrenal medulla into the blood triggers a prominent

response in target organs, which consists of an increased rate of breakdown of

glycogen in the muscles to yield lactate and in the liver to yield blood glucose,

along with inhibition of glycogen synthesis in the latter organ.

GLYCOGEN GLUCOSE-6P GLUCOSE

EPINEPHRINE

GLYCOGEN GLUCOSE-6P LACTATE

23
 IX. REGULATORY STEPS OF GLYCOGENOLYSIS AND GLYCOGENESIS
Glycogen phosphorylase and glycogen synthase are the regulatory enzymes in
glycogenolysis and glycogenesis, respectively. The enzymes are activated /
inactivated by mechanisms involving phosphorylation / dephosphorylation
reactions that are critical for the regulation of cell signaling pathways.
Pi Pi
H2O H2O
[glucose]n
protein protein
phosphatase phosphatase
1 1
UDP glycogen synthase D
phosphorylase b P Pi (inactive) P
a Glu-6P
b UDP-Glucose
I D
phosphorylase a
glycogen synthase I
Glu-1P (active) cAMP

phosphorylase protein kinase A
kinase (PKA)
[glucose]n–1
ATP ATP
ADP ADP

24
 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM
receptor
epinephrine
EPINEPHRINE
a. Binding of epinephrine to the b-adrenergic AC plasma
activated
adenylate membrane
receptor in the plasma membrane of liver or cyclase cAMP
ATP
muscle cells leads to the activation of a
adenylate
plasma membrane adenylate cyclase that cyclase
ATP AMPc + PPi
catalyzes the conversion of ATP into cyclic NH2
AMP (cAMP) and pyrophosphate (PPi). The
N
N
binding of glucagon to the glucagon
receptor proceeds by the same mechanism, N N

i.e., activation of adenylate cyclase and O—CH2 O
formation of the secondary messenger,
cAMP.
O –— P O OH
||
O

25
 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM

EPINEPHRINE
b. cAMP exerts its effects mainly by activating
cAMP
C R
a cyclic AMP-dependent protein kinase:
inactive
protein kinase A (PKA). The activation of
PKA requires binding of cAMP to the R cAMP PKA
regulatory subunit (R) of PKA, thereby active
dissociating it from the catalytic subunit (C).

26
 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM
EPINEPHRINE
c. Once activated, PKA modulates glycogen metabolism in a concerted
manner that affects three pathways:
Stimulation of glycogenolysis by facilitating the conversion of
phosphorylase-b to the active form phosphorylase-a.
Inhibition of glycogenesis by facilitating the conversion of glycogen
synthase I to the inactive glycogen synthase D.
Stimulation of glycogenolysis and inhibition of glycogenesis upon
inhibition of protein phosphatase I (an enzyme shared by both pathways,
glycogenolysis and glycogenesis)

27
Glycogenolysis PKA Glycogenesis
❶ ❷

Inhibitor 1 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM
❸
EPINEPHRINE
Protein
Phosphatase 1
Stimulation of glycogenolysis by facilitating the conversion of
phosphorylase-b to the active phosphorylase-a. The active PKA stimulates the conversion
of dephosphophosphorylase kinase (inactive form) into phosphophosphorylase kinase
(active form). The reaction reaction requires Ca++. The active phosphorylase kinase
catalyzes the conversion of phosphorylase–b into phosphorylase–a.
Phosphorylase–a, in turn, catalyzes the breakdown of
PROTEIN
KINASE A
glycogen ([glucose]n) into glucose–1P, which follow- (active)
4 ATP
ing isomerization is converted into glucose-6P.
PKA
C ATP PHOSPHORYLASE b
OH PKA OPO3 2–

Ca++ P
Ca++
4 ADP
ATP
dephospho-
DEPHOSPHO– ADP PHOSPHO– ADP P P
PHOSPHORYLASE phosphorylase PHOSPHORYLASE
KINASE kinase KINASEphospho-
(inactive) (inactive) (active)
phosphorylase
kinase
(active)
P P
PHOSPHORYLASE a
28
 Stimulation of glycogenolysis by facilitating the conversion of
phosphorylase-b to phosphorylase-a

b-adrenergic epinephrine 10–9 M
receptor

AC ATP

cAMP

phosphorylase-b
PKA
Dephospho-
phosphorylase Ca2+ Phosphorylase
kinase kinase
[glucose]n
phosphorylase-a

glucose-1P

glucose-6P
glucose-6
phosphatase

10–3 M GLUCOSE
29
 Stimulation of glycogenolysis by facilitating the conversion of
phosphorylase-b to phosphorylase-a
b-adrenergic epinephrine
receptor

AC ATP

cAMP

phosphorylase-b
PKA
Dephospho-
phosphorylase Ca2+ Phosphorylase
kinase kinase
[glucose]n
phosphorylase-a

glucose-1P

lactate pyruvate glycolysis glucose-6P

LACTATE
30
Glycogenolysis PKA Glycogenesis
❶ ❷

Inhibitor 1

❸ X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM
Protein
Phosphatase 1
EPINEPHRINE
Inhibition of glycogen synthesis by epinephrine is achieved by the
PKA-mediated phosphorylation of glycogen synthase I (active) to
glycogen synthase D (inactive). The inhibition of glycogen synthase is therefore brought
about by a chain of events triggered by the same stimulus that causes acceleration of
glycogen breakdown to yield blood glucose. Epinephrine not only stimulates glycogen
breakdown but also inhibits glycogen synthesis in the liver, thus directing all available
glucose residues and precursors into the production of free blood glucose

PKA

Glycogen Glycogen
Synthase Synthase
I D P

active inactive
non-phosphorylated phosphorylated 31
Inhibition of glycogenesis by facilitating the conversion of
glycogen synthase I to glycogen synthase D

b-adrenergic epinephrine
receptor

AC
ATP

cAMP

PKA
PKA

Glycogen Glycogen
Synthase Synthase
I D P

active inactive
non-phosphorylated phosphorylated

32
Glycogenolysis PKA Glycogenesis
❶ ❷
EPINEPHRINE
Inhibitor 1

❸
Stimulation of glycogenolysis and inhibition of

phosphorylase b
glycogenesis upon inhibition of protein phosphatase

synthase I
Protein

glycogen
glycogen
Phosphatase 1
I. Protein phosphatase 1 catalyzes the conversion

phosphatase
protein
phosphorylase-a → phosphorylase b (thus inactivat-

phosphorylase a

1

synthase D
glycogen
glycogen
ing glycogen breakdown) and the conversion glycogen synthase D → glycogen synthase
I (thus stimulating glycogen biosynthesis). Protein phosphatase I glycogen
phosphorylase b
is inhibited by inhibitor 1, that exists under two forms: the phos- glycogen
phosphorylase a
phorylated- and the dephosphorylated forms. The phosphorylated

inhibitor 1
form of inhibitor 1 blocks the protein phosphatase 1
protein
inhibitor 1 inhibitor 1
activity. The phosphorylation of inhibitor 1 is under phosphatase

P
1
ATP
hormonal control, because it is phosphorylated by P

ADP
ADP
PKA and, therefore, its degree of phosphorylation glycogen
ADPis synthase D
dependent on the cellular concentration of cAMP. PKA glycogen
p

ATP
ATP synthase I
inhibitor 1

inhibitor 1 inhibitor 1

ATP 33
Stimulation of glycogenolysis and inhibition of glycogenesis upon
inhibition of protein phosphatase I

b-adrenergic epinephrine
receptor

AC ATP

cAMP
glycogen
phosphorylase b
glycogen
phosphorylase a

PKA
protein
inhibitor 1 inhibitor 1 phosphatase
1
ATP
P
glycogen
ADP synthase D
glycogen
synthase I

34
 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM
– SUMMARY EPINEPHRINE –

b-adrenergic epinephrine
receptor

AC ATP

DEPHOSPHO- cAMP GLYCOGEN
PHOSPHORYLASE SYNTHASE I
KINASE (active)
(inactive)

PHOSPHATASE
PROTEIN
Ca2+

1
PHOSPHORYLASE-b PKA
(inactive)
PHOSPHATASE
PROTEIN

PHOSPHO- GLYCOGEN
glycogen PHOSPHORYLASE SYNTHASE D
1

KINASE (inactive)
(active)

PHOSPHORYLASE-a
(active)
INHIBITOR 1 INHIBITOR 1
(inactive) (active)
glucose-1P

35
 X. REGULATORY STEPS OF GLYCOGENOLYSIS AND GLYCOGENESIS
Glycogen phosphorylase and glycogen synthase are the regulatory enzymes in
glycogenolysis and glycogenesis, respectively. The enzymes are activated /
inactivated by mechanisms involving phosphorylation / dephosphorylation
reactions that are critical for the regulation of cell signaling pathways.
Pi Pi
H2O H2O
[glucose]n
protein protein
phosphatase phosphatase
1 1
UDP glycogen synthase D
phosphorylase b P Pi (inactive) P
a Glu-6P
b UDP-Glucose
I D
phosphorylase a
glycogen synthase I
Glu-1P (active) cAMP

phosphorylase protein kinase A
kinase (PKA)
[glucose]n–1
ATP ATP EPINEPHRINE
EPINEPHRINE ADP ADP

36
 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM
Hyperglycemic and Hypoglycemic Hormones
Superimposed on the allosteric controls over glycogen synthase and glycogen
phosphorylase, is another set of controls involving regulation by hormones,
particularly by
Epinephrine and Glucagon
Insulin
Basic principles:
The responsive target cells for any hormone contain specific hormone
receptors, which are specialized proteins capable of binding the hormone
molecule with high specificity and affinity. The receptors for epinephrine,
glucagon, and insulin are located on the cell surface.
The binding of the hormone to its specific receptor causes the formation of an
intracellular messenger molecule, which stimulates or depresses some
biochemical activity of the target tissue.
37
 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM
INSULIN

Insulin is secreted by the b cells of the islet of pancreas. The release of

insulin from pancreas depends on the blood glucose concentration. When

the blood glucose increases significantly above its normal level (80-90

mg/100 ml), insulin is secreted into the blood. The effect of insulin is a

prompt reduction of blood glucose level due to:

an enhancement of the transport of glucose from the blood across the

plasma membrane of muscle and fat cells (facilitated by GLUTs).

stimulation glycogenesis by favoring the conversion of glycogen

synthase D (inactive) into glycogen synthase I (active).

insulin differs from glucagon and epinephrine in that its binding to the

target cell membrane does not cause an increase in cAMP
38
 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM

THE INSULIN RECEPTOR
The insulin receptor is an integral membrane –S–S–

glycoprotein consisting of two a and two b Cysteine-rich
domain
chains joined by three disulfides bonds. The a

a-chain

a-chain
chains are on the extracellular side of the
membrane, whereas the b chains traverse the

–S–S–

–S–S–
membrane. The a chains contain a cysteine-rich

b-chain
domain, whereas the b chains contain a tyrosine

b-chain
Plasma
kinase domain. Membrane
Tyrosine kinase
The overall effects of insulin are rationalized in domain
terms of the mechanism involving tyrosine
kinase activity of the insulin receptor.

39
 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM
BINDING OF INSULIN TO THE INSULIN RECEPTOR (IR)
Upon binding of insulin the receptor becomes activated, i.e., the tyrosine kinase
domain located on the cytosolic portion of the b chains phosphorylates itself
(autophosphorylation). Thus, the activated insulin receptor is an enzyme that catalyzes
the phosphorylation of tyrosine residues in target proteins. ACTIVE RECEPTOR
PHOSPHORYLATES
TYROSINE RESIDUES
Insulin IN OTHER PROTEINS

–S–S– –S–S– –S–S– –S–S–
–S–S–
–S–S–

a-chain
a-chain

a-chain

a-chain

a-chain
a-chain

a-chain

a-chain

a-chain

a-chain
a-chain

a-chain
–S–S–

–S–S–
–S–S–

–S–S–

–S–S–

–S–S–

–S–S–

–S–S–

–S–S–

–S–S–
–S–S–

–S–S–
b-chain

b-chain

b-chain

b-chain

b-chain
b-chain

b-chain

b-chain

b-chain

b-chain
b-chain

b-chain
P P P P
P P
P P

RECEPTOR INSULIN-BOUND PHOSPHORYLATED TYROSINE
P
TO RECEPTOR KINASE IN RECEPTOR Protein Protein
CATALYTIC ACTIVITY (AUTOPHOSPHORYLATION) Protein Pr
P
OF TYROSINE KINASE Protein Protein
DOMAIN IS SWITCHED
39
 X. ENDOCRINE REGULATION OF GLYCOGEN METABOLISM

THE INSULIN SIGNALING PATHWAY
phosphorylase
Once the insulin receptor is activated, its glycogen
b
phosphorylase b

glycogenolysis
Decreased
autophosphorylation increases the capacity of phosphorylase
glycogen
phosphorylase
a a
tyrosine kinase to phosphorylate
PKA
PKA tyrosine
Protein
inhibitor
residues on target 1
proteins, among inhibitor
them a1 insulin
P Phosphatase
I

glycogenesis
protein target that stimulates
ATP
ATP ADP protein

Increased
ADP glycogen
glycogen
synthase D
phosphatase 1. Activation of protein phos- glycogen
synthase glycogen
D synthase
synthase
I I
phatase 1 leads to increased rates of glyco-
genesis and decreased rates of glycogenolysis

41
 X. REGULATORY STEPS OF GLYCOGENOLYSIS AND GLYCOGENESIS
— INSULIN —

Protein Phosphatase 1 is involved in the regulation of glycogenolysis and

glycogenesis. Insulin stimulates protein phosphatase 1, thereby inhibiting the

degradation of glycogen and activating the synthesis of glycogen.
Pi Pi
H2O INSULIN INSULIN H2O
[glucose]n
protein protein
phosphatase phosphatase
1 1
UDP glycogen synthase D
phosphorylase b P Pi (inactive) P
a Glu-6P
b UDP-Glucose
I D
phosphorylase a
glycogen synthase I
Glu-1P (active) cAMP

phosphorylase protein kinase A
kinase (PKA)
[glucose]n–1
ATP ATP
ADP ADP

42
 X. REGULATORY STEPS OF GLYCOGENOLYSIS AND GLYCOGENESIS
Glycogen phosphorylase and glycogen synthase are the regulatory enzymes in
glycogenolysis and glycogenesis, respectively. The enzymes are activated /
inactivated by mechanisms involving phosphorylation / dephosphorylation
reactions that are critical for the regulation of cell signaling pathways.
Pi Pi
H2O H2O
[glucose]n
protein protein
phosphatase phosphatase
1 1
UDP glycogen synthase D
phosphorylase b P Pi (inactive) P
a Glu-6P
b UDP-Glucose
I D
phosphorylase a
glycogen synthase I
Glu-1P (active) cAMP

phosphorylase protein kinase A
kinase (PKA)
[glucose]n–1
ATP ATP EPINEPHRINE
EPINEPHRINE ADP ADP

43
XI. RECEPTORS, SECOND MESSENGERS,
AND
TISSUE-SPECIFIC OUTCOMES

44
XI. RECEPTORS, SECOND MESSENGERS, AND TISSUE-SPECIFIC OUTCOMES

GLUCAGON AND EPINEPHRINE STIMULATE
GLYCOGEN METABOLISM IN LIVER
Glucagon is released from a cells of
pancreas in response to low blood glucose
levels; it binds to the glucagon receptors,
located on the plasma membrane of
hepatocytes and leads to the activation of
adenylate cyclase and, consequently,
activation glycogenolysis and inactivation
of glycogenesis and to a rapid increase of
blood glucose levels.
Epinephrine is released into blood from
the adrenal medulla in response to stress
and interacts with b-adrenergic receptors
in the hepatocyte plasma membrane to
activate adenylate cyclase and outcomes
similar to glucagon.
45
XI. RECEPTORS, SECOND MESSENGERS, AND TISSUE-SPECIFIC OUTCOMES

EPINEPHRINE EFFECTS ON THE a-ADRENERGIC
RECEPTOR IN THE LIVER
The plasma membrane of hepatocytes has
another binding protein for epinephrine, the a-
adrenergic receptor. Interaction of epinephrine
with this receptor leads to the formation of
second messengers IP3 and DAG, generated in
the plasma membrane by the action of
phospholipase C on phosphatidylinositol-4,5-
bisphosphate. IP3 stimulates Ca2+ release that
activates phosphorylase kinase and inhibits
phosphorylase. The consequences of epinephrine
action are an increased release of glucose into
the blood from the glycogen stored in liver.

46
XI. RECEPTORS, SECOND MESSENGERS, AND TISSUE-SPECIFIC OUTCOMES

EPINEPHRINE STIMULATES GLYCOGENOLYSIS IN
HEART AND SKELETAL MUSCLE

Epinephrine stimulates glycogen degradation in
heart and skeletal muscle upon binding to a b-
adrenergic receptor: cAMP, the second messen-
ger, activates glycogen glycogenolysis and inacti-
vates glycogenesis. Glycolysis is also stimulated.
These effects lead to formation of pyruvate.
Skeletal muscle lacks glucose-6-phosphatase and
as a consequence of the action of epinephrine on
skeletal muscle lactate is released into blood and
taken up by tissues (e.g., liver) that can synthesize
glucose and regulate glycemia.

47
XI. RECEPTORS, SECOND MESSENGERS, AND TISSUE-SPECIFIC OUTCOMES

NEURAL CONTROL OF GLYCOGEN METABOLISM IN
SKELETAL MUSCLE
Nervous excitation of muscle activity is mediated
via the acetyl choline receptor and involves
changes in Ca2+ concentrations through an initial
membrane depolarization. The release of Ca2+
triggers muscle contraction. Changes in Ca2+ affect
the activity of phosphorylase kinase and lead to
activation of glycogen phosphorylase. The result is
that more glycogen is converted to glucose-6-P so
that more ATP can be produced to meet the greater
energy demand of muscle contraction.

48
XI. RECEPTORS, SECOND MESSENGERS, AND TISSUE-SPECIFIC OUTCOMES

49
 XI. RECEPTORS, SECOND MESSENGERS, AND TISSUE-SPECIFIC OUTCOMES

INSULIN STIMULATES GLYCOGENESIS IN MUSCLE AND insulin
insulin
LIVER receptor

An increase in blood glucose signals the release of
insulin from the b cells of pancreas. Binding of insulin glycogen
PrPase 1 PrPase 1
to its receptor promotes glucose utilization by
GSD GSI P-a P-b

promoting glycogenesis) and inhibiting glycogenolysis
glucose-1P
in muscle and liver. The glucose transporter in
hepatocytes (GLUT2; high capacity) is insulin-
glucose-6P
insensitive, whereas glucose transport in muscle and
adipocytes (GLUT4) is insulin-sensitive. Glycogenesis
glucose
is stimulated in both tissues upon activation of protein GLUT4

phosphatase-1, thus resulting in inhibition of glycogen plasma
glucose membrane
phosphorylase and stimulation of glycogen synthase.
50
 XII
TISSUE-SPECIFIC
CARBOHYDRATE METABOLISM

51
 XII. TISSUE-SPECIFIC CARBOHYDRATE METABOLISM

RED BLOOD CELL
After penetrating the plasma membrane by
glucose
mediated transport, glucose is metabolized GLUT

mainly by glycolysis in erythrocytes.
glucose
Mature erythrocytes lack mitochondria; HK
hence the end product of glycolysis is
Pentose-P glucose-6P
lactate, which is released from the red PPP

glycolysis
blood cells back into the plasma.
pyruvate lactate
Metabolism of glucose in red blood cells
MCT
via the pentose phosphate pathway provides
lactate
NADPH that is required to maintain
glutathione levels

52
 XII. TISSUE-SPECIFIC CARBOHYDRATE METABOLISM
BRAIN
glucose
The brain, as the red blood cells, takes up
GLUT

glucose by mediated transport in an insulin-
glucose
independent manner (GLUT1 present in HK
endothelial cells of the blood-brain barrier). Pentose-P glucose-6P
PPP

glycolysis
Glycolysis in the brain yields pyruvate, which
is then oxidized to CO2 and H2O via the pyruvate lactate
lactate
pyruvate
tricarboxylic acid cycle (TCA). The pentose decarboxylation

phosphate pathway is also quite active in acetyl-CoA

brain and NADPH formed is used for
reductive synthesis and to maintain TCA

glutathione levels. GLUT4, however, present CO2

in neurons is an insulin-sensitive glucose
transporter.
53
 XII. TISSUE-SPECIFIC CARBOHYDRATE METABOLISM

MUSCLE glucose
Muscle and heart cells utilize glucose GLUT

readily and its transport into these cells lactate
glucose
proceeds via the insulin-sensitive GLUT4. HK glycogenesis

Glucose is metabolized via glycolysis to Pentose-P glucose-6P glycogen
PPP

glycolysis
pyruvate and lactate. Pyruvate can be glycogenolysis

oxidized to acetyl-CoA in mitochondria to pyruvate lactate MCT lactate
generate considerable energy in the form of
ATP. In contrast to brain and erythrocytes, acetyl-CoA
muscle and heart cells can synthesize signi-
ficant amounts of glycogen. Synthesis and
TCA
degradation of glycogen are important
CO2
processes in these cells.

54
 XII. TISSUE-SPECIFIC CARBOHYDRATE METABOLISM
ADIPOSE TISSUE
The transport of glucose into adipose tissue glucose

occurs by the insulin-sensitive GLUT4. GLUT

Pyruvate from glycolysis, can be oxidized by glucose
HK
the pyruvate dehydrogenase complex to acetyl- glycogenesis

CoA. However, acetyl-CoA is primarily used Pentose-P glucose-6P glycogen
PPP

glycolysis
glycogenolysis
for the synthesis of fatty acids. Generation of
pyruvate
NADPH by the pentose phosphate pathway is
pyruvate
decarboxylation
important in the adipocyte: NADPH is used for
acetyl-CoA
the de novo synthesis of fatty acids. Although
synthesis and degradation of glycogen occurs in
Fat
the adipocyte, these processes are much more
limited in this tissue than in muscle and heart.

55
 XII. TISSUE-SPECIFIC CARBOHYDRATE METABOLISM
LIVER
Uptake of glucose by liver occurs independent
glucose
of insulin by means of a high capacity GLUT
transport system (GLUT2). Glucose is used
glucose
in the pentose phosphate pathway for the
Pentose-P HK glycogenesis
synthesis of NADPH, which is required PPP
glucose-6- glucose-6P glycogen
for numerous reactions. glucose phosphatase
glycogenolysis

gluconeogenesis
for glycogen storage (glycogen synthesis).

glycolysis
glucuronides
for detoxification via the glucuronic acid
pathway.
pyruvate MCT lactate
For the synthesis of fats via acetyl-CoA pyruvate
decarboxylation
yielded by pyruvate metabolism
acetyl-CoA
The liver is unique in that it also has the lipogenesis

capacity to convert three carbon precursors, Fat
such as lactate and alanine, into glucose by TCA
gluconeogenesis. The glucose produced can is
CO2
used to meet the metabolic needs of peripheral
tissues.
56
 CARBOHYDRATE METABOLISM
GROUP PROJECT
Description
Derangements in carbohydrate metabolism occur because of genetic deficiencies of key enzymes, factors,
transporters, or imbalances in aerobic/anaerobic metabolism resulting in a particular pathophysiology.
1. Lactic acidosis......................................................
2. Hemolytic anemia................................................ pyruvate kinase
3. Hypoglycemia and premature infants..................
4. Hypoglycemia and alcohol intoxication..............
5. Wernicke-Korsakoff syndrome............................
6. Drug hemolytic anemia........................................
7. Pernicious anemia................................................
8. Galactosemia........................................................
9. Lactose intolerance..............................................
10. Type I or von Gierke's disease.............................
11. Type V or McArdle's disease...............................
12. Type XI or Fanconi-Bickel's disease...................

Steps
1 Complete the items above by adding the genetic deficiencies of key enzymes, factors, transporters, or imbalances
in aerobic/anaerobic metabolism causing a particular pathophysiology (example in number 2 (hemolytic anemia)).
2 Explain the genetic deficiency inherent in 3 (hypoglycemia and premature infants) and whether or not the Cori
cycle supports brain function under this condition.
3 Explain the genetic deficiency in 12 (Fanconi-Bickel's disease) and the outcome in terms of glycemia values.
4 Provide a simple diagram of how insulin affects the co-regulation of the key enzymes of glycogenesis and
glycogenolysis.
5 Write a short report (maximum 1 page) addressing points 1 to 4 above.

Evaluation
Submit the report via Brightspace
57