Glycogen Metabolism PDF

Summary

This document explains glycogen metabolism, a crucial biological process. It describes the synthesis and breakdown of glycogen, highlighting the different roles of the liver and muscle tissues in this process. The document also covers the enzymes involved, the regulation of these processes, and the significance of glycogen as an energy store.

Full Transcript

Glycogen Metabolism
Asst. Prof. Gökhan BAĞCI

Glycogen
Higher organisms store carbohydrates as glucose polysaccharides in order to continuously supply glucose.
Plants: Starch

Humans and animals : Glycogen
Glycogen is a broad glucose primary in its main chain linked by α-1,4 glycosidic bonds, with glucose units
branching by α-1,6 glycosidic bonds every 8-10 units.

Glycogen stored in humans is sufficient for 12-18 hours.
Glycogen metabolism takes place in the cytosol and its responsible enzymes are located in the cytosol.

• Glycogen synthesis occurs in almost all
tissues.

• However, intense glycogen synthesis occurs
in the liver and muscle tissue.
• Glycogen is the storage form of glucose in
the liver. It is easily converted to blood
glucose for distribution to other tissues.
• Glucose obtained from the breakdown of
glycogen in the muscles is used to provide
the necessary ATP for muscle contraction.
• UDP-glucose is the substrate of glycogen
synthesis.

• The synthesis of glycogen starting from a precursor
molecule is called glycogenin, the breakdown of
glucose units from the non-reduced end of glycogen
and the release of free glucose into the circulation is
called glycogenolysis.

• Glycogen breakdown in muscle and liver is different
from each other.
• Muscle: Glycogen is broken down to glucose 6phosphate and this product is metabolized for ATP
synthesis via glycolysis and the TCA cycle.

• Liver: Free glucose, which is the end product of
glycogenolysis, is given to the bloodstream, enabling
other tissues to use glucose.

Fluctuation of glycogen stores
• Liver glycogen stores increase during the well-fed
state and are depleted during a fast.
• Muscle glycogen is not affected by short periods of
fasting (a few days) and is only moderately
decreased in prolonged fasting (weeks).
• Muscle glycogen is synthesized to replenish muscle
stores after they have been depleted following
strenuous exercise.
• [Note: Glycogen synthesis and degradation are
cytosolic processes that go on continuously.
• The differences between the rates of these two
processes determine the levels of stored glycogen
during specific physiologic states.]

• Sugar nucleotides are involved in most of the
transformation

or

polymerization

reactions

of

hexoses.
• In sugar nucleotides, the anomeric carbon atom of
the sugar is activated by binding to the nucleotide
by a phosphodiester bond.
• Sugar

nucleotides

polymerization

of

are

substrates

for

monosaccharides

the

into

disaccharides, glycogen, starch, cellulose, and
more complex extracellular polysaccharides.
• The formation of sugar nucleotides is metabolically
irreversible, making the synthesis pathways in
which it is an intermediate also irreversible.

UDP-Glucose

Sugar nucleotide formation: It is formed by a condensation reaction between a nucleoside triphosphate (NTP)
and a sugar phosphate.
The negatively charged oxygen on the sugar phosphate acts as a nucleophile and attacks the phosphate of the
nucleoside triphosphate, displacing the pyrophosphate.

The reaction is continued forward by hydrolysis of PPi by inorganic pyrophosphatase.

Glycogen

Glycogen in its straight chain forming α(1→4) glycosidic bonds
and It contains α(1→6) glycosidic bonds at the branching point.
• After an average of eight to ten glucosyl residues, there is a branch containing an α(1→6) linkage .
• A single molecule of glycogen can have a molecular mass of up to 108 daltons.
• These molecules exist in discrete cytoplasmic granules that also contain most of the enzymes necessary for
glycogen synthesis and degradation.

Glycogen Synthesis
➢ The starting point of glycogen synthesis is glucose-6phosphate.
➢ Glucose 6-phosphate is formed from free glucose by
glucokinase (in liver) or hexokinase (in muscle).
➢ The phosphoglucomutase enzyme reversibly converts
glucose 6-phosphate to glucose 1-phosphate.
➢ Thus, an intermediate product of glycogen synthesis and
degradation occurs.
➢ The liver glucose 6-phosphatase enzyme hydrolyzes
glucose 6-phosphate to release glucose into the
circulation.
➢ This enzyme is not found in muscle.

• Glycogen Synthesis
UDP-glucose+ glycogen (n residue)→UDP+Gliycogen (n+1
residue)

- Glycogen consists of α-D-glucose units.

- Its synthesis takes place in the cytosol with energy from
ATP (for the phosphorylation of glucose) and UTP..

- UDP-glucose, the active form of glucose, is synthesized
from glucose 1-phosphate and UTP by the enzyme UDPglucose pyrophosphorylase.

• UDP-glucose is the glucose donor for glycogen synthesis.
• A glycogen moiety in the cell can be the initiator for the initiation of glycogen synthesis.
• If glycogen is completely depleted, then a special protein called glycogenin acts as a receptor for glucose residues.
• UDP-glucose is the glucose donor in the reaction catalyzed by glycogen synthase.
• The glycogen synthase enzyme transfers glucose from UDP-glucose to the non-reducing end of the branched glycogen
molecule. This enzyme forms (α1-4) glycosidic bonds but not (α1-6) bonds.

• Elongation of the glycogen chain: Chain elongation occurs
with the formation of a glycosidic bond between the hydroxyl
group of the first carbon (anomeric) of glucose from UDPglucose and the 4th carbon of the acceptor glucose in the
chain.
• In other words, a glucose from UDP-glucose is added to the
chain.
• The enzyme that makes α-1,4 glycoside bonds in chain
extension reactions is glycogen synthase.
• The rate-limiting step in glycogen synthesis is the glycogen
synthase step.
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• Formation of the branching point: After at least 11 glucose units, branching occurs in
glycogen.

• The enzyme that performs the reactions is glucosyl α-4.6 transferase [amilo (1→4)→(1→6)
transglycosylase] known as the branching enzyme.
• This enzyme takes a terminal fragment containing six or seven glucose from the non-

reducing end of a glycogen branch with at least 11 glucose molecules and transfers it to
another place in the chain or to the C-6 hydroxyl group of a glucose molecule located further
inside another glycogen molecule. allows to form.

• The new bond formed is an α-1,6 glycoside bond.
• The newly formed non-reduced end is extended by glycogen synthase like the previous nonreduced end.
• When the elongation of the newly formed tips is completed, the last 5-8 residues are
separated and new branches are formed.

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Glycogen Breakdown (Glycogenolysis)

Glycogen breakdown (Glycogenolysis)
Rate-limiting reaction: Glycogen phosphorylase breaks the α-1,4 glycoside bond at
the end of the glycogen chain, allowing glucose to be separated as glucose-1phosphate.
Glycogen (n) + Pi  Glycogen (n-1) + Glucose-1-phosphate

20

⚫

When four glucose units remain at the branching point, glycogen phosphorylase
stops.

⚫This

final structure formed is called limit dextrin.

⚫Limit

dextrin is broken down by the glycogen cleavage enzyme, which shows two
different activities.

⚫1)

With the 4-glucanotransferase activity, 3 units of glucose are transferred from
the branching point to the free 4' end of the chain on the glycogen molecule.

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2) With the amylo 1,6-glucosidase activity, the α-1,6-glucosidic bond is hydrolyzed to release one
unit of glucose into the circulation.

This is a hydrolysis reaction and not phosphorylation. Therefore, free glucose is
released directly into the circulation.
Glucose-1-phosphate is not the product of this reaction.

Glucose
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• In cells, glucose-1-phosphate is rapidly converted to glucose6-phosphate by the enzyme phosphoglucomutase.
• In the liver, glucose-6-phosphate is hydrolyzed to free glucose
by glucose-6-phosphatase.
• Muscle glycogen cannot increase blood sugar levels because
there is no glucose 6-phosphatase in the muscles.

GLYCOGEN METABOLISM IS REGULATED BY TWO HORMONES

Glycogen Synthase
When phosphorilated= Inactive
When dephosphorilated= Active

Glycogen Phosphorilase
When phosphorilated= Active
When dephosphorilated= Inactive

• Glycogen synthesis and glycogen breakdown
cannot occur simultaneously.
• Therefore Glycogen synthase and glycogen
phosphorylase cannot be active at the same
time.
• Insulin and, according to tissues, glucagon
or adrenaline (epinephrine) are effective
hormones in this regulation.

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• Hormones and second messengers regulate the phosphorylation of
glycogen synthase and glycogen phosphorylase enzymes.
• Insulin, which increases the synthesis of glycogen in the liver and
skeletal muscle, enables the storage of excess carbohydrates taken with
food as glycogen.

• When the blood glucose level decreases in fasting, glucagon increases
the blood glucose level by stimulating glycogen breakdown in the liver.

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Glycogen Storage Diseases

• Extraordinary Measures is a 2010 American medical drama film
starring Brendan Fraser, Harrison Ford, and Keri Russell.
• The film is about parents who form a biotechnology company to
develop a drug to save the lives of their children, who have a lifethreatening disease.
• The film is based on the true story of John and Aileen Crowley,
whose children have Pompe's disease.