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Contents

(Top) 1 Steps 2 Control and regulations 2.1 Epinephrine (adrenaline) 2.2 Calcium ions 3 See also 4 References

Glycogenesis

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Glycogenesis is the process of glycogen synthesis, in which glucose molecules are added to chains of glycogen for storage. This process is activated during rest periods following the Cori cycle, in the liver, and also activated by insulin in response to high glucose levels.^[1]

Steps[edit]

Glucose is converted into glucose 6-phosphate by the action of glucokinaseorhexokinase with conversion of ATP to ADP.
Glucose-6-phosphate is converted into glucose-1-phosphate by the action of phosphoglucomutase, passing through the obligatory intermediate glucose-1,6-bisphosphate.
Glucose-1-phosphate is converted into UDP-glucose by the action of the enzyme UDP-glucose pyrophosphorylase. Pyrophosphate is formed, which is later hydrolysed by pyrophosphatase into two phosphate molecules.
The enzyme glycogenin is needed to create initial short glycogen chains, which are then lengthened and branched by the other enzymes of glycogenesis. Glycogenin, a homodimer, has a tyrosine residue on each subunit that serves as the anchor for the reducing end of glycogen. Initially, about seven UDP-glucose molecules are added to each tyrosine residue by glycogenin, forming α(1→4) bonds.
Once a chain of seven glucose monomers is formed, glycogen synthase binds to the growing glycogen chain and adds UDP-glucose to the 4-hydroxyl group of the glucosyl residue on the non-reducing end of the glycogen chain, forming more α(1→4) bonds in the process.
Branches are made by glycogen branching enzyme (also known as amylo-α(1:4)→α(1:6)transglycosylase), which transfers the end of the chain onto an earlier part via α-1:6 glycosidic bond, forming branches, which further grow by addition of more α-1:4 glycosidic units.

Metabolism of common monosaccharides, including glycolysis, gluconeogenesis, glycogenesis and glycogenolysis

Control and regulations[edit]

Glycogenesis responds to hormonal control.

One of the main forms of control is the varied phosphorylation of glycogen synthase and glycogen phosphorylase. This is regulated by enzymes under the control of hormonal activity, which is in turn regulated by many factors. As such, there are many different possible effectors when compared to allosteric systems of regulation.

Epinephrine (adrenaline)[edit]

Glycogen phosphorylase is activated by phosphorylation, whereas glycogen synthase is inhibited.

Glycogen phosphorylase is converted from its less active "b" form to an active "a" form by the enzyme phosphorylase kinase. This latter enzyme is itself activated by protein kinase A and deactivated by phosphoprotein phosphatase-1.

Protein kinase A itself is activated by the hormone adrenaline. Epinephrine binds to a receptor protein that activates adenylate cyclase. The latter enzyme causes the formation of cyclic AMP from ATP; two molecules of cyclic AMP bind to the regulatory subunit of protein kinase A, which activates it allowing the catalytic subunit of protein kinase A to dissociate from the assembly and to phosphorylate other proteins.

Returning to glycogen phosphorylase, the less active "b" form can itself be activated without the conformational change. 5'AMP acts as an allosteric activator, whereas ATP is an inhibitor, as already seen with phosphofructokinase control, helping to change the rate of flux in response to energy demand.

Epinephrine not only activates glycogen phosphorylase but also inhibits glycogen synthase. This amplifies the effect of activating glycogen phosphorylase. This inhibition is achieved by a similar mechanism, as protein kinase A acts to phosphorylate the enzyme, which lowers activity. This is known as co-ordinate reciprocal control. Refer to glycolysis for further information of the regulation of glycogenesis.

Calcium ions[edit]

Calcium ions or cyclic AMP (cAMP) act as secondary messengers. This is an example of negative control. The calcium ions activate phosphorylase kinase. This activates glycogen phosphorylase and inhibits glycogen synthase.

See also[edit]

References[edit]

^ Patino, Sara C.; Orrick, Josephine A. (2021), "Biochemistry, Glycogenesis", StatPearls, Treasure Island (FL): StatPearls Publishing, PMID 31747227, retrieved 2021-12-29

t

e

Metabolism, catabolism, anabolism

General

Energy
metabolism

Aerobic respiration

Glycolysis → Pyruvate decarboxylation → Citric acid cycle → Oxidative phosphorylation (electron transport chain + ATP synthase)

Anaerobic respiration

Electron acceptors other than oxygen

Glycolysis → Substrate-level phosphorylation
- ABE
- Ethanol
- Lactic acid

Specific
paths

Protein metabolism

Protein synthesis
Catabolism (protein→peptide→amino acid)

Amino acid synthesis
Amino acid degradation (amino acid→pyruvate, acetyl CoA, or TCA intermediate)
Urea cycle

Nucleotide
metabolism

Carbohydrate metabolism
(carbohydrate catabolism
and anabolism)

Human

Glycolysis ⇄ Gluconeogenesis

Glycogenolysis ⇄ Glycogenesis

Glycosylation
- N-linked
- O-linked

Nonhuman

Lipid metabolism
(lipolysis, lipogenesis)

Fatty acid metabolism

Other

Other

t

e

Carbon
fixation

Photo-
respiration

Pentose
phosphate
pathway

Citric
acid cycle

Glyoxylate
cycle

Urea
cycle

Fatty
acid
synthesis

Fatty
acid
elongation

Beta
oxidation

Peroxisomal

beta
oxidation

Glyco-
genolysis

Glyco-
genesis

Glyco-
lysis

Gluconeo-
genesis

Pyruvate
decarb-
oxylation

Fermentation

Keto-
lysis

Keto-
genesis

feeders to
gluconeo-
genesis

Direct / C4 / CAM
carbon intake

Light reaction

Oxidative
phosphorylation

Amino acid
deamination

Citrate
shuttle

Lipogenesis

Lipolysis

Steroidogenesis

MVA pathway

MEP pathway

Shikimate
pathway

Transcription &
replication

Translation

Proteolysis

Glycosyl-
ation

Double/multiple
sugars & glycans

Amino sugars
& sialic acids

Nucleotide sugars

α-Keto-
glutarate

Respiratory
chain

Branched-chain
amino acids

Aspartate
group

Homoserine
group
& lysine

Glutamate
group
& proline

Creatine
& polyamines

Ketogenic &
glucogenic
amino acids

Aromatic amino
acids & histidine

Ascorbate
(vitamin C)

Cobalamins (vitamin B₁₂)

Various
vitamin Bs

Calciferols
(vitamin D)

Retinoids
(vitamin A)

Quinones (vitamin K)
& tocopherols (vitamin E)

Vitamins
& minerals

Glycoproteins
& proteoglycans

MEP

MVA

Terpenoid
backbones

Terpenoids
& carotenoids (vitamin A)

Glycero-
phospholipids

Glyco-
sphingolipids

Polyunsaturated
fatty acids

Neurotransmitters
& thyroid hormones

Endo-
cannabinoids

Major metabolic pathwaysinmetro-style map. Click any text (name of pathway or metabolites) to link to the corresponding article.
Single lines: pathways common to most lifeforms. Double lines: pathways not in humans (occurs in e.g. plants, fungi, prokaryotes).

Orange nodes: carbohydrate metabolism.

Violet nodes: photosynthesis.

Red nodes: cellular respiration.

Pink nodes: cell signaling.

Blue nodes: amino acid metabolism.

Grey nodes: vitamin and cofactor metabolism.

Brown nodes: nucleotide and protein metabolism.

Green nodes: lipid metabolism.

t

e

Glycogenesis and glycogenolysis metabolic intermediates

Other

t

e

Metabolism: carbohydrate metabolism, glycogenesis and glycogenolysis enzymes

Glycogenesis

Glycogenolysis

extralysosomal:

Alpha-glucosidase (Acid)

Regulation

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