glycogenesis

1 the formation in animals of glycogen from glucose

2 the conversion of glucose to glycogen when the glucose in the blood exceeds the demand

Glycogenesis is the process of glycogen synthesis, in which glucose molecules are added to chains of glycogen. This process is activated by insulin in response to high glucose levels, for example after a carbohydrate containing meal.

Steps

• Glucose is converted into Glucose-6-Phosphate by the action of Glucokinase or Hexokinase.
• Glucose-6-Phosphate is converted into Glucose-1-Phosphate by the action of Phosphoglucomutase, passing through an obligatory intermediate step of Glucose-1,6-Phosphate.
• Glucose-1-Phosphate is converted into UDP-glucose by the action of Uridyl Transferase (also called UDP-glucose pyrophosphorylase) and Pyrophosphate is formed, which is hydrolyzed by pyrophosphatase into 2 molecules of Pi.
• Glucose molecules are collected in a chain by glycogen synthase, which must act on a pre-existing glycogen primer or glycogenin (small protein that forms the primer).
• Branches are made by 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 glucosidic bond, forming branches, which further grow by addition of more α-1:4 glucosidic units.

Control and regulation

Glycogenesis responds to both hormonal and electrical 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 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.

Adrenaline

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. Adrenaline binds to a receptor protein which activates adenylate cyclase. This in turn activates the secondary messenger system, by causing the formation of cyclic AMP, which acts allosterically to activate protein kinase A

Returning to glycogen phosphorylase, the less active form (b) 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 this helps to change the rate of flux in response to energy demand.

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

Insulin

Insulin has an antagonistic effect compared to adrenaline. The glycogen synthase enzyme can be kept in a low activation form by insulin, which switches off one of its kinase enzymes – glycogen synthase kinase 3.

Calcium ion

Calcium ion, like cyclic AMP (cAMP), acts as a secondary messenger. This is an example of negative control. The calcium ions activate phosphorylase kinase. This activates glycogen phosphorylase and inhibits glycogen synthase.

External links

• The chemical logic of glycogen synthesis