Glycogen metabolism regulation

As an example, the protein kinase that regulates glycogen metabolism is regulated by a repressor subunit that is displaced by cyclic AMP. 

Donahue, M. J., Yacoub, N. J., Kaeini, M. R. and Harris, B. G. (1981) Activity of enzymes regulating glycogen metabolism in perfused muscle-cuticle sections of Ascaris suum (Nematoda). J. Parasitol. 67 362-367. 

Explain the role of hormones in regulating glycogen metabolism. 

The principal enzymes controlling glycogen metabolism—glycogen phosphorylase and glycogen synthase— are regulated by allosteric mechanisms and covalent modifications due to reversible phosphorylation and... 

REGULATION OF GLYCOGEN METABOLISM IS EFFECTED BY A BALANCE IN ACTIVITIES BETWEEN GLYCOGEN SYNTHASE PHOSPHORYLASE (Figure 18-8)... 

The bottom line for any of the above disorders is that insulin action is lost. Insulin is the primary hormone that regulates the metabolism of glucose in its conversion to the storage of carbohydrate—glycogen stored in the liver and muscles. Insulin also... 

The membrane-associated Akt kinase is now a substrate for protein kinase PDKl that phosphorylates a specific Thr and Ser residue of Akt kinase. The double phosphorylation converts Akt kinase to the active form. It is assumed that the Akt kinase now dissociates from the membrane and phosphorylates cytosolic substrates such as glycogen synthase kinase, 6-phosphofructo-2-kinase and ribosomal protein S6 kinase, p70 . According to this mechanism, Akt kinase regulates central metabolic pathways of the cell. Furthermore, it has a promoting influence on cell division and an inhibitory influence on programmed cell death, apoptosis. A role in apoptosis is suggested by the observation that a component of the apoptotic program. Bad protein (see Chapter 15) has been identified as a substrate of Akt kinase. 

Of the protein kinases, protein kinase A is the best investigated and characterized (review Francis and Corbin, 1994). The functions of protein kinase A are diverse. Protein kinase A is involved in the regulation of metabolism of glycogen, lipids and sugars. Substrates of protein kinase A may be other protein kinases, as well as enzymes of intermediary metabolism. Protein kinase A is also involved in cAMP-stimulated transcription of genes that have a cAMP-responsive element in their control region (review Montminy, 1997). An increase in cAMP concentration leads to activation of protein kinase A which phosphorylates the transcription factor CREB at Ser 133. CREB only binds to the transcriptional coactivator CBP in the phosphorylated state and stimulates transcription (see Chapter 1.4.4.2). 

The multifimctional CaM kinases are collectively referred to as CaM kinases of type II, whereby further subtypes a, p, y and 6 are differentiated. The a and P subtypes of CaM kinase II only occur in the brain whereas the other subtypes are also found in other organs. The multifunctional CaM kinases regulate many processes (see Table 7.1) such as glycogen metabolism, activity of transcription factors, microfilament formation, synaptic release of neurotransmitters from storage vesicles, biosynthesis of neurotransmitters and many more. An important cellular function is assigned to CaM kinase II in brain, where it makes up 0.25 % of the total protein. 

The current state of Ser/Thr phosphorylation of a protein is determined by the relative activity of Ser/Thr-specific protein kinase and protein phosphatase. It is therefore imderstandable that the cell has had to develop special mechanisms to balance the two activities with one another, and, when needed, to allow kinase or phosphatase activity to dominate. One of the best investigated examples of coordinated activity of protein kinases and protein phosphatases is the regulation of glycogen metabolism in skeletal muscle. Glycogen metabolism is an example of how two different signals, namely a cAMP signal and a Ca signal meet in one metabolic pathway and control the activity of one and the same enzyme. 

Fig. 7.18. Regulation of glycogen metabolism in muscle. Phosphorylase kinase stands at the center of regulation of glycogen metabolism. Phosphorylase kinase may exist in an active, phosphorylated form and an inactive, unphosphorylated form. Phosphorylation of phosphorylase kinase is triggered by hormonal signals (e.g. adrenahne) and takes place via an activation of protein kinase A in the cAMP pathway. In the absence of hormonal stimulation, phosphorylase kinase can also be activated by an increase in cytosolic Ca. The active phosphorylase kinase stimulates glycogen degradation and inhibits glycogen synthesis, in that, on the one side, it activates glycogen phosphorylase by phosphorylation, and on the other side, it inactivates glycogen synthase by phosphorylation.

Renewed docking of the catalytic subunit requires the removal of the phosphate residue at the G subunit phosphorylated at the P2 site. This takes place via the protein phosphatases 2A and 2B (calcineurin). Thus, a cascade of protein phosphatases is involved in the regulation of dephosphorylation of key enzymes of glycogen degradation, whereby a phosphatase, namely protein phosphatase I, is indirectly activated by other protein phosphatases. With calcineurin, a Ca -dependent protein phosphatase is involved and thus it is possible to influence glycogen metabolism via Ca -mediated signals. 

New Chapter 15. Principles of Metabolic Regulation, Illustrated with Glucose and Glycogen Metabolism... 

---