Muscle glucose 1-phosphate kinase

Figure 18-7. Control of glycogen synthase in muscle (n = number of glucose residues). The sequence of reactions arranged in a cascade causes amplification at each step, allowing only nanomole quantities of hormone to cause major changes in glycogen concentration. (GSK, glycogen synthase kinase-3, -4, and -5 G6P, glucose 6-phosphate.)...

The yeast enzyme is a homodimer of Mr2 X 102 500 and has 49% sequence identity to the muscle enzyme. The yeast enzyme is more simply regulated feedback inhibition by the allosteric inhibitor glucose-6-phosphate and activation by a 3 -5 -cyclic AMP-dependent protein kinase or a yeast phosphorylase that phosphorylates Thr-10.55... 

Simulation of glucose transport and glucose transporter translocation from intracellular stores to the plasma membrane in muscle cells by vanadate and peroxovan-adate involve a mechanism independent of PI-3K and protein kinase C systems utilized for stimulation of these processes by insulin. The transport of GLUT4 to the plasma membrane in muscle cells growing in culture after stimulation by vanadate, peroxovanadate, or insulin all require an intact actin network [138], Sometimes, the insulin-like action of vanadium is accompanied by overall stimulation of actual metabolic pathways. One example of this is the stimulation of the pentose phosphate pathway observed when vanadate promotes the incorporation of glucose into lipids, an antilipogenic effect [139],... 

In muscle and adipose tissue, insulin promotes transport of glucose and other monosaccharides across cell membranes it al.so facilitates tran.sport of amino icids, potassium ion.s. nucleosides, and ionic phosphate. Insulin also activates certain enzymes—kinases and glycogen. synthetase in muscle und adipose tissue. In adipose tissue, insulin decreases the release of fatty acids induced by epinephrine or glucagon. cAMP promotes fatty acid release from adipose ti.ssue therefore. it is pos.sible that insulin decreases fatty acid release by reducing tissue levels of cAMP. Insulin also facilitates the incorporation of intracellular amino acids into protein. 

Figure 16.17 Regulation of glycolysis in muscle. At rest (left), glycolysis is not very active (thin arrows). The high concentration of ATP inhibits phosphofructokinase (PFK), pyruvate kinase, and hexokinase. Glucose 6-phosphate is converted into glycogen (Chapter 21). During exercise (right), the decrease in the ATP/AMP ratio resulting from muscle contraction activates phosphofructokinase and hence glycolysis. The flux down the pathway is increased, as represented by the thick arrows.

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