Two substrains of the epithelial liver cell line C1I, one storing large amounts of glycogen, the other one being very poor in glycogen were used as a model for studying glycogen synthesis. The glycogen content of glycogen-rich cells doubled during the proliferative phase and remained high in plateau phase although glycogen synthase I activity was not significantly altered during growth cycle and was too low to account for the increase in glycogen. However, the activity of the glucose 6-phosphate (Glc6-P)-dependent synthase rose continuously during growth cycle, and intracellular Glc6-P-concentration increased about 10-fold in log phase cells to 0.72 mumol g-1 wet weight. A0.5 of synthase for Glc6-P was 0.79 mM. It was also found that in contrast to the enzyme from normal liver, glycogen phosphorylase a from C1I cells was inhibited by Glc6-P, the apparent Ki being 0.45 mM. It was concluded that glycogen accumulation in C1I cells was due to stimulation of synthase and inhibition of phosphorylase by Glc6-P. Findings from the glycogen-poor cell line which revealed similar specific activities of synthase and phosphorylase but only low Glc6-P (0.056 mumol g-1 wet weight) supported this conclusion. Addition of glucose to starved cells resulted in a transient activation of synthase in both cell lines. Net glycogen synthesis, was, however, only observed in the cells with a high Glc6-P-content. Thus, modulation of synthase and phosphorylase by Glc6-P and not activation/inactivation of the enzymes seems to play a predominant role in glycogen accumulation in this cell line.
Long-term dietary administration of the adrenal hormone dehydroepiandrosterone (DHEA) to male Sprague-Dawley rats induced significant alterations in the activities of enzymes involved in liver carbohydrate metabolism. Although glycogen synthase activity was increased and phosphorylase decreased, glycogen stores were reduced. This was presumably related to lysosomal glycogen degradation, since alpha-glucosidase was increased. All rate-limiting enzymes of glucose metabolism which were studied (glucose-6-phosphate dehydrogenase, total hexokinases, pyruvate kinase, fructose-1,6-bisphosphatase) revealed markedly reduced activity, only glucose-6-phosphatase activity was increased. These enzymatic changes point to a far-reaching metabolic shift towards energy loss via decreased glucose consumption and increased glucose output. The enzyme pattern induced by DHEA is in many respects opposite to that induced in preneoplastic and neoplastic liver lesions by chemical hepatocarcinogens.
Glycogen phosphorylase isoenzymes were isolated from normal rat liver, rat brain, the glycogen-poor Morris hepatoma (MH) 3924A, and the glycogen-rich non-tumorigenic liver cell line C1I. Electrophoretic and immunological characterization of the enzymes showed that tumour and C1I cells expressed a phosphorylase isoform similar to the brain type; the liver type was not detectable. All enzymes were obtained as dimers; the Mr of the subunits was 96000 (liver), 93000 (brain and MH 3924A) and 92000 (C1I). Isoelectric focusing revealed a main band of pI 6.34 for liver phosphorylase a, pl 5.67 for the enzymes from MH 3924A and brain, and pI 5.68 for CII phosphorylase. Partial kinetic characterization of the AMP-independent forms of the isoenzymes yielded Km values for glucose 1-phosphate of 3.5 + 0.5 mm (liver), 3.9 mm (brain), 1.9 + 0.3 mm (MH 3924A) and 2.5 + 0.5 mm (C1I); Km values for glycogen were 0.4 mM (liver) and 0.3 mm (MH 3924A and C1I), calculated as glucose equivalents. The AMP-independent phosphorylase was inhibited by glucose 6-phosphate (Glc6P) with Ki values of 0.32 + 0.03 mm (C1I), 0.50 + 0.04 mm (MH 3924A) and -5 mM (brain). The inhibition could be abolished by 1 mM-AMP, indicating that AMP and Glc6P may partially compete for the same site on the protein. Liver phosphorylase a was not inhibited by up to 25 mM-Glc6P. In contrast with liver and brain isoenzymes, phosphorylase from the cell lines was not affected by NaF and Na2SO4. The data show that both the hepatocellular carcinoma and the non-malignant immortalized liver cells express a phosphorylase isoform different from the liver type. Furthermore, there is some evidence that the enzyme from MH 3924A and C1I cells is distinct from brain phosphorylase a, in spite of electrophoretic and immunological resemblance, and that this isoenzyme is subject to altered metabolic regulation.
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