Development of diabetes mellitus in the progeny of 6 generations of female rats with alloxan diabetes

The development of diabetes mellitus has been studied in six progeny generations of female Wistar rats with alloxan diabetes coupled with normal males. An increased incidence of diabetes and its higher degree have been observed in younger generations studied. A correlation has been established between the frequency of diabetic type of glucose tolerance and hypoglycemia in rats of the first generation during the first month of their postnatal life, and the incidence of diabetes in the progeny of mother rats from the older generations.     

Gluconeogenesis from glycine and serine in fasted normal and diabetic rats.

1. Non-anaesthetized normal and diabetic rats were fasted for 1 day, and [U-14C]glycine, or [U-14C]serine, or [U-14C]- plus [3-3H]-glucose was injected intra-arterially. The rates of synthesis de novo/irreversible disposal for glycine, serine and glucose, as well as the contribution of carbon atoms by the amino acids to plasma glucose, were calculated from the integrals of the specific-radioactivity-versus-time curves in plasma. 2. The concentrations of both glycine and serine in blood plasma were lower in diabetic than in fasted normal animals. 3. The rates of synthesis de novo/irreversible disposal of both amino acids tended to be lower in diabetic animals, but the decrease was statistically significant only for serine (14.3 compared with 10.5 mumol/min per kg). 4. Of the carbon atoms of plasma glucose, 2.9% arose from glycine in both fasted normal and diabetic rats, whereas 4.46% of glucose carbon originated from serine in fasted normal and 6.77% in diabetic rats. 5. As judged by their specific radioactivities, plasma serine and glycine exchange carbon atoms rapidly and extensively. 6. It was concluded that the turnover of glycine remains essentially unchanged, whereas that of serine is decreased in diabetic as compared with fasted normal rats. The plasma concentration of both amino acids was lower in diabetic rats. Both glycine and serine are glucogenic. In diabetic rats the contribution of carbon atoms from glycine to glucose increases in direct proportion to the increased glucose turnover, whereas the contribution by serine becomes also proportionally higher.     

Changes in somatotropic and lactotropic functions of the adenohypophysis of rats with acute alloxan diabetes

Increased growth hormone and prolactin contents of the rat adenohypophysis during the development of experimental diabetes were found by colorimetric studies of stained electrophoregrams. 4 to 5 days after alloxan administration the levels of somatotropic hormone (STH) and prolactin were higher in comparison to those in intact animals by 58% and 43%, respectively. Experiments on the primary cell culture using the precursor 14C-L-leucine revealed an enhanced secretion of somatotropic hormone and prolactin by cells of the rats with alloxan diabetes. A possible role of the adenohypophyseal changes in the development of experimental diabetes is discussed.     

Effect of NAD and ADP on glycolysis in the kidneys and liver of rats during ischemia

Experiments on albino rats have shown that kidney ischemia and its simulation by the anaerobic incubation of postmitochondrial kidney homogenate fraction without a substrate induce a considerable damage of the glycolytic system at the stage of the glucoso-6-phosphate transformation into fructoso-1.6-diphosphate and a less pronounced damage in the fructoso-1.6-diphosphate transformation into lactate. Administration of adenosine diphosphate (ADP) and nicotinamide adenine dinucleotide (NAD) to rats before kidney vessel occlusion or their addition to the postmitochondrial fraction before the anaerobic incubation without a substrate decreased a degree of the glycolytic system damage. The damage of the glycolytic system and protective action of NAD are also detected under simulation of liver ischemia. Possible mechanisms of the ischemic damage in the glycolytic liver and kidney tissue system are discussed.     

Gluconeogenesis in the liver of arthritic rats

The gluconeogenic response in the liver from rats with chronic arthritis to various substrates and the effects of glucagon were investigated. The experimental technique used was the isolated liver perfusion. Hepatic gluconeogenesis in arthritic rats was generally lower than in normal rats. The difference between normal and arthritic rats depended on the gluconeogenic substrate. In the absence of glucagon the following sequence of decreasing differences was found: alanine (-71.8 per cent) reverse similarglutamine (-71.7 per cent)>pyruvate (-60 per cent)>lactate+pyruvate (-44.9 per cent)>xylitol (n.s.=non-significant) reverse similarglycerol (n.s.). For most substrates glucagon increased hepatic gluconeogenesis in both normal and arthritic rats. The difference between normal and arthritic rats, however, tended to diminish, as revealed by the data of the following sequence: alanine (-48.9 per cent) reverse similarpyruvate (-47.6 per cent)>glutamine (-33.8 per cent)>glycerol (n.s.) reverse similarlactate+pyruvate (n.s.) reverse similarxylitol (n.s.). The causes for the reduced hepatic gluconeogenesis in arthritic rats are probably related to: (a) lower activities of key enzymes catalyzing most probably steps preceding phosphoenolpyruvate (e.g. phosphoenolpyruvate carboxykinase, pyruvate carboxylase, etc. ); (b) a reduced availability of reducing equivalents in the cytosol; (c) specific differences in the situations induced by hormones or by the individual substrates. Since glycaemia is almost normal in chronically arthritic rats, it seems that lower gluconeogenesis is actually adapted to the specific needs of these animals.