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.
The steady-state kinetics and distribution of glucose were assessed using noncompartmental and various two-compartment models in rats that were infused with insulin (+/- euglycemic clamping), methylprednisolone (MP), or phlorizin (PHL) as well as rats injected with protamine-zinc-insulin (PZI) or rendered diabetic. Decreases in clearance of glucose (PCR) were greatest with insulin infusion, followed by PHL, MP, and PZI treatments. PCR decreased in diabetes to 25% of normal. With hyperinsulinemia and euglycemia, turnover rates were 1.18 times the rate of glucose infusion. In normal rats the ratio of the contents of the two compartments was 0.6-0.8 (depending on the model). Significant increases, of between 2.8 and 5.2, were observed with insulin infusion and between 0.8 and 1.8 with PHL, again depending on the model. Because PHL-induced changes in PCR are renal, these data suggest that variations in glucose distribution depend on changes in PCR as well as insulin. The intercompartmental rate constant decreased, and the noncompartmental volume of distribution increased to reflect the above changes. In non-steady-state studies, glucose release increased in response to insulin but not to PHL in contrast to other species.
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