Metabolism of 3H- and 14C-labeled glutamate, proline, and alanine in normal and adrenalectomized rats using different sites of tracer administration and sampling.

Alanine, glutamate and proline labeled with 14C and 3H were infused into fasted normal and adrenalectomized rats. Alanine was administered by the A-V mode (arterial administration-venous sampling), and glutamate and proline by both the A-V and V-A (venous administration-arterial sampling) modes. The kinetics of 14C alanine and 14C glutamate differed markedly from those of the tritium-labeled compounds, but there was little difference in the kinetics of 3H and 14C proline. The replacement rate calculated from the A-V mode for glutamate was about half that obtained in the V-A mode, but there was little difference with proline. The masses of the amino acids (total content of amino acids in the body) were calculated from the washout curves of the tritium-labeled compounds after the infusion of tracer was terminated. The masses for the normal rats were 407 mumol/kg for alanine, 578 mumol/kg for glutamate and 296 mumol/kg for proline. The so-called distribution spaces calculated conventionally from total masses and the amino acid concentrations in plasma are much greater than the volume of the body, reflecting the fact that amino acid concentrations in tissues greatly exceed those in plasma. Adrenalectomy markedly affected the kinetics of the three amino acids, and their replacement rates were greatly reduced. The proline and glutamate masses were reduced by at least one half, while that of alanine was unchanged. Adrenalectomy markedly reduced the conversion of proline to glutamate. The hydrocortisone regimen used in this study restored the metabolism of alanine and glutamate to normal, but had no effect on that of proline.

Inhalation anesthetics.

The inhalation anesthetics affect operating room personnel as well as the patient. This occupational exposure is similar in all respects to industrial solvent exposures. Although the extent of the hazard is not yet established, it is clear that only quite low levels of these active chemical should be allowed in the operating room air.

Abuse of inhalation anesthetic drugs.

Abuse of inhalational drugs used to produce anesthesia has progressed pari passu with their evolvement and may exist far into the future. It occurs among both professional and lay people and is fraught with toxicological and sociological hazard in excess of many other forms of substance abuse.

Fructose-6-phosphate substrate cycling and glucose and insulin regulation of gluconeogenesis in vivo.

The question whether glucose or insulin regulates gluconeogenesis by effecting changes in the fructose-6-phosphate (F-6-P) substrate cycle (phosphofructokinase (PFK), fructose-1,6-diphosphatase (FDPase)) was investigated in vivo in fasted normal rats using [3-3H,U-14C]- or [3-3H,6-14C]glucose. The plasma glucose 3H/14C ratio was used as an index of substrate cycling because 3H loss from the liver hexose phosphate pool is limited by the activities of PFK and FDPase during gluconeogenesis and glycolysis, respectively. The 3H/14C ratio was corrected where necessary for glucose or insulin-induced changes in reincorporation of 14C from C-6 to C-1-3 of plasma glucose. A glucose infusion producing hyperglycemia and insulinemia was accompanied by decreased hepatic glucose production and diminished F-6-P substrate cycling, i.e., decreased FDPase activity. When insulin was infused along with glucose to produce high plasma insulin levels and avoid hypo- or hyperglycemia, the 3H/14C decay rate did not change, suggesting that the hormone does not influence basal rates of gluconeogenesis or PFK or FDPase activities. These in vivo results suggest that increased blood glucose levels inhibit gluconeogenesis and depress F-6-P substrate cycling. Whether these cycle changes constitute primary regulatory actions of glucose or occur secondarily to other metabolic events resulting from excess hexose (e.g., increased glycogen synthetase activity) cannot now be concluded.

Fructose-6-phosphate substrate cycling and hormonal regulation of gluconeogenesis in vivo.

The possible role of the hepatic fructose-6-phosphate substrate cycle (phosphofructokinase, fructose-1,6-diphosphatase) in the rapid hormonal regulation of gluconeogenesis was investigated in vivo in fasted normal and adrenalectomized rats after administration of [3-3H, U-14C]- or [3-3H, 6-14C]glucose. The plasma glucose 3H/14C ratio was used as an index of substrate cycling because the amount of 3H loss from liver hexose phosphates is determined by the extent of cycling. PFK and FDPase activities limit 3H loss during gluconeogenesis and glycolysis, respectively. Glucagon-stimulated hepatic glucose production is always accompanied by increased substrate cycling, i.e., increased FDPase and PFK activities. The high PFK activity may be a secondary event due possibly to elevated cellular fructose-6-phosphate levels. Decreased substrate cycling, i.e., lowered FDPase activity, always accompanies the depressed hepatic glucose production that occurs during hyperglycemia. Glucagon has no effect on substrate cycling in adrenalectomized rats that are insensitive to the hormone. The in vivo experiments presented provide evidence, although indirect, that glucagon administration results in changes in the fructose-6-phosphate substrate cycle in a living animal. Whether these changes are primary regulatory events or occur secondarily to hormone actions elsewhere is not known.

Use of 3H and 14C doubly labeled glucose and amino acids in the study of hormonal regulation of gluconeogenesis in rats.

Double isotope procedures (3H and 14C) were used in vivo to investigate a) slow long-term gluconeogenic actions of adrenal glucocorticoids, and b) rapid stimulation of gluconeogenesis by glucagon. [U-14C,6-3H]Glucose was administered to normal and adrenalectomized rats. No effect was observed on the [6-3H]glucose half-life suggesting the dicarboxylic acid shuttle is unaffected by adrenalectomy; the Cori cycle is also not influenced. Loads of [14C]aspartate, [14C]glutamate, or [14C]alanine were given to normal and adrenalectomized rats. Simultaneously, in vivo transaminase activity was studied by measuring the appearance of 3H2O in body water after administration of [2-3H]aspartate, [2-3H]glutamate, or [2-3H]alanine, Adrenalectomy has no influence on the incorporation of glutamate or aspartate into glucose or on their in vivo transaminases. Diminution of incorporation of [14C]alanine into glucose and alanine transaminase activities occurs only when rats are given unphysiological loads. These studies support the contention that glucocorticoid rate-limiting actions occur in extrahepatic tissues to produce an increased flow of glucose precursors to the liver. [U-14C,3-3H]Glucose was used to investigate the effect of glucagon on the hepatic fructose-6-phosphate (F-6-P) cycle. Glucagon administration resulted in a rapid drop in the 3H/14C ratio of circulating glucose, suggesting an increase in F-6-P recycling caused by activation of FDPase with little or no decrease in phosphofructokinase. Such a change would direct substrate flux toward gluconeogenesis.

Glucose turnover in kelp bass (Paralabrax sp.): in vivo studies with [6-3H,6-14C]glucose.

[6-3H,6-14C]glucose was injected via an indwelling arterial cannula in free-swimming, fed, and fasted kelp bass to determine hepatic glucose production, peripheral glucose uptake, minimal glucose mass, mean transit time, and the percent of carbon recycling under the two different nutritional states. Mean plasma glucose levels remained unchanged in fed and fasted fish (48+/-8 vs. 43+/-8 mg/100 ml). During steady-state conditions, glucose replacement rates of fed and fasted fish determined with [6-3H]glucose are similar (0.035+/-0.006 vs. 0.025+/-0.003 mg/min per 100 g) and do not differ from rates determined with [6-14C]glucose (0.035+/-0.005 vs. 0.026+/-0.002). The minimal glucose masses and the mean transit tim-s determined with both isotopes are also similar suggesting that plasma glucose levels and glucose turnover are maintained in fish fasted up to 40 days with no apparent increase in carbon recycling. Nonsteady-state isotope experiments suggest that these fish can alter rates of hepatic glucose production and peripheral uptake in response to hyper- and hypoglycemia.

Amino acid gluconeogenesis and glucose turnover in kelp bass (Paralabrax sp.).

The glucose replacement rate, plasma glucose concentration, glucose body mass, and amino acid gluconeogenesis were determined in vivo in fed and fasted kelp bass (Paralabrax clathratus) using [6-3H]glucose administered with [U-14C]glutamate, [U-14C]aspartate, or [U-14C]alanine. Fasting (14 days) and prolonged starvation (72 days) do not produce changes in the replacement rate, body mass, or plasma concentration of glucose. The removal of amino acids from the circulation is rapid in both fed and fasting states with nearly 50% of the administered 14Ctracer disappearing by 5 min. The incorporation of [14C]amino acid carbon into the body glucose mass is also rapid with significant amounts of tracer appearing within 15 min after administration. Gluconeogenesis from alanine and glutamate is increased by fasting whereas that from aspartate is diminished. The gluconeogenic rate is comparable to that previously observed in rats (Dunn, A., M. Chenoweth, and J. G. Hemington. The relationship of adrenal glucocorticoids to transaminase activity and gluconeogenesis in the intact rat. Biochim. Biophys. Acta 237: 192-202, 1971), although the glucose replacement rate is significantly lower. We propose that the paradoxically high rate of gluconeogenesis in fish may serve to provide carbohydrate precursors for mucus synthesis in these carnivorous animals with limited carbohydrate intake.