Carbohydrate metabolism in fructose-fed and food-restricted running rats

In chronically catheterized rats hepatic glycogen was increased by fructose (approximately 10 g/kg) gavage (FF rats) or lowered by overnight food restriction (FR rats). [3-3H]- and [U-14C]glucose were infused before, during, and after treadmill running. During exercise the increase in glucose production (Ra) was always directly related to work intensity and faster than the increase in glucose disappearance, resulting in increased plasma glucose levels. At identical work-loads the increase in Ra and plasma glucose as well as liver glycogen breakdown were higher in FF and control (C) rats than in FR rats. Breakdown of muscle glycogen was less in FF than in C rats. Incorporation of [14C]glucose in glycogen at rest and mobilization of label during exercise partly explained that 14C estimates of carbohydrate metabolism disagreed with chemical measurements. In some muscles glycogen depletion was not accompanied by loss of 14C and 3H, indicating futile cycling of glucose. In FR rats a postexercise increase in liver glycogen was seen with 14C/3H similar to that of plasma glucose, indicating direct synthesis from glucose. In conclusion, in exercising rats the increase in glucose production is subjected to feedforward regulation and depends on the liver glycogen concentration. Endogenous glucose may be incorporated in glycogen in working muscle and may be used directly for liver glycogen synthesis rather than after conversion to trioses. Fructose ingestion may diminish muscular glycogen breakdown. The [14C]glucose infusion technique for determination of muscular glycogenolysis is of doubtful value in rats.     

Mechanical, biochemical, and morphological changes in the heart from chronic food-restricted rats

Food restriction (FR) has been shown to induce important morphological changes in rat myocardium. However, its influence on myocardial performance is not completely defined. We examined the effects of chronic FR on cardiac muscle function and morphology. Sixty-day-old Wistar-Kyoto rats were fed a control (C) or a restricted diet (daily intake reduced to 50% of the amount of food consumed by the control group) for 90 days. Myocardial performance was studied in isolated left ventricular (LV) papillary muscle. Fragments of the LV free wall were analysed by light microscopy, and the ultrastructure of the myocardium was examined in the LV papillary muscle. The myocardial collagen concentration was also evaluated. FR decreased body weight (BW) and LV weight (LVW); the LVW/BW ratio was higher in the restricted group (C, 1.86+/-0.17 mg/g; FR, 2.19+/-0.31 mg/g; p < 0.01). In the FR animals, the cardiac fibers were polymorphic, some of them were of small diameter and others presented lateral infoldings; the ultrastructural alterations were focal and included reduction of sarcoplasmic content, absence and (or) disorganization of myofilaments and Z line, numerous electron dense and polymorphic mitochondria, and deep infoldings of the plasma membrane. The hydroxyproline concentration was higher in the FR animals (p < 0.01). FR prolonged the contraction and relaxation time of the papillary muscle and did not change its ability to contract and shorten. In conclusion, although a 90-day period of FR caused striking myocardial ultrastructural alterations and increased the collagen concentration, it only minimally affected the mechanical function.     

Early undernutrition induces glucagon resistance and insulin hypersensitivity in the liver of suckling rats

Developing brains are vulnerable to nutritional insults. Early undernutrition alters their structure and neurochemistry, inducing long-term pathological effects whose causal pathways are not well defined. During suckling, the brain uses glucose and ketone bodies as substrates. Milk is a high-fat low-carbohydrate diet, and the liver must maintain high rates of gluconeogenesis and ketogenesis to address the needs of these substrates. Insulin and glucagon play major roles in this adaptation: throughout suckling, their blood concentrations are low and high, respectively, and the liver maintains low insulin sensitivity and increased glucagon responsiveness. We propose that disturbances in the endocrine profile and available plasma substrates along with undernutrition-related changes in brain cortex capacity for ketone utilization may cause further alterations in some brain functions. We explored this hypothesis in 10-day-old suckling rats whose mothers were severely food restricted from the 14th day of gestation. We measured the plasma/serum concentrations of glucose, ketone body, insulin and glucagon, and hepatic insulin and glucagon responses. Undernutrition led to hypoglycemia and hyperketonemia to 84% (P < 0.001) and 144% (P < 0.001) of control values, respectively. Liver responsiveness to insulin and glucagon became increased and reduced, respectively; intraperitoneal glucagon reduced liver glycogen by 90% (P < 0.01) in control and by 35% (P < 0.05) in restricted. Cortical enzymes of ketone utilization remained unchanged, but their carrier proteins were altered: monocarboxylate transporter (MCT) 1 increased: 73 ± 14, controls; 169 ± 20, undernourished (P < 0.01; densitometric units); MCT2 decreased: 103 ± 3, controls; 37 ± 4, undernourished (P < 0.001; densitometric units). All of these changes, coinciding with the brain growth spurt, may cause some harmful effects associated with early undernutrition.     

Effect of insulin and glucagon on superoxide dismutase degradation in the liver of irradiated rats

A study was made of the effect of insulin and glucagon on the time of functioning and degradation of superoxidedismutase in the liver of rats irradiated with a dose of 8 Gy. The hormones were shown to enhance the effect of radiation.     

Effects of glucagon and insulin on liver lysosomes

Recent experimental evidence has been obtained, principally in the laboratory of Glenn Mortimore, that hepatic lysosomes can act as a pool of amino acids during fasting. This pool is generated through $\text{autophagy}$, whereby intracellular proteins are somehow captured by the lysosomes and then rapidly hydrolyzed to free amino acids by the lysosomal proteinases. Two important metabolic fates of these lysosomal digestive products can be: 1) conversion of the glucogenic amino acids into glucose, and 2) conversion of trimethyl-lysine into carnitine. The latter metabolite is required to transfer fatty acids to the mitochondrial site of β-oxidation. Most interesting is the observation that glucagon appears to induce lysosomal autophagy and the resulting degradation of intracellular proteins by decreasing the size of amino acid pools in the perfused liver. This effect of the hormone may be directed at the single amino acid glutamine, since adding it alone to the perfusate can prevent the increase in autophagy caused by glucagon. Insulin also rapidly inactivates hepatic autophagy and its ensuing proteolysis. The $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ for the rate of los of autophagic vocuoles from the insulin-treated liver (or animal) is approximately 8 min. Thus, glucagon and insulin actively control intracellular protein catabolism that takes place within hepatic lysosomes, and this regulation by the two hormones may be one of their major molecular effects on gluconegenesis in the liver.     

Effects of epinephrine, glucagon and insulin on glucose metabolism of planaria

Epinephrine and insulin increased glucose uptake in Planaria, but epinephrine did so to a much grater extent. Glucagon proved to be without effect. The experiments support earlier results according to which in unicellular and invertebrate organisms membrane patterns can be found, which are similar to those of higher organisms and behave like receptors.     

Influence of the corticosterone rhythm on photic entrainment of locomotor activity in rats

The question of involvement of glucocorticoid hormones as temporal signals for the synchronization of the timekeeping system was addressed in rats with different corticosterone status. The authors showed that adrenalectomy had no effects on the synchronization of wheel-running activity rhythms to a steady-state LD 12:12 cycle, regardless of whether it was compensated for by a corticosterone replacement therapy that either reinstated constant plasma concentrations of the hormone or mimicked its natural rhythm. However, after a 12-h phase shift (daylight reversal), the lack of circulating corticosterone induced a significant shortening of the resynchronization rate (less than 3 days vs. 7 days). Normalization required restoration of a rhythmic corticosterone secretion that was synchronized to the new photoperiod. Under constant darkness, the corticosterone rhythm did not show any synchronizing effect, providing evidence that it participates in entrainment of the locomotor activity rhythm through modulation of light effects. It is proposed that, under stable lighting conditions, circulating glucocorticoids contribute to stabilizing activity rhythms by reinforcing resistance of the circadian timing system to variations of the photoperiod. Experimental evidence that serotonergic neurons are involved in relaying their modulatory effects to the clock is also presented.     

Arginine stimulated insulin and glucagon release from islets transplanted into the liver of diabetic rats

We investigated the ability of intraportal transplanted islets to release insulin and glucagon after stimulation with arginine. Furthermore, the islet volume and hormone content of the recipient pancreas were analyzed. Three months after syngeneic portal islet transplantation the liver of STZ-diabetic rats was perfused in vitro in the presence of different arginine concentrations. Transplanted islets preserve their functional integrity for at least three months indicated by a stimulus adequate insulin release and contribute substantially to the observed amelioration of the diabetic state. The islet and B-cell volume as well as the insulin and glucagon content of the recipient pancreas are still markedly decreased three months after islet transplantation when compared with healthy controls.     

Reciprocal changes of insulin and glucagon receptors in primary cultured hepatocytes

The specific [125I]insulin binding to primary cultured hepatocytes was significantly greater than that to freshly isolated hepatocytes. Low affinity insulin binding sites in cultured cells were 6-fold greater in number than those of freshly isolated cells without a significant change in high affinity sites. However, both sensitivity (insulin concentration for half maximum stimulation) and responsiveness (% of increase above the basal level) to insulin for the stimulation of ODC activity were similar for isolated and cultured cells indicating an important role of high affinity sites in the insulin action. On the other hand, the specific [125I]glucagon binding to cultured cells was significantly decreased. Low affinity glucagon binding sites in cultured cells decreased by about 50% in cultured cells without a significant change in high affinity sites. Both sensitivity and responsiveness to glucagon for the stimulation of ketogenesis from palmitate also decreased as compared with those of isolated cells, indicating an important role of low affinity sites in the glucagon action. These results indicate that insulin and glucagon receptors were reciprocally changed in cultured cells, as compared with isolated cells.     

Effect of insulin and glucagon on aldolase turnover in rat liver

The effects of exogenous and endogenous insulin and glucagon on aldolase turnover in rat liver and blood were studied. Some effects of these hormones on the biosynthesis and degradation of hepatic aldolase were specified. The rate of the "de novo" synthesis of aldolase was investigated in hepatocyte mitochondria and in blood plasma. The exogenous and endogenous hormones were shown to produce different effects on the biosynthesis and spontaneous degradation of rat liver aldolase.     

Some aspects of corticosterone metabolism in lithium treated rats

The effect of lithium administration on adrenal steroidogenesis has been studied in rats. An increase in plasma corticosterone (CS) levels was observed and this appears to be due to increased steroidogenesis. This effect on the adrenal is mediated via ACTH, suggesting an involvement of the pituitary adrenal axis.     

Role of insulin and glucagon in oxytocin effects on glucose metabolism.

Oxytocin (OT) infusion in normal dogs increases plasma insulin and glucagon levels and increases rates of glucose production and uptake. The purpose of this study was to determine whether the effects of OT on glucose metabolism were direct or indirect. The studies were carried out in normal, unanesthetized dogs in which OT infusion was superimposed on infusion of either somatostatin, which suppresses insulin and glucagon secretion, or clonidine, which suppresses insulin secretion only. Infusion of 0.2 microgram/kg/min of somatostatin suppressed basal levels of plasma insulin and glucagon and inhibited the OT-induced rise of these hormones by about 60-80% of that seen with OT alone. The rates of glucose production and uptake by tissues, measured with [6-3H] glucose, were significantly lower than those seen with OT alone, and the rise in glucose clearance was completely inhibited. Clonidine (30 micrograms/kg, sc), given along with an insulin infusion to replace basal levels of insulin, completely prevented the OT-induced rise in plasma insulin and markedly reduced the glucose uptake seen with OT alone, but did not reduce the usual increase in plasma glucose and glucagon levels or glucose production. To determine whether the OT-induced rise in plasma insulin was in response to the concomitant increase in plasma glucose, similar plasma glucose levels were established in normal dogs by a continuous infusion of glucose and an OT infusion was superimposed. OT did not raise plasma glucose levels further, but plasma insulin levels were increased, indicating that OT can stimulate insulin secretion independently of the plasma glucose changes. Studies by others have shown that the addition of OT to pancreatic islets or intact pancreas can stimulate insulin and glucagon secretion, indicating a direct effect. Our studies agree with that and suggest that in vivo, OT raises plasma insulin levels, at least in part, through a direct action on the pancreas. These studies also show that OT increases glucose production by increasing glucagon secretion and, in addition, a direct effect of OT on glucose production is likely. The OT-induced increase in glucose uptake is mediated largely by increased insulin secretion.     

The influence of restraint stress in rats on metallothionein production and corticosterone and glucagon secretion

Earlier studies on metallothionein (MT) induction by stress used a wide range of stimuli, all of them considered as physical stressors. The present paper reports the effect of a basically psychogenic stress such as restraint on serum and liver MT. Male adult rats were stressed for 1, 12, 24 and 48 hours and then killed. Liver MT increased continuously throughout the experimental period. Rats deprived of water and food for 24 and 48 hours showed higher liver MT levels than control but lower levels than stressed ones. Serum MT was not modified by either restraint or water and food deprivation. The lack of relationship between the two MT pools was corroborated by the absence of a significant correlation between them. Restraint stress increased serum corticosterone but not glucagon levels, suggesting that only glucocorticoids are important in MT induction by stress. However, a strong circadian rhythmicity was observed in serum corticosterone but not in serum or liver MT in non-stressed rats. In addition, preliminary data with adrenalectomized rats indicate that glucocorticoids seem not to be essential in MT induction by stress. Likewise glucagon does not appears to be associated with MT induction by stress since its levels were not modified by restraint.     

Perinatal changes in amylase and serum corticosterone levels in rats

In rats amylase activity in the pancreas increased greatly from day 15 of gestation to a maximum on day 21. Then it decreased to less than one-tenth of this maximum value on about day 5 after birth. It increased again about 15 days after birth and reached the adult level about 30 days after birth.No amylase activity was in the parotid gland before birth: it appeared about 12 days after birth and reached the adult level, which was higher than that in the pancreas, about 30 days after birth.The serum corticosterone level was as high as the adult level before birth. Then it decreased to less than one-tenth of the adult level 5 days after birth and increased again from 15 to 25 days after birth to the adult level. The developmental change in the serum corticosterone level seemed to influence amylase activity in the pancreas both before and after birth, and that in the parotid gland only after birth.The serum contained both pancreatic and paratoid type isozymes of amylase until 1 day after birth but only the parotid type from 3 days after birth.