Decreased basal, noninsulin-stimulated glucose uptake and metabolism by skeletal soleus muscle isolated from obese-hyperglycemic (ob/ob) mice.

Insulin resistance of diaphragms of ob/ob mice has been repeatedly demonstrated previously both in vitro and in vivo. In the present study, transport and metabolism of glucose with and without insulin stimulation were compared in a skeletal muscle more likely than diaphragm or heart to be representative of the overall striated muscle mass, i.e. isolated soleus muscle. Compared with soleus muscle from lean controls, unstimulated lactate release in the presence of exogenous glucose was depressed from 16.2 to 12.3 nmol/60 min per mg wet wt in soleus from ob/ob mutants; glycolysis was decreased from 6.6 to 3.7 and [14C]glucose oxidation to 14CO2 from 0.90 to 0.33 nmol glucose/60 min per mg wet wt. Uptake of 2-deoxyglucose (2-DOG), both with and without insulin, was very much less for soleus from ob/ob than from lean mice, at 2-DOG concentrations ranging from 0.1 to 10 mM, and in mice of 6-15 wk. When 2-DOG concentration was 1 mM, its basal uptake was 0.53 nmol/30 min per mg wet wt for soleus of ob/ob as against 0.96 for soleus of lean mice. The absolute increment due to 1 mU/ml insulin was 0.49 in muscle of ob/ob as against 1.21 in that of lean mice. When the resistance to insulin action was decreased by pretreatment in vivo by either streptozotocin injection or fasting, the decreased basal 2-DOG uptake of subsequently isolated soleus muscle was not improved. Inhibition of endogenous oxidation of fatty acids by 2-bromostearate, while greatly increasing 14CO2 production from [14C]glucose, did not affect basal [5-3H]glucose metabolism or 2-DOG uptake. It is suggested that transport and/or phosphorylation of glucose under basal, unstimulated conditions are depressed in soleus muscle of ob/ob mice, whether or not resistance to insulin and hyperinsulinemia are also present. Although the origin of the decreased basal glucose uptake remains unknown it might be related to a similar decrease in basal glucose uptake by ventromedial hypothalamic cells, an event presumably resulting in a tendency to hyperphagia. Decreased basal glucose uptake by soleus muscle of ob/ob mice might explain the hyperglycemia, and hence partly the hyperinsulinemia and excessive fat deposition of those animals.

Fuels, hormones, and liver metabolism at term and during the early postnatal period in the rat.

The metabolic response to the first fast experienced by all mammals has been studied in the newborn rat. Levels of fuels and hormones have been compared in the fetal and maternal circulations at term. Then, after cesarean section just before the normal time of birth, sequential changes in the same parameters were quantified during the first 16 h of the neonatal period. No caloric intake was permitted, and the newborns were maintained at 37 degrees C. Activities of three key hepatic enzymes involved in glucose production were estimated. Marked differences in maternal and fetal hormones and fuels were observed. Lower levels of glucose, free fatty acids, and glycerol but higher levels of lactate, alpha-amino nitrogen, alanine, and glutamine were present in the fetus. Pyruvate, glutamate, and ketone bodies were not significantly different. The combination of a strikingly higher fetal immunoreactive insulin and a slightly lower immunoreactive glucagon (pancreatic) resulted in a profound elevation in the insulin-to-glucagon ratio, a finding consistent with an organism in an anabolic state. The rat at birth presents a body composition with respect to fuels available for mobilization and conversion which is dominated by carbohydrate and protein, since little fat is present. However, at birth a transient period of hypoglycemia occurred, associated with a rapid fall in insulin and rise in glucagon, causing reversal of the insulin-to-glucagon relationship toward ratios such as were observed in the mother. After a lag period, hepatic activities of phosphorylase, glucose-6-phosphatase, and phosphoenolpyruvate carboxykinase increased. Concurrent with these enzyme changes, the blood glucose returned to levels at or above those of the fetus. Interestingly, the fall observed in levels of the gluconeogenic precursors, lactate and amino acids, preceded the rise in enzyme activities and restoration of blood glucose. After 4 h, however, hypoglycemia recurred, during a period of decreasing hepatic glycogen content and blood lactate, pyruvate, and glycerol levels but of stable or increasing amino acid concentrations. Hepatic gluconeogenesis in this phase of depleted glycogen stores was insufficient to maintain euglycemia. Substrates derived from fat showed early changes of smaller magnitude. The rise in free fatty acids which occurred was less than twofold the value at birth, though this rise persisted up to 6 h. Whereas glycerol rose transiently, acetoacetate did not change and beta-hydroxybutyrate concentration fell. Both ketone bodies showed a marked rise at 16 h. at a time of diminished free fatty acid levels. Plasma growth hormone, though higher in the fetal than the maternal circulation, showed no consistent change during the period of observation. The changes in levels of the endocrine pancreatic hormones at birth were appropriate in time, magnitude, and direction to be implicated as prime regulators of the metabolic response during the neonatal period in the rat.

Studies on the dual effects of glucose on 45Ca++ efflux from isolated rat islets.

45Ca++ efflux studies were performed on rat islets of Langerhans which were loaded to isotopic equilibrium during 48 h in tissue cultures. 45Ca++ loading was 50% complete at 1 h, 80% at 4 h, and reached, at equilibrium, a content equal to 10-11 pmol/islet. The islets responded to glucose stimulation with a rapid and markedly biphase insulin release. Under normal conditions, glucose stimulated 45Ca++ efflux with an initial surge (simultaneous with the first peak of insulin release), which declined rapidly to 50% of the peak value and then slowly declined for the remainder of the glucose stimulation. Special conditions were required to uncover an early inhibition of 45Ca++ efflux; these were the lowering of the temperature of the perifusate from 37 C to 30 C or below, or reduction of the medium Ca++ concentration to 0.1 mM or less. Under zero calcium conditions the glucose inhibition of 45Ca++ efflux can be rigorously interpreted as an inhibition of calcium efflux. The studies at low temperature or low Ca++ concentrations revealed two effects of glucose on 45Ca++ efflux: an initial inhibition followed by a stimulation, the inhibitory effect was obscured by the rapidity of onset of the stimulatory effect under normal conditions. At low temperature it was also possible to inhibit glucose-stimulated insulin release, although the stimulated 45Ca++ efflux remained unchanged. At 30 C or in experiments with 0.3 mM Ca++, glucose-stimulated insulin release preceded the stimulation of 45Ca++ efflux. It therefore, is, concluded that the stimulated 45Ca++ efflux is a consequence, rather than a determinant, of stimulus-secretion coupling. The stimulated efflux is dependent on the presence of Ca++ in the medium and is independent of emiocytosis. This latter finding excludes the secretory granules as a significant source of glucose-stimulated 45Ca++ extrusion.

Hormone-substrate responses to total fasting in lean and obese mice.

The hormone-substrate milieu has been investigated in male fasted lean (C57BL/6-+/+) mice and mutant obese mice of the same strain (C57BL/6-obob). The lean mouse, in winter, mobilized insufficient fat (due to inadequate stores) to permit survival beyong 3 days and was unable to achieve any degree of conservation of vital protein stores. By contrast, in summer, the same animals survived 7 days and showed evidence of greater and more sustained fat mobilization and ketosis and the ability to conserve protein. The insulin, glucagon, and insulin/glucagon molar ratios changed in both groups in a direction consistent with conversion to a catabolic state, and hence were probably largely responsible for the mobilization of substrates and stimulation of gluconeogenesis and ketogenesis. The seasonal difference in response is unexplained. The obob mice, generally employed as a model for obesity, hyperglycemia, and hyperinsulinemia showed these features but also adapted to fasting in a fashion permitting prolonged survival during this state. In a fashion analogous to that known to occur in man, these animals developed fall in glycemia, rise in circulating fat-derived substrates, and marked protein conservation. Profound fall in insulinemia was associated with a fall in glucagonemia, the latter from normal levels. Thus the initial markedly "anabolic" insulin/glucagon molar ratio diminished, but nevertheless remained higher than at any time in the lean mice. Pancreatic contents of insulin showed markedly different changes with fasting in obob compared with lean mice. The ability of the obese mouse to adapt to prolonged fasting in a fashion largely analogous to that of man renders it a useful model for the study of metabolism in this state, with the potential of applicability of findings to man.