John E. Gerich

Lack of glucagon response to hypoglycemia in diabetes: evidence for an intrinsic pancreatic alpha cell defect

Despite excessive glucagon responses to infusion of arginine, plasma glucagon did not rise in six juvenile-type diabetics during severe insulin-induced hypoglycemia, whereas glucagon in the controls rose significantly. Thus in diabetics pancreatic alpha cells are insensitive to glucose even in the presence of large amounts of circulating insulin. An intrinsic defect common to both alpha and beta pancreatic cells—failure to recognize (or respond to) plasma glucose fluctuations—may be operative in juvenile diabetes.

Effects of physiologic levels of glucagon and growth hormone on human carbohydrate and lipid metabolism. Studies involving administration of exogenous hormone during suppression of endogenous hormone secretion with somatostatin.

To study the individual effects of glucagon and growth hormone on human carbohydrate and lipid metabolism, endogenous secretion of both hormones was simultaneously suppressed with somatostatin and physiologic circulating levels of one or the other hormone were reproduced by exogenous infusion. The interaction of these hormones with insulin was evaluated by performing these studies in juvenile-onset, insulin-deficient diabetic subjects both during infusion of insulin and after its withdrawal. Infusion of glucagon (1 ng/kg-min) during suppression of its endogenous secretion with somatostatin produced circulating hormone levels of approximately 200 pg/ml. When glucagon was infused along with insulin, plasma glucose levels rose from 94 +/- 8 to 126 +/- 12 mg/100 ml over 1 h (P less than 0.01); growth hormone, beta-hydroxy-butyrate, alanine, FFA, and glycerol levels did not change. When insulin was withdrawn, plasma glucose, beta-hydroxybutyrate, FFA, and glycerol all rose to higher levels (P less than 0.01) than those observed under similar conditions when somatostatin alone had been infused to suppress glucagon secretion. Thus, under appropriate conditions, physiologic levels of glucagon can stimulate lipolysis and cause hyperketonemia and hyperglycemia in man; insulin antagonizes the lipolytic and ketogenic effects of glucagon more effectively than the hyperglycemic effect. Infusion of growth hormone (1 mug/kg-h) during suppression of its endogenous secretion with somastostatin produced circulating hormone levels of approximately 6 ng/ml. When growth hormone was administered along with insulin, no effects were observed. After insulin was withdrawn, plasma beta-hydroxybutyrate, glycerol, and FFA all rose to higher levels (P less than 0.01) than those observed during infusion of somatostatin alone when growth hormone secretion was suppressed; no difference in plasma glucose, alanine, and glucagon levels was evident. Thus, under appropriate conditions, physiologic levels of growth hormone can augment lipolysis and ketonemia in man, but these actions are ordinarily not apparent in the presence of physiologic levels of insulin.

Evidence for a physiologic role of pancreatic glucagon in human glucose homeostasis: Studies with somatostatin☆

To study the role of glucagon in human glucose homeostasis, experimental glucagon deficiency was produced by infusing somatostatin (i. v. 250 mug bolus, followed by infusion of 500 mug/hr) in six normal subjects and in two hypophysectomized patients-an insulin-dependent diabetic and a nondiabetic. In normal subjects, somatostatin lowered plasma glucagon from a mean (plus or minus SE) basal level of 85 plus or minus 15 to 33 plus or minus 10 pg/ml, p smaller than 0.001. Concurrently, plasma glucose fell from 90 plus or minus 2 to 73 plus or minus 3 mg/100 ml, p smaller than 0.001. Serum insulin and growth hormone fell slightly during somatostatin infusion, while plasma free fatty acids rose. In both hypophysectomized patients, somatostatin lowered plasma glucagon and glucose levels. In all subjects, after stopping somatostatin infusions, plasma glucagon and glucose returned promptly to control values, while serum growth hormone did not change. In additional in vitro studies, somatostatin (1 mug/ml) had no effect on muscle glucose uptake. Since it is known that somatostatin has no direct effect on hepatic glucose production, these results suggest that the fall in plasma glucose during somatostatin infusion resulted from inhibition of glucagon secretion, thus providing evidence that this hormone plays a physiologic role in the maintenance of fasting euglycemia in man.

Effects of Alterations of Plasma Free Fatty Acid Levels on Pancreatic Glucagon Secretion in Man

The present investigation was undertaken to ascertain whether alterations in plasma free fatty acids (FFA) affect pancreatic glucagon secretion in man since FFA have been reported to influence pancreatic alpha cell function in other species. Elevation of plasma FFA from a mean (+/-SE) basal level of 0.478+/-0.036 mM to 0.712+/-0.055 mM after heparin administration caused plasma glucagon levels to fall approximately 50%, from a basal value of 122+/-15 pg/ml to 59+/-14 pg/ml (P < 0.001). Lowering of plasma FFA from a basal level of 0.520+/-0.046 mM to 0.252+/-0.041 mM after nicotinic acid administration raised plasma glucagon from a basal level of 113+/-18 pg/ml to 168+/-12 pg/ml (P < 0.005). Infusion of glucose elevated plasma glucose levels to the same degree that heparin raised plasma FFA levels. This resulted in suppression of plasma glucagon despite the fact that plasma FFA levels also were suppressed. Glucagon responses to arginine were diminished after elevation of plasma FFA (P < 0.01) and during infusion of glucose (P < 0.01). Diminution of plasma FFA by nicotinic acid did not augment glucagon responses to arginine. These results thus demonstrate that rather small alterations in plasma FFA within the physiologic range have a significant effect on glucagon secretion in man. Although the effects of glucose appear to predominate over those of FFA, alterations in plasma FFA may nevertheless exert an important physiologic influence over human pancreatic alpha cell function, especially in the postabsorptive state.

Comparison of the suppressive effects of elevated plasma glucose and free fatty acid levels on glucagon secretion in normal and insulin-dependent diabetic subjects. Evidence for selective alpha-cell insensitivity to glucose in diabetes mellitus.

To examine whether abnormal pancreatic alpha-cell function found in human diabetes mellitus may represent a selective insensitivity to glucose, plasma glucagon responses to hyperglycemia and elevation of plasma free fatty acid levels (both known suppressors of glucagon secretion) were compared in juvenile-onset, insulin-requiring diabetic subjects, and in normal nondiabetic subjects. In the latter, both elevation of plasma free fatty acid levels induced by heparin administration of hyperglycemia produced by intravenous infusion of glucose resulted in a comparable 30--40% suppression of circulating glucagon levels (P less than 0.01). In the diabetic subjects, glucagon suppression by hyperglycemia (less than 20%) was less than that occurring in normal subjects (P less than 0.01), even when accompanied by infusion of supraphysiologic amounts of insulin. However, suppression of glucagon levels by elevation of plasma free fatty acids in the diabetic group was similar to that found in normal subjects and of comparable magnitude to that due to hyperglycemia in the normal subjects. These results thus demonstrate a selective impairment of the diabetic alpha-cell response to glucose and provide further evidence for the presence of an abnormal alpha-cell glucoreceptor in human diabetes mellitus.

Effects of Acute Insulin Withdrawal and Administration on Plasma Glucagon Responses to Intravenous Arginine in Insulin-dependent Diabetic Subjects

To assess further the role of insulin in the abnormal alpha-cell dysfunction found in human diabetes mellitus, the effects of acute insulin withdrawal and administration on plasma glucagon responses to intravenous arginine were studied in eight insulin-dependent diabetic subjects. Arginine infusions (30 gm. over 30 minutes) were performed during and at one and four hours after discontinuation of a 14-hour insulin infusion (1.5 U. per hour), which had rendered the subjects euglycemic, and on another occasion before and one and four hours into a five-hour infusion of insulin (1.5 U. per hour). During the last hour of the 14-hour infusion, glucagon responses to arginine (area under the curve, nanograms per milliliter per minute) were similar to those found in normal subjects (10.3 ± 0.8 vs. 9.0 ± 0.8, respectively). After discontinuation of the insulin infusions, glucagon responses increased progressively (p < 0.01) to values (16.8 ± 1.2) that exceeded those of normal subjects by four hours (p < 0.01). These were similar to results found in the same subjects studied when their diabetes was in < optimal control (14.9 ± 1.3). Infusion of insulin under these conditions progressively decreased glucagon responses to arginine to values (9.6 ± 0.8; p < 0.01) that, at four hours, were similar to those of normal subjects and to values found at the end of the 14-hour infusion of insulin in the same diabetic individuals. These results demonstrate a rapid effect of insulin on glucagon responses to arginine and suggest that the abnormal responses seen in diabetes mellitus are the immediate result of insulin deficiency. Since abnormal glucagon responses to glucose in diabetes are not as readily corrected by insulin, the mechanisms underlying the abnormal responses to these two stimuli may differ.

The diabetic Chinese hamster: In vitro insulin and glucagon release; the “chemical diabetic”; and the effect of diet on ketonuria

SummaryInsulin and glucagon release (in response to glucose, theophylline, and arginine) were measured from thein vitro perfused pancreases of non-ketotic diabetic Chinese hamsters. These animals showed impaired alpha and beta cell sensitivity to glucose (i.e. excessive glucagon, and a reduction in both phases of insulin release) and abnormal alpha cell sensitivity to arginine (excessive glucagon), but normal responses to theophylline. Pancreatic insulin content was significantly decreased and glucagon content increased in unperfused diabetic pancreases. Abnormal responses to glucose and arginine were not directly related to pancreatic content, since responses to theophylline were normal. Insulin responses of normal animals from five normal sublines and non-ketotics from eight diabetic sublines were compared; certain diabetic sublines showed significantly less insulin release than did others, despite similar severities of glucosuria. — Fasting blood glucose during stress, glucose tolerance, andin vitro pancreatic insulin responses to glucose were measured in the normoglycemic, aglucosuric siblings of diabetics; the responses were diabetic-like, and therefore such animals are referred to here as “chemical diabetics”. — The incidence of glucosuria and ketonuria was studied in ketotic diabetic hamsters on high- and low-fat diets; glucosuria decreased and ketonuria disappeared on the low-fat diet.

Discordance of Diabetic Microangiopathy in Identical Twins

In a pair of 19-year-old monozygotic twin girls, one developed insulin-dependent, ketosis-prone diabetes at the age of three and has required insulin for the past 16 years. Her identical twin has maintained normal oral and intravenous glucose tolerance with normal insulin release and glucagon suppression. An unequivocal hypertrophy of the muscle capillary basement membrane(1,800 ± 148 Å) was found in the diabetic twin, while a normal thickness of 1,149 ± 62 Å was present in her nondiabetic sister. Follow-up of the present subjects and data from other discordant identical twins who have reached adulthood could determine whether muscle capillary basement membrane hypertrophy is an independent marker of genetic diabetes in adults. Discordance of diabetic microangiopathy in a pair of monozygotic twins has important implications regarding the influence of heredity and environment on diabetic microangiopathy.

ROLE OF GLUCAGON IN HUMAN DIABETIC KETOACIDOSIS: STUDIES USING SOMATOSTATIN

The present studies demonstrate that endogenous glucagon is hyperglycaemic, lipolytic and ketogenic in man, and that insulin deficiency is necessary, but is in itself not sufficient, to cause fulminant diabetic ketoacidosis. Furthermore, continuous elevation of endogenous glucagon secreation appears to be necessary for the maintenance and continued development of the characteristic metabolic consequences of insulin lack.

Plasma glucagon suppression by phenformin in man

SummaryIn an attempt to elucidate the mechanism of action of phenformin, eleven juvenile-onset, insulin-requiring diabetic subjects underwent four different treatment regimens during standard breakfast tests. These four treatments were: control (no insulin or phenformin); insulin alone (15 U regular insulin administered subcutaneously one-half hour before breakfast); phenformin alone (50 mg of the timed-release capsule given twice daily for three days before the study and two and one-half hours before breakfast on the day of study); and phenformin plus insulin (in the amounts and at the times stated above). Phenformin was found to decrease postprandial hyperglycaemia significantly when compared with control values, and its addition to insulin further decreased the postprandial glucose rise below that found with insulin alone (p<0.005). These effects were associated with a reduction in early (30-min) postprandial hyperglucagonaemia (p <0.05). Triglyceride levels, gastrin secretion, growth hormone levels, and increments ofα-amino nitrogen were not affected by phenformin. Thus, suppression of postprandial hyperglucagonaemia may be an additional mechanism in the reduction of postprandial hyperglycaemia after phenformin.