Interaction of glucose and epinephrine in the regulation of insulin secretion

Cilnidipine, the N- and L-type calcium channel antagonist, reduced on 24-h urinary catecholamines and C-peptide in hypertensive non-insulin-dependent diabetes mellitus

To evaluate the effects of cilnidipine (CNP), L- and N-type calcium channel blocker and nilvadipine (NVP) on 24-h urinary epinephrine (U-EP), norepinephrine (U-NE), dopamine (U-DA) and C-peptide (U-CPR) in patients associated with hypertension and non-insulin-dependent diabetes mellitus (HT-NIDDM), a randomized crossover study was performed with 35 HT-NIDDM patients. The patients were given CNP (10 mg/day) and NVP (8 mg/day), separately, for 4 weeks each. After CNP treatment, U-NE, U-DA and U-CPR levels were significantly reduced compared with pre-treatment levels: 160.4 +/- 12.7 to 111.7 +/- 8.9 microg/day (mean +/- S.E., P < 0.005); 934.8 +/- 163.4 to 590.3 +/- 33.4 microg/day (P < 0.05); 86.7 +/- 9.9 to 57.6 +/- 7.4 microg/day (P < 0.05), respectively. Although no significant differences were observed in U-EP, U-NE, U-DA and U-CPR levels by NVP treatment, U-NE, U-DA and U-CPR levels after CNP treatment were significantly lower than those after NVP treatment: 111.7 +/- 8.9 versus 155.0 +/- 13.7 microg/day (P < 0.02); 590.3 + 33.4 versus 822.2 +/- 104.3 microg/day (P < 0.05); 57.6 +/- 7.4 versus 80.6 +/- 8.1 microg/day (P < 0.05), respectively. In conclusion, it was demonstrated that CNP treatment significantly reduced U-NE, U-DA and U-CPR excretion compared with NVP treatment in HT-NIDDM patients.

Effects of epinephrine on insulin-mediated glucose uptake in whole body and leg muscle in humans: role of blood flow

In vivo insulin-mediated glucose uptake (IMGU) occurs chiefly in skeletal muscle, where it is determined by the product of arteriovenous glucose difference (delta AVG) and blood flow (BF) rate into muscle. Epinephrine (Epi) reduces the rate of IMGU in whole body. To examine whether this is due to a reduction in delta AVG across or BF into skeletal muscle we constructed insulin dose-response curves for whole body IMGU and leg muscle IMGU- using euglycemic clamp ((+)[3-3H]glucose infusion) and leg balance techniques during insulin infusions ranging from 10 to 1,200 mU.m-2.min-1. We studied six subjects [wt 70 +/- 2 (SE) kg] during an Epi infusion at a single rate of 0.002 mg.kg-1.min-1 and six subjects (70 +/- 3 kg) during a saline infusion alone. Maximum whole body glucose uptake (WBGU) was similar during Epi and saline infusions [71.4 vs. 73.6 mmol.kg-1.min-1, P = not significant (NS)]. Compared with saline, maximum delta AVG was decreased during Epi infusion (1.04 vs. 1.31 mM, P less than 0.01). Compared with saline alone maximum leg BF was increased (5.3 vs. 4.3 dl/min, P less than 0.01) during Epi infusion. Thus maximum leg glucose uptake (LGU) was similar (696 vs. 821 pmol.leg-1.min-1, P = NS) during infusion of Epi and saline, respectively. Half-maximal effective dose for insulin's effect to stimulate WBGU, delta AVG, BF, and LGU was increased two- to threefold during Epi vs. saline infusions (P less than 0.01 for all values).(ABSTRACT TRUNCATED AT 250 WORDS)

Dose-related effects of epinephrine on glucose production in conscious dogs

The effects of increases in plasma epinephrine from 78 +/- 32 to 447 +/- 75, 1,812 +/- 97, or 2,495 +/- 427 pg/ml on glucose production, including gluconeogenesis, were determined in the conscious, overnight-fasted dog, using a combination of tracer [( 3-3H]glucose and [U-14C]alanine) and arteriovenous difference techniques. Insulin and glucagon were fixed at basal levels using a pancreatic clamp. Plasma glucose levels rose during the 180-min epinephrine infusion by 47 +/- 7, 42 +/- 22, and 74 +/- 25 mg/dl, respectively, in association with increases in hepatic glucose output of 1.04 +/- 0.22, 1.87 +/- 0.23, and 3.70 +/- 0.83 mg.kg-1.min-1 (at 15 min). Blood lactate levels rose by 1.52 +/- 0.24, 4.29 +/- 0.49, and 4.60 +/- 0.45 mmol/l, respectively, by 180 min, despite increases in hepatic uptake of lactate of 3.47 +/- 5.73, 12.83 +/- 3.46, and 37.00 +/- 4.20 mumol.kg-1.min-1. The intrahepatic gluconeogenic efficiency with which the liver converted the incoming alanine to glucose had risen by 84 +/- 40, 77 +/- 24, and 136 +/- 34% at 180 min, respectively. The latter effect plus the effect on net hepatic lactate uptake point to an intrahepatic action of high levels of the hormone in vivo. In conclusion, epinephrine produces dose-dependent increments in overall glucose production, which involve a progressive stimulation of both glycogenolysis (as assessed by glucose production at 15 min) and gluconeogenesis (assessed in the last 30 min of the study). The latter involves a peripheral action of the catecholamine to increase gluconeogenic substrate supply to the liver and may also involve a hepatic effect when high epinephrine levels are present.

Nocturnal growth hormone secretion does not affect diurnal variations in arginine and glucose-stimulated insulin secretion

There is a diurnal variation in insulin secretion, with higher values in the morning (AM) than in the afternoon (PM). This study tested the hypothesis that nocturnal human growth hormone (hGH) secretion might be the mechanism producing this diurnal variation in insulin secretion. Six healthy normal-weight men were studied on four occasions: twice in the early morning (AM) and twice in the afternoon (PM). Oral methscopolamine (Pamine), an anticholinergic agent that blocks hGH release, was administered at bedtime prior to the AM study or before breakfast for the PM study. An index of insulin secretion in all four tests was obtained from measurement of the acute release of insulin in response to two intravenous (IV) boluses of arginine, one given basally and the other given after raising glucose levels to approximately 150 mg/dL above the baseline. Insulin secretion was significantly greater in the morning than in the afternoon in both control and methscopolamine-pretreated subjects. The mean peak hGH was reduced in subjects pretreated with oral methscopolamine. Drug treatment reduced insulin secretion proportionally in the morning and afternoon. These results suggest that the diurnal insulin response to stimulation with arginine during a hyperglycemic clamp persists despite complete suppression of hGH by anticholinergic blockade, and that the diurnal insulin secretion is not caused by sleep- or meal-induced GH secretion.

The effects of epinephrine on islet hormone secretion in the dog

We investigated the direct effects of physiological levels of epinephrine on the basal and arginine-stimulated secretion of insulin, glucagon, and somatostatin from the in situ pancreas in halothane-anaesthetized dogs. An IV infusion of 20 ng/kg/min of epinephrine increased plasma epinephrine levels to 918 +/- 103 pg/ml (P less than 0.001), and increased the baseline pancreatic output of insulin (P less than 0.05), glucagon (P less than 0.05) and somatostatin (P less than 0.05). The acute insulin response (AIR) to 2.5 g of arginine during this infusion of epinephrine was significantly higher (P less than 0.05) than in controls as were the acute glucagon response (AGR) (P less than 0.05) and the acute somatostatin response (ASLIR) (P less than 0.05). Plasma glucose levels increased slightly and transiently during infusion of epinephrine from 99 +/- 2 mg/dl to a maximum of 110 +/- 3 mg/dl (P less than 0.05). An IV infusion of 80 ng/kg/min of epinephrine produced plasma epinephrine levels of 2,948 +/- 281 pg/ml, and increased the baseline pancreatic output of insulin (P less than 0.05) and glucagon (P less than 0.05). In contrast, baseline somatostatin output decreased transiently during this high dose infusion of epinephrine. The AIR and ASLIR to arginine were both significantly lower (P less than 0.05) than those during the infusion of epinephrine at the low dose. The AGR to arginine remained potentiated (P less than 0.05). Plasma glucose levels increased from 99 +/- 3 mg/dl to 119 +/- 4 mg/dl (P less than 0.01). We conclude that the effect of epinephrine on islet hormone secretion is dependent on the plasma level of epinephrine. At stress levels of 900-1000 pg/ml, both insulin and somatostatin secretion are stimulated; only at near pharmacologic, or extreme stress levels, does epinephrine produce net inhibition.

Pathophysiology of insulin secretion in diabetes mellitus

In normal man, glucose serves to regulate basal insulin secretion by its participation with insulin in a feedback loop. In addition, glucose stimulates insulin secretion directly and potentiates insulin responses to nonglucose stimuli such as amino acids, beta-adrenergic stimuli, and gut hormones. Maximal glycemic potentiation of the acute insulin response to IV arginine occurs at a glucose level of approx. 450 mg/dl. In patients with noninsulin dependent diabetes mellitus (NIDDM), basal insulin levels have usually been reported as normal, but if plasma glucose is lowered to normal levels, a deficiency of basal insulin becomes apparent. In addition, the first phase (0-10 min) insulin response to IV glucose is absent in virtually all patients with overt NIDDM. In contrast, the second-phase (greater than 10 min) response is often preserved in NIDDM due to its maintenance by ambient hyperglycemia. Similarly, insulin responses to nonglucose stimuli such as arginine often appear normal in NIDDM because of potentiation by hyperglycemia. However, insulin responses to arginine are lower than those of nondiabetic controls when compared at multiple matched glucose levels. Indeed, maximal potentiation by glucose of the insulin response to arginine is markedly subnormal in NIDDM, suggesting a loss of functional B cell secretory capacity. In patients with long-standing insulin-dependent diabetes mellitus (IDDM), basal insulin secretion and insulin responses to all stimuli are virtually absent. However, in a remission phase, or in IDDM of short duration, basal insulin secretion and insulin responses to nonglucose stimuli may be relatively preserved. Therefore, islet dysfunction in IDDM and NIDDM, while etiologically different, share some common pathophysiological features.

Role of counterregulatory hormones in the catabolic response to stress

Patients with major injury or illness develop protein wasting, hypermetabolism, and hyperglycemia with increased glucose flux. To assess the role of elevated counterregulatory hormones in this response, we simultaneously infused cortisol (6 mg/m2 per h), glucagon (4 ng/kg per min), epinephrine (0.6 microgram/m2 per min), and norepinephrine (0.8 micrograms/m2 per min) for 72 h into five obese subjects receiving only intravenous glucose (150 g/d). Four obese subjects received cortisol alone under identical conditions. Combined infusion maintained plasma hormone elevations typical of severe stress for 3 d. This caused a sustained increase in plasma glucose (60-80%), glucose production (100%), and total glucose flux (40%), despite persistent hyperinsulinemia. In contrast, resting metabolic rate changed little (9% rise, P = NS). Urinary nitrogen excretion promptly doubled and remained increased by approximately 4 g/d, reflecting increased excretion of urea and ammonia. Virtually all plasma amino acids declined. The increment in nitrogen excretion was similar in three additional combined infusion studies performed in 3-d fasted subjects not receiving glucose. Cortisol alone produced a smaller glycemic response (20-25%), an initially smaller insulin response, and a delayed rise in nitrogen excretion. By day 3, however, daily nitrogen excretion was equal to the combined group as was the elevation in plasma insulin. Most plasma amino acids rose rather than fell. In both infusion protocols nitrogen wasting was accompanied by only modest increments in 3-methylhistidine excretion (approximately 20-30%) and no significant change in leucine flux. We conclude: (a) Prolonged elevations of multiple stress hormones cause persistent hyperglycemia, increased glucose turnover, and increased nitrogen loss; (b) The sustained nitrogen loss is no greater than that produced by cortisol alone; (c) Glucagon, epinephrine, and norepinephrine transiently augment cortisol-induced nitrogen loss and persistently accentuate hyperglycemia; (d) Counterregulatory hormones contribute to, but are probably not the sole mediators of the massive nitrogen loss, muscle proteolysis, and hypermetabolism seen in some clinical settings of severe stress.

Dexamethasone-induced insulin resistance enhances B cell responsiveness to glucose level in normal men

To determine whether islet adaptation during insulin resistance involves increased responsiveness to the level of plasma glucose, insulin resistance was induced in nine normal men by giving dexamethasone (Dex) (3 mg twice daily for 2 days). Plasma insulin and acute insulin responses (AIR) to isoproterenol were measured at three different glucose levels under control and Dex conditions. During Dex there were elevations above control levels of basal glucose (104 +/- 2 vs. 94 +/- 3 mg/dl) and insulin (21 +/- 3 vs. 13 +/- 2 microU/ml, both P less than 0.03). When glucose levels were raised stepwise by matching amounts using glucose clamps, AIR to isoproterenol rose as a linear function of glucose level under both conditions but rose more steeply during Dex. That is, the potentiating effect of glucose (delta AIR/delta glucose) was greater during Dex: 1.3 +/- 0.2 vs. 0.8 +/- 0.2 (P less than 0.01). Similarly, matched increments in glucose level produced greater increments in prestimulus insulin level during Dex (P less than 0.03). We conclude that 48 h of Dex raises the "gain" of the potentiating effect of glucose. Because the direct effect of glucocorticoids on B cell function has been reported to be inhibitory, the observed stimulation is likely to be a result of the insulin resistance caused by Dex.

Diminished B cell secretory capacity in patients with noninsulin-dependent diabetes mellitus

In order to assess whether patients with noninsulin-dependent diabetes mellitus (NIDDM) possess normal insulin secretory capacity, maximal B cell responsiveness to the potentiating effects of glucose was estimated in eight untreated patients with NIDDM and in eight nondiabetic controls. The acute insulin response to 5 g intravenous arginine was measured at five matched plasma glucose levels that ranged from approximately 100-615 mg/dl. The upper asymptote approached by acute insulin responses (AIRmax) and the plasma glucose concentration at half-maximal responsiveness (PG50) were estimated using nonlinear regression to fit a modification of the Michaelis-Menten equation. In addition, glucagon responses to arginine were measured at these same glucose levels to compare maximal A cell suppression by hyperglycemia in diabetics and controls. Insulin responses to arginine were lower in diabetics than in controls at all matched glucose levels (P less than 0.001 at all levels). In addition, estimated AIRmax was much lower in diabetics than in controls (83 +/- 21 vs. 450 +/- 93 microU/ml, P less than 0.01). In contrast, PG50 was similar in diabetics and controls (234 +/- 28 vs. 197 +/- 20 mg/dl, P equals NS) and insulin responses in both groups approached or attained maxima at a glucose level of approximately 460 mg/dl. Acute glucagon responses to arginine in patients with NIDDM were significantly higher than responses in controls at all glucose levels. In addition, although glucagon responses in control subjects reached a minimum at a glucose level of approximately 460 mg/dl, responses in diabetics declined continuously throughout the glucose range and did not reach a minimum. Thus, A cell sensitivity to changes in glucose level may be diminished in patients with NIDDM. In summary, patients with NIDDM possess markedly decreased maximal insulin responsiveness to the potentiating effects of glucose. Such a defect indicates the presence of a reduced B cell secretory capacity and suggests a marked generalized impairment of B cell function in patients with NIDDM.

Effect of epinephrine on glycogenolysis and gluconeogenesis in conscious overnight-fasted dogs

The aim of this study was to assess the importance of epinephrine as a gluconeogenic hormone in the conscious 18-h-fasted dog. Glucose production ([3H]glucose turnover) and gluconeogenesis [( 14C]alanine conversion to [14C]glucose; and transhepatic gluconeogenic substrate balances) were assessed during epinephrine infusion (0.04 microgram X kg-1 X min-1). Insulin and glucagon were fixed at basal levels (13 +/- 1 microU/ml and 138 +/- 16 pg/ml, respectively) using a pancreatic clamp [somatostatin (0.8 microgram X kg-1 X min-1) plus intraportal insulin (233 microU X kg-1 X min-1) and glucagon (0.65 ng X kg-1 X min-1)]. Plasma epinephrine levels increased to 424 +/- 48 pg/ml. Glucose production increased rapidly (15 min) from 2.7 +/- 0.3 to 3.7 +/- 0.4 mg X kg-1 X min-1 (P less than 0.01) but then returned to base line (2 h). The plasma glucose level rose progressively from 115 +/- 16 to 160 +/- 16 mg/dl (P less than 0.01) at 3 h, whereas glucose clearance fell by 28% (P less than 0.05). Plasma alanine rose from 340 +/- 20 to 497 +/- 50 microM, and blood lactate increased from 640 +/- 135 to 1,910 +/- 241 microM. Net hepatic alanine and lactate uptake increased to maxima of 4.0 +/- 0.3 and 9.3 +/- 2.0 mumol X kg-1 X min-1, respectively. The conversion of alanine to glucose increased by a maximum of 163 +/- 56% (vs. 49 +/- 16% in controls not given epinephrine), whereas the efficiency with which the liver converted alanine to glucose rose by 84 +/- 27% (vs. 82 +/- 12% in controls not given epinephrine).(ABSTRACT TRUNCATED AT 250 WORDS)

Islet function and stress hyperglycemia: plasma glucose and epinephrine interaction

Catecholamines and a number of other hormones released during stress states contribute to the development of hyperglycemia by directly stimulating glucose production and interfering with tissue disposal of glucose. However, hyperglycemia stimulates the secretion of insulin and inhibits the secretion of glucagon, effects that will diminish the degree of hyperglycemia resulting from direct actions of stress hormones on glucose production and disposal. The key additional role of catecholamines in the development of stress hyperglycemia is interference with the normal feedback control of insulin and glucagon secretion by circulating glucose levels. Although pancreatic islet responses to hyperglycemia may be modulated by catecholamines, any increase of insulin secretion or suppression of glucagon secretion that does occur may be important for limiting the degree of elevation of circulating glucose that results. Thus, plasma insulin and glucagon levels during stress states will reflect the interaction between the opposing effects of hyperglycemia and catecholamines. Diabetic patients who have impaired islet responses to glucose will be particularly prone to the development of marked hyperglycemia during stress states because they may be unable to respond to the influence of hyperglycemia in counteracting adrenergic inhibition of insulin secretion and stimulation of glucagon secretion.