Interactions of cholecystokinin and glucose in rat pancreatic islets

The effects of sulfated cholecystokinin (CCK-8S) and glucose on insulin secretion and polyphosphoinositide (PPI) metabolism were studied in isolated rat islets. Both agonists stimulate PPI hydrolysis, inositol phosphate accumulation, 3H efflux from [3H]inositol-prelabeled tissue, and 45Ca efflux from prelabeled cells. However, the effects of CCK-8S on PPI metabolism are considerably greater than those of glucose. Furthermore, the effects of CCK-8S on PPI and Ca2+ metabolism are observed whether islets are incubated in either 2.75 or 7 mM glucose, but CCK-8S only stimulates insulin secretion (a biphasic response) when the higher glucose concentration is present. Addition of 1 microM forskolin to islets incubated in media containing 2.75 mM glucose does not influence basal insulin secretion but sensitizes the islets to the action of CCK-8S. In the presence of forskolin, CCK-8S induces a very marked first phase but no second phase of insulin secretion. We postulate that CCK-8S acts in this tissue via receptor-linked PPI hydrolysis, leading to an inositol trisphosphate-induced Ca2+ efflux. These receptor-mediated effects of CCK-8S are not altered either by the ambient glucose concentration or the cAMP content of the islets, but these two factors determine the responsiveness of the islets (in terms of insulin secretion) to a given CCK-8S signal.     

Cholecystokinin-induced alterations in beta-cell sensitivity. Duration, specificity, and involvement of phosphoinositide metabolism

Prior exposure of isolated perifused rat islets to the sulfated gut hormone cholecystokinin-8 (CCK-8S) dramatically increased their insulin secretory response to 7.5 mM glucose, 10 mM arginine, and 10 mM alpha-ketoisocaproate. In the case of glucose, the heightened secretory response was still apparent 60-80 min after CCK-8S removal from the perifusion medium. Prior exposure of perifused islets to arginine (10 mM), tolbutamide (25 microM), or forskolin (1.0 microM) did not sensitize them to 7.5 mM glucose. CCK-8S exposure increased 3H efflux from islets prelabeled with [3H]inositol, and the increase in 3H efflux was sustained after CCK-8S removal from the perifusion medium. The duration of this increase in 3H efflux paralleled the temporal characteristics of this sensitization process and was significantly attenuated by 25 microM asperlicin, a competitive antagonist of CCK binding to its membrane receptor. Arginine, tolbutamide, or forskolin treatment of islets did not increase 3H efflux from [3H]inositol-prelabeled islets. The results suggest that the turnover of membrane phosphoinositides induced by CCK-8S is largely responsible for this heightened state of secretory responsiveness to various stimulants. Second-messenger molecules generated during phosphoinositide turnover may be responsible for the phenomenon of sensitization displayed by islet tissue to CCK-8S addition.     

Effect of dynorphin on insulin and somatostatin secretion, calcium uptake, and c-AMP levels in isolated rat islets of Langerhans

Dynorphin-[1-13], at concentrations of 5.8 X 10(-12) to 5.8 X 10(-9) M, stimulated insulin secretion from isolated islets of Langerhans of the rat, in medium containing 6 mM glucose. Higher concentrations of dynorphin had no significant effect on secretion. Dynorphin (5.8 X 10(-9) M) was unable to initiate insulin release from islets in the presence of 2 mM glucose, or to increase insulin secretion further in the presence of 20 mM glucose or 6 and 12 mM glyceraldehyde. Dynorphin-induced insulin secretion from islets was blocked by verapamil (5 microM) or by chlorpropamide (72 microM), but not by a mu opiate receptor antagonist, naloxone (0.11 microM), or by ICI 154129, a specific antagonist for the delta receptor (0.25 microM). Dynorphin had no effect on islet somatostatin secretion, under conditions in which insulin secretion was greatly stimulated. Glucose (20 mM) and glyceraldehyde (6 and 12 mM) significantly increased both insulin and somatostatin secretion. Dynorphin (5.8 X 10(-9) M) increased 45Ca2+ uptake into islets, and also increased intracellular islet c-AMP levels. These changes persisted when higher concentrations of dynorphin were used. These results suggest that (1) dynorphin is a very potent stimulus for insulin secretion; (2) dynorphin does not affect somatostatin secretion in static incubations of islets, in the same way as does glucose and glyceraldehyde; (3) dynorphin's effects may involve increased calcium ion movement and can be blocked by verapamil; (4) dynorphin can also increase islet c-AMP, and could thereby modulate the responsiveness of other secretagogues; (5) the actions of dynorphin on insulin secretion are not mediated by delta or mu opiate receptors in islets.     

Influence of cAMP and calcium on [3H]inositol efflux, inositol phosphate accumulation, and insulin release from isolated rat islets

The influence of cyclic AMP (cAMP) and extracellular calcium on phosphoinositide (PI) hydrolysis in isolated islets was assessed and related to insulin output. Three stimulants were chosen to activate the beta-cell: sulfated cholecystokinin (CCK-8S, 200 nM), high-level glucose (20 mM), and the sulfonylurea tolbutamide (200 microM). The insulin secretory response to all three agonists was amplified by forskolin (which increases cAMP levels) and reduced by nitrendipine (which decreases calcium influx). All three stimulants increased the hydrolysis of inositol-containing phospholipids, an event monitored by an increase in [3H]inositol efflux from [3H]inositol-prelabeled islets and by the accumulation of labeled inositol phosphates. Forskolin, despite its positive impact on insulin secretion, reduced [3H]inositol efflux and inositol phosphate accumulation in response to all agonists. A similar inhibitory effect on these parameters was noted with nitrendipine; however, nitrendipine abolished secretion in response to all agonists. These findings support the following conclusions: 1) an increase in cellular cAMP levels reduces the quantitative impact of various agonists on these indices of PI hydrolysis; 2) despite this inhibitory effect, cAMP amplifies the insulin secretory response to these agonists; and 3) extracellular calcium is a crucial determinant of both PI hydrolysis and the ensuing insulin secretory response.     

Lack of islet amyloid polypeptide regulation of insulin biosynthesis or secretion in normal rat islets

We examined the effects of rat islet amyloid polypeptide (IAPP) on insulin biosynthesis and secretion by isolated rat islets of Langerhans. Culture of islets for 24 h in the presence of 10(-6) M IAPP and 5.5 mM glucose had no effect on insulin mRNA levels. Similarly, the rates of proinsulin biosynthesis were not altered in islets incubated in 10(-4)-10(-9) M IAPP and 5.5 mM glucose, nor was the rate of conversion of proinsulin to insulin changed at 10(-6) M IAPP. Addition of 10(-5) M IAPP to islets incubated in 11 mM glucose decreased the fractional insulin secretion rate; however, the secretion of newly synthesized proinsulin and insulin was not affected. These data indicate that it is unlikely that IAPP is a physiologically relevant modulator of insulin biosynthesis or secretion.     

Age-dependent stimulation of neonatal insulin release and inositol phosphate accumulation by CCK-8 and carbachol

Development of a robust insulin secretory response to glucose occurs during the early neonatal period. To determine if neuroendocrine agents play a role during this time, we studied the effects of selected peptides and neurotransmitters on insulin release and polyphosphoinositide metabolism in islets isolated from 1- and 3-day neonatal rats. Vasoactive intestinal peptide had no effect on glucose-stimulated release in either islet population. In contrast, sulfated cholecystokinin octapeptide (CCK-8) significantly enhanced glucose-induced insulin release in both islet groups. One-day islets were stimulated only by a concentration of 300 nM, whereas 3-day islets were responsive at 3 nM. Similar to CCK-8, there were clear differences in responses to carbachol between 1- and 3-day islets. One-day islets required a concentration of 200 microM for insulin release to be significantly greater than with glucose alone; 3-day islet insulin release was significant at 2 microM carbachol. Both agonists stimulated inositol phosphate accumulation in 3-day islets, but only CCK-8 caused a significant increase over glucose-induced levels in 1-day islets. These results indicate that islet responsiveness to CCK-8 and carbachol develops in parallel during the early neonatal period. This development may be linked to the maturation of a critical step of stimulus-secretion coupling through which these agents act.     

Evidence that cholecystokinin interacts with specific receptors and regulates insulin release in isolated rat islets of Langerhans

To determine the nature of the pancreatic islet cell cholecystokinin (CCK) receptor, we studied CCK receptor binding and biologic activity in isolated rat pancreatic islets. Binding of 70 pM 125I-CCK to collagenase-prepared isolated rat pancreatic islets at 24 degrees C was one-half maximal after 5 min and maximal at 60 min. At 60 min, specific binding was 12% of total radioactivity per 100 micrograms islet protein; nonspecific binding (in the presence of 1 microM CCK 8) was less than 2% of total radioactivity. Unlabeled CCK 33 inhibited labeled hormone binding one-half maximally at 2 nM; Scatchard analysis showed one binding site (Kd, 2.3 +/- 0.4 nM; Bmax, 8.1 pmol/mg protein). The agonist selectivity of this binding site was: CCK 8 = CCK 33 greater than desulfated-CCK 8 greater than CCK 4. Two CCK antagonists were studied; N-carbobenzoxy-L-tryptophan was more potent than dibutyryl-cGMP. When the effect of CCK on insulin release from the islets was studied, the order of potency of CCK agonists and antagonists on insulin secretion was the same as the order of their ability to inhibit 125I-CCK binding. The effect of CCK on insulin secretion was dependent on the glucose concentration in the media. CCK had no effect at 5.6 mM glucose and was fully effective at 11.0 mM glucose. These data, therefore, indicate that: specific binding sites for CCK are present in rat pancreatic beta cells; and CCK acts in concert with glucose to stimulate insulin secretion.     

Differential effects of age versus glycemic stimulation on the maturation of insulin stimulus-secretion coupling during culture of fetal rat islets

We have cultured islets from 21.5-day-old fetal rats for 1-7 days in RMPI 1640/10% fetal calf serum containing 2.8 or 11.1 mM glucose to evaluate the differential effects of age vis-à-vis glycemic stimulation on the maturation of selected components of stimulus-secretion coupling. After 1 day of culture in either media, acute stimulation with 3.0 mg/ml glucose during basal perifusion with 0.5 mg/ml glucose elicited only a small first phase of stimulated insulin secretion and no second phase. The acute exposure to 3.0 mg/ml glucose produced no change in the prevailing high rates of oxygen consumption (QO2) and caused only minor increments in phosphate efflux (i.e., peak values for phosphate flush of 126 +/- 16% of baseline for islets that had been cultured in 11.1 mM glucose and 162 +/- 30% for islets cultured in 2.8 mM glucose). After 7 days of culture in 11.1 mM glucose, acute stimulation with 3.0 mg/ml glucose increased Qo2 (as in adult islets) and effected acute increases in the AT32P and GT32P content of prelabeled islets. The 3.0 mg/ml glucose also triggered phosphate flush to 599 +/- 45% of baseline and elicited first as well as early second phases of stimulated insulin secretion that replicated the performance of adult islets. By contrast, after 7 days of culture in 2.8 mM glucose, similar acute exposures of fetal islets to 3.0 mg/ml glucose effected only a small first phase and a negligible second phase of stimulated insulin secretion despite the occurrence of the same increments in Qo2 as after culture in 11.1 mM glucose, highly significant increases in AT32P and GT32P, and phosphate flushes that peaked at 306 +/- 16% of basal values. Thus, the ontogeny of individual components of stimulus-secretion coupling may occur in asynchronous fashion and varying require glycemic stimulation in addition to aging per se. The capacities to augment efflux of orthophosphate, enhance respiration, and heighten nucleotide turnover in response to acute stimulation with glucose seem to mature in large measure in time-dependent fashion, whereas some chronic exposure to ambient glucose in excess of basal levels may be required to establish and/or maintain the other coupled components that underlie biphasic stimulated insulin release. However, we did not achieve full exocytotic maturation even after 7 days of culture with 11.1 mM glucose.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of norepinephrine on insulin, glucagon, and somatostatin secretion in isolated perifused rat islets.

The rate of insulin, glucagon, and somatostatin secretion was measured from isolated rat islets maintained in a perifusion system. The effect of norepinephrine (NE) was simultaneously determined on the release rate of all three hormones. Norepinephrine was employed at an acute dose of 10 micrometers and in graded doses from 1 nM to 10 micrometers in the presence of high (22 mM) and low (1.4 mM) glucose conditions, insulin secretion was maximally inhibited at 10 micrometers NE concentration and was significantly depressed at 100 mM NE concentration. Under both high and low glucose conditions, glucagon release was maximally stimulated at 10 micrometers NE concentration and was significantly elevated at 10 nM NE concentration. Under high and low glucose conditions, somatostatin release was inhibited by 10 micrometers NE concentration and was significantly depressed at 100 nM NE concentration. During the initial maximal stimulation of glucagon, NE inhibition of somatostatin and insulin was prevented, possibly by the high level of glucagon released. A paracrine effect of glucagon on beta and delta cells is proposed.     

Induction of memory in rat pancreatic islets by tolbutamide. Dependence on ambient glucose level, calcium, and phosphoinositide hydrolysis

The ability of the sulfonylurea tolbutamide to induce insulin output, increase phosphoinositide (PI) hydrolysis, and modulate the insulin response to other agonists was assessed. At 200 microM, tolbutamide increased both insulin release and the efflux of 3H from [3H]inositol-prelabeled islets only in the presence of 5.5 or 7 mM glucose. When the glucose level was maintained at 2.75 mM, tolbutamide (200 microM) had no positive impact on either parameter. The calcium-influx inhibitor nitrendipine (200 nM) blocked the effects of 200 microM tolbutamide (with 7 mM glucose) on 3H efflux and insulin output. Prior exposure of islets to tolbutamide (200 microM) in the presence of 7 mM glucose amplified their subsequent insulin response to 10 mM glucose and 5 mM glyceraldehyde. The effect of 200 microM tolbutamide (with 7 mM glucose) was blocked by nitrendipine. Furthermore, the effect of 200 microM tolbutamide was not observed with 2.75 mM glucose; however, if the level of tolbutamide was increased to 1 mM, both PI hydrolysis and potentiated release to subsequent stimulation with 10 mM glucose were observed. Tolbutamide (200 microM with 7 mM glucose) stimulation for 20 min resulted in an increase in 3H efflux from [3H]inositol-prelabeled islets. Despite the rapid fall in insulin secretion, elevated rates of 3H efflux persisted long after the removal of the sulfonylurea from the medium. The duration of the 3H-efflux response paralleled the duration of potentiation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of high glucose on insulin secretion by isolated rat islets and purified beta-cells and possible role of glycosylation

We investigated the effect of 24 h of exposure to various glucose concentrations on insulin secretion by isolated rat pancreatic islets and purified rat beta-cells. Compared with islets cultured with standard medium (5.5 mM glucose), islets cultured with 16.7 mM glucose showed a higher basal insulin release (means +/- SE, 3.0 +/- 0.5 vs. 0.7 +/- 0.2%, n = 8, P less than .005) and reduced glucose-stimulated insulin secretion (2.4 +/- 0.3 vs. 5.8 +/- 0.4%, n = 8, P less than .005). Similar results were also obtained with purified beta-cells. The effect of high glucose was time dependent (present after 12 h, maximal after 24 h) and reversible: when islets cultured with high glucose were transferred to standard medium, normal responsiveness to glucose was restored within 8 h and normal basal release within 24 h. Mannitol, 3-O-methylglucose, and 2-deoxyglucose were not able to mimic the effects of glucose. Islets or purified beta-cells cultured in the presence of high glucose had a normal response when stimulated with glyburide, dibutyryl cyclic AMP, and isobutylmethylxanthine. Tunicamycin, an inhibitor of N-terminal glycosylation, prevented glucose-induced desensitization when added during 24 h of islet culture with 16.7 mM glucose. Swainsonine, another agent that influences glycosylation, had a similar effect. Our study indicates 1) that 24 h of exposure to high glucose induces a specific and reversible impairment of insulin secretion in response to glucose, 2) that this is a direct effect of glucose on beta-cells, and 3) that islet glucose metabolism and glycosylation processes may play a critical role in determining glucose desensitization.     

Multiple alterations in insulin responses to glucose in islets from 48-h glucose-infused nondiabetic rats

To examine the biochemical mechanisms by which hyperglycemia produces insulin secretory abnormalities, we studied isolated islets from control rats and rats infused for 48 h with a 50% glucose solution. To preserve the effects of in vivo hyperglycemia during in vitro handling for islet isolation, our standard isolation procedure utilized buffers containing 16.8 mM glucose. Islets from infused rats released similar amounts of insulin in low or high glucose during first incubations at 37 degrees C (92.4 +/- 7.0 ng.10 islets-1.45 min-1 at 2.8 mM, 84.4 +/- 4.1 ng.10 islets-1.45 min-1 at 16.8 mM) in contrast with control (uninfused) islets (18.6 +/- 2.8 ng.10 islets-1.45 min-1 at 2.8 mM and 109.8 +/- 8.0 ng.10 islets-1.45 min-1 at 16.8 mM glucose) (P less than 0.01). Secretion by islets of glucose-infused rats was lower during 60-min second incubations at 28 mM glucose than in first incubations of the same islets in low glucose (P less than 0.01). This phenomenon is comparable to the paradoxical hypersecretion observed during the first 10-15 min of exposure of glucose-infused pancreas to low-glucose perfusions. Paradoxical secretion in low glucose waned rapidly, so that during second incubations at 37 degrees C, little immunoreactive insulin release occurred at 2.8 mM glucose, despite the persistence of two additional lesions. The glucose-insulin dose-response curves in second incubations showed a leftward shift for glucose-infused islets, with two- to threefold higher secretion at 5.6-8.4 mM glucose than control islets. This is termed sensitization to glucose.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stimulation of insulin secretion from isolated rat islets by SaRI 59-801

Oral administration of SaRI 59-801 (DL-alpha-[dimethylaminomethyl]-2-[3-ethyl-5-methyl-4-isoxazolyl]-1H- indole-3-methanol) has been reported to decrease blood glucose in several species and to elevate plasma insulin in rats and mice. In studies with isolated rat pancreatic islets incubated 1 h with 3 mM glucose, 0.05 mM 59-801 produced a significant increase in insulin secretion, and 0.3 mM produced maximum release. 59-801 (0.3 mM) stimulated insulin release 4-5-fold from islets incubated with 0, 3, or 5 mM glucose but had little effect on the high rates of release obtained at 10 or 20 mM glucose. Ten millimolar mannoheptulose, which inhibits phosphorylation of glucose and blocks glucose-stimulated insulin release, had little effect on the stimulation of insulin release by 0.3 mM 59-801 from islets incubated with 3 mM glucose. Stimulation of insulin release in the absence of glucose or in the presence of 3 mM glucose plus 10 mM mannoheptulose suggests that glucose metabolism is not required for the action of 59-801. The rate of conversion of 5 mM [5(-3)H]-glucose to 3H2O by islets, a measure of the rate of glycolysis, was not affected by 59-801. The potency, dependency on glucose concentration, lack of inhibition by mannoheptulose, and lack of effect on glycolysis of 59-801 were similar to that of tolbutamide. However, proinsulin synthesis by islets incubated with 5.55 mM glucose was not affected by 0.5 mM 59-801, but was inhibited 72% and 67% by 0.5 mM tolbutamide and 0.1 mM glibenclamide, respectively.     

Antisomatostatin gamma globulin augments secretion of both insulin and glucagon in vitro: evidence for a physiologic role for endogenous somatostatin in the regulation of pancreatic A- and B-cell function

To assess the effects of endogenous somatostatin on pancreatic islet A- and B-cell function, isolated rat islets were incubated in antisomatostatin gamma-globulin to bind endogenously released somatostatin, and the insulin and glucagon secretion of these islets was compared with that of islets incubated in gamma-globulin isolated from nonimmune serum. Islets incubated in antisomatostatin gamma-globulin released significantly more insulin at 4, 8, 16, and 32 mM glucose and significantly more glucagon at 8, 16, and 32 mM glucose, P < 0.05-0.005. For glucose-stimulated insulin release the threshold was decreased, the Vmax was increased, but the apparent Km was unaltered; for glucose-suppression of glucagon release the threshold was increased, maximal suppression was decreased, but the apparent Ki was unaltered. The augmentative effect of the antisomatostatin gamma-globulin was most prominent at 4 mM glucose for insulin release and at 8mM glucose for glucagon release, but was not limited to glucose since both insulin and glucagon release stimulated by arginine were also augmented by antisomatostatin gamma-globulin. These results provide evidence that endogenous somatostatin may act as a physiologic local regulator of both insulin and glucagon secretion and that its effect on insulin and glucagon secretion is dependent on the prevailing glucose concentration.     

Interleukin 1 inhibits insulin secretion from isolated perifused rat islets

Preincubation of collagenase-isolated rat islets for 150 min with 100 U/ml purified human interleukin 1 (IL-1) altered their ability to secrete insulin. Whereas basal release rates with 4 mM glucose were comparable in control and IL-1-treated islets, both the first and second phases of release in response to 20 mM glucose were significantly reduced from IL-1-treated tissue. IL-1 pretreatment also impaired the secretory response to the combination of 100 nM cholecystokinin plus 7 mM glucose. However, the secretory response to 10 mM alpha-ketoisocaproate was comparable in control and IL-1-pretreated islets. Reducing the IL-1 exposure time to 60 min was accompanied by an augmented first phase of release to 20 mM glucose. Second phase secretion was diminished. The use of glucose measured after the perifusion was similar in control and IL-1-treated islets. Similar to other compounds that adversely impact on beta-cell viability, the inhibitory effect of IL-1 on release may presage a cytotoxic action of monokine.     

Phosphoinositide hydrolysis and insulin release from isolated perifused rat islets. Studies with glucose

The ability of glucose to promote the hydrolysis of prelabeled [2-3H]inositol-containing phosphoinositides (PI) was assessed by measuring the efflux of 3H in response to glucose and the accumulation of labeled inositol phosphates. The inclusion of nonradioactive inositol (1 mM) in the perifusion medium dramatically improved our ability to monitor glucose-induced increases in 3H efflux. Efflux studies with this method revealed the following. 1) 3H efflux is significantly greater at 7 than at 2.75 mM glucose, and this parallels a small but significant increase in insulin secretion. 2) D-manno-Heptulose reduces 3H efflux with 7 mM glucose to a level approximating that seen in the presence of 2.75 mM glucose and has no effect on 3H efflux with 2.75 mM glucose. 3) In the presence of 20 mM glucose plus 1 mM inositol, 3H efflux is rapid and biphasic, a response that parallels the timing and amplitude of the biphasic pattern of insulin secretion. Direct measurements of labeled inositol and inositol phosphate levels in islets revealed the following. 4) After 50 min of perifusion with 2.75 or 7 mM glucose, labeled inositol phosphates were significantly greater with 7 mM glucose. 5) In response to 20 mM glucose alone, islet levels of free inositol, inositol monophosphate (IP1), and inositol bisphosphate (IP2) increased. 6) In response to 20 mM glucose plus 1 mM cold inositol, islet levels of free inositol increased, whereas islet levels of IP1, IP2, and inositol trisphosphate (IP3) were reduced compared with values obtained with 20 mM glucose alone.(ABSTRACT TRUNCATED AT 250 WORDS)     

The third phase of in vitro insulin secretion. Evidence for glucose insensitivity

In this study, in vitro B-cell models are described, which may be applicable for studying the reported B-cell desensitization produced by hyperglycemia in IDDM and NIDDM. Using a programmable perifusion/perfusion system, insulin secretion from perifused islets was measured at 10-30-min intervals for 24-50 h. After 3-4 h continuous glucose (11 mM), a new phase of insulin release occurs in which secretion declines to, and remains at, approximately 25% maximal release. Results were similar when using: perifused islets embedded in Cytodex 3, or Bio-Gel P-2, 100-200 mesh; batchincubated islets with hourly changes of medium; and the isolated pancreas perfused for 8 h. Three different media, Hana HB 104 (fortified, fully defined medium), RPMI-1640 + 10% FBS, and perfusion bufferalbumin, were used. Despite reduced secretion to continuous glucose, each system responded vigorously to an acute stimulation with glucose-forskolin. Decreased secretion was primarily caused by decreased secretagogue efficiency (reduced fractional secretion). Prolonged stimulation with glucose or glucose-IBMX produced a similar waning of secretion regardless of the amount of insulin released. It is concluded that the third phase of insulin secretion may represent a secret-agogue-induced, signal desensitization of the B-cell, rather than exhaustion of a B-cell compartment of stored insulin.     

Physiological role of cholecystokinin in meal-induced insulin secretion in conscious rats. Studies with L 364718, a specific inhibitor of CCK-receptor binding

It has been suggested that the gut hormone cholecystokinin (CCK), by modulating insulin output from pancreatic beta-cells, plays an important role in the enteroinsular axis. To investigate this hypothesis, eight rats were studied on two different occasions: after injection of L 364718, a specific antagonist of CCK binding to its membrane receptor, and after vehicle injection. In both studies a mixture of casein (11%) and glucose (9%) was infused through a chronic indwelling intraduodenal catheter to evoke CCK secretion. Plasma was analyzed for insulin, glucose, glucagon, and tyrosine many times during the procedure. Prior administration of the CCK antagonist significantly attenuated the increase in plasma insulin and glucagon after casein infusion. These results support the concept that cholecystokinin plays an important physiologic role in the in vivo regulation of postprandial plasma insulin and glucagon concentrations after protein ingestion.     

Effects of monensin on conversion of proinsulin to insulin and secretion of newly synthesized insulin in isolated rat islets

When isolated rat islets were incubated with 10(-10) - 10(-6) M monensin, a sodium and proton ionophore, glucose-stimulated insulin release was inhibited in a concentration- and time-dependent manner. After removal of monensin, inhibition of insulin secretion persisted during stimulation with a variety of secretagogues, including 5 mM glucose plus 15 mM arginine, 20 mM glucose, and 20 mM glucose plus 1 mM 3-isobutyl-1-methylxanthine. Within the same low range of monensin concentrations, proteolytic conversion of newly synthesized proinsulin to insulin was also blocked. At each concentration, prohormone-to-hormone conversion was inhibited to almost the same extent as inhibition of insulin secretion. Therefore, both processes may have equal or common dependency on a subcellular ionic gradient. Although monensin decreased total insulin secretion, the glucose-regulated marking process was unaffected. Regardless of the monensin concentration or the overall rate of insulin secretion, the percentage of secreted newly synthesized versus older insulin remained the same, and the threefold differences in the fractional secretory rates of newly synthesized versus total insulin also remained the same. Thus, rather than specifically blocking protein traffic through the Golgi apparatus of the beta cell, monensin probably first inhibited insulin secretion by disrupting proton gradients in secretory vesicles and, thereby, also inhibited other processes occurring within this organelle.     

Insulin secretion in vitro and insulin binding to isolated hepatocytes in congenic mice with different H-2 complexes

Congenic male mice with differences in the H-2 complex have been used to investigate insulin secretion in vitro, insulin binding to isolated hepatocytes, plasma glucose, and serum insulin. Plasma glucose and serum insulin did not show consistent differences in the B10.BR, B10.D2, B10.A, B10.G, B10.M, B10.S, C57/10SCSN, and C3H.OH strains. Isolated islets of Langerhans responded to stimulation with 400 mg/dl glucose with a 3-5-fold increase in insulin secretion rates (2P less than 0.01): B10.BR greater than B10.M greater than C57BL/10SCSN greater than B10.G greater than C3H.OH, B10.D2, B10.A, B10.S. The biphasic pattern of insulin secretion was less distinct in B10.M, B10.G, and C3H.OH mice. The high-affinity constants of insulin binding to isolated hepatocytes at 37 degrees C varied between 4.5 X 10(7) L X mol-1 and 4.5 X 10(8) L X mol-1 (2P less than 0.01): B10.A greater than B10.BR greater than C57BL/10SCSN, B10.S, B10.D2 greater than B10.M, B10.G. The glucose-stimulated insulin secretion from isolated islets of Langerhans and the binding of insulin to isolated hepatocytes correlate to the H-2 complex independently.