ß-Cell adaptation in pregnancy.

Pregnancy in placental mammals places unique demands on the insulin-producing ß-cells in the pancreatic islets of Langerhans. The pancreas anticipates the increase in insulin resistance that occurs late in pregnancy by increasing ß-cell numbers and function earlier in pregnancy. In rodents, this ß-cell expansion depends on secreted placental lactogens that signal through the prolactin receptor. Then at the end of pregnancy, the ß-cell population contracts back to its pre-pregnancy size. In the current review, we focus on how glucose metabolism changes during pregnancy, how ß-cells anticipate these changes through their response to lactogens and what molecular mechanisms guide the adaptive compensation. In addition, we summarize current knowledge of ß-cell adaptation during human pregnancy and what happens when adaptation fails and gestational diabetes ensues. A better understanding of human ß-cell adaptation to pregnancy would benefit efforts to predict, prevent and treat gestational diabetes.

Somatostatin coordinately regulates glucagon gene expression and exocytosis in HIT-T15 cells.

Somatostatin (SRIF) regulates secretion from several endocrine cell types. SRIF inhibits both insulin and glucagon secretion and reduces insulin gene expression. However, whether SRIF inhibition of glucagon secretion from the pancreatic alpha cell is mediated via pertussis toxin-sensitive G-proteins is not presently known, nor has it been determined whether SRIF can regulate glucagon gene expression. Consequently, we performed studies in the transformed islet cell line HIT-T15 to determine whether the inhibitory effect of SRIF on glucagon exocytosis is preserved in this cell line, whether this effect is mediated through a pertussis toxin-sensitive mechanism, and whether SRIF has an inhibitory effect on glucagon gene expression. Confocal microscopy with immunostaining revealed that 15-25% of HIT-T15 cells contained glucagon. In static incubations forskolin (FSK, 1 microM) increased glucagon secretion 3.6 +/- 0.9-fold (P < 0.01) and mixed amino acids (15 mM) increased glucagon secretion 2.8 +/- 0.4-fold (P < 0.01). Addition of SRIF significantly inhibited both forskolin- and amino acid-stimulated secretion. Maximal inhibition of both FSK- and amino acid-stimulated secretion occurred at SRIF concentrations > or = 10(-8) M and these inhibitory effects were completely prevented by pertussis toxin pretreatment. In addition to inhibiting glucagon secretion, SRIF significantly reduced both basal and FSK-stimulated glucagon mRNA levels and this reduction in glucagon mRNA was completely prevented by the addition of cyclic AMP analogue. Glucagon gene promoter activity, as assessed by transient transfection experiments, was stimulated 2.1 +/- 0.25-fold by forskolin (P < 0.01). This effect was significantly inhibited by SRIF (71 +/- 4% reduction from FSK alone, P < 0.04) suggesting that SRIF inhibition of the glucagon promoter may, at least in part, account for the observed decrease in glucagon mRNA levels. These studies uniquely demonstrate that glucagon secretion from the HIT-T15 cell line is inhibited by SRIF through a pertussis toxin-sensitive mechanism and that SRIF also inhibits glucagon gene expression in part by reducing glucagon promoter activity. These findings indicate that SRIF can coordinately regulate glucagon delivery by the alpha cell both at the level of gene expression and hormone exocytosis.

Glucose- and GTP-dependent stimulation of the carboxyl methylation of CDC42 in rodent and human pancreatic islets and pure beta cells. Evidence for an essential role of GTP-binding proteins in nutrient-induced insulin secretion.

Several GTP-binding proteins (G-proteins) undergo post-translational modifications (isoprenylation and carboxyl methylation) in pancreatic beta cells. Herein, two of these were identified as CDC42 and rap 1, using Western blotting and immunoprecipitation. Confocal microscopic data indicated that CDC42 is localized only in islet endocrine cells but not in acinar cells of the pancreas. CDC42 undergoes a guanine nucleotide-specific membrane association and carboxyl methylation in normal rat islets, human islets, and pure beta (HIT or INS-1) cells. GTPgammaS-dependent carboxyl methylation of a 23-kD protein was also demonstrable in secretory granule fractions from normal islets or beta cells. AFC (a specific inhibitor of prenyl-cysteine carboxyl methyl transferases) blocked the carboxyl methylation of CDC42 in five types of insulin-secreting cells, without blocking GTPgammaS-induced translocation, implying that methylation is a consequence (not a cause) of transfer to membrane sites. High glucose (but not a depolarizing concentration of K+) induced the carboxyl methylation of CDC42 in intact cells, as assessed after specific immunoprecipitation. This effect was abrogated by GTP depletion using mycophenolic acid and was restored upon GTP repletion by coprovision of guanosine. In contrast, although rap 1 was also carboxyl methylated, it was not translocated to the particulate fraction by GTPgammaS; furthermore, its methylation was also stimulated by 40 mM K+ (suggesting a role which is not specific to nutrient stimulation). AFC also impeded nutrient-induced (but not K+-induced) insulin secretion from islets and beta cells under static or perifusion conditions, whereas an inactive structural analogue of AFC failed to inhibit insulin release. These effects were reproduced not only by S-adenosylhomocysteine (another methylation inhibitor), but also by GTP depletion. Thus, the glucose- and GTP-dependent carboxyl methylation of G-proteins such as CDC42 is an obligate step in the stimulus-secretion coupling of nutrient-induced insulin secretion, but not in the exocytotic event itself. Furthermore, AFC blocked glucose-activated phosphoinositide turnover, which may provide a partial biochemical explanation for its effect on secretion, and implies that certain G-proteins must be carboxyl methylated for their interaction with signaling effector molecules, a step which can be regulated by intracellular availability of GTP.

Insulin secretion in mammosomatotropic tumor-bearing and pregnant rats. A role for lactogens.

The experiments reported here investigate the effects of two conditions of elevated lactogen activity on the threshold of glucose stimulation of insulin secretion and suprathreshold, glucose-stimulated insulin secretion in the isolated, perfused rat pancreas. In both the tumor-bearing animals and pregnant animals, the glucose threshold for insulin release was markedly reduced and the suprathreshold insulin release was elevated over that observed in control pancreata. There was no change on the glucose threshold or extent of release of somatostatin secretion. Altered insulin secretion appears to be readily reversible, since the secretion profile from postlactating animals was not different from the controls. The possible mechanistic role of lactogens is discussed.

Dissociation of glucose stimulation of somatostatin and insulin release from glucose inhibition of glucagon release in the isolated perfused rat pancreas.

This study investigated the modulating role of glucose on 5 mM arginine stimulation of insulin, somatostatin, and glucagon release from the isolated perfused rat pancreas. As the concentration of glucose was increased linearly from 50 to 300 mg/dl, arginine-stimulated glucagon release was inhibited, with half-maximal inhibition occurring at 84 mg/dl glucose. As glucose increased above 80 mg/dl, somatostatin and insulin release was initiated and they continued to increase in a nearly parallel fashion during the glucose gradient (300 mg/dl). When 5 mM arginine was presented "en block" against varying backgrounds of glucose (30, 60, 75, 90, 120, 150, and 300 mg/dl), glucagon release was diminished in the presence of glucose concentrations greater than 60 mg/dl. Arginine elicited insulin release at all glucose concentrations and was significantly augmented in the presence of glucose greater than 90 mg/dl. Arginine-stimulated somatostatin release was detectable in the 90-mg/dl glucose group and was significantly augmented in the 120- and 150-mg/dl glucose treatment groups. In conclusion, these studies indicate that glucose modulates the arginine effect on alpha, beta, and delta cells; and alpha cells have a lower threshold to glucose than beta and delta cells. Glucose inhibits arginine-stimulated glucagon release in the absence of a detectable glucose or arginine stimulation of somatostatin release. Thus, glucose appears to play a major role in the control of the putative hormonal influence among the islet cells.

Immunohistochemical localization of aldose reductase. I. Enzyme purification and antibody preparation--localization in peripheral nerve, artery, and testis.

Aldose reductase (AR) was purified from rat and bovine seminal vesicles using DEAE-cellulose, hydroxylapatite, and Sephadex-gel column chromatography. The purification resulted in the obtention of an AR pool and a contaminating pool. Antibodies were raised in rabbits against both enzymes by subcutaneous injection of the AR pool. The antisera was judged to be specific for AR by immunoprecipitation of AR activity and by Ouchterlony double immunodiffusion and immunoelectrophoretic methods. Antibodies against rat AR were used in the unlabeled antibody-enzyme (PAP) technique to demonstrate the cellular location of the enzyme in a number of tissues known to be sites of diabetic lesions. Antibodies against bovine AR were not cross reactive with the rat enzyme, as determined by Ouchterlony and competitive protein-binding studies. AR was localized in rat tissues to the Schwann cell sheath of peripheral nerve, arterial endothelium, and the sustentacular (Sertoli) cells and mature spermatids of the testis.

Immunohistochemical localization of aldose reductase. II. Rat eye and kidney.

Aldose reductase (AR) was purified from rat seminal vesicles. Specific antibodies to this enzyme were prepared in rabbits and were used in the unlabeled antibody-enzyme (PAP) technique to localize AR in a number of tissues known to be sites of diabetic lesions. AR was localized in the following structures in the eye: lens epithelial lining and cortical lenticular fibers; corneal endothelium; the inner, nonpigmented layer of ciliary body epithelium and its extension as the posterior surface of the iris; and neuroglial (Müller) cells in the retina. Retinal capillary endothelium did not contain immunoreactive AR. In the kidney, staining was intense in the inner medulla. Specific structures included thin limbs of the loop of Henle, collecting tubules deep in the inner medulla, and transitional epithelial cells lining the pelvic space: structures in the cortex including glomerular podocytes and distal convoluted tubules. Collecting tubules in the outer medulla and cortex, as well as proximal convoluted tubules and glomerular capillary endothelium did not contain immunoreactive AR.

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.

An immunohistochemical, ultrastructural, and physiologic study of pancreatic islets from copper-deficient, penicillamine-treated rats.

Murine copper deficiency induced by diet and supplemented with a copper chelator is known to produce a progressive atrophy of pancreatic acinar tissue largely replaced by noninflammatory lipomatosis, while the ductal and endocrine systems appear to remain unaffected. The islets were studied morphologically and physiologically in animals rendered copper deficient by diet and supplemented with D-penicillamine. Using immunohistochemistry, the distribution of islet cell types from copper-deficient animals exhibited a normal cellular complement for A-, B-, D-, and PP-cells. Ultrastructural analysis showed the islet tissue remains normal in appearance during the course of the metal-deficient state. Physiologic data based on the response of islets to a low- and high-glucose load in perfused, isolated pancreata as well as intravenous glucose tolerance tests indicated that insulin-secreting B-cells were functionally normal. Because of the accessibility of islets enhanced by atrophy of acini, this model may be adopted for the isolation of viable islets and for in situ physiologic studies of islet hormone secretion.

Increased dye coupling in pancreatic islets from rats in late-term pregnancy.

Our previous studies have suggested that elevated lactogen, increased glucose-stimulated insulin secretion, and increased beta-cell coupling are associated. To determine whether this association occurs under conditions of physiologically increased lactogen, we have studied the extent of dye coupling in rat islets during the later stage of pregnancy. These animals have high plasma lactogen levels in the form of placental lactogen, increased plasma insulin, and decreased plasma glucose. The fluorescent tracer, Lucifer yellow CH, was microinjected into central cells of islets from both pregnant and virgin rats, and the extent of transfer was quantitated by determining the projected area of dye spread. Two area measurements were made for each injection, one around the entire discernible fluorescent region ("outer") and another around the distinct brighter region of cells surrounding the injected cell ("inner"). Pregnancy increased dye transfer, as determined by both measurements. The outer area of dye transfer was 9047 +/- 775 microns2 for the islets from pregnant rats and 4699 +/- 391 microns2 for the islets from virgin rats (P less than .001). Similarly, pregnancy increased the inner area of dye transfer, 1447 +/- 161 microns2 for the islets from pregnant rats and 795 +/- 80 microns2 for the islets from virgin rats (P less than .001). These results support the hypothesis that elevated lactogen, increased glucose-stimulated insulin secretion, and increased beta-cell dye coupling are associated under physiological conditions. The study indicates that enhanced beta-cell coupling is part of the structural and functional adaptation that the islets undergo during a subject's pregnancy and demonstrates that the extent of beta-cell coupling is regulated by a physiological condition.

Effect of muscimol on glucose-stimulated somatostatin and insulin release from the isolated, perfused rat pancreas.

This study examines the effect of muscimol, a high affinity, specific gamma-aminobutyric acid (GABA) agonist, on glucose-stimulated somatostatin and insulin release from the isolated, perfused rat pancreas. Perfusion with low glucose (50 mg/dl) conditions resulted in basal somatostatin release of 46 +/- 4 pg/ml. Basal insulin release was less than 20 microU/ml. High glucose (300 mg/dl) conditions stimulated somatostatin and insulin release. Steady-state levels of somatostatin and insulin release under high glucose conditions were 425 +/- 12 pg/ml and 419 +/- 18 microU/ml, respectively. Perfusion with medium containing 1 microM muscimol inhibited glucose-stimulated somatostatin release by 38%, whereas the course of glucose-stimulated insulin release was unaffected. Tentative conclusions from this study are (1) that GABA is potentially a modulator of islet somatostatin but not insulin release, and (2) the fact that somatostatin, an inhibitor of insulin, can be suppressed 38% without coincidental increase in insulin release seems to indicate that, under high glucose conditions, somatostatin is without a significant paracrine effect on the beta-cells.

Cysteamine blocks somatostatin secretion without altering the course of insulin or glucagon release. A new model for the study of islet function.

Cysteamine (300 mg/kg) administered subcutaneously depletes pancreatic somatostatin to 36% of control levels, but does not alter pancreatic insulin or glucagon content. Although perfusion of pancreata from normal animals with glucose (300 mg/dl) markedly stimulated somatostatin release, pancreata from cysteamine-treated animals failed to secrete somatostatin in response to glucose. Cysteamine treatment was without effect on insulin and glucagon release under the conditions tested. The isolated perfused pancreas from the cysteamine-treated rat provides a model for further investigations into regulation of islet hormone release in the absence of stimulated somatostatin release.

Structural and functional considerations of GABA in islets of Langerhans. Beta-cells and nerves.

gamma-Aminobutyric acid (GABA), a prominent inhibitory neurotransmitter, is present in high concentrations in beta-cells of islets of Langerhans. The GABA shunt enzymes, glutamate decarboxylase (GAD) and GABA transaminase (GABA-T), have also been localized in islet beta-cells. With the recent demonstration that the 64,000-M, antigen associated with insulin-dependent diabetes mellitus is GAD, there is increased interest in understanding the role of GABA in islet function. Only a small component of beta-cell GABA is contained in insulin secretory granules, making it unlikely that GABA, coreleased with insulin, is physiologically significant. Our immunohistochemical study of GABA in beta-cells of intact islets indicates that GABA is associated with a vesicular compartment distinctly different from insulin secretory granules. Whether this compartment represents a releasable pool of GABA has yet to be determined. GAD in beta-cells is associated with a vesicular compartment, similar to the GABA vesicles. In addition, GAD is found in a unique extensive tubular cisternal complex (GAD complex). It is likely that the GABA-GAD vesicles are derived from this GAD-containing complex. Physiological studies on the effect of extracellular GABA on islet hormonal secretion have had variable results. Effects of GABA on insulin, glucagon, and somatostatin secretion have been proposed. The most compelling evidence for GABA regulation of islet hormone secretion comes from studies on somatostatin secretion, where it has an inhibitory effect. We present new evidence demonstrating the presence of GABAergic nerve cell bodies at the periphery of islets with numerous GABA-containing processes extending into the islet mantle. This close association between GABAergic neurons and islet alpha- and delta-cells strongly suggests that GABA inhibition of somatostatin and glucagon secretion is mediated by these neurons. Intracellular beta-cell GABAA and its metabolism may have a role in beta-cell function. New evidence indicates that GABA shunt activity is involved in regulation of insulin secretion. In addition, GABA or its metabolites may regulate proinsulin synthesis. These new observations provide insight into the complex nature of GABAergic neurons and beta-cell GABA in regulation of islet function.

Prolactin enhances cell-to-cell communication among beta-cells in pancreatic islets.

To determine the role of prolactin in increasing junctional communication among islet beta-cells, we studied dye coupling in pancreatic islets exposed to elevated levels of prolactin in vivo and in vitro. Islets were isolated from rats immediately after lactation or from rats bearing mammosomatotropic tumors (MtTW15), conditions involving high levels of prolactin (either 5-fold or 1000-fold control levels, respectively). When beta-cells were microinjected with the gap junction permeant dye Lucifer yellow CH, the mean number of dye-coupled cells per injection was approximately 10-fold greater than in islets from virgin control rats. As a more direct test of the effects of prolactin on beta-cell coupling, islets isolated from virgin rats were treated for 90 min with 500 ng/ml rat prolactin in the presence of low glucose (2.8 mM) and were microinjected with dye. The mean number of dye-coupled cells per injection increased by 6.7-fold over controls with low glucose, demonstrating a direct effect of prolactin on beta-cell coupling. In vitro treatment with high glucose (16.7 mM) resulted in a 2.7-fold increase in dye-coupled cells per injection. We discuss the possible relationship between the effects of glucose and of prolactin on coupling.

Three-dimensional imaging of intact isolated islets of Langerhans with confocal microscopy.

We present a new technique for analyzing the three-dimensional structure of intact isolated islets of Langerhans. Adult rat and human islets were stained with whole-mount immunofluorescence techniques and optically sectioned with a confocal microscope. This has several advantages over traditional methods: 1) the technical difficulties in serial sectioning and handling the large numbers of sections are avoided, 2) optical sectioning by confocal microscopy gives improved resolution and strongly suppresses light from out-of-focus structures, and 3) entire islets can be rapidly imaged for the presence of positive staining. This new technique should facilitate the study of the three-dimensional structure of islets of Langerhans.

Role of cAMP in upregulation of insulin secretion during the adaptation of islets of Langerhans to pregnancy.

Islets undergo a number of upregulatory changes to meet the increased demand for insulin during pregnancy, including an increase in glucose-stimulated insulin secretion with a reduction in the stimulation threshold. Treatment with the lactogenic hormone prolactin (PRL) in vitro has been shown to induce changes in islets similar to those observed during pregnancy. We examined cAMP production in islets treated with PRL to determine if changes in cAMP are involved in the upregulation of insulin secretion. Insulin secretion and cAMP concentrations were measured from islets in response to a suprathreshold (6.8 mmol/l) or high (16.8 mmol/l) glucose concentration in the presence of the phosphodiesterase inhibitor isobutylmethylxanthine. Insulin secretion increased by 2.1-, 5.0-, and 5.9-fold at the suprathreshold glucose concentration and by 1.6-, 2.3-, and 2.9-fold at the higher glucose concentration after 1, 3, and 5 days of PRL treatment, respectively. After a similar pattern, cAMP metabolism increased by 1.2-, 1.6-, and 2.1-fold at the suprathreshold glucose concentration and by 1.2-, 1.7-, and 2.2-fold at the high glucose concentration after 1, 3, and 5 days of PRL treatment, respectively. The similar increases in insulin secretion and cAMP concentration suggest that changes in cAMP metabolism are involved in lactogen-induced upregulation of insulin secretion. To gain additional insight into the role of cAMP in the upregulation of islet function after lactogen treatment, we examined the relationship between changes in cAMP concentration and insulin secretion. Under all conditions (differing glucose concentrations and time periods), the increase in insulin release was directly proportional to the increase in cAMP. Thus increased glucose-stimulated insulin secretion from lactogen-treated islets could be accounted for by increased generation of cAMP and did not appear to require any further specific changes in intracellular processes mediated by cAMP. Because the PRL receptor is not directly involved in cAMP metabolism, the lactogen-induced increase in cAMP was most likely due to the increase in glucose metabolism that we have previously demonstrated in PRL-treated islets and in islets during pregnancy.

Immunoperoxidase demonstration of human serum globulin binding to islet tissue.

Sera from juvenile diabetic and nondiabetic controls were tested, using the immunoperoxidase method, for the presence of islet-binding immunoglobulins. All diabetic sera tested contained an islet-binding protein and on the average the sera were more positive than age-matched controls. Normal adult sera are undifferentiated from juvenile diabetic sera. Most sera from children less than two years of age did not bind to islet tissue and sera from cystic fibrosis patients had a markedly diminished ability to bind to islet tissue. The binding protein appears to be an immunoglobulin which selectively reacts with elements of the islet beta cell.

Regulation of islet beta-cell proliferation by prolactin in rat islets.

This study examined the effects of prolactin on beta-cell proliferation in pancreatic islet of Langerhans. Insulin secretion and beta-cell proliferation were significantly increased from neonatal rat islets cultured for 4 days in the presence of either 500 ng/ml ovine prolactin (oPRL) or rat prolactin (rPRL). These effects could be prevented by including anti-oPRL serum in the culture media. Although insulin secretion and beta-cell proliferation were slightly higher during the first 24 h of exposure to rPRL, maximal response was observed after 4 days for insulin secretion and 6-10 days for beta-cell proliferation. The initial mitogenic response of beta-cell to rPRL occurred by the limited recruitment of nondividing beta-cells into the cell cycle and by most daughter cells proceeding directly into additional cell division cycles. Subsequently, the maximal effect of rPRL on beta-cell proliferation was maintained by a higher rate of recruitment of previously nondividing beta-cells into cell cycle with only one fourth of the daughter cells continuing to divide. These observations are difficult to reconcile with the proposal that a limited pool of beta-cells capable of undergoing cell division exists in islets. Instead, these observations suggest that individual beta-cells are transiently re-entering the cell cycle and dividing infrequently in response to rPRL. In this case, the majority of the beta-cells would not be expected to be in an irreversible Go phase. We also demonstrated that the effects of rPRL on beta-cell proliferation occur at normal serum glucose concentrations and are affected by inhibitors of polyamine metabolism. Additional studies on the effects of rPRL on beta-cells should provide important information on the regulation of beta-cell proliferation during conditions of increased insulin demand.

Glucose stimulation of somatostatin and insulin release from the isolated, perfused rat pancreas.

Insulin and somatostatin release from the isolated perfused rat pancreas was studied under conditions of 50 and 300 mg/dl glucose as well as a linear 50-300 mg/dl glucose gradient. The glucose-stimulated response profile of somatostatin was nearly parallel to that of insulin in both the acute and gradient dose experiments. Antisomatostatin serum was without significant effect on glucose-stimulated insulin release. In spite of the marked, fifteenfold stimulation of somatostatin release (1.5 x 10-10 M in the perfusate effluent) by glucose, the concentration of somatostatin was insufficient to significantly alter glucose-stimulated insulin release in the isolated perfused rat pancreas.

Morphological and functional characterization of beta TC-6 cells--an insulin-secreting cell line derived from transgenic mice.

Morphological analysis of hormone content and functional assessment of hormone secretion were conducted in beta TC-6 cells, an insulin-secreting cell line derived from transgenic mice expressing the large T-antigen of simian virus 40 (SV40) in pancreatic beta-cells. We observed by immunohistochemistry and confocal microscopy that beta TC-6 cells contain abundant insulin and small amounts of glucagon and somatostatin (SRIF). Glucagon usually co-localized with insulin, whereas cells containing SRIF did not contain insulin or glucagon. Static incubation and perifusion experiments demonstrated that beta TC-6 cells at passage 30-45 secrete insulin in response to glucose. In static incubations, maximal stimulation was achieved for glucose concentrations > 2.8 mmol/l glucose, and the half-maximal effect was observed at 0.5 mmol/l. Maximal stimulation was four times greater than HIT-T15 cells at passage 72-81, although HIT cells had a greater response over their basal levels. The magnitude of the insulin response to glucose in perifusion was 1,734 +/- 384 pmol.l-1. min and was 4.6-fold greater in the presence of 3-isobutyl-1-methylxanthine. Low amounts of glucagon were released in response to amino acids. Epinephrine (EPI), and to a lesser extent SRIF, inhibited phasic glucose-induced insulin secretion. A major portion of these inhibitory effects was mediated by pertussis toxin-sensitive substrates. Immunoblots detected the presence of the G-proteins Gi alpha 2, Gi alpha 3, and Go alpha 2. These results indicate that beta TC-6 cells are a glucose-responsive cell line in which insulin exocytosis is physiologically regulated by EPI and SRIF through Gi/Go-mediated mechanisms.