Effect of gastrin-releasing peptide on the secretion of mouse islet hormones in vitro

Collagenase-isolated mouse islets were incubated with gastrin-releasing peptide (GRP). At 5.6 mmol glucose/l. 10 nmol GRP/l increased the release of insulin (by 50%) and glucagon (by twofold), decreased the release of pancreatic polypeptide (by 35%), but did not significantly affect the release of somatostatin. At 16.7 mmol glucose/l, 10 nmol GRP/l increased glucagon release (by fivefold) and decreased pancreatic polypeptide release (by 46%), without significantly altering insulin and somatostatin release. GRP (200 nmol/l) did not affect insulin release by perifused mouse islets at 2.8 mmol glucose/l, but increased both first and second phase insulin release after a square wave increase in the glucose concentration to 11.1 mmol/l. At 5.6 mmol glucose/l, GRP (100 pmol/1-100 nmol/l) increased (by 50-70%) insulin release by the RINm5F clonal cell line. GRP did not affect glucose oxidation or the cyclic adenosine monophosphate content of RINm5F cells. However, the intracellular free Ca2+ concentration of RINm5F cells was rapidly and transiently increased by GRP (maximum increase of 64% about 10 s after exposure to 1 mumol GRP/l). The rise of intracellular free Ca2+ was approximately halved in the absence of extracellular Ca2+. The results suggest that GRP may contribute to the normal regulation of the endocrine pancreas. The insulin-releasing effect of GRP is mediated via increased cytosolic free Ca2+, derived both from an increased net influx of extracellular Ca2+ and from mobilization of intracellular Ca2+ stores.     

Effects of growth hormone-releasing hormone on the secretion of islet hormones and on glucose homeostasis in lean and genetically obese-diabetic (ob/ob) mice and normal rats

The effect of synthetic human growth hormone-releasing hormone(1-40) (hGHRH-40) on the function of the endocrine pancreas and on glucose homeostasis in lean and genetically obese-diabetic (ob/ob) mice and normal rats has been examined. The addition of 1 mumol hGHRH-40/1 to incubated islets from normal lean mice increased insulin release by 90 and 37% at 5.6 and 16.7 mmol glucose/l respectively. Lower concentrations of hGHRH-40 did not affect insulin release. hGHRH-40 (1 mumol/l) increased pancreatic polypeptide release by 50% at 5.6 mmol glucose/l. A range of concentrations of hGHRH-40 (1 nmol/l-1 mumol/l) reduced glucagon release by 42-73% at 5.6 mmol glucose/l, and by 38-70% at 16.7 mmol glucose/l. Somatostatin release was increased (eightfold) by 1 mumol hGHRH-40/1 at 5.6 mmol glucose/1, but at 1 nmol hGHRH-40/1 somatostatin release was reduced (by greater than 50%). At 16.7 mmol glucose/litre 0.01-1 mumol hGHRH-40/1 increased somatostatin release (three- to fourfold), but 1 nmol hGHRH-40/1 produced a reduction of 50%. In vivo, administration of hGHRH-40 (50 micrograms/kg body weight i.p.) to fasted lean and ob/ob mice did not alter basal plasma concentrations of glucose and insulin, or the glucose and insulin responses to a concomitant i.p. glucose challenge. Intravenous injection of hGHRH-40 (20 micrograms/kg body weight) to anaesthetized rats increased plasma concentrations of insulin in the hepatic portal vein. A lower dose of hGHRH-40 (0.2 micrograms/kg) was ineffective, and neither dose of hGHRH-40 altered plasma glucose.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of GIP on the secretion of insulin and somatostatin and the accumulation of cyclic AMP in vitro in the rat

The effects of gastric inhibitory polypeptide (GIP) on insulin secretion as well as on the intra-islet accumulation of [3H]cyclic AMP were investigated in isolated pancreatic islets of the rat. In the presence of 6.7 mmol/l of glucose, 3.0 and 30 nmol/l of GIP induced both insulin and [3H]cyclic AMP responses, while lower and higher concentrations of the peptide were ineffective. A coupling of the two parameters was also found with regard to interaction between glucose and GIP. Thus while 30 nmol/l of GIP was stimulatory together with 6.7, 16.7 or 33.3 mmol/l of glucose, the peptide stimulated neither insulin release, nor the accumulation of [3H]cyclic AMP in the presence of a low concentration of glucose (3.3 mmol/l). The concomittant release of insulin and somatostatin was studied in the perfused pancreas in order to assess a possible influence by somatostatin on the dose-response pattern for GIP-induced insulin release. In this preparation 1.0 to 10 nmol/l of GIP stimulated insulin and somatostatin secretion; however while these concentrations were equipotent on insulin release, 10 nmol/l of GIP stimulated somatostatin release more than 1 nmol/l, indicating differences in dose-response curves for the GIP-induced stimulation of the two hormones. It is concluded that 1) modulation of GIP-induced insulin release is coupled to changes in cyclc AMP response in the islet, 2) GIP-induced somatostatin secretion may influence the concomittant insulin response.     

Cholecystokinin-33 potentiates and vasoactive intestinal polypeptide inhibits gastric inhibitory polypeptide--induced insulin secretion in the perfused rat pancreas

Gastric inhibitory polypeptide (GIP), cholecystokinin (CCK), and vasoactive intestinal polypeptide (VIP) stimulate insulin secretion. In this study we investigated whether CCK-33 and VIP could influence the insulinogenic effect of simultaneously administered GIP and 6.7 mmol/l glucose in the perfused rat pancreas. We found that at 0.1 nmol/l, GIP markedly potentiated glucose-induced insulin release whereas CCK-33 and VIP had a weak stimulatory effect and only during the late phase. At this low dose level, CCK-33 potentiated but VIP inhibited the late phase of insulin release stimulated by glucose and GIP. At 1.0 nmol/l, GIP, CCK-33, and VIP markedly potentiated both phases of glucose-induced insulin secretion. At this dose level CCK-33 and GIP exerted additive stimulatory effects on the late phase of insulin release triggered by glucose. In contrast, 1.0 nmol/l VIP inhibited insulin secretion augmented by glucose and GIP. In summary 1) GIP, CCK-33 and VIP all potentiate glucose-induced insulin secretion from the perfused rat pancreas, and 2) CCK-33 potentiates and VIP inhibits GIP-induced insulin secretion. We suggest that interactions of this kind are of importance for the precise regulation of insulin secretion.     

The interaction of Vasoactive Intestinal Polypeptide (VIP), glucose and arginine on the secretion of insulin,glucagon and somatostatin in the perfused rat pancreas

Summary Vasoactive Intestinal Polypeptide (VIP) increased the release of insulin, glucagon and somatostatin from the perfused rat pancreas. The amount of these hormones released was dependent upon the prevailing glucose concentration. VIP stimulated glucagon release in the absence of glucose, while insulin and somatostatin release were increased by VIP only in the presence of glucose concentrations of 4.4 mmol/l and above. Glucagon secretion stimulated by arginine in the presence of 4.4 mmol/l glucose was potentiated by VIP. In contrast, VIP did not induce any further increase in the secretion of insulin and somatostatin over that stimulated by arginine. At higher concentrations of glucose (6.7, 16.7, and 33.3 mmol/l) VIP continued to stimulate insulin and somatostatin release, this effect being synergistic on early-phase insulin release. The effects of VIP on islet cells thus depend on the levels of modulating nutrients.     

Pancreatic polypeptide,glucagon and insulin secretion from the isolated perfused canine pancreas

Summary The release of pancreatic polypeptide (PP) by gut hormones, acetyl choline and adrenaline was investigated in an isolated perfused pancreas preparation. PP was potently released by 1 nmol/l caerulein (186±12%, p<0.001) and gastric inhibitory peptide (GIP) (211±31%, p<0.005) as well as by 1 [mol/l acetyl choline (1097±59%, p<0.001). A significant two-fold release of PP was also evoked by 1 nmol/l vasoactive intestinal peptide (VIP) (129±38%, p<0.02 and gastrin (108±25% p<0.01). Insulin release, induced by high glucose concentration was enhanced by both GIP (210 ±38%, p<(0.01) and VIP (48±5%, p<0.001). In addition GIP enhanced the release of glucagon by 179±18% (p<0.001) at 1.4 mmol/l glucose and by 127±24% (p<0.005) at 8.3 mmol/l glucose. Thus no simple inter-relationship appears to exist between the control of the three circulating islet hormones.     

Effects of galanin on islet cell secretory responses to VIP, GIP, 8-CCK, and glucagon by the perfused rat pancreas

Exogenous galanin has been shown to suppress insulin secretion as elicited by a number of secretagogues such as glucose, arginine, tolbutamide, carbachol, and oral nutrients. To achieve further insight into the influence of galanin on the endocrine pancreas, we have investigated the effect of synthetic porcine galanin (a 200 ng bolus followed by constant infusion at a concentration of 16.8 ng/mL for 16 to 24 minutes) on unstimulated insulin, glucagon, and somatostatin release, as well as on the responses of these hormones to 1 nmol/L vasoactive intestinal peptide (VIP), 1 nmol/L gastric inhibitory peptide (GIP), 1 nmol/L 26 to 33 octapeptide form of cholecystokinin (8-CCK) or 10 nmol/L glucagon in the perfused rat pancreas. Galanin infusion reduced unstimulated insulin secretion by 60% without modifying glucagon and somatostatin output. Galanin also blocked insulin release elicited by VIP, GIP, and 8-CCK, it did not affect the glucagon responses to VIP and GIP, or the somatostatin responses to VIP, GIP, and 8-CCK. Finally, galanin inhibited the insulin output, but not the somatostatin release induced by glucagon. In conclusion, in the perfused rat pancreas, galanin appears to behave as a general inhibitor of insulin secretion. Since this neuropeptide does not modify glucagon or somatostatin release, a direct effect of galanin on the B-cell seems plausible.     

Effects of glucagon, secretin, and vasoactive intestinal polypeptide on gastric somatostatin and gastrin release from isolated perfused rat stomach

To investigate the role of gastric somatostatin on gastrin secretion, glucagon, secretin, and vasoactive intestinal polypeptide (VIP) were perfused in the isolated pancreas-spleen-duodenum deprived preparation of rat stomach. After a preperfusion with 4.6% dextran Krebs-Ringer bicarbonate buffer containing 5.5 mM glucose, glucagon, secretin, and VIP at the concentrations of 10(-8), 10(-7), and 10(-6) M were infused into the left gastric artery at a constant flow of 2 ml/min for 15 min. All glucagon, secretin, and VIP evoked dose-dependent increases of somatostatin secretion with a simultaneous dose-related decrease of gastrin release. Furthermore, a significant correlation was found between the increase of somatostatin release and the decrease of gastrin secretion induced by glucagon, secretin, and VIP. These results raise the possibility that the suppression of gastrin secretion induced by glucagon, secretin, and VIP may, at least in part, be mediated by local action of gastric somatostatin.     

Pancreastatin inhibits insulin secretion as induced by glucagon, vasoactive intestinal peptide, gastric inhibitory peptide, and 8-cholecystokinin in the perfused rat pancreas

Pancreastatin is a 49-amino acid straight chain molecule isolated from porcine pancreatic extracts. In the perfused rat pancreas, this peptide has been shown to inhibit unstimulated insulin release and the insulin responses to glucose, arginine, and tolbutamide. To further explore the influence of pancreastatin on islet cell secretion, the effect of synthetic porcine pancreastatin (a 2-micrograms priming dose, followed by constant infusion at a concentration of 15.7 nmol/L) was studied on the insulin, glucagon, and somatostatin responses to 1 nmol/L vasoactive intestinal peptide (VIP), 1 nmol/L gastric inhibitory peptide (GIP), and 1 nmol/L 26 to 33 octapeptide form of cholecystokinin (8-CCK). The effect of pancreastatin on the insulin and somatostatin secretion elicited by glucagon (20 nmol/L) was also examined. Pancreastatin infusion consistently reduced the insulin responses to VIP, GIP, and 8-CCK without modifying glucagon or somatostatin release. It also inhibited the insulin release but not the somatostatin output induced by glucagon. These observations broaden the spectrum of pancreastatin as an inhibitor of insulin release. The finding that pancreastatin does not alter glucagon or somatostatin secretion supports the concept that it influences the B cell directly, and not through an A cell or D cell paracrine effect.     

Interaction of glucagon-like peptide-1(7-36) amide and gastric inhibitory polypeptide or cholecystokinin on insulin and glucagon secretion from the isolated perfused rat pancreas.

The interaction of three incretin candidates, glucagon-like peptide-1(7-36)amide (t-GLP-1), gastric inhibitory polypeptide (GIP), and sulfated COOH-terminal octapeptide of cholecystokinin (CCK-8-S), on insulin and glucagon release from the isolated perfused rat pancreas was studied. Under the perfusate condition of 8.3 mmol/L glucose, coinfusion of 0.1 nmol/L t-GLP-1 and 0.1 nmol/L GIP resulted in an augmented insulin release greater than that obtained by the same dose of each peptide alone. The degree of stimulation elicited by t-GLP-1 and GIP reached a plateau at 0.3 nmol/L for both infusates, and no cooperative effect was observed by coinfusion at 0.3 nmol/L. Coinfusion of 0.1 nmol/L t-GLP-1 and and 0.1 nmol/L CCK-8-S also resulted in an augmented insulin release greater than that obtained by the same dose of each peptide alone. A similar cooperative effect was observed by coinfusion at 0.3 nmol/L, 1 nmol/L, and 3 nmol/L. With the same perfusion experiments, glucagon release was not significantly affected by any peptide at concentrations of 0.1, 0.3, 1, or 3 nmol/L. The coinfusion of 1 nmol/L t-GLP-1 and GIP elicited a transient, but significant, increase in glucagon release. A similar result was obtained by the coinfusion of 0.3 nmol/L and 3 nmol/L t-GLP-1 and GIP, respectively. The coinfusion of t-GLP-1 and CCK-8-S did not affect the glucagon release.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of somatostatin on fasting and glucose-stimulated gastric inhibitory polypeptide release in man

The effect of intravenous somatostatin infusion on circulating gastric inhibitory polypeptide (GIP), insulin, glucagon and on blood glucose was investigated in 7 healthy volunteers in the fasting state and during the oral ingestion of 75 g glucose. Somatostatin (1.1 microgram/kg/h) infused 30 min before and continued 60 min after the ingestion of glucose did not affect fasting levels of any of the above parameters while it significantly suppressed the GIP and insulin response to glucose. The same somatostatin dose infused 30 min after the ingestion of glucose decreased significantly the raised levels of GIP and insulin and further increased blood glucose levels. It is concluded that somatostatin inhibits GIP release mainly at the level of the GIP-producing cells.     

Influence of glucagon, gastric inhibitory polypeptide, pancreatic polypeptide and somatostatin on beta-adrenergically induced insulin secretion in the mouse

The effect of four polypeptides, glucagon, Gastric Inhibitory Polypeptide (GIP), Pancreatic Polypeptide (PP) and somatostatin on beta-adrenoceptor stimulated insulin secretion in vivo in the mouse was investigated. The beta-adrenoceptor stimulation was induced by isoprenaline (IPNA). It was found that at dose levels without influence on basal insulin secretion the polypeptides produced the following pattern of interaction with IPNA. Insulin secretion induced by IPNA was increased by glucagon and inhibited by somatostatin. GIP and PP did not change IPNA-induced insulin release. It is concluded from this and earlier published studies that glucagon, but not always GIP, serves as a positive modulator of basal and stimulated insulin secretion, and that somatostatin is a general inhibitor of insulin release. beta-Adrenoceptor-induced insulin secretion however, seems to be less sensitive to somatostatin than insulin release induced by glucose.     

Effects of rat pancreatic polypeptide on islet-cell secretion in the perfused rat pancreas.

Pancreatic polypeptide (PP) secretory cells are abundant in the islets of Langerhans. Results concerning the effects of exogenous PP on islet-cell secretion are controversial. This might be due in part to species specificity, given that most reports refer to studies performed using PP of bovine, porcine, or human origin in a heterologous animal model. Thus, we have investigated the influence of synthetic rat PP (80 nmol/L) on unstimulated insulin, glucagon, and somatostatin release, and on the responses of these hormones to glucose (11 mmol/L) and to arginine (3.5 mmol/L) in a homologous animal model, the perfused rat pancreas. Infusion of rat PP (rPP) reduced unstimulated insulin release by 35% (P = .03), and the insulin responses to glucose by 65% (P = .029) and to arginine by 50% (P = .026), without modifying glucagon output. rPP did not affect somatostatin secretion, either in unstimulated conditions or in the presence of 11 mmol/L glucose. However, it induced a clear-cut increase in somatostatin release during 3.5 mmol/L arginine infusion. Our observation that rPP inhibited insulin secretion without affecting glucagon and somatostatin output points to a direct effect of PP on B-cell function. However, during aminogenic priming of the D cell, the inhibition of insulin output induced by rPP was accompanied by an increase in somatostatin release. Thus, in this circumstance, it might be considered that the blocking effect of PP on B-cell secretion could be, at least in part, mediated by a D-cell paracrine effect.     

The influence of calcium on the basal and acetylcholine-stimulated secretion of pancreatic polypeptide.

The influence of calcium on basal and acetylcholine-stimulated pancreatic polypeptide (PP) secretion was investigated in an isolated pancreatico-duodenal preparation and compared to the secretion of glucagon and insulin. The stimulatory effect of 5 mmol/liter calcium on PP release was of the same magnitude as that obtained by 5 mmol/liter arginine or 10 nmol/liter isoproterenol but only one fifth of the PP response to acetycholine (1 mumol/liter). All stimuli were equipotent with respect to insulin and glucagon release. The acetylcholine (1 mumol/liter)-stimulated PP release was almost identical at calcium concentrations of 1.3 and 6.3 mmol/liter, whereas glucagon release was calcium dependent, with higher responses at high (6.3 mmol/liter) than at normal (1.3 mmol/liter) calcium concentrations. In a calcium-depleted medium, acetylcholine induced a prompt, short-lived, but repeatable PP response, whereas no increase in glucagon or insulin was found. Further, when calcium influx into cells was blocked by excess magnesium (5.0 mmol/liter), the basal and acetylcholine (1 mumol/liter)-stimulated PP secretion was only inhibited by 12% (P = NS) and 42% (2P less than 0.05), respectively, whereas glucagon release was inhibited 56% (2P less than 0.001) and 76% (2P less than 0.01), respectively. It is concluded that the secretion of PP is influenced by calcium ions; however, the PP release is much less dependent on extracellular calcium ions than are insulin and glucagon secretions.     

Effects of cholecystokinin (CCK)-8, CCK-33, and gastric inhibitory polypeptide (GIP) on basal and meal-stimulated pancreatic hormone secretion in man.

Gastrointestinal hormones with insulinotropic effects, like cholecystokinin (CCK) and gastric inhibitory polypeptide (GIP) might tentatively be used in the treatment of non-insulin-dependent diabetes mellitus. We therefore examined the effects of intravenous injection of pharmacological dose levels of CCK-8 (100 and 300 pmol/kg), CCK-33 (100 pmol/kg), GIP (100 pmol/kg), and CCK-8 plus GIP (100 pmol/kg of each) on plasma levels of glucose, insulin, somatostatin, glucagon, and pancreatic polypeptide (PP) in healthy human volunteers. The peptides were given under basal conditions or in combination with a mixed meal. CCK-8, CCK-33, and GIP were all found to increase the basal plasma levels of insulin, somatostatin, and PP; the increases were observed already in samples taken at 2 min after the injection. In contrast, the plasma glucagon levels were unaffected by the peptides. CCK-8, CCK-33, and GIP (100 pmol/kg) all potentiated the meal-induced plasma responses of insulin and PP, whereas plasma levels of glucagon after the meal were not affected. Plasma somatostatin levels after the meal were increased by GIP but not affected by CCK-8 or CCK-33. CCK-8 and GIP together (100 pmol/kg for both) increased plasma levels of insulin, PP and somatostatin as much as each of the peptides given alone, both under basal conditions and after the meal intake. Plasma levels of glucagon were not affected by CCK-8 and GIP together. We conclude that in man, both CCK-8, CCK-33, and GIP moderately stimulate basal and meal related insulin release without any synergistic effects and that the peptides do not inhibit the secretion of glucagon.     

Glucagon-like peptide-1, but not glucose-dependent insulinotropic peptide,inhibits glucagon secretion via somatostatin (receptor subtype 2) in the perfused rat pancreas

Aims/hypothesis  The glucose-lowering effect of glucagon-like peptide-1 (GLP-1) is based not only upon its potent insulinotropic actions but also on its ability to restrain glucagon secretion. Surprisingly, the closely related glucose-dependent insulinotropic peptide (GIP) stimulates glucagon release. We examined whether the islet hormone somatostatin, which strongly inhibits glucagon secretion, is involved in this divergent behaviour. Methods  At 1.5 mmol/l glucose and therefore minimal insulin secretion, the glucagon, insulin and somatostatin responses to 20 mmol/l glucose, GLP-1, GIP and somatostatin were studied in the presence of a high-affinity monoclonal somatostatin antibody and of a highly specific somatostatin receptor subtype 2 (SSTR2) antagonist (PRL-2903) in the isolated perfused rat pancreas. Results  In control experiments, GLP-1 at 1 and 10 nmol/l reduced glucagon secretion significantly to 59.0 ± 6.3% (p < 0.004; n = 5; SSTR2 series; each vs pre-infusion level) and to 48.0 ± 2.6% (p < 0.001; n = 6; somatostatin antibody series) respectively. During somatostatin antibody administration, GLP-1 still inhibited glucagon secretion significantly, but the effect was less pronounced than in control experiments (p < 0.018). Co-infusion of the SSTR2 antagonist completely abolished the GLP-1-induced suppression of glucagon secretion. In contrast, neither the GIP-induced stimulation of glucagon release nor its inhibition by 20 mmol/l glucose was altered by somatostatin antibody or SSTR2 antagonist administration. Conclusions/interpretation  We conclude that GLP-1 is capable of inhibiting glucagon secretion even in the absence of secretory products from the beta cell. It is highly likely that this is mediated via somatostatin interacting with SSTR2 on rat alpha cells. In contrast, GIP and glucose seem to influence the alpha cell independently of somatostatin secretion.     

Correlation of endogenous somatostatin, gastric inhibitory polypeptide, glucagon and insulin with gastric function in the conscious calf

Levels of endogenous somatostatin, gastric inhibitory polypeptide (GIP), glucagon and insulin were measured during gastric (abomasal) emptying in the conscious calf. Isotonic NaHCO3 infused into the duodenum increased rates of emptying of a saline test meal and of gastric acid secretion, but had no effect on basal levels of blood glucose, somatostatin, GIP, insulin or glucagon. By contrast, intraduodenal infusion of 60 mM-HCl caused complete inhibition of gastric emptying, reduction of acid secretion, and an immediate increase in plasma somatostatin from 121.3 +/- 9.4 (S.E.M.) to 286.3 +/- 16.3 pg/ml (P less 0.01) but levels of GIP, insulin, glucagon and glucose were unaltered. Intravenous injection of somatostatin (0.5 microgram/kg) suppressed the antral electromyographic recording and gastri efflux so long as plasma somatostatin levels remained above approx. 200pg/ml. This suggest that somatostatin can be released by intraduodenal acidification and that it inhibits gastric function by an endocrine effect. Since somatostatin retards gastric emptying it may therefore have an indirect role in nutrient homeostasis by limiting discharge of gastric chyme to the duodenum.     

Are ionic fluxes of pancreatic beta cells a target for gastric inhibitory polypeptide?

Gastric inhibitory polypeptide (GIP), an incretin candidate, is suggested to amplify the glucose-induced insulin secretion. To evaluate its mode of action we examined whether GIP affects 86Rb+ efflux, 45Ca2+ uptake or efflux, and intracellularly recorded electrical activity of mouse pancreatic islets. GIP (5 nM) neither inhibited 86Rb+ efflux at 3 mM glucose nor modulated 86Rb+ efflux that was inhibited by 5.6 mM glucose or stimulated by the calcium ionophore A23187. 45Ca2+ uptake was increased by GIP in the presence of 16.7 mM which was not observed at 3 or 11 mM glucose. GIP elevated 45Ca2+ efflux from islets, but did not modify 45Ca2+ efflux when a virtually Ca2+ free medium was used. Electrical activity of beta cells induced by 16.7 mM glucose was significantly increased by 5 nM GIP. It is concluded that the amplification of insulin release by GIP is based on the effect of GIP on Ca2+ uptake.     

The effect of insulin deprivation on fasting levels of 5000 dalton gastric inhibitory polypeptide in type 1 (insulin-dependent) diabetics

To investigate whether metabolic decompensation has an effect on gastric inhibitory polypeptide (GIP), 8 fasting male type 1 diabetics were deprived of insulin for 12 h. An overnight insulin infusion aiming at normoglycaemia was stopped at 08.00 h. During the following 12 h blood glucose increased from 7.0 +/- 0.4 to 14.9 +/- 1.0 mmol/l, P less than 0.01, 3-hydroxy-butyrate from 0.18 +/- 0.07 to 4.00 +/- 0.74 nmol/1, P less than 0.01, and immunoreactive GIP (IR-GIP) from 16.7 +/- 2.6 to 21.9 +/- 2.9 pmol/1, P less than 0.05. The antiserum employed, R65, only measures 5000 dalton IR-GIP. The final IR-GIP concentrations were not significantly different from fasting IR-GIP concentrations in 13 normal male subjects (17.4 +/- 1.5 pmol/1). Short term insulin deprivation therefore is associated with a slight increase in fasting IR-GIP concentrations. Whether this modest increase in IR-GIP significantly enhances insulin secretion is unknown.