Postinhibitory overshoot of insulin release by gastric inhibitory polypeptide

Following intravenous infusion of somatostatin $\text{in vivo}$ occasionally there is a large rebound overshoot of insulin release. An $\text{in vitro}$ model to simulate this phenomenon was made by perfusing rat pancreas with gastric inhibitory polypeptide (GIP) during simultaneous perfusion with somatostatin. Adding GIP (100 ng/ml) to the perfusate for 2 minutes beginning either 3 or 9 minutes before terminating the somatostatin perfusion produced a large overshoot in insulin release. The magnitude of overshoot was greater when medium contained 300 mg/dl glucose that when it contained 150 mg/dl glucose. Perfusion with GIP for 2 minutes beginning 9 minutes before increasing the glucose concentration of the medium from 30 to 300 mg/dl elicited a large increase in both the acute and second-phase release of insulin. These suggest that post-inhibitory overshoot of insulin release after somatostatin may be produces $\text{in vitro}$ by the suppressed action of stimulatory hormones such as GIP. Prior infusion with GIP can also potentiate glucose-stimulated insulin increase.     

Reduction of hepatic insulin clearance after oral glucose ingestion is not mediated by glucagon-like peptide 1 or gastric inhibitory polypeptide in humans

Changes in hepatic insulin clearance can occur after oral glucose or meal ingestion. This has been attributed to the secretion and action of gastric inhibitory polypeptide (GIP) and glucagon-like peptide (GLP)-1. Given the recent availability of drugs based on incretin hormones, such clearance effects may be important for the future treatment of type 2 diabetes. Therefore, we determined insulin clearance in response to endogenously secreted and exogenously administered GIP and GLP-1. Insulin clearance was estimated from the molar C-peptide-to-insulin ratio calculated at basal conditions and from the respective areas under the curve after glucose, GIP, or GLP-1 administration. Oral glucose administration led to an approximately 60% reduction in the C-peptide-to-insulin ratio (P < 0.0001), whereas intravenous glucose administration had no effect (P = 0.09). The endogenous secretion of GIP or GLP-1 was unrelated to the changes in insulin clearance. The C-peptide-to-insulin ratio was unchanged after the intravenous administration of GIP or GLP-1 in the fasting state (P = 0.27 and P = 0.35, respectively). Likewise, infusing GLP-1 during a meal course did not alter insulin clearance (P = 0.87). An inverse nonlinear relationship was found between the C-peptide-to-insulin ratio and the integrated insulin levels after oral and during intravenous glucose administration. Insulin clearance is reduced by oral but not by intravenous glucose administration. Neither GIP nor GLP-1 has significant effects on insulin extraction. An inverse relationship between insulin concentrations and insulin clearance suggests that the secretion of insulin itself determines the rate of hepatic insulin clearance.     

Restricted feeding schedules alter the circadian rhythms of serum insulin and gastric inhibitory polypeptide

Insulin and gastric inhibitory polypeptide (GIP) have a circadian rhythm of secretion that is altered by various feeding schedules. We acclimated rats over 3 weeks to one of 6 different feeding schedules. They were then killed at intervals over one feeding cycle. Blood was collected, and their stomachs were weighed. Hormones in the serum were measured by radioimmunoassay. When highest and lowest measured concentrations were compared in ad libitum fed rats, insulin more than doubled (445 +/- 50 to 993 +/- 180 pg/ml) and GIP more than tripled (682 +/- 108 to 1964 +/- 145 pg/ml) during a 24-h period. With restricted schedules, concentrations correlated with the feeding schedule, not the light-dark cycle. Hormone levels rose higher during feeding and fell lower with fasting than in ad lib fed rats. For example, GIP in one study fluctuated from 468 +/- 22 to 6433 +/- 432 pg/ml. In another example, insulin ranged from 30 +/- 5 to 2259 +/- 406 pg/ml during a 24-h period. However, insulin did not always correlate well with stomach weight. Circadian rhythms occurred for insulin with all feeding schedules and for GIP with all schedules except fasted rats. This finding implies an endogenous insulin rhythm, whereas food intake controls GIP secretion. Thus, disruption of normal circadian cycles of feeding may yield misleading information about gut hormone secretion.     

Effect of cholecystokinin, secretin, and gastric inhibitory polypeptide on insulin release from the isolated perfused rat pancreas

The actions of gastric inhibitory polypeptide (GIP) on insulin release from the isolated perfused rat pancreas were compared with those of pure secretin and cholecystokinin (CCK). At dose levels physiologically achievable for GIP (1 ng/mL perfusate), infusions of CCK stimulated significant insulin release both on a weight (1 ng/mL) and a molar (770 pg/mL) basis. Although 50% as potent as GIP on a weight basis and 43% as potent on a molar basis, the insulin response to CCK was multiphasic and sustained for the duration of the infusion. The action of CCK, like that of GIP, was glucose dependent yielding no significant insulin release at a low perfusate glucose concentration (80 mg/dL). Irrespective of perfusate glucose concentration or dose (1 or 5 ng/mL), secretin failed to stimulate significant release of insulin from the perfused pancreas. It was concluded that secretin is ineffective as an incretin and that a physiological role for CCK in an enteroinsular axis awaits accurate measurement of circulating levels of immunoreactive CCK.     

Effect of bombesin and gastrin-releasing peptide on the release of gastric inhibitory polypeptide and insulin in rats

The objective of this study was to determine whether bombesin- or gastrin-releasing peptide-induced release of insulin occurs before or after the release of gastric inhibitory polypeptide (GIP) in rats. The present results demonstrate that GIP release occurs before insulin release and suggest that bombesin-like peptides and GIP interact to stimulate insulin secretion.     

Defective insulin secretion during total parenteral nutrition in rat and its normalization by pituitary adenylate cyclase-activating polypeptide 27

The role of PACAP27, PACAP38 and VIP in the regulation of insulin release from pancreatic islets isolated from rats previously subjected to total parenteral nutrition (TPN) for 10 days was studied. Glucose-stimulated insulin secretion from islets of TPN rats was attenuated in parallel with cyclic AMP production. Immunocytochemistry showed an increased number of VIP-immunoreactive nerve fibers in the pancreatic islets of TPN rats. PACAP27, PACAP38 and VIP dose dependently and to the same magnitude potentiated insulin secretion from the islets of freely fed controls in the presence of a substimulatory glucose concentration (8.3 mmol/l). The secretory response of islets from TPN-treated rats to these neuropeptides was, however, markedly exaggerated compared to the controls. The insulin response of islets from TPN-treated rats to PACAP27 and PACAP38 was much greater than to VIP. With respect to insulin secretion, TPN treatment shifted the PACAP27 and PACAP38 dose-response curve to the left by two orders of magnitude. In the presence of 8.3 mmol/l glucose, cAMP accumulation was slightly higher in islets from TPN rats and the PACAP27, PACAP38 and VIP-stimulated increase in the cAMP production was markedly greater compared to the controls. Additional complementary in vivo experiments showed that PACAP27 normalized the defective glucose-stimulated insulin secretory response of TPN-treated rats. The data suggest that the defective nutrient-stimulated insulin secretion seen after long-term TPN treatment could be normalized by agents stimulating cAMP production possibly through cAMP/PK A-pathway.     

Analysis of the putative regulatory region of the gastric inhibitory polypeptide receptor gene in food-dependent Cushing's syndrome

Gastric inhibitory polypeptide (GIP)-dependent Cushing's syndrome (CS) results from the ectopic expression of non-mutated GIP receptor (hGIPR) in the adrenal cortex. We evaluated whether mutations or polymorphisms in the regulatory region of the GIPR gene could lead to this aberrant expression. We studied 9.0kb upstream and 1.3kb downstream of the GIPR gene putative promoter (pProm) by sequencing leukocyte DNA from controls and from adrenal tissues of GIP- and non-GIP-dependent CS patients. The putative proximal promoter region (800 bp) and the first exon and intron of the hGIPR gene were sequenced on adrenal DNA from nine GIP-dependent CS, as well as on leukocyte DNA of nine normal controls. Three variations found in this region were found in all patients and controls; at position -4/-5, an insertion of a T was seen in four out of nine patients and in five out of nine controls. Transient transfection studies conducted in rat GC and mouse Y1 cells showed that the TT allele confers loss of 40% in the promoter activity. The analysis of the 8-kb distal pProm region revealed eight distal single nucleotide polymorphisms (SNPs) without probable association with the disease, since frequencies in patients and controls were very similar. In conclusion, mutations or SNPs in the regulatory region of the GIPR gene are unlikely to underlie GIP-dependent CS.     

The reduction in hepatic insulin clearance after oral glucose is not mediated by gastric inhibitory polypeptide (GIP)

Since the C-peptide/insulin ratio is reduced after oral glucose ingestion, the incretin hormone gastric inhibitory polypeptide (GIP) has been assumed to decrease hepatic insulin extraction. It was the aim of the present study to evaluate the effects of GIP on insulin extraction. Seventy-eight healthy subjects (27 male, 51 female, 43+/-11 years) were subjected to (a). an oral glucose tolerance test and (b). an intravenous injection of 20 pmol GIP/kg body weight, with capillary and venous blood samples collected over 30 min for insulin, C-peptide and GIP (specific immunoassays). Following GIP administration, plasma concentrations of total and intact GIP reached to peak levels of 80+/-7 and 54+/-5 pmol/l, respectively (p<0.0001). The rise in insulin after oral glucose and after intravenous GIP administration significantly exceeded the rise in C-peptide (p<0.0001). Estimating insulin extraction from the total integrated insulin and C-peptide concentrations (AUCs), only the oral glucose load (p<0.0001), but not the intravenous GIP administration (p=0.18) significantly reduced insulin clearance. Therefore, insulin clearance is reduced after an oral glucose load. This effect does not appear to be mediated by GIP.     

Gastric inhibitory polypeptide enhancement of the insulin effect on fatty acid incorporation into adipose tissue in the rat

The influence of gastric inhibitory polypeptide (GIP) on fatty acid incorporation into adipose tissue (FIAT) was studied in the rat on epididymal fat pads at concentrations amounting to 1, 2 and 4 ng/ml. Without insulin in the incubation medium, GIP induced a slight though significant FIAT decrease with a maximum of 9% for 2 ng/ml concentration. In the presence of rat insulin (100 μU/ml), it significantly enhanced the insulin-induced FIAT increase, that progressed from 106.4% of the basal value to 110.5% for 1 ng/ml concentration (P < 0.025) and to 118.2% for 4 ng/ml concentration (P < 0.0025).The existence of such a phenomenon as well as that of an hyperactive enteroinsular axis in obese subjects could represent two important factors in the development of obesity.     

Suppression of androgen receptor signaling in prostate cancer cells by an inhibitory receptor variant

There is increasing evidence that sensitization of the androgen receptor (AR) signaling pathway contributes to the failure of androgen ablation therapy for prostate cancer, and that direct targeting of the AR may be a useful therapeutic approach. To better understand how AR function could be abrogated in prostate cancer cells, we have developed a series of putative dominant-negative variants of the human AR, containing deletions or mutations in activation functions AF-1, AF-5, and/or AF-2. One construct, AR inhibitor (ARi)-410, containing a deletion of AF-1 and part of AF-5 of the AR, had no intrinsic transactivation activity but inhibited wild-type AR (wtAR) in a ligand-dependent manner by at least 95% when transfected at a 4:1 molar ratio. ARi-410 was an equally potent inhibitor of gain-of-function AR variants. Ectopic expression of ARi-410 inhibited the proliferation of AR-positive LNCaP cells, but not AR-negative PC-3 cells. Whereas ARi-410 also marginally inhibited progesterone receptor activity, this was far less pronounced than the effect on AR (50% vs. 95% maximal inhibition, respectively), and there was no inhibition of either vitamin D or estrogen receptor activity. In the presence of ligand, ARi-410 interacted with wtAR, and both receptors translocated into the nucleus. Whereas the amino-carboxy terminal interaction was not necessary for optimal dominant-negative activity, disruption of dimerization through the ligand binding domain reduced the efficacy of ARi-410. In addition, although inhibition of AR function by ARi-410 was not dependent on DNA binding, the DNA binding domain was required for dominant-negative activity. Taken together, our results suggest that interaction between ARi-410 and the endogenous AR in prostate cancer cells, potentially through the DNA binding and ligand binding domains, results in a functionally significant reduction in AR signaling and AR-dependent cell growth.     

Mechanism of transmembrane signaling: insulin binding and the insulin receptor

Transmembrane signaling via receptor tyrosine kinases generally requires oligomerization of receptor monomers, with the formation of ligand-induced dimers or higher multimers of the extracellular domains of the receptors. Such formations are expected to juxtapose the intracellular kinase domains at the correct distances and orientations for transphosphorylation. For receptors of the insulin receptor family that are constitutively dimeric, or those that form noncovalent dimers without ligands, the mechanism must be more complex. For these, the conformation must be changed by the ligand from one that prevents activation to one that is permissive for kinase phosphorylation. How the insulin ligand accomplishes this action has remained a puzzle since the discovery of the insulin receptor over 2 decades ago, primarily because membrane proteins in general have been refractory to structure determination by crystallography. However, high-resolution structural evidence on individual separate subdomains of the insulin receptor and of analogous proteins has been obtained. The recently solved quaternary structure of the complete dimeric insulin receptor in the presence of insulin has now served as the structural envelope into which such individual domains were fitted. The combined structure has provided answers on the details of insulin/receptor interactions in the binding site and on the mechanism of transmembrane signaling of this covalent dimer. The structure explains many observations on the behavior of the receptor, from greater or lesser binding of insulin and its variants, point and deletion mutants of the receptor, to antibody-binding patterns, and to the effects on basal and insulin-stimulated autophosphorylation under mild reducing conditions.     

Modification of the insulin receptor by diethyl pyrocarbonate: effect on insulin binding and action

Insulin binding to rat liver plasma membranes is inhibited in a time- and dose-dependent fashion by prior treatment of membranes with the histidine-specific reagent diethyl pyrocarbonate. If all receptors are occupied by unlabeled hormone during diethyl pyrocarbonate treatment, no inhibition of 125I-labeled insulin binding is observed folowing washout of unlabeled hormone and unreacted reagent. Scatchard analysis of the binding inhibtion due to diethyl pyrocarbonate reveals a loss in receptor number rather than a change in receptor affinity for hormone. Fat cells treated with diethyl pyrocarbonate exhibit a rightward shift in the dose-response relationship for insulin-stimulated glucose oxidation consistent with a loss in receptor number due to the reagent. The pH profile for inhibition of insulin binding by diethyl pyrocarbonate and the partial reversibility of this inhibition by hydroxylamine are consistent with modification of a histidine residue. These results suggest that a histidine residue at or near the receptor binding site is required for formation of the biologically relevant insulin - receptor complex.     

Effect of acute zinc deficiency on insulin receptor binding in rat adipocytes

Considerable data have been reported on the relationship between insulin resistance and zinc deficiency. In this study, insulin receptor binding was measured in isolated rat adipocytes. Two assays were carried out at 37°C (binding and internalization) and 16°C (binding) using¹²⁵I insulin 0.05–20 nM. A decreased insulin receptor binding was observed in zinc-deficient rat adipocytes, but we could not make any distinction between the specific zinc depletion effects and the effects of the caloric restriction induced by zinc deficiency.     

Effects of insulin on lipoprotein secretion in rat hepatocyte cultures. The role of the insulin receptor

Insulin inhibits the secretion of lipoprotein components such as triglyceride, phospholipid, and apolipoproteins B and E in primary rat hepatocyte cultures. The aim of this study was to determine whether these hormonal effects are related to the interaction of insulin with its receptor on the surface of cultured hepatocytes. Half-maximal inhibition of secretion of apolipoprotein E and triglyceride occurred at 6 ng/ml porcine insulin, equivalent to a 20% receptor occupancy. When compared to porcine insulin, both guinea pig insulin and desoctapeptide insulin were 60 times less inhibitory on triglyceride and apolipoprotein secretion. These analogs were also 60 times less effective in competing with porcine 125I-insulin for receptor binding. Anti-insulin receptor IgG inhibited binding of porcine insulin to cells in a dose-dependent fashion. However, similar to the hormone itself, it reduced the secretion of triglyceride and apolipoproteins E and B. Preincubation of cells with 200 ng/ml porcine insulin for 15 h caused a 2.5-fold reduction of surface receptor number. These cells were less sensitive to the inhibitory effect of porcine insulin on secretion of triglyceride and apolipoproteins B and E. We conclude that the effects of insulin on lipoprotein processing by hepatocytes in culture are receptor-mediated, can be imitated by antibodies, to the insulin receptor, and are subject to control by receptor down-regulation.     

Effect of exogenous or endogenous gastric inhibitory polypeptide (GIP) on plasma triglyceride responses in rats.

We examined the effects of exogenous and endogenous GIP on plasma triglyceride levels in rats, pretreated with a fat-enriched diet, during intraduodenal infusion of a lipid test meal (Lipomul, 8 ml/h). Following the fat load the plasma triglyceride levels increased nearly linearly from a fasting value of 0.621 +/- 0.031 mmol/l to 3.32 +/- 0.403 mmol/l at 150 min. Simultaneously, the plasma GIP levels rose from 47.1 +/- 5.1 at fasting to a peak value of 268.4 +/- 32.2 pmol/l at 120 min. When porcine GIP was infused intravenously during the fat load, the plasma triglyceride increments were significantly smaller (control 1.64 +/- 0.264 mmol/l versus 0.949 +/- 0.114 mmol/l during GIP infusion at 60 min; p less than 0.002). GIP infusion in the absence of the fat load did not change fasting triglyceride levels. The effect of endogenous GIP was investigated by neutralization of GIP by injection of GIP antiserum (0.3 ml). Rats pretreated with the antiserum exhibited a significantly greater triglyceride increment late in the time course of the fat load. These data demonstrate that exogenous and endogenous GIP are able to lower the plasma triglyceride response to a fat load. Both, inhibition of fat absorption or stimulation of triglyceride uptake by peripheral tissues may be responsible for the GIP effects. The gut peptide GIP seems to represent an important hormonal regulator of postprandial triglyceride response.     

Gastric inhibitory polypeptide stimulated secretion of somatostatinlike immunoreactivity from the stomach: inhibition by acetylcholine or vagal stimulation

The possible involvement of gastric somatostatinlike immunoreactivity (SLI) in the acid inhibitory action of gastric inhibitory polypeptide (GIP) was studied in an isolated perfused rat stomach. GIP, in a dose of 5 or 50 ng/mL, caused a 4- and 12-fold increase in SLI secretion, respectively. At the higher dose level the stimulated secretory rate declined throughout the perfusion suggesting that secretion exceeded the capacity to synthesize SLI under excessive GIP stimulation. Acetylcholine (10 microM) or vagal stimulation (7 V, 10 Hz, 5 ms) completely inhibited GIP-stimulated SLI secretion. It is therefore proposed that the acid inhibitory activity of GIP is probably mediated via release of gastric SLI and this action is under cholinergic control.     

Control of insulin receptor autophosphorylation by polypeptide substrates: inhibition and stimulation by interaction with the catalytic subunit.

Autophosphorylation of purified insulin receptor, in the absence of insulin, was stimulated by selected polypeptide substrates. In the presence of 1 microM insulin these peptides inhibited autophosphorylation. Stimulation was observed with reduced [S-(carboxamidomethyl)cysteinyl]lysozyme (RCAM-lysozyme) and three peptides generated by CNBr cleavage, V8 proteinase digestion and/or chemical modification. We also generated two peptide substrates from RCAM-lysozyme which did not stimulate receptor autophosphorylation and were very weak inhibitors. As a control peptide, the simple substrate angiotensin inhibited receptor autophosphorylation in the absence or presence of insulin. However, stimulatory peptide, but not insulin, significantly shifted the concentration dependence for inhibition by angiotensin. The stimulatory peptides also increased autophosphorylation of the cloned cytoplasmic domain of the kinase [R-BIRK; Villalba, M., Wente, S. R., Russell, D. S., Ahn, J., Reichelderfer, C. F., & Rosen, O. M. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 7848]. Therefore, stimulation occurs by interaction with the cytoplasmic process of the beta-subunit and not through interaction with the insulin binding alpha-subunit of the native receptor. Autophosphorylation was analyzed by mapping 32P-labeled tryptic phosphopeptides from the beta-subunit and from R-BIRK. Nearly identical phosphopeptide maps were found, comparing first, basal R-BIRK and basal native receptor, second, peptide- and insulin-stimulated native receptor, and third, peptide-stimulated R-BIRK and insulin-stimulated native receptor. Therefore, R-BIRK functions as a basal-state enzyme and can be stimulated in an insulin-like manner. On the basis of these observations, stimulation by insulin and by peptides yields similar functional results, but by apparently different mechanisms.