Antidiabetic effect of novel modulating peptides of G-protein-coupled kinase in experimental models of diabetes.

AIMS/HYPOTHESIS: G-protein-coupled receptor kinases (GRKs) play a key role in agonist-induced desensitisation of G-protein-coupled receptors (GPCRs) that are involved in metabolic regulation and glucose homeostasis. Our aim was to examine whether small peptides derived from the catalytic domain of GRK2 and -3 would ameliorate Type 2 diabetes in three separate animal models of diabetes. METHODS: Synthetic peptides derived from a kinase-substrate interaction site in GRK2/3 were initially screened for their effect on in vitro melanogenesis, a GRK-mediated process. The most effective peptides were administered intraperitoneally, utilising a variety of dosing regimens, to Psammomys obesus gerbils, Zucker diabetic fatty (ZDF) rats, or db/db mice. The metabolic effects of these peptides were assessed by measuring fasting and fed blood glucose levels and glucose tolerance. RESULTS: Two peptides, KRX-683(107) and KRX-683(124), significantly reduced fed-state blood glucose levels in the diabetic Psammomys obesus. In animals treated with KRX-683(124) at a dose of 12.5 mg/kg weekly for 7 weeks, ten of eleven treated animals responded with mean blood glucose significantly lower than controls (4.7+/-0.4 vs 16.8+/-0.8 mmol/l, p

Irreversibility of nutritionally induced NIDDM in Psammomys obesus is related to beta-cell apoptosis.

Psammomys lapses into fully fledged diabetes when maintained on a high-energy diet. Progression to diabetes has been classified into stage A of normoglycemia and normoinsulinemia (<120 mg/ml and 100 mU/L, respectively); stage B of hyperinsulinemia (100-300 mU/L) with marked insulin resistance in the face of normoglycemia; stage C of pronounced hyperinsulinemia with hyperglycemia < or =500 mg/ml; stage D at 6-10 weeks after stage C, featuring further hyperglycemia and loss of insulin. Insulin resistance expressed in Psammomys at stages B and C was demonstrated by nonsuppression of the hepatic gluconeogenesis enzyme phosphoenolpyruvate carboxykinase by the endogenous hyperinsulinemia and by the reduced capacity of insulin to activate muscle and liver tyrosine kinase of the insulin receptor. Diabetes at stage C, but not at stage D, was fully reversed to stage A by restricting the food ration of animals by half (from 14 to 7 g/day) for 10-14 days. We examined islet beta cells of Psammomys in the four stages of progression to diabetes by staining for insulin as well as for apoptosis by the terminal deoxynucleotidyl transferase biotin-dUTP nick end labeling (TUNEL) and visualizing the biotin-labeled cleavage sites. Psammomys in stage A had insulin-laden beta cells. In stage B, a hypertrophy and partial insulin depletion of beta cells was evident with negative TUNEL staining. In stage C, beta cells were markedly depleted of insulin, and their number within the islets decreased, but the TUNEL staining was virtually negative. In stage D, beta cells were markedly diminished within the islets, almost void of insulin, showing distinct TUNEL staining of beta cells. These results indicate that prolonged exposure of islets to in vivo hyperglycemia with beta-cell overtaxation induces nuclear disintegration with irreversible damage to the insulin-secretion apparatus. This precludes the return to normalcy by restricting the food intake of Psammomys. The appearance of cells with TUNEL-positive staining may serve as a marker of impending irreversibility of nutritionally induced diabetes.

Immunocytochemical investigation of insulin secretion by pancreatic beta-cells in control and diabetic Psammomys obesus.

Hyperproinsulinemia is a characteristic feature of non-insulin-dependent diabetes mellitus (NIDDM) caused by pancreatic beta-cell dysfunction through a secretion-related alteration or impaired proinsulin processing. We have investigated the insulin processing and secretion in Psammomys obesus fed with low- and high-energy diets, which represent a model for diet-induced NIDDM. With a high-energy diet the animals develop hyperglycemia and hyperinsulinemia, whereas those maintained on a low-energy diet remain normoglycemic. Although a large amount of insulin immunoreactivity was detected in beta-cells of the normoglycemic compared to hyperglycemic animals, in situ hybridization for insulin mRNA demonstrated a particularly high signal in the beta-cells of the hyperglycemic animals. By electron microscopy, the beta-cells of normoglycemic animals displayed large accumulations of secretory granules, whereas those of the hyperglycemic animals contained very few granules and large deposits of glycogen. These results reflect a secretory resting condition for the cells of the normoglycemic animals in contrast to stimulated synthetic and secretory activities in the cells of the hyperglycemic ones. Using colloidal gold immunocytochemistry at the electron microscopic level, we have examined subcellular proinsulin processing in relation to the convertases PC1 and PC2. Immunolabeling of proinsulin, insulin, C-peptide, PC1, and PC2 in different cell compartments involved in beta-cell secretion were evaluated. Both PC1 and PC2 antigenic sites were detected in beta-cells of hyperglycemic Psammomys, but their labeling intensity was weak compared to the cells of normoglycemic animals. In both groups of animals, higher levels of PC2 were found in the Golgi apparatus than in the immature granules. Major decreases in proinsulin, insulin, PC1, and PC2 immunoreactivity were recorded in beta-cells of the hyperglycemic Psammomys. In addition, all these antigenic sites were detected in lysosome-like structures, revealing a major degradation process. These results suggest that the insulin-secreting cells in hyperglycemic Psammomys obesus are in a chronic secretory state during which impaired processing of proinsulin appears to take place.

Biochemical and morpho-cytochemical evidence for the intestinal absorption of insulin in control and diabetic rats. Comparison between the effectiveness of duodenal and colon mucosa.

A combined biochemical and morpho-cytochemical investigation was carried out in order to assess insulin absorption by the duodenal and colon epithelium. Insulin was introduced in the lumen of the rat duodenum or colon in combination with sodium cholate and aprotinin. Blood analysis made at several time points has demonstrated a rapid increase in circulating levels of insulin followed by significant and consistent decreases in blood glucose. This indicates that biologically active insulin is absorbed by the intestinal mucosa and transferred to the circulation. Because of the initial high blood glucose levels, the lowering of the glycaemic values was more significant in diabetic animals. Also, levels of circulating insulin remained higher for longer time when the administration was performed in the colon. The integrity of the intestinal wall after insulin administration, evaluated morphologically, was retained. Application of protein A-gold immunocytochemistry has established the pathway for insulin absorption. In both duodenal and colon epithelial cells the labelling for insulin was detected in the endosomal compartment, in the Golgi apparatus and in association with the baso-lateral plasma membrane interdigitations. Some labelling was also present in the interstitial space and in capillary endothelial plasmalemmal vesicles. Insulin introduced in the lumen of the rat duodenum and colon appears thus to be rapidly internalized by the epithelial cells and transferred through a transcytotic pathway to the interstitial space from which it reaches the blood circulation. This exogenous insulin then induces significant decreases in plasma glucose levels which lasts for several hours. The results obtained support the possibility for the clinical development of an oral preparation of insulin.

Morpho-cytochemical and biochemical evidence for insulin absorption by the rat ileal epithelium.

In order to investigate the mechanism through which insulin is absorbed by the intestinal epithelium and transferred to the circulation where it exercises its biological activity of lowering blood glucose levels, a combined biochemical morpho-cytochemical study was undertaken on rat ileal tissue, in vivo. Insulin was introduced into the lumen of the ileum in combination with sodium cholate and aprotinin and allowed to be absorbed for various periods of time. Analysis of blood samples from the inferior vena cava, at different time points has demonstrated an increase in plasma insulin followed by a decrease in blood glucose levels. The ileal tissues were studied at different time points after the introduction of the insulin, by applying the protein A-gold immunocytochemical technique. Insulin antigenic sites were detected with high resolution, at various levels of the enterocytes but were absent from goblet cells. At 2 to 5 min, the labelling was mainly associated with the microvilli and endocytotic vesicles in the apical portion of the epithelial cells. Some gold particles were in contact with the lateral membranes. At 10 min, the labelling was found at the level of the trans-side of the Golgi apparatus and mainly along the baso-lateral membranes of the epithelial cells. Labelling was also detected in the interstitial space. The control experiments have demonstrated the specificity of the labelling and confirmed the nature of the insulin molecules detected. Furthermore, the morphological study has confirmed that exposure of the tissue to the insulin-cholate-aprotinin solution does not affect the integrity of the epithelium while promoting insulin absorption.(ABSTRACT TRUNCATED AT 250 WORDS)