The biosynthesis of insulin in the islets of Langerhans is strongly controlled at the translational level by glucose. We have used a variety of experimental approaches in efforts to dissect the mechanisms underlying the stimulatory effect of glucose. To assess its effects on rates of peptide-chain elongation, isolated rat islets were labelled with [3H]leucine at different glucose concentrations in the presence or absence of low concentrations of cycloheximide. Under these conditions, at glucose concentrations up to 5.6 mM, endogenous insulin mRNA did not become rate-limiting for the synthesis of insulin, whereas stimulation of non-insulin protein synthesis was abolished by cycloheximide at all glucose concentrations, indicating either that insulin synthesis is selectively regulated at the level of elongation at glucose concentrations up to 5.6 mM, or that at these concentrations inactive insulin mRNA is transferred to an actively translating pool. Glucose-induced changes in the intracellular distribution of insulin mRNA in cultured islets were assessed by subcellular fractionation and blot-hybridization using insulin cDNA probes. At glucose concentrations above 3.3 mM, cytoplasmic insulin mRNA was increasingly transferred to fractions co-sedimenting with ribosomes, and relatively more of the ribosome-associated insulin mRNA became membrane-associated, consistent with effects of glucose above 3.3 mM on both the initiation of insulin mRNA and SRP (signal recognition particle)-mediated transfer of cytosolic nascent preproinsulin to the endoplasmic reticulum. When freshly isolated islets were homogenized and incubated with 125I-Tyr-tRNA, run-off incorporation of 125I into preproinsulin was increased by prior incubation of the islets at 16.7 mM-glucose. The addition of purified SRP receptor increased the run-off incorporation of [125I]iodotyrosine into preproinsulin, especially when the islets had been preincubated at 16.7 mM-glucose. These findings taken together suggest that glucose may stimulate elongation rates of nascent preproinsulin at concentrations up to 5.6 mM, stimulates initiation of protein synthesis involving both insulin and non-insulin mRNA at concentrations above 3.3 mM, and increases the transfer of initiated insulin mRNA molecules from the cytoplasm to microsomal membranes by an SRP-mediated mechanism that involves the modification of interactions between SRP and its receptor.
Fetal pancreatic beta cells demonstrate a deficient insulin release in response to glucose, but the underlying mechanism at the cellular level is unknown. By using beta cells from 21-day fetal rats we made an attempt to clarify the mechanism(s) behind this reduced glucose response. In addition to measuring insulin release, glucose metabolism, and cellular ATP content, ATP-regulated K+ channels (G channels) and voltage-activated Ca2+ currents were investigated with the patch-clamp technique. It was thus demonstrated that the ATP-regulated K+ channels in fetal beta cells were not sensitive to glucose but otherwise had similar characteristics as those of adult beta cells. Also, the characteristics of the voltageactivated Ca2+ currents were similar in adult and fetal beta cells. However, as judged from measurements of both glucose oxidation and glucose utilization, glucose metabolism was impaired in fetal beta cells. In addition, there was no increase in the ATP content, even when the cells were stimulated for 30 min. It is therefore concluded that the attenuated glucoseinduced insulin release in fetal pancreatic beta cells is due to an immature glucose metabolism resulting in impaired regulation of the ATP-sensitive K+ channels. These rmdings may be relevant to the understanding of the deficient stimulus-secretion coupling associated with non-insulin-dependent diabetes.In adult beta cells glucose promotes the closure of a K+ channel that is regulated by intracellular ATP (G channel) (1-4), resulting in depolarization, opening of voltage-activated Ca2l channels, and insulin release (1). The significance of the G channel is further emphasized by the finding that hypoglycemic sulfonylureas, drugs used in the treatment of noninsulin-dependent diabetes (type II diabetes), initiate insulin release by a direct closure of this channel (1, 5-7). Thus, one can postulate that failure of glucose to promote insulin release in type II diabetes might result from either the G channel or its regulation being defective. In vitro studies of the endocrine pancreas of both man and animals have demonstrated a poor coupling between ambient glucose concentration and fetal insulin discharge (8)(9)(10)(11)(12)(13)(14)(15)(16)(17)(18)(19)(20). So far it has not been possible to define the step(s) in the stimulus-secretion coupling responsible for the reduced glucose response. In the present study we intended to clarify whether the relative inability of glucose to promote insulin release from fetal pancreatic beta cells can indeed be explained in terms of an altered function of the G channel protein and/or a defect in G channel regulation. Information obtained from studies of the stimulus-secretion coupling in fetal beta cells is relevant also for the understanding of the mechanism(s) responsible for the defect in insulin release in type II diabetes. MATERIALS AND METHODSPreparation and Dispersion of Fetal Pancreatic Islets as Well as Measurements of Insulin Release. Fetal rat islets were isolated from 21-day pregnant rats as in He...
Shb is a recently described Src homology 2 (SH2) domain-containing adaptor protein. Here we show that Shb is expressed in lymphoid tissues, and is recruited into signaling complexes upon activation of Jurkat T cells. Grb2 binds proline-rich motifs in Shb via its SH3 domains. As a result, a number of proteins detected in anti-Shb and anti-Grb2 immunoprecipitates are shared, including phosphoproteins of 22, 36/38, 55/57 and 70 kDa. Shb-association with p22, which represents the T cell receptor associated z chain, occurs through the Shb SH2 domain. The central region of Shb binds p36/ 38. Since this interaction was inhibited by phosphotyrosine, this region of Shb is likely to contain a non-SH2 PTB (phosphotyrosine binding) domain. The Shb PTB domain was found to preferentially bind the sequence Asp-Asp-X-pTyr when incubated with a phosphopeptide library. A peptide corresponding to a phosphorylation site in 34 kDa Lnk inhibited association between Shb and p36/38. Overexpression of Shb in Jurkat cells led to increased basal phosphorylation of Shb-associated p36/ 38 and p70 proteins. Inactivation of the Shb SH2 domain by an R522K mutation resulted in a reduced stimulation of tyrosine phosphorylation of several proteins in response to CD3 crosslinking when expressed in Jurkat cells. Together, our results show three distinct domains of Shb all participate in the formulation of multimeric signaling complexes in activated T cells. These results indicate that the Shb protein functions in T cell receptor signaling.
Recently it has been postulated that interleukin-1 (IL-1) locally released by infiltrating mononuclear cells may destroy the pancreatic B cells during the development of insulin-dependent diabetes mellitus. Since IL-1 is a potent inducer of interleukin-6 (IL-6) in various cells, it is conceivable that IL-6 is a second mediator of the IL-1 action. In the present study the effects of IL-6 alone or in combination with IL-1 were studied on pancreatic islet function in vitro after tissue culture and compared with the effects observed after exposure to IL-1 only. Rat pancreatic islets were cultured in medium RPMI 1640 + 10% calf serum with or without the addition of human recombinant IL-6 (500-5000 pg/ml) for 48 h. The medium insulin accumulation was increased by 40-50% after culture with 500-2000 pg/ml IL-6, but was similar to the controls at 5000 pg/ml. When islets were cultured for 18 h only, also 5000 pg/ml IL-6 stimulated the medium insulin accumulation. IL-6 did not affect the islet insulin content and the rates of islet (pro)insulin and total protein biosynthesis. It inconsistently decreased the islet DNA content. In short-term experiments after 48-h culture with IL-6, there was a dose-dependent inhibition of the glucose-stimulated insulin release. On the other hand, islets cultured with IL-6 (5000 pg/ml) exhibited an elevated glucose oxidation and oxygen uptake, but a lower ATP content at 16.7 mM glucose and an unaffected glucose utilization and glutamine oxidation compared to the controls. This raises the possibility that IL-6 had induced a condition with an increased energy expenditure, resulting in an enhanced mitochondrial metabolism of glucose. Islets cultured with human recombinant IL-1 beta (25 units/ml) showed a strong inhibition of the insulin accumulation in the culture medium and of glucose-stimulated insulin release and a marked decrease in the islet DNA and insulin content. A combination of IL-1 (25 U/ml) + IL-6 (1000 pg/ml) did not alter the inhibitory action of IL-1 alone. The present findings thus show that IL-6 induces a dissociation between insulin secretion and glucose oxidation in islets in vitro. This has not been observed in islets exposed to IL-1, which suggests that IL-6 does not solely mediate the inhibitory effects of IL-1 on islet function.(ABSTRACT TRUNCATED AT 250 WORDS)
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