Differences in insulin secretion between the rat and mouse: role of cAMP.

Although information regarding insulin secretion usually is considered equivalent when generated in the mouse or the rat, it is established that the kinetics of insulin secretion from mouse and rat pancreatic beta cells differ. The mechanisms underlining these differences are not understood. The in vitro perfused pancreas and isolated islets of the mouse or rat were employed in this study to investigate the role of cyclic adenosine monophosphate (cAMP), a major positive modulator of beta-cell function, as one differentiating signal for the uniquely different insulin release from the beta cells of these commonly used rodents. Glucose-stimulated first-phase insulin release from the perfused pancreas of the rat was higher than the mouse when calculated per gram of pancreas or as fractional secretion, but this phase was identical in the two species when results were adjusted for total body weight. Whether related to insulin content, pancreatic weight or body weight, the rat pancreas responded to glucose with a progressively increasing second-phase insulin release compared to the mouse pancreas, which secreted a flat second-phase of lesser magnitude. Isolated islets from rat and mouse were comparable in insulin content whereas the basal cAMP level of mouse islets was less than half that of the rat. At submaximal stimulation with glucose or glucose + IBMX or forskolin, mouse islets exhibited lower cAMP levels to a given stimulus than the rat. In rat islets cAMP levels increased to approximately 1000 fmol per islet, although insulin secretion maximized by 100-150 fmol.(ABSTRACT TRUNCATED AT 250 WORDS)

Interrelationship of changes in islet nicotine adeninedinucleotide, insulin secretion, and cell viability induced by interleukin-1 beta.

Complete loss of pancreatic insulin function in insulin-dependent diabetes is thought to be due to an autoimmune cytokine-mediated destruction of the beta-cell. The effects of several classes of agents on interleukin-1 beta (IL-1 beta)-induced suppression of insulin secretion, beta-cell NAD levels, and beta-cell viability were examined. After overnight incubation of isolated rat islets with 15 U/ml IL-1 beta and 11 mM glucose, sequential hourly insulin secretory responses to the same glucose concentration, 22 mM glucose, and 22 mM glucose plus forskolin were severely inhibited to 10-37% of the control value. Islet NAD levels were also sharply reduced to 43% of the control value after 24-h exposure to IL-1 beta, but not after 1 or 3 h, demonstrating the same time course as that for inhibition of insulin secretion. Exposure to IL-1 beta also decreased islet cell viability measured as trypan blue exclusion. Only 1 mM N-methyl arginine, an inhibitor of nitric oxide synthase, completely protected all three parameters of beta-cell function from damage by IL-1 beta. Nicotinamide and thymidine prevented the IL-1 beta-induced loss of cell viability and suppression of NAD, but had no effect on sustaining insulin secretion. Antioxidants, steroids, and several neuropeptides also did not prevent inhibition or restore the secretory response. Thus, the loss of the secretory response appears to be more narrowly restricted to nitric oxide radical damage induced by exposure to IL-1B.

Opposite, phase-dependent effects of 3,4,5-trimethoxybenzoic acid 8-(diethylamino) octyl ester or tetracaine on islet function during three phases of glucose-stimulated insulin secretion.

The spontaneous decline of insulin secretion which occurs under a variety of secretory conditions is well documented and suggests a general desensitization of the secretory process distal to signal recognition. Accordingly, we have investigated the effects of agents thought to mobilize intracellular Ca++ on insulin secretion over 24 h, which includes periods of rising secretory activity (second phase) and desensitized secretory activity (third phase). During the first 3 h of glucose stimulation of freshly isolated rat islets, insulin secretion was strongly inhibited by 30 microM 3,4,5-trimethoxybenzoic acid 8-(diethylamino) octyl ester (TMB) or 300 microM tetracaine hydrochloride (TC). However, when either of these agents was added for the first time to islets at h 20 when insulin secretion was at a low steady rate (third phase), insulin secretion was greatly enhanced. Both these inhibitory and stimulatory effects declined with continued administration. Removal of TMB and rechallenge with high glucose plus forskolin uncovered a residual inhibition in both chronically and acutely treated islets. Coadministration of forskolin with either TMB or TC blunted both inhibitory and stimulatory effects. Pertussis toxin pretreatment, however, did not alter subsequent response of islets to either agent. Thus TMB or TC have opposite, phase-dependent effects on glucose-stimulated insulin secretion. We postulate that potentiators of glucose-stimulated insulin secretion, which are increased during second phase, are most sensitive to inhibitory effects of TMB or TC, and that the low steady rate of third phase permits their stimulatory component(s) to become apparent.

The role of Ca(2+)-related events in glucose-stimulated desensitization of insulin secretion.

The spontaneous decline of insulin secretion (third phase) that occurs under a variety of secretory conditions is well documented and suggests a general impairment or desensitization of the secretory process. We have examined several aspects of Ca2+ flux as well as regulators of Ca-linked second messenger events in freshly isolated rat islets chronically stimulated with glucose over 24 h, a period that encompasses initial (hour 1), peak (hour 3), and subsequent impaired or desensitized (hour 20-22) secretion. In islets incubated for these periods in HB104 medium with 22 mM glucose, 45Ca2+ uptake did not vary (12.6 +/- 1.6 vs. 10.2 +/- 1.7 vs. 13.2 +/- 3.4 pmol Ca2+/islet.10 min at 1, 3, and 22 h, respectively). Chronic incubation in 2 mM glucose reduced total Ca2+ uptake at each of the time periods, but, again, uptake did not change with desensitization (9.8 +/- 1.4 vs. 6.6 +/- 2.1 vs. 7.8 +/- 2.3 pmol Ca2+/islet.10 min). In 11 mM glucose, the Ca channel antagonist verapamil (1-10 microM) reduced insulin secretion by 55-80% in a dose-dependent manner over 1-3 h; islets continuously exposed to verapamil escaped inhibition by 20 h even at the highest concentration. However, in islets first exposed to 10 microM verapamil only during 20-22 h, hourly insulin secretion was suppressed 25%, 45%, and 33% at 20, 21, and 22 h, respectively, indicating that glucose-desensitized islets were still sensitive to further inhibition of Ca channels. Staurosporine (1 microM), an inhibitor of protein kinase-C activity, progressively inhibited glucose-stimulated insulin secretion from 48% at 1 h to more than 80% by 3 h; again, this inhibitory effect was lost by 20 h of chronic staurosporine. When staurosporine was first administered at 20 h, insulin secretion was modestly suppressed and returned to control values in the next hour. With continuous glucose, the islet response to positive stimulation of endogenous C-kinase activity by carbachol was maintained. The Ca/calmodulin inhibitor trifluoroperazine also inhibited insulin secretion by 75-80% during 1-3 h and continued to exert inhibitory effects through 23 h of continuous administration. We conclude that even though insulin secretion has desensitized to glucose, 1) Ca2+ entry is unchanged and is still regulated by glucose, 2) voltage-dependent Ca channels are still sensitive to blockade by acute verapamil, but can desensitize to chronic verapamil; 3) stimulus-enhanced C-kinase activity may be especially labile during glucose-induced desensitization, while 4) possible Ca/calmodulin potentiation of secretion persists through the three secretory phases.(ABSTRACT TRUNCATED AT 400 WORDS)