Cadmium-metallothionein nephrotoxicity is increased in genetically diabetic as compared with normal Chinese hamsters.

To investigate the extra susceptibility of diabetics to some nephrotoxic agents, adult normal and diabetic Chinese hamsters (6-7 animals in each group) were injected subcutaneously with different doses of cadmium-metallothionein (Cd-MT) equivalent to 0.0, 0.1 or 0.25 mg Cd/kg body weight and the first 24 hr urinary outputs were collected. Several days prior to exposure to the Cd-MT the diabetic hamsters were hyperglycaemic, and plasma insulin levels and body weights were elevated in some of the diabetics. The higher dose of Cd-MT caused significant spillage of N-acetyl-beta-glucosaminidase (U-NAG) activity and protein into the urine of both normal and diabetic animals. The higher dose of Cd-MT was more toxic to the diabetic kidneys because U-NAG levels were higher in the diabetics (2.5-fold higher than normal). U-Cd levels were proportional to the injected Cd-MT dose. U-Zn levels were not consistently affected by the injected Cd-MT although it had contained small amounts of Zn. Therefore, genetic diabetes in the Chinese hamster appears to increase susceptibility to acute cadmium-MT nephrotoxicity. The mechanisms underlying this need to be further investigated.

Glucose-stimulated elevation of cytoplasmic calcium is defective in the diabetic Chinese hamster islet B cell.

To characterize insulin release and cytoplasmic free Ca2+ ([Ca2+]i) levels in the diabetic Chinese hamster islet B cell, islets from genetically normal (subline M) and diabetic (subline L) hamsters were collagenase isolated. Insulin release and glucose utilization (conversion of D-[5-(3H)]glucose to 3H2O) were measured in whole islets; [Ca2+]i levels were measured in single islet cells using fura-2. The Ca2+ channel agonist, 12 mmol/l perchlorate, ClO4-, increased the subnormal insulin response during 20 mmol/l glucose perifusion, but did not normalize it. Glucose utilization measured over a 2-h period was normal. Glucose induced an initial decrease and then a rise in [Ca2+]i in 85% of the normal (presumably B) cells. In diabetic cells, the [Ca2+]i response was delayed, subnormal and only observed in 23% of the cells. When perchlorate or another Ca2+ channel agonist, 10 mumol/l CGP 28392, was added with glucose, a larger proportion of the diabetic cells (61-67%) showed increased [Ca2+]i and the mean [Ca2+]i response was not different from normal. However, neither perchlorate nor CGP 28392 could normalize glucose-stimulated insulin release, and K(+)-induced insulin release was decreased in diabetic islets. The K(+)-induced [Ca2+]i rise was essentially normal in all the diabetic islet cells. Therefore, the diabetic hamster islet appears to metabolize glucose normally, but has a diminished insulin response to glucose and K+. The Ca2+ channel agonists markedly improve the subnormal [Ca2+]i response but not the insulin response. Glucose-induced elevation of [Ca2+]i and exocytosis appear defective in the diabetic Chinese hamster B cell.

Effect of perchlorate on glucose-stimulated insulin release and 45Ca2+ uptake in pancreatic islets from diabetic Chinese hamsters.

Insulin release and 45Ca2+ uptake were studied in isolated islets from Chinese hamsters of genetically diabetic and normal sublines. The calcium channel agonist, perchlorate (ClO4-, 12 mmol/L), augmented both 45Ca2+ uptake and insulin release from normal islets in the presence of 20 but not 1 mmol/L glucose. The agonist also amplified the glucose-stimulated 45Ca2+ uptake and insulin release from diabetic islets but did not normalize the insulin release despite normal insulin concentration in the diabetic Chinese hamster islets. The dry weight of the diabetic islets was subnormal (54%, p < 0.005) but the insulin concentration (insulin per dry weight of islet tissue) was not different from normal (122%). It appears that there are defective mechanisms in addition to the glucose-stimulated influx of Ca2+ in diabetic islet B cells.

DNA replication in pancreatic islets and adrenals in diabetic Chinese hamsters.

The diabetic syndrome in Chinese hamsters is progressive and there is a decrease in the size of the pancreatic islets. To what extent this is due to impaired DNA replication in their islet cells is unknown. Therefore 3H-thymidine incorporation into islet cells was studied in genetically diabetic (subline L) male hamsters aged 17-20 days, 6 weeks, 3, 6 and 12 months. Because adrenal weight was decreased at almost all ages, studies of adrenal morphology and function were also performed. Age- and sex-matched normal (subline M) hamsters served as controls. Autoradiography showed progressively falling labeling with increasing age in both normal and diabetic animals in both islets and adrenals. At the earliest age studied, the diabetic subline animals were normoglycemic but showed hyperinsulinemia. DNA replication was reduced both in the islet cells and the adrenal cortex. From 6 weeks of age and onwards, the diabetic hamsters were hyperglycemic and usually hyperinsulinemic but DNA replication in both islets and adrenals was not different from that in normals. Histomorphometry showed reduced volume in both the adrenal medulla and cortex in 3-month-old diabetic hamsters. In 12-month-old male and female diabetic hamsters plasma cortisol and aldosterone and 24-hour urinary epinephrine were normal, but urinary norepinephrine and dopamine levels were excessive. Thus, in contrast to what is found in the obese-hyperglycemic mouse, there was no increased islet cell DNA replication in response to the increased functional demand in the diabetic Chinese hamster.(ABSTRACT TRUNCATED AT 250 WORDS)

Elemental composition in the pancreatic B cell is normal in the prediabetic Chinese hamster.

To clarify whether elemental changes are present before the onset of diabetes, freeze-dried pancreas sections from young (18-19 days old), genetically prediabetic Chinese hamsters were subjected to proton bombardment and the concentrations of 15 elements (Na, Mg, Al, P, S, Cl, K, Ca, Mn, Fe, Cu, Zn, Rb, Cd, and Pb) in B cells and exocrine pancreas were calculated from the x-rays emitted. We have previously shown that islet B cells and exocrine pancreas from adult, overtly diabetic Chinese hamsters contain subnormal levels of Al (-61%, -88%) and excess levels of Cu (+92%, +59%), Rb (+13%, +13%), and Mg (+6%, +6%) in B cells and exocrine pancreas, respectively (Juntti-Berggren et al., Biosci Rep 1976;7:33-41). In the present study the prediabetic B cells contained normal levels of all 15 elements, whereas the prediabetic exocrine pancreas contained a subnormal level of Fe (-10%; p less than 0.005). Hence, the development of diabetes in the Chinese hamster does not seem to be associated with an early change in the elemental composition of the pancreatic B cells. In fact, the overt diabetic condition may cause changes in the body's handling of some elements.

Insulin release from isolated mouse islets in vitro: no effect of physiological levels of melatonin or arginine vasotocin.

Some data in the literature suggest that heightened activity of the pineal gland may be diabetogenic. The onset of insulin-dependent diabetes mellitus is highest during the winter months and at puberty when melatonin levels are also greatest. To study the direct effects of pineal hormones on insulin release, hand-dissected ob/ob-mouse islets of Langerhans were incubated in vitro with melatonin (1 nmol/l to 100 mumol/l) or arginine vasotocin (1 pmol/l to 10 mumol/l) and D-glucose (3 or 20 mmol/l for 1 hr. Melatonin did not affect basal or glucose-stimulated insulin release. Arginine vasotocin (AVT) did not affect basal insulin release, but at presumably pharmacological levels (1 and 10 mumol/l) the peptide significantly increased glucose-stimulated insulin release. We conclude that melatonin and AVT at physiological concentrations have no direct effect on islet insulin release, and that any diabetogenic effect of the pineal gland must occur via suppression of insulin action or via production of a metabolite or hormone that suppresses insulin release.

Diabetes is not associated with a change in the elemental composition of the pancreatic B cell in diabetic C57BL KsJ-db/db mice.

Freeze-dried pancreas sections from 7-, 17- and 27-week-old genetically diabetic (db/db) and normal (+/-/+/-) mice were subjected to proton bombardment and the concentrations of 15 elements in B cells and exocrine pancreas were calculated from the characteristic X-rays emitted. In the 7-week-old diabetic animals, B cells contained significantly above-normal levels of Na and S, while exocrine pancreas contained subnormal levels of Ca, and excess Mn. The B cells from the 17-week-old diabetic animals contained subnormal levels of Cu and the exocrine pancreas of the 27-week-old diabetic animals was deficient in Cd. The 7-, 17- and 27-week-old, genetically diabetic (db/db) mice were hyperglycemic, hyperinsulinemic and heavier than age-matched normal (+/-/+/-) mice. Although significant changes were found in elemental composition when comparing both B cells and exocrine pancreas at different ages, the changes were not consistent. Therefore, it appears as if the measured elemental changes were random and not related to the onset of diabetes.

Changes in phosphate do not affect insulin release from isolated mouse islets of Langerhans.

Phosphate affects glucose tolerance, insulin release and peripheral insulin sensitivity. In the present study moderate changes in the phosphate concentration of the incubation medium from 0.3 to 2 mmol/l (i.e., within the physiological range) did not affect insulin release from isolated mouse islets in vitro. In addition, the vitamin-D status of the animals had no effect on the glucose-stimulated insulin response in the different phosphate concentrations. Therefore these data indicate that the impaired glucose tolerance seen in hypophosphatemic states is not due to a direct effect of phosphorus levels on the insulin-releasing B-cell.

Abnormalities in glucose-stimulated insulin release, 45Ca uptake, and 86Rb efflux in diabetic Chinese hamster islets.

We loaded islets from normal and diabetic Chinese hamsters with 86Rb (an analogue for K+) and measured 86Rb efflux during stimulation with 20 mM D-glucose. Genetically diabetic Chinese hamsters were selected from a subline (L) known for subnormal pancreatic insulin release and excessive pancreatic glucagon release in vitro. 86Rb accumulation in 1 mM glucose was normal in the diabetic islets. Similar to the pattern of 86Rb efflux previously seen from normal rat and mouse islets, 20 mM glucose suppressed 86Rb efflux within 1-2 min, and efflux remained suppressed until return to 1 mM glucose in both normal and diabetic hamster islets. After the first 2 min of 20 mM glucose, suppression of 86Rb efflux was somewhat greater in the diabetic hamster islets than in the normals. In addition, glucose-stimulated insulin release and 45Ca uptake were significantly reduced in the diabetic islets. Therefore, in the diabetic hamster islets, there is at least no impairment in the initial suppression of 86Rb efflux by glucose. This suggests that the diabetic beta-cells recognize glucose and carry out the initial steps in the stimulus-secretion coupling sequence normally. The later, excessive suppression of 86Rb efflux may be due to impaired Ca2+-induced changes in 86Rb efflux, suggesting that defective regulation of intracellular Ca2+ activity, rather than defective regulation of K+ permeability, may lead to the impaired insulin secretion.

Islet morphology in young, genetically diabetic Chinese hamsters during the hyperinsulinemic phase.

Plasma glucose and insulin levels were measured in genetically diabetic (subline L) hamsters from 2 1/2 weeks to over 1 year of age. This nonobese subline is known for subnormal pancreatic insulin release. Hyperglycemia was seen from 4 weeks onward. A short period of hyperinsulinemia was seen at 6 weeks of age, after which plasma insulin levels were not different from normal. During the hyperinsulinemia phase (age 6 weeks), pancreatic insulin content was subnormal, islet volume (as percent of pancreas cross-sectional area) and islet size (as islet cross-sectional area in micron2) were not different from normal, islet morphology appeared normal in electron micrographs, but granule volume was slightly but significantly below normal. Because the islets appeared morphologically normal, except for the slight degranulation during the hyperinsulinemic phase, these data suggest (a) that the islets "hypersecrete" to reduce hyperglycemia; but (b) synthesis does not increase enough to maintain a normal pancreatic insulin content; (c) that the first sign of pancreatic failure may be degranulation and decreased insulin synthesis or content; (d) that early peripheral resistance to insulin, rather than early islet failure, may cause the early hyperglycemia, and (e) that early hyperglycemia or insulin resistance contributes to the later islet exhaustion, which is seen in these diabetic animals when adult.

Proton microprobe analysis of 15 elements in pancreatic B cells and exocrine pancreas in diabetic Chinese hamsters.

Diabetes mellitus spontaneously develops in certain sublines of non-obese Chinese hamsters, and the diabetic L-subline is known for subnormal pancreatic insulin release in vitro. The cause of the secretory defect is unknown. Freeze-dried pancreas sections from genetically diabetic Chinese hamsters and normal controls were subjected to proton bombardment and the concentration of 15 elements in B cells and acini was calculated from the X-rays emitted. Diabetic B cells contained significantly less Al (-61%) and significantly more Cu (+92%), Mg (+6%) and Rb (+13%) than their normal counterparts. The diabetic acini showed similar, significant changes. The molar ratio between K and Na was about 10 in endocrine as well as exocrine pancreas from both groups of animals, implying that neither sample preparation nor irradiation had induced significant diffusive changes. In conclusion, the high K/Na ratio suggests that the diabetic B cell has a well-functioning Na+/K+ pump. However, significant and parallel changes in Al-, Cu-, Mg- and Rb-levels were found in both the B cells and acinar portion of the diabetic pancreas. It is not clear whether these elemental changes cause the islet secretory defect or result from it.

Cold storage (8 C) of islets of Langerhans in a high-potassium "intracellular medium": near-normal insulin release and morphology after one week.

Islets of Langerhans from ob/ob mice were microdissected and stored for one week at 8 C or 37 C in a high-potassium "intracellular medium" or in a traditional culture medium (RPMI 1640 +/- fetal calf serum). Subsequent glucose-stimulated insulin release and islet morphology were best preserved by 8 C-storage in the high-potassium "intracellular medium". This suggests that normal, adult, mammalian tissues which do not readily divide in vitro may be better preserved for short periods of time at refrigerator temperatures in a high-potassium medium than by conventional culture at 37 C in a tissue culture medium.

Vitamin D3 stimulates calcium-45 uptake by isolated mouse islets in vitro.

Islets isolated from ob/ob mice which had been fed a vitamin D-deficient diet released significantly less insulin in response to glucose than did vitamin D-replete islets but showed normal net 45Ca2+ uptake. To determine whether vitamin D3 has a direct effect on the pancreatic B cell, islets from ob/ob mice on a normal diet were exposed to vitamin D3 in vitro for 1 week or only 3 h, and then glucose-stimulated 45Ca2+ uptake and insulin release were measured. Exposure to 1 nM or 1 microM vitamin D3 for 1 week stimulated 45Ca2+ uptake in the presence of 3 mM, but not 20 mM glucose, and did not affect insulin release. Exposure to vitamin D3 for 3 h did not significantly increase net 45Ca2+ uptake although there was a tendency to such an effect (P = 0.10). In conclusion, vitamin D-deficiency in vivo suppressed subsequent glucose-stimulated insulin release in vitro and this effect may be due to a direct effect of the sterol (or one of its metabolites) on calcium handling by the B cell.

Insulin, glucagon, and somatostatin release from the prediabetic Chinese hamster.

Diabetes mellitus in the adult Chinese hamster is characterized by subnormal pancreatic insulin release in vitro, decreased insulin content, and lack of obesity. The cause of the islet B-cell failure is not clear. We measured insulin, glucagon, and somatostatin release from in vitro perfused pancreases of young (mean age 10 and 20 weeks), genetically diabetic animals (subline AC, mean plasma glucose 8.0 and 16.6 mmol/l, respectively). Compared to age- and sex-matched normal hamsters (subline M, mean plasma glucose 5.3 mmol/l), the younger diabetic animals had a significantly elevated mean plasma glucose level, but net in vitro pancreatic release of insulin, glucagon, and somatostatin was normal. Pancreatic content of insulin and glucagon was also not significantly different from normal. At age 20 weeks, when the plasma glucose of the diabetic animals was even more elevated, pancreatic content and release of insulin were significantly subnormal, whereas glucagon and somatostatin release were normal, and pancreatic content of glucagon was normal. In a similar group of young (mean age 10 weeks) diabetic animals, non-fasting plasma insulin levels were within the normal range, but the corresponding glucose levels were excessive in most of the animals (13 out of 19). In conclusion, 10-week-old diabetic hamsters show mild hyperglycaemia which cannot be accounted for directly by decreased pancreatic release in response to a glucose plus arginine stimulus in vitro. Decreased ability of the B cell to respond in vivo to hyperglycaemia or peripheral resistance to insulin may contribute to later B-cell failure in the older diabetic hamster.

Cyclophosphamide treatment of prediabetic Chinese hamsters.

To assess the immune system's involvement in the causation of diabetes in the genetically diabetic Chinese hamster, "prediabetic" animals were immunosuppressed with cyclophosphamide, starting several weeks prior to the expected onset of hyperglycemia. The immunosuppressant dose was titrated to maximally depress the lymphocyte count without significant deleterious effects on food consumption, body weight or granulocyte count. Immunosuppression did not prevent or postpone the development of hyperglycemia or glucosuria. This suggests that if there is an autoimmune component in the etiology of diabetes in the genetically diabetic Chinese hamster, it takes place earlier or is of a more specific nature than that investigated in the present study.

Beta cell membrane potential and insulin release; role of calcium and calcium:magnesium ratio.

Glucose-induced insulin release from perfused rat pancreas was compared with glucose-induced changes in membrane potential of beta cells from mouse islets. Extracellular concentrations of Ca and Mg were varied as steps, simultaneously or separately, from 10% to 200% of normal in the presence of 11.1 mM glucose. A change in Ca induced a transient change in electrical activity paralleled by a transient change in insulin release. If the Ca/Mg ratio was maintained, steady-state insulin release remained constant between 10% and 200% Ca, while electrical activity showed alterations. Analysis of burst parameters indicated that increased or decreased Ca entry was balanced by decreased or increased excitability. It is postulated that the beta cell contains a compensator mechanism for the regulation of Ca influx.

Insulin and glucagon release in the diabetic Chinese hamster: differences among inbred sublines.

Release of insulin and glucagon from perfused pancreases in vitro of 40 normal male and female Chinese hamsters (from one inbred subline) and 110 male and female diabetic hamsters (from three inbred sublines) was measured in response to glucose plus arginine, theophylline alone, or potassium alone, in order to determine if differences in hormone secretion exist among different diabetic sublines. Glucose plus arginine and potassium produced subnormal insulin responses in all three diabetic sublines, whereas theophylline induced 'normal' or above normal insulin responses. Excessive glucagon release was consistently seen in only one diabetic subline. The female normal animals showed greater insulin release than the male normal hamsters in response to glucose plus arginine. This sex difference was not seen in the diabetic animals.

Effects of K+ and arginine on insulin, glucagon, and somatostatin release from the in vitro perfused rat pancreas.

Rat pancreases were perfused in vitro for 5-min periods with K+ alone (8, 10, and 12 mM) or in the presence of arginine (10 mM). Alone, K+ caused bursts of insulin, glucagon, and somatostatin (SRIF) release; with arginine, it caused a burst of insulin and sustained SRIF release, but caused sustained suppression of glucagon. This suppression correlated better with SRIF than insulin release. Therefore, if a paracrine effect is responsible for the inhibition of glucagon secretion under these circumstances, SRIF is a more likely candidate than insulin.

Calcium affects insulin release and membrane potential in islet beta-cells.

Insulin release from perfused rat pancreas was compared with membrane potentials of single beta-cells from perifused mouse islets during glucose stimulation (11.1 mM) in the presence of varying Ca and Mg concentrations. Depolarization was associated with insulin release and hyperpolarization with its suppression, irrespective of Ca concentration. After sudden reduction of Ca and Mg (to 0.05 and 0.01 mM, respectively), glucose-stimulated insulin release was maintained while the cell membrane depolarized, leading to a reversed pattern of burst activity. Readdition of Ca and Mg caused suppression of insulin release that paralleled hyperpolarization of the cell membrane. This suppression was transient, lasting < 5 min, and was due mainly to readdition of Ca. Patterns of insulin release during reduction of Ca and Mg in the presence of valinomycin (1 microM), diphenylhydantoin (25 microgram/ml), and ethyleneglycol-bis(beta-aminoethylether)-N,N'-tetraacetic acid (0.037 and 1.0 mM) were also studied. In conclusion, the relative concentrations of Ca and Mg and the membrane potential per se are important in the release of insulin. Also, under certain experimental conditions, Ca can block glucose-stimulated insulin release, possibly by increasing K+ permeability.