Pancreatic-specific inactivation of IGF-I gene causes enlarged pancreatic islets and significant resistance to diabetes

The dogma that IGF-I stimulates pancreatic islet growth has been challenged by combinational targeting of IGF or IGF-IR (IGF receptor) genes as well as beta-cell-specific IGF-IR gene deficiency, which caused no defect in islet cell growth. To assess the physiological role of locally produced IGF-I, we have developed pancreatic-specific IGF-I gene deficiency (PID) by crossing Pdx1-Cre and IGF-I/loxP mice. PID mice are normal except for decreased blood glucose level and a 2.3-fold enlarged islet cell mass. When challenged with low doses of streptozotocin, control mice developed hyperglycemia after 6 days that was maintained at high levels for at least 2 months. In contrast, PID mice only exhibited marginal hyperglycemia after 12 days, maintained throughout the experiment. Fifteen days after streptozotocin, PID mice demonstrated significantly higher levels of insulin production. Furthermore, streptozotocin-induced beta-cell apoptosis (transferase-mediated dUTP nick-end labeling [TUNEL] assay) was significantly prevented in PID mice. Finally, PID mice exhibited a delayed onset of type 2 diabetes induced by a high-fat diet, accompanied by super enlarged pancreatic islets, increased insulin mRNA levels, and preserved sensitivity to insulin. Our results suggest that locally produced IGF-I within the pancreas inhibits islet cell growth; its deficiency provides a protective environment to the beta-cells and potential in combating diabetes.     

Comparison of insulin secretory patterns in obese nondiabetic LA/N-cp and obese diabetic SHR/N-cp rats. Role of hyperglycemia

Obese diabetic SHR/N-(cp/cp) rats are a genetic model for non-insulin-dependent diabetes mellitus. When SHR/N-cp rats are overtly diabetic, they are hyperinsulinemic and hyperglycemic in the fed state when consuming commercial chow or semipurified high-carbohydrate diets. Obese SHR/N-cp rats were hyperinsulinemic by 4 wk of age, although hyperglycemia did not appear until 3-4 wk later and was exacerbated by a high-sucrose diet (mean +/- SE 1488 +/- 238 microU/ml insulin and 425 +/- 51 mg/dl glucose). The control SHR/N-cp rats (+/?) on the sucrose diet remained lean and normoglycemic. The obese diabetic SHR/N-cp rats showed three alterations in pancreas perfusion data (not present in control rats): 1) paradoxically high insulin secretion at low glucose levels (2.5 mM), 2) secretion of insulin in response to arginine (10 mM) in the absence of glucose, and 3) impaired response of insulin secretion to high glucose (16.7 mM). To determine whether hyperglycemia was responsible for the abnormalities of insulin secretion, perfusion studies were conducted in obese nondiabetic LA/N-cp rats and compared with the SHR/N-cp rats. The obese LA/N-cp rats resembled the corpulent SHR/N-cp rats in every way, except that they were normoglycemic on the sucrose diet. The obese LA/N-cp rats had two of the three alterations in insulin secretion shown by obese SHR/N-cp rats, lacking only the impaired response to high glucose, suggesting that hyperglycemia was required for that defect to occur.(ABSTRACT TRUNCATED AT 250 WORDS)     

"Activated" T-lymphocyte levels in the spontaneously diabetic BB rat syndrome

About 50% of individual members of a diabetes-prone stock of BB rats eventually become hyperglycemic (usually between 60 and 180 days of age) while the remainder remain normoglycemic for life. Circulating levels of Ia antigen bearing T-lymphocytes from different lymphoid compartments of acutely diabetic and normoglycemic (but diabetes prone) BB rats were determined with monoclonal antibodies in an effort to analyze the temporal relationship between levels of this unusual T cell antigen and the onset of diabetes. In young normoglycemic rats elevated blood levels of Ia-positive T-lymphocytes (greater than or equal to 4.00%) predicted the future development of hyperglycemia with a sensitivity of 85% and a specificity of 83%. The interval between the identification of these elevated levels and the onset of diabetes ranged from 22 to 82 days. After the development of hyperglycemia the level of Ia-positive T-lymphocytes declined progressively in all lymphoid compartments with chronicity of the diabetes. We conclude that Ia antigens bearing T cells serve as immunologic "markers" of susceptibility to diabetes in this "high-risk" population and probably reflect an ongoing immune process during the prediabetic state. Similar findings in humans with a family history of diabetes might lead to identification of prediabetic individuals and allow selective use of immunomodulation to prevent the disease.     

Glucagon-like peptide-1 gene therapy in obese diabetic mice results in long-term cure of diabetes by improving insulin sensitivity and reducing hepatic gluconeogenesis

Long-term treatment with glucagon-like peptide (GLP)-1 or its analog can improve insulin sensitivity. However, continuous administration is required due to its short half-life. We hypothesized that continuous production of therapeutic levels of GLP-1 in vivo by a gene therapy strategy may remit hyperglycemia and maintain prolonged normoglycemia. We produced a recombinant adenovirus expressing GLP-1 (rAd-GLP-1) under the cytomegalovirus promoter, intravenously injected it into diabetic ob/ob mice, and investigated the effect of this treatment on remission of diabetes, as well as the mechanisms involved. rAd-GLP-1-treated diabetic ob/ob mice became normoglycemic 4 days after treatment, remained normoglycemic over 60 days, and had reduced body weight gain. Glucose tolerance tests found that exogenous glucose was cleared normally. rAd-GLP-1-treated diabetic ob/ob mice showed improved beta-cell function, evidenced by glucose-responsive insulin release, and increased insulin sensitivity, evidenced by improved insulin tolerance and increased insulin-stimulated glucose uptake in adipocytes. rAd-GLP-1 treatment increased basal levels of insulin receptor substrate (IRS)-1 in the liver and activation of IRS-1 and protein kinase C by insulin in liver and muscle; increased Akt activation was only observed in muscle. rAd-GLP-1 treatment reduced hepatic glucose production and hepatic expression of phosphoenolpyruvate carboxykinase, glucose-6-phosphatase, and fatty acid synthase in ob/ob mice. Taken together, these results show that a single administration of rAd-GLP-1 results in the long-term remission of diabetes in ob/ob mice by improving insulin sensitivity through restoration of insulin signaling and reducing hepatic gluconeogenesis.     

A pentadecapeptide fragment of islet neogenesis-associated protein increases beta-cell mass and reverses diabetes in C57BL/6J mice

OBJECTIVE: The objective of this study was to demonstrate that islet neogenesis-associated protein (INGAP) peptide, a pentadecapeptide containing the biologically active portion of native INGAP, increases functional beta-cell mass in normal animals and can be used therapeutically to reverse hyperglycemia in streptozotocin-induced diabetes. SUMMARY BACKGROUND DATA: INGAP, a 175 amino acid pancreatic acinar cell protein, has been suggested to be implicated in beta-cell mass expansion. METHODS: In the first part of this study, normoglycemic hamsters were administered either 500 microg INGAP peptide (n = 30) or saline (n = 20) intraperitoneally daily and sacrificed after 10 or 30 days of treatment. Blood glucose and insulin levels were measured, and a histologic and morphometric analysis of the pancreas was performed to determine the effect of INGAP peptide on the endocrine pancreas. In the second part of the study, 6- to 8-week-old C57BL/6J mice (n = 8) were administered multiple low doses of the beta-cell toxin streptozotocin (STZ) inducing insulitis and hyperglycemia. The mice were then injected with INGAP peptide (n = 4) or saline (n = 4) for 39 days and sacrificed at 48 days. Two additional groups of diabetic mice were administered either a peptide composed of a scrambled sequence of amino acids from INGAP peptide (n = 5) or exendin-4 (n = 5), an incretin that has been associated with amelioration of hyperglycemia. RESULTS: Islet cell neogenesis was stimulated in INGAP-treated hamsters by 10 days. At 30 days, the foci of new endocrine cells had the appearance of mature islets. There was a 75% increase in islet number, with normal circulating levels of blood glucose and insulin. Administration of INGAP peptide to diabetic mice reversed the diabetic state in all animals, and this was associated with increased expression of PDX-1 in duct cells and islet cell neogenesis with a reduction of insulitis in the new islets. Diabetic mice treated with exendin-4 or a scrambled INGAP peptide did not revert from hyperglycemia. CONCLUSION: Because there is a deficiency of beta-cell mass in both type-1 and type-2 diabetes, INGAP peptide stimulation of fully functional neoislet differentiation may provide a novel approach for diabetes therapy.     

Severe diabetes induced in subtotally depancreatized dogs by sustained hyperglycemia

Chronic clamping of plasma glucose levels at greater than or equal to 250 mg/dl in four partially depancreatized but previously nondiabetic dogs was followed within 2 wk by persistent hyperglycemia and glycosuria of less than or equal to 500 g/day, ketonuria, and weight loss. Three of the four dogs required daily insulin injections to control these catabolic manifestations. There was no evidence of spontaneous improvement of the severe diabetic state during the 39-69 days of observation after discontinuation of intravenous glucose infusion. Impairment of intravenous glucose tolerance, loss of the insulin response to glucose and arginine, fasting hyperglucagonemia, exaggerated glucagon responsiveness to arginine, and a significant reduction in sensitivity to insulin were characteristic of all diabetic dogs. Morphometric analysis of the endocrine pancreas revealed a profound reduction in the number and size of identifiable islets of the hyperglycemic dogs compared with islets from their own pancreases resected months earlier and with those from pancreatic remnants of eight subtotally depancreatized control dogs that had not been subjected to chronic hyperglycemic clamping. The reduction in number and size of islets of the hyperglycemic dogs was largely the consequence of depletion of insulin-containing cells and was similar to that of dogs with long-standing alloxan-induced diabetes. In the eight control dogs, clinical evidence of diabetes did not develop during a follow-up period of 193-296 days. In this group, there was no evidence of diminution of intravenous glucose tolerance, of the insulin response to glucose or arginine, or of insulin sensitivity as determined by an acute hyperinsulinemic hyperglycemic clamp. The number and size of islets and number of beta-cells in pancreatic remnants from these dogs did not differ morphometrically from those of the pancreatic segment that had been resected. We conclude that in subtotally depancreatized but nondiabetic dogs, maintenance of constant hyperglycemia of greater than or equal to 250 mg/dl by means of intravenous glucose infusion causes a severe, persistent, and often insulin-requiring diabetic state that does not occur in the absence of the hyperglycemia.     

Glucose effects on skin keratinocytes: implications for diabetes skin complications.

Altered skin wound healing is a common cause of morbidity and mortality among diabetic patients. However, the molecular mechanisms whereby diabetes alters skin physiology have not been elucidated. In this study, we investigated the relative roles of hyperglycemia, insulin, and IGF-I, all of which are abnormal in diabetes, in primary murine skin keratinocytes. These cells proliferate and differentiate in vitro in a manner similar to skin in vivo. It was found that in the presence of high glucose (20 mmol/l), the glucose transport rate of primary proliferating or differentiating keratinocytes was downregulated, whereas at 2 mmol/l glucose, the transport rate was increased. These changes were associated with changes in the GLUT1 expression and with changes in the affinity constant (K(m)) of the transport. Exposure to high glucose was associated with changes in cellular morphology, as well as with decreased proliferation and enhancement of Ca(2+)-induced differentiation of keratinocytes. Furthermore, in the presence of high glucose, ligand-induced IGF-I receptor but not insulin receptor (IR) autophosphorylation was decreased. Consequently, in high glucose, the effects of IGF-I on glucose uptake and keratinocyte proliferation were inhibited. Interestingly, lack of IR expression in IR-null keratinocytes abolished insulin-induced glucose uptake and partially decreased insulin- and IGF-I-induced proliferation, demonstrating the direct involvement of the IR in these processes. Our results demonstrate that hyperglycemia and impaired insulin signaling might be directly involved in the development of chronic complications of diabetes by impairing glucose utilization of skin keratinocytes as well as skin proliferation and differentiation.     

IGF-I--stimulated glucose transport in human skeletal muscle and IGF-I resistance in obesity and NIDDM

Based on the observation that insulinlike growth factor I (IGF-I) can stimulate glucose utilization in nondiabetic subjects and that the action of the IGF-I receptor is normal in the skeletal muscle of patients with non-insulin-dependent diabetes mellitus (NIDDM), it seems possible that IGF-I might provide an effective acute treatment for the hyperglycemia of NIDDM. Using our recently developed in vitro human muscle preparation, we investigated the hypothesis that IGF-I might be an effective alternative to insulin in stimulating glucose transport in diabetic muscle. Abdominal muscle samples from nonobese nondiabetic, obese nondiabetic, and obese NIDDM patients were obtained during elective abdominal surgery. Plasma levels of IGF-I in diabetic patients were lower than those in either of the nondiabetic groups. Binding studies with wheat-germ-agglutinin-chromatography-purified receptors demonstrated the presence of IGF-I receptors in human muscle, with IGF-I binding being approximately 24% that of insulin. There was no change in IGF-I binding in muscle from obese or diabetic subjects, and the structural characteristics of the IGF-I receptor were not altered, as determined by electrophoretic mobility. IGF-I stimulated glucose transport approximately twofold in incubated muscle from control subjects, but there was no IGF-I stimulation of transport in muscle from obese subjects with or without NIDDM. These results confirm a previous report that human muscle contains receptors for IGF-I and demonstrate for the first time that IGF-I can stimulate glucose transport in human muscle. However, muscle from obese subjects with or without NIDDM is resistant to the action of IGF-I.     

Analysis of differential survival of syngeneic islets transplanted into hyperglycemic C57BL/6J versus C57BL/KsJ mice

C57BL/KsJ (BKs) male mice were more sensitive to diabetes induction by administration of multiple low-doses of streptozotocin (Sz) than were C57BL/6J (B6) male mice. Analysis of islet size and insulin content of the two parental strains did not indicate that differences in drug sensitivity could be attributed to an effect of genetic background on islet size or insulin content. 50 BKs islets implanted into the spleens of BKs male mice made diabetic by Sz were eliminated within 12 days posttransplantation, whereas an equal number of B6 islets implanted into the spleens of diabetic B6 recipients were retained, even though the numbers of islets implanted were insufficient to effect remission from hyperglycemia. In contrast to the rapid loss of islets implanted into spleens of hyperglycemic BKs recipients, BKs islets implanted into spleens of normoglycemic recipients were not eliminated, thus suggesting that the basis for the differential survival between the B6 and BKs strains reflected their ability to survive hyperglycemic stress rather than a differential ability to replicate. Since BKs beta cells have been shown to respond to hyperglycemia by expression of an endogenous retroviral gene that cannot be expressed by B6 beta cells, the possibility that this differential survival represents a strain difference in autoreactivity against islet cells is raised.     

Effects of hyperglycemia on function of isolated mouse pancreatic islets transplanted under kidney capsule

The insulin release from isolated pancreatic islets grafted under the kidney capsule was examined by means of a modified kidney-perfusion technique. The grafts, consisting of 150 C57BL/6 or 250 C57BL/Ks mouse islets, were implanted syngeneically under the left kidney capsule of normoglycemic or alloxan-induced diabetic recipients 4 wk before the perfusion. In both mouse strains, islets grafted to normoglycemic animals showed an immediate distinct peak of insulin release when challenged with high glucose, whereas no response was observed from islets grafted to hyperglycemic mice. In a similar way in C57BL/Ks mice, arginine stimulated insulin release from the islet grafts in normoglycemic but not in hyperglycemic recipients. Insulin treatment of the diabetic recipients, however, partially normalized the insulin response to glucose. Islet grafts were removed in toto and analyzed for contents of insulin, glucagon, somatostatin, and DNA or rates of glucose-stimulated (pro)insulin biosynthesis. In both mouse strains, islets implanted into hyperglycemic animals contained significantly less insulin, and their rates of (pro)insulin biosynthesis were markedly decreased. Insulin treatment only marginally affected these parameters. The glucagon content of the grafted islets was unaffected by the hyperglycemia in both strains of mice, whereas a significant decrease in the somatostatin content was observed in the C57BL/Ks mice. We concluded that grafted islets exposed to prolonged hyperglycemic stress become functionally impaired in mice of both strains. Our perfusion technique of islet-graft-bearing kidneys in combination with biochemical studies on the removed grafts provides a suitable model for studies of the effects of prolonged hyperglycemia on islet beta-cell function.     

Diabetic rats transplanted with adult porcine islets and immunosuppressed with cyclosporine A, mycophenolate mofetil, and leflunomide remain normoglycemic for up to 100 days

BACKGROUND: Transplantation of adult porcine islets (APIs) offers a possible means of treating diabetes. However, isolating APIs has been notoriously difficult. Furthermore, islet xenograft rejection must be prevented. MATERIALS AND METHODS: APIs were isolated by a modified automated method. API quality was assessed by static glucose stimulation (SGS), by transplantation to diabetic nude mice and by intraperitoneal glucose tolerance tests (IPGTTs). The morphologic characteristics of API xenograft rejection in rats were studied immunohistochemically. Furthermore, APIs were transplanted to diabetic rats that were either left untreated or immunosuppressed with cyclosporine A (CsA), mycophenolate mofetil (MMF) and leflunomide (LEF). B-glucose and porcine C-peptide levels were monitored and grafts were studied morphologically. RESULTS: Large numbers of APIs were isolated. At SGS, insulin release increased significantly. All nude mice transplanted with APIs were normoglycemic within 24 hr and remained so for up to 1 year. During IPGTTs, B-glucose levels were rapidly regulated to porcine levels. In untreated rats, API xenografts were destroyed within 6 days by a cellular infiltrate consisting mainly of macrophages. In untreated diabetic rats normoglycemia was sustained for 5.5+/-0.3 days. Rats immunosuppressed with CsA+MMF+LEF remained normoglycemic for 59.6+/-11.3 days. In 3 of 11 rats, normoglycemia was sustained for up to 101 days. Porcine C-peptide was detected in serum. At recurrence of hyperglycemia, many mononuclear cells were found close to the xenografts. However, only occasional cells infiltrated the grafts and many APIs were intact. CONCLUSIONS: Well-functioning APIs can be isolated in large numbers. API xenografts can be protected from rejection and can maintain an adequate function for up to 100 days, in rats immunosuppressed with CsA+MMF+LEF.     

Optimal insulin treatment in syngeneic islet transplantation

Insulin-induced normoglycemia has shown to have a beneficial effect on the outcome of pancreatic islets transplanted to diabetic recipients. The aim of the study was to identify the insulin treatment that can maximize its beneficial effect on islet transplants. Six groups of streptozotocin diabetic C57Bl/6 mice were transplanted (Tx) with 100 syngeneic islets, an insufficient beta cell mass to restore normoglycemia, and were treated with insulin as follows: group 1 (n = 9): from day 10 before Tx to day 14 after Tx; group 2 (n = 11): from day 6 before Tx to Tx day; group 3 (n = 11): from Tx day to day 6 after Tx; group 4 (n = 7): from Tx day to day 14 after Tx; group 5 (n = 8): from day 10 to day 24 after Tx; group 6 (n = 18): Tx mice were not treated with insulin. Sixty days after Tx, normoglycemia was achieved in 100% of mice in groups 1, 4, and 5, in 73% of mice in group 2, and in only 45% and 33% of mice in groups 3 and 6, respectively (p < 0.01). Intraperitoneal glucose tolerance, determined only in normoglycemic mice, was similar in groups 1, 2, 4, and normal controls. In contrast, normoglycemic mice from groups 3, 5, and 6, exposed to more severe and prolonged hyperglycemia after Tx, showed higher glucose values after glucose injection, suggesting that hyperglycemia had a long-lasting deleterious effect on transplanted beta cell function. The initially transplanted beta cell mass was maintained in the grafts of normoglycemic mice, but was severely reduced in hyperglycemic mice. Transplanted beta cell mass was similar in normoglycemic groups with normal or impaired glucose tolerance, indicating that impaired glucose tolerance was not due to reduced beta cell mass. In summary, the beneficial effect of insulin-induced normoglycemia on transplanted islets was maximal when insulin treatment was maintained the initial 14 days after transplantation. Exposure to sustained hyperglycemia initially after transplantation had a long-lasting deleterious effect on transplanted islets.     

Experimental diabetes induces functional and structural changes in the peritoneum

BACKGROUND: Peritoneal dialysis (PD) is an established renal replacement therapy in diabetic patients, but the influence of diabetes on the peritoneal membrane (PM) remains debated. We have used functional, biochemical and molecular studies in vivo and in vitro to substantiate the changes induced by diabetes and hyperglycemia in the PM. METHODS: Peritoneal equilibration tests were performed 2, 4, and 6 weeks after induction of diabetes with streptozotocin (STZ) in rats. Morphological analyses, determination of nitric oxide synthase (NOS) activities, and expression studies for NOS isoforms and advanced glycation end products (AGE) were performed in parallel. Additional studies were conducted in diabetic rats treated with insulin, non-diabetic rats fed with urea, and cultured bovine aortic endothelial cells (BAEC). RESULTS: In comparison with controls, diabetic rats were characterized by: increased permeability for small solutes and decreased sodium sieving; capillary proliferation; increased endothelial NOS (eNOS) and AGE immunoreactivity; up-regulation of eNOS and down-regulation of neuronal NOS; and increased NOS activity in the PM. The changes, which culminated at week 6, were prevented by chronic insulin treatment in diabetic rats. In contrast to hyperglycemia, hyperosmolality alone did not induce functional or structural changes in the PM. Studies in BAEC showed that high glucose incubation led to increased activity and expression of eNOS, a prerequisite for vascular proliferation. CONCLUSIONS: These data demonstrate that chronic hyperglycemia is associated with functional and structural changes in the peritoneum that parallel with selective regulation of NOS isoforms and AGE deposits. The alterations are prevented by insulin treatment, which suggests that adequate control of diabetes can preserve PM integrity in diabetic patients prior to PD.     

Hyperglycemia decreases glucose uptake in type I diabetes

It has recently been postulated that hyperglycemia per se may contribute to insulin resistance in diabetes. To examine this possibility directly, we measured glucose uptake after 24 h of hyperglycemia (281 +/- 16 mg/dl) and normoglycemia (99 +/- 6 mg/dl) in 10 type I (insulin-dependent) diabetic patients (age 33 +/- 3 yr, relative body wt 102 +/- 3%) treated with continuous subcutaneous insulin infusion. Hyperglycemia was induced by an intravenous glucose infusion, whereas saline was administered during the control day. During both studies the patient received a similar diet and insulin dose. After hyper- and normoglycemia, a primed continuous infusion of insulin (40 mU X m-2 X min-1) was started, and plasma glucose was adjusted to and maintained at 142 +/- 2 and 140 +/- 2 mg/dl, respectively, during 60-160 min of insulin infusion. The rate of glucose uptake after hyperglycemia averaged 8.3 +/- 1.1 mg X kg-1 X min-1, which was lower than the rate after the normoglycemic period (10.1 +/- 1.2 mg X kg-1 X min-1, P less than .001). In conclusion, short-term hyperglycemia reduces glucose uptake in type I diabetic patients. Thus, part of the glucose or insulin resistance in these patients may be caused by hyperglycemia per se.     

The diabetic phenotype is conserved in myotubes established from diabetic subjects: evidence for primary defects in glucose transport and glycogen synthase activity

The most well-described defect in the pathophysiology of type 2 diabetes is reduced insulin-mediated glycogen synthesis in skeletal muscles. It is unclear whether this defect is primary or acquired secondary to dyslipidemia, hyperinsulinemia, or hyperglycemia. We determined the glycogen synthase (GS) activity; the content of glucose-6-phosphate, glucose, and glycogen; and the glucose transport in satellite cell cultures established from diabetic and control subjects. Myotubes were precultured in increasing insulin concentrations for 4 days and subsequently stimulated acutely by insulin. The present study shows that the basal glucose uptake as well as insulin-stimulated GS activity is reduced in satellite cell cultures established from patients with type 2 diabetes. Moreover, increasing insulin concentrations could compensate for the reduced GS activity to a certain extent, whereas chronic supraphysiological insulin concentrations induced insulin resistance in GS and glucose transport activity. Our data suggest that insulin resistance in patients with type 2 diabetes comprises at least two important defects under physiological insulin concentrations: a reduced glucose transport under basal conditions and a reduced GS activity under acute insulin stimulation, implicating a reduced glucose uptake in the fasting state and a diminished insulin-mediated storage of glucose as glycogen after a meal.     

Dynamic changes in {beta}-cell mass and pancreatic insulin during the evolution of nutrition-dependent diabetes in psammomys obesus: impact of glycemic control

Recent studies ascribe a major role to pancreatic beta-cell loss in type 2 diabetes. We investigated the dynamics of beta-cell mass during diabetes evolution in Psammomys obesus, a model for nutrition-dependent type 2 diabetes, focusing on the very early and the advanced stages of the disease. P. obesus fed a high-calorie diet for 26 days developed severe hyperglycemia, beta-cell degranulation, and markedly reduced pancreatic insulin content. Reducing calories for 7 days induced normoglycemia in 90% of the animals, restoring beta-cell granulation and insulin content. To dissociate effects of diet from blood glucose reduction, diabetic animals received phlorizin for 2 days, which normalized glycemia and increased the pancreatic insulin reserve to 50% of control, despite a calorie-rich diet. During diabetes progression, beta-cell mass decreased initially but recovered spontaneously to control levels, despite persistent hyperglycemia. Strikingly, however, beta-cell mass did not correlate with degree of hyperglycemia or pancreatic insulin content. We conclude that reduced insulin reserve is the main cause of diabetes progression, whereas irreversible beta-cell mass reduction is a late event in P. obesus. The rapid recovery of the pancreas by phlorizin-induced normoglycemia implies a causal relationship between hyperglycemia and islet dysfunction. Similar mechanisms could be operative during the evolution of type 2 diabetes in humans.     

Inhibitory effect of a growth hormone receptor antagonist (G120K-PEG) on renal enlargement, glomerular hypertrophy, and urinary albumin excretion in experimental diabetes in mice.

Growth hormone (GH) and IGFs have a long and distinguished history in diabetes, with possible participation in the development of renal complications. To investigate the effect of a newly developed GH receptor (GHR) antagonist (G120K-PEG) on renal/glomerular hypertrophy and urinary albumin excretion (UAE), streptozotocin-induced diabetic and nondiabetic mice were injected with G120K-PEG every 2nd day for 28 days. Placebo-treated diabetic and nondiabetic animals were used as reference groups. Placebo-treated diabetic animals were characterized by growth retardation, hyperphagia, hyperglycemia, increased serum GH levels, reduced serum IGF-I, IGF-binding protein (IGFBP)-3, and liver IGF-I levels, increased kidney IGF-I, renal/glomerular hypertrophy, and increased UAE when compared with nondiabetic animals. No differences were seen between the two diabetic groups with respect to body weight, food intake, blood glucose, serum GH, IGF-I, and IGFBP-3 levels or hepatic IGF-I levels. Kidney IGF-I, kidney weight, and glomerular volume were normalized, while the rise in UAE was partially attenuated in the G120K-PEG-treated diabetic animals. No effect of G120K-PEG treatment on any of the parameters mentioned above was seen in nondiabetic animals. In conclusion, administration of a GHR antagonist in diabetic mice has renal effects without affecting metabolic control and circulating levels of GH, IGF-I, or IGFBP-3, thus indicating that the effect of G120K-PEG may be mediated through a direct inhibitory effect on renal IGF-I through the renal GHR. The present study suggests that specific GHR blockade may present a new concept in the treatment of diabetic kidney disease.