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Abstract
The gerbil Psammomys obesus develops nutrition-dependent diabetes. We studied the interaction between diet and diabetic predisposition for beta-cell function. A 4-day high-energy (HE) diet induced a 3-, 4-, and 1.5-fold increase in serum glucose, insulin, and triglycerides, respectively, in diabetes-prone (DP) but not diabetes-resistant (DR) P. obesus. Hyperglycemia and concurrent 90% depletion of islet immunoreactive insulin stores were partially corrected by an 18-h fast. In vitro early insulin response to glucose was blunted in both DR and DP perifused islets. The HE diet augmented early and late insulin response in DR islets, whereas in DP islets, secretion progressively declined. Dose-response studies showed a species-related increase in islet glucose sensitivity, further augmented in DP P. obesus by a HE diet, concomitant with a decreased threshold for glucose and a 55% reduction in maximal response. These changes were associated with a fourfold increase in glucose phosphorylation capacity in DP islets. There were no differences in islet glucokinase (GK) and hexokinase (HK) Km; however, GK Vmax was 3.7- to 4.6-fold higher in DP islets, and HK Vmax was augmented 3.7-fold by the HE diet in DP islets. We conclude that the insulin-resistant P. obesus has an inherent deficiency in insulin release. In the genetically predisposed P. obesus (DP), augmented islet glucose phosphorylation ability and diet-induced reduction of the glucose threshold for secretion may lead to inadequate insulin secretion and depletion of insulin stores in the presence of caloric abundance. Thus, genetic predisposition and beta-cell maladaptation to nutritional load seem to determine together the progression to overt diabetes in this species. It is hypothesized that similar events may occur in obese type 2 diabetic patients.
... Indeed, prolonged or intermittent exposure of rodent and human islets to elevated glucose concentrations in vitro has been shown to increase β-cell apoptosis (Ling et al. 1994, Efanova et al. 1998, Piro et al. 2002, Khaldi et al. 2004, DelGuerra et al. 2007, Hou et al. 2008b, Bensellam et al. 2009, Jonas et al. 2009). These results are strongly supported by the observation of increased β-cell apoptosis in different animal models of T2D , Pick et al. 1998, Donath et al. 1999, Finegood et al. 2001, Song et al. 2008) and in human patients (Butler et al. 2003, Jurgens et al. 2011. However, the rate of β-cell apoptosis is relatively low and may not fully explain the loss of β-cell mass in T2D. ...
... GK rat islets ( Px rat islets (Jonas et al. 1999) ZDF rat islets (Cockburn et al. 1997) db/db mouse islets (Kjorholt et al. 2005) Psammomys obesus (Nesher et al. 1999) mRNA and enzymatic activity ...
... In the context of diabetes, increased mRNA levels of Hk1 have been reported in Px rats and db/db mouse islets (Jonas et al. 1999, Kjorholt et al. 2005. In agreement, HK enzymatic activity was upregulated in the islets of ZDF rats (Cockburn et al. 1997), DBA/2 mice (Kooptiwut et al. 2002) and Psammomys obesus on high energy diet (Nesher et al. 1999). Moreover, exposure of rat islets to elevated glucose levels in vitro upregulated the mRNA levels of Hk2 (Ghanaat-Pour et al. 2007) (Table 3). ...
Like all the cells of an organism, pancreatic β-cells originate from embryonic stem cells through a complex cellular process termed differentiation. Differentiation involves the coordinated and tightly controlled activation/repression of specific effectors and gene clusters in a time-dependent fashion thereby giving rise to particular morphological and functional cellular features. Interestingly, cellular differentiation is not a unidirectional process. Indeed, growing evidence suggests that under certain conditions, mature β-cells can lose, to various degrees, their differentiated phenotype and cellular identity and regress to a less differentiated or a precursor-like state. This concept is termed dedifferentiation and has been proposed, besides cell death, as a contributing factor to the loss of functional β-cell mass in diabetes. β-cell dedifferentiation involves: 1) the downregulation of β-cell-enriched genes, including key transcription factors, insulin, glucose metabolism genes, protein processing and secretory pathway genes, 2) the concomitant upregulation of genes suppressed or expressed at very low levels in normal β-cells; the β-cell forbidden genes, and 3) the likely upregulation of progenitor cell genes. These alterations lead to phenotypic reconfiguration of β-cells and ultimately defective insulin secretion. While the major role of glucotoxicity in β-cell dedifferentiation is well established, the precise mechanisms involved are still under investigation. This review highlights the identified molecular mechanisms implicated in β-cell dedifferentiation including oxidative stress, endoplasmic reticulum (ER) stress, inflammation and hypoxia. It discusses the role of FoxO1, MYC and inhibitor of differentiation proteins and underscores the emerging role of non-coding RNAs. Finally, it proposes a novel hypothesis of β-cell dedifferentiation as a potential adaptive mechanism to escape cell death under stress conditions.
... The genetic background for nutrition-evoked diabetes was demonstrated in the Jerusalem colony of P. obesus by selection of two outbred lines of animals: diabetes-prone (DP) and partially diabetes-resistant (DR) P. obesus (3,4). Most animals of the DP line under the age of 4 months develop diabetes when switched from a low-energy (LE) to a high-energy (HE) diet (3); 90% of them display hyperglycemia within the first 4-5 days of HE nutrition (5). In contrast, only 30-40% of the animals of the DR line develop diet-induced diabetes (3). ...
... In contrast, only 30-40% of the animals of the DR line develop diet-induced diabetes (3). Thus, unlike the evolution of diabetes in other rodent models of type 2 diabetes, such as the Zucker diabetic fatty rat (6) and the Otsuka Long-Evans Tokushima fatty rat (7), nutritionally induced diabetes is a rapid event in DP P. obesus (5,8). Progression of diabetes is also fast, with most P. obesus reaching the end stage of the disease within 4-6 weeks of HE nutrition (M.Y., N.K., unpublished data). ...
... Metabolic parameters. Diet-induced hyperglycemia is a very rapid process in DP P. obesus (Fig. 1A); blood glucose level increased from <6 mmol/l in DP P. obesus on an LE diet to an average of 15 mmol/l on day 4 of an HE diet, reaching levels as high as 30 mmol/l after 4 weeks of HE nutrition (5,8). This was accompanied by an initial increase of serum IRI concentrations peaking at 7 days of an HE diet and declining thereafter to levels observed in normoglycemic animals ( Fig. 1C) (8). ...
Deficient insulin secretion and relative hyperproinsulinemia are characteristic features of type 2 diabetes. The gerbil Psammomys obesus appears to be an ideal natural model of the human disease because it shows increased tendency to develop diet-induced diabetes, which is associated with moderate obesity. The disease is characterized by initial hyperinsulinemia, progressing to hypoinsulinemia associated with depleted pancreatic insulin stores and an increased proportion of insulin precursor molecules in the blood and islets. Although the proinsulin translational efficacy was found to be increased in hyperglycemic animals, insulin mRNA levels were not augmented and exhibited a gradual decrease with disease progression. The development of hyperglycemia was associated with a transient increase in beta-cell proliferative activity, as opposed to a prolonged increase in the rate of beta-cell death, culminating in disruption of islet architecture. The hypothesis that glucotoxicity is responsible in part for these in vivo changes was investigated in vitro in primary islet cultures. Islets from diabetes-prone P. obesus cultured at high glucose concentrations displayed changes in beta-cell function that mimic those observed in diabetic animals. These changes include deficient insulin secretion, depleted insulin content, an increased proportion of insulin precursor molecules, a progressive increase of DNA fragmentation, and a transient proliferative response. Furthermore, insulin mRNA was not increased by short-term exposure of P. obesus islets to elevated glucose in vitro. It is proposed that beta-cell glucotoxicity in P. obesus results from the inability of proinsulin biosynthesis to keep pace with chronic insulin hypersecretion. The resulting depletion of the insulin stores may be related to deficient glucose-regulated insulin gene transcription, possibly due to defective PDX-1 (pancreatic duodenal homeobox factor-1) expression in the adult P. obesus. An additional glucotoxic effect involves the loss of beta-cell mass in hyperglycemic P. obesus as a result of progressive beta-cell death without an adequate increase in the rate of beta-cell proliferation.
... The genetic background for this nutrition-evoked diabetes was demonstrated in the Jerusalem colony of P. obesus by selection of two lines of animals, a diabetes-prone (DP) and a diabetes-resistant (DR) line (3). Almost all animals of the DP line develop diabetes when changed from a low-energy (LE) to a high-energy (HE) diet, with 90% developing hyperglycemia within 5 days of HE nutrition (7). Conversely, 60-70% of the animals of the DR line of P. obesus are resistant to diet-induced diabetes and remain normoglycemic on an HE diet. ...
... Conversely, 60-70% of the animals of the DR line of P. obesus are resistant to diet-induced diabetes and remain normoglycemic on an HE diet. Because animals of both lines seem equally resistant to insulin action (8), we studied the relative contributions of genetic predisposition and nutritional intake to -cell dysfunction and demonstrated a species-dependent defect in insulin release in both lines of P. obesus (7). In the DP line, superimposed on this deficiency was a hyperglycemia-induced reduction of the glucose threshold for insulin release with augmented glucose phosphorylation, which promoted depletion of -cell insulin stores (7). ...
... Because animals of both lines seem equally resistant to insulin action (8), we studied the relative contributions of genetic predisposition and nutritional intake to -cell dysfunction and demonstrated a species-dependent defect in insulin release in both lines of P. obesus (7). In the DP line, superimposed on this deficiency was a hyperglycemia-induced reduction of the glucose threshold for insulin release with augmented glucose phosphorylation, which promoted depletion of -cell insulin stores (7). Because very little information is available on -cell stimulus-secretion coupling in P. obesus, the present study was undertaken to examine the major -cell-signaling pathways of glucose-dependent and -independent insulin release and their modification in relation to diet as well as to diabetic predisposition. ...
Psammomys obesus is a model of type 2 diabetes that displays resistance to insulin and deranged beta-cell response to glucose. We examined the major signaling pathways for insulin release in P. obesus islets. Islets from hyperglycemic animals utilized twice as much glucose as islets from normoglycemic diabetes-prone or diabetes-resistant controls but exhibited similar rates of glucose oxidation. Fractional oxidation of glucose was constant in control islets over a range of concentrations, whereas islets from hyperglycemic P. obesus showed a decline at high glucose. The mitochondrial substrates alpha-ketoisocaproate and monomethyl succinate had no effect on insulin secretion in P. obesus islets. Basal insulin release in islets from diabetes-resistant P. obesus was unaffected by glucagon-like peptide 1 (GLP-1) or forskolin, whereas that of islets of the diabetic line was augmented by the drugs. GLP-1 and forskolin potentiated the insulin response to maximal (11.1 mmol/l) glucose in islets from all groups. The phorbol ester phorbol myristic acid (PMA) potentiated basal insulin release in islets from prediabetic animals, but not those from hyperglycemic or diabetes-resistant P. obesus. At the maximal stimulatory glucose concentration, PMA potentiated insulin response in islets from normoglycemic prediabetic and diabetes-resistant P. obesus but had no effect on islets from hyperglycemic P. obesus. Maintenance of islets from hyperglycemic P. obesus for 18 h in low (3.3 mmol/l) glucose in the presence of diazoxide (375 pmol/l) dramatically improved the insulin response to glucose and restored the responsiveness to PMA. Immunohistochemical analysis indicated that hyperglycemia was associated with reduced expression of alpha-protein kinase C (PKC) and diminished translocation of lambda-PKC. In summary, we found that 1) P. obesus islets have low oxidative capacity, probably resulting in limited ability to generate ATP to initiate and drive the insulin secretion; 2) insulin response potentiated by cyclic AMP-dependent protein kinase is intact in P. obesus islets, and increased sensitivity to GLP-1 or forskolin in the diabetic line may be secondary to increased sensitivity to glucose; and 3) islets of hyperglycemic P. obesus display reduced expression of alpha-PKC and diminished translocation of lambda-PKC associated with impaired response to PMA. We conclude that low beta-cell oxidative capacity coupled with impaired PKC-dependent signaling may contribute to the animals' poor adaptation to a high-energy diet.
... Within a few days on a high-energy (HE) diet, DP P. obesus develop hyperglycemia associated with hyperinsulinemia, rapidly followed by a progressive decline in -cell function leading to absolute insulin deficiency (14,15). In contrast, DR P. obesus are less hyperinsulinemic and remain normoglycemic on HE diet (16). Previous studies have shown that after 5 days on HE diet, glucose-stimulated insulin secretion (GSIS) is markedly altered in islets from DP but not DR P. obesus, possibly as a result of decreased insulin content, lower oxidative capacity, and altered protein kinase C activity (16,17). ...
... In contrast, DR P. obesus are less hyperinsulinemic and remain normoglycemic on HE diet (16). Previous studies have shown that after 5 days on HE diet, glucose-stimulated insulin secretion (GSIS) is markedly altered in islets from DP but not DR P. obesus, possibly as a result of decreased insulin content, lower oxidative capacity, and altered protein kinase C activity (16,17). However, a shift to the left of the glucose concentrationresponse curve for insulin secretion was also noted (16), indicating an increased sensitivity to glucose in islets from DP P. obesus fed an HE diet. ...
... Previous studies have shown that after 5 days on HE diet, glucose-stimulated insulin secretion (GSIS) is markedly altered in islets from DP but not DR P. obesus, possibly as a result of decreased insulin content, lower oxidative capacity, and altered protein kinase C activity (16,17). However, a shift to the left of the glucose concentrationresponse curve for insulin secretion was also noted (16), indicating an increased sensitivity to glucose in islets from DP P. obesus fed an HE diet. ...
When fed a high-energy (HE) diet, diabetes-prone (DP) Psammomys obesus develop type 2 diabetes with altered glucose-stimulated insulin secretion (GSIS). Beta-cell stimulus-secretion coupling was investigated in islets isolated from DP P. obesus fed a low-energy (LE) diet (DP-LE) and after 5 days on a HE diet (DP-HE). DP-LE islets cultured overnight in 5 mmol/l glucose displayed glucose dose-dependent increases in NAD(P)H, mitochondrial membrane potential, ATP/(ATP + ADP) ratio, cytosolic calcium concentration ([Ca(2+)](c)), and insulin secretion. In comparison, DP-HE islets cultured overnight in 10 mmol/l glucose were 80% degranulated and displayed an increased sensitivity to glucose at the level of glucose metabolism, [Ca(2+)](c), and insulin secretion. These changes in DP-HE islets were only marginally reversed after culture in 5 mmol/l glucose and were not reproduced in DP-LE islets cultured overnight in 10 mmol/l glucose, except for the 75% degranulation. Diabetes-resistant P. obesus remain normoglycemic on HE diet. Their beta-cell stimulus-secretion coupling was similar to that of DP-LE islets, irrespective of the type of diet. Thus, islets from diabetic P. obesus display an increased sensitivity to glucose at the level of glucose metabolism and a profound beta-cell degranulation, both of which may affect their in vivo GSIS.
... In the present study we have used the Psammomys obesus model of type 2 diabetes to evaluate the possible mechanisms of nutrition-induced -cell dysfunction, focusing on 1) variations in pancreatic insulin reserve and -cell mass and 2) the influence of hyperglycemia on -cell dysfunction. P. obesus seems particularly suitable to address these questions because it is a natural model of nutrition-dependent diabetes, in which hyperglycemia is associated with rapid depletion of pancreatic insulin stores and with temporal changes in -cell proliferation and death that culminate in disturbed islet morphology (13)(14)(15)(16)(17). ...
... After weaning at 3 weeks, animals were maintained on a nondiabetogenic low-energy diet containing 2.38 kcal/g (Koffolk, Petach-Tikva, Israel) and exhibited normoglycemia (random nonfasted blood glucose Ͻ7.8 mmol/l, Accutrend Sensor; Roche Diagnostics, Mannheim, Germany). Diabetes, defined by blood glucose Ͼ8.3 mmol/l, was induced by high-energy diet (2.93 kcal/g; Weizmann Institute of Science, Rehovot, Israel); nearly 90% of the animals developed hyperglycemia within 5 days (16). Only animals that developed hyperglycemia on the high-energy diet were used in our study. ...
... In our previous studies (13,16), moderate caloric increase resulted in rapid development of hyperglycemia in P. obesus, with Ͼ90% of animals exhibiting high glucose levels by day 5. We now show that hyperglycemia is already apparent by 24 h of high-energy diet feeding (Fig. 3), although only 50% of the animals are hyperglycemic at this time (not shown). ...
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.
... Nutrition-induced diabetes in DP P. obesus is a rapid process (Fig. 1). Blood glucose increases from an average nonfasted level of Ͻ6 mmol/l to 12-15 mmol/l during the 1st week of the HE diet and to 20 -30 mmol/l by 3-4 weeks, after which some animals progress to the terminal stage of the disease, with glucose concentrations rising to Ն30 mmol/l (6,10,11). Serum immunoreactive insulin initially increases, followed by a decrease approaching pre-diabetic levels around 4 weeks of HE diet (11). The end stage of diabetes is characterized by marked hypoinsulinemia (Fig. 1). ...
... The circulating immunoreactive insulin in hyperglycemic P. obesus contains a high proportion of insulin precursor molecules, similar to patients with type 2 dia-betes (12)(13)(14). Elevated cholesterol and triglyceride levels, with increased VLDL cholesterol and LDL cholesterol, were observed in hyperglycemic P. obesus, whereas circulating free fatty acid concentrations were usually below 400 mol/l (10,15). Animals at the hyperglycemic-hypoinsulinemic end stage of diabetes exhibited marked lipemia (triglycerides 10 -70 mmol/l). ...
... To study the role of the endocrine pancreas in dietinduced diabetes and its dependence on the genetic background of P. obesus, we combined in vivo and in vitro studies in which kinetic parameters of insulin secretion and stimulus-secretion coupling signals were analyzed (10,26,27). ...
Type 2 diabetes is characterized by insulin resistance and progressive beta-cell failure. Deficient insulin secretion, with increased proportions of insulin precursor molecules, is a common feature of type 2 diabetes; this could result from inappropriate beta-cell function and/or reduced beta-cell mass. Most studies using tissues from diabetic patients are retrospective, providing only limited information on the relative contribution of beta-cell dysfunction versus decreased beta-cell mass to the "beta-cell failure" of type 2 diabetes. The gerbil Psammomys obesus is a good model to address questions related to the role of insulin resistance and beta-cell failure in nutritionally induced diabetes. Upon a change from its natural low-calorie diet to the calorie-rich laboratory food, P. obesus develops moderate obesity associated with postprandial hyperglycemia. Continued dietary load, superimposed on its innate insulin resistance, results in depletion of pancreatic insulin stores, with increased proportions of insulin precursor molecules in the pancreas and the blood. Inadequate response of the preproinsulin gene to the increased insulin needs is an important cause of diabetes progression. Changes in beta-cell mass do not correlate with pancreatic insulin stores and are unlikely to play a role in disease initiation and progression. The major culprit is the inappropriate insulin production with depletion of insulin stores as a consequence. Similar mechanisms could operate during the evolution of type 2 diabetes in humans.
... By way of emphasis, impaired glucose metabolism, possibly implicating juvenile insulin resistance (IR) in childhood as well, initially appeared as a transient defect in weanling pups early during the first 4 weeks of a hiCHO diet challenge in Experiment 1, where females appeared slightly more impaired than males based on higher FBG, but not 30-min OGTT. This conclusion about transient IR derives from the observation that overnight food deprivation typically allowed an elevated RBG to reset to normal FBG (<60 mg/dl) by morning, i.e., the presumed IR, demonstrated previously linked to hyperinsulinemia and hyperleptinemia [12,60], appeared to dissipate if tissues in young Nile rats were allowed to experience a prolonged period of fasting, which is not unlike the diabetic prone Sand rat [72][73][74][75][76][77] and the recent emphasis on intermittent fasting as a prescribed method for arresting development of T2DM in humans [78]. ...
... By weaning pups onto test diets at 3 weeks of age, these experiments on diabetes induction were limited to a more reasonable 8 to 10 week trial, and even 4 weeks, as in Experiment 1, all during the major growth period in Nile rats when metabolic imprinting by dietary factors is most apt to occur. In this fashion, and assuming one has the correct balance between genetically permissive pups with 'resistant' and 'susceptible' traits as outcomes, one might reasonably delineate the dietary factors involved in diabetes induction in the naïve metabolic system of the Nile rat, a metabolic circumstance apparently shared with another North African desert rodent, the Sand rat [72][73][74][75][76][77]. By contrast, most human epidemiologic studies of T2DM have been conducted in adults [10,11,[36][37][38][39][40][41][42][43], which are arguably beyond the juvenile imprinting stage that favors induction and, thus, are less apt to detect the effects of dietary modulation on either MetS or diabetes. ...
Objective: The Nile rat (Arvicanthis niloticus) is a superior model for Type-II Diabetes Mellitus (T2DM) induced by diets with a high glycemic index (GI) and glycemic load (GLoad). To better define the age and gender attributes of diabetes in early stages of progression, weanling rats were fed a high carbohydrate (hiCHO) diet for between 2 to 10 weeks. Methods. Data from four experiments compared two diabetogenic semipurified diets (Diet 133 (60:20:20, as % energy from CHO, fat, protein with a high glycemic load (GLoad) of 224 per 2000 kcal) versus Diets 73MBS or 73MB (70:10:20 with or without sucrose and higher GLoads of 259 or 295, respectively). An epidemiological technique was used to stratify the diabetes into quintiles of blood glucose (Q1 to Q5), after 2-10 weeks of dietary induction in 654 rats. The related metagenetic physiological growth and metabolic outcomes were related to the degree of diabetes based on fasting blood glucose (FBG), random blood glucose (RBG), and oral glucose tolerance test (OGTT) at 30 minutes and 60 minutes. Results. Experiment 1 (Diet 73MBS) demonstrated that the diabetes begins aggressively in weanlings during the first 2 weeks of a hiCHO challenge, linking genetic permissiveness to diabetes susceptibility or resistance from an early age. In Experiment 2, ninety male Nile rats fed Diet 133 (60:20:20) for 10 weeks identified two quintiles of resistant rats (Q1,Q2) that lowered their RBG between 6 weeks and 10 weeks on diet, whereas Q3-Q5 became progressively more diabetic, suggesting an ongoing struggle for control over glucose metabolism, which either stabilized or not, depending on genetic permissiveness. Experiment 3 (32 males fed 70:10:20) and Experiment 4 (30 females fed 60:20:20) lasted 8 weeks and 3 weeks respectively, for gender and time comparisons. The most telling link between a quintile rank and diabetes risk was telegraphed by energy intake (kcal/day) that established the cumulative GLoad per rat for the entire trial, which was apparent from the first week of feeding. This genetic permissiveness associated with hyperphagia across quintiles was maintained throughout the study and was mirrored in body weight gain without appreciable differences in feed efficiency. This suggests that appetite and greater growth rate linked to a fiber-free high GLoad diet were the dominant factors driving the diabetes. Male rats fed the highest GLoad diet (Diet 73MB 70:10:20, GLoad 295 per 2000 kcal for 8 weeks in Experiment 3], ate more calories and developed diabetes even more aggressively, again emphasizing the Cumulative GLoad as a primary stressor for expressing the genetic permissiveness underlying the diabetes. Conclusion: Thus, the Nile rat model, unlike other rodents but similar to humans, represents a superior model for high GLoad, low-fiber diets that induce diabetes from an early age in a manner similar to the dietary paradigm underlying T2DM in humans, most likely originating in childhood.
... Hyperglycaemia in P. obesus is associated with marked depletion of islet insulin content and increased -cell apoptosis (Donath et al. 1999, Leibowitz et al. 2001a, Kaiser et al. 2003). Defective stimulus–secretion coupling and reduced glucose-stimulated insulin production underlie the failure of pancreatic islets to increase insulin secretion in response to innate and acquired insulin resistance , emphasizing the central role of the -cell in the pathogenesis of nutrition-dependent type 2 diabetes (Nesher et al. 1999, Leibowitz et al. 2001a). Therefore, P. obesus is an ideal model to study the effects of drugs that aim to improve -cell function and survival. ...
... Diabetes, defined by random non-fasted blood glucose levels of >8·3 mM (Accutrend Sensor; Roche Diagnostics, Mannheim, Germany), was induced by giving an HE diet (2·93 kcal/g; Weizmann Institute of Science, Rehovot, Israel). Using this dietary manipulation, 90% of the animals develop hyperglycaemia within 5 days (Nesher et al. 1999). Animals were housed one per cage under standard light conditions (12 h:12 h light/dark cycle) and had free access to food and water. ...
Glucagon-like peptide 1 (GLP-1) analogues are considered potential drugs for type 2 diabetes. We studied the effect of a novel GLP-1 analogue, S 23521 ([a8-des R36] GLP-1-[7-37]-NH2), on the metabolic state and beta-cell function, proliferation and survival in the Psammomys obesus model of diet-induced type 2 diabetes. Animals with marked hyperglycaemia after 6 days of high-energy diet were given twice-daily s.c. injection of 100 microg/kg S 23521 for 15 days. Food intake was significantly decreased in S 23251-treated P. obesus; however, there was no significant difference in body weight from controls. Progressive worsening of hyperglycaemia was noted in controls, as opposed to maintenance of pre-treatment glucose levels in the S 23521 group. Prevention of diabetes progression was associated with reduced mortality. In addition, the treated group had higher serum insulin, insulinogenic index and leptin, whereas plasma triglyceride and non-esterified fatty acid levels were decreased. S 23521 had pronounced effect on pancreatic insulin, which was 5-fold higher than the markedly depleted insulin reserve of control animals. Immunohistochemical analysis showed islet degranulation with disrupted morphology in untreated animals, whereas islets from S 23521-treated animals appeared intact and filled with insulin; beta-cell apoptosis was approximately 70% reduced, without a change in beta-cell proliferation. S 23521 treatment resulted in a 2-fold increase in relative beta-cell volume. Overall, S 23521 prevented the progression of diabetes in P. obesus with marked improvement of the metabolic profile, including increased pancreatic insulin reserve, beta-cell viability and mass. These effects are probably due to actions of S 23521 both directly on islets and via reduced food intake, and emphasize the feasibility of preventing blood glucose deterioration over time in type 2 diabetes.
... It is the only diurnal Gerbillidea living in the Sahara (Petter, 1961). P. obesus has attracted growing attention in the study of metabolic disorders (Nesher et al., 1999). It received widespread attention when it turned out to be an excellent experimental animal model for human non-insulin-dependent (type 2) diabetes mellitus. ...
The Fat Sand Rat (Psammomys obesus, P. obesus) is a diurnal herbivore and phytophage, with seasonal reproductive behavior. The sexually active phase lasts from autumn to early spring and the sexually inactive phase from late spring to summer. In the past years, P. obesus has gained much attention as an animal model in biological and clinical research. It is a suitable model for diet-induced insulin resistance, non-insulin-dependent diabetes mellitus and obesity studies. In addition, the seasonal reproduction of P. obesus is gaining more and more attention. The current paper aims to review and sum up the progress in the understanding of the reproductive anatomo-histo-physiology of Psammomys obesus, in order to facilitate future research in this area and to expose further perspectives for researchers.
... When fed with a high digestible energy diet (HE) in captivity, a proportion of the animals develop a metabolic syndrome that resembles human T2D. HE diet results in excess nutrient availability that enhances insulin secretion, reduction of the glucose-stimulated insulin secretion threshold (Pertusa et al., 2002) and rapid depletion of pancreatic insulin stores, correlating with the appearance of postprandial hyperglycemia (Nesher et al., 1999;Donath et al., 1999). Islets of newborn or adult P. obesus have no functional gene product of the homeodomain transcription factor Ipf1/Pdx1 (Leibowitz et al., 2001), required by β-cells for efficient expression of insulin, glucose transporter 2, and prohormone convertases 1/3 and 2. A recent study sequenced the P. obesus genome and identified an unusual, extensive, and mutationally biased GC-rich genomic domain encompassing several functionally essential genes, including Pdx1. ...
This presentation will survey the retinal architecture, advantages, and limitations of several lesser-known rodent species that provide a useful diurnal complement to rats and mice. These diurnal rodents also possess unusually cone-rich photoreceptor mosaics that facilitate the study of cone cells and pathways. Species to be presented include principally the Sudanian Unstriped Grass Rat and Nile Rat (Arvicanthis spp.), the Fat Sand Rat (Psammomys obesus), the degu (Octodon degus) and the 13-lined ground squirrel (Ictidomys tridecemlineatus). The retina and optic nerve in several of these species demonstrate unusual resilience in the face of neuronal injury, itself an interesting phenomenon with potential translational value.
... At variance with some other studies, in which the sand rats became diabetic after only 5 days exposure to a hypercaloric diet (16)(17)(18), the development of diabetes was more slow in the present study. Thus, as judged from either the difference between diabetic and non-diabetic sand rats at each time point or the changes recorded during the transition period in the diabetic animals, a significant increase of postprandial glycemia in the latter animals was only recorded 21 days after introduction of the hypercaloric diet, whilst still failing to achieve statistical significance 14 days after such an introduction. ...
... Selective breeding has been applied to develop several animal models for diabetes research [2,18,19]. The polygenic background of selectively bred animal models is most likely to mimic the human pathophysiological features of type 2 diabetes. ...
Hereditary predisposition to diet-induced type 2 diabetes has not yet been fully elucidated. We recently established 2 mouse lines with different susceptibilities (resistant and prone) to high-fat diet (HFD)-induced glucose intolerance by selective breeding (designated selectively bred diet-induced glucose intolerance-resistant [SDG-R] and -prone [SDG-P], respectively). To investigate the predisposition to HFD-induced glucose intolerance in pancreatic islets, we examined the islet morphological features and functions in these novel mouse lines. Male SDG-P and SDG-R mice were fed a HFD for 5 weeks. Before and after HFD feeding, glucose tolerance was evaluated by oral glucose tolerance test (OGTT). Morphometry and functional analyses of the pancreatic islets were also performed before and after the feeding period. Before HFD feeding, SDG-P mice showed modestly higher postchallenge blood glucose levels and lower insulin increments in OGTT than SDG-R mice. Although SDG-P mice showed greater β cell proliferation than SDG-R mice under HFD feeding, SDG-P mice developed overt glucose intolerance, whereas SDG-R mice maintained normal glucose tolerance. Regardless of whether it was before or after HFD feeding, the isolated islets from SDG-P mice showed impaired glucose- and KCl-stimulated insulin secretion relative to those from SDG-R mice; accordingly, the expression levels of the insulin secretion-related genes in SDG-P islets were significantly lower than those in SDG-R islets. These findings suggest that the innate predispositions in pancreatic islets may determine the susceptibility to diet-induced diabetes. SDG-R and SDG-P mice may therefore be useful polygenic animal models to study the gene-environment interactions in the development of type 2 diabetes.
... 18 Esta enfermedad es frecuentemente una consecuencia de la mala nutrición por exceso que provoca el sobrepeso, el cual entonces potencia la resistencia a la insulina. La hiperglicemia resultante induce una permanente estimulación exacerbada de la maquinaria secretora de las células β, lo cual termina en una hiperinsulinemia y/o hipoinsulinemia por agotamiento 19 Recientemente se ha descrito un receptor denominado "receptor AT1", el cual media muchos efectos biológicos del sistema renina-angiotensina como la vasoconstricción y la proliferación celular. La insulina, que se encuentra elevada en el síndrome X (hiperinsulinemia), induce un alto nivel de expresión de los receptores AT1, lo cual potencia la eficiencia biológica de la angiotensina II. ...
... Gene–gene and gene –environment interactions may further help illustrate the biological basis for complex diseases and provide important clues for personalized interventions or clinical therapeutics (Collins et al., 2003). These interactions contribute to b-cell function (Nesher et al., 1999; Li et al., 2009), insulin sensitivity (Black et al., 2008) and T2DM risk (Cornelis and Hu, 2012 ). Further, a number of environmental factors, such as diet and lifestyle factors, have been significantly associated with GDM risk (Zhang and Ning, 2011). ...
BACKGROUND
Several studies have examined associations between genetic variants and the risk of gestational diabetes mellitus (GDM). However, inferences from these studies were often hindered by limited statistical power and conflicting results. We aimed to systematically review and quantitatively summarize the association of commonly studied single nucleotide polymorphisms (SNPs) with GDM risk and to identify important gaps that remain for consideration in future studies.METHODS
Genetic association studies of GDM published through 1 October 2012 were searched using the HuGE Navigator and PubMed databases. A SNP was included if the SNP-GDM associations were assessed in three or more independent studies. Two reviewers independently evaluated the eligibility for inclusion and extracted the data. The allele-specific odds ratios (ORs) and 95% confidence intervals (CIs) were pooled using random effects models accounting for heterogeneity.RESULTSOverall, 29 eligible articles capturing associations of 12 SNPs from 10 genes were included for the systematic review. The minor alleles of rs7903146 (TCF7L2), rs12255372 (TCF7L2), rs1799884 (-30G/A, GCK), rs5219 (E23K, KCNJ11), rs7754840 (CDKAL1), rs4402960 (IGF2BP2), rs10830963 (MTNR1B), rs1387153 (MTNR1B) and rs1801278 (Gly972Arg, IRS1) were significantly associated with a higher risk of GDM. Among them, genetic variants in TCF7L2 showed the strongest association with GDM risk, with ORs (95% CIs) of 1.44 (1.29-1.60, P < 0.001) per T allele of rs7903146 and 1.46 (1.15-1.84, P = 0.002) per T allele of rs12255372.CONCLUSIONS
In this systematic review, we found significant associations of GDM risk with nine SNPs in seven genes, most of which have been related to the regulation of insulin secretion.
... Upregulation of these genes diverts glucose from its classical metabolism pathway, leading to the alteration of GSIS as evidenced in models of overexpression/deletion of some of these genes (Ainscow et al., 2000;Becker et al., 1994;Chan et al., 2001;Ishihara et al., 1994;Trinh et al., 1997;Zhang et al., 2001). Particularly, upregulation of Hks, and likely other glycolytic genes, could explain the reduced glucose threshold for basal insulin secretion in Psammomys obesus, Px rats, and cultured rat islets Hosokawa et al., 1995;Khaldi et al., 2004;Nesher et al., 1999). On the other hand, upregulation of Ldha and Mcts may hamper GSIS by diverting the flux of carbon from oxidative phosphorylation and ATP generation toward lactate production and transport, and may represent a sign of b-cell hypoxia Bensellam et al., 2012;Jonas et al., 2009). ...
It is well established that regular physiological stimulation by glucose plays a crucial role in the maintenance of the β-cell differentiated phenotype. In contrast, prolonged or repeated exposure to elevated glucose concentrations both in vitro and in vivo exerts deleterious or toxic effects on the β-cell phenotype, a concept termed as glucotoxicity. Evidence indicates that the latter may greatly contribute to the pathogenesis of type 2 diabetes. Through the activation of several mechanisms and signaling pathways, high glucose levels exert deleterious effects on β-cell function and survival and thereby, lead to the worsening of the disease over time. While the role of high glucose-induced β-cell overstimulation, oxidative stress, excessive Unfolded Protein Response (UPR) activation, and loss of differentiation in the alteration of the β-cell phenotype is well ascertained, at least in vitro and in animal models of type 2 diabetes, the role of other mechanisms such as inflammation, O-GlcNacylation, PKC activation, and amyloidogenesis requires further confirmation. On the other hand, protein glycation is an emerging mechanism that may play an important role in the glucotoxic deterioration of the β-cell phenotype. Finally, our recent evidence suggests that hypoxia may also be a new mechanism of β-cell glucotoxicity. Deciphering these molecular mechanisms of β-cell glucotoxicity is a mandatory first step toward the development of therapeutic strategies to protect β-cells and improve the functional β-cell mass in type 2 diabetes.
... In this context, we found that the mRNA expression of the prolactin (PRLR), growth hormone (GHR), cholecystokinine A (CCKAR), and glucose-dependent insulinotropic polypeptide (GIPR) receptors are all increased by glucose stimulation in rodent beta cells, suggesting that appropriate glucose recognition has important effects on the beta cells' growth factor responsiveness by regulating their receptors ( Fig. 17.2). The ability of the beta cell mass to expand in response to glucose stimulation, is also determined by genetic background (Nesher et al., 1999;Swenne and Andersson, 1984) and this correlates with the susceptibility of the beta cell to high glucose-induced deregulation (Leibowitz et al., 2001;Svensson et al., 1993). Similarly, in humans, the genetic background, such as variants in the TCF7L2 regulatory sequence, could affect the adaptive increase in functional beta cell mass in conditions of increased metabolic needs such as in pregnancy or obesity (Lingohr et al., 2002;Sladek et al., 2007). ...
The key role of glucose in regulating insulin release by the pancreatic beta cell population is not only dependent on acute stimulus‐secretion coupling mechanisms but also on more long‐term influences on beta cell survival and phenotype. Glucose serves as a major survival factor for beta cells via at least three actions: it prevents an oxidative redox state, it suppresses a mitochondrial apoptotic program that is triggered at reduced mitochondrial metabolic activity and it induces genes needed for the cellular responsiveness to glucose and to growth factors. Glucose‐regulated pathways may link protein synthetic and proliferative activities, making glucose a permissive factor for beta cell proliferation, in check with metabolic needs. Conditions of inadequate glucose metabolism in beta cells are not only leading to deregulation of acute secretory responses but should also be considered as causes for increased apoptosis and reduced formation of beta cells, and loss of their normal differentiated state.
... Nevertheless, P. obesus -cells stained positive for insulin, somatostatin, glucagon, GLUT2, and the transcription factors ISL-1, Nkx2.2, and Nkx6.1 (Fig. 3 and other data not shown). Moreover, P. obesus islets exhibited glucose-responsive insulin secretion, albeit with altered glucose sensitivity (24), and glucokinase activity was also present in P. obesus islets, with HE diet further increasing the glucose phosphorylation activity of the islets (24). As further confirmation, IPF1/PDX1 could not be de-tected by Western blot analysis of nuclear and whole-islet cell extracts obtained from diabetic or normoglycemic P. obesus, whereas the expected 45-kDa protein was detected in rat islets and various -cell lines (Fig. 4A). ...
The homeodomain transcription factor IPF1/PDX1 is required in beta-cells for efficient expression of insulin, glucose transporter 2, and prohormone convertases 1/3 and 2. Psammomys obesus, a model of diet-responsive type 2 diabetes, shows markedly depleted insulin stores when given a high-energy (HE) diet. Despite hyperglycemia, insulin mRNA levels initially remained unchanged and then decreased gradually to 15% of the basal level by 3 weeks. Moreover, insulin gene expression was not increased when isolated P. obesus islets were exposed to elevated glucose concentrations. Consistent with these observations, no functional Ipf1/Pdx1 gene product was detected in islets of newborn or adult P. obesus using immunostaining, Western blot, DNA binding, and reverse transcriptase-polymerase chain reaction analyses. Other beta-cell transcription factors (e.g., ISL-1, Nkx2.2, and Nkx6.1) were expressed in P. obesus islets, and the DNA binding activity of the insulin transcription factors RIPE3b1-Act and IEF1 was intact. Ipf1/Pdx1 gene transfer to isolated P. obesus islets normalized the defect in glucose-stimulated insulin gene expression and prevented the rapid depletion of insulin content after exposure to high glucose. Taken together, these results suggest that the inability of P. obesus islets to adapt to dietary overload, with depletion of insulin content as a consequence, results from IPF1/PDX1 deficiency. However, because not all animals become hyperglycemic on HE diet, additional factors may be important for the development of diabetes in this animal model.
... Interestingly, body weight changes were not significantly different among the groups. Similar results regarding only the CH and CL groups were found in another study (21), suggesting that the energy balance of all 3 groups was similar. It should also be noted that the EH group might gain weight by increasing their muscle mass due to the daily exercise training. ...
We hypothesized that exercise training might prevent diabetes mellitus in Psammomys obesus. Animals were assigned to three groups: high-energy diet (CH), high-energy diet and exercise (EH), and low-energy diet (CL). The EH group ran on a treadmill 5 days/wk, twice a day. After 4 wk, 93% of the CH group were diabetic compared with only 20% of the EH group. There was no difference in weight gain among the groups. Both EH and CH groups were hyperinsulinemic. Epididymal fat (% of body weight) was higher in the CH group than in either the EH and or the CL group. Protein kinase C (PKC)-delta activity and serine phosphorylation were higher in the EH group. No differences were found in tyrosine phosphorylation of the insulin receptor, insulin receptor substrate-1, and phosphatidylinositol 3-kinase among the groups. We demonstrate for the first time that exercise training effectively prevents the progression of diabetes mellitus type 2 in Psammomys obesus. PKC-delta may be involved in the adaptive effects of exercise in skeletal muscles that lead to the prevention of type 2 diabetes mellitus.
... Increased hepatic gluconeogenesis is characterized by a high activity of phosphoenolpyruvate (PEP) carboxykinase and glucose 6-phosphatase [10], while hepatic pyruvate dehydrogenase activity is decreased [4]. Psammomys NIDDM is believed to be primitively related to a native state of insulin resistance responsible for a decreased glucose metabolism in skeletal muscle [10,11], but several other abnormalities are involved including genetic specificity, pancreatic apoptosis and leptin abnormality [12][13][14][15][16][17][18]. Interestingly, pure type-2 diabetes, i.e. without reduced insulin production, is fully reversed by food restriction [12]. ...
In this study we have compared glucose metabolism and liver gluconeogenesis in wild adult desert gerbil Psammomys obesus fed with their natural halophilic plants and Wistar rats fed on a laboratory chow. Psammomys obesus is a natural model of insulin resistance when fed a rodent laboratory chow.
Basal glucose and insulin were determined in plasma of fasting animals. Hepatocyte gluconeogenesis from lactate-plus-pyruvate was investigated in perifused hepatocytes by assessing simultaneously glucose synthesis rate and intracellular oxaloacetate, phosphoenolpyruvate, 3-phosphoglycerate, fructose 6-phosphate and glucose 6-phosphate (G6P) under true steady state conditions.
Fasting blood glucose (2.8 +/- 0.1 vs 4.8 +/- 0.4 mmol.L(- 1)) and plasma insulin concentration (129 +/- 14 vs 150 +/- 21 pmol.L(-1)) were significantly lower in Psammomys as compared to albino rats. Maximal gluconeogenic rate was also lower in Psammomys (2.3 +/- 0.3 vs 5.1 +/- 0.3 micromol x min(-1) x g dry cells(-1)). This effect was related to a slower hydrolysis of G6P.
A lower G6P hydrolysis in Psammomys as compared to wistar was the main difference between the two groups of liver cells. Such feature may represent the major metabolic adaptation permitting Psammomys to survive despite its severe restrictive natural conditions. Indeed, a low G6P hydrolysis allows an insulin resistance state, with a high lipogenic activity, but associated with low blood glucose. The rise in blood glucose occurring when Psammomys are fed with exogenous carbohydrates perturbs such delicate metabolic equilibrium, resulting thus in a diabetic state because of the deleterious effect of hyperglycemia.
... In contrast to the GK rat, and in spite of the fact that its obesity is mild, this gerbil (nicknamed sand rat) is severely insulin resistant. When presented with a calorie-rich diet, it develops hyperglycaemia within 4–5 days (Nesher et al., 1999), reaching blood glucose levels around 15 mM, which may progress to severe ketotic diabetes after a few weeks (Shafrir & Ziv, 1998). Islet insulin content is rapidly depleted with the onset of hyperglycaemia (Donath et al., 1999). ...
S 21403 (mitiglinide) is a new drug for type 2 diabetes mellitus (T2DM). Its action on insulin release and biosynthesis was investigated in several experimental systems utilizing pancreas from normal and T2DM animals.
At high concentrations (10 μM), S 21403, like classical sulphonylurea, induced insulin release in the absence of glucose. In contrast, at therapeutic (0.1–1.0 μM) concentrations, S 21403 amplified insulin secretion glucose dose-dependently and with similar magnitude in normal and diabetic GK rat islets.
In perfused GK rat pancreas, S 21403 induced normal kinetics of insulin secretion including first-phase response.
The effect of S 21403 was strongly modulated by physiological factors. Thus, 0.1 μM adrenaline inhibited S 21403-induced insulin release. There was marked synergism between S 21403 and arginine in GK rat islets, combination of the two normalizing insulin secretion.
In primary islet cultures from normal rats or prediabetic Psammomys obesus, prolonged exposure to S 21403 did not induce further depletion of insulin stores under normal or ‘glucotoxic’ conditions.
Proinsulin biosynthesis was not affected by 2-h exposure of rat or prediabetic P. obesus islets to 1 μM S 21403. Yet, 24-h exposure of rat islets to S 21403 resulted in 30% increase in proinsulin biosynthesis at 8.3 mM glucose.
Amplification by S 21403 of glucose-induced insulin secretion in diabetic GK β-cells with restoration of first-phase response, a strong synergistic interaction with arginine and marked inhibition by adrenaline, make it a prime candidate for successful oral antidiabetic agent.
British Journal of Pharmacology (2005) 146, 872–881. doi:10.1038/sj.bjp.0706374
... Ultrastructurally, different signs of necrotic destruction of pancreatic -cells (e.g., the pyknosis of nuclei and a massive vacuolization in the cytoplasm) were observed to be accompanied by swollen mitochondria and dilated cisternae of the Golgi complex and of the rough endoplasmic reticulum. When the pancreas was removed from animals at stage D, -cells exhibited apoptosis and nuclear DNA fragmentation Nesher et al. 1999;Shafrir et al. 1991). ...
The dietary effects of hyperglycemia increasingly result in type 2 diabetes in humans. Two species, the spiny mice (Acomys cahirinus) and the desert gerbil (Psammomys obesus), which have different metabolic responses to such effects, are discussed. Spiny mice exemplify a pathway that leads to diabetes without marked insulin resistance due to low supply of insulin on abundant nutrition, possibly characteristic of a desert animal. They respond with obesity and glucose intolerance, beta-cell hyperplasia, and hypertrophy on a standard rodent diet supplemented with fat-rich seeds. The accompanying hyperglycemia and hyperinsulinemia are mild and intermittent but after a few months, the enlarged pancreatic islets suddenly collapse, resulting in loss of insulin and ketosis. Glucose and other secretagogues produce only limited insulin release in vivo and in vitro, pointing to the inherent disability of the beta-cells to respond with proper insulin secretion despite their ample insulin content. On a 50% sucrose diet there is marked lipogenesis with hyperlipidemia without obesity or diabetes, although beta-cell hypertrophy is evident. P.obesus is characterized by muscle insulin resistance and the inability of insulin to activate the insulin signaling on a high-energy (HE) diet. Insulin resistance imposes a vicious cycle of Hyperglycemia and compensatory hyperinsulinemia, leading to beta-cell failure and increased secretion of proinsulin. Ultrastructural studies reveal gradual disappearance of beta-cell glucokinase, GLUT 2 transporter, and insulin, followed by apoptosis of beta-cells. Studies using the non-insulin-resistant HE diet-fed animals maintained as a control group are discussed. The insulin resistance that is evident to date in the normoglycemic state on a low-energy diet indicates sparing of glucose fuel in muscles of a desert-adapted animal for the benefit of glucose obligatory tissues. Also discussed are the effect of Psammomys age on the disabetogenicity of the HE diet; the impaired function of several components of the insulin signal transduction pathway in muscles, which reduces the availability of GLUT4 transporter; the testing of several antidiabetic modalities for the prevention of nutritional diabetes in Psammomys; and various complications related to the diabetic condition.
Purpose: To compare the retinal function of a diurnal murid rodent, Psammomys obesus, with that of Wistar albino rat and human subjects.
Materials and methods: Adult Psammomys obesus were captured and transferred to the animal facilities where they were maintained at 25°C with standard light/dark cycles and natural halophilic plants, rich in water and mineral salts. Standard full-field photopic and scotopic electroretinograms were obtained.
Results: The right eye of all animals displayed well detectable and reproducible scotopic and photopic electroretinogram (ERG) responses. Results were compared with those obtained from human subjects and Wistar rats. ERG measurement showed that the amplitudes of scotopic responses in Psammomys obesus are quite similar to those of human subjects. The amplitude of the photopic a-wave was comparable to that of humans and six times higher than that of the albino rat. The amplitudes of photopic b-wave, photopic oscillatory potentials (OPs), and 30 Hz flicker were all markedly larger in Psammomys obesus compared to those obtained from human subjects and Wistar rats. Furthermore, like the human photopic ERG, the photopic ERG of Psammomys obesus also includes prominent post b-wave components (i.e. i- and d-waves) while the ERG of Wistar rats does not.
Conclusions: Our results suggest that the retinal function of Psammomys obesus, especially the cone-mediated function, shares several features with that of human subjects. We believe that Psammomys obesus represents an interesting alternative to study the structure and function of the normal and diseased retina in a human-like rodent model of retinal function.
Type 2 diabetes mellitus features an asymptomatic insulin resistance phase preceding the onset of diabetes. Hyperglycemia occurs when a relative insulin deficiency appears, meaning that beta cell secretory dysfunction is a key element in type 2 diabetes pathophysiology. So far, insulin secretion deficiency is explained by pancreatic beta cell "exhaustion" phenomena, Recent data suggest that apoptotic mechanisms could explain insulin deficiency through a reduction in the absolute pancreatic beta cell number. Psammamys obesus(sand rat) is an animal model for type 2 diabetes mellitus, initially characterized by hyperinsulinism followed by insulin deficiency linked with a reduction in the number of pancreatic beta cells. Transition to diabetes can be observed following changes in usual lifestyle of the sand rat In the desert caloric intake is low and physical expenditure is heavy. In the laboratory, animals turn diabetic as early as 4 days following a high calory diet. At a later stage, diabetes is irreversible and animals die from diabetic ketoacidosis. beta cell apoptosis rate is low in non diabetic animals and increases 14-fold by 20 days after diabetes onset. At this stage, cells undergoing apoptosis can be observed, coexisting with necrotic cells without any insulitis. Similar results were obtained in vitro in isolated pancreatic islets that were exposed to increasing glucose concentrations, suggesting that chronic hyperglycemia plays a role in the onset or the deterioration of the process. However, precise mechanisms of apoptosis in this case remain poorly understood. Aminoguanidin does not prevent beta cell apoptosis in vitro, suggesting that advanced glycation products or NO production are not involved in this beta cell destruction process. Similar mechanisms secondary to hyperglycemia could play a role in the diabetes process in man and explain the marked insulin secretory deficiency that is sometimes observed in these patients. In addition to its preventing role on diabetes complication, the obtention of normoglycemia could help maintaining beta cell function.
Wild and black rats maintained for biomedical research purposes have an extremely diverse and interesting background. The uses of wild rats in biomedical research range the spectrum of human disease syndromes, including oncology, virology, parasitology, and metabolic diseases (obesity and diabetes). There are also several specific rat models that are important in the understanding of the basic biology and mechanisms of disease. For example, the sand rat has been used extensively to study non-insulin-dependent diabetes mellitus and obesity. Psammomys obesus has been used in the study of diabetes, covering the gamut of leptin receptor effects, exercise, beta cells, and diabetic complications (vascular, renal, and ocular). Another important animal model has been the cotton rat, which has become one of the most commonly used species to study the pathogenesis of human respiratory viruses. There is also a major focus in wild and black rats to study how their close proximity to the daily lives of mankind impacts the transmission of zoonotic diseases such as hantavirus, viral hemorrhagic fevers, and bacterial infections. Handling these animals in a safe manner for both the handler and the animal is critical to working with captive wild rodents. These are animals that have not been selectively bred to be docile and often present a unique challenge when it comes time for experimental manipulation or even simple cage changes.
Pregnancy and obesity are frequently associated with diminished insulin sensitivity, which is normally compensated for by an expansion of the functional β cell mass that prevents chronic hyperglycemia and development of diabetes mellitus. The molecular basis underlying compensatory β cell mass expansion is largely unknown. We found in rodents that β cell mass expansion during pregnancy and obesity is associated with changes in the expression of several islet microRNAs, including miR-338-3p. In isolated pancreatic islets, we recapitulated the decreased miR-338-3p level observed in gestation and obesity by activating the G protein-coupled estrogen receptor GPR30 and the glucagon-like peptide 1 (GLP1) receptor. Blockade of miR-338-3p in β cells using specific anti-miR molecules mimicked gene expression changes occurring during β cell mass expansion and resulted in increased proliferation and improved survival both in vitro and in vivo. These findings point to a major role for miR-338-3p in compensatory β cell mass expansion occurring under different insulin resistance states.
Hyperglycemia is widely recognized to be a potent stimulator of monocyte activity, which is a crucial event in the pathogenesis of atherosclerosis. We analyzed the monocyte proteome for potential markers that would enhance the ability to screen for early inflammatory status in Type 2 diabetes mellitus (T2DM), using proteomic technologies. Monocytic cells (THP-1) were primed with high glucose (HG), their protein profiles were analyzed using 2DE and the downregulated differentially expressed spots were identified using MALDI TOF/MS. We selected five proteins that were secretory in function with the help of bioinformatic programs. A predominantly downregulated protein identified as cyclophilin A (sequence coverage 98%) was further validated by immunoblotting experiments. The cellular mRNA levels of cyclophilin A in various HG-primed cells were studied using qRT-PCR assays and it was observed to decrease in a dose-dependent manner. LC-ESI-MS was used to identify this protein in the conditioned media of HG-primed cells and confirmed by Western blotting as well as ELISA. Cyclophilin A was also detected in the plasma of patients with diabetes. We conclude that cyclophilin A is secreted by monocytes in response to HG. Given the paracrine and autocrine actions of cyclophilin A, the secreted immunophilin could be significant for progression of atherosclerosis in type 2 diabetes. Our study also provides evidence that analysis of monocyte secretome is a viable strategy for identifying candidate plasma markers in diabetes.
Insulin deficiency is the underlying cause of hyperglycemia in type 2 diabetes. The gerbil Psammomys obesus (P. obesus) is a naturally insulin resistant rodent with tendency to develop diet-induced hyperglycemia associated with obesity. P. obesus does not exhibit hyperglycemia in its natural desert habitat, feeding on low caloric vegetation. However, when fed regular laboratory chow containing higher caloric density, the animals develop moderate obesity and hyperglycemia. Diabetes development and progression is very fast in P. obesus. The animals reach the irreversible hypoinsulinemic stage of the disease, in which a marked reduction of β-cell mass is apparent, within 4-6 weeks of high caloric diet. The present review describes the P. obesus of the Hebrew University colony, with emphasis on its use for the study of β-cell dysfunction in type 2 diabetes.
The pathophysiology of vascular disease in diabetes involves abnormalities in endothelial cells, vascular smooth muscle cells, and monocytes. The metabolic abnormalities that characterize diabetes, such as hyperglycemia, increased free fatty acids, and insulin resistance, each provoke molecular mechanisms that contribute to vascular dysfunction. Several molecules have been identified as risk markers, and have been studied to prevent progression of disease and long-term complications. Markers such as C-reactive protein and monocyte chemoattractant protein-1 are used to assess risk for adverse cardiac events, but elevated levels are possible due to the presence of other risk factors as part of the natural physiological defense mechanism. In this review we discuss potential of cyclophilin-A, a secreted oxidative-stress-induced immunophilin with diverse functions. We present evidence for a significant role of cyclophilin-A in the pathogenesis of atherosclerosis in diabetes, and its potential as a marker for vascular disease in type-2 diabetes.
Glucose-induced insulin secretion from pancreatic β-cells involves metabolism-induced membrane depolarization and voltage-dependent Ca2+ influx. The electrical events in β-cell glucose sensing have been studied intensely using mouse islets of Langerhans, but data from other species, including models of type 2 diabetes mellitus (T2DM), are lacking. In this work, we made intracellular recordings of electrical activity from cells within islets of the gerbil Psammomys obesus (fat sand rat), a model of dietary-induced T2DM. Most islet cells from lean, non-diabetic sand rats displayed glucose-induced, KATP channel-dependent, oscillatory electrical activity that was similar to the classic “bursting” pattern of mouse β-cells. However, the oscillations were slower in sand rat islets, and the dose–response curve of electrical activity versus glucose concentration was left-shifted. Of the non-bursting cells, some produced action potentials continuously, while others displayed electrical activity that was largely independent of glucose. The latter activity consisted of continuous or intermittent action potential firing, and persisted for long periods in the absence of glucose. The glucose-insensitive activity was suppressed by diazoxide, indicating that the cells expressed KATP channels. Sand rat islets produced intracellular Ca2+ oscillations reminiscent of the oscillatory electrical pattern observed in most cells, albeit with a longer period. Finally, we found that the glucose dependence of insulin secretion from sand rat islets closely paralleled that of the bursting electrical activity. We conclude that while subpopulations of KATP-expressing cells in sand rat islets display heterogeneous electrical responses to glucose, insulin secretion most closely follows the oscillatory activity. The ease of recording membrane potential from sand rat islets makes this a useful model for studies of β-cell electrical signaling during the development of T2DM.
Diabetic retinopathy (DR) is a leading cause of blindness, yet pertinent animal models are uncommon. The sand rat (Psammomys obesus), exhibiting diet-induced metabolic syndrome, might constitute a relevant model.
Adult P. obesus (n = 39) were maintained in captivity for 4 to 7 months and fed either vegetation-based diets (n = 13) or standard rat chow (n = 26). Although plant-fed animals exhibited uniform body weight and blood glucose levels over time, nearly 60% of rat chow-raised animals developed diabetes-like symptoms (test group). Animals were killed, and their eyes and vitreous were processed for immunochemistry.
Compared with plant-fed animals, diabetic animals showed many abnormal vascular features, including vasodilation, tortuosity, and pericyte loss within the blood vessels, hyperproteinemia and elevated ratios of proangiogenic and antiangiogenic growth factors in the vitreous, and blood-retinal barrier breakdown. Furthermore, there were statistically significant decreases in retinal cell layer thicknesses and densities, accompanied by profound alterations in glia (downregulation of glutamine synthetase, glutamate-aspartate transporter, upregulation of glial fibrillar acidic protein) and many neurons (reduced expression of protein kinase Cα and Cξ in bipolar cells, axonal degeneration in ganglion cells). Cone photoreceptors were particularly affected, with reduced expression of short- and mid-/long-wavelength opsins. Hypercaloric diet nondiabetic animals showed intermediate values.
Simple dietary modulation of P. obesus induces a rapid and severe phenotype closely resembling human type 2 DR. This species presents a valuable novel experimental model for probing the neural (especially cone photoreceptor) pathogenic modifications that are difficult to study in humans and for screening therapeutic strategies.
Cone photoreceptor-based central vision is of paramount importance in human eyesight, and the increasing numbers of persons affected by macular degeneration emphasizes the need for relevant and amenable animal models. Although laboratory mice and rats have provided valuable information on retinal diseases, they have inherent limitations for studies on macular pathology. In the present study, we extend our recent analyses of diurnal murid rodents to demonstrate that the sand rat Psammomys obesus has a remarkably cone-rich retina, and represents a useful adjunct to available animal models of central vision.
Adult P. obesus were captured and transferred to animal facilities where they were maintained under standard light/dark cycles. Animals were euthanised and their eyes enucleated. Tissue was either fixed in paraformaldehyde and prepared for immunohistochemistry, or solubilized in lysis buffer and separated by SDS-PAGE and subjected to western blot analysis. Samples were labelled with a battery of antibodies against rod and cone photoreceptors, inner retinal neurones, and glia.
P. obesus showed a high percentage of cones, 41% of total photoreceptor numbers in both central and peripheral retina. They expressed multiple cone-specific proteins, including short and medium-wavelength opsin and cone transducin. A second remarkable feature of the retina concerned the horizontal cells, which expressed high levels of glial fibrillar acidic protein and occludin, two proteins which are not seen in other species.
The retina of P. obesus displays high numbers of morphologically and immunologically identifiable cones which will facilitate analysis of cone pathophysiology in this species. The unusual horizontal cell phenotype may be related to the cone distribution or to an alternative facet of the animals lifestyle.
This study deals with the effects of daily intermittent fasting for 15 h upon the development of diabetes in sand rats exposed to a hypercaloric diet. The same pattern of daily intermittent fasting was imposed on sand rats maintained on a purely vegetal diet (control animals). Over the last 30 days of the present experiments, non-fasting animals gained weight, whilst intermittently fasting sand rats lost weight. In this respect, there was no significant difference between control animals and either diabetic or non-diabetic sand rats exposed to the hypercaloric diet. The postprandial glycemia remained fairly stable in the control animals. During a 3-week transition period from a purely vegetal to a hypercaloric diet, the post-prandial glycemia increased by 5.95 ± 1.26 mM (n=6) in diabetic sand rats, as distinct from an increase of only 0.45 ± 0.56 mM (n=6) in the non-diabetic animals. During the intermittent fasting period, the postprandial glycemia decreased significantly in the diabetic animals, but not so in the non-diabetic sand rats. Before the switch in food intake, the peak glycemia at the 30th min of an intraperitoneal glucose tolerance test was already higher in the diabetic than non-diabetic rats. In both the non-diabetic and diabetic sand rats, intermittent fasting prevented the progressive deterioration of glucose tolerance otherwise observed in non-fasting animals. These findings reveal that, at least in sand rats, intermittent daily fasting prevents the progressive deterioration of glucose tolerance otherwise taking place when these animals are exposed to a hypercaloric diet.
We characterised the development of Type 2 diabetes and associated changes in islet appearance in female ZDF rats and explored its suitability for studies with novel therapeutic agents.
Female ZDF rats were either chow or high fat (60%) fed for up to 36 days and blood glucose and plasma insulin concentration measured. Additionally, we restored two groups of rats back to chow diet after ten and nineteen days of high fat feeding to determine the reversibility. Finally, two other groups of high fat-fed animals were dosed either orally with drug vehicle or had a minipump implanted subcutaneously to determine the effect of dosing method upon the progression of this disease model. The beta cell mass and morphology were assessed by immunohistochemistry for insulin.
High fat feeding elevated blood glucose compared to chow-fed controls which peaked by 15 days, and maintained throughout the study. Plasma insulin reached a maximum after 8 days, but declined over the remaining 4 weeks. Assessment of islets revealed marked disruption, dispersion and weaker insulin staining. The area and percentage β-cells were higher in high fat-fed animals. High fat diet treatment reversal when animals were moderately hyperglycaemic, when plasma insulin was still elevated, reversed the hyperglycaemia and maintained islet morphology similar to that of chow-fed animals. In contrast, dietary reversal when plasma insulin was declining, did not prevent continual decline in plasma insulin, β-cell mass or islet disruption. Oral dosing tended to increase blood glucose and decrease plasma insulin whereas administration by minipump lowered blood glucose.
The obese female ZDF rat offers the opportunity for preclinical evaluation of novel therapies directed towards improving pancreatic function, provided treatment is initiated prior to the precipitous decline in insulin production. Caution should be exercised in comparison of compounds administered by different dosing routes however.
The pancreatic beta-cell adapts to increased nutrient availability and insulin resistance by increasing its function and mass. These processes are orchestrated by signals derived from nutrient metabolism, hormones and cytokines. Their end-result is the regulation of insulin secretion and biosynthesis, and beta-cell proliferation and apoptosis. This review focuses on the mechanisms involved in beta-cell nutrient sensing and adaptation and the potential causes of beta-cell dysfunction and death in type 2 diabetes mellitus. Understanding the mechanisms that regulate adequate beta-cell adaptation and the natural history of beta-cell failure is of utmost importance for the development of novel disease modifying treatments.
In type 2 diabetes, glucose toxicity leads to beta cell apoptosis with decreased beta cell mass as a consequence. Thioredoxin-interacting protein (TXNIP) is a critical mediator of glucose-induced beta cell apoptosis. Since hyperglycaemia leads to elevated serum insulin, we hypothesised that insulin is involved in the regulation of TXNIP protein levels in beta cells.
We studied the production of TXNIP in INS-1E beta cells and in islets of Psammomys obesus, an animal model of type 2 diabetes, in response to glucose and different modulators of insulin secretion.
TXNIP production was markedly augmented in islets from diabetic P. obesus and in beta cells exposed to high glucose concentration. In contrast, adding insulin to the culture medium or stimulating insulin secretion with different secretagogues suppressed TXNIP. Inhibition of glucose and fatty acid-stimulated insulin secretion with diazoxide increased TXNIP production in beta cells. Nitric oxide (NO), a repressor of TXNIP, enhanced insulin signal transduction, whereas inhibition of NO synthase abolished its activation, suggesting that TXNIP inhibition by NO is mediated by stimulation of insulin signalling. Treatment of beta cells chronically exposed to high glucose with insulin reduced beta cell apoptosis. Txnip knockdown mimicking the effect of insulin prevented glucose-induced beta cell apoptosis.
Insulin is a potent repressor of TXNIP, operating a negative feedback loop that restrains the stimulation of TXNIP by chronic hyperglycaemia. Repression of TXNIP by insulin is probably an important compensatory mechanism protecting beta cells from oxidative damage and apoptosis in type 2 diabetes.
Summary 1. A patient with insulin resistant diabetes mellitus has been described in detail with emphasis upon the time relationship between prior insulin therapy for mental illness and the subsequent development of overt diabetes. 2. The localization of the insulin antibodies in the g-globulins with some extension into the region of a has been delineated. 3. The possible relationship between the immunologic responsiveness of the patient and the eventual manifestation of the disease is discussed.
Sympatholytic dopamine agonist treatment utilizing bromocriptine and SKF38393 (BC/SKF) significantly lowers basal plasma insulin levels and normalizes basal and glucose-induced insulin secretion of the pancreatic beta cell in ob/ob mice. While BC/SKF has no significant effect on pancreatic islet cells directly, drug action is mediated via alterations in the hypothalamic-neuroendocrine axis, which drives metabolic changes in peripheral tissues leading to a marked reduction in hyperglycemia and hyperlipidemia and corrects autonomic control of islet function. To elucidate the nature of the functional response of islets to systemic BC/SKF treatment in ob/ob mice, we investigated the relative changes in the levels of functionally important beta-cell proteins in situ, as well as differences in the beta-cell turnover rate, following a 2-week drug treatment. Isolated islets from treated mice exhibit a 3.5-fold increase in insulin content (P <.01) that correlated with a 51% reduction in basal plasma insulin levels (P <.01) compared with vehicle-treated controls. Using quantitative immunofluorescence microscopy on pancreatic tissue sections, insulin and GLUT2 immunoreactivity of islet beta cells of BC/SKF-treated mice were significantly increased (approximately 2.3-fold and approximately 4.4-fold, respectively; P <.002) to the levels observed in islets of their lean littermates. Glucokinase (GK) immunoreactivity was greatly (75%) reduced in beta cells from ob/ob versus lean mice (P <.0001). A modest increase in GK immunoreactivity in beta cells of drug-treated mice was observed (approximately 1.6-fold; P <.05). Isolated islets from BC/SKF-treated mice exhibit a 42% reduction in DNA content compared with vehicle-treated controls (P <.01) to levels observed in lean mice, but without notable differences in islet size. In situ assays for mitosis and apoptosis, using 5-bromodeoxyuridine (BrdU) and terminal deoxyribotransferase (TdT)-UTP nick end labeling (TUNEL) staining techniques, respectively, were performed in pancreas of these mice to determine if beta cells show a reduction in hyperplasia following BC/SKF treatment. Accordingly, a pronounced decrease in replicating, BrdU-positive beta cells in the drug-treated mice compared with the control group was observed, but without differences in their TUNEL-staining patterns. Collectively, these data suggest that systemic sympatholytic dopaminergic therapy that attenuates hyperglycemia and hyperlipidemia improves islet function in ob/ob mice by improving aberrations in the beta cell's glucose-sensing apparatus, enhancing insulin storage and/or retention, and stabilizing hyperplasia, thus reducing basal insulin levels.
Albert Renold strived to gain insight into the abnormalities of human diabetes by defining the pathophysiology of the disease peculiar to a given animal. He investigated the Israeli desert-derived spiny mice (Acomys cahirinus), which became obese on fat-rich seed diet. After a few months hyperplasia and hypertrophy of beta-cells occurred leading to a sudden rupture, insulin loss and ketosis. Spiny mice were low insulin responders, which is probably a characteristic of certain desert animals, protecting against insulin oversecretion when placed on an abundant diet. We have compared the response to overstimulation of several mutant diabetic species and nutritionally induced nonmutant animals when placed on affluent diet. Some endowed with resilient beta-cells sustain long-lasting oversecretion, compensating for the insulin resistance, without lapsing into overt diabetes. Some with labile beta cells exhibit apoptosis and lose their capacity of coping with insulin resistance after a relatively short period. The wide spectrum of response to insulin resistance among different diabetes prone species seems to represent the varying response of human beta cells among the populations. In search for the molecular background of insulin resistance resulting from overnutrition we have studied the Israeli desert gerbil Psammomys obesus (sand rat), which progresses through hyperinsulinemia, followed by hyperglycemia and irreversible beta cell loss. Insulin resistance was found to be the outcome of reduced activation of muscle insulin receptor tyrosine kinase by insulin, in association with diminished GLUT4 protein and DNA content and overexpression of PKC isoenzymes, notably of PKCepsilon. This overexpression and translocation to the membrane was discernible even prior to hyperinsulinemia and may reflect the propensity to diabetes in nondiabetic species and represent a marker for preventive action. By promoting the phosphorylation of serine/threonine residues on certain proteins of the insulin signaling pathway, PKCepsilon exerts a negative feedback on insulin action. PKCepsilon was also found to attenuate the activity of PKB and to promote the degradation of insulin receptor, as determined by co-incubation in HEK 293 cells. PKCepsilon overexpression was related to the rise in muscle diacylglycerol and lipid content, which are prevalent on lascivious nutrition especially if fat-rich. Thus, Psammomys illustrates the probable antecedents of the development of worldwide diabetes epidemic in human populations emerging from food scarcity to nutritional affluence, inappriopriate to their metabolic capacity.
Ca2+-responsive mitochondrial FAD-linked glycerophosphate dehydrogenase (mGPDH) is a key component of the pancreatic beta-cell glucose-sensing device. The purpose of this study was to examine the association of mutations in the cDNA coding for the FAD-binding domain of mGPDH and to explore the functional consequences of these mutations in vitro. To investigate this association in type 2 diabetes mellitus, we studied a cohort of 168 patients with type 2 diabetes and 179 glucose-tolerant control subjects of Spanish Caucasian origin by single-stranded conformational polymorphism analysis. In vitro site-directed mutagenesis was performed in the mGPDH cDNA sequence to reproduce those mutations that produce amino acid changes in a patient with type 2 diabetes. We detected mutations in the mGPDH FAD-binding domain in a single patient, resulting in a Gly to Arg amino acid change at positions 77, 78, and 81 and a Thr to Pro at position 90. In vitro expression of the mutated constructs in Xenopus oocytes resulted in a significantly lower enzymatic activity than in cells expressing the wild-type form of the enzyme. Our results indicate that although mutations in the mGPDH gene do not appear to have a major role in type 2 diabetes mellitus, the reduction in mGPDH enzymatic activity associated with the newly described mGPDH mutations suggests that they may contribute to the disease in some patients.
Psammomys obesus, an animal model of type 2 diabetes, shows rapid and marked depletion of pancreatic insulin content as hyperglycemia develops when fed a high-calorie diet. P. obesus islets do not increase proinsulin gene expression when exposed to high glucose, which may be related to absence of the conserved form of the transcription factor insulin promoter factor 1/pancreatic-duodenal homeobox 1. The present study assesses the importance of regulation of proinsulin gene expression by glucose for insulin production. Islets of diabetes-prone P. obesus and diabetes-resistant Wistar rats, cultured at various glucose concentrations for up to 24 h, were analyzed for proinsulin mRNA by quantitative RT-PCR, proinsulin biosynthesis by leucine incorporation into proinsulin, and insulin content and secretion by RIA. No increase in proinsulin mRNA was observed in P. obesus islets during 24-h exposure to increasing concentrations of glucose. In contrast, rat islets exposed to high glucose responded with a 2- to 3-fold stimulation of proinsulin mRNA. The failure of P. obesus islets to increase proinsulin mRNA was accompanied by a reduced proinsulin biosynthetic response: after 24 h, maximal proinsulin biosynthesis was blunted, associated with depletion of islet insulin content. Inhibition of glucose-stimulated proinsulin gene transcription in rat islets by actinomycin D did not affect the early proinsulin biosynthetic response, which, however, was reduced to the level of P. obesus islets after 24 h in culture. We conclude that stimulation of proinsulin gene transcription by glucose is necessary for maintaining proinsulin biosynthesis and hence conserving pancreatic insulin stores, under conditions of sustained secretory drive, but not for short-term regulation of proinsulin biosynthesis Our findings support the hypothesis that inadequate regulation of proinsulin gene expression by glucose contributes to the failure of P. obesus to cope with the increased demand for insulin associated with caloric excess, leading to depletion of insulin stores and diabetes.
Type 2 diabetes mellitus is increasing worldwide with a trend of declining age of onset. It is characterized by insulin resistance and a progressive loss of beta-cell function. The ability to secrete adequate amounts of insulin is determined by the functional integrity of beta-cells and their overall mass. Glucose, the main regulator of insulin secretion and production, exerts negative effects on beta-cell function when present in excessive amounts over a prolonged period. The multiple metabolic aberrations induced by chronic hyperglycemia in the beta-cell include increased sensitivity to glucose, increased basal insulin release, reduced response to stimulus to secrete insulin, and a gradual depletion of insulin stores. Inadequate insulin production during chronic hyperglycemia results from decreased insulin gene transcription due to hyperglycemia-induced changes in the activity of beta-cell specific transcription factors. Hyperglycemia may negatively affect beta-cell mass by inducing apoptosis without a compensatory increase in beta-cell proliferation and neogenesis. The detrimental effect of excessive glucose concentrations is referred to as 'glucotoxicity'. The present review discusses the role of glucotoxicity in beta-cell dysfunction in type 2 diabetes mellitus.
It has recently been suggested that insulin augments its own production by a physiologically important feed-forward autocrine loop. We studied the kinetics of glucose-regulated proinsulin gene expression and proinsulin biosynthesis in normal rat islets with emphasis on the potential role of insulin as a mediator of the glucose effect. There was a time-dependent increase in steady-state proinsulin mRNA in islets cultured at 16.7 mmol/l compared with 3.3 mmol/l glucose; no early (1-3 h) increase in proinsulin gene expression was observed. In contrast, there was a threefold increase in proinsulin biosynthesis within 1 h of glucose stimulation that was not affected by inhibition of glucose-stimulated proinsulin gene transcription with actinomycin D. In addition, inhibition of glucose-stimulated insulin secretion with diazoxide had no effect on glucose-stimulated proinsulin mRNA or biosynthesis. Furthermore, addition of different concentrations of insulin to islets cultured in low glucose failed to affect proinsulin biosynthesis. Taken together, our data suggest that the early glucose-dependent increase in proinsulin biosynthesis is mainly regulated at the translational level, rather than by changes in proinsulin gene expression. Moreover, we could not demonstrate any effect of insulin on islet proinsulin mRNA level or rate of proinsulin biosynthesis. Thus, if insulin has any effect on the proinsulin biosynthetic apparatus, it is a minor one. We conclude that the secreted insulin is not an important mediator of insulin production in response to glucose.
Substrate autoregulation of glucose transporter-1 (GLUT-1) mRNA and protein expression provides vascular endothelial and smooth muscle cells a sensitive mechanism to adapt their rate of glucose transport in response to changing glycemic conditions. Hyperglycemia-induced downregulation of glucose transport is particularly important in protecting these cells against an excessive influx of glucose and consequently increased intracellular protein glycation and generation of free radicals; both are detrimental in the development of vascular disease in diabetes. We aimed to investigate the molecular mechanism of high glucose-induced downregulation of GLUT-1 mRNA expression in primary bovine aortic vascular endothelial (VEC) and smooth muscle (VSMC) cell cultures. Using RNA mobility shift, UV cross-linking, and in vitro degradation assays, followed by mass-spectrometric analysis, we identified calreticulin as a specific destabilizing trans-acting factor that binds to a 10-nucleotide cis-acting element (CAE(2181-2190)) in the 3'-untranslated region of GLUT-1 mRNA. Pure calreticulin accelerated the rate of GLUT-1 mRNA-probe degradation in vitro, whereas overexpression of calreticulin in vascular cells decreased significantly the total cell content of GLUT-1 mRNA and protein. The expression of calreticulin was augmented in vascular cells exposed to high glucose in comparison with low-glucose conditions. Similarly, increased expression of calreticulin was observed in aortae of diabetic Psammomys obesus in comparison with normoglycemic controls. These data suggest that CAE(2181-2190)-calreticulin complex, which is formed in VSMC and VEC exposed to hyperglycemic conditions, renders GLUT-1 mRNA susceptible to degradation. This interaction underlies the process of downregulation of glucose transport in vascular cells under high-glucose conditions.
Type 2 diabetes is increasingly viewed as a disease of insulin deficiency due not only to intrinsic pancreatic beta-cell dysfunction but also to reduction of beta-cell mass. It is likely that, in diabetes-prone subjects, the regulated beta-cell turnover that adapts cell mass to body's insulin requirements is impaired, presumably on a genetic basis. We still have a limited knowledge of how and when this derangement occurs and what might be the most effective therapeutic strategy to preserve beta-cell mass. The animal models of type 2 diabetes with reduced beta-cell mass described in this review can be extremely helpful (a) to have insight into the mechanisms underlying the defective growth or accelerated loss of beta-cells leading to the beta-cell mass reduction; (b) to investigate in prospective studies the mechanisms of compensatory adaptation and subsequent failure of a reduced beta-cell mass. Furthermore, these models are of invaluable importance to test the effectiveness of potential therapeutic agents that either stimulate beta-cell growth or inhibit beta-cell death.
Mammalian target of rapamycin (mTOR) and its downstream target S6 kinase 1 (S6K1) mediate nutrient-induced insulin resistance by downregulating insulin receptor substrate proteins with subsequent reduced Akt phosphorylation. Therefore, mTOR/S6K1 inhibition could become a therapeutic strategy in insulin-resistant states, including type 2 diabetes. We tested this hypothesis in the Psammomys obesus (P. obesus) model of nutrition-dependent type 2 diabetes, using the mTOR inhibitor rapamycin.
Normoglycemic and diabetic P. obesus were treated with 0.2 mg x kg(-1) x day(-1) i.p. rapamycin or vehicle, and the effects on insulin signaling in muscle, liver and islets, and on different metabolic parameters were analyzed.
Unexpectedly, rapamycin worsened hyperglycemia in diabetic P. obesus without affecting glycemia in normoglycemic controls. There was a 10-fold increase of serum insulin in diabetic P. obesus compared with controls; rapamycin completely abolished this increase. This was accompanied by weight loss and a robust increase of serum lipids and ketone bodies. Rapamycin decreased muscle insulin sensitivity paralleled by increased glycogen synthase kinase 3beta activity. In diabetic animals, rapamycin reduced beta-cell mass by 50% through increased apoptosis. Rapamycin increased the stress-responsive c-Jun NH(2)-terminal kinase pathway in muscle and islets, which could account for its effect on insulin resistance and beta-cell apoptosis. Moreover, glucose-stimulated insulin secretion and biosynthesis were impaired in islets treated with rapamycin.
Rapamycin induces fulminant diabetes by increasing insulin resistance and reducing beta-cell function and mass. These findings emphasize the essential role of mTOR/S6K1 in orchestrating beta-cell adaptation to hyperglycemia in type 2 diabetes. It is likely that treatments based on mTOR inhibition will cause exacerbation of diabetes.
Glucose metabolism and glucose-stimulated insulin secretion are thought to be controlled at the level of glucose phosphorylation in pancreatic islet beta-cells. In the current study we have investigated the importance of glucose phosphorylation by using recombinant adenovirus as a gene delivery system for isolated rat islets. Treatment of islets with a virus containing the cDNA encoding the Escherichia coli beta-galactosidase gene (AdCMV-beta GAL) resulted in efficiencies of gene transfer of 70.3 +/- 2.5 and 61.2 +/- 2.2% in two independent experiments. Treatment of islets with a virus containing the cDNA encoding rat hexokinase I (AdCMV-HKI) resulted in a 10.7-fold increase in immunodetectable hexokinase protein and a similar increase in enzyme activity. A large percentage of the overexpressed hexokinase activity was associated with a cell fraction enriched in mitochondria. These changes in enzyme level were accompanied by a 2-fold increase in insulin release and [5-3H]glucose usage at basal glucose concentrations (3 mM). The rate of glucose usage at 20 mM glucose and the magnitude of the insulin secretory response to this stimulatory level of the sugar were unchanged relative to control islets. Overexpression of hexokinase I in isolated islets therefore creates a phenotype of elevated basal insulin release similar to that seen in islets from obese and insulin-resistant mammals. The discrepancy between the large increase in hexokinase activity and the small increase in glucose usage and insulin release may indicate, however, that other steps in glucose metabolism become rate-limiting after only modest increases in glucose-phosphorylating activity.
The insulin receptor was evaluated at different disease stages in the sand rat (Psammomys obesus), a model for nutrition-induced diabetes. Nondiabetic sand rats showed markedly low receptor number in liver compared with albino rats. Their receptor had an intact tyrosine kinase activity but a higher Km for ATP in the phosphorylation reaction of exogenous substrates. The initial effects of overeating (i.e., development of hyperinsulinemia without hyperglycemia) were associated in the sand rat with a dramatic decrease in in vitro and in vivo insulin-induced receptor tyrosine kinase activity in both liver and muscle. In muscle, this coincided with a decrease in receptor number and an increase in basal tyrosine kinase activity. Similar changes were observed upon development of hyperinsulinemia with hyperglycemia. Upon recovery from the diabetic state by diet restriction, the impaired receptor kinase activation was corrected. Complete restoration occurred only in animals that fully recovered from the diabetic state and became normoinsulinemic. These observations indicate that loss and gain of receptor tyrosine kinase activity were dependent on insulin levels. Thus, overeating may lead to the development of hyperinsulinemia through ineffective extraction of excess insulin by the scarce liver receptors. Hyperinsulinemia, in turn, causes a reversible reduction in receptor kinase activity, leading to insulin resistance. This sequence of events may be relevant to diet-related changes in human non-insulin-dependent diabetes mellitus.
The cause of disproportionate hyperproinsulinemia in patients with type II diabetes is controversial. To examine whether increased beta cell demand might contribute, we measured proinsulin and insulin concentrations in clinically healthy humans who had undergone hemipancreatectomy for the purpose of organ donation, a procedure previously demonstrated to increase beta cell demand and diminish insulin secretory reserve capacity. Subjects were studied at least 1 yr after hemipancreatectomy. Seven donors were followed prospectively and serves as their own controls. Nine additional donors were matched with normal controls (cross-sectional group). Fasting serum concentrations of intact proinsulin and conversion intermediates (total) were measured by a two-step radioimmunoassay; independent determinations of intact proinsulin and 32,33 split proinsulin were performed using an immunoradiometric assay. Serum total proinsulin values were significantly greater in hemipancreatectomized groups than controls (prospective group: predonation = 6.24 +/- 1.14 pM, postdonation = 34.63 +/- 17.47 pM, P < 0.005; cross-sectional group: controls = 5.78 +/- 1.12 pM, donors = 15.22 +/- 5.20 pM, P < 0.025). The ratio of total proinsulin to immunoreactive insulin was directly correlated with fasting plasma glucose and showed a significant inverse relationship to secretory reserve capacity. Both absolute and relative hyperproinsulinemia is found in hemipancreatectomized donors. These data demonstrate that partial pancreatectomy with its associated increase in beta cell demand raises measures of proinsulin in humans.
If two consecutive glucose infusions are administered with 40 min of rest between, the insulin response to the second challenge is markedly potentiated. When the insulin response to the first glucose infusion was suppressed by 65 % with the aid of adrenaline, potentiation of the insulin response to the second infusion was not modified. This suggests that the generation of a state of enhancement in the islet does not necessitate that glucose exerts its insulin releasing action. It is postulated that islet glucose metabolism may be involved in producing the potentiation.
Pretreatment of the subjects with a glucose infusion enhanced also the insulin responses to glucagon and to tolbutamide, given intravenously 50 min later. Thus, the potentiation generated by glucose is not restricted to the insulinogenic signal induced by glucose. The eventual role that the beta-cell adenylate cyclase may play in this respect is discussed.
A spontaneously diabetic rat with polyuria, polydipsia, and mild obesity was discovered in 1984 in an outbred colony of Long-Evans rats, which had been purchased from Charles River Canada (St. Constant, Quebec, Canada) in 1982. A strain of rats developed from this rat by selective breeding has since been maintained at the Tokushima Research Institute (Otsuka Pharmaceutical, Tokushima, Japan) and named OLETF. The characteristic features of OLETF rats are 1) late onset of hyperglycemia (after 18 wk of age); 2) a chronic course of disease; 3) mild obesity; 4) inheritance by males; 5) hyperplastic foci of pancreatic islets; and 6) renal complication (nodular lesions). Histologically, the changes of pancreatic islets can be classified into three stages: 1) an early stage (6-20 wk of age) of cellular infiltration and degeneration; 2) a hyperplastic stage (20-40 wk of age); and 3) a final stage (at > 40 wk of age). These clinical and pathological features of disease in OLETF rats resemble those of human NIDDM.
Using cultured islets as the experimental system, this study established dosage-response and time-dependency curves of the inductive glucose effect on glucose-stimulated insulin release, glucose usage, and glucokinase activity. Glucose-stimulated insulin release in islets cultured for 1, 2, or 7 days was increased as a function of glucose concentration in the culture medium and as a function of time. Glucose usage in the cultured islets showed a close relationship with glucose concentration in the culture medium at both 2 and 7 days of culture. Glucokinase activity increased in islets cultured for 1, 2, or 7 days as a function of increasing glucose concentrations in the culture medium and as a function of time. The V(max) of glucokinase in islets cultured for 7 days in medium containing 30 mM glucose was twice the value of freshly isolated islets and was almost fivefold higher than that in islets cultured for 7 days in 3 mM glucose. The glucose induction of glucose-stimulated insulin release, of glucose usage, and of glucokinase activity were tightly correlated. The biochemical mechanisms of glucose induction of islet glucokinase were further studied. Immunoblotting with an antibody against C-terminal peptide of glucokinase showed that densities of a 52,000-kD protein band from tissue extracts of islets cultured for 7 days in 3, 12, and 30 mM glucose were 25, 44, and 270% compared with that of extract from freshly isolated islets (100%). RNA blot analysis of glucokinase mRNA demonstrated virtually the same levels in fresh islets and islets after 7 days of culture in 3 or 30 mM glucose. The adaptive response of glucokinase to glucose appears therefore to be occurring at a translational or posttranslational site in cultured islets. These data greatly strengthen the concept that glucose is the regulator that induces the activity of glucokinase, which in turn determines the rate change of glucose usage as well as glucose-stimulated insulin release from beta-cells. Thus, the hypothesis that glucokinase is the glucose sensor of beta-cells is strengthened further.
The purpose of the study was to investigate the development of microangiopathic complications in North African sand rats with diabetes induced by a long-term standard laboratory diet. Hyperinsulinaemic rats, whether non-diabetic obese or diabetic, developed capillary basement membrane (CBM) thickening in the skin; in insulin-dependent animals, this change was diffuse. Many PAS positive areas were demonstrated in skeletal muscle and myocardium, together with evidence of microangiopathy; the primary myocardial lesion in insulin-dependent disease was ischaemic fibrosis. The kidney was also affected with marked basement membrane thickening in Bowman's capsule and glomerular capillaries; glomerulosclerosis and tubular changes were found in insulin-dependent disease. No evidence of diabetic retinopathy was found, and there was a high incidence of cataract.
A highly specific two-site immunoradiometric assay for insulin was used to measure the plasma insulin response to 75 g glucose administered orally to 49 patients with non-insulin-dependent diabetes (NIDDM). The plasma insulin concentration 30 min after glucose ingestion was lower in the diabetic patients than in matched controls for both non-obese (11-83 pmol/l vs 136-297 pmol/l, p less than 0.01) and obese subjects (23-119 pmol/l vs 137-378 pmol/l, p less than 0.01). By means of another two-site immunoradiometric assay, the basal intact proinsulin level was found to be higher in the NIDDM patients than in the controls for both non-obese (7.1 [SEM 1.2] pmol/l vs 2.4 [0.4] pmol/l, p less than 0.01) and obese subjects (14.4 [2.2] pmol/l vs 5.9 [1.9] pmol/l, p less than 0.01). The basal level of 32-33 split proinsulin was also raised in NIDDM. Previous failure to show clear separation between normal and NIDDM insulin responses was probably due to the high concentrations of proinsulin-like molecules in the plasma of NIDDM patients. These substances cross-react as insulin in most, if not all, insulin radioimmunoassays but have very little biological insulin-like activity. It is therefore now possible and necessary to designate most NIDDM patients as insulin deficient.
Serum proinsulin is disproportionately elevated both in the basal state and after an oral glucose load in non-insulin-dependent diabetes mellitus (NIDDM). However, there is no detailed information about the effect of glycemic control on this abnormality. We investigated the effect of glycemic control by dietary treatment on serum proinsulin level in the basal state and in response to an oral glucose load. Ten NIDDM patients (7 men and 3 women), aged 19-60 yr, with mean (+/- SD) body mass index of 28 +/- 6 kg/m2 (range 21-42 kg/m2) and normal renal and liver function were studied. Before and after dietary therapy (25-30 kcal/kg ideal body wt), 100-g oral glucose tolerance tests were performed. Proinsulin was measured with our proinsulin-specific antiserum, which recognizes the connecting site of the B-chain of insulin and C-peptide. After dietary treatment, fasting plasma glucose decreased from 197 +/- 35 to 113 +/- 18 mg/dl (P less than .001). Both serum insulin and proinsulin decreased (insulin from 15 +/- 8 to 10 +/- 4 microU/ml, P less than .02; proinsulin from 31 +/- 18 to 13 +/- 5 pM, P less than .02), and the molar ratio of proinsulin to insulin also tended to decrease (from 0.321 +/- 0.08 to 0.24 +/- 0.10, P less than .10). Insulin response to oral glucose increased after dietary treatment, whereas proinsulin response did not change, resulting in a significant decrease in the molar ratio of the area under the curve of proinsulin to insulin after glucose load (from 0.28 +/- 0.12 to 0.13 +/- 0.07, P less than .001).(ABSTRACT TRUNCATED AT 250 WORDS)
A radioimmunoassay, using an antiserum that is specific for human proinsulin, has been used to study the response of serum proinsulin to low (25 g) and high (75 g) oral glucose loads in non-obese patients with non-insulin-dependent diabetes mellitus (NIDDM). Diabetic patients were treated by diet only (N = 8) or were receiving oral anti-hyperglycemic agents (N = 8) and therapy was not interrupted during the study. In the fasted state, proinsulin concentrations were higher (P less than 0.05) in the drug-treated patients (31 +/- 3 pmol/l (SEM)) compared with age- and weight-matched healthy subjects (22 +/- 2 pmol/l; N = 10), but concentrations in the diet-treated patients 25 +/- 3 pmol/l) were not significantly different. Following 25 g and 75 g glucose loads, the rises in serum immunoreactive insulin and C-peptide concentrations in both groups of diabetic patients were impaired and delayed relative to those in the control subjects. The responses of serum proinsulin, however, were not significantly different in the NIDDM patients compared with controls at any time point up to 180 min except in the case of drug-treated patients receiving 25 g of glucose who had elevated (P less than 0.05) proinsulin concentrations at 150 min and 180 min after ingestion. It is concluded that NIDDM is not associated with an exaggerated release of proinsulin in response to glucose compared with healthy subjects, but the islets have maintained the ability to release proinsulin better than the ability to release insulin.
The dynamics of insulin release were investigated in vitro in order to determine the regulatory processes governing its biphasic shape. When subjected to a square wave glucose stimulation, the isolated perfused rat pancreas responded with typical biphasic insulin release. Both the duration of the nadir between the two phases and the slope of recovery of insulin release during second-phase secretion exhibited glucose dose dependency. Successive 40-min stimuli with glucose (8.3 and 16.7 mM), separated by a 20-min rest period, resulted in 2.6- 3.3-fold potentiation of the early phase insulin release rate, previously described as glucose-primed time-dependent potentiation (TDP) of insulin secretion. A linear relationship (r = 0.89, P less than 0.001) was observed between the degree of TDP and the slope of second-phase insulin release. Successive short stimuli with glucose (5-10 min long, 5-10 min apart; 6.9, 8.3, and 16.7 mM) resulted in the inhibition of the response to the second stimulus; this effect was termed time-dependent inhibition (TDI) of insulin release. Arginine also induced TDI; this was completely overcome by synergistic interaction with glucose (8.3 mM). The glucose-arginine interaction was utilized to demonstrate that the interphasic nadir of insulin release was the expression of TDI. Thus, introduction of an arginine stimulus during the nadir in glucose-induced insulin release abolished the silent phase, the secretion rate reaching the level expected for the combined glucose-arginine stimulus. However, the continued presence of TDI could be demonstrated by removal of the arginine stimulus, at which time, despite ongoing glucose stimulation, insulin secretion was markedly inhibited. These observations support the concept that the biphasic dynamics of insulin release is the net expression of three regulatory processes: 1) the acute stimulus-secretion coupling system, best observed as the immediate, first-phase response to a stimulus; 2) TDI of insulin release, a relatively rapid signal responsible for the silent period; and 3) TDP of insulin release, a slow rising signal responsible for recovery from the silent phase, building up the second-phase of secretion.
In this study, we found that the ratio of proinsulin to total immunoreactive insulin was much higher in 22 patients with Type 2 (non-insulin-dependent) diabetes mellitus than in 28 non-diabetic control subjects of similar age and adiposity (32 +/- 3 vs 15 +/- 1%, p less than 0.001). In addition, the arginine-induced acute proinsulin response to total immunoreactive insulin response ratio was greater in diabetic patients (n = 10) than in control subjects (n = 9) (8 +/- 2 vs 2 +/- 0.5%, p = 0.009), suggesting that increased islet secretion per se accounted for the increased ratio of proinsulin to immunoreactive insulin. One explanation for these findings is that increased demand for insulin in the presence of islet dysfunction leads to a greater proportion of proinsulin secreted from the B cell. We tested this hypothesis by comparing proinsulin secretion before and during dexamethasone-induced insulin resistance in diabetic patients and control subjects. Dexamethasone treatment (6 mg/day for 3 days) raised the proinsulin to immunoreactive insulin ratio in control subjects from 13 +/- 2 to 21 +/- 2% (p less than 0.0001) and in diabetic patients from 29 +/- 5 to 52 +/- 7% (p less than 0.001). Dexamethasone also raised the ratio of the acute proinsulin response to the acute immunoreactive insulin response in control subjects from 2 +/- 0.5 to 5 +/- 2% (p = 0.01) and in diabetic patients from 8 +/- 2 to 14 +/- 4% (p = NS), suggesting that the dexamethasone-induced increment in the basal ratio of proinsulin to immunoreactive insulin was also due to increased secretion.(ABSTRACT TRUNCATED AT 250 WORDS)
Sand rats (Psammomys obesus) maintained on a diet providing a free choice between laboratory chow and salt bush (Atriplex halimus) were classified into four groups differing in extent of the diabetic syndrome: A, normoglycemic-normoinsulinemic; B, normoglycemic-hyperinsulinemic; C, hyperglycemic-hyperinsulinemic; or D, hyperglycemic with reduced insulin levels. The metabolic pattern of these groups was characterized by measuring the uptake of fatty acid-labeled, very-low-density lipoprotein-borne triglycerides (VLDL-TG) and [3H]-2-deoxyglucose (2-DOG) into muscle and adipose tissues; incorporation of [14C]alanine into glycogen in vivo; gluconeogenesis from lactate, pyruvate, and alanine in hepatocytes; the effect of insulin on glycogen synthesis from glucose; the oxidation of albumin-bound [1-14C]palmitate and [14C]glucose in strips of soleus muscle; activities of muscle and adipose tissue lipoprotein lipase; and activities of rate-limiting enzymes of glycolysis, gluconeogenesis, and fatty acid synthesis in liver. In group A, uptake of VLDL-TG and activity of lipoprotein lipase were higher in adipose tissue and lower in muscle than in albino rats. In the liver, gluconeogenesis and the activity of phosphoenolpyruvate carboxykinase, as well as lipid synthesis and the activity of NADP-malate dehydrogenase, were higher than in albino rats, whereas activity of pyruvate kinase was lower. In group B, uptake of VLDL-TG by adipose tissue and muscle and lipoprotein lipase activity were similar or higher than in group A. Uptake of 2-DOG by muscle and adipose tissue and activity of liver phosphoenolpyruvate carboxykinase were lower than in group A. In groups C and D, uptake of VLDL-TG and lipoprotein lipase activity in muscle were further increased.(ABSTRACT TRUNCATED AT 250 WORDS)
Insulin release kinetics were studied in perifused islets of Langerhans, isolated from mildly hyperglycaemic and from normoglycaemic spiny mice (Acomys cahirinus), a rodent predisposed to develop spontaneously non-ketotic diabetes. In both groups, insulin response to glucose (16.7 mmol/l) was delayed in comparison with that of rat islets, the release kinetics being analogous to that of human Type 2 (non-insulin-dependent) diabetes. Thirty min priming of the isolated Acomys islets with glucose (16.7 mmol/l) resulted in potentiation of the insulin release to a second stimulation. The degree of potentiation decreased exponentially with the time interval between stimulations, showing a t1/2 of 18 min. Induction of potentiation by glucose was time-dependent, giving a maximal effect after 20 min of priming. In addition to overall amplification of the insulin response, priming with glucose accelerated markedly the initial release rates, correcting the dynamics of the response. We conclude that: (1) decreased and delayed insulin secretion is found in Acomys cahirinus before the development of hyperglycaemia; (2) induction of time-dependent potentiation in the islet by priming with glucose corrects the diabetic-type dynamics of insulin release; (3) therefore the deficient insulin release of Acomys is of a functional nature, the mechanism of potentiation bypassing the defect; (4) since insulin release in Acomys resembles that in prediabetic and diabetic man, similar conclusions might apply to the islet dysfunction in Type 2 diabetes.
A simple method for the isolation of intact islets from the normal rat pancreas is described. The method is based upon disruption of the acinar parenchyma by injecting Hanks solution into the pancreatic duct system followed by incubation of the pancreas in collagenase. Islets can be separated rapidly from this mixture by sedimentation. The isolated islets release insulin in vitro and appear normal by light and electron microscopy after incubation. A centrifugation method is also described for isolation of large quantities of islets for biochemical studies.
A simple and rapid assay for quantitative determinations of DNA in crude homogenates is described. The method is based on the enhancement of fluorescence seen when bisbenzimidazole (Hoechst 33258) binds to DNA. Crude homogenates in which chromatin has been dissociated with high salt buffer can be assayed directly and reliably in a few minutes. The dissociation of chromatin is critical to accurate determinations of DNA in biological materials using this method. The assay can detect as little as 10 ng of DNA with rather unsophisticated instrumentation.
Egyptian sand rats (Psammomys obesus) developed under laboratory holding conditions and in dependence of different food intake various states of hyperglycemia and hyperinsulinism. Associated with the development of this syndrome insulin resistance of muscle- and adipose tissue appears. The question arose as to whether hyperglycemia and hyperinsulinism generally leads to hormone resistance. Therefore, we selected sand rats with different degrees of hyperglycemia and various stages of hyperinsulinism. Two groups of sand rats were investigated: normoglycemic and hyperglycemic animals. In these sand rats the catecholamine action on cAMP production adipose tissue was studied in vitro. There was a significant reduction of hormone responsiveness in adipose tissue of the hyperglycemic group compared with the noradrenaline response of adipose tissue of the normoglycemic sand rats. In no case had insulin significantly inhibited the noradrenaline stimulated cAMP production. By means of adenosine deaminase studies the interference of the eventual release of adenosine with the hormone action on adipose tissue in vitro could be excluded. In the sand rats correlations between IRI levels in the decapitation blood and noradrenaline stimulated cAMP release associated with simultaneous occurrence of insulin- and catecholamine resistance in adipose tissue seem to indicate that hormone resistance could be a general phenomenon during the development of hyperinsulinism.
Glucokinase is the beta-cell glucose sensor, i.e., the site in glucose metabolism that determines the glucose set-point (sensitivity) for insulin secretion. Hexokinase is also present, but it normally contributes little to glucose metabolism because of end-product inhibition by glucose 6-phosphate. There is a lowered glucose set-point for insulin secretion in 90% pancreatectomized (Px) diabetic rats. We investigated the mechanism by measuring hexokinase and glucokinase activity in islet extracts. Glucokinase activity was minimally raised in Px islets (Vmax 125% of sham-operated control rats). In contrast, hexokinase Vmax was 250% of the control value, suggesting that the increased hexokinase activity caused the beta-cell glucose hypersensitivity. Additional evidence was obtained with a 40-h fast that was performed because of a previous observation that the inhibitory effect of fasting on insulin secretion was impaired in Px rats. Glucokinase activity fell normally in the Px rats (32 +/- 4% reduction in sham vs. 37 +/- 4% in Px rats) as opposed to hexokinase activity, which was unaffected in either group. In summary, a feature of hyperglycemia is upregulated islet hexokinase activity. The result is that hexokinase assumes partial control over the glucose set-point for insulin secretion. As such, regulatory effects on insulin secretion, such as fasting, that are mediated through glucokinase activity may be altered.
We have recently shown that the diabetic syndrome in Psammomys obesus is characterized by severe depletion of islet immunoreactive insulin (IRI) stores together with a marked increase in the islet proinsulin to insulin ratio. In the present in vitro studies, we show marked enhancement of proinsulin biosynthesis in islets from diabetic P. obesus (approximately 8-fold compared to nondiabetic islets). Proinsulin to insulin conversion and insulin degradation do not differ significantly between diabetic and nondiabetic islets. The rate of IRI secretion at a stimulatory concentration of glucose (16.7 mM) is comparable in diabetic and nondiabetic animals, but at a nonstimulatory glucose concentration (0 mM), islets obtained from diabetic animals show significant IRI release. beta-Cells from diabetic P. obesus also exhibited increased secretion of newly synthesized proinsulin and conversion intermediates under stimulatory conditions. Moreover, a novel secretory compartment, highly enriched in newly synthesized C peptide, characterized the beta-cells of diabetic animals. Our data suggest that the marked insulin depletion observed in diabetic islets is probably due to a hyperglycemia-driven increase in secretory demand that is not met by the enhanced biosynthetic capacity of these islets. This leads to relative enrichment of the depleted diabetic islets with immature secretory granules of a higher proinsulin content.
Patients with noninsulin-dependent diabetes mellitus exhibit increased proportions of plasma proinsulin and proinsulin conversion intermediates. We used hyperinsulinemic diabetic and nondiabetic Psammomys obesus to study the possible relationship between steady state pancreatic insulin stores and the proportion of proinsulin-related peptides in the plasma and pancreas. Insulin-like peptides were separated by reverse phase HPLC and identified by pulse-chase experiments. A marked increase in the proportions of proinsulin and proinsulin conversion intermediates in the plasma and pancreas of diabetic nonfasted Psammomys was associated with 90% reduction in insulin stores of the pancreas. After a 16- to 20-h fast, the depletion of pancreatic insulin in the diabetic animals was partially corrected, and the proinsulin/insulin ratio was normalized. In contrast, nondiabetic Psammomys showed only 50% reduction in pancreatic insulin stores under nonfasting conditions, with no change in the proinsulin/insulin ratio. These findings suggest that in the diabetic Psammomys obesus, the pancreatic capacity for storage of insulin may be limited; the metabolic consequences of this limitation are amplified by increased secretory demand secondary to insulin resistance, thus facilitating the establishment of hyperglycemia, which may in itself further exacerbate pancreatic dysfunction.
Glucose-induced insulin secretion is impaired in the presence of chronic hyperglycaemia. Insulin secretion was studied in a diabetic rat model prior to the beta cells becoming non-responsive to glucose in order to map out the sequence of changes that accompany chronic hyperglycaemia. In vitro pancreas perfusions were carried out 1 and 2 weeks after a 90% pancreatectomy; controls underwent a sham pancreatectomy. One week post 90% pancreatectomy: (i) non-fasting plasma glucose values were 2-3 mmol/l above normal, (ii) the in vitro insulin response to 16.7 mmol/l glucose was 20 +/- 4% of shams, a response that was appropriate for the surgical reduction in beta-cell mass, (iii) the beta-cell sensitivity for glucose was increased as reflected by left-shifted dose-response curves for glucose-induced insulin secretion (half maximal insulin output 5.7 mmol/l glucose vs 16.5 mmol/l glucose in shams) and glucose potentiation of arginine-induced insulin secretion (half maximal insulin output 3.5 mmol/l glucose vs 14.8 mmol/l glucose in shams). This heightened beta-cell sensitivity for glucose was not a result of the hyperglycaemia, because similarly reduced half-maximal insulin responses were found after a 60% pancreatectomy, a surgical procedure in which plasma glucose values remained normal. In summary, a rise in beta-cell sensitivity for glucose precedes the loss of glucose-induced insulin secretion in diabetic rats.
Pancreatic islets were cultured for 24 h in medium containing either low (1.4), normal (5.5), or high (16.7 mM) glucose, and then insulin secretion was measured at the end of 1 h incubation at 37 degrees C. Insulin release in the absence of glucose was 64 +/- 20, 152 +/- 11, and 284 +/- 30 pg.islet-1.h-1 (mean +/- SE, n = 6, G1.4 and G16.7 vs. G.5.5, P < 0.05) and the response to 22 mM glucose stimulation was 640 +/- 136, 2460 +/- 276, and 1890 +/- 172 pg.islet-1.h-1, respectively (n = 6, G1.4 vs. G5.5, P < 0.01, G16.7 vs. G5.5, P = 0.065). The 50% maximal response of insulin secretion (increment over baseline) was reached at an average glucose concentration of 9.9 +/- 0.7 mM in islets preexposed to G5.5, and at glucose 13.3 +/- 0.9 and 4.8 +/- 0.4 mM (P < 0.05 in respect to G5.5) in islets preexposed to G1.4 and G16.7, respectively. To investigate the molecular mechanism responsible for this altered glucose sensitivity, we measured, in parallel experiments, the kinetic characteristics of glucose transport, glucokinase, and glucose utilization. Glucose transport was measured by evaluating 3-O-methylglucose uptake. The apparent Km of the low-affinity transporter (GLUT2) was 16.6 +/- 2.4 mM in isolated pancreatic cells cultured at 5.5 mM glucose.(ABSTRACT TRUNCATED AT 250 WORDS)
Two separate lines--diabetic and partially diabetes-resistant--have been isolated from the sand rat (Psammomys obesus), each with different growth characteristics in response to diets of varying digestible caloric densities (high energy, HE, 2.93 kcal/g, or low energy, LE, 2.38 kcal/g). Over a two week period all animals consumed similar quantities (c. 125 g) irrespective of the diet consumed. Weight gains were as follows: diabetic line on HE diet - 59.7 g, on LE - 46.2 g; non-diabetic animals from the diabetes-resistant line on HE - 44 g. Only animals from the diabetic line, fed the HE diet, developed hyperinsulinemia, obesity and diabetes. The energy cost of weight gain for the diabetic line fed either HE or LE diets was 6.0 - 6.3 kcal/g whereas for the diabetes-resistant line on the HE diet, the cost of growth was 50% higher at 9.3 kcal/g. These differences could be due either to alterations in the content of tissue laid down or to differences in energy expenditure. It has already been established that diet-induced obesity and diabetes develop in the diabetic line with features typical of insulin resistance in the metabolism of the pancreas, liver and peripheral tissues. Some of the animals of the diabetes-resistant line may also develop diabetes over a long time period and go through a phase of transient hyperinsulinemia-normoglycemia. This may represent an intermediate stage in the development of the diabetic syndrome and serve as a model of type 2 diabetes in man.
The desert gerbil Psammomys obesus ("sand rat"), a model of nutritionally induced insulin resistance and non-insulin-dependent diabetes mellitus, was treated after weaning with exogenous insulin implants in the normoglycaemic, normoinsulinaemic state. Albino rats matched for weight and age served as high energy diet adjusted reference animals. Insulin administration, elevating the serum insulin to 6000 pmol/l resulted in only a mild reduction in blood glucose levels in Psammomys, but caused a severe, often fatal hypoglycaemia in the albino rats. The hepatic response to insulin-induced hypoglycaemia in rats involved a significant loss in glycogen and suppression of phosphoenolpyruvate carboxykinase (PEPCK) activity. In Psammomys under similar hyperinsulinaemia no appreciable changes in liver glycogen and PEPCK activity were evident, indicating that blood glucose was replenished by continuing gluconeogenesis. Euglycaemic, hyperinsulinaemic clamp caused a complete shut-down of hepatic glucose production in albino rats. However, in both diabetes-prone and diabetes-resistant Psammomys lines, mean hepatic glucose production was reduced by only 62 to 53% respectively, despite longer lasting and higher levels of hyperinsulinaemia. These results indicate that Psammomys is characterized by muscle and liver insulin resistance prior to diet-induced hyperglycaemia and hyperinsulinaemia. This is assumed to be a species feature of Psammomys, exemplifying a metabolic adjustment to survival in conditions of food scarcity of both animal and human populations. It may reflect a propensity to insulin resistance and hyperglycaemia in population groups exposed to affluent nutrition.
Insulinoma beta-cells capable of overexpressing glucokinase under the control of a doxycycline-dependent transcriptional transactivator were established from parental INS-1 cells. Glucokinase could be maximally induced to a level more than 20 times the basal level after 36 h of culture with doxycycline. Intermediate levels of induction could be achieved by varying doses of, and time of culture with, the inducer. The rate of glycolysis was measured in cells with 3-, 5-, and 8-fold increment in glucokinase activity above the noninduced level. Proportionate increases in glycolytic flux occurred in cells cultured at low physiological glucose concentration. At high glucose concentration, induction of glucokinase in excess of 2-fold above basal resulted in little additional increase in glycolysis. The consequences of graded increases of glucokinase on two physiological glucose effects were investigated. Increments in glucokinase activity were accompanied by a stepwise shift to the left of the dose-response curve for the inductive effect of glucose on the L-type pyruvate kinase mRNA. Similarly, the insulin secretory response to glucose was shifted leftward in glucokinase-induced cells. The following conclusions are drawn: (i) glucokinase is the major rate-limiting enzyme for glycolysis in these cells; (ii) downstream metabolic steps become limiting at high extracellular glucose concentration with moderate increases in glucokinase over the wild-type level; (iii) within limits, glucokinase activity is a determining factor for two types of glucose responses of the beta-cell, the induction of specific gene expression, and insulin release.
The production of insulin from proinsulin involves cleavage of intact proinsulin into proinsulin conversion intermediates by the processing of enzymes PC2 and PC3 before fully processed insulin is produced. Intact proinsulin and these conversion intermediates are measured in many immunoreactive insulin (IRI) assays, and therefore contribute to the absolute IRI measurement. The proportion of basal IRI made up of proinsulin (PI)-like molecules (PI/IRI) is increased in NIDDM. Whether stimulated IRI levels are similarly made up of disproportionately increased PI/IRI or whether the relative proportions of proinsulin and its conversion intermediates are altered has not been evaluated. An index of the efficiency of proinsulin processing within the pancreatic beta-cell can be achieved by measuring PI/IRI immediately following acute stimulation of beta-cell secretion, and then determining the proportion of intact proinsulin and proinsulin conversion intermediates contributing to circulating proinsulin-like molecules. In this study, we determined the PI/IRI levels under basal and arginine-stimulated conditions in 17 healthy and 16 NIDDM subjects; high-performance liquid chromatography (HPLC) was also performed in a subset of these subjects to measure the relative contribution of intact proinsulin and its conversion intermediates to total proinsulin-like molecules. In NIDDM subjects, levels of both basal (44.6 +/- 9.6 vs. 9.3 +/- 1.5 pmol/l; P = 0.0007) and stimulated (64.0 +/- 12.7 vs. 19.8 +/- 2.8 pmol/l; P = 0.001) proinsulin-like molecules were higher than in healthy subjects. Although IRI was higher in NIDDM than in control subjects under basal conditions (106 +/- 19 vs. 65.1 +/- 8.1 pmol/l; P = 0.05), it was lower in NIDDM than in control subjects following stimulation (increment: 257 +/- 46 vs. 416 +/- 51 pmol/l; P = 0.03). PI/IRI ratios were increased in NIDDM subjects under both basal (43.3 +/- 5.0 vs. 14.0 +/- 1.3%; P < 0.0001) and stimulated (increment: 10.1 +/- 2.1 vs. 2.5 +/- 0.2%; P = 0.0006) conditions, compatible with the release of a disproportionately increased amount of proinsulin-like products. HPLC analysis revealed that, in the stimulated state, intact proinsulin made up 40.1 +/- 6.7% of proinsulin-like molecules in NIDDM individuals (n = 9) and 30.1 +/- 5.6% in healthy subjects (n = 7; NS). The remainder of the proinsulin-like molecules comprised the des-31,32-split proinsulin conversion intermediate. The increase in PI/IRI in NIDDM under basal and especially under stimulated conditions suggests that proinsulin conversion is indeed perturbed in this disorder. Because the relative proportions of intact and des-31,32-split proinsulin are similar in both healthy and NIDDM subjects, the orderly cleavage of proinsulin at its two junctions appears preserved. However, at the time of exocytosis, the secretory granule in the islet of NIDDM subjects contains an increased proportion of incompletely processed proinsulin, presumably reflecting a slower rate of conversion or granules' reduced time of residence in beta-cells.
Achieving predictable model of type 2 diabetes in the sand rat
- Jh Adler
- R Kalman
- G Lazarovici
- H Bar-On
- E Ziv
Adler JH, Kalman R, Lazarovici G, Bar-On H, Ziv E: Achieving predictable
model of type 2 diabetes in the sand rat. In Frontiers in Diabetes Research:
Lessons From Animal Diabetes III. Shafrir E, Ed. London, Smith-Gordon,
1991, p. 212–214
Spontaneous long-term hyperglycemic rat with diabetic complications: Otsuka Long-Evans Tokushima Fatty (OLETF) strain. D i a b e t e s 41:1422–1428, 1992 induces a reversible impairment in insulin receptor function leading to diabetes in the sand rat model of NIDDM
- K Kawano
- T Hirashima
- S Mori
- Y Saitoh
- M Kurosumi
- T Notori
Kawano K, Hirashima T, Mori S, Saitoh Y, Kurosumi M, Notori T: Spontaneous
long-term hyperglycemic rat with diabetic complications: Otsuka Long-Evans
Tokushima Fatty (OLETF) strain. D i a b e t e s 41:1422–1428, 1992 induces a reversible impairment in insulin receptor function leading to diabetes
in the sand rat model of NIDDM. Proc Natl Acad Sci U S A 91:1853–1857, 1994
Upregulated hexokinase activity in isolated islets from diabetic 90% pancreatectomized rats. D i a b e t e s 44:1328–1333, 1995 fatty rat as a model of non-insulin-dependent diabetes mellitus
- H Hosokawa
- Ay Hosokawa
- Jl Leahy
Hosokawa H, Hosokawa AY, Leahy JL: Upregulated hexokinase activity in isolated islets from diabetic 90% pancreatectomized rats. D i a b e t e s 44:1328–1333, 1995 fatty rat as a model of non-insulin-dependent diabetes mellitus. ILAR News
32:16–19, 1990
Modulation of glucose responsiveness of insulinoma betacells by graded overexpression of glucokinase
- H Wang
- Pb Iynedjian
Wang H, Iynedjian PB: Modulation of glucose responsiveness of insulinoma betacells by graded overexpression of glucokinase. Proc Natl Acad Sci U S A
94:4372–4377, 1997