Elimination of glucagon-like peptide 1R signaling does not modify weight gain and islet adaptation in mice with combined disruption of leptin and GLP-1 action.

Leptin and glucagon-like peptide 1 (GLP-1) exhibit opposing actions in the endocrine pancreas. GLP-1 stimulates insulin biosynthesis, secretion, and islet growth, whereas leptin inhibits glucose-dependent insulin secretion and insulin gene transcription. In contrast, GLP-1 and leptin actions overlap in the central nervous system, where leptin has been shown to activate GLP-1 circuits that inhibit food intake. To determine the physiological importance of GLP-1 receptor (GLP-1R)-leptin interactions, we studied islet function and feeding behavior in ob/ob:GLP-1R(-/-) mice. Although GLP-1R actions are thought to be essential for glucose-dependent insulin secretion, the levels of fasting glucose, glycemic excursion after glucose loading, glucose-stimulated insulin, and pancreatic insulin RNA content were similar in ob/ob:GLP-1R(+/+) versus ob/ob:GLP-1R(-/-) mice. Despite evidence linking GLP-1R signaling to the regulation of islet neogenesis and proliferation, ob/ob:GLP-1R(-/-) mice exhibited significantly increased islet numbers and area and an increase in the number of large islets compared with GLP-1R(+/+) or (-/-) mice (P < -0.01 to 0.05). Similarly, growth rates and both shortand long-term control of food intake were comparable in ob/ob:GLP-1R(+/+) versus ob/ob:GLP-1R4(-/-) mice. Furthermore, leptin produced a similar inhibition of food intake in GLP-1R(-/-), ob/ob:GLP-1R(+/+), and ob/ob:GLP1R4(-/-) mice. These findings illustrate that although leptin and GLP-1 actions overlap in the brain and endocrine pancreas, disruption of GLP-1 signaling does not modify the response to leptin or the phenotype of leptin deficiency in the ob/ob mouse, as assessed by long-term control of body weight or the adaptive beta-cell response to insulin resistance in vivo.

Neuroendocrine function and response to stress in mice with complete disruption of glucagon-like peptide-1 receptor signaling.

Glucagon-like peptide-1 (GLP-1), a potent regulator of glucose homeostasis, is also produced in the central nervous system, where GLP-1 has been implicated in the neuroendocrine control of hypothalamic-pituitary function, food intake, and the response to stress. The finding that intracerebroventricular GLP-1 stimulates LH, TSH, corticosterone, and vasopressin secretion in rats prompted us to assess the neuroendocrine consequences of disrupting GLP-1 signaling in mice in vivo. Male GLP-1 receptor knockout (GLP-1R-/-) mice exhibit reduced gonadal weights, and females exhibit a slight delay in the onset of puberty; however, male and female GLP-1R-/- animals reproduce successfully and respond appropriately to fluid restriction. Although adrenal weights are reduced in GLP-1R-/- mice, hypothalamic CRH gene expression and circulating levels of corticosterone, thyroid hormone, testosterone, estradiol, and progesterone are normal in the absence of GLP-1R-/- signaling. Intriguingly, GLP-1R-/- mice exhibit paradoxically increased corticosterone responses to stress as well as abnormal responses to acoustic startle that are corrected by glucocorticoid treatment. These findings suggest that although GLP-1R signaling is not essential for development and basal function of the murine hypothalamic-pituitary-adrenal axis, abrogation of GLP-1 signaling is associated with impairment of the behavioral and neuroendocrine responses to stress.

New developments in the biology of the glucagon-like peptides GLP-1 and GLP-2.

Glucagon-like peptides 1 and 2 (GLP-1 and GLP-2) are coencoded within a single mammalian proglucagon precursor, and are liberated in the intestine and brain. GLP-1 exerts well known actions on islet hormone secretion, gastric emptying, and food intake. Recent studies suggest GLP-1 plays a central role in the development and organization of islet cells. GLP-1 receptor signaling appears essential for beta cell signal transduction as exemplified by studies of GLP-1R-/- mice. GLP-2 promotes energy assimilation via trophic effects on the intestinal mucosa of the small and large bowel epithelium via a recently cloned GLP-2 receptor. The actions of GLP-2 are preserved in the setting of small and large bowel injury and inflammation. The biological actions of the glucagon-like peptides suggest they may have therapeutic efficacy in diabetes (GLP-1) or intestinal disorders (GLP-2).

Altered cAMP and Ca2+ signaling in mouse pancreatic islets with glucagon-like peptide-1 receptor null phenotype.

1-Cells from rodents and humans express different receptors recognizing hormones of the secretin-glucagon family, which--when activated--synergize with glucose in the control of insulin release. We have recently reported that isolated islets from mice homozygous for a GLP-1 receptor null mutation (GLP-1R(-/-)) exhibit a well-preserved insulin-secretory response to glucose. This observation can be interpreted in two different ways: 1) the presence of GLP-1R is not essential for the secretory response of isolated islets to glucose alone; 2) beta-cells in GLP-1R(-/-) pancreases underwent compensatory changes in response to the null mutation. To explore these possibilities, we studied islets from control GLP-IR(+/+) mice in the absence or presence of 1 pmol/l exendin (9-39)amide, a specific and potent GLP-1R antagonist. Exendin (9-39)amide (15-min exposure) reduced glucose-induced insulin secretion from both perifused and statically incubated GLP-1R(+/+) islets by 50% (P < 0.05), and reduced islet cAMP production in parallel (P < 0.001). Furthermore, GLP-1R(-/-) islets exhibited: 1) reduced cAMP accumulation in the presence of 20 mmol/l glucose (knockout islets versus control islets, 12 +/- 1 vs. 27 +/- 3 fmol x islet(-1) x 15 min(-1); P < 0.001) and exaggerated acceleration of cAMP production by 10 nmol/l glucose-dependent insulinotropic peptide (GIP) (increase over 20 mmol/l glucose by GIP in knockout islets versus control islets: 66 +/- 5 vs. 14 +/- 3 fmol x islet(-1) x 15 min(-1); P < 0.001); 2) increased mean cytosolic [Ca2+] ([Ca2+]c) at 7, 10, and 15 mmol/l glucose in knockout islets versus control islets; and 3) signs of asynchrony of [Ca2+]c oscillations between different islet subregions. In conclusion, disruption of GLP-1R signaling is associated with reduced basal but enhanced GIP-stimulated cAMP production and abnormalities in basal and glucose-stimulated [Ca2+]c. These abnormalities suggest that GLP-1R signaling is an essential upstream component of multiple beta-cell signaling pathways.

Exendin-(9-39) is an inverse agonist of the murine glucagon-like peptide-1 receptor: implications for basal intracellular cyclic adenosine 3',5'-monophosphate levels and beta-cell glucose competence.

The effect of exendin-(9-39), a described antagonist of the glucagon-like peptide-1 (GLP-1) receptor, was evaluated on the formation of cAMP- and glucose-stimulated insulin secretion (GSIS) by the conditionally immortalized murine betaTC-Tet cells. These cells have a basal intracellular cAMP level that can be increased by GLP-1 with an EC50 of approximately 1 nM and can be decreased dose dependently by exendin-(9-39). This latter effect was receptor dependent, as a beta-cell line not expressing the GLP-1 receptor was not affected by exendin-(9-39). It was also not due to the endogenous production of GLP-1, because this effect was observed in the absence of detectable preproglucagon messenger RNA levels and radioimmunoassayable GLP-1. Importantly, GSIS was shown to be sensitive to this basal level of cAMP, as perifusion of betaTC-Tet cells in the presence of exendin-(9-39) strongly reduced insulin secretion. This reduction of GSIS, however, was observed only with growth-arrested, not proliferating, betaTC-Tet cells; it was also seen with nontransformed mouse beta-cells perifused in similar conditions. These data therefore demonstrated that 1) exendin-(9-39) is an inverse agonist of the murine GLP-1 receptor; 2) the decreased basal cAMP levels induced by this peptide inhibit the secretory response of betaTC-Tet cells and mouse pancreatic islets to glucose; 3) as this effect was observed only with growth-arrested cells, this indicates that the mechanism by which cAMP leads to potentiation of insulin secretion is different in proliferating and growth-arrested cells; and 4) the presence of the GLP-1 receptor, even in the absence of bound peptide, is important for maintaining elevated intracellular cAMP levels and, therefore, the glucose competence of the beta-cells.

Enhanced glucose-dependent insulinotropic polypeptide secretion and insulinotropic action in glucagon-like peptide 1 receptor -/- mice.

Incretins are gastrointestinal hormones that act on the pancreas to potentiate glucose-stimulated insulin secretion. Despite the physiological importance of the enteroinsular axis, disruption of glucagon-like peptide (GLP)-1 action is associated with only modest glucose intolerance in GLP-1 receptor -/- (GLP-1R -/-) mice. We show here that GLP-1R -/- mice exhibit compensatory changes in the enteroinsular axis via increased glucose-dependent insulinotropic polypeptide (GIP) secretion and enhanced GIP action. Serum GIP levels in GLP-1R -/- mice were significantly elevated versus those in +/+ control mice after an oral glucose tolerance test (369 +/- 40 vs. 236 +/- 28 pmol/l; P < or = 0.02). Furthermore, GIP perfusion of mice pancreas and isolated islets in the presence of elevated glucose concentrations elicited a significantly greater insulin response in GLP-1R -/- than in +/+ mice (P < or = 0.02-0.05). In contrast, no significant perturbation in the insulin response to perfused glucagon was detected under conditions of low (4.4 mmol/l) or high (16.6 mmol/l) glucose in GLP-1R -/- mice. Total pancreatic insulin but not glucagon content was significantly reduced in GLP-1R -/- compared with in +/+ mice (77 +/- 9 vs. 121 +/- 10 pmol/mg protein; P < or = 0.005). These observations suggest that upregulation of the GIP component of the enteroinsular axis, at the levels of GIP secretion and action, modifies the phenotype resulting from interruption of the insulinotropic activity of GLP-1 in vivo.

Effects of aging and a high fat diet on body weight and glucose tolerance in glucagon-like peptide-1 receptor -/- mice.

Disruption of glucagon-like peptide-1 (GLP-1) receptor signaling in mice results in mild glucose intolerance, principally due to elimination of the incretin effect of GLP-1. Despite the inhibitory effects of GLP-1 on food intake, 6- to 8-week-old GLP-1 receptor -/-(GLP-1R-/-) mice were not obese and did not exhibit disturbances of feeding behavior. As both diabetes and obesity frequently become more phenotypically evident in older rodents, we studied the consequences of aging and a high fat diet on glucose control and body weight in GLP-1R-/- mice. No evidence of obesity or deterioration in glucose control was detected in 11- and 16-month-old GLP-1R-/- mice (mean weight, 34.7 +/- 2.0, 30.5 +/- 1.5, and 34.6 +/- 2.8 g in male and 25.3 +/-1.6, 28.4 +/-1.2, and 31.9 +/- 2.9 g in female GLP-1R+/+, GLP-1R+/-, and GLP-1R-/- mice, respectively; P = NS). After 18 weeks of high fat feeding, GLP-1R-/- mice gained similar (males) or less (females) weight than age- and sex-matched CD1 controls. No significant deterioration in glucose tolerance was observed after high fat feeding in GLP-1R-/- mice. These observations demonstrate that long term disruption of GLP-1 signaling in the central nervous system and peripheral tissues of older mice is not associated with the development of obesity or deterioration in glucose homeostasis.

Identification of glucagon-like peptide 1 (GLP-1) actions essential for glucose homeostasis in mice with disruption of GLP-1 receptor signaling.

Glucagon-like peptide-1 (GLP-1) acts to control blood glucose via multiple mechanisms, including regulation of insulin and glucagon secretion, gastric emptying, satiety, and peripheral insulin sensitivity. However, the relative importance of these actions for regulation of blood glucose remains unclear. We demonstrate here a gene dosage effect for the incretin action of GLP-1, as heterozygous GLP-1R +/- mice exhibit an abnormal glycemic response to oral glucose challenge in association with reduced circulating levels of glucose-stimulated insulin. In contrast, GLP-1 signaling is not required for normal control of fasting and postabsorptive glucagon levels, and no significant changes were detected in the tissue content of pancreatic and intestinal proglucagon mRNA, glucagon-like immunoreactivity, or GLP-1 in GLP-1R -/- or +/- mice. Despite the demonstration that GLP-1 stimulates proinsulin gene transcription, pancreatic insulin mRNA transcripts were similar in wild-type and GLP-1R -/- mice. Furthermore, despite suggestions that GLP-1 regulates peripheral glucose disposal, whole-body glucose utilization was similar in wild-type and GLP-1R -/- mice under both basal and hyperinsulinemic conditions. These observations demonstrate that of the numerous physiological activities ascribed to GLP-1, only the incretin effect on pancreatic beta-cells appears essential for regulation of glucose homeostasis in vivo.

Mouse pancreatic beta-cells exhibit preserved glucose competence after disruption of the glucagon-like peptide-1 receptor gene.

Previous work suggested that glucagon-like peptide 1 (GLP-1) can acutely regulate insulin secretion in two ways, 1) by acting as an incretin, causing amplification of glucose-induced insulin release when glucose is given orally as opposed to intravenous glucose injection; and 2) by keeping the beta-cell population in a glucose-competent state. The observation that mice with homozygous disruption of the GLP-1 receptor gene are diabetic with a diminished incretin response to glucose underlines the first function in vivo. Isolated islets of Langerhans from GLP-1 receptor -/- mice were studied to assess the second function in vitro. Absence of pancreatic GLP-1 receptor function was observed in GLP-1 receptor -/- mice, as exemplified by loss of [125I]GLP-1 binding to pancreatic islets in situ and by the lack of GLP-1 potentiation of glucose-induced insulin secretion from perifused islets. Acute glucose competence of the beta-cells, assessed by perifusing islets with stepwise increases of the medium glucose concentration, was well preserved in GLP-1 receptor -/- islets in terms of insulin secretion. Furthermore, neither islet nor total pancreatic insulin content was significantly changed in the GLP-1 receptor -/- mice when compared with age-and sex-matched controls. In conclusion, mouse islets exhibit preserved insulin storage capacity and glucose-dependent insulin secretion despite the loss of functional GLP-1 receptors. The results demonstrate that the glucose responsiveness of islet beta-cells is well preserved in the absence of GLP-1 receptor signaling.

Leptin sensitivity in nonobese glucagon-like peptide I receptor -/- mice.

Glucagon-like peptide I (GLP-I) stimulates glucose-dependent insulin secretion and inhibits food intake in the central nervous system. Because leptin reduces food intake but inhibits insulin secretion, we examined leptin action in mice with a null mutation in the GLP-I receptor. Intracerebroventricular leptin administration inhibited food intake in both wild-type and GLP-I receptor (GLP-IR) -/- mice, and daily intraperitoneal administration of leptin for 2 weeks produced comparable reductions in food intake and body weight in control and GLP-IR -/- mice. Glucose tolerance was improved in both wild-type and GLP-IR -/- mice, whether pair fed or leptin treated; however, blood sugars were significantly lower in the leptin-treated GLP-IR -/- mice following oral glucose challenge (P < 0.01). Glucose-stimulated insulin was reduced in both pair-fed and leptin-treated mice (P < 0.01-0.001); however, insulin levels were significantly lower in leptin-treated versus pair-fed GLP-IR -/- mice (P < 0.01). A single leptin injection had no effect on glucose tolerance in GLP-IR -/- mice, but decreased hepatic PEPCK mRNA in both wild-type and GLP-IR -/- mice. The improvement in blood glucose excursion, despite lower levels of glucose-stimulated insulin in lean leptin-treated GLP-IR -/- mice, suggests that leptin may have beneficial effects on control of blood glucose in the absence of obesity. Furthermore, the greater effects of leptin on glucose and insulin in leptin-treated versus pair-fed GLP-IR -/- mice raises the possibility that disruption of GLP-I signaling modifies the sensitivity to leptin in vivo.

Glucocorticoids induce corticosteroid-binding globulin biosynthesis by immature mouse liver and kidney.

Marked changes in mouse corticosteroid-binding globulin (CBG) gene expression in the liver and kidney occur postnatally. To study the influence of glucocorticoids on the initiation of mouse CBG biosynthesis in these tissues during the first two weeks after birth, we administered dexamethasone (0.5 microgram/g body wt/day) to 4- and 11-day-old pups for three days. This resulted in higher serum CBG and hepatic CBG mRNA levels in animals, irrespective of their ages. Higher relative amounts of CBG mRNA in the kidneys of 14-day-old pups after three days of dexamethasone treatment co-incided with higher amounts of intact and proteolytically cleaved CGB in their urine, and both are indicative of increased CGB production by the developing renal tubules. When an additional group of 11-day-old pups (n = 4) was treated with 0.25 microgram dexamethasone/g body weight per day for five days, this also resulted in significantly higher levels of serum CBG (P < 0.01), hepatic CBG mRNA (P < 0.01) and renal CBG mRNA (P < 0.05), compared to littermates treated with the oil vehicle alone. In contrast, serum CBG levels progressively decreased in adult female mice during five days of treatment with 0.5 microgram dexamethasone/g body weight per day. Taken together, these data indicate that glucocorticoids induce murine CBG gene expression in the immature liver and kidney, and support the concept that the effects of glucocorticoids on CBG gene expression are developmentally stage-specific.

Glucose intolerance but normal satiety in mice with a null mutation in the glucagon-like peptide 1 receptor gene.

Glucagon-like peptide 1 (GLP1) is postulated to regulate blood glucose and satiety, but the biological importance of GLP1 as an incretin and neuropeptide remains controversal. The regulation of nutrient-induced insulin secretion is dependent on the secretion of incretins, gut-derived peptides that potentiate insulin secretion from the pancreatic islets. To ascertain the relative physiological importance of GLP1 as a regulator of feeding behavior and insulin secretion, we have generated mice with a targeted disruption of the GLP1 receptor gene (GLP1R). These GLP1R-/- mice are viable, develop normally but exhibit increased levels of blood glucose following oral glucose challenge in association with diminished levels of circulating insulin. It is surprising that they also exhibit abnormal levels of blood glucose following intraperitoneal glucose challenge. Intracerebroventricular administration of GLP1 inhibited feeding in wild-type mice but not in GLP1R-/- mice; however, no evidence for abnormal body weight or feeding behavior was observed in GLP1R-/- mice. These observations demonstrate that GLP1 plays a central role in the regulation of glycemia; however, disruption of GLP1/GLP1R signaling in the central nervous system is not associated with perturbation of feeding behavior or obesity in vivo.

Corticosteroid-binding globulin biosynthesis in the mouse liver and kidney during postnatal development.

Plasma corticosteroid-binding globulin (CBG) is produced by the liver, but low levels of CBG mRNA have been detected in other tissues, including the kidney. Glucocorticoids influence postnatal renal development in rodents, and CBG production in the kidney may influence the local bioavailability of glucocorticoids. We, therefore, used in situ hybridization and immunohistochemistry to define the sites of CBG biosynthesis during postnatal development and have found that the liver and kidney are major sites of CBG biosynthesis in the first weeks of life. Both CBG and its mRNA were undetectable in the neonatal liver, and only a weak hybridization signal for CBG mRNA was present in the 7-day-old mouse liver. In neonatal mice, the developing tubules of the kidney represent the most active site of CBG biosynthesis, and immunoreactive CBG was also detected in the same cells. By 7 days of age, CBG and its mRNA were colocalized to the proximal convoluted tubules of the juxtamedullary nephrons. The abundance of CBG mRNA in the liver increased from 10 days of age and was accompanied by similar increases in serum CBG until adult levels were reached by 4 weeks of age. In contrast, CBG mRNA in the kidney increased to a maximum during the third week of life, but was undetectable 3 weeks later. The CBG within the proximal convoluted tubules was located in secretory granules close to the luminal surface of the epithelial cells, suggesting that it is secreted into the tubular lumen. Western analysis revealed that marked proteolytic degradation of CBG occurs in the urine concurrently with an increase in CBG biosynthesis in the developing kidney. Thus, the liver is not the only site of CBG biosynthesis in the developing mouse, and CBG production by the epithelial cells of the proximal convoluted tubules may influence glucocorticoid-dependent maturation of the kidney tubules by a process that somehow involves proteolytic degradation.

Spatial and temporal distribution of corticosteroid-binding globulin and its messenger ribonucleic acid in embryonic and fetal mice.

Glucocorticoids influence fetal development, and their actions are regulated by plasma corticosteroid-binding globulin (CBG). Immunohistochemistry and in situ hybridization were, therefore, used to localize CBG and its mRNA in sections of embryonic and fetal mice and their associated placental tissues from day 5 of gestation until term (day 19). In the fetus, CBG mRNA was first detectable in the hepatocytes on day 11 of gestation. The amount of CBG mRNA in these cells increased transiently to a maximum on days 15-16 of gestation and was negligible by day 19. In hepatocytes, CBG immunoreactivity correlated with the distribution and relative abundance of CBG mRNA. The fetal exocrine pancreas also contained CBG mRNA, but this was only present on days 15-16 of gestation, while immunoreactive CBG persisted in these cells until term. Immunoreactive CBG was detected in the tubular cells of the developing fetal kidney as early as day 13, but CBG mRNA was never found in the fetal kidney, suggesting that the protein is probably sequestered from fetal blood directly or via the glomerular filtrate. The placenta contained immunoreactive CBG throughout gestation, even before its detection in fetal tissues, and it was most abundant in the spongiotrophoblasts and the extracellular matrix surrounding fetal and maternal capillaries. However, CBG mRNA was not detected in the placenta at any gestational age. Therefore, CBG present in the placenta is most likely of maternal origin and may influence the activities of steroid hormones that control placental development and/or function. The presence of smaller immunoreactive polypeptides in placental extracts, compared to CBG in corresponding maternal serum samples, suggests that this process may involve an interaction between maternal CBG and placental proteinases. The results presented here suggest that temporal and spatial changes in the localization of CBG and its mRNA in the fetus may influence the effects of steroid hormones on developing tissues.

Alteration of proto-oncogene c-fos expression in neonatal estrogenized BALB/c female mice & murine cervicovaginal tumor LJ6195.

Experiments were performed to determine the effect of neonatal estrogen treatment on the expression of the proto-oncogene c-fos in the BALB/c mouse cervicovaginal tract. Estradiol induces the expression of c-fos in the normal mouse cervicovaginal tract. However, c-fos expression was not stimulated by estradiol in the cervicovaginal tracts of mice that received neonatal estrogen treatment. In addition, the level of expression of c-fos by the estrogen- and progesterone-induced murine cervicovaginal LJ6195 tumor was similar to that in the normal vaginal tract following estradiol stimulation and was not regulated by estradiol.