Hepatocyte growth factor (HGF) is produced in pancreatic mesenchyme-derived cells and in islet cells. In vitro, HGF increases the insulin content and proliferation of islets. To study the role of HGF in the islet in vivo, we have developed three lines of transgenic mice overexpressing mHGF using the rat insulin II promoter (RIP). Each RIP-HGF transgenic line displays clear expression of HGF mRNA and protein in the islet. RIPmHGF mice are relatively hypoglycemic in post-prandial and fasting states compared with their normal littermates. They display inappropriate insulin production, striking overexpression of insulin mRNA in the islet, and a 2-fold increase in the insulin content in islet extracts. Importantly, beta cell replication rates in vivo are two to three times higher in RIP-HGF mice. This increase in proliferation results in a 2-3-fold increase in islet mass. Moreover, the islet number per pancreatic area was also increased by approximately 50%. Finally, RIP-mHGF mice show a dramatically attenuated response to the diabetogenic effects of streptozotocin. We conclude that the overexpression of HGF in the islet increases beta cell proliferation, islet number, beta cell mass, and total insulin production in vivo. These combined effects result in mild hypoglycemia and resistance to the diabetogenic effects of streptozotocin. Hepatocyte growth factor (HGF)1 is a mesenchyme-derived protein originally identified as a circulating factor implicated in liver regeneration after hepatic injury or hepatectomy (1-3). It is now recognized that HGF also exhibits its mitogenic, motogenic, and morphogenic activities in a wide variety of cells (4, 5). The active form of HGF is a disulfide-linked heterodimeric protein, which is composed of a 69-kDa ␣-chain and a 34-kDa -chain, containing four kringle domains and a serine protease-like domain, respectively. Active HGF derives from an inactive single chain precursor that is processed and activated by proteolysis. Four proteases have been reported to date to activate HGF in vitro, including blood coagulation factor XIIa, urokinase, tissue-type plasminogen activator, and a serumderived serine protease named HGF activator (6 -9). HGF is primarily a paracrine factor produced by mesenchymal cells that acts on epithelial cells through a membrane-spanning tyrosine kinase receptor, the protein product of the proto-oncogene, c-met (5, 10, 11). The receptor, like the ligand, has a widespread distribution.Messenger RNAs encoding HGF and the HGF receptor, cmet, are highly expressed during the early development of the pancreas, and then maintained at a low level during puberty and adult life (12)(13)(14). HGF has been detected immunohistochemically in the exocrine portion of rabbit pancreas, and in rat and human pancreatic islet cells (15-17). Tissue-type plasminogen activator has been detected in the rat endocrine pancreas, preferentially in somatostatin cells (18). In addition, confocal immunofluorescent studies have preferentially colocalized the c-Met receptor protein to insulin-conta...
The factors that regulate pancreatic beta cell proliferation are not well defined. In order to explore the role of murine placental lactogen (PL)-I (mPL-I) in islet mass regulation in vivo, we developed transgenic mice in which mPL-I is targeted to the beta cell using the rat insulin II promoter. Rat insulin II-mPL-I mice displayed both fasting and postprandial hypoglycemia (71 and 105 mg/dl, respectively) as compared with normal mice (92 and 129 mg/dl; p < 0.00005 for both). Plasma insulin concentrations were inappropriately elevated, and insulin content in the pancreas was increased 2-fold. Glucose-stimulated insulin secretion by perifused islets was indistinguishable from controls at 7.5, 15, and 20 mM glucose. Beta cell proliferation rates were twice normal (p ؍ 0.0005). This hyperplasia, together with a 20% increase in beta cell size, resulted in a 2-fold increase in islet mass (p ؍ 0.0005) and a 1.45-fold increase in islet number (p ؍ 0.0012). In mice, murine PL-I is a potent islet mitogen, is capable of increasing islet mass, and is associated with hypoglycemia over the long term. It can be targeted to the beta cell using standard gene targeting techniques. Potential exists for beta cell engineering using this strategy.
Introduction: PTH and PTH-related protein (PTHrP) cause primary hyperparathyroidism (HPT) and humoral hypercalcemia of malignancy (HHM), respectively. Whereas HHM and HPT resemble one another in many respects, osteoblastic bone formation and plasma 1,25(OH) 2 vitamin D are increased in HPT but reduced in HHM. Materials and Methods:We performed 2-to 4-day continuous infusions of escalating doses of PTH and PTHrP in 61 healthy young adults, comparing the effects on serum calcium and phosphorus, renal calcium and phosphorus handling, 1,25(OH) 2 vitamin D, endogenous PTH(1-84) concentrations, and plasma IGF-1 and markers of bone turnover. Results: PTH and PTHrP induced comparable effects on renal calcium and phosphorus handling, and both stimulated IGF-1 and bone resorption similarly. Surprisingly, PTH was consistently more calcemic, reflecting a selectively greater increase in renal 1,25(OH) 2 vitamin D production by PTH. Equally surprisingly, continuous infusion of both peptides markedly, continuously, and equivalently suppressed bone formation. Conclusions: PTHrP and PTH produce markedly different effects on 1,25(OH) 2 vitamin D homeostasis in humans, leading to different calcemic responses. Moreover, both peptides produce profound suppression of bone formation over multiple days, contrasting with events in HPT, but mimicking HHM. These findings underscore the facts that the mechanisms underlying the anabolic skeletal response to PTH and PTHrP in humans is poorly understood, as are the signal transduction mechanisms that link the renal PTH receptor to 1,25(OH) 2 vitamin D synthesis. These studies emphasize that much remains to be learned regarding the normal regulation of vitamin D metabolism and bone formation in response to PTH and PTHrP in humans.
The physiological consequences and mechanism(s) for thyroid hormone-induced alterations in serum leptin are not known. To address this, leptin expression in rats was evaluated in relationship to food intake, fat mass, and body temperature in rats with pharmacologically altered thyroid status. Total body weight, food intake, and temperature were decreased in hypothyroid rats. Fat weight was decreased in both chronically hypothyroid and hyperthyroid rats (n = 6/group). Serum leptin was linearly correlated with fat weight, epididymal and retroperitoneal fat leptin mRNA concentration, but not total body weight. Serum leptin was decreased in the chronically hyperthyroid rats. When fat weight was used as a covariant, serum leptin was not different between the three groups. Epididymal fat leptin mRNA was higher in euthyroid (n = 7) than in hypothyroid and hyperthyroid rats. Retroperitoneal fat leptin mRNA was not affected by thyroid status. A positive linear relationship between food intake and free triiodothyronine (FT3) index was observed, but not between food intake and serum leptin alone. In a time course study, serum leptin, epididymal fat leptin mRNA content, and fat weight did not change within 24 hours of high-dose triiodothyronine (T3) (n = 6/group), but both temperature and epididymal fat S14 mRNA content rapidly increased. These findings demonstrate that thyroid state influences circulating leptin levels, but primarily does so indirectly through the regulation of fat mass. Leptin does not influence core body temperature across thyroidal state. Finally, thyroid state is more important to regulate food intake, through an as yet undefined mechanism, than are thyroid state-associated changes in serum leptin.
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