Your search keyword '"Lin HV"' showing total 5 results

1. Proatherogenic abnormalities of lipid metabolism in SirT1 transgenic mice are mediated through Creb deacetylation.

Author

Qiang L, Lin HV, Kim-Muller JY, Welch CL, Gu W, and Accili D

Subjects

Animals, Atherosclerosis genetics, Blotting, Western, Dyslipidemias genetics, Enzyme-Linked Immunosorbent Assay, Glucose metabolism, HEK293 Cells, Humans, Immunohistochemistry, Immunoprecipitation, Insulin Resistance genetics, Lipid Metabolism genetics, Mice, Mice, Transgenic, Phosphorylation, Rats, Real-Time Polymerase Chain Reaction, Atherosclerosis metabolism, Cyclic AMP Response Element-Binding Protein metabolism, Dyslipidemias metabolism, Gene Expression Regulation physiology, Insulin Resistance physiology, Lipid Metabolism physiology, Sirtuin 1 metabolism

Abstract

Dyslipidemia and atherosclerosis are associated with reduced insulin sensitivity and diabetes, but the mechanism is unclear. Gain of function of the gene encoding deacetylase SirT1 improves insulin sensitivity and could be expected to protect against lipid abnormalities. Surprisingly, when transgenic mice overexpressing SirT1 (SirBACO) are placed on atherogenic diet, they maintain better glucose homeostasis, but develop worse lipid profiles and larger atherosclerotic lesions than controls. We show that transcription factor cAMP response element binding protein (Creb) is deacetylated in SirBACO mice. We identify Lys136 is a substrate for SirT1-dependent deacetylation that affects Creb activity by preventing its cAMP-dependent phosphorylation, leading to reduced expression of glucogenic genes and promoting hepatic lipid accumulation and secretion. Expression of constitutively acetylated Creb (K136Q) in SirBACO mice mimics Creb activation and abolishes the dyslipidemic and insulin-sensitizing effects of SirT1 gain of function. We propose that SirT1-dependent Creb deacetylation regulates the balance between glucose and lipid metabolism, integrating fasting signals., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011

2. Genetic and biochemical pathways of beta-cell failure in type 2 diabetes.

Author

Talchai C, Lin HV, Kitamura T, and Accili D

Subjects

Animals, Apoptosis physiology, Cell Count, Cell Proliferation, Cell Survival physiology, Diabetes Mellitus, Type 2 genetics, Hyperplasia genetics, Hyperplasia physiopathology, Insulin biosynthesis, Insulin metabolism, Insulin Receptor Substrate Proteins genetics, Insulin Secretion, Insulin-Secreting Cells pathology, Mice, Signal Transduction physiology, Diabetes Mellitus, Type 2 physiopathology, Insulin Resistance physiology, Insulin-Secreting Cells physiology

Abstract

We review mechanisms of beta-cell failure in type 2 diabetes. A wealth of information indicates that it is caused by impaired insulin secretion and decreased beta-cell mass. Interestingly, there appears to be a link between these two mechanisms. The earliest reaction to peripheral insulin resistance is an increase in insulin production, owing primarily to increased secretion, and to a lesser extent to decreased clearance. Experimental animal models indicate that hyperinsulinaemia promotes an increase in beta-cell mass, largely via increased beta-cell replication. In contrast, following the onset of overt diabetes, there is a slowly progressive loss of beta-cell function and mass, both in animal models and in diabetic humans. It is of great interest that most diabetes-associated genes identified in genome-wide association studies appear to be enriched in the beta-cell and to have the potential to regulate mass and/or function. Here, we review evidence derived from experimental animal models to unravel the mechanisms underlying beta-cell dysfunction. We focus primarily on signalling pathways, as opposed to nutrient sensing, and specifically on the notion that insulin and growth factor signalling via Foxo1 in pancreatic beta-cells links insulin secretion with cellular proliferation and survival.

Published

2009

3. Adiponectin resistance exacerbates insulin resistance in insulin receptor transgenic/knockout mice.

Author

Lin HV, Kim JY, Pocai A, Rossetti L, Shapiro L, Scherer PE, and Accili D

Subjects

AMP-Activated Protein Kinases, Animals, Biomarkers, Blood Glucose metabolism, Disease Susceptibility, Gene Expression Regulation, Glucose Metabolism Disorders metabolism, Glucose Metabolism Disorders pathology, Humans, Insulin blood, Liver drug effects, Liver metabolism, Macrophages drug effects, Macrophages metabolism, Male, Mice, Mice, Transgenic, Multienzyme Complexes metabolism, PPAR alpha metabolism, Phosphorylation drug effects, Protein Serine-Threonine Kinases metabolism, Receptor, Insulin genetics, Receptors, Adiponectin, Receptors, Cell Surface genetics, Systemic Inflammatory Response Syndrome blood, Time Factors, Adiponectin blood, Adiponectin pharmacology, Insulin Resistance, Receptor, Insulin deficiency, Receptor, Insulin metabolism

Abstract

Objective: Adiponectin increases insulin sensitivity and contributes to insulin's indirect effects on hepatic glucose production., Research Design and Methods: To examine adiponectin's contribution to insulin action, we analyzed adiponectin levels and activation of AMP-activated protein kinase (AMPK) in insulin receptor transgenic/knockout mice (L1), a genetic model of resistance to insulin's indirect effects on hepatic glucose production., Results: In euglycemic, insulin-resistant L1 mice, we detected hyperadiponectinemia with normal levels of adiponectin receptor-1 and -2. Moreover, adiponectin administration is unable to lower glucose levels or induce activation of AMPK, consistent with a state of adiponectin resistance. In a subset of hyperglycemic L1 mice, we observed decreased mRNA expression of AdipoR2 in liver and muscle, as well as decreased peroxisome proliferator-activated receptor (PPAR)alpha target gene expression in liver, raising the possibility that deterioration of adiponectin/AdipoR2 signaling via PPARalpha activation contributes to the progression from compensated insulin resistance to diabetes. In contrast, we failed to detect changes in other markers of the systemic or local inflammatory response., Conclusions: These data provide evidence for a mechanism of adiponectin resistance and corroborate the notion that adiponectin potentiates hepatic insulin sensitivity.

Published

2007

4. Role of the forkhead protein FoxO1 in beta cell compensation to insulin resistance.

Author

Okamoto H, Hribal ML, Lin HV, Bennett WR, Ward A, and Accili D

Subjects

Animals, Diabetes Mellitus genetics, Disease Models, Animal, Forkhead Box Protein O1, Forkhead Transcription Factors genetics, Insulin-Like Growth Factor II genetics, Insulin-Like Growth Factor II metabolism, Mice, Mice, Inbred C57BL, Mice, Knockout, Mice, Transgenic, Receptor, Insulin deficiency, Receptor, Insulin genetics, Forkhead Transcription Factors physiology, Insulin Resistance physiology, Insulin-Secreting Cells metabolism

Abstract

Diabetes is associated with defective beta cell function and altered beta cell mass. The mechanisms regulating beta cell mass and its adaptation to insulin resistance are unknown. It is unclear whether compensatory beta cell hyperplasia is achieved via proliferation of existing beta cells or neogenesis from progenitor cells embedded in duct epithelia. We have used transgenic mice expressing a mutant form of the forkhead-O1 transcription factor (FoxO1) in both pancreatic ductal and endocrine beta cells to assess the contribution of these 2 compartments to islet expansion. We show that the mutant FoxO1 transgene prevents beta cell replication in 2 models of beta cell hyperplasia, 1 due to peripheral insulin resistance (Insulin receptor transgenic knockouts) and 1 due to ectopic local expression of IGF2 (Elastase-IGF2 transgenics), without affecting insulin secretion. In contrast, we failed to detect a specific effect of the FoxO1 transgene on the number of periductal beta cells. We propose that beta cell compensation to insulin resistance is a proliferative response of existing beta cells to growth factor signaling and requires FoxO1 nuclear exclusion.

Published

2006

5. Agonists at GPR119 mediate secretion of GLP-1 from mouse enteroendocrine cells through glucose-independent pathways.

Author

Lan, H, Lin, HV, Wang, CF, Wright, MJ, Xu, S, Kang, L, Juhl, K, Hedrick, JA, and Kowalski, TJ

Subjects

*G proteins, *ENDOCRINE glands, *BLOOD sugar, *INSULIN resistance, *PANCREATIC beta cells, *GLUCAGON-like peptide 1, *LABORATORY mice

Abstract

BACKGROUND AND PURPOSE The G protein-coupled receptor 119 (GPR119) mediates insulin secretion from pancreatic β cells and glucagon-like peptide 1 (GLP-1) release from intestinal L cells. While GPR119-mediated insulin secretion is glucose dependent, it is not clear whether or not GPR119-mediated GLP-1 secretion similarly requires glucose. This study was designed to address the glucose-dependence of GPR119-mediated GLP-1 secretion, and to explore the cellular mechanisms of hormone secretion in L cells versus those in β cells. EXPERIMENTAL APPROACH GLP-1 secretion in response to GPR119 agonists and ion channel modulators, with and without glucose, was analysed in the intestinal L cell line GLUTag, in primary intestinal cell cultures and in vivo. Insulin secretion from Min6 cells, a pancreatic β cell line, was analysed for comparison. KEY RESULTS In GLUTag cells, GPR119 agonists stimulated GLP-1 secretion both in the presence and in the absence of glucose. In primary mouse colon cultures, GPR119 agonists stimulated GLP-1 secretion under glucose-free conditions. Moreover, a GPR119 agonist increased plasma GLP-1 in mice without a glucose load. However, in Min6 cells, GPR119-mediated insulin secretion was glucose-dependent. Among the pharmacological agents tested in this study, nitrendipine, an L-type voltage-dependent calcium channel blocker, dose-dependently reduced GLP-1 secretion from GLUTag cells, but had no effect in Min6 cells in the absence of glucose. CONCLUSIONS AND IMPLICATIONS Unlike that in pancreatic β cells, GPR119-mediated GLP-1 secretion from intestinal L cells was glucose-independent in vitro and in vivo, probably because of a higher basal calcium tone in the L cells. [ABSTRACT FROM AUTHOR]

Published

2012