The peroxisome proliferator-activated receptors (PPARalpha, gamma, delta) are members of the nuclear receptor superfamily of ligand-activated transcription factors that have central roles in the storage and catabolism of fatty acids. Although the three PPAR subtypes are closely related and bind to similar DNA response elements as heterodimers with the 9-cis retinoic acid receptor RXR, each subserves a distinct physiology. PPARalpha (NR1C1) is the receptor for the fibrate drugs, which are widely used to lower triglycerides and raise high-density lipoprotein cholesterol levels in the treatment and prevention of coronary artery disease. In rodents, PPARalpha agonists induce hepatomegaly and stimulate a dramatic proliferation of peroxisomes as part of a coordinated physiological response to lipid overload. PPARgamma (NR1C3) plays a critical role in adipocyte differentiation and serves as the receptor for the glitazone class of insulin-sensitizing drugs used in the treatment of type 2 diabetes. In contrast to PPARalpha and PPARgamma, relatively little is known about the biology of PPARdelta (NR1C2), although recent findings suggest that this subtype also has a role in lipid homeostasis. All three PPARs are activated by naturally occurring fatty acids and fatty acid metabolites, indicating that they function as the body's fatty acid sensors. Three-dimensional crystal structures reveal that the ligand-binding pockets of the PPARs are much larger and more accessible than those of other nuclear receptors, providing a molecular basis for the promiscuous ligand-binding properties of these receptors. Given the fundamental roles that the PPARs play in energy balance, drugs that modulate PPAR activity are likely to be useful for treating a wide range of metabolic disorders, including atherosclerosis, dyslipidemia, obesity, and type 2 diabetes.
{"title":"Peroxisome proliferator-activated receptors: from genes to physiology.","authors":"S. Kliewer, H. Xu, M. Lambert, T. Willson","doi":"10.1210/RP.56.1.239","DOIUrl":"https://doi.org/10.1210/RP.56.1.239","url":null,"abstract":"The peroxisome proliferator-activated receptors (PPARalpha, gamma, delta) are members of the nuclear receptor superfamily of ligand-activated transcription factors that have central roles in the storage and catabolism of fatty acids. Although the three PPAR subtypes are closely related and bind to similar DNA response elements as heterodimers with the 9-cis retinoic acid receptor RXR, each subserves a distinct physiology. PPARalpha (NR1C1) is the receptor for the fibrate drugs, which are widely used to lower triglycerides and raise high-density lipoprotein cholesterol levels in the treatment and prevention of coronary artery disease. In rodents, PPARalpha agonists induce hepatomegaly and stimulate a dramatic proliferation of peroxisomes as part of a coordinated physiological response to lipid overload. PPARgamma (NR1C3) plays a critical role in adipocyte differentiation and serves as the receptor for the glitazone class of insulin-sensitizing drugs used in the treatment of type 2 diabetes. In contrast to PPARalpha and PPARgamma, relatively little is known about the biology of PPARdelta (NR1C2), although recent findings suggest that this subtype also has a role in lipid homeostasis. All three PPARs are activated by naturally occurring fatty acids and fatty acid metabolites, indicating that they function as the body's fatty acid sensors. Three-dimensional crystal structures reveal that the ligand-binding pockets of the PPARs are much larger and more accessible than those of other nuclear receptors, providing a molecular basis for the promiscuous ligand-binding properties of these receptors. Given the fundamental roles that the PPARs play in energy balance, drugs that modulate PPAR activity are likely to be useful for treating a wide range of metabolic disorders, including atherosclerosis, dyslipidemia, obesity, and type 2 diabetes.","PeriodicalId":21099,"journal":{"name":"Recent progress in hormone research","volume":"63 1","pages":"239-63"},"PeriodicalIF":0.0,"publicationDate":"2001-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"80123242","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
K(ATP) channels are a unique, small family of potassium (K+)-selective ion channels assembled from four inward rectifier pore-forming subunits, K(IR)6.x, paired with four sulfonylurea receptors (SURs), members of the adenosine triphosphate (ATP)-binding cassette superfamily. The activity of these channels can be regulated by metabolically driven changes in the ratio of adenosine diphosphate (ADP) to ATP, providing a means to couple membrane electrical activity with metabolism. In pancreatic beta cells in the islets of Langerhans, K(ATP) channels are part of an ionic mechanism that couples glucose metabolism to insulin secretion. This chapter 1) briefly describes the properties of K(ATP) channels; 2) discusses data on a genetically recessive form of persistent hyperinsulinemic hypoglycemia of infancy (PHHI), caused by loss of beta-cell K(ATP) channel activity; and 3) compares the severe impairment of glucose homeostasis that characterizes the human phenotype with the near-normal phenotype observed in K(ATP) channel null mice.
{"title":"Of mice and men: K(ATP) channels and insulin secretion.","authors":"L. Aguilar-Bryan, J. Bryan, M. Nakazaki","doi":"10.1210/RP.56.1.47","DOIUrl":"https://doi.org/10.1210/RP.56.1.47","url":null,"abstract":"K(ATP) channels are a unique, small family of potassium (K+)-selective ion channels assembled from four inward rectifier pore-forming subunits, K(IR)6.x, paired with four sulfonylurea receptors (SURs), members of the adenosine triphosphate (ATP)-binding cassette superfamily. The activity of these channels can be regulated by metabolically driven changes in the ratio of adenosine diphosphate (ADP) to ATP, providing a means to couple membrane electrical activity with metabolism. In pancreatic beta cells in the islets of Langerhans, K(ATP) channels are part of an ionic mechanism that couples glucose metabolism to insulin secretion. This chapter 1) briefly describes the properties of K(ATP) channels; 2) discusses data on a genetically recessive form of persistent hyperinsulinemic hypoglycemia of infancy (PHHI), caused by loss of beta-cell K(ATP) channel activity; and 3) compares the severe impairment of glucose homeostasis that characterizes the human phenotype with the near-normal phenotype observed in K(ATP) channel null mice.","PeriodicalId":21099,"journal":{"name":"Recent progress in hormone research","volume":"49 1","pages":"47-68"},"PeriodicalIF":0.0,"publicationDate":"2001-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"77733928","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Mutations in the glucokinase (GK) gene cause two different diseases of blood glucose regulation: maturity onset diabetes of the young, type 2 (MODY-2) and persistent hyperinsulinemic hypoglycemia of infancy (PHHI). To gain further understanding of the pathophysiology of these disorders, we have used both transgenic and gene-targeting strategies to explore the relationship between GK gene expression in specific tissues and the blood glucose concentration. These studies, which have included the use of aCre/loxP gene-targeting strategy to perform both pancreatic beta-cell- and hepatocyte-specific knockouts of GK, clearly demonstrate multiple, cell-specific roles for this hexokinase that, together, contribute to the maintainance of euglycemia. In the pancreatic beta cell, GK functions as the glucose sensor, determining the threshold for insulin secretion. Mice lacking GK in the pancreatic beta cell die within 3 days of birth of profound hyperglycemia. In the liver, GK facilitates hepatic glucose uptake during hyperglycemia and is essential for the appropriate regulation of a network of glucose-responsive genes. While mice lacking hepatic GK are viable, and are only mildly hyperglycemic when fasted, they also have impaired insulin secretion in response to hyperglycemia. The mechanisms that enable hepatic GK to affect beta-cell function are not yet understood. Thus, the hyperglycemia that occurs in MODY-2 is due to impaired GK function in both the liver and pancreatic beta cell, although the defect in beta-cell function is clearly more dominant. Whether defects in GK gene expression also impair glucose sensing by neurons in the brain or enteroendocrine cells in gut, two other sites known to express GK, remains to be determined. Moreover, whether the pathophysiology of PHHI also involves multitissue dysfunction remains to be explored.
{"title":"Cell-specific roles of glucokinase in glucose homeostasis.","authors":"Catherine Postic, Masakazli Shiota, M. Magnuson","doi":"10.1210/RP.56.1.195","DOIUrl":"https://doi.org/10.1210/RP.56.1.195","url":null,"abstract":"Mutations in the glucokinase (GK) gene cause two different diseases of blood glucose regulation: maturity onset diabetes of the young, type 2 (MODY-2) and persistent hyperinsulinemic hypoglycemia of infancy (PHHI). To gain further understanding of the pathophysiology of these disorders, we have used both transgenic and gene-targeting strategies to explore the relationship between GK gene expression in specific tissues and the blood glucose concentration. These studies, which have included the use of aCre/loxP gene-targeting strategy to perform both pancreatic beta-cell- and hepatocyte-specific knockouts of GK, clearly demonstrate multiple, cell-specific roles for this hexokinase that, together, contribute to the maintainance of euglycemia. In the pancreatic beta cell, GK functions as the glucose sensor, determining the threshold for insulin secretion. Mice lacking GK in the pancreatic beta cell die within 3 days of birth of profound hyperglycemia. In the liver, GK facilitates hepatic glucose uptake during hyperglycemia and is essential for the appropriate regulation of a network of glucose-responsive genes. While mice lacking hepatic GK are viable, and are only mildly hyperglycemic when fasted, they also have impaired insulin secretion in response to hyperglycemia. The mechanisms that enable hepatic GK to affect beta-cell function are not yet understood. Thus, the hyperglycemia that occurs in MODY-2 is due to impaired GK function in both the liver and pancreatic beta cell, although the defect in beta-cell function is clearly more dominant. Whether defects in GK gene expression also impair glucose sensing by neurons in the brain or enteroendocrine cells in gut, two other sites known to express GK, remains to be determined. Moreover, whether the pathophysiology of PHHI also involves multitissue dysfunction remains to be explored.","PeriodicalId":21099,"journal":{"name":"Recent progress in hormone research","volume":"68 1","pages":"195-217"},"PeriodicalIF":0.0,"publicationDate":"2001-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"90288917","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Insulin is the most-potent physiological anabolic agent known, promoting the synthesis and storage of carbohydrates and lipids and inhibiting their degradation and release into the circulation. This action of the hormone is due in part to the acute regulation of metabolic enzymes through changes in their phosphorylation state. In fat, liver, and muscle, insulin stimulates the dephosphorylation of a number of enzymes involved in glycogen and lipid metabolism via activation of protein phosphatases. Numerous studies have indicated that protein phosphatase-1 (PP1) is the primary phosphatase involved in insulin action. Although PP1 is a cytosolic protein, the phosphatase is compartmentalized in cells by discrete targeting subunits. These proteins confer substrate specificity to PP1 and mediate the specific regulation of intracellular pools of PP1 by a variety of extracellular signals. Four proteins have been described that target the phosphatase to the glycogen particle. G(M) and GL are expressed exclusively in striated muscle and liver, while protein targeting to glycogen (PTG) and R6 are more widely expressed. Despite a common targeting function, these four proteins are not highly conserved, suggesting profound differences in the mechanisms by which they contribute to the hormonal regulation of PP1 activity. Overexpression studies in cell lines or animals have revealed major differences among these proteins regarding basal glycogen levels and hormonal responsiveness. Furthermore, alterations in the expression or function of PP1 glycogen-targeting subunits may contribute to the onset of insulin resistance and type 2 diabetes.
{"title":"The role of protein phosphatase-1 in insulin action.","authors":"Matthew J. Brady, A. Saltiel","doi":"10.1210/RP.56.1.157","DOIUrl":"https://doi.org/10.1210/RP.56.1.157","url":null,"abstract":"Insulin is the most-potent physiological anabolic agent known, promoting the synthesis and storage of carbohydrates and lipids and inhibiting their degradation and release into the circulation. This action of the hormone is due in part to the acute regulation of metabolic enzymes through changes in their phosphorylation state. In fat, liver, and muscle, insulin stimulates the dephosphorylation of a number of enzymes involved in glycogen and lipid metabolism via activation of protein phosphatases. Numerous studies have indicated that protein phosphatase-1 (PP1) is the primary phosphatase involved in insulin action. Although PP1 is a cytosolic protein, the phosphatase is compartmentalized in cells by discrete targeting subunits. These proteins confer substrate specificity to PP1 and mediate the specific regulation of intracellular pools of PP1 by a variety of extracellular signals. Four proteins have been described that target the phosphatase to the glycogen particle. G(M) and GL are expressed exclusively in striated muscle and liver, while protein targeting to glycogen (PTG) and R6 are more widely expressed. Despite a common targeting function, these four proteins are not highly conserved, suggesting profound differences in the mechanisms by which they contribute to the hormonal regulation of PP1 activity. Overexpression studies in cell lines or animals have revealed major differences among these proteins regarding basal glycogen levels and hormonal responsiveness. Furthermore, alterations in the expression or function of PP1 glycogen-targeting subunits may contribute to the onset of insulin resistance and type 2 diabetes.","PeriodicalId":21099,"journal":{"name":"Recent progress in hormone research","volume":"12 1","pages":"157-73"},"PeriodicalIF":0.0,"publicationDate":"2001-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"84498662","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Biological amines react with reducing sugars to form a complex family of rearranged and dehydrated covalent adducts that are often yellow-brown and/or fluorescent and include many cross-linked structures. Food chemists have long studied this process as a source of flavor, color, and texture changes in cooked, processed, and stored foods. During the 1970s and 1980s, it was realized that this process, called the Maillard reaction or advanced glycation, also occurs slowly in vivo. Advanced glycation endproducts (AGEs) that form are implicated, causing the complications of diabetes and aging, primarily via adventitious and crosslinking of proteins. Long-lived proteins such as structural collagen and lens crystallins particularly are implicated as pathogenic targets of AGE processes. AGE formation in vascular wall collagen appears to be an especially deleterious event, causing crosslinking of collagen molecules to each other and to circulating proteins. This leads to plaque formation, basement membrane thickening, and loss of vascular elasticity. The chemistry of these later-stage, glycation-derived crosslinks is still incompletely understood but, based on the hypothesis that AGE formation involves reactive carbonyl groups, the authors introduced the carbonyl reagent aminoguanidine hydrochloride as an inhibitor of AGE formation in vivo in the mid 1980s. Subsequent studies by many researchers have shown the effectiveness of aminoguanidine in slowing or preventing a wide range of complications of diabetes and aging in animals and, recently, in humans. Since, the authors have developed a new class of agents, exemplified by 4,5-dimethyl-3-phenacylthiazolium chloride (DPTC), which can chemically break already-formed AGE protein-protein crosslinks. These agents are based on a new theory of AGE crosslinking that postulates that alpha-dicarbonyl structures are present in AGE protein-protein crosslinks. In studies in aged animals, DPTC has been shown to be capable of reverting indices of vascular compliance to levels seen in younger animals. Human clinical trials are underway.
{"title":"Protein glycation, diabetes, and aging.","authors":"P. Ulrich, A. Cerami","doi":"10.1210/RP.56.1.1","DOIUrl":"https://doi.org/10.1210/RP.56.1.1","url":null,"abstract":"Biological amines react with reducing sugars to form a complex family of rearranged and dehydrated covalent adducts that are often yellow-brown and/or fluorescent and include many cross-linked structures. Food chemists have long studied this process as a source of flavor, color, and texture changes in cooked, processed, and stored foods. During the 1970s and 1980s, it was realized that this process, called the Maillard reaction or advanced glycation, also occurs slowly in vivo. Advanced glycation endproducts (AGEs) that form are implicated, causing the complications of diabetes and aging, primarily via adventitious and crosslinking of proteins. Long-lived proteins such as structural collagen and lens crystallins particularly are implicated as pathogenic targets of AGE processes. AGE formation in vascular wall collagen appears to be an especially deleterious event, causing crosslinking of collagen molecules to each other and to circulating proteins. This leads to plaque formation, basement membrane thickening, and loss of vascular elasticity. The chemistry of these later-stage, glycation-derived crosslinks is still incompletely understood but, based on the hypothesis that AGE formation involves reactive carbonyl groups, the authors introduced the carbonyl reagent aminoguanidine hydrochloride as an inhibitor of AGE formation in vivo in the mid 1980s. Subsequent studies by many researchers have shown the effectiveness of aminoguanidine in slowing or preventing a wide range of complications of diabetes and aging in animals and, recently, in humans. Since, the authors have developed a new class of agents, exemplified by 4,5-dimethyl-3-phenacylthiazolium chloride (DPTC), which can chemically break already-formed AGE protein-protein crosslinks. These agents are based on a new theory of AGE crosslinking that postulates that alpha-dicarbonyl structures are present in AGE protein-protein crosslinks. In studies in aged animals, DPTC has been shown to be capable of reverting indices of vascular compliance to levels seen in younger animals. Human clinical trials are underway.","PeriodicalId":21099,"journal":{"name":"Recent progress in hormone research","volume":"102 1","pages":"1-21"},"PeriodicalIF":0.0,"publicationDate":"2001-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"88119212","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Type 1A diabetes is an autoimmune disease with genetic and environmental factors contributing to its etiology. Twin studies, family studies, and animal models have helped to elucidate the genetics of autoimmune diabetes. Most of the genetic susceptibility is accounted for by human leukocyte antigen (HLA) alleles. The most-common susceptibility haplotypes are DQA1*0301-DQB1*0302 and DQA1*0501-DQB1*0201. Less-common haplotypes such as DQA1*0401-DQB1*0402 and DQA1*0101-DQB1*0501 are associated with high risk for diabetes; however, large study populations are needed to analyze their effect. The DQA1*0102-DQB1*0602 haplotype is associated with diabetes resistance. DR molecules, such as DRB1*1401, confer protection from diabetes. Monozygotic twins of patients with type 1A diabetes have a diabetes risk higher than that for HLA-identical ordinary siblings, suggesting that non-HLA genes contribute to diabetes risk. Polymorphisms in the regulatory region of the insulin gene (designated IDDM2), polymorphisms in cytotoxic T lymphocyte antigen-4 (CTLA-4) gene (IDDM12), and other genes are likely to contribute to diabetes risk and susceptibility in some individuals. In selected families, major diabetogenes (e.g., IDDM17, autoimmune regulator gene (AIRE)) are likely to be of importance. Other factors--either noninherited genes (i.e., somatic mutations and T-cell receptor or immunoglobulin rearrangements) or environment--may have a role in progression to diabetes. This is suggested by the finding that the risk for monozygotic twins of patients with type 1A diabetes is not 100 percent. Studying the genetics of type 1A diabetes will allow us to better define this disease, to improve our ability to identify individuals at risk, and to predict the risk of associated disorders.
{"title":"Genetics of type 1A diabetes.","authors":"M. Redondo, P. Fain, G. Eisenbarth","doi":"10.1210/RP.56.1.69","DOIUrl":"https://doi.org/10.1210/RP.56.1.69","url":null,"abstract":"Type 1A diabetes is an autoimmune disease with genetic and environmental factors contributing to its etiology. Twin studies, family studies, and animal models have helped to elucidate the genetics of autoimmune diabetes. Most of the genetic susceptibility is accounted for by human leukocyte antigen (HLA) alleles. The most-common susceptibility haplotypes are DQA1*0301-DQB1*0302 and DQA1*0501-DQB1*0201. Less-common haplotypes such as DQA1*0401-DQB1*0402 and DQA1*0101-DQB1*0501 are associated with high risk for diabetes; however, large study populations are needed to analyze their effect. The DQA1*0102-DQB1*0602 haplotype is associated with diabetes resistance. DR molecules, such as DRB1*1401, confer protection from diabetes. Monozygotic twins of patients with type 1A diabetes have a diabetes risk higher than that for HLA-identical ordinary siblings, suggesting that non-HLA genes contribute to diabetes risk. Polymorphisms in the regulatory region of the insulin gene (designated IDDM2), polymorphisms in cytotoxic T lymphocyte antigen-4 (CTLA-4) gene (IDDM12), and other genes are likely to contribute to diabetes risk and susceptibility in some individuals. In selected families, major diabetogenes (e.g., IDDM17, autoimmune regulator gene (AIRE)) are likely to be of importance. Other factors--either noninherited genes (i.e., somatic mutations and T-cell receptor or immunoglobulin rearrangements) or environment--may have a role in progression to diabetes. This is suggested by the finding that the risk for monozygotic twins of patients with type 1A diabetes is not 100 percent. Studying the genetics of type 1A diabetes will allow us to better define this disease, to improve our ability to identify individuals at risk, and to predict the risk of associated disorders.","PeriodicalId":21099,"journal":{"name":"Recent progress in hormone research","volume":"76 1","pages":"69-89"},"PeriodicalIF":0.0,"publicationDate":"2001-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"89141723","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
The beta-adrenergic receptors (betaARs) are members of the large family of G protein-coupled receptors. There are three betaAR subtypes (beta1AR, beta2AR beta3AR), each of which is coupled to Galphas and the stimulation of intracellular cAMP levels. While beta1AR and beta2AR are broadly expressed throughout tissues of the body, beta3AR is found predominantly in adipocytes. Stimulation of the betaARs leads to lipolysis in white adipocytes and nonshivering thermogenesis in brown fat. However, in essentially all animal models of obesity, the betaAR system is dysfunctional and the ability to stimulate lipolysis and thermogenesis is impaired. Nevertheless, we and others have shown that selective beta3AR agonists are able to prevent or reverse obesity and the loss of betaAR expression and to stimulate thermogenesis. This chapter will review the current understanding of the role of the sympathetic nervous system and the adipocyte betaARs in models of obesity; the physiologic impact of changes in betaAR expression on body composition and thermogenesis; and the regulation and unique properties of betaAR subtypes in brown and white adipocytes. The latter includes our recent discovery of novel signal transduction mechanisms utilized by beta3AR to activate simultaneously the protein kinase A and MAP kinase pathways. The impact of understanding these pathways and their potential role in modulating adaptive thermogenesis is discussed.
{"title":"The beta-adrenergic receptors and the control of adipose tissue metabolism and thermogenesis.","authors":"Sheila Collins, R. Surwit","doi":"10.1210/RP.56.1.309","DOIUrl":"https://doi.org/10.1210/RP.56.1.309","url":null,"abstract":"The beta-adrenergic receptors (betaARs) are members of the large family of G protein-coupled receptors. There are three betaAR subtypes (beta1AR, beta2AR beta3AR), each of which is coupled to Galphas and the stimulation of intracellular cAMP levels. While beta1AR and beta2AR are broadly expressed throughout tissues of the body, beta3AR is found predominantly in adipocytes. Stimulation of the betaARs leads to lipolysis in white adipocytes and nonshivering thermogenesis in brown fat. However, in essentially all animal models of obesity, the betaAR system is dysfunctional and the ability to stimulate lipolysis and thermogenesis is impaired. Nevertheless, we and others have shown that selective beta3AR agonists are able to prevent or reverse obesity and the loss of betaAR expression and to stimulate thermogenesis. This chapter will review the current understanding of the role of the sympathetic nervous system and the adipocyte betaARs in models of obesity; the physiologic impact of changes in betaAR expression on body composition and thermogenesis; and the regulation and unique properties of betaAR subtypes in brown and white adipocytes. The latter includes our recent discovery of novel signal transduction mechanisms utilized by beta3AR to activate simultaneously the protein kinase A and MAP kinase pathways. The impact of understanding these pathways and their potential role in modulating adaptive thermogenesis is discussed.","PeriodicalId":21099,"journal":{"name":"Recent progress in hormone research","volume":"6 1","pages":"309-28"},"PeriodicalIF":0.0,"publicationDate":"2001-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"80224416","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
The pancreas is essential for digestion and glucose homeostasis. Diseases associated with the pancreas (e.g., pancreatitis, pancreatic cancer, diabetes) are generally debilitating for the patient. Diabetes is particularly prominent in the United States, affecting nearly 6 percent of the population, with associated annual health costs in the billions of dollars. Pancreas development is a complex process that requires the timely expression of numerous factors. Among them, a basic Helix-Loop-Helix factor, BETA2, was shown to be important for terminal differentiation of islet cells including insulin- and glucagon-producing cells. Expression studies demonstrated the presence of BETA2 in islet cells and specific neurons. Targeted deletion of the BETA2 gene in mice revealed its significance in pancreas development. In addition, BETA2 is important in granule cell development of the hippocampus and cerebellum. This chapter will focus on the role of BETA2 in pancreas physiology, neuronal development, and its molecular biology.
{"title":"BETA2 and pancreatic islet development.","authors":"K. Chu, E. Némoz-Gaillard, T. Mj","doi":"10.1210/RP.56.1.23","DOIUrl":"https://doi.org/10.1210/RP.56.1.23","url":null,"abstract":"The pancreas is essential for digestion and glucose homeostasis. Diseases associated with the pancreas (e.g., pancreatitis, pancreatic cancer, diabetes) are generally debilitating for the patient. Diabetes is particularly prominent in the United States, affecting nearly 6 percent of the population, with associated annual health costs in the billions of dollars. Pancreas development is a complex process that requires the timely expression of numerous factors. Among them, a basic Helix-Loop-Helix factor, BETA2, was shown to be important for terminal differentiation of islet cells including insulin- and glucagon-producing cells. Expression studies demonstrated the presence of BETA2 in islet cells and specific neurons. Targeted deletion of the BETA2 gene in mice revealed its significance in pancreas development. In addition, BETA2 is important in granule cell development of the hippocampus and cerebellum. This chapter will focus on the role of BETA2 in pancreas physiology, neuronal development, and its molecular biology.","PeriodicalId":21099,"journal":{"name":"Recent progress in hormone research","volume":"145 1","pages":"23-46"},"PeriodicalIF":0.0,"publicationDate":"2001-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"80480407","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Insulin elicits diverse biological responses in many tissues and cell types by binding to its specific receptor. The insulin receptor (IR) is a tetramer consisting of two extracellular alpha subunits and two membrane-spanning beta subunits. The binding of insulin to the receptor causes conformational changes that lead to autophosphorylation and activation of the tyrosine kinase intrinsic to the beta subunits. Insulin receptor transphosphorylates several immediate substrates, resulting in modulation of a cascade of downstream signal transduction molecules. In order to discover small molecules that activate the human insulin receptor tyrosine kinase (IRTK), a cell-based assay was established and utilized to screen a collection of synthetic chemicals and natural product extracts. This effort led to the identification of a nonpeptidyl, small molecule, insulin-mimetic compound (demethylasterriquinone B-1, DMAQ-B1) that was isolated from a mixture of metabolites produced by a tropical endophytic fungus, Pseudomassaria sp. This compound induced human IRTK activation and increased tyrosine phosphorylation of IR beta subunit. It mediated insulin-like effects, including insulin receptor substrate-1 (IRS-1) phosphorylation and activation of phosphotidylinositide 3-kinase and Akt kinase. DMAQ-B1 also exhibited an insulin-like effect on glucose uptake in adipocytes and skeletal muscle tissue. Furthermore, the compound was relatively selective for IR vs. insulin-like growth factor-I (IGF-I) receptor and other homologous receptor tyrosine kinases. In addition, it activated partially purified native IR or recombinant IR kinase, demonstrating the direct interaction of the small molecule with the IR. Oral administration of DMAQ-B1 resulted in significant glucose lowering in two mouse models of diabetes. Thus, DMAQ-B1 represents the first orally active insulin-mimetic agent. Pharmaceutical intervention aimed at augmenting IR function ultimately may prove beneficial as a novel therapeutic option in patients with diabetes.
胰岛素通过与其特定受体的结合,在许多组织和细胞类型中引发多种生物反应。胰岛素受体(IR)是由两个细胞外α亚基和两个跨膜β亚基组成的四聚体。胰岛素与受体的结合引起构象变化,导致β亚基固有的自磷酸化和酪氨酸激酶的激活。胰岛素受体转磷酸化几个直接底物,导致下游信号转导分子级联的调节。为了发现激活人胰岛素受体酪氨酸激酶(IRTK)的小分子,建立了一种基于细胞的检测方法,并用于筛选一系列合成化学品和天然产物提取物。研究人员从热带内生真菌Pseudomassaria sp产生的代谢物混合物中分离出了一种非肽基、小分子、模拟胰岛素的化合物(demethylasterriquinone B-1, DMAQ-B1)。该化合物可诱导人IRTK激活并增加IR β亚基的酪氨酸磷酸化。它介导胰岛素样效应,包括胰岛素受体底物-1 (IRS-1)的磷酸化和磷脂酰肌苷3激酶和Akt激酶的激活。DMAQ-B1对脂肪细胞和骨骼肌组织的葡萄糖摄取也表现出胰岛素样的作用。此外,该化合物对胰岛素样生长因子- i (IGF-I)受体和其他同源受体酪氨酸激酶具有相对的选择性。此外,它激活了部分纯化的天然IR或重组IR激酶,证明了小分子与IR的直接相互作用。口服DMAQ-B1可显著降低两种糖尿病小鼠的血糖。因此,DMAQ-B1代表了第一种口服活性胰岛素模拟剂。旨在增强IR功能的药物干预最终可能被证明是糖尿病患者的一种新的治疗选择。
{"title":"Discovery of a small molecule insulin receptor activator.","authors":"G. Salituro, F. Pelaez, B. Zhang","doi":"10.1210/RP.56.1.107","DOIUrl":"https://doi.org/10.1210/RP.56.1.107","url":null,"abstract":"Insulin elicits diverse biological responses in many tissues and cell types by binding to its specific receptor. The insulin receptor (IR) is a tetramer consisting of two extracellular alpha subunits and two membrane-spanning beta subunits. The binding of insulin to the receptor causes conformational changes that lead to autophosphorylation and activation of the tyrosine kinase intrinsic to the beta subunits. Insulin receptor transphosphorylates several immediate substrates, resulting in modulation of a cascade of downstream signal transduction molecules. In order to discover small molecules that activate the human insulin receptor tyrosine kinase (IRTK), a cell-based assay was established and utilized to screen a collection of synthetic chemicals and natural product extracts. This effort led to the identification of a nonpeptidyl, small molecule, insulin-mimetic compound (demethylasterriquinone B-1, DMAQ-B1) that was isolated from a mixture of metabolites produced by a tropical endophytic fungus, Pseudomassaria sp. This compound induced human IRTK activation and increased tyrosine phosphorylation of IR beta subunit. It mediated insulin-like effects, including insulin receptor substrate-1 (IRS-1) phosphorylation and activation of phosphotidylinositide 3-kinase and Akt kinase. DMAQ-B1 also exhibited an insulin-like effect on glucose uptake in adipocytes and skeletal muscle tissue. Furthermore, the compound was relatively selective for IR vs. insulin-like growth factor-I (IGF-I) receptor and other homologous receptor tyrosine kinases. In addition, it activated partially purified native IR or recombinant IR kinase, demonstrating the direct interaction of the small molecule with the IR. Oral administration of DMAQ-B1 resulted in significant glucose lowering in two mouse models of diabetes. Thus, DMAQ-B1 represents the first orally active insulin-mimetic agent. Pharmaceutical intervention aimed at augmenting IR function ultimately may prove beneficial as a novel therapeutic option in patients with diabetes.","PeriodicalId":21099,"journal":{"name":"Recent progress in hormone research","volume":"25 1","pages":"107-26"},"PeriodicalIF":0.0,"publicationDate":"2001-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"86885208","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Obesity is a common problem in western society that is directly linked to several disease processes and is associated with significant morbidity and mortality. Adipocytes--the primary site for energy storage (as triglycerides) and release--were long suspected to have an active role in regulating body weight homeostasis and energy balance. As a result, many studies have focused on finding abnormalities in adipocyte physiology and metabolism. An ever-increasing body of evidence indicates that, in addition to serving as a repository for energy reserves, adipocytes secrete a myriad of factors that comprise a complex network of endocrine, autocrine, and paracrine signals. Very little is known regarding the molecular mechanisms utilized by the adipocyte in regulating the biosynthesis and exocytosis of these secreted products. In order to gain a better understanding of these processes, we have examined the two classical secretory pathways: regulated and constitutive. Using leptin as a model adipocyte-secretory protein, this review focuses primarily on the latter pathway. This includes regulation of leptin synthesis and secretion by insulin and glucocorticoids and, more recently, the finding that the orexigenic neuropeptide, melanin-concentrating hormone (MCH), can stimulate leptin synthesis and secretion. This chapter also incorporates new data describing the partial purification and effect of insulin on leptin-containing vesicles in rat adipocytes. These data indicate that the majority of leptin trafficking occurs via a constitutive secretory pathway and that the primary acute insulin effect on leptin secretion is to increase leptin protein content. In addition, we describe the identification and characterization of the vesicle-associated protein, pantophysin, which may play a multifunctional role in vesicle biogenesis and transport.
{"title":"The adipocyte as a secretory organ: mechanisms of vesicle transport and secretory pathways.","authors":"R. L. Bradley, K. Cleveland, B. Cheatham","doi":"10.1210/RP.56.1.329","DOIUrl":"https://doi.org/10.1210/RP.56.1.329","url":null,"abstract":"Obesity is a common problem in western society that is directly linked to several disease processes and is associated with significant morbidity and mortality. Adipocytes--the primary site for energy storage (as triglycerides) and release--were long suspected to have an active role in regulating body weight homeostasis and energy balance. As a result, many studies have focused on finding abnormalities in adipocyte physiology and metabolism. An ever-increasing body of evidence indicates that, in addition to serving as a repository for energy reserves, adipocytes secrete a myriad of factors that comprise a complex network of endocrine, autocrine, and paracrine signals. Very little is known regarding the molecular mechanisms utilized by the adipocyte in regulating the biosynthesis and exocytosis of these secreted products. In order to gain a better understanding of these processes, we have examined the two classical secretory pathways: regulated and constitutive. Using leptin as a model adipocyte-secretory protein, this review focuses primarily on the latter pathway. This includes regulation of leptin synthesis and secretion by insulin and glucocorticoids and, more recently, the finding that the orexigenic neuropeptide, melanin-concentrating hormone (MCH), can stimulate leptin synthesis and secretion. This chapter also incorporates new data describing the partial purification and effect of insulin on leptin-containing vesicles in rat adipocytes. These data indicate that the majority of leptin trafficking occurs via a constitutive secretory pathway and that the primary acute insulin effect on leptin secretion is to increase leptin protein content. In addition, we describe the identification and characterization of the vesicle-associated protein, pantophysin, which may play a multifunctional role in vesicle biogenesis and transport.","PeriodicalId":21099,"journal":{"name":"Recent progress in hormone research","volume":"61 1","pages":"329-58"},"PeriodicalIF":0.0,"publicationDate":"2001-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"89174450","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
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