Browsing by Subject "Metabolism -- Disorders"
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Item Effect of coronary perivascular adipose tissue on vascular smooth muscle function in metabolic syndrome(2013-12-19) Owen, Meredith Kohr; Tune, Johnathan D.; Considine, Robert V.; March, Keith Leonard, 1963-; Sturek, Michael Stephen; Witzmann, F. A. (Frank A.)Obesity increases cardiovascular disease risk and is associated with factors of the “metabolic syndrome” (MetS), a disorder including hypertension, hypercholesterolemia and/or impaired glucose tolerance. Expanding adipose and subsequent inflammation is implicated in vascular dysfunction in MetS. Perivascular adipose tissue (PVAT) surrounds virtually every artery and is capable of releasing factors that influence vascular reactivity, but the effects of PVAT in the coronary circulation are unknown. Accordingly, the goal of this investigation was to delineate mechanisms by which lean vs. MetS coronary PVAT influences vasomotor tone and the coronary PVAT proteome. We tested the hypothesis that MetS alters the functional expression and vascular contractile effects of coronary PVAT in an Ossabaw swine model of the MetS. Utilizing isometric tension measurements of coronary arteries in the absence and presence of PVAT, we revealed the vascular effects of PVAT vary according to anatomical location as coronary and mesenteric, but not subcutaneous adipose tissue augmented coronary artery contractions to KCl. Factors released from coronary PVAT increase baseline tension and potentiate constriction of isolated coronary arteries relative to the amount of adipose tissue present. The effects of coronary PVAT are elevated in the setting of MetS and occur independent of endothelial function. MetS is also associated with substantial alterations in the coronary PVAT proteome and underlying increases in vascular smooth muscle Ca2+ handling via CaV1.2 channels, H2O2-sensitive K+ channels and/or upstream mediators of these ion channels. Rho-kinase signaling participates in the increase in coronary artery contractions to PVAT in lean, but not MetS swine. These data provide novel evidence that the vascular effects of PVAT vary according to anatomic location and are influenced by the MetS phenotype.Item The impact of mTOR, TFEB and Bid on non-alcoholic fatty liver disease and metabolic syndrome(2015-05-18) Zhang, Hao; Yin, Xiao-Ming; Chalasani, Naga P.; Konger, Raymond Lloyd; Murrell, Jill R.Non-alcoholic fatty liver disease and metabolic syndrome induced by high nutrient status have increasingly become a global health concern as it cause multiple complications. The mTOR complex is central in regulating anabolic reactions within cells under growth factors or under high nutrients stimulation. Constitutive and persistent activation of mTOR can impair cellular functions. In the first part of this study, we demonstrate a damping oscillation of mTOR activity during a long-term treatment of high fat diet. TFEB translocation and lysosomal enzyme activity also oscillate, but in an opposite direction. TFEB controls the lysosomal activity, autophagic degradation and lipid metabolism. Overexpression of wild type and mutant TFEB could inhibit NAFLD development in mice. In addition, TFEB location in nucleus inversely correlates with NAFLD severity in patients. mTOR activation under hypernutrition status suppresses TFEB translocation, inhibits lysosomal functions and autophagic degradation of lipid droplets. Inhibition of mTOR activity by rapamycin reverse the above phenotypes. Because mTOR activation also requires normal lysosomal function, the inhibition of TFEB by mTOR leads to decreased lysosomal function and mTOR downregulation. This negative feedback may explain the oscillation pattern of mTOR activation in long term high fat diet regimen and is a novel mechanism for inhibition of mTOR. In the second part of study, we report that Bid protein, previously known for its pro-apoptosis function in promoting mitochondrial permeability, plays an unexpected role in regulating fatty acid beta oxidation. Deletion of Bid in mice reprograms the body's response to hyper-nutrition caused by high fat diet, leading to the resistance to the development of obesity, liver steatosis and metabolic syndrome. These mice present a higher oxygen consumption, a lower respiratory quotient, and an increased beta-oxidation rate. Mechanistically, the high fat diet regimen triggers translocation of the full length Bid molecule to mitochondrial membrane. Genetic deletion of Bid also affects the stability of its binding protein, MTCH2 in the mitochondrial membrane. In summary, we describe in this study a mTOR-TFEB-lysosome feedback loop, which can regulate NAFLD development, and a novel Bid-mediated regulatory mechanism in beta-oxidation, which limits energy expenditure and promotes obesity development.Item Loss of mTORC1 signalling impairs β-cell homeostasis and insulin processing(Nature Communication Group, 2017-07-12) Blandino-Rosano, Manuel; Barbaresso, Rebecca; Jimenez-Palomares, Margarita; Bozadjieva, Nadejda; Werneck-de-Castro, Joao Pedro; Hatanaka, Masayuki; Mirmira, Raghavendra G.; Sonenberg, Nahum; Liu, Ming; Rüegg, Markus A.; Hall, Michael N.; Bernal-Mizrachi, Ernesto; Pediatrics, School of MedicineDeregulation of mTOR complex 1 (mTORC1) signalling increases the risk for metabolic diseases, including type 2 diabetes. Here we show that β-cell-specific loss of mTORC1 causes diabetes and β-cell failure due to defects in proliferation, autophagy, apoptosis and insulin secretion by using mice with conditional (βraKO) and inducible (MIP-βraKOf/f) raptor deletion. Through genetic reconstitution of mTORC1 downstream targets, we identify mTORC1/S6K pathway as the mechanism by which mTORC1 regulates β-cell apoptosis, size and autophagy, whereas mTORC1/4E-BP2-eIF4E pathway regulates β-cell proliferation. Restoration of both pathways partially recovers β-cell mass and hyperglycaemia. This study also demonstrates a central role of mTORC1 in controlling insulin processing by regulating cap-dependent translation of carboxypeptidase E in a 4EBP2/eIF4E-dependent manner. Rapamycin treatment decreases CPE expression and insulin secretion in mice and human islets. We suggest an important role of mTORC1 in β-cells and identify downstream pathways driving β-cell mass, function and insulin processing.Item The roles of pancreatic hormones in regulating pancreas development and beta cell regeneration(2015-06-16) Ye, Lihua; Anderson, Ryan M.; Mirmira, Raghu G.; Roach, Peter J.; Fueger, Patrick T.; Skalnik, David G.Diabetes mellitus is a group of related metabolic diseases that share a common pathological mechanism: insufficient insulin signaling. Insulin is a hormone secreted from pancreatic β cells that promotes energy storage and consequently lowers blood glucose. In contrast, the hormone glucagon, released by pancreatic α cells, plays a critical complementary role in metabolic homeostasis by releasing energy stores and increasing blood glucose. Restoration of β cell mass in diabetic patients via β cell regeneration is a conceptually proven approach to finally curing diabetes. Moreover, in situ regeneration of β cells from endogenous sources would circumvent many of the obstacles encountered by surgical restoration of β cell mass via islet transplantation. Regeneration may occur both by β cell self-duplication and by neogenesis from non-β cell sources. Although the mechanisms regulating the β cell replication pathway have been highly investigated, the signals that regulate β cell neogenesis are relatively unknown. In this dissertation, I have used zebrafish as a genetic model system to investigate the process of β cell neogenesis following insulin signaling depletion by various modes. Specifically, I have found that after their ablation, β cells primarily regenerate from two discrete cellular sources: differentiation from uncommitted pancreatic progenitors and transdifferentiation from α cells. Importantly, I have found that insulin and glucagon play crucial roles in controlling β cell regeneration from both sources. As with metabolic regulation, insulin and glucagon play counter-balancing roles in directing endocrine cell fate specification. These studies have revealed that glucagon signaling promotes β cell formation by increasing differentiation of pancreas progenitors and by destabilizing α cell identity to promote α to β cell transdifferentiation. In contrast, insulin signaling maintains pancreatic progenitors in an undifferentiated state and stabilizes α cell identity. Finally, I have shown that insulin also regulates pancreatic exocrine cell development. Insufficient insulin signaling destabilized acinar cell fate and impairs exocrine pancreas development. By understanding the roles of pancreatic hormones during pancreas development and regeneration can provide new therapeutic targets for in vivo β cell regeneration to remediate the devastating consequences of diabetes.