Deletions of Fstl3 and/or Fst Isoforms 303 and 315 Results in Hepatic Steatosis

Ungerleider, Nathan A

01 January 2010

TGFβ ligands, activin and myostatin have been shown to stimulate insulin production and secretion. Antagonists, Follistatin (FST) and Follistatin like 3 (FSTL3) were partially and fully ablated, respectively, creating hyperinsulinemic mice with fatty liver. Much research has surfaced on the connection between hepatic steatosis and hepatic insulin resistance. We present two different models, each with a different mechanism behind the development of fatty liver. FST288-only mice have increased synthesis of mRNA and proteins responsible for hepatic triglyceride (TG) uptake, while our double mutants have increased synthesis of mRNA and proteins responsible for TG synthesis. This alteration was likely independent of hepatic insulin resistance as livers from both mouse lines were insulin sensitive. Experiments conducted in this study to realize the causal factor of hepatic steatosis can be performed on adipose and muscle tissues in the future to better characterize the phenotype.

hepatic steatosis

insulin resistance

srebp1

lipid uptake

Circadian Integration of Hepatic De Novo Lipogenesis and Peripheral Energy Substrates Utilization

Liu, Sihao

14 March 2013

The liver maintains energy substrate homeostasis by synchronizing circadian or diurnal expression of metabolic genes with the feeding/fasting state. The activities of hepatic de novo lipogenic gene products peak during feeding, converting carbohydrates into fats that provide vital energy sources for peripheral tissues. Conversely, deregulated hepatic lipid synthesis leads to systemic metabolic dysfunction, establishing the importance of temporal regulation of fat synthesis/usage in metabolic homeostasis. Pharmacological activation of peroxisome proliferator-activated receptor \(\delta / \beta (PPAR \delta / \beta)\)improves glucose handling and systemic insulin sensitivity. However, the mechanisms of hepatic \(PPAR\delta\) actions and the molecular pathways through which it is able to modulate global metabolic homeostasis remain unclear. Here we show that hepatic \(PPAR\delta\) controls the diurnal expression of lipogenic genes in the dark/feeding cycle. Adenovirus mediated liver restricted activation of \(PPAR\delta\) promotes glucose utilization in the liver and fat utilization in the muscle. Liver specific deletion of either \(PPAR\delta\) or the \(PPAR\delta\)-regulated lipogenic gene acetyl-CoA carboxylase 1 (ACC1) reduces muscle fatty acid uptake. Unbiased metabolite profiling identifies 1-stearoyl-2-oleoyl-sn-glycero-3-phosphocholine (SOPC) as a serum lipid derived from the hepatic \(PPAR\delta\)-ACC1 activity that reduces postprandial lipid levels and increases muscle fatty acid uptake. These findings reveal a regulatory mechanism that coordinates lipid synthesis and utilization in the liver-muscle axis, providing mechanistic insights into the hepatic regulation of systemic energy substrates homeostasis.

Biology

Genetics

Molecular biology

Circadian Rhythm

Lipid Uptake

Lipogenesis

PPAR

Studies of SR-BI in HDL Lipid Uptake in Hepatocytes

Brunet, Rachelle

06 1900

<p> Gene-targeted studies in mice have shown that the murine scavenger receptor class B type I (mSR-BI) is atheroprotective and plays a key role in the clearance of high density lipoprotein (HDL) cholesterol by the liver. We focused on the analysis of human SR-BI (hSR-BI) and the role of its C-terminal cytoplasmic tail on its localization, lipid uptake activity, and regulation in hepatocytes both in vitro and in vivo. Full length hSRBI and hSR-BI lacking its C-terminal cytoplasmic tail (hSR-BI-DM) localized to vesiclelike structures in the cytoplasm, to juxtanuclear regions and to the cell surface in HepG2 cells. Similar cytoplasmic punctate distribution was observed in transfected human and mouse aortic endothelial cells. </p> <p> In HepG2 cells both hSR-BI and hSR-BI-DM mediated HDL-lipid uptake; however, the truncation mutant displayed only half ofthe activity, suggesting that removal ofthe C-terminal cytoplasmic tail reduced but did not eliminate SR-BI's activity. In HepG2 cells treated with the PKC inhibitor, calphostin C, hSR-BI or hSR-BI-DM mediated HDL-lipid uptake was decreased by 40 and 50%, respectively, indicating that this activity is regulated by PKC. </p> <p> In order to determine the effects of hSR-BI and hSR-BI-DM in vivo, we set out to generate transgenic mice with hepatic overexpression ofeach protein using a bipartite expression system requiring driver and responder transgenes. Mice expressing the responder transgenes, PTREhSR-BI and PTREhSR-BI-DM, as well as a reporter transgene (PTRdacZ), driven by the same bi-directional promoter, were generated and mated to mice with a liver-specific driver trans gene, PMuptTA. The mice were analyzed and showed the presence of a reporter protein, ~-galactosidase, in their livers, but not in other tissues tested. Total and HDL cholesterol levels were not altered in PMuPtTA I PrREhSRBI or PMuptTA I PrREhSR-BI-DM transgenic mice. Further characterization ofthe double transgenic mice revealed that hSR-BI m.RNA transcripts were detected in the livers of PMuPtTA I PrREhSR-BI mice, but not in those ofPMuPtTA I PrREhSR-BI-DM mice. However, neither PMuptTA I PrREhSR-BI nor PMuptTA I PrREhSR-BI-DM mice showed increased expression of SR-BI in their livers. </p> / Thesis / Master of Science (MSc)

SR-BI

HDL Lipid Uptake

Hepatocytes

Gene-targeted studies

mice

A Novel Selective Lipid Uptake Pathway Contributing to LDL-Induced Macrophage Foam Cell Formation

Meyer, Jason M.

01 January 2013

Atherosclerosis is a disease characterized by cholesterol-rich plaques within the intima of medium and large arteries. Cholesterol deposition is thought to occur by infiltration of low-density lipoprotein (LDL) into lesions followed by uptake into macrophages, generating lipid-loaded “foam cells.” Foam cells can also be generated in vitro by treatment of macrophages with LDL or oxidized LDL (oxLDL). The purpose of the current investigation was to determine the contribution of selective cholesteryl ester (CE) uptake versus whole-particle uptake during LDL-induced foam cell formation in cultured macrophages. Murine bone marrow-derived macrophages (BMMs) exhibited significant cholesterol accumulation when treated with LDL as indicated by quantification of cellular cholesterol and visualization of Oil Red-O-stained neutral lipid droplets. Uptake of LDL cholesterol was determined by measuring uptake of 3H and 125I into BMMs during treatment with [3H]CE/125I-LDL. [3H]CE uptake was linearly related to the LDL concentration at the concentrations used and was much larger than 125I uptake, indicating that the majority of LDL-cholesterol was acquired by nonsaturable, selective CE uptake. This pathway was demonstrated to be independent of whole-particle uptake by showing that inhibition of actin polymerization blocked LDL particle uptake but not selective CE uptake. Analysis by thin-layer chromatography (TLC) indicated that following uptake, [3H]CE was rapidly hydrolyzed into [3H]cholesterol by cells and largely effluxed into the culture medium. In contrast to LDL, studies of [3H]CE/125I-oxLDL uptake demonstrated that CE was acquired from oxLDL by whole-particle uptake with little or no selective CE uptake. Using a series of ten different [3H]CE/125I-oxLDLs oxidized for 0-24 hours, selective [3H]CE uptake was shown to be progressively impaired by LDL oxidation, while 125I-LDL particle uptake was increased as expected. Interestingly, the impairment of selective CE uptake occurred very early in LDL oxidation and this minimally oxidized LDL induced significantly less cholesterol accumulation in BMMs compared to native LDL. Together, these results demonstrate that selective CE uptake is the primary mode of cholesterol uptake from LDL but not oxidized LDL, a finding that has important implications for cholesterol metabolism in atherosclerotic lesions. Future studies seek to identify the molecular components that participate in the macrophage selective CE uptake mechanism.

macrophage foam cell

selective lipid uptake

selective CE uptake

native LDL

oxidized LDL

Cardiovascular Diseases

Lipids

Quantifying the role of lymphatics in lipid transport and lymphatic filariasis using novel engineering approaches

Kassis, Timothy

21 September 2015

The lymphatic system has fundamental physiological roles in maintaining fluid homeostasis, immune cell trafficking and lipid transport from the small intestine to the venous circulation. Lymphatic vessels are the main functional organ responsible for the diverse transport roles the system plays. Unlike the blood vasculature, the lymphatic system does not have a central pump, such as the heart, and relies on a variety of factors to move lymph through. It was long thought that only external factors, such as skeletal muscle contraction and lymph formation, played a role in the functional transport capacity of these vessels. With the advancement of imaging capabilities (both hardware and software), it has become clear in the past two decades or so that the main factor in driving lymph transport is the ability of these vessels to intrinsically contract whereby each vessel is comprised of a chain of ‘mini pumps’ in series. The functional capacity of these vessels is thus now understood to be primarily determined by this pumping activity that has been shown to be regulated by various mechanical and biochemical cues. Lymphatic vessel dysfunction has been implicated in a variety of diseases including many lipid related pathologies and a neglected tropical disease known as lymphatic filariasis. While it has been possible to study the vessel function in the context of fluid drainage and immune cell trafficking, the capability to understand the role of lymphatic vessels in lipid transport has not been available due to the lack of experimental animal models and acquisition systems. As part of this thesis, we sought to develop an experimental animal model along with hardware and software tools to investigate the interplay between lymphatics and their lipid content. We report the first functional measurements of how vessels respond to elevated lipid loads. We further utilized our engineering expertise to develop an experimental platform allowing us to further understand the parasite known as B. malayi that migrates to and resides in lymphatic vessels.

Lymphatics

B. malayi

Lymphatic imaging

Filariasis

Biomechanics

Lipid uptake

Lipid transport