Itsaso Garcia-Arcos

Adipose-specific Lipoprotein Lipase Deficiency More Profoundly Affects Brown than White Fat Biology

Background: Lipoprotein lipase (LpL) is rate-limiting for plasma triglyceride lipolysis, but its importance in adipose development is uncertain. Results: Adipocyte LpL knock-out affected brown but not white fat composition. White fat was reduced when muscle LpL expression was increased. Conclusion: LpL distribution and adipose metabolism affect adipogenesis. Significance: All fat depots are not equally dependent on triglyceride uptake. Adipose fat storage is thought to require uptake of circulating triglyceride (TG)-derived fatty acids via lipoprotein lipase (LpL). To determine how LpL affects the biology of adipose tissue, we created adipose-specific LpL knock-out (ATLO) mice, and we compared them with whole body LpL knock-out mice rescued with muscle LpL expression (MCK/L0) and wild type (WT) mice. ATLO LpL mRNA and activity were reduced, respectively, 75 and 70% in gonadal adipose tissue (GAT), 90 and 80% in subcutaneous tissue, and 84 and 85% in brown adipose tissue (BAT). ATLO mice had increased plasma TG levels associated with reduced chylomicron TG uptake into BAT and lung. ATLO BAT, but not GAT, had altered TG composition. GAT from MCK/L0 was smaller and contained less polyunsaturated fatty acids in TG, although GAT from ATLO was normal unless LpL was overexpressed in muscle. High fat diet feeding led to less adipose in MCK/L0 mice but TG acyl composition in subcutaneous tissue and BAT reverted to that of WT. Therefore, adipocyte LpL in BAT modulates plasma lipoprotein clearance, and the greater metabolic activity of this depot makes its lipid composition more dependent on LpL-mediated uptake. Loss of adipose LpL reduces fat accumulation only if accompanied by greater LpL activity in muscle. These data support the role of LpL as the “gatekeeper” for tissue lipid distribution.

Age-related subproteomic analysis of mouse liver and kidney peroxisomes

BackgroundDespite major recent advances in the understanding of peroxisomal functions and how peroxisomes arise, only scant information is available regarding this organelle in cellular aging. The aim of this study was to characterize the changes in the protein expression profile of aged versus young liver and kidney peroxisome-enriched fractions from mouse and to suggest possible mechanisms underlying peroxisomal aging. Peroxisome-enriched fractions from 10 weeks, 18 months and 24 months C57bl/6J mice were analyzed by quantitative proteomics.ResultsPeroxisomal proteins were enriched by differential and density gradient centrifugation and proteins were separated by two-dimensional electrophoresis (2-DE), quantified and identified by mass spectrometry (MS). In total, sixty-five proteins were identified in both tissues. Among them, 14 proteins were differentially expressed in liver and 21 proteins in kidney. The eight proteins differentially expressed in both tissues were involved in β-oxidation, α-oxidation, isoprenoid biosynthesis, amino acid metabolism, and stress response. Quantitative proteomics, clustering methods, and prediction of transcription factors, all indicated that there is a decline in protein expression at 18 months and a recovery at 24 months.ConclusionThese results indicate that some peroxisomal proteins show a tissue-specific functional response to aging. This response is probably dependent on their differential regeneration capacity. The differentially expressed proteins could lead several cellular effects: such as alteration of fatty acid metabolism that could alert membrane protein functions, increase of the oxidative stress and contribute to decline in bile salt synthesis. The ability to detect age-related variations in the peroxisomal proteome can help in the search for reliable and valid aging biomarkers.

Involvement of lipid droplets in hepatic responses to lipopolysaccharide treatment in mice.

Infection and inflammation induce important changes in lipid metabolism, which result in increased free fatty acids and triacylglycerol in plasma and altered high density lipoprotein (HDL) metabolism. Our aim was to elucidate whether hepatic lipid droplets (LDs) are involved in the adaptations of lipid metabolism to endotoxemia. We characterized the lipid content and several enzymatic activities in subcellular fractions and subpopulations of LDs from livers of mice 24h after lipopolysaccharide (LPS) treatment and analyzed the expression of key genes involved in lipid management. Endotoxemic mice showed lower lipid content in LDs with decreased molar fraction of cholesteryl ester and higher diacylglycerol/triacylglycerol ratio as compared to their controls. They also showed a decrease in cytosolic triacylglycerol hydrolase activity, specifically in dense LDs, and in microsomal and cytosolic diacylglycerol hydrolase activity; concomitantly neutral lipid biosynthetic capacity and triacylglycerol levels in plasma lipoproteins increased. Together with the overexpression of genes involved in lipogenesis and HDL formation our results suggest that altered hepatic management of LD lipids in LPS-treated mice might be related to the channeled mobilization of triacylglycerol for very low density lipoprotein assembly and to the induction of cholesterol export.

Association of SND1 protein to low density lipid droplets in liver steatosis

Although the human homologue of SND p102, p100 coactivator, was initially described as a nuclear protein, the p100 coactivator protein family members have non-nuclear localization in mammalian cells with active lipid handling, storage, and secretion. However, their role in lipid homeostasis remains unresolved. Here, we investigate the distribution of the rat homologue SND p102 (also called SND1) and its association with newly formed lipid droplets in the liver parenchyma and cultured hepatocytes. Sucrose gradient fractionation showed that SND p102 cofractionated with endoplasmic reticulum and Golgi markers. Such cofractionation was not altered in regenerating steatotic rat liver. However, SND p102 was also detected in lipid droplets from regenerating liver, showing a specific directionalization to the least dense ones. Confocal microscopy of cultured hepatocytes confirmed the findings of gradient fractionation. In addition, p100 coactivator was consistently encountered in microsomes and lipid droplets in control and oleate-treated HepG2 cells. The total amount of SND p102 in hepatocytes was similar in both conditions, suggesting a specific translocation of the protein. Our findings indicate that SND p102 and the human p100 coactivator have a ubiquitous cytoplasmic distribution in hepatocytes and that steatogenic conditions promote the targeting of SND p102 from other cell compartments to specific low density lipid droplets.

Synaptotagmin 11 interacts with components of the RNA-induced silencing complex RISC in clonal pancreatic β-cells.

Synaptotagmins are two C2 domain‐containing transmembrane proteins. The function of calcium‐sensitive members in the regulation of post‐Golgi traffic has been well established whereas little is known about the calcium‐insensitive isoforms constituting half of the protein family. Novel binding partners of synaptotagmin 11 were identified in β‐cells. A number of them had been assigned previously to ER/Golgi derived‐vesicles or linked to RNA synthesis, translation and processing. Whereas the C2A domain interacted with the Q‐SNARE Vti1a, the C2B domain of syt11 interacted with the SND1, Ago2 and FMRP, components of the RNA‐induced silencing complex (RISC). Binding to SND was direct via its N‐terminal tandem repeats. Our data indicate that syt11 may provide a link between gene regulation by microRNAs and membrane traffic.

Lipid Analysis Reveals Quiescent and Regenerating Liver-Specific Populations of Lipid Droplets

The mammalian liver, a key organ in lipid homeostasis, can accumulate increased amounts of lipids in certain physiological conditions including liver regeneration. Lipid droplets (LD), the lipid storage organelles in the cytoplasm, are composed of a core of neutral lipids (mainly triacylglycerols and cholesteryl esters) surrounded by a monolayer of phospholipids and cholesterol with associated proteins. It is recognized that LD lipid composition is cell- and environment-specific and enables LD to carry out specific functions, but few descriptive studies aiming to interpret such differences have been published. We characterized eight density fractions of LD isolated from quiescent (control) and regenerating liver after partial hepatectomy, and grouped populations according to their lipid composition. LD from quiescent liver resembled the cholesteryl ester storage LD found in steroidogenic tissues, whereas in the regenerating tissue they were similar to adipocyte LD. Specifically, there were large, light LD with increased triacylglycerol content, the hallmark of liver regeneration. The apparent volume of the dense LD was, however, lower than in the quiescent density-matched populations, concomitant with increased phosphatidylcholine and phosphatidylethanolamine and decreased neutral lipid content. Analysis of the lipid profile of LD populations from quiescent and regenerating tissue leads us to define four physiological LD phenotypes for rat liver.

STAT3 modulates cigarette smoke-induced inflammation and protease expression

Signal transducer and activator of transcription-3 (STAT3) regulates inflammation, apoptosis, and protease expression, which are critical processes associated with airway injury and lung tissue destruction. However, the precise role of STAT3 in the development of airway diseases such as chronic obstructive pulmonary disease (COPD) has not been established. This study shows that cigarette smoke activates STAT3 in the lungs of mice. Since cigarette smoke activated STAT3 in the lung, we then evaluated how the loss of STAT3 would impact on smoke-mediated lung inflammation, protease expression, and apoptosis. STAT3+/+ and STAT3−/− mice were exposed to 8 days of cigarette smoke. Compared to the STAT3+/+ mice bronchoalveolar lavage fluid (BALF) cellularity was significantly elevated in the STAT3−/− mice both before and after cigarette smoke exposure, with the increase in cells primarily macrophages. In addition, smoke exposure induced significantly higher BALF protein levels of Interleukin-1α (IL-1α), and monocyte chemotactic protein-1 (MCP-1) and higher tissue expression of keratinocyte chemoattractant (KC) in the STAT3−/− mice. Lung mRNA expression of MMP-12 was increased in STAT3−/− at baseline. However, the smoke-induced increase in MMP-10 expression seen in the STAT3+/+ mice was not observed in the STAT3−/− mice. Moreover, lung protein levels of the anti-inflammatory proteins SOCS3 and IL-10 were markedly lower in the STAT3−/− mice compared to the STAT3+/+ mice. Lastly, apoptosis, as determined by caspase 3/7 activity assay, was increased in the STAT3−/− at baseline to levels comparable to those observed in the smoke-exposed STAT3+/+ mice. Together, these results indicate that the smoke-mediated induction of lung STAT3 activity may play a critical role in maintaining normal lung homeostasis and function.

Lipoprotein Lipase Deficiency Impairs Bone Marrow Myelopoiesis and Reduces Circulating Monocyte Levels

Objective— Tissue macrophages induce and perpetuate proinflammatory responses, thereby promoting metabolic and cardiovascular disease. Lipoprotein lipase (LpL), the rate-limiting enzyme in blood triglyceride catabolism, is expressed by macrophages in atherosclerotic plaques. We questioned whether LpL, which is also expressed in the bone marrow (BM), affects circulating white blood cells and BM proliferation and modulates macrophage retention within the artery. Approach and Results— We characterized blood and tissue leukocytes and inflammatory molecules in transgenic LpL knockout mice rescued from lethal hypertriglyceridemia within 18 hours of life by muscle-specific LpL expression (MCKL0 mice). LpL-deficient mice had ≈40% reduction in blood white blood cell, neutrophils, and total and inflammatory monocytes (Ly6C/Ghi). LpL deficiency also significantly decreased expression of BM macrophage-associated markers (F4/80 and TNF-&agr; [tumor necrosis factor &agr;]), master transcription factors (PU.1 and C/EBP&agr;), and colony-stimulating factors (CSFs) and their receptors, which are required for monocyte and monocyte precursor proliferation and differentiation. As a result, differentiation of macrophages from BM-derived monocyte progenitors and monocytes was decreased in MCKL0 mice. Furthermore, although LpL deficiency was associated with reduced BM uptake and accumulation of triglyceride-rich particles and macrophage CSF–macrophage CSF receptor binding, triglyceride lipolysis products (eg, linoleic acid) stimulated expression of macrophage CSF and macrophage CSF receptor in BM-derived macrophage precursor cells. Arterial macrophage numbers decreased after heparin-mediated LpL cell dissociation and by genetic knockout of arterial LpL. Reconstitution of LpL-expressing BM replenished aortic macrophage density. Conclusions— LpL regulates peripheral leukocyte levels and affects BM monocyte progenitor differentiation and aortic macrophage accumulation.

Infection of primary hepatocytes with adenoviral vectors alters biliary lipid metabolism

In the context of a study of the involvement of SND1 (also known as coactivator p100) in biliary lipid secretion by primary rat hepatocytes, first-generation adenoviral vectors were used to promote the overexpression and underexpression of the protein SND1. Although differential expression of SND1 did not result in significant changes in the processes studied, some effects of the adenoviral infection itself were observed. In particular, infected hepatocytes showed a higher intracellular taurocholate accumulation capacity. Additionally, small heterodimer partner (SHP) and farnesoid X receptor (FXR), which are nuclear receptors essential for the regulation of bile salt metabolism and transport, were underregulated at the mRNA level. Our results suggest that adenoviral vectors could be altering some important control mechanism and indicate that adenoviral vectors should be used with caution as transfection vectors for hepatocytes when biliary lipid metabolism is to be studied.

La infección de hepatocitos de rata en cultivo con adenovirus recombinantes causa un drástico descenso en la secreción de lipoproteínas de muy baja densidad

Introduccion Tras su administracion sistemica,los adenovirus recombinantes se concentran en el higado, lo que les validaria para la transferencia genica a este organo, pero existen efectos colaterales. En este trabajo se ha analizado el impacto de la infeccion sobre la cantidad y composicion de las lipoproteinas de muy baja densidad (VLDL) secretadas en hepatocitos de rata en cultivo. Metodos Se generaron 2 vectores adenovirales, con ADNc en direccion sentido o antisentido, ambos con capacidad infectiva pero no de propagacion. Se infectaron cultivos de hepatocitos de rata con una dosis no citotoxica y se analizaron las VLDL secretadas durante los 3 periodos de 24 h posteriores a la infeccion y el contenido en lipidos del citosol. Resultados La infeccion causo un moderado descenso en la secrecion de apo B48 y de ester de colesterol durante las primeras 24 h, pero posteriormente se redujo drasticamente la secrecion de particulas con apo B48 y apo B100 y su contenido en lipidos. Ademas, modifico sus proporciones, aumentando el porcentaje de colesterol libre a costa del esterificado, que llego a ser indetectable. La menor secrecion de VLDL no conllevo una acumulacion de lipido intracelular e, incluso, descendio la masa citosolica de ester de colesterol. Conclusion La infeccion con adenovirus reduce la secrecion hepatocitaria de VLDL y su porcentaje de colesterol esterificado y, a diferencia de otros virus, estas acciones no parecen ir acompanadas de esteatosis hepatocelular.