Project description:In humans, adipose tissue is distributed in subcutaneous abdominal and subcutaneous gluteal depots that comprise a variety of functional differences. Whereas energy storage in gluteal adipose tissue has been shown to mediate a protective effect, an increase of abdominal adipose tissue is associated with metabolic disorders. However, the molecular basis of depot-specific characteristics is not completely understood yet. Using array-based analyses of transcription profiles, we identified a specific set of genes that was differentially expressed between subcutaneous abdominal and gluteal adipose tissue. To investigate the role of epigenetic regulation in depot-specific gene expression, we additionally analyzed genome-wide DNA methylation patterns in abdominal and gluteal depots. By combining both data sets, we identified a highly significant set of depot-specifically expressed genes that appear to be epigenetically regulated. Interestingly, the majority of these genes form part of the homeobox gene family. Moreover, genes involved in fatty acid metabolism were also differentially expressed. Therefore we suppose that changes in gene expression profiles might account for depot-specific differences in lipid composition. Indeed, triglycerides and fatty acids of abdominal adipose tissue were more saturated compared to triglycerides and fatty acids in gluteal adipose tissue. Taken together, our results uncover clear differences between abdominal and gluteal adipose tissue on the gene expression and DNA methylation level as well as in fatty acid composition. Therefore, a detailed molecular characterization of adipose tissue depots will be essential to develop new treatment strategies for metabolic syndrome associated complications. DNA methylation profiles of abdominal adipose tissue (6 samples) and gluteal adipose tissue (6 samples) were generated using Infinium methylation 450K BeadChips from Illumina (Illumina, San Diego, USA).

Project description:To identify genes differentially expressed in abdominal and gluteal adipose tissue, we determined the mRNA transcription profile of 10 abdominal and 10 gluteal female adipose tissue sections using Agilent Whole Human Genome Microarrays. RNA of 10 subcutaneous abdominal and 10 subcutaneous gluteal fat depot samples was processed by Miltenyi Biotech GmbH (Bergisch Gladbach, Germany) and loaded on single-color Whole Human Genome 4x44K microarrays (G4112F) from Agilent Technologies.

Project description:Adipose tissue is a primary regulator of energy balance and metabolism. The distribution of adipose tissue depots is of clinical interest because the accumulation of upper-body subcutaneous (ASAT) and visceral adipose tissue (VAT) is associated with cardiometabolic diseases, whereas lower-body gluteal-femoral adipose tissue (GFAT) appears to be protective. There is heterogeneity in the morphological and metabolic traits of adipocytes obtained from different regions of the body, but detailed knowledge of the constituent proteins in each depot is lacking. Here, we determined the human adipocyte proteome from ASAT, VAT and GFAT using high-resolution SWATH mass spectrometry proteomics.

Project description:Obesity and associated metabolic outcomes define the metabolic syndrome. Interestingly, an under-appreciated fact is that body fat distribution, rather than total body fat amount, is a key determinant of metabolic disease. Indeed, in contrast to upper-body obesity, lower-body fat accumulation inversely correlates with metabolic risks. Understanding processes regulating upper- vs. lower-body fat expansion is paramount to predict (and prevent) these risks. We combine functional, proteomics, transcriptomics and epigenomics analyses to identify chromatin-associated mechanisms of adipose depot-specific fat expansion. Here, we analyze by RNA-seq the transcriptome of adipocytes differentiated in vitro from human gluteal (lower-body) and abdominal subcutaneous (upper-body) depots-derived adipose stem cells. We aim to identify adipose depot-specific and temporal differences in the up- or down-regulation of gene expression, and relate these differences to changes in chromatin states.

Project description:Suboptimal intrauterine nutrition predisposes the fetus to central obesity and metabolic syndrome in adult life, suggesting nutritional programming of the fat distribution. However, the underlying mechanisms are not elucidated. We hypothesized that prenatal nutritional deprivation leads to stimulation of adipogenesis, as an adaptive mechanism, in a depot-dependent manner. The induction of adipogenesis is most enhanced in the subcutaneous lower-body depots, followed by the subcutaneous upper-body and visceral adipose tissue depots. Stimulation of adipogenesis may lead to an early consumption of the stem cell pool, and thus, may impair adipose tissue expandability postnatally, which may lead to differences in regional adipose tissue growth. We tested this hypothesis by analyzing global gene expression to identify expression patterns in subcutaneous abdominal, subcutaneous femoral, and omental adipose depots of baboon fetuses that have been altered by nutritional maternal deprivation. Adipose tissue was collected from baboon fetuses at 165 dG from mothers fed control or 30% nutrient-restricted diets (three females and one male in each group). 24 samples, each consisted of pooled total RNA from triplicate wells (6-well plate).

Project description:Obesity and associated metabolic outcomes define the metabolic syndrome. Interestingly, an under-appreciated fact is that body fat distribution, rather than total body fat amount, is a key determinant of metabolic disease. Indeed, in contrast to upper-body obesity, lower-body fat accumulation inversely correlates with metabolic risks. Understanding processes regulating upper- vs. lower-body fat expansion is paramount to predict (and prevent) these risks. We combine functional, proteomics, transcriptomics and epigenomics analyses to identify chromatin-associated mechanisms of adipose depot-specific fat expansion. Here, we analyze by RNA-seq the transcriptome of adipose stem cells (ASCs) from gluteal (lower-body) and abdominal subcutaneous (upper-body) depots induced to differentiate in vitro towards the adipogenic lineage. We aim to identify adipose depot-specific and temporal differences in the up- or down-regulation of gene expression, and a later stage relate these differences to changes in chromatin states.

Project description:Suboptimal intrauterine nutrition predisposes the fetus to central obesity and metabolic syndrome in adult life, suggesting nutritional programming of the fat distribution. However, the underlying mechanisms are not elucidated. We hypothesized that prenatal nutritional deprivation leads to stimulation of adipogenesis, as an adaptive mechanism, in a depot-dependent manner. The induction of adipogenesis is most enhanced in the subcutaneous lower-body depots, followed by the subcutaneous upper-body and visceral adipose tissue depots. Stimulation of adipogenesis may lead to an early consumption of the stem cell pool, and thus, may impair adipose tissue expandability postnatally, which may lead to differences in regional adipose tissue growth. We tested this hypothesis by analyzing global gene expression to identify expression patterns in subcutaneous abdominal, subcutaneous femoral, and omental adipose depots of baboon fetuses that have been altered by nutritional maternal deprivation. Adipose tissue was collected from baboon fetuses at 165 dG from mothers fed control or 30% nutrient-restricted diets (three females and one male in each group).

Project description:We performed microarray analysis to evaluate differences in the transcriptome of the adipose tissue before and during pregnancy Biopsies of adipose tissue of the subcutaneous gluteal depots, processed for adipose cell isolation, the remining tissue was snap frozen in liquid nitrogen, adipocytes were isolated by digestion with collagenase

Project description:The two major mammalian adipose tissue depots are subcutaneous adipose tissue (SAT), which is associated with metabolic protection, and abdominal/visceral (VAT), which contributes to metabolic disease. To investigate the molecular underpinnings of these differences, we conducted a comprehensive analysis of the proteomes of adipocytes and whole tissue from these different depots across two different diets in male C57Bl/6J mice.

Project description:This study seeks to undertake an assessment of the effects of prenatal exposure of female sheep to excess testosterone, the estrogen precursor, in four different adipose depots. The depots investigated are subcutaneous adipose tissue (SAT) - a fat beneath the skin storing >80% of total body fat in the human body, visceral adipose tissue (VAT) - an intra-abdominal fat primarily associated with digestive system organs, and smaller depots such as epicardial adipose tissue (ECAT) and perirenal adipose tissue (PRAT) that serve specialized functions associated with the organs/tissues in their proximity. The goals are to 1) determine gene expression and gene network profiles in the depots; 2) assess prenatal T-treatment induced disruptions in adipose depot-specific gene expression and gene networks; and 3) identify common and divergent gene and gene pathways underlying depot-specific disruption in prenatal T-treated female sheep.