Project description:Weight loss significantly improves metabolic and cardiovascular health in people with obesity. Adipose tissue remodelling is central to these varied and important clinical effects. However surprisingly little is known about the underlying mechanisms, presenting a barrier to treatment advances. Here we report a spatially resolved single nucleus atlas (171,247 cells, 70 people) investigating the cell types, molecular events and regulatory factors that reshape human adipose tissues, and thus metabolic health, in obesity and therapeutic weight loss. We discover selective vulnerability to senescence in metabolic, precursor and vascular cells and reveal senescence is potently reversed by weight loss. We define gene regulatory mechanisms and tissue signals that may drive a degenerative cycle of senescence, tissue injury and metabolic dysfunction. We find that weight loss reduces adipocyte hypertrophy and biomechanical constraint pathways, activating global metabolic flux and bioenergetic substrate cycles that may mediate systemic improvements in metabolic health. In the immune compartment, we demonstrate that weight loss represses obesity-induced macrophage infiltration but does not completely reverse activation, leaving these cells primed to trigger potential weight regain and worsen metabolic dysfunction. Throughout, we map cells to tissue niches to understand the collective determinants of tissue injury and recovery. Overall, our complementary single nucleus and spatial datasets offer unprecedented insights into the basis of obese adipose tissue dysfunction and its reversal by weight loss, and a key resource for mechanistic and therapeutic exploration.

Project description:Nicotinamide adenine dinucleotide (NAD+) is an essential coenzyme regulating cellular energy metabolism across all species. Recent studies have shown the pleiotropic roles of adipose tissue NAD+ biology in adipose tissue and whole-body metabolism. The major purpose of the present study was to test the hypothesis that adipose tissue NAD+ biosynthesis, mediated by nicotinamide phosphoribosyltransferase (NAMPT), is a physiological regulator of whole-body metabolic flexibility. To this end, we analyzed adipocyte-specific Nampt knockout (ANKO) mice and subcutaneous white adipose tissue (WAT) biopsy samples obtained from human subjects. We found ANKO mice preferably utilized glucose substrate during the light period or after prolonged fasting. In contrast, ANKO mice had marked decreases in stimulation of glucose oxidation and suppression of fat oxidation during the postprandial status despite hyperinsulinemia. Data obtained from RNA-sequencing of WAT suggest that loss of NAMPT causes inflammation, oxidative stress, defective fatty acid oxidation, and mitochondrial dysfunction in WAT, key features of obesity and metabolic inflexibility. We also found WAT NAD+ concentration was decreased in people with obesity and insulin resistance compared with those who were non-obese and insulin-sensitive. In addition, bariatric surgery-induced 20% weight loss increased WAT NAD+ concentration in people with obesity. Taken together, our results reveal the importance of adipose tissue NAMPT-mediated NAD+ biosynthesis in regulating whole-body metabolic flexibility. Our results also provide translational and clinical insight into adipose tissue NAD+ biology in obesity and whole-body metabolic health.

Project description:Lipedema is a lipodystrophic disease characterized by marked increases in lower-body subcutaneous adipose tissue, anecdotally reported to: i) increase inflammation and fibrosis and impair microvascular and lymphatic circulation in the affected adipose tissue, ii) reduce risk of developing obesity-related cardiometabolic abnormalities; and iii) be resistant to diet-induced weight loss. To further our understanding of lipedema, we examined body composition, metabolic health and adipose tissue bology in women with obesity and lipedema (Obese-LIP) at baseline and following ~9% diet-induced weight loss. At baseline, people with Obese-LIP had ~23% greater leg fat mass, ~11% lower android-to-gynoid ratio and ~54% greater insulin sensitivity compared to women matched on age, body mass index and whole-body fat mass. In the Obese-LIP group, total and proinflammatory macrophage content and expression of inflammation and fibrosis-related genes were greater while lymph/angiogenesis-related genes were lower in subcutaneous femoral compared to abdominal adipose tissue. Diet-induced weight loss improved insulin sensitivity and decreased total fat mass due to similar reductions in abdominal and leg fat masses, with minimal effect on markers of adipose tissue inflammation/fibrosis and lymph/angiogenesis. Our study provides important insights into the pathophysiology of lipedema and suggests diet-induced weight loss should be the cornerstone therapy in people with Obese-LIP.

Project description:Obesity is associated with insulin resistance and increased intrahepatic triglyceride (IHTG) content, which are key risk factors for diabetes and cardiovascular disease. However, a subset of obese people does not develop these metabolic complications. We tested the hypothesis that MNO, but not MAO, people are protected from the adverse metabolic effects of weight gain. To this end, global transcriptional profile in adipose tissue before and after weight gain was evaluated by microarray analyses. We collected subcutaneous adipose tissue samples from MNO (n=11) and MAO (n=7) subjects before and after moderate (~6%) weight gain (total 36 samples). We evaluated the effects of weight gain on adipose tissue gene expression in both MNO and MNO subjects.We used the GeneChip Human Gene 1.0 ST array (Affymetrix, Santa Clara, CA, USA).

Project description:The purpose of this study was to evaluate the effect of progressive weight loss (5, 10, 15% weight loss) on metabolic function such as multi-organ insulin sensitivity and beta-cell function in obese people. We conducted microarray analysis to determine the effect of progressive weight loss on adipose tissue gene expression profile. We examined subcuntaneous adipose tissue samples obtained from 9 obese subjects before (A) and after 5% (B), 10% (C) and 15% (D) weight loss (total 36 samples).

Project description:Obesity is associated with insulin resistance and increased intrahepatic triglyceride (IHTG) content, which are key risk factors for diabetes and cardiovascular disease. However, a subset of obese people does not develop these metabolic complications. We tested the hypothesis that MNO, but not MAO, people are protected from the adverse metabolic effects of weight gain. To this end, global transcriptional profile in adipose tissue before and after weight gain was evaluated by microarray analyses.

Project description:Metabolic plasticity is the ability of a biological system to adapt its metabolic phenotype to different environmental stressors. We used a whole-body and tissue- specific phenotypic, functional, metabolomic and transcriptomic approach to systematically assess metabolic plasticity in diet-induced obese mice after a combined nutritional and exercise intervention. Although most pathological features were successfully reverted, we observed a high degree of metabolic dysfunction irreversibility in visceral white adipose tissue, characterised by abnormal mitochondrial morphology and functionality. Despite two sequential therapeutic interventions and apparent global phenotypic recovery, obesity specifically triggered in visceral adipose tissue a cascade of events progressing from mitochondrial metabolic and proteostatic defects to widespread cellular stress, which compromises its biosynthetic and recycling capacity. Our data indicate that obesity prompts a lasting metabolic fingerprint that leads to an aging-like progressive breakdown of metabolic plasticity in white adipose tissue. A similar phenomenon was observed in an obese human cohort following weight loss. Further human studies should help dissect patients’ stratification of this significant milestone in obesity progression.

Project description:The purpose of this study was to evaluate the effect of progressive weight loss (5, 10, 15% weight loss) on metabolic function such as multi-organ insulin sensitivity and beta-cell function in obese people. We conducted microarray analysis to determine the effect of progressive weight loss on adipose tissue gene expression profile.

Project description:Plakophilin2 (PKP2) is a key component of desmosomes mostly recognized for its involvement in the fibro fatty infiltration of heart muscle under defective PKP2. While thoroughly explored in cardiomyocytes, less attention has been given to its role in fat cells. Here we report steadily increased PKP2 during adipogenesis, with expression levels reaching its apex in terminally differentiated adipocytes. Notably, the loss of this protein in adipocytes under a pro-inflammatory microenvironment demonstrates its commitment in maintaining the expression of genes required to nurture cell cycle. Then, we show that diminished expressions of this member of the armadillo repeat family in subcutaneous adipose tissue co-segregate with obesity, being normalized upon mild to intense weight loss. We also demonstrate that impaired PKP2 in human adipocytes breaks cell cycle dynamics to breed premature senescence, a key rheostat for stress induced adipose tissue dysfunction. Conversely, restoring PKP2 in inflamed adipocytes rewires E2F signalling towards re-activation of cell cycle and decreased senescence. Our findings bound the expression of PKP2 in fat cells to the physiopathology of obesity, and uncover a previously unknown defect in cell cycle and activated adipocyte senescence due to impaired PKP2.

Project description:It has been proposed that there is a direct pathophysiological link between metabolic dysfunction and musculoskeletal degeneration in people with obesity but direct evidence for this proposition is lacking. We performed a comprehensive assessment of musculoskeletal status in people with obesity and prediabetes and a control group of sex-, age- and adiposity-matched participants with normoglycemia. We find muscle mass and bone mineral density scores, muscle growth markers, myofiber size, myofiber capillarization, and muscle type 2 macrophage content are lower, and intramyocellular lipid, but not inter- or intra-muscular adipose tissue, content are higher in people with prediabetes compared with the control group. Moreover, muscle strength during repeated maximum voluntary contractions declines faster in people with prediabetes. These findings demonstrate a close interrelationship between metabolic and musculoskeletal dysfunction in people with obesity and have direct clinical implications, because greater muscle fatigability in people with prediabetes may present a barrier to physical activity.