Project description:Most individuals do not maintain weight loss, and weight regain increases cardio-metabolic risk beyond that of obesity. Adipose inflammation directly contributes to insulin resistance; however, immune-related changes that occur with weight loss and weight regain are not well understood. Single cell RNA-sequencing was completed with CITE-sequencing and biological replicates to profile changes in murine immune subpopulations following obesity, weight loss, and weight cycling. Weight loss normalized glucose tolerance, however, type 2 immune cells did not repopulate adipose following weight loss. Many inflammatory populations persisted with weight loss and increased further following weight regain. Obesity drove T cell exhaustion and broad increases in antigen presentation, lipid handing, and inflammation that persisted with weight loss and weight cycling. This work provides critical groundwork for understanding the immunological causes of weight cycling-accelerated metabolic disease.

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: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:Obesity is a chronic disease that contributes to the development of insulin resistance, type 2 diabetes (T2D), and cardiovascular risk. GIP receptor (GIPR) and GLP-1 receptor (GLP-1R) co-agonism provide an improved therapeutic profile in individuals with T2D and obesity when compared with selective GLP-1R agonism. While the metabolic benefits of GLP-1R agonism are established, whether GIPR activation impacts weight loss through peripheral mechanisms is yet to be fully defined. Here, we generated a mouse model of GIPR induction exclusively in the adipocyte. We show that GIPR induction in the fat cell protects mice from diet-induced obesity and triggers profound weight loss (~35%) in an obese setting. Adipose GIPR further increases lipid oxidation, thermogenesis and energy expenditure. Mechanistically, we demonstrate that GIPR induction activates SERCA-mediated futile calcium cycling in the adipocyte. GIPR activation further triggers a metabolic memory effect, which maintains weight loss after the transgene has been switched off, highlighting a unique aspect in adipocyte biology. Collectively, we present a mechanism of peripheral GIPR action in adipose tissue, which exerts beneficial metabolic effects on body weight and energy balance.

Project description:While weight loss is highly recommended for obesity, promoting inflammation resolution, >80% of those who lose weight will regain it back, resulting in worsening of disease outcomes (including cardiovascular disease), relative to never having lost weight. However, how weight loss and regain directly influence atherosclerotic inflammation was unknown and investigated in this stud. Using short-term caloric restriction (stCR) in obese mice, we found that weight loss promotes atherosclerosis resolution, independently of plasma cholesterol. Mechanistically, we found that this is partly attributed to a unique subset of macrophage, distinguished by high expression of the antibody receptor Fcgr4, that accumulated in epididymal adipose tissue and plaques with stCR and help to clear necrotic cores. Interestingly, our data suggest that eWAT-derived Fcgr4 macrophages contribute to the clearance of plaque necrotic cores. On the other hand, weight regain achieved by ab libitum feeding following the stCR phase resulted in acceleration of atherosclerosis progression and disappearance of Fcgr4 macrophages from both adipose and plaques. Furthermore, weight regain caused inflammatory reprogramming of bone marrow immune progenitors, retaining hyper-inflammatory capabilities for long periods thereafter.

Project description:Time-restricted eating has shown great promise for improving metabolic health in humans with obesity, but its mechanism is still not completely resolved. In this study, we investigated how time-restricted feeding (TRF) affects microglial immunometabolism using Wistar rats. High-fat diet (HFD)-fed animals became obese, but restricting food intake to the active phase reduced fat mass, reinforced the rhythmicity of the microglial transcriptome, and prevented an increase of hypothalamic microglial cell numbers. However, TRF failed to reverse HFD-induced microglial immune dysfunction and metabolic disturbances, including suppressed electron transport chain activity, increased lipid metabolism gene expression, and impaired metabolic flexibility. These findings suggest that obesity-driven microglial immunometabolic reprogramming persists despite TRF-induced weight loss and may contribute to obesogenic memory and weight regain after weight loss induced by dietary interventions.

Project description:Obesity represents a major global healthcare crisis, with childhood obesity rising at an alarming rate. Children with obesity are highly likely to carry it into adulthood, bringing numerous associated health risks. Even more troubling is the emerging understanding of “obesity memory”, which contributes to the frequent issue of weight regain. Here, we show that obesity imprints CD4 T cells through DNA methylation, leading to a long-time lag, spanning years, before adaptive immune homeostasis is restored after weight loss. Differential DNA methylation analysis highlighted autophagy and immune senescence as key mechanisms underpinning this memory of obesity in CD4 T cells. Additionally, saturated fatty acids, in particular palmitate, drive epigenetic changes in CD4 T cells, perpetuating this altered state. Importantly, we identified molecular targets (i.e., Stk26 and Cdkn1c) underpinning key cell functions (autophagy and immune senescence) that could be targeted to promote a return to immune homeostasis alongside weight loss.

Project description:To search for genes and pathways that are involved in obesity memory, we harvested the inguinal fat after weight regain and performed gene expression profiling using mouse gene expression microarrays.

Project description:Adipose tissue retains an epigenetic memory of obesity after weight loss

Project description:Reducing body weight to improve metabolic health and related comorbidities is a primary goal in treating obesity. However, maintaining weight loss is a considerable challenge, especially as the body appears to retain an obesogenic memory that defends against body weight changes. Overcoming this barrier for long-term treatment success is difficult because the molecular mechanisms underpinning this phenomenon remain largely unknown. Here, by using single-nuclei RNA-sequencing, we show that both human and mouse adipose tissue retain cellular transcriptional changes after appreciable weight loss. Furthermore, we find persistent obesity-induced alterations in the mouse adipocyte epigenome, negatively affecting their function and response to metabolic stimuli. Mice carrying this obesogenic memory show accelerated rebound weight gain, and the epigenetic memory can explain future transcriptional deregulation in adipocytes in response to further high-fat diet feeding. In summary, our findings indicate the existence of an obesogenic memory, largely based on stable epigenetic changes, in mouse adipocytes, and likely other cell types. These changes appear to prime cells for pathological responses in an obesogenic environment, contributing to the problematic "yo-yo" effect often seen with dieting. Targeting these changes in the future could improve long-term weight management and health outcomes.