The Role of Neuropeptide Y in Adipocyte-Macrophage Crosstalk during High Fat Diet-Induced Adipose Inflammation and Liver Steatosis

Obesity is associated with an increased risk of non-alcoholic fatty liver disease (NAFLD), which is initiated by adipocyte-macrophage crosstalk. Among the possible molecules regulating this crosstalk, we focused on neuropeptide Y (NPY), which is known to be involved in hypothalamic appetite and adipose tissue inflammation and metabolism. In this study, the NPY−/− mice showed a marked decrease in body weight and adiposity, and lower free fatty acid and adipose inflammation without food intake alteration during a high fat diet (HFD). Moreover, NPY deficiency increased the thermogenic genes expression in brown adipose tissue. Notably, NPY-mRNA expression was upregulated in macrophages from the HFD mice compared to that from the mice on a standard diet. The NPY-mRNA expression also positively correlated with the liver mass/body weight ratio. NPY deletion alleviated HFD-induced adipose inflammation and liver steatosis. Hence, our findings point toward a novel intracellular mechanism of NPY in the regulation of adipocyte-macrophage crosstalk and highlight NPY antagonism as a promising target for therapeutic approaches against obesity and NAFLD.

Abstract MP16: Perivascular Adipose Tissue Inflammation Impairs Microvascular Endothelial Function In People Living With HIV

Introduction and hypothesis: We had reported that people living with HIV (PLWH) have microvascular endothelial dysfunction and increased ROS. We now tested the hypothesis that perivascular adipose tissue (PVAT) could enhance oxidative stress and inflammation and impair the function of subcutaneous microarterioles (SMAs) in PLWH. Methods: SMAs were obtained from young, virally-suppressed HIV-infected subjects (n=11) or matched controls (n=11). Subjects were without associated CVD risk factors. Microvascular reactivity and PVAT function were accessed by myograph from isolated subcutaneous vessels with or without PVAT of skin biopsy. Results: The HIV-infected group had significantly (P<0.05) increased adipose MDA, TNFα, IL-1α, leptin and reduced adiponectin. The PVAT-denuded SMAs from the HIV group had significantly (P<0.05) impaired acetylcholine-induced endothelium-dependent relaxation factor (EDRF, 26±4 vs 38±3%) and NO activity (0.35±0.03 vs 0.58± 0.07 Δfluoresence unit) and significantly (P<0.05) increased contraction to U-46,619 (200±8 vs 141±7%) and endothelin 1 (ET1, 167±12 vs 118±17%) and ROS generation (0.32 ± 0.06 vs 0.1 ± 0.03 (E/DHE fluoresce unit). PVAT enhanced EDRF (50±4 vs 38±3 %) and NO (0.84 ±0.1 vs 0.58±0.07 Δfluoresence unit ) only in controls (P<0.05). The reduction of U46,619 anti-contractivity by PVAT is decreased in HIV (48±7 vs 85±9%, P<0.05). Conclusion: HIV-infected individuals have intrinsic vascular defects from ROS augmented by extrinsic vascular defects from adipose inflammation that impairs the beneficial microvascular PVAT signaling. Therefore, targets for potential prevention of cardiovascular morbidity in PLWH should include the elimination of ROS and inflammation in both microvessels themselves and the surrounding extravascular PVAT.

Bromodomain containing 9 (BRD9) regulates macrophage inflammatory responses by potentiating glucocorticoid receptor activity

In macrophages, homeostatic and immune signals induce distinct sets of transcriptional responses, defining cellular identity and functional states. The activity of lineage-specific and signal-induced transcription factors are regulated by chromatin accessibility and other epigenetic modulators. Glucocorticoids are potent antiinflammatory drugs; however, the mechanisms by which they selectively attenuate inflammatory genes are not yet understood. Acting through the glucocorticoid receptor (GR), glucocorticoids directly repress inflammatory responses at transcriptional and epigenetic levels in macrophages. A major unanswered question relates to the sequence of events that result in the formation of repressive regions. In this study, we identify bromodomain containing 9 (BRD9), a component of SWI/SNF chromatin remodeling complex, as a modulator of glucocorticoid responses in macrophages. Inhibition, degradation, or genetic depletion of BRD9 in bone marrow-derived macrophages significantly attenuated their responses to both liposaccharides and interferon inflammatory stimuli. Notably, BRD9-regulated genes extensively overlap with those regulated by the synthetic glucocorticoid dexamethasone. Pharmacologic inhibition of BRD9 potentiated the antiinflammatory responses of dexamethasone, while the genetic deletion of BRD9 in macrophages reduced high-fat diet-induced adipose inflammation. Mechanistically, BRD9 colocalized at a subset of GR genomic binding sites, and depletion of BRD9 enhanced GR occupancy primarily at inflammatory-related genes to potentiate GR-induced repression. Collectively, these findings establish BRD9 as a genomic antagonist of GR at inflammatory-related genes in macrophages, and reveal a potential for BRD9 inhibitors to increase the therapeutic efficacies of glucocorticoids.

Multiomics reveals persistence of obesity-associated immune cell phenotypes in adipose tissue during weight loss and subsequent weight regain

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. Thus, we have created an open-access interactive portal for our processed data to improve accessibility for the research community.

Metabolic endotoxemia is dictated by the type of lipopolysaccharide

Lipopolysaccharides (LPS) can promote metabolic endotoxemia, which is considered inflammatory and metabolically detrimental based on Toll-like receptor (TLR)4 agonists such as Escherichia coli-derived LPS. LPS from certain bacteria antagonize TLR4 yet contribute to endotoxemia measured by Endotoxin Units (EU). We found that E. coli LPS impaired gut barrier function and worsened glycemic control in mice, but equal doses of LPS from other bacteria did not. Matching the LPS dose from R. sphaeroides and E. coli by EU revealed that only E. coli LPS promoted dysglycemia, adipose inflammation, delayed intestinal glucose absorption, and augmented insulin and GLP-1 secretion. Metabolically beneficial endotoxemia promoted by R. sphaeroides LPS counteracted dysglycemia caused by an equal dose of E. coli LPS and promoted insulin sensitivity in obese mice. The concept of metabolic endotoxemia should be expanded beyond LPS load (EU) to include LPS characteristics, where the balance of deleterious and beneficial endotoxemia regulates host metabolism.

Adipocyte-Derived Lactate Potentiates Obesity-Evoked Adipose Macrophage Inflammation

Introduction: Obesity is characterized by mobilization of macrophage inflammation, which represents the major events of obesity-associated adipose tissue inflammation. . On the other hand, lactate accumulation in adipose tissue long been observed. However, whether elevation of lactate plays an essential role in adipose inflammation is not known. In this study, we sought to examine the intermediary role of lactate in macrophage polarization and adipose inflammation upon obesity. Method: Lactate level and activity of lactate dehydrogense (LDH), the key enzyme of lactate production, were measured by biochemical assays. Adipocyte- and macrophage- specific Ldha knock out mice were constructed by cre-LoxP system to study the physiological role of lactate in diet induced obesity. Macrophage polarization and inflammation were examined by western blotting and Q-PCR. Results: Lactate and LDH activity were selectively upregulated in adipose tissues of obese mice. Adipocyte-, but not macrophage-selective deletion of LDHA, led to a significant improvement of adipose inflammation and metabolic dysfunctions. In vitro experiments showed that the lactate promoted M1 polarization through direct interation and inhibition of the PHD2, which subsequently stabilizes HIF-1alpha. In addition, a positive correlation between adipose lactate level and adipose tissue inflammation was found in obese patients. Conclusion: In obese condition, increased production of lactate from adipocytes enhances adipose tissue inflammation by promoting the proinflammatory polarization of adipose macrophages.

Review: Obesity and COVID-19: A Detrimental Intersection

Obesity has been recognized as an independent risk factor for critical illness and major severity in subjects with coronavirus disease 2019 (COVID-19). The role of fat distribution, particularly visceral fat (often linked to metabolic abnormalities), is still unclear. The adipose tissue represents a direct source of cytokines responsible for the pathological modifications occurring within adipose tissue in obese subjects. Adipokines are a crucial connection between metabolism and immune system: their dysregulation in obesity contributes to chronic low-grade systemic inflammation and metabolic comorbidities. Therefore the increased amount of visceral fat can lead to a proinflammatory phenotypic shift. This review analyzes the interrelation between obesity and COVID-19 severity, as well as the cellular key players and molecular mechanisms implicated in adipose inflammation, investigating if adipose tissue can constitute a reservoir for viral spread, and contribute to immune activation and cytokines storm. Targeting the underlying molecular mechanisms might have therapeutic potential in the management of obesity-related complications in COVID-19 patients.

ICOS signaling limits regulatory T cell accumulation and function in visceral adipose tissue

A unique population of Foxp3+ regulatory T cells (TRs) resides in visceral adipose tissue (VAT) that regulates adipose inflammation and helps preserve insulin sensitivity. Inducible T cell co-stimulator (ICOS) is highly expressed on effector (e)TRs that migrate to nonlymphoid tissues, and contributes to their maintenance and function in models of autoimmunity. In this study, we report an unexpected cell-intrinsic role for ICOS expression and downstream phosphoinositide 3-kinase (PI3K) signaling in limiting the abundance, VAT-associated phenotype, and function of TRs specifically in VAT. Icos−/− mice and mice expressing a knock-in form of ICOS that cannot activate PI3K had increased VAT-TR abundance and elevated expression of canonical VAT-TR markers. Loss of ICOS signaling facilitated enhanced accumulation of TRs to VAT associated with elevated CCR3 expression, and resulted in reduced adipose inflammation and heightened insulin sensitivity in the context of a high-fat diet. Thus, we have uncovered a new and surprising molecular pathway that regulates VAT-TR accumulation and function.