Grace Bennett

Dynamic, M2-like Remodeling Phenotypes of CD11c+ Adipose Tissue Macrophages During High Fat Diet-Induced Obesity in Mice

OBJECTIVE To identify, localize, and determine M1/M2 polarization of epidydimal adipose tissue (eAT) macrophages (Φs) during high-fat diet (HFD)-induced obesity. RESEARCH DESIGN AND METHODS Male C57BL/6 mice were fed an HFD (60% fat kcal) or low-fat diet (LFD) (10% fat kcal) for 8 or 12 weeks. eATMΦs (F4/80+ cells) were characterized by in vivo fluorescent labeling, immunohistochemistry, fluorescence-activated cell sorting, and quantitative PCR. RESULTS Recruited interstitial macrophage galactose-type C-type lectin (MGL)1+/CD11c− and crown-like structure–associated MGL1−/CD11c+ and MGL1med/CD11c+ eATMΦs were identified after 8 weeks of HFD. MGL1med/CD11c+ cells comprised ∼65% of CD11c+ eATMΦs. CD11c+ eATMΦs expressed a mixed M1/M2 profile, with some M1 transcripts upregulated (IL-12p40 and IL-1β), others downregulated (iNOS, caspase-1, MCP-1, and CD86), and multiple M2 and matrix remodeling transcripts upregulated (arginase-1, IL-1Ra, MMP-12, ADAM8, VEGF, and Clec-7a). At HFD week 12, each eATMΦ subtype displayed an enhanced M2 phenotype as compared with HFD week 8. CD11c+ subtypes downregulated IL-1β and genes mediating antigen presentation (I-a, CD80) and upregulated the M2 hallmark Ym-1 and genes promoting oxidative metabolism (PGC-1α) and adipogenesis (MMP-2). MGL1med/CD11c+ eATMΦs upregulated additional M2 genes (IL-13, SPHK1, CD163, LYVE-1, and PPAR-α). MGL1med/CD11c+ ATMΦs expressing elevated PGC-1α, PPAR-α, and Ym-1 transcripts were selectively enriched in eAT of obese mice fed pioglitazone for 6 days, confirming the M2 features of the MGL1med/CD11c+ eATMΦ transcriptional profile and implicating PPAR activation in its elicitation. CONCLUSIONS These results 1) redefine the phenotypic potential of CD11c+ eATMΦs and 2) suggest previously unappreciated phenotypic and functional commonality between murine and human ATMΦs in the development of obesity and its complications.

Dietary Blueberry Attenuates Whole-Body Insulin Resistance in High Fat-Fed Mice by Reducing Adipocyte Death and Its Inflammatory Sequelae

Adipose tissue (AT) inflammation promotes insulin resistance (IR) and other obesity complications. AT inflammation and IR are associated with oxidative stress, adipocyte death, and the scavenging of dead adipocytes by proinflammatory CD11c+ AT macrophages (ATMPhi). We tested the hypothesis that supplementation of an obesitogenic (high-fat) diet with whole blueberry (BB) powder protects against AT inflammation and IR. Male C57Bl/6j mice were maintained for 8 wk on 1 of 3 diets: low-fat (10% of energy) diet (LFD), high-fat (60% of energy) diet (HFD) or the HFD containing 4% (wt:wt) whole BB powder (1:1 Vaccinium ashei and V. corymbosum) (HFD+B). BB supplementation (2.7% of total energy) did not affect HFD-associated alterations in energy intake, metabolic rate, body weight, or adiposity. We observed an emerging pattern of gene expression in AT of HFD mice indicating a shift toward global upregulation of inflammatory genes (tumor necrosis factor-alpha, interleukin-6, monocyte chemoattractant protein 1, inducible nitric oxide synthase), increased M1-polarized ATMPhi (CD11c+), and increased oxidative stress (reduced glutathione peroxidase 3). This shift was attenuated or nonexistent in HFD+B-fed mice. Furthermore, mice fed the HFD+B were protected from IR and hyperglycemia coincident with reductions in adipocyte death. Salutary effects of BB on adipocyte physiology and ATMPhi gene expression may reflect the ability of BB anthocyanins to alter mitogen-activated protein kinase and nuclear factor-kappaB stress signaling pathways, which regulate cell fate and inflammatory genes. These results suggest that cytoprotective and antiinflammatory actions of dietary BB can provide metabolic benefits to combat obesity-associated pathology.

T Cell Recruitment and Th1 Polarization in Adipose Tissue During Diet-Induced Obesity in C57BL/6 mice

The role of adaptive immunity in obesity‐associated adipose tissue (AT) inflammation and insulin resistance (IR) is controversial. We employed flow cytometry and quantitative PCR to assess T‐cell recruitment and activation in epididymal AT (eAT) of C57BL/6 mice during 4–22 weeks of a high‐fat diet (HFD (60% energy)). By week 6, eAT mass and stromal vascular cell (SVC) number increased threefold in mice fed HFD, coincident with onset of IR. We observed no increase in the proportion of CD3+ SVCs or in gene expression of CD3, interferon‐γ (IFN‐γ), or regulated upon activation, normal T‐cell expressed and secreted (RANTES) during the first 16 weeks of HFD. In contrast, CD11c+ macrophages (MΦ) were enriched sixfold by week 8 (P < 0.01). SVC enrichment for T cells (predominantly CD4+ and CD8+) and elevated IFN‐γ and RANTES gene expression were detected by 20–22 weeks of HFD (P < 0.01), coincident with the resolution of eAT remodeling. HFD‐induced T‐cell priming earlier in the obesity time course is suggested by (i) elevated (fivefold) interleukin‐12 (IL‐12)p40 gene expression in eAT by week 12 (P ≤ 0.01) and (ii) greater IFN‐γ secretion from phorbol myristate acetate (PMA)/ionophore‐stimulated eAT explants at week 6 (onefold, P = 0.08) and week 12 (fivefold, P < 0.001). In conclusion, T‐cell enrichment and IFN‐γ gene induction occur subsequent to AT macrophage (ATMΦ) recruitment, onset of IR and resolution of eAT remodeling. However, enhanced priming for IFN‐γ production suggests the contribution of CD4+ and/or CD8+ effectors to cell‐mediated immune responses promoting HFD‐induced AT inflammation and IR.

Diet-induced obesity elevates colonic TNF-α in mice and is accompanied by an activation of Wnt signaling: a mechanism for obesity-associated colorectal cancer

Inflammation associated with obesity may play a role in colorectal carcinogenesis, but the underlying mechanism remains unclear. This study investigated whether the Wnt pathway, an intracellular signaling cascade that plays a critical role in colorectal carcinogenesis, is activated by obesity-induced elevation of the inflammatory cytokine tumor necrosis factor-alpha (TNF-α). Animal studies were conducted on C57BL/6 mice, and obesity was induced by utilizing a high-fat diet (60% kcal). An inflammation-specific microarray was performed, and results were confirmed with real-time polymerase chain reaction. The array revealed that diet-induced obesity increased the expression of TNF-α in the colon by 72% (P=.004) and that of interleukin-18 by 41% (P=.023). The concentration of colonic TNF-α protein, determined by ex vivo culture assay, was nearly doubled in the obese animals (P=.002). The phosphorylation of glycogen synthase kinase 3 beta (GSK3β), an important intermediary inhibitor of Wnt signaling and a potential target of TNF-α, was quantitated by immunohistochemistry. The inactivated (phosphorylated) form of GSK3β was elevated in the colonic mucosa of obese mice (P<.02). Moreover, β-catenin, the key effector of canonical Wnt signaling, was elevated in the colons of obese mice (P<.05), as was the expression of a downstream target gene, c-myc (P<.05). These data demonstrate that diet-induced obesity produces an elevation in colonic TNF-α and instigates a number of alterations of key components within the Wnt signaling pathway that are protransformational in nature. Thus, these observations offer evidence for a biologically plausible avenue, the Wnt pathway, by which obesity increases the risk of colorectal cancer.

Adipose tissue inflammation and reduced insulin sensitivity in ovariectomized mice occurs in the absence of increased adiposity.

Menopause promotes central obesity, adipose tissue (AT) inflammation, and insulin resistance (IR). Both obesity and the loss of estrogen can activate innate and adaptive immune cells (macrophages, T cells). The respective impacts of weight gain and loss of ovarian hormones on AT inflammation and IR are poorly understood. Here we determined the temporal kinetics of fat accretion, AT inflammation, and IR over a 26-wk time course in ovariectomized (OVX) mice, a model of menopause. OVX and sham-operated (SHM) C57BL6 mice were fed a normal chow diet. Weight, body composition (magnetic resonance imaging), total and regional adiposity, activity, food intake, AT crown-like structures, biohumoral measures, and insulin sensitivity (insulin tolerance testing and homeostatic model assessment) were determined at wk 12, 20, and 26. Macrophages and T cells from perigonadal AT were immunophenotyped by fluorescence-associated cell sorting, and perigonadal adipose tissue (PGAT) gene expression was quantified by quantitative PCR. OVX mice (≈ 31 g) became fatter than SHM mice (≈ 26 g) by wk 12, but mice were equally insulin sensitive. PGAT of OVX mice contained more T cells but expressed higher levels of M2-MΦ (arginase-1) and T cell-regulatory (cytotoxic T-lymphocyte antigen 4) genes. At wk 20, both OVX and SHM mice weighed approximately 35 g and were equally insulin sensitive with comparable amounts of PGAT and total body fat. OVX mice became less insulin sensitive than SHM mice by wk 26, coincident with the down-regulation of PGAT arginase-1 (-20-fold) and cytotoxic T-lymphocyte antigen 4 (2-fold) and up-regulation of M1/Th1 genes CD11c (+2-fold), IL12p40 (+2-fold), and interferon-γ (+78-fold). Ovarian hormone loss in mice induces PGAT inflammation and IR by mechanisms that can be uncoupled from OVX-induced obesity.

Deletion of TNF-like weak inducer of apoptosis (TWEAK) protects mice from adipose and systemic impacts of severe obesity.

To investigate the role of TNF‐like weak inducer of apoptosis (TWEAK) in pathological adipose tissue (AT) remodeling and complications of obesity.

Bad Fat or Just More Fat? Murine Models of Metabolically Healthy Obesity

Worldwide obesity has more than doubled since 1980, with more than 500 million individuals currently obese (BMI > 30) [1]. The potential public health, economic and social impacts of this “epidemic” are daunting, as obesity is an independent risk factor for debilitating comorbidities, including type 2 diabetes mellitus (T2DM), cardiovascular disease (CVD), stroke, nonalcoholic steatohepatitis (NASH), certain cancers, and overall mortality [2, 3]. These comorbidities reflect in large part the metabolic dysregulation that typifies the chronically obese state. Intriguingly, however, a significant proportion (25 %) of obese individuals remains relatively protected from metabolic complications typically associated with obesity [4]. This group, referred to as the metabolically healthy obese (MHO) remain insulin sensitive with favorable hormonal and liver enzyme profiles in the relative absence of hypertension, dyslipidemia, and/or inflammation [2, 4–13]. Criteria for defining “metabolic health” in MHO individuals vary in the literature. As a rule, however, the criteria are based on the absence or “below cutoff” values for cardiometabolic risk factors, metabolic syndrome hallmarks or insulin resistance in individuals with BMI > 30 [14–16]. Independent of the criteria used to assess MHO, the metabolic profiles of these individuals approximate those of young lean individuals [17] and have been longitudinally associated with reduced incidences of T2DM and cardiovascular disease. Accordingly, elucidating the factors that underlie the MHO phenotype is an important undertaking.