Chronic inflammation characterized by T cell and macrophage infiltration of visceral adipose tissue (VAT) is a hallmark of obesity associated insulin resistance and glucose intolerance. Here we demonstrate a fundamental pathogenic role for B cells in the development of these metabolic abnormalities. B cells accumulate in VAT in diet induced obese (DIO) mice, and DIO mice lacking B cells are protected from disease despite weight gain. B cell effects on glucose metabolism are mechanistically linked to activation of pro-inflammatory macrophages and T cells, and production of pathogenic IgG antibodies. Treatment with a B cell-depleting CD20 antibody attenuates disease, while transfer of DIO-IgG rapidly induces insulin resistance and glucose intolerance. Moreover, insulin resistance in obese humans is associated with a unique profile of IgG autoantibodies. These results establish the importance of B cells and adaptive immunity in insulin resistance and suggest new diagnostic and therapeutic modalities to manage the disease.
In silico quantification of cell proportions from mixed-cell transcriptomics data (deconvolution) requires a reference expression matrix, called basis matrix. We hypothesize that matrices created using only healthy samples from a single microarray platform would introduce biological and technical biases in deconvolution. We show presence of such biases in two existing matrices, IRIS and LM22, irrespective of deconvolution method. Here, we present immunoStates, a basis matrix built using 6160 samples with different disease states across 42 microarray platforms. We find that immunoStates significantly reduces biological and technical biases. Importantly, we find that different methods have virtually no or minimal effect once the basis matrix is chosen. We further show that cellular proportion estimates using immunoStates are consistently more correlated with measured proportions than IRIS and LM22, across all methods. Our results demonstrate the need and importance of incorporating biological and technical heterogeneity in a basis matrix for achieving consistently high accuracy.
Interleukin (IL)-9-producing CD4+ T cells are a novel subset of T helper (Th) cells that develops independently of the Th1, Th2, Th17 and regulatory T-cell lineages. Similar to the murine model, transforming growth factor (TGF)-β and IL-4 directed human naive CD4+ T cells to produce IL-9. Whereas IL-4 suppressed TGF-β-induced Foxp3 expression, TGF-β failed to inhibit IL-4-mediated upregulation of the Th2 transcription factor GATA-3. Addition of IL-1β, IL-6, IL-10, interferon (IFN)-α, IFN-β or IL-21 to Th9-polarizing conditions augmented Th9 differentiation, while the Th1-associated cytokines IFN-γ and IL-27 partially suppressed IL-9 production. Given that T cells are a primary source of IL-21, IL-21 expression was analyzed under Th9-polarizing conditions in the context of inflammatory cytokines. Surprisingly, type I IFNs induced elevated levels of IL-21, and blockade of IL-21 abrogated their ability to enhance Th9 differentiation. Taken together, these data indicate a complex cytokine network in the regulation of human IL-9-producing CD4+ T cells.
Obesity-associated insulin resistance, a common precursor of type 2 diabetes, is characterized by chronic inflammation of tissues, including visceral adipose tissue (VAT). Here we show that B-1a cells, a subpopulation of B lymphocytes, are novel and important regulators of this process. B-1a cells are reduced in frequency in obese high-fat diet (HFD)-fed mice, and EGFP interleukin-10 (IL-10) reporter mice show marked reductions in anti-inflammatory IL-10 production by B cells in vivo during obesity. In VAT, B-1a cells are the dominant producers of B cell–derived IL-10, contributing nearly half of the expressed IL-10 in vivo. Adoptive transfer of B-1a cells into HFD-fed B cell–deficient mice rapidly improves insulin resistance and glucose tolerance through IL-10 and polyclonal IgM-dependent mechanisms, whereas transfer of B-2 cells worsens metabolic disease. Genetic knockdown of B cell–activating factor (BAFF) in HFD-fed mice or treatment with a B-2 cell–depleting, B-1a cell–sparing anti-BAFF antibody attenuates insulin resistance. These findings establish B-1a cells as a new class of immune regulators that maintain metabolic homeostasis and suggest manipulation of these cells as a potential therapy for insulin resistance.
Cytokines dimerize their receptors, with binding of the “second chain” triggering signaling. In the interleukin (IL)-4/13 system, different cell types express varying levels of alternative second receptor chains (γc or IL-13Rα1), forming functionally distinct Type-I or Type-II complexes. We manipulated the affinity and specificity of second chain recruitment by human IL-4. A Type-I receptor-selective IL-4 ‘superkine’ with 3700-fold higher affinity for γc was 3-10 fold more potent than wild-type IL-4. Conversely, a variant with high affinity for IL-13Rα1 more potently activated cells expressing the Type-II receptor, and induced differentiation of dendritic cells from monocytes, implicating the Type-II receptor in this process. Superkines exhibited signaling advantages on cells with lower second chain levels. Comparative transcriptional analysis reveals that the superkines induce largely redundant gene expression profiles. Variable second chain levels can be exploited to redirect cytokines towards distinct cell subsets and elicit novel actions, potentially improving the selectivity of cytokine therapy.
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