Granzyme B is a cytotoxic lymphocyte-derived protease that plays a central role in promoting apoptosis of virus-infected target cells, through direct proteolysis and activation of constituents of the cell death machinery. However, previous studies have also implicated granzymes A and B in the production of proinflammatory cytokines, via a mechanism that remains undefined. Here we show that IL-1α is a substrate for granzyme B and that proteolysis potently enhanced the biological activity of this cytokine in vitro as well as in vivo. Consistent with this, compared with full-length IL-1α, granzyme B-processed IL-1α exhibited more potent activity as an immunoadjuvant in vivo. Furthermore, proteolysis of IL-1α within the same region, by proteases such as calpain and elastase, was also found to enhance its biological potency. Thus, IL-1α processing by multiple immune-related proteases, including granzyme B, acts as a switch to enhance the proinflammatory properties of this cytokine.
Apoptosis is commonly thought to represent an immunologically silent or even anti-inflammatory mode of cell death, resulting in cell clearance in the absence of explicit activation of the immune system. However, here we show that Fas/CD95-induced apoptosis is associated with the production of an array of cytokines and chemokines, including IL-6, IL-8, CXCL1, MCP-1, and GMCSF. Fas-induced production of MCP-1 and IL-8 promoted chemotaxis of phagocytes toward apoptotic cells, suggesting that these factors serve as "find-me" signals in this context. We also show that RIPK1 and IAPs are required for optimal production of cytokines and chemokines in response to Fas receptor stimulation. Consequently, a synthetic IAP antagonist potently suppressed Fas-dependent expression of multiple proinflammatory mediators and inhibited Fas-induced chemotaxis. Thus, in addition to provoking apoptosis, Fas receptor stimulation can trigger the secretion of chemotactic factors and other immunologically active proteins that can influence immune responsiveness toward dying cells.
Despite its long record of successful use in human vaccines, the mechanisms underlying the immunomodulatory effects of alum are not fully understood. Alum is a potent inducer of interleukin-1 (IL-1) secretion in vitro in dendritic cells and macrophages via Nucleotide-binding domain and leucinerich repeat-containing (NLR) family, pyrin domain-containing 3 (NLRP3) inflammasome activation. However, the contribution of IL-1 to aluminduced innate and adaptive immune responses is controversial and the role of IL-1a following alum injection has not been addressed. This study shows that IL-1 is dispensable for alum-induced antibody and CD8 T cell responses to ovalbumin. However, IL-1 is essential for neutrophil infiltration into the injection site, while recruitment of inflammatory monocytes and eosinophils is IL-1 independent. Both IL-1a and IL-1b are released at the site of injection and contribute to the neutrophil response. Surprisingly, these effects are NLRP3-inflammasome independent as is the infiltration of other cell populations. However, while NLRP3 and caspase 1 were dispensable, alum-induced IL-1b at the injection site was dependent on the cysteine protease cathepsin S. Overall, these data demonstrate a previously unreported role for cathepsin S in IL-1b secretion, show that inflammasome formation is dispensable for alum-induced innate immunity and reveal that IL1a and IL-1b are both necessary for alum-induced neutrophil influx in vivo.
Obesity is characterized by chronic inflammation associated with neutrophil and M1 macrophage infiltration into white adipose tissue. However, the mechanisms underlying this process remain largely unknown. Based on the ability of oil-based adjuvants to induce immune responses, we hypothesized that endogenous oils derived from necrotic adipocytes may function as an immunological "danger signal." Here we show that endogenous oils of human origin are potent adjuvants, enhancing antibody responses to a level comparable to Freund's incomplete adjuvant. The endogenous oils were capable of promoting interleukin (IL)-1a-dependent recruitment of neutrophils and M1-like macrophages, while simultaneously diminishing M2-like macrophages. We found that endogenous oils from subcutaneous and omental adipocytes, and from healthy and unhealthy obese individuals, promoted comparable inflammatory responses. Furthermore, we also confirmed that white adipocytes in visceral fat of metabolically unhealthy obese (MUO) individuals are significantly larger than those in metabolically healthy obese individuals. Since adipocyte size is positively correlated with adipocyte death, we propose that endogenous oils have a higher propensity to be released from hypertrophied visceral fat in MUO individuals and that this is the key factor in driving inflammation. In summary, this study shows that adipocytes contain a potent oil adjuvant which drives IL1a-dependent proinflammatory responses in vivo.Obesity is characterized by chronic, low-grade inflammation resulting in insulin resistance. Understanding the mechanisms underlying this inflammation would provide valuable insights into the disease and potentially offer new therapeutic targets. Early studies showing that sodium salicylate can reverse the symptoms of type 2 diabetes (1) highlighted roles for inhibitor of kB kinase b (IKKb) and Jun N-terminal kinase (JNK) in this process. JNK can directly phosphorylate Serine307 on insulin receptor substrate 1, thus impairing insulin signaling and mediating obesity-induced insulin resistance (2). IKKb can also phosphorylate insulin receptor substrate 1 (3), and myeloid-specific deletion of IKKb in obese mice protects against insulin resistance (4). In addition, IKKbmediated translocation of nuclear factor-kB into the nucleus
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