Figure 3. p4 exhibits rapid concentration-dependent lytic activity against E. coli. A, E. coli HB101 was incubated with the indicated concentrations of p4 for 2 h. Cell viability was analyzed by MDA assay. n ϭ 3, mean Ϯ S.D. B, E. coli HB101 was incubated with 100 M p4 or vehicle for the indicated times. Cell viability was analyzed by MDA assay, n ϭ 3; mean Ϯ S.D. C, human erythrocytes were incubated with 1% Triton X-100, the indicated concentration of p4, or vehicle for 2 h. Hemolysis of erythrocytes is shown relative to lysis caused by Triton X-100. n ϭ 3, mean Ϯ S.D. D, E. coli HB101 was incubated with 100 M p4 or vehicle for the indicated times. Bacterial morphology was assessed by TEM. E, E. coli HB101 was incubated with 100 M p4 for 5 min. Alterations in bacterial permeability were visualized by fluorescence imaging. Bacteria were treated with FITC-labeled p4 (green), stained with PI (red), and counterstained with Hoechst to visualize DNA (blue). Arrows point to accumulation of p4 at the cell surface. F, -galexpressing E. coli JM83 was incubated with the indicated concentrations of p4 for 15 min. The -gal activity present in supernatants of p4-treated bacteria is shown as a percentage of the vehicle-treated bacteria. n ϭ 3, mean Ϯ S.D. G, E. coli HB101 was treated with p4 for 45 min, followed by TEM. Arrows and asterisks indicate outer membrane perturbations and the discontinuous inner membrane, respectively. H, intracellular localization of p4 is shown by immunogold labeling. E. coli HB101 was treated with biotin-p4 or p4 as a control, fixed, and stained with mouse anti-biotin Abs, followed by anti-mouse Abs conjugated to gold particles. Arrowheads indicate gold particles. The enlarged image (i) demonstrates interaction of p4 with the cell membrane. ***, p Ͻ 0.001; **, p Ͻ 0.01; *, p Ͻ 0.05 by Kruskal-Wallis one-way ANOVA with post hoc Dunn's test. TEM and fluorescence microscopy images are from one experiment and are representative of at least three experiments.
Neutrophils are broadly classified into conventional neutrophils (PMNs) and low-density granulocytes (LDGs). LDGs are better than PMNs at generating neutrophil extracellular traps (NETs), which may contribute to the pathology of autoimmune diseases. We hypothesized that LDGs and PMNs differ in their levels of unrestrained NE that supports NET generation. Here, we show that individuals with psoriasis contain elevated levels of LDGs and that in contrast to PMNs, the LDGs display higher staining for NE and lower staining for its inhibitor SLPI. The heterogeneity between blood-derived LDGs and PMNs was somewhat reminiscent of the differences in the NE and SLPI staining patterns observed in psoriasis skin-infiltrating neutrophils. Distinctive staining for NE and SLPI in LDGs and PMNs did not result from differences in their protein levels nor manifested in higher total proteolytic activity of NE in LDGs; rather, it likely depended on different cytosolic sequestration of these proteins. The disparate profile of NE and SLPI in LDGs and PMNs coincided with altered migratory responses of these cells to cutaneous chemoattractants. Collectively, differential NE and SLPI staining identifies common attributes of both circulating and skin-infiltrating neutrophils, which may guide neutrophil migration to distinct skin regions and determine the localization of LDGs-mediated cutaneous pathology.
Chemerin is a chemoattractant protein with adipokine properties encoded by the retinoic acid receptor responder 2 (RARRES2) gene. it has gained more attention in the past few years due to its multilevel impact on metabolism and immune responses. However, mechanisms controlling the constitutive and regulated expression of RARRES2 in a variety of cell types remain obscure. To our knowledge, this report is the first to show that DNA methylation plays an important role in the cell-specific expression of RARRES2 in adipocytes, hepatocytes, and B lymphocytes. Using luciferase reporter assays, we determined the proximal fragment of the RARRES2 gene promoter, located from − 252 to + 258 bp, to be a key regulator of transcription. Moreover, we showed that chemerin expression is regulated in murine adipocytes by acute-phase cytokines, interleukin 1β and oncostatin M. in contrast with adipocytes, these cytokines exerted a weak, if any, response in mouse hepatocytes, suggesting that the effects of IL-1β and OSM on chemerin expression is specific to fat tissue. Together, our findings highlight previously uncharacterized mediators and mechanisms that control chemerin expression. Chemerin is a small (18 kDa) multifunctional protein capable of regulating different biological processes, including immune cell migration, adipogenesis, osteoblastogenesis, angiogenesis, myogenesis, and glucose homeostasis 1. Moreover, it shows broad-spectrum antimicrobial activity in both human and mouse epidermis, suggesting it plays a role in maintaining skin-barrier homeostasis 2,3. Chemerin-induced signaling is mediated predominantly through chemokine-like receptor 1 (CMKLR1), which is expressed by many cells including plasmacytoid dendritic cells (pDCs), macrophages, natural killer (NK) cells, adipocytes, hepatocytes, and keratinocytes 2,4-9. Chemerin is secreted as pro-chemerin and circulates in plasma as an inactive precursor protein (Chem163S) that can subsequently be activated through posttranslational carboxyl-terminal processing by a variety of proteinases 10,11. The gene encoding chemerin is known as retinoic acid receptor responder 2 (RARRES2) 12 , or as tazaroteneinduced gene 2 (TIG2) given it was first discovered in tazarotene-treated psoriatic skin lesions 13,14. Liver and adipose tissue are reported to be the major sites of chemerin production; nonetheless, RARRES2 mRNA is detectable in many other tissues, including the adrenal glands, ovaries, pancreas, lungs, kidney, and skin 2,15. Chemerin
Periodontal inflammation is one of the most common chronic inflammatory conditions in humans. Despite recent advances in identifying and characterizing oral microbiota dysbiosis in the pathogenesis of gum disease, just how host factors maintain a healthy homeostatic oral microbial community or prevent the development of a pathogenic oral microbiota remains poorly understood. An important determinant of microbiota fate is local antimicrobial proteins. Here, we report that chemoattractant protein chemerin, which we recently identified as a potent endogenous antimicrobial agent in body barriers such as the skin, is present in the oral cavity under homeostatic and inflammatory conditions. Chemerin and a chemerin-derived antimicrobial peptide are bactericidal against select bacteria strategically positioned in dental biofilm. Gingival crevicular samples from patients with gingivitis but not periodontitis contain abundant bioactive chemerin capable of inducing CMKLR1-dependent leukocyte migration. Gingipains secreted by the periodontopathogen P. gingivalis inactivate chemerin. Together, these data suggest that as an antimicrobial agent and leukocyte chemoattractant, chemerin likely contributes to antimicrobial immune defense in the oral cavity.
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