Roles of neutrophils in the regulation of the extent of human inflammation through delivery of IL-1 and clearance of chemokines

This study examined the establishment of neutrophilic inflammation in humans. We tested the hypotheses that neutrophil recruitment was associated with local CXCL8 production and that neutrophils themselves might contribute to the regulation of the size of the inflammatory response. Humans were challenged i.d. with endotoxin. Biopsies of these sites were examined for cytokine production and leukocyte recruitment by qPCR and IHC. Additional in vitro models of inflammation examined the ability of neutrophils to produce and sequester cytokines relevant to neutrophilic inflammation. i.d. challenge with 15 ng of a TLR4-selective endotoxin caused a local inflammatory response, in which 1% of the total biopsy area stained positive for neutrophils at 6 h, correlating with 100-fold up-regulation in local CXCL8 mRNA generation. Neutrophils themselves were the major source of the early cytokine IL-1β. In vitro, neutrophils mediated CXCL8 but not IL-1β clearance (>90% clearance of ≤2 nM CXCL8 over 24 h). CXCL8 clearance was at least partially receptor-dependent and modified by inflammatory context, preserved in models of viral infection but reduced in models of bacterial infection. In conclusion, in a human inflammatory model, neutrophils are rapidly recruited and may regulate the size and outcome of the inflammatory response through the uptake and release of cytokines and chemokines in patterns dependent on the underlying inflammatory stimulus

Bone marrow MyD88 signaling modulates neutrophil function and ischemic myocardial injury

Myeloid differentiation factor 88 (MyD88), an adaptor critical for innate immune function, plays a role in neutrophil recruitment and myocardial injury after transient ischemia. However, how MyD88 signaling modulates neutrophil function and myocardial injury remains unclear. In an in vivo model of neutrophil migration and a chimeric model of MyD88 deletion, we demonstrated that Gr-1-positive (Gr-1+) neutrophil migration was significantly decreased by 68% in MyD88-deficient (Myd88−/−) mice and by 33% in knockout→wild-type (KO→WT; donor→recipient) chimeric mice, which lacked MyD88 in bone marrow cells but maintained normal MyD88 expression in the heart. This marked attenuation in neutrophil migration was associated with decreased peritoneal neutrophil CXCR2 expression and lower peritoneal KC, a neutrophil chemoattractant, in MyD88−/− mice. Moreover, in vitro, KC induces significantly more downregulation of CXCR2 expression in MyD88−/− than WT neutrophils. In an in vivo model of myocardial ischemia-reperfusion (I/R) injury, KO→WT chimeric mice had significantly smaller infarct sizes compared with the WT→WT mice. While there was a marked increase in proinflammatory cytokine/chemokine expression in the myocardium following I/R, there was no significant difference between WT→WT and KO→WT mice. In contrast, Gr-1+ neutrophil recruitment in the myocardium was markedly attenuated in MyD88−/− mice. Deletion of Toll-interleukin-1 receptor (TIR)-domain-containing adaptor protein-inducing interferon-β-mediated transcription factor (Trif), another innate immune adaptor, had no effect on the KC-mediated CXCR2 downregulation or on myocardial neutrophil recruitment after I/R. Taken together, these findings suggest that MyD88 signaling is essential for maintaining neutrophil migratory function and chemokine receptor expression. MyD88 signaling in bone marrow-derived circulating cells may play a specific and critical role in the development of myocardial I/R-induced injury

Ozone production by amino acids contributes to killing of bacteria

Reactive oxygen species produced by phagocytosing neutrophils are essential for innate host defense against invading microbes. Previous observations revealed that antibody-catalyzed ozone formation by human neutrophils contributed to the killing of bacteria. In this study, we discovered that 4 amino acids themselves were able to catalyze the production of an oxidant with the chemical signature of ozone from singlet oxygen in the water-oxidation pathway, at comparable level to antibodies. The resultant oxidant with the chemical signature of ozone exhibited significant bactericidal activity in our distinct cell-free system and in human neutrophils. The results also suggest that an oxidant with the chemical signature of ozone produced by neutrophils might potentiate a host defense system, when the host is challenged by high doses of infectious agents. Our findings provide biological insights into the killing of bacteria by neutrophils