Characterization of the shear stress regulation of CD18 surface expression by HL60-derived neutrophil-like cells

MicroRNA-375 modulates neutrophil chemotaxis via targeting Cathepsin B in zebrafish

Neutrophils are crucial for defense against numerous infections, and their migration and activations are tightly regulated to prevent collateral tissue damage. We previously performed a neutrophil-specific miRNA overexpression screening and identified several microRNAs, including miR-375, as potent modulators for neutrophil activity. Overexpression of miR-375 decreases neutrophil motility and migration in zebrafish and human neutrophil-like cells. We screened the genes downregulated by miR-375 in zebrafish neutrophils and identified that Cathepsin B (Ctsba) is required for neutrophil motility and chemotaxis upon tail wounding and bacterial infection. Pharmacological inhibition or neutrophil-specific knockout of ctsba significantly decreased the neutrophil chemotaxis in zebrafish and survival upon systemic bacterial infection. Notably, Ctsba knockdown in human neutrophil-like cells also resulted in reduced chemotaxis. Inhibiting integrin receptor function using RGDS rescued the neutrophil migration defects and susceptibility to systemic infection in zebrafish with either miR-375 overexpression or ctsba knockout. Our results demonstrate that miR-375 and its target Ctsba modulate neutrophil activity during tissue injury and bacterial infection in vivo, providing novel insights into neutrophil biology and the overall inflammation process.

Fluid shear-induced cathepsin B release in the control of Mac1-dependent neutrophil adhesion

There is compelling evidence that circulatory hemodynamics prevent neutrophil activation, including adhesion to microvessels, in the microcirculation. However, the underlying mechanism or mechanisms by which that mechanoregulation occurs remain unresolved. Here, we report evidence that exposure to fluid shear stress (FSS) promotes neutrophils to release cathepsin B (ctsB) and that this autocrine regulatory event is antiadhesive for neutrophils on endothelial surfaces through Mac1-selective regulation. We used a combined cell-engineering and immunocytochemistry approach to find that ctsB was capable of cleaving Mac1 integrins on neutrophils and demonstrated that this proteolysis alters their adhesive functions. Under no-flow conditions, ctsB enhanced neutrophil migration though a putative effect on pseudopod retraction rates. We also established a flow-based cell detachment assay to verify the role of ctsB in the control of neutrophil adhesion by fluid flow stimulation. Fluid flow promoted neutrophil detachment from platelet and endothelial layers that required ctsB, consistent with its fluid shear stress-induced release. Notably, compared with leukocytes from wild-type mice, those from ctsB-deficient (ctsB ^-/- ) mice exhibited an impaired CD18 cleavage response to FSS, significantly elevated baseline levels of CD18 surface expression, and an enhanced adhesive capacity to mildly inflamed postcapillary venules. Taken together, the results of the present study support a role for ctsB in a hemodynamic control mechanism that is antiadhesive for leukocytes on endothelium. These results have implications in the pathogenesis of chronic inflammation, microvascular dysfunction, and cardiovascular diseases involving sustained neutrophil activation in the blood and microcirculation.