Hsiun-ing Chen

C57BL/6 and BALB/c Bronchoalveolar Macrophages Respond Differently to Exercise

Macrophages from prototypical Th1 strains (e.g., C57BL/6) and Th2 strains (e.g., BALB/c) are classified as M-1 and M-2 phenotypes. We investigated the different phagocytic responses between M-1 and M-2 bronchoalveolar macrophages (BAMs) under resting and two various exercise conditions. At rest, M-1 BAMs showed higher phagocytic capacity of unopsonized particles, higher expression of MARCO (macrophage receptor with collagenous structure), and higher generation of NO than M-2 BAMs. Severe exercise, but not moderate exercise, significantly enhanced both phagocytosis of unopsonized particles and expression of MARCO in M-2 BAMs. In contrast, M-1 BAMs were unaffected by either exercise protocol. The phagocytosis of unopsonized particles was largely mediated by MARCO, especially in M-1 BAMs. Secreted products from cultured M-2 BAMs isolated after severe exercise, but not those from M-1 BAMs, enhanced BAM phagocytosis. The cultured M-1 BAMs secreted phagocytosis inhibitors, and this effect could be blocked by NO antagonists. Moreover, the extent of phagocytosis suppression induced by M-1 BAM-secreted products correlated with their production of nitrite/nitrate. Exogenous NO donors as well as NO derivatives, nitrite and nitrate, suppressed the BAM phagocytosis. We propose that while the severe exercise-enhanced phagocytosis in M-2 BAMs was largely mediated by MARCO up-regulation and secretion of stimulators, the lack of exercise effect in M-1 BAMs could be partially due to the constitutive secretion of NO-related suppressors. In conclusion, genetically different mice use different strategies in regulating BAM activity under resting conditions and in response to various exercise paradigms.

Severe exercise enhances phagocytosis by murine bronchoalveolar macrophages.

Because physical activity affects the immune competency of individuals by an unknown mechanism, we investigated the effect of acute exercise on phagocytosis of bronchoalveolar macrophages (BAMs). Male BALB/c mice, 7–9 weeks old, ran on a treadmill to exhaustion (severe exercise, SE) or at a final speed of 17 m/min for 30 min (moderate exercise, ME). Although both exercise protocols induced differential leukocytosis, 95% leukocytes from lung lavages of both groups were BAMs. The BAM phagocytic capacity of nonopsonized beads increased immediately after SE but not after ME, gradually returning to the basal level after 4 h. SE upregulates the macrophage scavenger receptors (SR‐A type I/II and MARCO), CR3, and ICAM‐1, but not FcγR. Although the blocking effect of MARCO antibody was most pronounced, that of ICAM‐1 antibody was totally reversed by cross‐linking CR3. Our results showed that SE, but not ME, activated BAMs and that the enhanced nonopsonized phagocytosis was mainly mediated by scavenger receptors and ICAM‐1/CR3.

NO signaling in exercise training-induced anti-apoptotic effects in human neutrophils

Short-lived neutrophils play a predominant role in innate immunity, the effects of exercise training on neutrophil survival is unclear. In this study, we investigated the underlying mechanisms of training effects on human neutrophil apoptosis. Healthy male subjects were trained on a cycling ergometer for 8 weeks and followed by 4 weeks of detraining. Blood neutrophils were collected before exercise, after training, and after detraining. Comparing with pre-exercise specimens, neutrophils collected after training showed reduced apoptosis rate, which partially returned after detraining. Various intracellular proteins, including iNOS, Mcl-1, A1, Grp78, and IL-8, were upregulated by training, and they remained high after detraining. Upregulated iNOS was closely correlated with these anti-apoptotic molecules in neutrophils. Furthermore, the possible mechanism by which iNOS suppressed apoptosis was explored. Neutrophil apoptosis was accelerated by blocking and retarded by stimulating the endogenous iNOS activity. As an anti-apoptosis mediator of NO signaling, the Mcl-1 level dropped by depletion of the major NO downstream molecule cGMP and such loss of Mcl-1 was avoidable when supplying exogenous NO. Upon activation of NO-cGMP signaling, neutrophils held increased Mcl-1 expression and delayed apoptosis. Collectively, our results suggested that exercise training may retard neutrophil apoptosis by upregulating the iNOS-NO-cGMP-Mcl-1 pathway.

Polymorphonuclear leukocyte transverse migration induces rapid alterations in endothelial focal contacts

Transmigrated polymorphonuclear leukocytes (PMNs) usually undergo subendothelial transverse migration before penetrating into inner tissue layers. Whether or how endothelial cells (ECs) respond to the PMN migrating underneath them is unknown. A tissue flow chamber was used to establish a fMLP gradient and to observe PMN transverse migration along with its associated endothelial responses in culture (on a collagen gel) or in vascular tissues. Our results indicated that transversely migrating PMNs were in direct contact with the basal side of ECs. Contrasting to focal adhesion kinase (FAK) or proteins with phosphorylated tyrosine, paxillin disappeared rapidly (<1 min) from endothelial focal contacts afterencountering the leukocytes leading edge and soon rejoined them after the PMN had left. In addition, FAK moved away or became dephosphorylated when PMNs remained at the same subendothelial location for longer than 10 min, leaving actin filaments apparently unaltered. Unlike PMN transendothelial migration, PMN transverse migration did not induce any detectable endothelial calcium signaling. Taken together, our findings indicated that PMN transverse migration interrupted endothelial‐matrix interactions and induced rapid alterations in endothelial focal contact composition.