Heparin-binding protein decreases apoptosis in human and murine neutrophils.

BACKGROUND: Heparin-binding protein (HBP), a serine protease without any known proteolytic activity, is found in human polymorphonuclear leukocyte (PMN) granules, but not in mice. HBP potentiates the endotoxin-induced release of tumor necrosis factor (TNF) alpha, interleukin (IL)-1, and IL-6 from isolated monocytes. HBP has also been shown to increase the survival of cultured monocytes and protect them from oxidative stress. However, whether HBP affects PMNs themselves is not known. MATERIALS AND METHODS: Based on our work with cultured monocytes and the survival benefit noted in experimental peritonitis, we hypothesized that HBP would have a beneficial effect on the survival of neutrophils. We evaluated the effect of HBP on apoptosis in murine peritoneal exudative cells elicited by intraperitoneal thioglycollate administration and in normal human neutrophils from volunteers. Leukocytes were isolated from the peritoneal cavity and blood of mice that underwent intraperitoneal thioglycollate instillation. The mouse peritoneal exudate cells and normal human neutrophils isolated from peripheral blood were used to study the effect of HBP on survival and apoptosis. RESULTS: HBP decreased percentage apoptosis of mouse cells in both serum-enriched (from 24.8 to 4.5%) and serum-deprived (from 23.1 to 8.2%) cultures. In human PMNs, the protective effect of HBP was seen only in the serum-deprived group, with a decrease in percentage apoptosis from 69.1 to 43.3%. CONCLUSIONS: For the first time, we have shown that HBP, in addition to its known augmentation of the proinflammatory response of monocytes, also acts as a prosurvival protein for neutrophils themselves, and thereby enhances local host defense.

Neutrophil sequestration in liver and lung is differentially regulated by C-X-C chemokines during experimental peritonitis.

C-X-C chemokines play an important role in the migration and activation of neutrophils (PMNs) during an inflammatory event. We measured mRNA and protein expression of the murine C-X-C chemokines macrophage inflammatory protein-2 (MIP-2) and KC in the lungs, liver, blood, and peritoneal cavity of Swiss Webster mice after cecal ligation and puncture (CLP). Neutralizing antibodies to MIP-2 and KC were also used to determine the biological effects of these chemokines on neutrophil sequestration and organ injury in the CLP model. The data showed that early after CLP, MIP-2 mRNA and protein were expressed predominantly by the lung, whereas KC mRNA and protein were expressed by the liver. Inhibition of MIP-2 reduced both lung neutrophil sequestration and peritoneal neutrophil migration. Inhibition of KC had no effect on overall neutrophil sequestration in liver but reduced injury as measured by serum transaminases. An early survival benefit was found with anti-KC treatment, although overall survival was not different. Our study showed a differential expression by organs of C-X-C chemokines during sepsis and suggested that such chemokine effects are tissue-specific.

Regulation of early peritoneal neutrophil migration by macrophage inflammatory protein-2 and mast cells in experimental peritonitis.

Neutrophil (PMN) migration into the peritoneal cavity in response to fecal peritonitis is an important mechanism of host defense against bacterial invasion. We show that the murine C-X-C (PMN-specific) chemokine, macrophage inflammatory protein-2 (MIP-2), on intraperitoneal injection in mice, causes PMN migration into the peritoneum. MIP-2 mRNA and protein were expressed by peritoneal leukocytes after cecal ligation and puncture (CLP) in mice and neutralization of MIP-2 reduced peritoneal PMN migration. A prerequisite for neutrophil-endothelial adhesion and subsequent migration from the circulation is selectin-mediated rolling. Pretreatment of mice with an anti-P-selectin antibody before intraperitoneal injection of MIP-2 significantly reduced peritoneal PMN migration. However, there are no reports that a C-X-C chemokine can up-regulate endothelial selectins. We postulated that MIP-2, when injected intraperitoneally, interacts with a cell that is known to release factors that up-regulate endothelial selectins. A likely candidate is the mast cell, which contains histamine and tumor necrosis factor alpha (TNF-alpha), and both of these factors induce selectins. Intraperitoneally injected MIP-2 caused an early significant increase in peritoneal TNF-alpha, whereas histamine levels were unaffected. In a subsequent experiment, mast cell-deficient mice and their normal controls were then injected intraperitoneally with MIP-2 or underwent CLP. Significantly fewer PMNs migrated into the peritoneal cavity in the mast cell-deficient mice after MIP-2 injection or CLP. Thus, our findings indicate that mast cells and MIP-2 are necessary for PMN migration into the peritoneum in response to intra-abdominal infection, and that MIP-2 appears to facilitate this through an increase in TNF-alpha release.

Neutrophil migration into the peritoneum is P-selectin dependent, but sequestration in lungs is selectin independent during peritonitis.

Neutrophil (PMN) influx into the peritoneal cavity in response to bacterial peritonitis is an indispensable aspect of host defense. PMNs also are responsible for the remote organ injury observed after major abdominal infection. The aim of this study was to examine the effect of selectin blockade on PMN migration into the peritoneum and on PMN sequestration in the lungs, early in the course of peritonitis. Cecal ligation and puncture (CLP) was performed on P-selectin-deficient (P-def) mice and their genetic controls (C57). Both groups were treated with anti-E-selectin antibody, anti-L-selectin, or isotypic control immunoglobulin G at the time of CLP. 6 h after CLP, mice were sacrificed. Peritoneal PMN migration decreased in P-def mice compared with C57 controls after CLP. Blockade of E- or L-selectin alone in controls did not alter peritoneal PMN influx or circulating PMNs after CLP. In the P-def mice, treatment with anti-E-antibody or anti-L-antibody nearly eliminated PMN influx into the peritoneum. In contrast, circulating PMNs markedly increased after CLP in P-def mice when compared with baseline values. Lung myeloperoxidase increased in all groups of mice following CLP. Blockade of P-selectin with anti-P-selectin antibody elicited a response similar to that observed in the P-def mice. In conclusion, P-selectin mediates PMN influx into the peritoneal cavity, while E- and L-selectins do not appear to play any significant role in the 6 h time period following CLP. Lung PMN sequestration, after CLP, occurred independent of P-, E-, or L-selectin expression. Blockade of P-selectin during peritonitis appears to be potentially deleterious by preventing early PMN influx into the compartment containing the septic focus.