Endotoxemia results in neutrophil localization within a number of microcirculatory beds, reflecting in part an adhesive interaction between neutrophils and the vascular endothelial cell. In previous studies, endotoxin or lipopolysaccharide (LPS) treatment of rabbits resulted in neutrophil sequestration at LPS concentrations well below those effective at increasing neutrophil adherence in vitro. We hypothesized that LPS-induced neutrophil adherence involved a plasma component. In the absence of plasma, high concentrations of LPS (10 $tg/ml) were required to increase human neutrophil adherence to endothelial cells in vitro. With the inclusion of as little as 1% plasma or serum, however, the LPS dose-response curve was markedly shifted, resulting in increments in adherence at 10 ng/ml, and the time course of enhanced adherence was accelerated. Pretreatment studies suggested that the effect of LPS was on the neutrophil rather than the endothelial cell. Immunoprecipitation of 0111:B4 LPS paralleled the loss of functional activity, suggesting that LPS was an integral part of the active complex, rather than altering a plasma component to make it active. The incubation of plasma with LPS decreased the apparent molecular mass of LPS from 500-1,000 kD to -100 kD. The disaggregated 0111:B4 LPS eluted in the range of albumin and was able to increase adherence in the absence of additional plasma. Plasma depleted of lipoproteins or heat treated retained activity, suggesting that the interaction of LPS with HDL or complement did not account for the observed findings. An LPSbinding protein isolated from rabbit serum enhanced the adherence-inducing effects of both 0111:B4 and Re595 LPS. Furthermore, the activity of rabbit serum was abolished after incubation with an antibody directed against this LPS-binding protein (LBP). An antibody directed against CD14, the putative receptor of the LPS-LBP complex, prevented the adhesive response to LPS. These data suggest that LPS is disaggregated by an LBP in serum and plasma to form an active LPS-plasma component complex. This putative complex then interacts with CD14 on the neutrophil so as to induce an adhesive state. (J.
Incubation of most bacterial lipopolysaccharides (LPS) with normal human sera at 37C activates the serum complement system, resulting in decreased levels of hemolytic complement. A panel of R-chemotype LPS preparations isolated from Salmonella minnesota rough mutant strains, as well as smooth wild-type LPS from S. minnesota, Escherichia coli 055-B5, Serratia marcescens, and Yersinia enterolitica, were used to examine the effect of LPS polysaccharide chain length on LPS lipid (lipid A)-dependent activation of the classical pathway of complement (CPC). To examine specific lipid A-dependent activation of the CPC, sera deficient in alternative pathway of complement activity were prepared by the removal of factor D. Absorption of normal human sera with formalinized rabbit erythrocytes was found to remove natural antibodies, factors capable of forming LPS complexes which activate the CPC, or both. By using such factor D-depleted formalinized rabbit erythrocyteabsorbed normal human sera, only isolated lipid A and Re-chemotype LPS (R595 LPS) were found to activate the CPC. Thus, the presence of the additional monosaccharide L-glycero-D-mannoheptose in the Rd2 LPS oligosaccharide chain compared with the L-glycero-D-mannoheptose-deficient Re-chemotype LPS structure is sufficient to block lipid A-dependent activation of the CPC by LPS.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.