Phospholipid metabolism by phagocytic cells

Bacterial endotoxins and pathogenesis of Gram-negative infections: current status and future direction

100 years after the discovery of a bacterial 'endotoxin', 50 years after the introduction of antibiotics and 25 years after the routine use of intensive care units to support septic shock patients, Gram-negative infections continue to account for significant morbidity and mortality. In the coming decade, basic research on the structure/function of LPS, the cytokine cascade, and receptor-mediated intracellular signalling responses to LPS and cytokines will provide a greater understanding of the molecular, cellular and systemic responses to endotoxin and infection. New therapeutic agents now emerging from research, and better designed clinical trials to assess those agents will contribute to the next significant decline in sepsis- and shock-related morbidity and mortality. This article summarizes the findings of a workshop convened at the National Institutes of Health (NIH) to examine current research on endotoxin and Gram-negative septic shock.

Salmonella typhimurium porin internalization by leukocytes

The location of Salmonella typhimurium porins has been found in human monocytes and lymphocytes by means of high resolution autoradiography. The results indicate that traces of porins are frequently visible on ultrathin sections of treated human lymphomonocytes and that they are located especially in the nuclear areas.

The activity of the pneumococcal autolytic system and the fate of the bacterium during ingestion by rabbit polymorphonuclear leukocytes

The extent to which autolytic microbial enzymes are involved in the fate of microorganisms ingested by phagocytes has not been determined. It is known, however, that activation of degradative enzymes occurs during certain microbicidal events. We examined the possible role of the pneumococcal autolytic enzyme (an N-acetylmuramyl-L-alanine amidase) in the loss of viability and degradation of pneumococci during phagocytosis by rabbit polymorphonuclear leukocytes. Three bacterial systems were compared: (a) wild type pneumococci with an active autolytic system; (b) wild type bacteria grown under conditions that block the endogenous autolytic activity and (c) a mutant strain defective in the major autolytic enzyme of this bacterium. No differences could be detected between the autolysis-positive and negative bacteria in the rate of killing and in the fate of macromolecular cell constituents during ingestion by rabbit peritoneal polymorphonuclear leukocytes.

The use of a phospholipase A-less Escherichia coli mutant to establish the action of granulocyte phospholipase A on bacterial phospholipids during killing by a highly purified granulocyte fraction

Phospholipase A2 present in a highly purified, potently bactericidal, fraction from rabbit graulocytes produces net bacterial phospholipid degradation during killing of a phospholipase A-less strain of Escherichia coli. In the wild-type parent strain phospholipid breakdown is caused not only by the action of phospholipase A2 but also by phospholipase A1, indicating activation of the most prominent phospholipase of E. coli. This activation occurs as soon as the bacteria are exposed to the granulocyte fraction. Phospholipid breakdown by both phospholipases A is dose dependent but reaches a plateau after 30-60 min and at higher concentrations of the fraction. Phospholipid degradation is accompanied in both strains by an increase in permeability to actinomycin D that is also dose dependent. Even though net hydrolysis of phospholipids is greater in the parent strain than in the mutant, the increase in permeability is the same in the two strains. The addition of 0.04 M Mg2+, after the effects on phospholipids and permeability have become manifest, initiates in both strains the restoration of insensitivity to actinomycin D, the net resynthesis of phospholipids, and the disappearance of monoacylphosphatides and the partial disappearance of free fatty acids that had accumulated. Loss of ability to multiply is not reversed by Mg2+ in either strain. Less than 5 micrograms of granulocyte fraction causes loss of viability of from 90 to 99% of 1 X 10(8) microorganisms of both strains. However, at lower concentrations the parent strain is considerably more sensitive to the bactericidal effect of the granulocyte fraction than the mutant strain.

Preparation and characterization of mouse intestinal phospholipase

Phospholipase has been prepared in a stable, partially purified form from the small intestine of mice infected with the tapewormHymenolepis nana. The enzyme(s) attacks diacylphosphatides with liberation of free fatty acids and a corresponding decrease in phospholipid phosphorus, without accumulation of lysophosphatides. The reactivity with various substrates is strongly influenced by their physical state, the presence of other lipids, proteins or detergents. The phospholipids of some biomembranes (mitochondria, microsomes, red cell ghosts) are readily hydrolyzed under customary reaction conditions. The ensuing biochemical, morphological and functional alterations have been documented. In contrast, the diacylphospholipids of the cell membrane (intact erythrocytes,Pseudomonas aerunginosa) are not accessible to phospholipase action unless some alteration of the integrity of the cell is induced by physical or chemical means (hemolysis, polymyxin). The enzyme is proposed as a tool for the investigation of biomembranes and as a model for the study of phospholipase activity.