Lysosomal enzyme activities in polymorphonuclear leukocytes,macrophages, serum,and spleen of conventional,germ-free,and antigen-free minnesota miniature swine

The activities of lysozyme, myeloperoxidase, and elastase were lower in PMNs and AMs from GF and AF Minnesota miniature piglets than in the leukocytes from their CONV counterparts. In the spleen and serum of gnotobiotic piglets only the levels of lysozyme were slightly reduced. Substantially depressed activities of these LEs were found also in PMNs from precolostral piglets in comparison with PMNs from their CONV mother. The bisassociation of GF piglets with Enterococcus liquefaciens and Escherichia coli caused an increase of LE activities in their AMs, spleens, and sera. Fewer LEs were released after phygocytic stimulation with zymosan from PMNs of GF, AF, and precolostral piglets than from PMNs of CONV animals of the same age. These data suggest that the antigenic-microbial stimulation is important for the development of normal lysosomal enzyme activities in PMNs and AMs from gnotobiotic animals.     

The passive anaphylactic reaction in guinea pigs elicited by whole and cathepsin D-degraded antigen

The systemic anaphylactic reaction and thein vitro anaphylactic contraction of the terminal segment of the ileum performed according to the Schultz-Dale technique, were elicited in guinea pigs passively sensitized with rabbit antibodies to human serum albumin, using whole and cathepsin D degraded antigen. The intensity of the systemic anaphylactic response that was evoked by degraded antigen was lower; a highly significant suppression of the response was obtained provided an antigen degraded more than by 70% was injected. With an increasing degradation of antigen, more animals responded with lower or even with no reaction; the number of animals developing severe or lethal shock, decreased at the same time. The number of animals that developed a medium anaphylactic response remained at the same level. The degraded antigen did not evoke the anaphylactic contraction of the terminal segment of the ileumin vitro, and moreover, it blocked the contraction after addition of the whole antigen.     

Chemistry, physiology and pathology of free radicals

The superoxide anion radical and other reactive oxygen species (ROS) are formed in all aerobic organisms by enzymatic and nonenzymatic reactions. ROS arise in both physiological and pathological processes, but efficient mechanisms have evolved for their detoxification. Similarly, reactive nitrogen intermediates (RNI) have physiological activity, but can also react with different types of molecules, including superoxide, to form toxic products. ROS and RNI participate in the destruction of microorganisms by phagocytes, as in the formation of a myeloperoxidase-hydrogen peroxide-chloride/iodide complex which can destroy many cells, including bacteria. It is known that the cellular production of ROS and RNI is controlled by different mechanisms. These free radicals can react with key cellular structures and molecules, thus altering their biological function. An imbalance between the systems producing and removing ROS and RNI may result in pathological consequences.     

Production of superoxide anion by phagocytosing human and pig leukocytes

The production of Superoxide anion during phagocytosis of zymosan particles and E. coli 055 by human polymorphonuclear leukocytes was found to be 2.2 –3 times higher than by pig leukocytes.