muramidase and ethyl-gallate

In septic shock (SS), cardiovascular collapse is caused by the release of inflammatory mediators. We previously found that lysozyme-c (Lzm-S), released from leukocytes, contributed to systemic vasodilation in a canine model of SS. We then delineated the pathway by which this occurs in a canine carotid artery organ bath preparation (CAP). We showed that Lzm-S could intrinsically generate hydrogen peroxide (H(2)O(2)) and that H(2)O(2) subsequently reacted with endogenous catalase to form compound I, an oxidized form of catalase. In turn, compound I led to an increase in cyclic guanosine 3',5'-monophosphate to produce vasodilation. However, it was not clear from previous studies whether it is necessary for Lzm-S to bind to the vasculature to cause vasodilation or, alternatively, whether the generation of H(2)O(2) by Lzm-S in the surrounding medium is all that is required. We examined this question in the present study in which we used multiple preparations. In a partitioned CAP, we found that when we added Lzm-S to a partitioned space in which a semipermeable membrane prevented diffusion of Lzm-S to the carotid artery tissue, vasodilation still occurred because of diffusion of H(2)O(2). On the other hand, we found that Lzm-S could accumulate within the vascular smooth muscle layer (VSML) after 7 h of SS in a canine model. We also determined that when Lzm-S was located in close proximity to vascular smooth muscle cells, it could generate H(2)O(2) to produce lengthening in a human cell culture preparation. We conclude that there are two mechanisms by which Lzm-S can cause vasodilation in SS. In one instance, H(2)O(2) generated by Lzm-S in plasma diffuses to the VSML to cause vasodilation. In a second mechanism, Lzm-S directly binds to the VSML, where it generates H(2)O(2) to produce vasodilation.

Topics: Animals; Cells, Cultured; Dogs; Gallic Acid; Humans; In Vitro Techniques; Muramidase; Myocytes, Smooth Muscle; Shock, Septic; Vasodilation

Although hydrogen peroxide (H2O2) is a well-described reactive oxygen species that is known for its cytotoxic effects and associated tissue injury, H2O2 has recently been established as an important signaling molecule. We previously demonstrated that lysozyme (Lzm-S), a mediator of sepsis that is released from leukocytes, could produce vasodilation in a phenylephrine-constricted carotid artery preparation by H2O2 signaling. We found that Lzm-S could intrinsically generate H2O2 and that this generation activated H2O2-dependent pathways. In the present study, we used this carotid artery preparation as a bioassay to define those antioxidants that could inhibit Lzm-S's vasodilatory effect. We then determined whether this antioxidant could reverse the hypotension that developed in an Escherichia coli bacteremic model. Of the many antioxidants tested, we found that ethyl gallate (EG), a nonflavonoid phenolic compound, was favorable in inhibiting Lzm-S-induced vasodilation. In our E. coli model, we found that EG reversed the hypotension that developed in this model and attenuated end-organ dysfunction. By fluorometric H2O2 assay and electrochemical probe techniques, we showed that EG could scavenge H2O2 and that it could reduce H2O2 production in model systems. These results show that EG, an antioxidant that was found to scavenge H2O2 in vitro, was able to attenuate cardiovascular dysfunction in a canine in vivo preparation. Antioxidants such as EG may be useful in the treatment of hemodynamic deterioration in septic shock.

Topics: Animals; Dogs; Free Radical Scavengers; Gallic Acid; Hydrogen Peroxide; Hypotension; In Vitro Techniques; Muramidase; Shock, Septic; Signal Transduction; Treatment Outcome; Vasodilation