The discovery of complex vascular lesions in SHIV-nef- but not SIV-infected animals, and the presence of Nef in the vascular cells of patients with HRPH, suggest that Nef plays a key role in the development of severe pulmonary arterial disease.
Glutamine (GLN) has been shown to attenuate cytokine release from LPS-stimulated human peripheral blood mononuclear cells; however, the in vivo antiinflammatory effect of GLN in polymicrobial sepsis and ARDS is unknown. This study evaluates the effect of GLN on inflammatory cytokine release and the pathways that may mediate antiinflammatory effects of GLN in the lung. Either 0.75 g/kg of GLN or saline placebo (SP) was administered to male rats 1 h after cecal ligation and puncture (CLP). NF-kappaB activation, IKBalpha degradation, phosphorylation of p38 MAPK, ERK, and MKP-1 expression were evaluated in lung tissue 6 h post-CLP. Lung tissue iNOS and eNOS, TNF-alpha, IL-6, and IL-18 cytokines were assayed. Last, lung histopathology for occurrence of ARDS and survival were examined. GLN given 1 h postsepsis led to inhibition of lung tissue NF-kappaB activation (P < 0.001 vs. SP), attenuated degradation of IKBalpha, and inhibited phosphorylation of p38 MAPK, and ERK, pathways critical for cytokine release. GLN treatment increased MKP-1 peptide expression and significantly attenuated TNF-alpha and IL-6 6 h after CLP. IL-18 was attenuated by GLN at multiple time points post-CLP. Further, GLN abrogated increases in lung iNOS expression and enhanced lung eNOS postsepsis. Finally, GLN prevented the histopathologic appearance of ARDS after sepsis and significantly improved survival. These data reveal that GLN exerts an antiinflammatory effect in sepsis that may be mediated via attenuation of multiple pathways of inflammation such as NF-kappaB, p38 MAPK, ERK, and MKP-1. GLN also showed an inhibition of increases in iNOS expression. The antiinflammatory effect of GLN was associated with attenuation of ARDS and mortality.
Background The clinical use of the immunosuppressant calcineurin inhibitor cyclosporine is limited by its nephrotoxicity. This is enhanced when combined with the immunosuppressive mTOR inhibitor sirolimus. Nephrotoxicity of both drugs is not yet fully understood. Methods The goal was to gain more detailed mechanistic insights into the time-dependent effects of cyclosporine and sirolimus on the rat kidney by using a comprehensive approach including metabolic profiling in urine (1H-NMR spectroscopy), kidney histology, kidney function parameters in plasma, measurement of glomerular filtration rates, the oxidative stress marker 15-F2t-isoprostane in urine and immunosuppressant concentrations in blood and kidney. Male Wistar rats were treated with vehicle (controls), cyclosporine (10/25mg/kg/d) and/or sirolimus (1mg/kg/d) by oral gavage once daily for 6 and 28 days. Results Twenty-eight day treatment led to a decrease of glomerular filtration rates (cyclosporine -59%, sirolimus -25%). These were further decreased when both drugs were combined (-86%). Histology revealed tubular damage after treatment with cyclosporine, which was enhanced when sirolimus was added. No other part of the kidney was affected. 1H-NMR spectroscopy analysis of urine (day 6) revealed time-dependent changes of 2-oxoglutarate, citrate and succinate concentrations. In combination with increased urine isoprostane concentrations these changes indicated oxidative stress. After 28 days of cyclosporine treatment, urine metabonomics shifted to patterns typical for proximal tubular damage with reduction of Krebs cycle intermediates and trimethylamine-N-oxide concentrations whereas acetate, lactate, trimethylamine and glucose concentrations increased. Again, sirolimus enhanced these negative effects. Conclusions Our results indicate that cyclosporine and/or sirolimus induce damage of the renal tubular system. This is reflected by urine metabolite patterns, which seem to be more sensitive than currently used clinical kidney function markers such as creatinine concentrations in serum. Metabolic profiling in urine may provide the basis for the development of toxicodynamic monitoring strategies for immunosuppressant nephrotoxicity.
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