Here we review the current knowledge on the biochemistry and molecular pathology of oxidative stress with specific regard to a major aldehydic end-product stemming from peroxidation of biomembranes, that is 4-hydroxynonenal (HNE). This multifunctional molecule, which derives from the most represented class of polyunsaturated fatty acids in the membranes, is potentially able to undergo a number of reactions with proteins, phospholipids, and nucleic acids. Despite an active metabolism in most of the cell types, HNE can be detected in several biological tissues by means of sufficiently precise methods, although with different sensitivity. In particular, relatively high steady-state levels of HNE are often detectable in a large variety of human disease processes, pointing to some involvement of the aldehyde in their pathogenesis. Among the prominent pathobiochemical effects of HNE is its remarkable stimulation of fibrogenesis and inflammation, which indicates a potential contribution of the aldehyde to the pathogenesis of several chronic diseases, whose progression is indeed supported by inflammatory reactions and characterized by fibrosis. Further, of interest appears to be the ability of HNE to modulate cell proliferation through interference with the activity of cyclins and protein kinases and with the apoptotic machinery. Finally, on the basis of the already achieved evidence, pursuing investigation of the role of HNE in signal transduction and gene expression seems very promising.
SummaryHere we review the current knowledge on the biochemistry and molecular pathology of oxidative stress with speci c regard to a major aldehydic end-product stemming from peroxidation of biomembranes, that is 4-hydroxynonenal (HNE). This multifunctional molecule, which derives from the most represented class of polyunsaturated fatty acids in the membranes, is potentially able to undergo a number of reactions with proteins, phospholipids, and nucleic acids. Despite an active metabolism in most of the cell types, HNE can be detected in several biological tissues by means of suf ciently precise methods, although with different sensitivity. In particular, relatively high steady-state levels of HNE are often detectable in a large variety of human disease processes, pointing to some involvement of the aldehyde in their pathogenesis. Among the prominent pathobiochemical effects of HNE is its remarkable stimulation of brogenesis and in ammation, which indicates a potential contribution of the aldehyde to the pathogenesis of several chronic diseases, whose progression is indeed supported by in ammatory reactions and characterized by brosis. Further, of interest appears to be the ability of HNE to modulate cell proliferation through interference with the activity of cyclins and protein kinases and with the apoptotic machinery. Finally, on the basis of
Since a gradual benign-to-malignant progression of murine melanoma B16 after exposure in vitro to hypoxia was described recently, the aim of this study was to test if exposing melanoma B16-F10 cells to aldehyde 4-hydroxynonenal (HNE), which is considered not only as one of the major "second toxic messengers" of oxygen free radicals (or oxidative stress), but as a normal constituent of many cells and tissues, might have opposite effects. Treatment of the tumor cells with 50 microM HNE in vitro or in vivo did not prevent development of the tumors, but inhibited their growth. Tumor growth inhibition was equal for in vitro and in vivo treatment, but appeared after a delay of almost one week, since there was no difference of the tumor volume to the control observed during the initial period of the tumor growth. Similarly, both HNE treatment of the tumor cells before transplantation and HNE treatment of the melanoma bearing mice resulted in equally prolonged survival time. Thus, the results obtained suggest that while hypoxia could increase the malignancy of the murine melanoma cells, exposing these cells to one of the major "second toxic messengers" of oxygen free radicals, HNE, has almost opposite effects and further indicate the possible use of the aldehyde in vivo.
The metabolism of glutathione (GSH), a marker of oxidative stress and trehalose, a rather general physiological stress marker, was examined in exponentially growing Saccharomyces cerevisiae cells after treatment with 4-hydroxynonenal (HNE). GSH was entirely depleted within a 2 h incubation with 250 |iM HNE. After removal of the aldehyde it was replenished by de novo synthesis leading to an overshooting GSH level, which later decreased to the basal level. In addition, trehalose was elevated 4-fold in HNE-treated yeast cells compared to control cells. We conclude that increased GSH levels upon HNE treatment are a general phenomenon of eukaryotic cells to ensure protection and survival during further harsh conditions. Furthermore, we have discovered a new indication for the stress marker trehalose in S. cerevisiae.
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