Impact of aldehydes on Dicer activity and expression: potential benefits of ALDH2 activation.

4-hydroxy-2-nonenal (4-HNE) is a major by-product of lipid peroxidation, a process that is exacerbated under oxidative stress conditions. This aldehyde is a very reactive molecule associated with the establishment and progression of many diseases, including cardiovascular diseases. We recently found using proteomics that 4-HNE directly targets Dicer in failing hearts, a critical enzyme for miRNA biology (unpublished data). Neither the aldehyde-Dicer adduction, nor its effect on protein stability and activity has been previously reported. Therefore, this study aimed to fill this gap by further investigating 4-HNE-Dicer interaction and characterizing its effect on Dicer profile. We hypothesize that 4-HNE will make adducts with Dicer and compromise its function and levels. Using an animal model of cardiac dysfunction, we evaluated the following parameters: levels of 4-HNE adducted proteins, Dicer levels and activity, and the levels of heart specific miRNAs (myomiRs). The same variables were analyzed in distinct cellular models (H9C2, MEF, HEK293) after acute exposure to 4-HNE. Additionally, we synthetized recombinant Dicer, and protein function and stability were assessed in vitro. As expected, the experiments with recombinant protein revealed that 4-HNE directly interacts with Dicer, and the formation of 4-HNE-DICER adduct causes loss of Dicer cleavage activity and stability in a time- and concentration-dependent manner. Regarding the animal model, Dicer activity, but not protein levels, dropped in failing hearts, which was paralleled by a reduction of mature miRNA levels. Of interest, animals with cardiac dysfunction chronically treated with a small molecule activator of aldehyde dehydrogenase 2 (ALDH2), termed Alda-1, displayed an elevated cardiac Dicer activity and mature miRNA levels compared with vehicle-treated animals. ALDH2 is the mains enzyme responsible for 4-HNE clearance. In this context, this study points out a potential connection among 4-HNE levels, Dicer activity and myomiR levels in cardiac dysfunction. Consistent with our in vivo data, cells acutely exposed to 4-HNE showed an increase in 4-HNE-protein adducts followed by a reduction in Dicer activity and changes in miRNA biosynthesis. However, Alda showed no protective effect in the latter model. Taken together, our findings using animal and cellular models suggest that Dicer activity is impaired in chronic (cardiac dysfunction) and acute aldehyde stress conditions. However, the molecular mechanisms involved in this response are still unclear. As both 4-HNE accumulation and microRNAs have been linked to innumerous pathologies, clarifying the modulation of Dicer activity under such conditions will certainly contribute to a better understanding the diseases and future therapeutic strategies. (AU)