Project description:The goal of this work was to investigate the influence of low red to far-red (R:FR) signals generated by a biological weedy and an artificial source of far-red light on the nitrate assimilation pathway in maize. In the absence of direct resource competition, far-red light reflected from neighboring weeds compromises light quality (red to far-red ratio; R/FR) and causes a wide range of morphological and physiological responses at early growth stages of crop plants. This study has investigated the effects of low R/FR light signals on nitrate assimilation in maize seedlings. The transcript levels of genes, metabolites, and activities of enzyme in the nitrate assimilation pathway under a biological and a simulated low R:FR light environment were compared with a high R:FR control environment. Low R:FR signals stimulated nitrate accumulation in maize leaves, which did not appear to result from the upregulation of nitrate transporter genes. A significant reduction in ferredoxin-dependent glutamine:2-oxoglutarate aminotransferase activity appears to play a major role in nitrate accumulation under low R:FR light environments, while activities of other enzymes of the nitrate assimilation pathway remain unchanged.
Project description:We report the application of ChIP-Seq technology for analyzing the DNA binding sites of SOD1 in the nucleus of HeLa cells. By obtaining a plenty of sequence from chromatin immunoprecipitated DNA, we generated genome-wide DNA binding sites of SOD1. After sequencing of ChIP samples, 42,737,195, 49,950,032, and 38,825,768 clean reads for control group, H2O2 treated group and LD100 (a specific inhibitor of SOD1) treated group were obtained through trimming the raw reads. We find that SOD1 occupies DNA sites with distinct sequence preference in the nucleus. The treatment with either H2O2 or LD100 was found to decrease the strength of SOD1 binding to DNA, indicating that the H2O2 exposure- or SOD1 inhibition-mediated redox dyshomeostasis may result in decreased genes that are reasonably regulated through alteration of SOD1 structures compared to control.
