Melatonin is a multifunctional molecule that mediates several circadian and seasonal processes in animal reproduction. Melatonin and its metabolites are antioxidants and free radical scavengers. We investigated the effects of melatonin on porcine oocyte maturation and embryo development. We then investigated the local expression of the melatonin receptor 1 (MT1) gene in cumulus cells, granulosa cells, and the oocytes with the reverse transcription-polymerase chain reaction (RT-PCR) method. We further evaluated the antioxidant effects [reactive oxygen species (ROS) levels in cumulus-oocytes complexes] of melatonin supplementation during in vitro maturation (IVM). Compared with control, melatonin supplementation (10 ng/mL) during IVM resulted in a greater proportion of oocytes extruding the polar body (75.6% versus 84.6%). Significantly greater proportion of parthenogenetically activated oocytes developed to blastocysts when the in vitro medium was supplemented with melatonin; however, cleavage frequency and blastocyst cell number were not affected by the treatment. RT-PCR analysis revealed the expression of MT1 gene in cumulus and granulosa cells but not in oocytes. Melatonin-treated oocytes had significantly lower levels of ROS than did control (untreated) oocytes. We conclude that exogenous melatonin has beneficial effects on nuclear and cytoplasmic maturation during porcine IVM. Some of the observed effects may be mediated by receptor binding and while others may have been receptor independent, e.g., direct free radical scavenging.
Rapid translation of genome sequences into meaningful biological information hinges on the integration of multiple experimental and informatics methods into a cohesive platform. Despite the explosion in the number of genome sequences available, such a platform does not exist for filamentous fungi. Here we present the development and application of a functional genomics and informatics platform for a model plant pathogenic fungus, Magnaporthe oryzae. In total, we produced 21,070 mutants through large-scale insertional mutagenesis using Agrobacterium tumefaciens-mediated transformation. We used a high-throughput phenotype screening pipeline to detect disruption of seven phenotypes encompassing the fungal life cycle and identified the mutated gene and the nature of mutation for each mutant. Comparative analysis of phenotypes and genotypes of the mutants uncovered 202 new pathogenicity loci. Our findings demonstrate the effectiveness of our platform and provide new insights on the molecular basis of fungal pathogenesis. Our approach promises comprehensive functional genomics in filamentous fungi and beyond.
The soxRS regulon functions in protecting Escherichia coli cells against superoxide and nitric oxide. When SoxR is activated by oxidation of its [2Fe–2S] cluster, it increases the synthesis of SoxS, which then activates its target gene expression. How the oxidized SoxR returns to and is maintained in its reduced state has been under question. To identity genes that constitute the SoxR‐reducing system, we screened an E.coli mutant library carrying a chromosomal soxSp::lacZ fusion, for constitutive mutants. Mutations mapped to two loci: the rsxABCDGE operon (named for reducer of SoxR) that is highly homologous to the rnfABCDGE operon in Rhodobacter capsulatus involved in transferring electrons to nitrogenase, and the rseC gene in the rpoE–rseABC operon. In‐frame deletion of each open reading frame in the rsxABCDGE operon produced a similar constitutive phenotype. The double mutation of rsx and rseC suggested that rsxABCDGE and rseC gene products act together in the same pathway in reducing SoxR. Electron paramagnetic resonance analysis of SoxR and measurement of re‐reduction kinetics support the proposal that rsx and rseC gene products constitute a reducing system for SoxR.
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