Transcriptional profile of genes involved in ascorbate glutathione cycle in senescing leaves for an early senescence leaf (esl) rice mutant.

Abstract To clarify the complex relationship between ascorbate–glutathione (AsA–GSH) cycle and H 2 O 2 -induced leaf senescence, the genotype-dependent difference in some senescence-related physiological parameters and the transcript levels and the temporal patterns of genes involved in the AsA–GSH cycle during leaf senescence were investigated using two rice genotypes, namely, the early senescence leaf ( esl ) mutant and its wild type. Meanwhile, the triggering effect of exogenous H 2 O 2 on the expression of OsAPX genes was examined using detached leaves. The results showed that the esl mutant had higher H 2 O 2 level than its wild type at the initial stage of leaf senescence. At transcriptional level, the association of expression of various genes involved in the AsA–GSH cycle with leaf senescence was isoform dependent. For OsAPXs , the transcripts of two cytosolic OsAPX genes ( OsAPX1 and OsAPX2 ), thylakoid-bound OsAPX8 , chloroplastic OsAPX7 and peroxisomal OsAPX4 exhibited remarkable genotype-dependent variation in their expression levels and temporal patterns during leaf senescence, there were significantly increasing transcripts of OsAXP1 and OsAPX7 , severely repressed transcripts of OsAPX4 and OsAPX8 for the esl rice at the initial leaf senescence. In contrast, the repressing transcript of OsAPX8 was highly sensitive to the increasing H 2 O 2 level in the senescing rice leaves, while higher H 2 O 2 concentration resulted in the enhancing transcripts of two cytosolic OsAPX genes, OsAPX7 transcript was greatly variable with different H 2 O 2 concentrations and incubating duration, suggesting that the different OsAPXs isoforms played a complementary role in perceiving and scavenging H 2 O 2 accumulation at various H 2 O 2 concentrations during leaf senescence. Higher H 2 O 2 level, increased AsA level, higher activities of APX and glutathione reductase (GR), and relatively stable GSH content during the entire sampling period in the leaves of esl mutant implied that a close interrelationship existed between AsA level and APX activity in the ongoing senescence of rice leaves. The GSH supply in rice leaves was not the limiting factor for the efficient maintenance of AsA–GSH cycle, despite the senescence-related change in GR activity between the two rice genotypes.