Differential regulation of plastidial and cytosolic isoforms of peptide methionine sulfoxide reductase in Arabidopsis.

We report the characterization of two members of a gene family from Arabidopsis that encode, respectively, cytosolic (cPMSR) and plastid-targeted (pPMSR) isoforms of the oxidative-stress-repair enzyme peptide methionine sulfoxide reductase. Overexpression of these proteins in Escherichia coli confirmed that each had PMSR enzyme activity with a synthetic substrate, N-acetyl-[(3)H]-methionine sulfoxide, or a biological substrate, alpha-1 proteinase inhibitor. The pPMSR was imported into intact chloroplasts in vitro with concomitant cleavage of its approximately 5-kD N-terminal signal peptide. The two PMSR isoforms exhibited divergent pH optima, tissue localization, and responses to developmental and environmental effects. Analysis of the Arabidopsis database indicated that there are probably at least two p-pmsr-like genes and three c-pmsr-like genes in the Arabidopsis genome. Expression of the p-pmsr genes and their protein products was restricted to photosynthetic tissues and was strongly induced following illumination of etiolated seedlings. In contrast, the c-pmsr genes were expressed at moderate levels in all tissues and were only weakly affected by light. Exposure to a variety of biotic and abiotic stresses showed relatively little effect on pmsr gene expression, with the exception of leaves subjected to a long-term exposure to the cauliflower mosaic virus. These leaves showed a strong induction of the c-pmsr gene after 2 to 3 weeks of chronic pathogen infection. These data suggest novel roles for PMSR in photosynthetic tissues and in pathogen defense responses in plants.

Identification of a peptide methionine sulphoxide reductase gene in an oleosin promoter from Brassica napus.

A bidirectional promoter can be defined operationally as a short segment of DNA that regulates divergent transcription. In an attempt to investigate whether the intergenic region between the oleosin and a second open reading frame (ORFII) in Brassica napus (L.) is a divergent promoter, and also to characterize the ORFII, cDNA clones homologous to ORFII were isolated from a leaf cDNA library. A representative cDNA (clone D) of one of the two classes identified was identical, in DNA sequence, to the genomic ORFII. The second representative cDNA (clone O) was 97% identical at the nucleotide level to the genomic ORFII. The predicted amino acid sequence of the cDNA clones each exhibit homology with the peptide methionine sulphoxide reductase (PMSR) of Escherichia coli. The gene structure of ORFII was elucidated and the relative positions of the oleosin, ORFII, and the intergenic promoter region were determined. This confirms that the B. napus oleosin-ORFII intergenic region has divergent promoter activity. Consequently this is the first such plant nuclear divergent promoter identified. RFLP-mapping results showed that all four ORFII genes are linked to four of the six copies of the oleosin genes. This suggested that the bidirectional promoter locus is conserved within the B. napus genome. The ORFII gene product is targeted to the chloroplast, which is consistent with previous data indicating the presence of PMSR activity in the chloroplast. The over-expressed recombinant fusion protein (minus the transitpeptide) showed the capability to reduce peptide methionine sulphoxide residues in vitro, indicating PMSR activity. This study demonstrates that ORFII is transcribed and encodes a plant PMSR, and is the first example of the isolation of a eukaryotic PMSR gene.