Induction of the AOX1D isoform of alternative oxidase in A. thaliana T-DNA insertion lines lacking isoform AOX1A is insufficient to optimize photosynthesis when treated with antimycin A.

Plant respiration is characterized by two pathways for electron transfer to O(2), namely the cytochrome pathway (CP) that is linked to ATP production, and the alternative pathway (AP), where electrons from ubiquinol are directly transferred to O(2) via an alternative oxidase (AOX) without concomitant ATP production. This latter pathway is well suited to dispose of excess electrons in the light, leading to optimized photosynthetic performance. We have characterized T-DNA-insertion mutant lines of Arabidopsis thaliana that do not express the major isoform, AOX1A. In standard growth conditions, these plants did not show any phenotype, but restriction of electron flow through CP by antimycin A, which induces AOX1A expression in the wild-type, led to an increased expression of AOX1D in leaves of the aox1a-knockout mutant. Despite the increased presence of the AOX1D isoform in the mutant, antimycin A caused inhibition of photosynthesis, increased ROS, and ultimately resulted in amplified membrane leakage and necrosis when compared to the wild-type, which was only marginally affected by the inhibitor. It thus appears that AOX1D was unable to fully compensate for the loss of AOX1A when electron flow via the CP is restricted. A combination of inhibition studies, coupled to metabolite profiling and targeted expression analysis of the P-protein of glycine decarboxylase complex (GDC), suggests that the aox1a mutants attempt to increase their capacity for photorespiration. However, given their deficiency, it is intriguing that increase in expression neither of AOX1D nor of GDC could fully compensate for the lack of AOX1A to optimize photosynthesis when treated with antimycin A. We suggest that the aox1a mutants can further be used to substantiate the current models concerning the influence of mitochondrial redox on photosynthetic performance and gene expression.

Transcriptional regulation of NADP-dependent malate dehydrogenase: comparative genetics and identification of DNA-binding proteins.

The transcriptional regulation of NADP-malate dehydrogenase (NADP-MDH) was analyzed in Arabidopsis ecotypes and other Brassicaceae. The amount of transcript increased twofold after transfer into low temperature (12 degrees C) or high light (750 microE) in all species. Analysis of the genomic DNA reveals that the NADP-MDH gene (At5g58330 in A. thaliana) in Brassicaceae is located between two other genes (At5g58320 and At5g58340 in Arabidopsis), both encoded on the opposite DNA strand. No promoter elements were identified in 5' direction of the NADP-MDH gene, and the expression of NADP-MDH was not affected in knock-out plants carrying a DNA insert in the 5' region. A yeast-one hybrid approach yielded only three DNA-binding proteins for the 500-bp fragment located upstream of the ATG sequence, but 34 proteins for its coding region. However, in Chlamydomonas and in some Poaceae, which do not possess any genes within the 1200 bp upstream region, typical promoter elements were identified. Alignments of genomic DNA reveal that, in contrast to Poaceae, the introns are highly conserved within Brassicaceae. We conclude that in Brassicaceae the majority of regulatory elements are located within the coding region. The NADP-MDH gene of both families evolved from a common precursor, similar to the gene in Chlamydomonas. Changes in the selection pressure allowed the insertion of At5g58340 into the promoter region of a common ancestor. When the demand for transcriptional regulation increased, At5g58340 disappeared in Poaceae, and a promoter developed in the 5' region. In contrast, Brassicaceae maintained At5g58340 and shifted all regulatory elements into the coding region of NADP-MDH.