SUMMARY
TheSolanum lycopersicum(tomato) genome encodes seven malic enzymes (MEs): three cytosolic NADP-ME isoforms (SlNADP-ME1, -2, and -3), two plastidic NADP-ME proteins (SlNADP-ME4a and -4b), and two mitochondrial NAD-dependent subunits (SlNAD-ME1 and -2) of a heteromeric enzyme. Except for SlNADP-ME3, which is almost exclusively expressed in the root, all the genes are active in the major tissues of flowering plants (leaf, stem, flower, and root), with SlNADP-ME2 and -4b transcripts accumulating at relative high levels. During the cell expansion and ripening phases of fruit development,SlNADP-ME3and-4bexpression increased in the pericarp and seeds whileSlNADP-ME2remained at a high level. In green fruit,SlNADP-ME3and-4bare down-regulated by ethylene, withSlNAD-ME1and-2being up-regulated. A correlation between SlNADP-ME4b accumulation and NADP-ME activity was observed from the early immature green to the mature green fruit stages, linking this plastidic isoform to starch and lipid biosynthesis.SlNADP-ME1and-4aexpression increase with temperature, suggesting involvement in defense mechanisms and supported bycis-elements composition in their promoters. Interesting, SlNADP-ME3 biochemical properties and its accumulation in seeds is part of an inherited and long-conserved genetic lineage in Angiosperms including Arabidopsis NADP-ME1, involved in normal seed germination. By analyzing the phylogeny and synteny ofSlNAD(P)-MEgenes and determining the biochemical properties of the recombinant proteins, we seek functional similarities to Arabidopsis NAD(P)-ME members. Our findings enhance the understanding of malate metabolism in tomatoes, which could inform strategies to improve fruit quality. Additionally, they prompt a re-evaluation of pre-existing notions regarding the functional orthology of enzymes based on phylogenetic relationships.
SIGNIFICANCE STATEMENT
Enzyme functional orthology among distant plant species cannot be inferred through phylogenetic analysis because of the large independent rearrangements of genomes during evolution. A comprehensive characterization of the tomato NAD(P)-ME family and their comparison with members from an unrelated plant species, such as Arabidopsis, allowed us to evaluate the impact of selective pressures on orthologous genes. This approach reveals that the phenotypic similarity of an entire enzyme family in different species is achieved through diverse evolutionary events such as ancestry, parallelism, and genetic convergence.
