CONICET | Buscador de Institutos y Recursos Humanos

The Arabidopsis thaliana genome contains two genes encoding mitochondrial NAD-malic enzyme (NAD-ME), NAD-ME1 (At2g13560) and NAD-ME2 (At4g00570). The characterization of recombinant NAD-ME1 and -2 indicated that both enzymes assemble as active homodimers, however, a heterodimeric enzyme (NAD-MEH) can also be detected by electrophoretic studies. To analyze the metabolic contribution of each enzymatic entity, NAD-MEH was obtained by a co-expression-based recombinant approach and its kinetic and regulatory properties were analyzed. The three NAD-MEs show similar kinetic properties although they differ in the regulation by several metabolic effectors. In this regard, while fumarate activates NAD-ME1, and CoA activates NAD-ME2, both compounds act synergistically on NAD-MEH activity. The characterization of two chimeric enzymes between NAD-ME1 and -2 allowed specific domains of the primary structure, which are involved in the differential allosteric regulation, to be identified. NAD-ME1 and -2 subunits showed a distinct pattern of accumulation in the separate components of the floral organ. In sepals, the NAD-ME1 subunit is present at a slightly higher proportion than NAD-ME2 subunit and thus NAD-MEH and NAD-ME1 act in concert in this tissue. On the other hand, NAD-ME2 is the only isoform present in anthers. In view of the different properties of NAD-ME1, -2 and -H, we suggest that mitochondrial NAD-ME activity may be regulated by varying native association in vivo, rendering enzymatic entities with distinct allosteric regulation to fulfill specific roles. The presence of three different NAD-ME entities which originate by alternative associations of two subunits is suggested to be a novel phenomenon unique to plant mitochondria