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Summary Background: In a previous study, nitrate reductase (NR, EC 1.6.6.1) from leaves of Ricinus communis L. showed different regulatory properties from most other higher plants NR's by an unusually strong Mg2+-sensitivity, a different pH-activity profile and only little ATP-dependent inactivation. The aim of this work was to elucidate the deviating properties of Ricinus NR in more details, from both molecular and physiological aspects. For that purpose, the NR gene from R. communis was cloned, expressed heterologously and characterized. Results: The deduced protein sequence showed that Ricinus NR shared high similarity with other NRs, apart from the N-terminal region. In the N-terminal region, the Ricinus NR possesses an acidic stretch which is conserved only in higher plants. Within the Moco-binding domain the Ricinus NR contained few amino acid residues which were unique in comparison with 17 plant NRs, including His103, Gln123, Val266 and Ala284 where other NRs possess asparagine, arginine, aspartate and praline. In the Dimer interface and Hinge 1 regions, the Ricinus NR also had some unique residues like Asn460 and Ala498 where other NRs have isoleucine and glycine instead. The Ricinus NR possesses an Arg482 which provides an additional predicted Trypsin cleavage site within 481KRHK484 (while most of plant-NRs possess KPHK). Additionally, the Ricinus NR contains a serine phosphorylation site (Ser-526) within the potential 14-3-3 binding motif 523KSVS*TP528, which is a common characteristic of nitrate reductases. In the C-Terminus of Ricinus NR a sequence 886CGPPP890 confirmed that Ricinus NR is a NADH-specific enzyme. Functional Ricinus NR protein was expressed in Pichia pastoris and compared with the features of Arabidopsis NR2 synthesized by the same expression system (AtNR2). The recombinant Ricinus NR (RcNR) itself was unresponsive to the incubation with MgATP, and so was AtNR2. As yeast extracts might lack factors required for NR regulation, desalted leaf extracts containing NR kinases and 14-3-3s were prepared from 4-day darkened (and therefore NR-free) leaves of Arabidopsis (ADL), spinach (SDL) and Ricinus (RDL), and added to the assay of RcNR and AtNR2 to check for ATP-dependent inactivation and Mg2+-sensitivity. When RcNR was combined with the NR-free extracts described above, it's unusually high Mg2+-sensitivity was restored only by incubation with RDL, but it remained unresponsive to ATP. In contrast, AtNR2 became inactive when incubated with the protein mixtures and ATP. It is obvious that one or some factors existing in RDL could interact with RcNR and therefore provide its high Mg2+-sensitivity. Interestingly, incubation of AtNR2 with different NR-free leaf extracts gave a significant activation of the enzyme activities, both in Mg2+ and EDTA, which were not observed in the case of RcNR. Moreover, using ammonium sulfate to fractionation the RDL revealed that about 0.2 mg of the protein factor(s) from 0-35% of ammonium sulfate precipitation was sufficient to provide the maximum inhibition of the RcNR. Conclusions: The insensitivity to ATP appears an inherent property of Ricinus NR, whereas the high Mg2+-sensitivity depends on one or several factors in Ricinus leaves. This as yet unknown factor(s) was boiling-sensitive and could be precipitated by ammonium sulfate. It appeared to interact specifically with recombinant Ricinus-NR to provide the Mg2+-sensitivity of the authentic leaf enzyme. Presumably, there is also a positive regulatory factor(s) for nitrate reductase existing in the leaves of higher plants.