Identification of residues of Rhodobacter capsulatus ferredoxin I important for its interaction with nitrogenase.

Abstract

In Rhodobacter capsulatus, ferredoxin I (FdI) serves as natural electron donor to nitrogenase. In order to probe amino acid residues possibly involved in the interaction with dinitrogenase reductase, FdI was subjected to site-specific mutagenesis. A three-dimensional structure of FdI was designed by computer modelling and used for selecting target residues. Mutant ferredoxins bearing substitutions of surface residues, as well as a variant having a Met2 --> Tyr replacement in the vicinity of one cluster, have been constructed. All FdI variants were expressed to similar levels both in Escherichia coli and in a FdI-deleted mutant of the natural host. Once purified, the mutant ferredoxins exhibited molecular and spectroscopic properties almost identical to wild-type FdI. Determination of the reduction potential of FdI by cyclic voltammetry gave an E'o of -510 mV (pH 7.6) for both clusters, which is one of the lowest values reported for a 2[4Fe-4S] ferredoxin. Only the [Tyr2]FdI variant showed a significant difference in redox potential (delta E'o = -15 mV). Based on in vitro assays, a [Glu27, Glu28]FdI double mutant exhibited a twofold decrease in the electron transfer rate to dinitrogenase reductase while the affinity of this mutant for the enzyme was barely affected. On the other hand, an Asp36 --> His substitution resulted in a sevenfold increase of the apparent Km for dinitrogenase reductase. Unlike FdI and the other mutant ferredoxins, the [His36]FdI variant also failed to form a cross-linked complex with dinitrogenase reductase upon incubation with a carbodiimide. It is concluded that Asp36 in FdI probably participates in the interaction between the two protein partners. Nevertheless, all the FdI mutants proved competent in restoring a wild-type phenotype when expressed in a FdI-deleted mutant background, indicating that none of the studied residues was absolutely critical for electron transfer to nitrogenase.