Purification,cofactor analysis,and site-directed mutagenesis of Synechococcus ferredoxin-nitrate reductase

The narB gene of the cyanobacterium Synechococcus sp. strain PCC 7942 encodes an assimilatory nitrate reductase that uses photosynthetically reduced ferredoxin as the physiological electron donor. This gene was expressed in Escherichia coli and electrophoretically pure preparations of the enzyme were obtained using affinity chromatography with either reduced-ferredoxin or NarB antibodies. The electronic absorption spectrum of the oxidized enzyme showed a shoulder at around 320 nm and a broad absorption band between 350 and 500 nm. These features are indicative of the presence of an iron-sulfur centre(s) and accordingly metal analysis showed ca. 3 atoms of Fe per molecule of protein that could represent a [3Fe-4S] cluster. Further analysis indicated the presence of 1 atom of Mo and 2 molecules of ribonucleotide-conjugated molybdopterin per molecule of protein. This, together with the requirement of a mobA gene for production of an active enzyme, strongly suggests the presence of Mo in the form of the bis-MGD (bis-molybdopterin guanine dinucleotide) cofactor in Synechococcusnitrate reductase. A model for the coordination of the Mo atom to the enzyme is proposed. Four conserved Cys residues were replaced by site-directed mutagenesis. The effects of these changes on the enzyme activity and electronic absorption spectra support the participation of those residues in iron-sulfur cluster coordination. This revised version was published online in June 2006 with corrections to the Cover Date.     

Molybdenum hydroxylases in Drosophila. III. Further characterization of the low xanthine dehydrogenase gene

The biochemical effects of several newly induced low xanthine dehydrogenase (lxd) mutations in Drosophila melanogaster were investigated. When homozygous, all lxd alleles simultaneously interrupt each of the molybdoenzyme activities to approximately the same levels: xanthine dehydrogenase, 25%; aldehyde oxidase, 12%; pyridoxal oxidase, 0%; and sulfite oxidase, 2% as compared to the wild type. In order to evaluate potentially small complementation or dosage effects, mutant stains were made coisogenic for 3R. These enzymes require a molybdenum cofactor, and lxd cofactor levels are also reduced to less than 10% of the wild type. These low levels of molybdoenzyme activities and cofactor activity are maintained throughout development from late larval to adult stages. The lxd alleles exhibit a dosage-dependent effect on molybdoenzyme activities, indicating that these mutants are leaky for wild-type function. In addition, cofactor activity is dependent upon the number of lxd ⁺ genes present. The lxd mutation results in the production of more thermolabile XDH and AO enzyme activities, but this thermolability is not transferred with the cofactor to a reconstituted Neurospora molybdoenzyme. The lxd gene is localized to salivary region 68 A4-9, 0.1 map unit distal to the superoxide dismutase (Sod) gene.     

Chaperone protection of immature molybdoenzyme during molybdenum cofactor limitation

Maturation of molybdoenzyme TorA involves chaperone TorD. This study shows that TorD is also required to protect apoTorA against proteolysis when the molybdenum cofactor is limiting in Escherichia coli. The absence of TorD leads to a complete loss of apoTorA during molybdenum cofactor deficiency whereas the presence of TorD maintains a significant amount of apoTorA that can be matured when the molybdenum cofactor becomes available.     

Thealdox-2 locus ofDrosophila melanogaster also affects sulfite oxidase and molybdenum metabolism

Mutation at thealdox-2 locus inDrosophila melanogaster affects the specific activities of four molybdoenzymes differentially during development. Sulfite oxidase activity is normal during late larval and pupal stages but is reduced during early adult stages inaldox-2 organisms. There was complete concordance among the effects ofaldox-2 on sulfite oxidase, aldehyde oxidase, xanthine dehydrogenase, and pyridoxal oxidase, when 38 stocks were analyzed which were derived from single recombination events betweenc andpx, markers which flankaldox-2. Several different biochemical analyses indicate that the active molybdoenzymes present in thealdox-2 strain are normal with respect to size, shape,pH-activity profile,K _m , and molecular weight. Significant differences were found between thealdox-2 strain and the OR control strain in their responses to dietary Na₂MoO₄ and Na₂WO₄. The mutant strain is much more resistant to the effects of dietary Na₂WO₄ and much more responsive to the administration of Na₂MoO₄ than the OR control strain when these effects are quantitated by measurements of molybdoenzyme specific activities. This evidence suggests that thealdox-2 ⁺ gene product has a molybdenum binding site which can also bind tungsten and that this site is altered in the mutant strain. The hypothesis presented explains the observed effects of thealdox-2 mutation and relates them to the other mutations reported in this gene-enzyme system.This work was supported by an Operating Grant from the Natural Sciences and Engineering Research Council to M.M.B.