An active Neurospora-like assimilatory NADPH-nitrate reductase (EC 1.6.6.2), which can be formed in vitro by incubation of extracts of nitrate-induced Neurospora crassa mutant nit-i with extracts of (a) certain other nonallelic nitrate reductase mutants, (b) uninduced wild type, or (c) xanthine oxidizing and liver aldehyde-oxidase systems was also formed by combination of the nit-i extract with other acid-treated enzymes known to contain molybdenum. These molybdenum enzymes included (a) nitrogenase, or its molybdenumiron protein, from Clostridium, Azotobacter, and soybeats- (7). One of the subunits was believed to be a nitrate-inducible component(s) of nit-i that is responsible at least for the early part of the electron transport sequence, as reflected by its inducible NADPH-cytochrome c reductase activity which is flavin-dependent. The second component was inferred to be a constitutive entity that is absent in nit-i, but present in all other mutants and uninduced wild type, and is responsible for the latter part of the nitrate reductase pathway that includes the molybdenum moiety. The second component could also be supplied by the individual molybdenum-enzymes bovine milk and intestinal xanthine oxidases, chicken liver dehydrogenase, and rabbit liver aldehyde oxidase (8), provided they were subjected to prior acidification, a treatment known to dissociate some proteins into their subunits (9-11). (However, sodium molybdate and some 20 different partially purified enzymes that do not contain molybdenum were inactive.) In all instances, in vitro formation of enzyme activity was accompanied by the conversion of cytochrome c reductase activity (S20, = 4.5S) to the faster sedimenting form (Seo,,0 = 7.9 S) which is associated with NADPH-nitrate reductase (suggestive of subunit assembly) and the appearance of NADPH-, FADH2-, and MVH-nitrate reductase activities. The assimilatory NADPH-nitrate reductase thus formed is similar to the wild-type Neurospora enzyme. Moreover, nit-i is the only one of the nitrate reductase Neurospora mutants that also lacks xanthine dehydrogenase, and is unable to grow on hypoxanthine or nitrate as the sole nitrogen source (8), similar to certain Aspergillus mutants (12).In the present pl)aper, we report that other acid-treated mnolybdenum-enzymes from diverse phylogenetic sources can also interact with the induced Neurospora nit-i extract to form a Neurospora-like assimilatory NADPH-nitrate reductase. The results suggest the existence of a molybdenum-containing component, perhaps in the form of a molybdenum cofactor, that is shared in common by the known molybdenum-enzymes among a diversity of organisms including microbes, plants, and animals. A preliminary account of a portion of this work has been published (13).
