Nitrate Reductase Regulates Expression of Nitrite Uptake and Nitrite Reductase Activities in Chlamydomonas reinhardtii

In Chlamydomonas reinhardtii mutants defective at the structural locus for nitrate reductase (nit-1) or at loci for biosynthesis of the molybdopterin cofactor (nit-3, nit-4, or nit-5 and nit-6), both nitrite uptake and nitrite reductase activities were repressed in ammonium-grown cells and expressed at high amounts in nitrogen-free media or in media containing nitrate or nitrite. In contrast, wild-type cells required nitrate induction for expression of high levels of both activities. In mutants defective at the regulatory locus for nitrate reductase (nit-2), very low levels of nitrite uptake and nitrite reductase activities were expressed even in the presence of nitrate or nitrite. Both restoration of nitrate reductase activity in mutants defective at nit-1, nit-3, and nit-4 by isolating diploid strains among them and transformation of a structural mutant upon integration of the wild-type nit-1 gene gave rise to the wild-type expression pattern for nitrite uptake and nitrite reductase activities. Conversely, inactivation of nitrate reductase by tungstate treatment in nitrate, nitrite, or nitrogen-free media made wild-type cells respond like nitrate reductase-deficient mutants with respect to the expression of nitrite uptake and nitrite reductase activities. Our results indicate that nit-2 is a regulatory locus for both the nitrite uptake system and nitrite reductase, and that the nitrate reductase enzyme plays an important role in the regulation of the expression of both enzyme activities.     

Nitrate reductase-deficient mutants in barley : immunoelectrophoretic characterization

Nitrate reductase-deficient barley (Hordeum vulgare L.) mutants were assayed for the presence of a functional molybdenum cofactor determined from the activity of the molybdoenzyme, xanthine dehydrogenase, and for nitrate reductase-associated activities. Rocket immunoelectrophoresis was used to detect nitrate reductase cross-reacting material in the mutants. The cross-reacting material levels of the mutants ranged from 8 to 136% of the wild type and were correlated with their nitrate reductase-associated activities, except for nar 1c, which lacked all associated nitrate reductase activities but had 38% of the wild-type cross-reacting material. The cross-reacting material of two nar 1 mutants, as well as nar 2a, Xno 18, Xno 19, and Xno 29, exhibited rocket immunoprecipitates that were similar to the wild-type enzyme indicating structural homology between the mutant and wild-type nitrate reductase proteins. The cross-reacting materials of the seven remaining nar 1 alleles formed rockets only in the presence of purified wild-type nitrate reductase, suggesting structural modifications of the mutant cross-reacting materials. All nar 1 alleles and Xno 29 had xanthine dehydrogenase activity indicating the presence of functional molybdenum cofactors. These results suggest that nar 1 is the structural gene for nitrate reductase. Mutants nar 2a, Xno 18, and Xno 19 lacked xanthine dehydrogenase activity and are considered to be molybdenum cofactor deficient mutants. Cross-reacting material was not detected in uninduced wild-type or mutant extracts, suggesting that nitrate reductase is synthesized de novo in response to nitrate.     

Nitrate reductase-deficient mutants in barley: enzyme stability and peptide mapping

Thermal stability and pH optima of NADH-nitrate reductase-associated cytochrome c reductase and FMNH₂-nitrate reductase from wild type, cv Steptoe or Winer, and mutants nar 1d, nar 1g, nar 1h, Xno 18 and Xno 19 were compared to determine if structural differences in the nitrate reductase protein could be detected. Also, the nitrate reductase-associated cytochrome c reductase from nar 1d was purified and compared with the wild type by peptide mapping. The pH optimum for FMNH₂-nitrate reductase from Steptoe and nar 1h, and for NADH-cytochrome c reductase from Steptoe, nar 1d, nar 1g and nar 2a was 7.5. Thermal stabilities of the nitrate reductase-associated activities (FMNH₂-nitrate reductase or NADH-cytochrome c reductase) from nar mutants were less than the Steptoe wild type, while Xno mutants were equal to the Winer wild type. Cleveland peptide maps of nar 1d NADH-cytochrome c reductase and Steptoe nitrate reductase were identicalwhen digested with endoprotease lys-C but were distinctly different in one peptide when digested with Staphylococcus aureus endoprotease V8. These results provide evidence that nar 1 gene codes for the nitrate reductase polypeptide.     

NITRATE REDUCTASE MUTANTS IN EUDORINA ELEGANS (CHLOROPHYCEAE)1

Three nitrate reductase mutants were independently isolated and characterized in the colonial alga, Eudorina elegans Ehrenberg. nar-1 is a leaky mutant, deficient in the production of nitrate reductase. nar-2 and nar-3 both lack the ability to produce nitrate reductase. However, nar-2 grows and nar-3 does not grow when hypoxanthine is the sole nitrogen source. The specific activity of the next enzyme, in the pathway, nitrite reductase is increased in nar-3 when compared to wild-type, nar-1 and nar-2.     

Characteristics of a Nitrate Reductase in a Barley Mutant Deficient in NADH Nitrate Reductase

A barley (Hordeum vulgare L.) mutant, nar1a (formerly Az12), deficient in NADH nitrate reductase activity is, nevertheless, capable of growth with nitrate as the sole nitrogen source. In an attempt to identify the mechanism(s) of nitrate reduction in the mutant, nitrate reductase from nar1a was characterized to determine whether the residual activity is due to a leaky mutation or to the presence of a second nitrate reductase. The results obtained indicate that the nitrate reductase in nar1a differs from the wild-type enzyme in several important aspects. The pH optima for both the NADH and the NADPH nitrate reductase activities from nar1a were approximately pH 7.7, which is slightly greater than the pH 7.5 optimum for the NADH activity and considerably greater than the pH 6.0 to 6.5 optimum for the NADPH activity of the wild-type enzyme. The nitrate reductase from nar1a exhibits greater NADPH than NADH activity and has apparent K_m values for nitrate and NADH that are approximately 10 times greater than those of the wild-type enzyme. The nar1a nitrate reductase has apparent K_m values of 170 micromolar for NADPH and 110 micromolar for NADH. NADPH, but not NADH, inhibited the enzyme at concentrations greater than 50 micromolar.     

Molecular characterization of conventional and new repeat-induced mutants of nit-3, the structural gene that encodes nitrate reductase in Neurospora crassa

Nitrate reductase of Neurospora crassa is a dimeric protein composed of two identical subunits, each possessing three separate domains, with flavin, heme, and molybdenum-containing cofactors. A number of mutants of nit-3, the structural gene that encodes Neurospora nitrate reductase, have been characterized at the molecular level. Amber nonsense mutants of nit-3 were found to possess a truncated protein detected by a specific antibody, whereas Ssu-1-suppressed nonsense mutants showed restoration of the wild-type, full-length nitrate reductase monomer. The mutants show constitutive expression of the truncated nitrate reductase protein; however normal control, which requires nitrate induction, was restored in the suppressed mutant strains. Three conventional nit-3 mutants were isolated by the polymerase chain reaction and sequenced; two of these mutants were due to the deletion of a single base in the coding region for the flavin domain, the third mutant was a nonsense mutation within the amino-terminal molybdenum-containing domain. Homologous recombination was shown to occur when a deleted nit-3 gene was introduced by transformation into a host strain with a single point mutation in the resident nit-3 gene. New, severely damaged, null nit-3 mutants were created by repeat-induced point mutation and demonstrated to be useful as host strains for transformation experiments.     

Regulation of molybdenum cofactor species in the green alga Chlamydomonas reinhardtii

Molybdenum cofactor (MoCo) of molybdoenzymes is constitutively produced in cells of the green alga Chlamydomonas reinhardtii grown in ammonium media, under which conditions certain molybdoenzymes are not synthesized. In soluble form, MoCo was found to be present in several forms: (i) as a low Mr free species; (ii) bound to a MoCo-carrier protein of about 50 kDa that could release MoCo to directly reconstitute in vitro nitrate reductase activity in the nit-1 mutant of Neurospora crassa, but not to Thiol-Sepharose which, in contrast, bonded free MoCo; and (iii) bound to other proteins, putatively constitutive molybdoenzymes, which only released MoCo after a denaturing treatment. The amount of total MoCo (free, carrier-bound and heat releasable forms) was dependent on the growth phase of cell cultures. Constitutive levels of total MoCo in ammonium-grown cells markedly increased when cells were transferred to media lacking ammonium (nitrate, urea or nitrogen-free media). This increase did not require de novo protein synthesis and was stimulated by light. Levels of both total MoCo and free plus carrier-bound MoCo seemed to be unrelated to either nitrate reductase synthesis or functioning of nit-1 and nit-2 genes responsible for nitrate reductase structure and regulation, respectively. Results suggest that MoCo is continuously synthesized in C. reinhardtii and that its levels are regulated by ammonium in a way independent of nitrate reductase synthesis.     

Nitrate transport system in Neurospora crassa

Nitrate uptake in Neurospora crassa has been investigated under various conditions of nitrogen nutrition by measuring the rate of disappearance of nitrate from the medium and by determining mycelial nitrate accumulation. The nitrate transport system is induced by either nitrate or nitrite, but is not present in mycelia grown on ammonia or Casamino Acids. The appearance of nitrate uptake activity is prevented by cycloheximide, puromycin, or 6-methyl purine. The induced nitrate transport system displays a K_m for nitrate of 0.25 mM. Nitrate uptake is inhibited by metabolic poisons such as 2,4-dinitrophenol, cyanide, and antimycin A. Furthermore, mycelia can concentrate nitrate 50-fold. Ammonia and nitrite are non-competitive inhibitors with respect to nitrate, with K_i values of 0.13 and 0.17 mM, respectively. Ammonia does not repress the formation of the nitrate transport system. In contrast, the nitrate uptake system is repressed by Casamino Acids. All amino acids individually prevent nitrate accumulation, with the exception of methionine, glutamine, and alanine. The influence of nitrate reduction and the nitrate reductase protein on nitrate transport was investigated in wild-type Neurospora lacking a functional nitrate reductase and in nitrate non-utilizing mutants, nit-1, nit-2, and nit-3. These mycelia contain an inducible nitrate transport system which displays the same characteristics as those found in the wild-type mycelia having the functional nitrate reductase. These findings suggest that nitrate transport is not dependent upon nitrate reduction and that these two processes are separate events in the assimilation of nitrate.     

Biochemical genetics of further chlorate resistant, molybdenum cofactor defective, conditional-lethal mutants of barley

Summary Three plants, R9201 and R11301 (from cv. Maris Mink) and R12202 (from cv. Golden Promise), were selected by screening M₂ populations of barley (Hordeum vulgare L.) seedlings (mutagenised with azide in the M₁) for resistance to 10 mM potassium chlorate. Selections R9201 and R11301 were crossed with the wild-type cv. Maris Mink and analysis of the F₂ progeny showed that one quarter lacked shoot nitrate reductase activity. These F₂ plants also withered and died in the continuous presence of nitrate as sole nitrogen source. Loss of nitrate reductase activity and withering and death were due in each case to a recessive mutation in a single nuclear gene. All F1 progeny derived from selfing selection R12202 lacked shoot nitrate reductase activity and also withered and subsequently died when maintained in the continuous presence of nitrate as sole nitrogen source. All homozygous mutant plants lacked not only shoot nitrate reductase activity but also shoot xanthine dehydrogenase activity. The plants took up nitrate, and possessed wild-type or higher levels of shoot nitrite reductase activity and NADH-cytochrome c reductase activity when treated with nitrate for 18 h. We conclude that loss of shoot nitrate reductase activity, xanthine dehydrogenase activity and withering and death, in the three mutants R9201, R11301 and R12202 is due to a mutation affecting the formation of a functional molybdenum cofactor. The mutants possessed wild-type levels of molybdenum and growth in the presence of unphysiologically high levels of molybdate did not restore shoot nitrate reductase or xanthine dehydrogenase activity. The shoot molybdenum cofactor of R9201 and of R12202 is unable to reconstitute NADPH nitrate reductase activity from extracts of the Neurospora crassa nit-1 mutant and dimerise the nitrate reductase subunits present in the respective barley mutant. The shoot molybdenum cofactor of R11301 is able to effect dimerisation of the R11301 nitrate reductase subunits and can reconstitute NADPH-nitrate reductase activity up to 40% of the wild-type molybdenum cofactor levels. The molybdenum cofactor of the roots of R9201 and R11301 is also defective. Genetic analysis demonstrated that R9201, but not R11301, is allelic to R9401 and Az34 (nar-2a), two mutants previously shown to be defective in synthesis of molybdenum cofactor. The mutations in R9401 and R9201 gave partial complementation of the nar-2a gene such that heterozygotes had higher levels of extractable nitrate reductase activity than the homozygous mutants.We conclude that: (a) the nar-2 gene locus encodes a step in molybdopterin biosynthesis; (b) the mutant R11301 represents a further locus involved in the synthesis of a functional molybdenum cofactor; (c) mutant Rl2202 is also defective in molybdopterin biosynthesis; and (d) the nar-2 gene locus and the gene locus defined by R11301 govern molybdenum cofactor biosynthesis in both shoot and root.     

Inheritance and expression of NAD(P)H nitrate reductase in barley

Summary NADH-specific and NAD(P)H bispecific nitrate reductases are present in barley (Hordeum vulgare L.). Wild-type leaves have only the NADH-specific enzyme while mutants with defects in the NADH nitrate reductase structural gene (nar1) have the NAD(P)H bispecific enzyme. A mutant deficient in the NAD(P)H nitrate reductase was isolated in a line (nar1a) deficient in the NADH nitrate reductase structural gene. The double mutant (nar1a;nar7w) lacks NAD(P)H nitrate reductase activity and has xanthine dehydrogenase and nitrite reductase activities similar to nar1a. NAD(P)H nitrate reductase activity in this mutant is controlled by a single codominant gene designated nar7. The nar7 locus appears to be the NAD(P)H nitrate reductase structural gene and is not closely linked to nar1. From segregating progeny of a cross between the wild type and nar1a;nar7w, a line was obtained which has the same NADH nitrate reductase activity as the wild type in both the roots and leaves but lacks NADPH nitrate reductase activity in the roots. This line is assumed to have the genotype Nar1Nar1nar7nar7. Roots of wild type seedlings have both nitrate reductases as shown by differential inactivation of the NADH and NAD(P)H nitrate reductases by a monospecific NADH-nitrate reductase antiserum. Thus, nar7 controls the NAD(P)H nitrate reductase in roots and in leaves of barley.Scientific Paper No. 7617, College of Agriculture Research Center and Home Economics, Washington State University, Pullman, WA, USA. Project Nos. 0233 and 0745     

nit 7: A New Locus for Molybdopterin Cofactor Biosynthesis in the Green Alga Chlamydomonas reinhardtii

Two new nitrate reductase-deficient mutants from Chlamydomonas reinhardtii have been genetically and biochemically characterized. Both H1 and F23 mutants carry single recessive allelic mutations that map at a new locus designated nit-7. This locus is unlinked to the other six nit loci related to the nitrate assimilation pathway in C. reinhardtii. Both mutant alleles H1 and F23 lack an active molybdopterin cofactor, the activity of which is restored neither in vitro nor in vivo by high concentrations of molybdate. Nitrate reductase subunits in these mutants seem to assemble, although not in a stable form, in a high molecular weight complex and, as in other molybdenum cofactor-defective mutants of C. reinhardtii, they cannot reconstitute nitrate reductase activity with an active molybdenum cofactor source from extracts of ammonium-grown cells. The results suggest that nit-7 mutants are defective in molybdopterin biosynthesis. They do produce some precursor(s) that are capable of binding to nitrate reductase subunits.     

Molecular characterization of conventional and new repeat-induced mutants of nit-3, the structural gene that encodes nitrate reductase in Neurospora crassa

Nitrate reductase of Neurospora crassa is a dimeric protein composed of two identical subunits, each possessing three separate domains, with flavin, heme, and molybdenum-containing cofactors. A number of mutants of nit-3, the structural gene that encodes Neurospora nitrate reductase, have been characterized at the molecular level. Amber nonsense mutants of nit-3 were found to possess a truncated protein detected by a specific antibody, whereas Ssu-1-suppressed nonsense mutants showed restoration of the wild-type, full-length nitrate reductase monomer. The mutants show constitutive expression of the truncated nitrate reductase protein; however normal control, which requires nitrate induction, was restored in the suppressed mutant strains. Three conventional nit-3 mutants were isolated by the polymerase chain reaction and sequenced; two of these mutants were due to the deletion of a single base in the coding region for the flavin domain, the third mutant was a nonsense mutation within the amino-terminal molybdenum-containing domain. Homologous recombination was shown to occur when a deleted nit-3 gene was introduced by transformation into a host strain with a single point mutation in the resident nit-3 gene. New, severely damaged, null nit-3 mutants were created by repeat-induced point mutation and demonstrated to be useful as host strains for transformation experiments.