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.     

Regulation of Nitrate Reductase in Neurospora crassa: Stability In Vivo

Nicotinamide adenine dinucleotide phosphate, reduced form (NADPH)-nitrate reductase and its related enzyme activities, NADPH-cytochrome c reductase and reduced benzyl viologen-nitrate reductase, are all induced following the transfer of ammonia-grown wild-type Neurospora mycelia to nitrate medium. After nitrate reductase is induced to the maximal level, the addition of an ammonium salt to, or the removal of nitrate from, the cultures results in a rapid inactivation of nitrate reductase and its two partial component activities. This rapid inactivation is slowed down by the protein synthesis inhibitor, cycloheximide. Experiments on the mixing of extracts in vitro rule out the presence of an inhibitor of nitrate reductase in free form in extracts containing inactivated nitrate reductase. Ammonia does not inhibit the uptake of nitrate by the mycelia. Inactivation of nitrate reductase in vivo by ammonia depends on the concentration of the ammonium salt and is not reversed by increasing the nitrate concentration of the medium. The nitrate-inducible NADPH-cytochrome c reductase activity and reduced benzyl viologen-nitrate reductase activity respectively of the nitrate-nonutilizing mutants nit-1 and nit-3 are not inactivated in vivo by the addition of an ammonium salt or the withdrawal of nitrate. This finding suggests that the integrity of the nitrate reductase complex is required for the in vivo inactivation of nitrate reductase and its associated activities.     

Regulation of nitrate reductase of Neurospora at the level of transcription and translation

The presence of nitrate is required for the induced synthesis of NADPH-nitrate reductase and its related partial activity Benzyl Viologen-nitrate reductase in a wild-type strain of Neurospora. In nit-3, a mutant lacking complete NADPH-nitrate reductase activity but retaining the partial activity Benzyl Viologen-nitrate reductase, the presence of nitrate ions is not required for the de-repressed synthesis of the latter enzyme. The accumulation of the capacity to synthesize nitrate reductase, and the related Benzyl Viologen-nitrate reductase, in the absence of protein synthesis does not require nitrate in the normal strain or in strain nit-3. Ammonia antagonizes the accumulation of this capacity in both strains. Nitrate is required for the synthesis of nitrate reductase and related activities from presumedly preformed mRNA in the wild-type strain. Nitrate is not required for the comparable function in strain nit-3. Ammonia appears to stop the synthesis of nitrate reductase and related activities from presumedly preformed mRNA in the wild-type strain and in strain nit-3. The effects of nitrate, or ammonia and of no nitrogen source on the induced synthesis of nitrate reductase cannot be explained on the basis of the effects of the different nitrogen sources on general synthesis of RNA or of protein.     

Identification and Characterization of a Nitrate Transporter Gene in Neurospora crassa

The Neurospora crassa genome database was searched for sequence similarity to crnA, a nitrate transporter in Aspergillus nidulans. A 3.9-kb fragment (contig 3.416, subsequence 183190-187090) was cloned by PCR. The gene coding for this nitrate transporter was termed nit-10. The nit-10 gene specifies a predicted polypeptide containing 541 amino acids with a molecular mass of 57 kDa. In contrast to crnA, which is clustered together with niaD, encoding nitrate reductase, and niiA, encoding nitrite reductase, nit-10 is not linked to nit-3 (nitrate reductase), nit-6 (nitrite reductase), or to nit-2, nit-4 (both are positive regulators of nit-3), or nmr (negative regulator of nit-3) in Neurospora crassa. A nit-10 rip mutant failed to grow in the medium when nitrate (< 10 mM) was used as the sole nitrogen source, but grew similarly to wild type when nitrate concentration was 10 mM or higher. In addition, it showed strong sensitivity to cesium in the presence of nitrate and resistance to chlorate in the presence of alanine, proline, or hypoxanthine. The expression of nit-10 required nitrate induction and was subject to repression by nitrogen metabolites such as glutamine. Expression of nit-10 also required functional products of nit-2 and nit-4. The half-life of nit-10 mRNA was determined to be approximately 2.5 min.     

In vitro restoration of nitrate reductase: investigation of Aspergillus nidulans and Neurospora crassa nitrate reductase mutants.

Extracts of Aspergillus nidulans wild type (bi-1) and the nitrate reductase mutant niaD-17 were active in the in vitro restoration of NADPH-dependent nitrate reductase when mixed with extracts of Neurospora crassa, nit-1. Among the A. nidulans cnx nitrate reductase mutants tested, only the molybdenum repair mutant, cnxE-14 grown in the presence of 10-minus 3 M Na2 MoO4 was active in the restoration assay. Aspergillus extracts contained an inhibitor(s) which was measured by the decrease in NADPH-dependent nitrate reductase formed when extracts of Rhodospirillum rubrum and N. crassa, nit-1 were incubated at room temperature. The inhibition by extracts of A. nidulans, bi-1, cnxE-14, cnxG-4 and cnxH-3 was a linear function of time and a logarithmic function of the protein concentration in the extract. The molybdenum content of N. crassa wild type and nit-1 mycelia were found to be similar, containing approx. 10 mu g molybdenum/mg dry mycelium. The NADPH-dependent cytochrome c reductase associated with nitrate reductase was purified from both strains. The NADPH-dependent cytochrome c reductase associated with nitrate reductase was purified from both strains. The enzyme purified from wild-type N. crassa contained more than 1 mol of molybdenum per mol of enzyme, whereas the enzyme purified from nit-1 contained negligible amounts of molybdenum.     

A study of the nitrate and nitrite discharge from the mutant cells of Neurospora crassa lacking nitrate and nitrite reductase activities

The Neurospora crassa mutants nit-2 (lacking both nitrite and nitrate reductases) and nit-6 (lacking nitrite reductase) grown in the medium with ammonium chloride as a sole source of nitrogen discharged nitrate and nitrite ions into culture medium. For nit-2, the content of nitrate exceeded that of nitrite in both the homogenate of fungal cells and growth medium; moreover, this difference was more pronounced in the culture medium. Unlike nit-2, the content of nitrite in the cultivation medium of the nit-6 mutant irradiated with visible light for 30 min during the lag phase of carotenogenesis photoinduction displayed a trend of increase as compared with the dark control. Further (to 240 min) irradiation of cells, i.e., irradiation during biosynthesis of carotenoid pigments, leveled this difference.     

Restoration of reduced nicotinamide adenine dinucleotide phosphate-nitrate reductase activity of a Neurospora mutant by extracts of various chlorate-resistant mutants of Escherichia coli

Acid-treated extracts of Escherichia coli were tested for their ability to restore reduced nicotinamide adenine dinucleotide phosphate-nitrate reductase activity to an extract of a Neurospora nit-1 mutant which produces a defective enzyme. With wild-type E. coli this complementation activity was more readily detected in the cytoplasmic fraction, although the nitrate reductase activity was found primarily in the particulate fraction. chlB mutants of E. coli appeared to have more complementation activity in the cytoplasm than was observed in the wild type, but no activity in the particulate fraction. The other chl mutants had little or no activity in either fraction. These results suggest that chlB mutants can produce a component or cofactor which is missing in the other mutants and in the Neurospora mutant, but cannot transfer it to the nitrate reductase enzyme.     

Regulation of glutamate dehydrogenases in nit-2 and am mutants of Neurospora crassa.

The regulation of the glutamate dehydrogenases was investigated in wild-type Neurospora crassa and two classes of mutants altered in the assimilation of inorganic nitrogen, as either nitrate or ammonium. In the wild-type strain, a high nutrient carbon concentration increased the activity of reduced nicotinamide adenine dinucleotide phosphate (NADPH)-glutamate dehydrogenase and decreased the activity of reduced nicotinamide adenine dinucleotide (NADH)-glutamate dehydrogenase. A high nutrient nitrogen concentration had the opposite effect, increasing NADH-glutamate dehydrogenase and decreasing NADPH-glutamate dehydrogenase. The nit-2 mutants, defective in many nitrogen-utilizing enzymes and transport systems, exhibited low enzyme activities after growth on a high sucrose concentration: NADPH-glutamate dehydrogenase activity was reduced 4-fold on NH(4)Cl medium, and NADH-glutamate dehydrogenase, 20-fold on urea medium. Unlike the other affected enzymes of nit-2, which are present only in basal levels, the NADH-glutamate dehydrogenase activity was found to be moderately enhanced when cells were grown on a low carbon concentration. This finding suggests that the control of this enzyme in nit-2 is hypersensitive to catabolite repression. The am mutants, which lack NADPH-glutamate dehydrogenase activity, possessed basal levels of NADH-glutamate dehydrogenase activity after growth on urea or l-aspartic acid media, like the wild-type strain, and possessed moderate levels (although three- to fourfold lower than the wild-type strain) on l-asparagine medium or l-aspartic acid medium containing NH(4)Cl. These regulatory patterns are identical to those of the nit-2 mutants. Thus, the two classes of mutants exhibit a common defect in NADH-glutamate dehydrogenase regulation. Double mutants of nit-2 and am had lower NADH-glutamate dehydrogenase activities than either parent. A carbon metabolite is proposed to be the repressor of NADH-glutamate dehydrogenase in N. crassa.     

Identification of the molybdenum cofactor in chlorate-resistant mutants of Escherichia coli.

Experiments were performed to determine whether defects in molybdenum cofactor metabolism were responsible for the pleiotropic loss of the molybdoenzymes nitrate reductase and formate dehydrogenase in chl mutants of Escherichia coli. In wild-type E. coli, molybdenum cofactor activity was present in both the soluble and membrane-associated fractions when the cells were grown either aerobically or anaerobically, with and without nitrate. Molybdenum cofactor in the soluble fraction decreased when the membrane-bound nitrate reductase and formate dehydrogenase were induced. In the chl mutants, molybdenum cofactor activity was found in the soluble fraction of chlA, chlB, chlC, chlD, chlE, and chlG, but only chlB, chlC, chlD, and chlG expressed cofactor activity in the membrane fraction. The defect in the chlA mutants which prevented incorporation of the soluble cofactor into the membrane also caused the soluble cofactor to be defective in its ability to bind molybdenum. This cofactor was not active in the absence of molybdate, and it required at least threefold more molybdate than did the wild type in the Neurospora crassa nit-1 complementation assay. However, the cofactor from the chlA strain mediated the dimerization of the nit-1 subunits in the presence and absence of molybdate to yield the 7.9S dimer. Growth of chlA mutants in medium with increased molybdate did not repair the defect in the chlA cofactor nor restore the molybdoenzyme activities. Thus, molybdenum cofactor was synthesized in all the chl mutants, but additional processing steps may be missing in chlA and chlE mutants for proper insertion of cofactor in the membrane.     

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.     

Purification and further characterization of the second nitrate reductase of Escherichia coli K12

Two nitrate reductases, nitrate reductase A and nitrate reductase Z, exist in Escherichia coli. The nitrate reductase Z enzyme has been purified from the membrane fraction of a strain which is deleted for the operon encoding the nitrate reductase A enzyme and which harbours a multicopy plasmid carrying the nitrate reductase Z structural genes; it was purified 219 times with a yield of about 11%. It is an Mr-230,000 complex containing 13 atoms iron and 12 atoms labile sulfur/molecule. The presence of a molybdopterin cofactor in the nitrate reductase Z complex was demonstrated by reconstitution experiments of the molybdenum-cofactor-deficient NADPH-dependent nitrate reductase activity from a Neurospora crassa nit-1 mutant and by fluorescence emission and excitation spectra of stable derivatives of molybdoterin extracted from the purified enzyme. Both nitrate reductases share common properties such as relative molecular mass, subunit composition and electron donors and acceptors. Nevertheless, they diverge by two properties: their electrophoretic migrations are very different (RF of 0.38 for nitrate reductase Z versus 0.23 for nitrate reductase A), as are their susceptibilities to trypsin. An immunological study performed with a serum raised against nitrate reductase Z confirmed the existence of common epitopes in both complexes but unambiguously demonstrated the presence of specific determinants in nitrate reductase Z. Furthermore, it revealed a peculiar aspect of the regulation of both nitrate reductases: the nitrate reductase A enzyme is repressed by oxygen, strongly inducible by nitrate and positively controlled by the fnr gene product; on the contrary, the nitrate reductase Z enzyme is produced aerobically, barely induced by nitrate and repressed by the fnr gene product in anaerobiosis.     

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.     

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.     

Functional analysis of the Escherichia coli molybdopterin cofactor biosynthesis protein MoeA by site-directed mutagenesis

Five moeA mutants were generated by replacing some conserved amino acids of MoeA by site-directed mutagenesis. The mutants were assayed for the ability to restore in vivo nitrate reductase activity of the moeA mutant Escherichia coli JRG97 and in vitro Neurospora crassa nit-1 nitrate reductase activity. The replacements Asp59AlaGly60Ala, Asp259Ala, Pro298AlaPro301Ala abolished the function of MoeA in Mo-molybdopterin formation and stabilization, reflected in the inability to restore nitrate reductase activity. The replacements Gly251AlaGly252Ala reduced, and that of Pro283Ala had no effect, on nitrate reductase activity. E. coli JRG97 cells transformed with mutants that failed to restore nitrate reductase activity showed by HPLC analysis a decreased level of molybdopterin-derived dephospho FormA as compared to bacteria transformed with wild-type moeA. The effects of the amino acid replacements on MoeA function may be explained in correlation with the MoeA crystal structure.