Isolation and characterization of Nicotiana plumbaginifolia nitrate reductase-deficient mutants: genetic and biochemical analysis of the NIA complementation group

Summary Two hundred and eleven nitrate reductase-deficient mutants (NR^–) were isolated from mutagenized Nicotiana plumbaginifolia protoplast cultures by chlorate selection and regenerated into plant. More than 40% of these clones were classified as cnx and presumed to be affected in the biosynthesis of the molybdenum cofactor, the remaining clones being classified as nia mutants. A genetic analysis of the regenerated plants confirmed this proportion of nia and cnx clones. All mutants regenerated were found to carry monogenic recessive mutations that impaired growth on nitrate as sole nitrogen source. Mutants propagated by grafting on N. tabacum systematically displayed a chlorotic leaf phenotype. This chlorosis was therefore related to the NR deficiency. The observation of leaves with NR^– chlorotic sectors surrounded by NR⁺ wild-type tissues suggeests that an NR deficiency is not corrected by diffusible factors. Periclinal chimeras between wild-type tobacco and the NR^– graft were also observed. In this type of chimeric tissue chlorosis was no longer detectable when NR⁺ cells were in the secondmost (L2) layer, but was still detectable when NR^– cells were in the secondmost layer. The genetic analysis of nia mutants revealed that they belong to a single complementation group. However three nia mutants were found to complement some of the other nia mutants. The apoenzyme of nitrate reductase was immunologically detected in several nia mutants but not in other members of this complementation group. Some of the nia mutants, although they were NR^–, still displayed methylviologenitrate reductase activity at a high level. These data show that the nia complementation group corresponds to the structural gene of nitrate reductase. Some of the mutations affecting this structural gene result in the overproduction of an inactive nitrate reductase, suggesting a feedback regulation of the level of the apoenzyme in the wild type.     

Co-segregation of nitrate-reductase activity and normal regeneration ability in selfed sibs of Nicotiana plumbaginifolia somatic hybrids,heterozygotes for nitrate-reductase deficiency

Summary The nitrate-reductase (NR) defective cell lines of Nicotiana plumbaginifolia isolated in our laboratory could not be regenerated into plants on the standard medium (Márton et al. 1982 a). The normal regeneration potential, however, was restored in somatic hybrids obtained by fusing the NR^– (green) lines with a pigment deficient (P^–), but NR⁺ line, A28. Somatic hybrid plants were fertile in two combinations (A28 + NA9 and A28 + NX9). As expected, segregation for NR^– and P^– was found after selfing the somatic F1 (SF1) obtained by protoplast fusion, and in the F2. The variable segregation ratios are explained by chromosome abnormalities. Co-segregation of the NR^– phenotype and the altered response to shoot induction on standard medium suggest the involvement of the nitrate-assimilatory pathway in determining shoot regeneration ability.     

Genetic analysis of nitrate reductase deficient mutants of Nicotiana plumbaginifolia: Evidence for six complementation groups among 70 classified molybdenum cofactor deficient mutants

Summary A total of 70 cnx mutants have been characterized from a collection of 211 nitrate reductase deficient (NR^-) mutants isolated from mutagenized Nicotiana plumbaginifolia protoplast cultures after chlorate selection and regeneration into plants. They are presumed to be affected in the biosynthesis of the molybdenum cofactor since they are also deficient for xanthine dehydrogenase activity but contain NR apoenzyme. The remaining clones were classified as nia mutants. Sexual crosses performed between cnx mutants allowed them to be classified into six independent complementation groups. Mutants representative of these complementation groups were used for somatic hybridization experiments with the already characterized N. plumbaginifolia mutants NX1, NX24, NX23 and CNX103 belonging to the complementation groups cnxA, B, C and D respectively. On the basis of genetic analysis and somatic hybridization experiments, two new complementation groups, cnxE and F, not previously described in higher plants, were characterized. Unphysiologically high levels of molybdate can restore the NR activity of cnxA mutant seedlings in vivo, but cannot restore NR activity to any mutant from the other cnx complementation groups.     

Nitrate reductase deficient cell lines from haploid protoplast cultures ofNicotiana plumbaginifolia

Summary Nitrate reductase deficient (NR^-) cell lines were selected indirectly by their resistance to 40 mM chlorate in protoplast cultures of haploidNicotiana plumbaginifolia. Frequency of the chlorate resistant clones was 5.8×10^-5 in non-mutagenized cultures, which could be increased up to 25 times by treatment with N-ethyl-N-nitrosourea (NEU) or gamma irradiation.Out of 136 chlorate resistant clones 29 were fully deficient in nitrate reductase. The rest of the clones contained decreased or normal levels of NR activity (91 and 16 clones, respectively).Further characterization was carried out in 9 clones which were fully deficient in NR and in 2 clones containing resisdual (0–5%) NR activity. The clones were tentatively classified as defective in the apoenzyme (7 clones including the 2 with residual NR activity) or the cofactor (4 clones) of NR by the xanthine dehydrogenase activity and in vitro enzyme complementation. The cofactor defectives could be further classified into two groups. In one of these (2 clones) the NR activity could be partially restored by unphysiologically high (0.2–1 mM) molybdate in the culture medium. The other two are new types which have not been described in flowering plants.Plant regeneration was obtained only in the clones which contained residual NR activity.     

Complementation analysis of a nitrate reductase deficient Hyoscyamus muticus cell line by somatic hybridisation

Summary Complementation of a nitrate reductase deficient variant of Hyoscyamus muticus (MA-2) and nitrate reductase apoenzyme (nia-115) and cofactor mutants (cnx-68) of Nicotiana tabacum was studied by protoplast fusion. Selection of prototrophic intergeneric somatic hybrids was achieved in combination of MA-2 with the apoenzyme mutant nia-115 of N. tabacum. The H. muticus MA-2 line was therefore classified to be a cnx type variant possessing an altered molybdenum cofactor of the nitrate reductase enzyme complex but unaffected in the apoprotein of nitrate reductase. The nitrate reductase deficient and chlorate resistant characters of MA-2 were functionally coupled recessive traits. Nitrate reductase activity accompanied by chlorate sensitivity could be detected only under inductive conditions in the somatic hybrids. The inductive expression of nitrate reductase in the somatic hybrids arising from the combination of cells harbouring either the inductive or constitutive type nitrate reductase is discussed.Abbreviations DTT 1,4-Dithio-DL-threitol - Mo-co molybdenum containing cofactor - PEG polyethylene glycol     

Biochemical and genetical characterization of nitrate reductase deficient mutants of Petunia

Four NR^– lines were selected by their resistance to 100 mM chlorate from X-ray irradiated protoplasts of haploid Petunia hybrida var. Mitchell. The four cell lines were characterized by the presence of xanthine dehydrogenase activity and by complementation tests via protoplast fusion. One mutant (line 1) was classified as defective in the NR apoprotein (tentatively, nia-type) and the other three (lines 2, 3, 4) in the molybdenum cofactor (tentatively, cnx-type). Some NR activity (15 %) could be restored by adding unphysiologically high concentrations of molybdate to the culture medium in two of the cnx-lines (lines 3 and 4). The third cnx-line (line 2) had no NR activity. A complementation analysis via protoplast fusion confirmed that the mutants comprised 3 non-allelic groups. From these results it can be concluded that these NR^– mutants are recessive and that two of the cnx-mutants (lines 3, 4) are allelic.Abbreviations MS Murashige and Skoog medium (Murashige and Skoog 1962) - MG Müller and Grafe medium (Müller and Grafe 1978), containing amino acids - V47 protoplast medium (Binding 1974) - MS-413-medium (McCormack and Hanson 1980) - IAA indoleacetic acid - BA benzyladenine - NAA -naphthaleneacetic acid - 2,4-D 2,4-dichlorophenoxyacetic acid - AA amino acids - XDH xanthine dehydrogenase - PEG polyethylene glycol - NR nitrate reductase     

Genetic analysis of revertants for the nitrate reductase function of Nicotiana plumbaginifolia

Summary Spontaneous revertants of nitrate reductase (NR)-less mutants were isolated by screening for nitrate utilization in diploid NR^– protoplast cultures of Nicotiana plumbaginifolia. The revertants contained in vivo NR activity in the case of apoenzyme mutants (nia) as well as of a cofactor-deficient (cnx) mutant. Revertants of the NIA type proved to be tetraploid, and genetic analysis showed that only one out of the four NR structural genes had reverted to a functional allele.     

Metabolic complementation for a single gene function associated with partial and total loss of donor DNA in interspecific somatic hybrids

Summary We report here on the obtainment of interspecific somatic, asymmetric, and highly asymmetric nuclear hybrids via protoplast fusion. Asymmetric nuclear hybrids were obtained after fusion of mesophyll protoplasts from a nitrate reductase-deficient cofactor mutant of N. plumbaginifolia with irradiated (100 krad) kanamycin resistant leaf protoplasts of a haploid N. tabacum. Selection for nitrate reductase (NR) and/or kanamycin (Km) resistance resulted in the production of three groups of plants (NR⁺, NR⁺, Km^R, and NR^-Km^R). Cytological analysis of some hybrid regenerants showed the presence of numerous tobacco chromosomes and chromosome fragments, besides a polyploid N. plumbaginifolia genome (tetra or hexaploid). All the regenerants tested were male sterile but some of them could be backcrossed to the recipient partner. In a second experiment, somatic and highly asymmetric nuclear hybrids were obtained after fusion of mesophyll protoplasts from the universal hybridizer of N. plumbaginifolia with suspension protoplasts of a tumor line of N. tabacum. Selection resulted in two types of colonies: nonregenerating hybrid calli turned out to be true somatic hybrids, while cytological analysis of regenerants obtained on morphogenic calli did not show any presence of donor-specific chromosomes. Forty percent of the hybrid regenerants were completely fertile, while the others could only be backcrossed to the recipient N. plumbaginifolia. Since the gene we selected for is not yet cloned, we were not able to demonstrate the transfer of genetic material at the molecular level. However, since no reversion frequency for the nitrate reductase mutant is known, and due to a detailed cytological knowledge of both fusion partners, we feel confident in speculating that intergenomic recombination between N. plumbaginifolia and N. tabacum has occurred.     

A rapid assay for genetic complementation of nitrate reductase deficiency via bulk protoplast fusion

Summary Genetic complementation of different nitrate reductase-deficient (NR^-) Nicotiana plumbaginifolia cell lines could be recognized in the described fusion disc technique as early as 5–10 days after protoplast fusion. Protoplasts of previously characterized mutant cell lines, belonging to four different complementation groups, were mixed in pairwise combinations and fused by the drop-wise fusion technique at very high protoplast densities (10⁶ protoplasts in an 8–10 mm spot) which resulted in the formation of a fusion disc on the bottom of the petri dish. After 5–10 days of incubation in K3 medium the restoration of NR activity could be detected directly in the original culture by the in vivo NR assay. Such a rapid test giving information about the genetic complementation of different auxotrophic cell lines has not previously been published for plants.     

Chromosomes in somatic hybrids between Nicotiana plumbaginifolia and a monoploid potato

Summary Leaf mesophyll protoplasts of the monohaploid potato (Solanum tuberosum L.) clone H7322 were fused with callus protoplasts of nitrate reductase deficient (NR^–) mutants Cnx 20 and NA 36 of Nicotiana plumbaginifolia. Somatic hybrid lines were selected for nitrate reductase proficiency. All callus lines tested appeared to be stable for the retention of the potato chromosome carrying the compensating NR gene when grown for over 1.5 years in the absence of nitrate. Shoots were regenerated from six different fusion lines of Cnx 20 + H7322 24 months after fusion. Chromosomal analysis in callus cultures revealed that in both fusion combinations 40–120 N. plumbaginifolia chromosomes were present, as were 9–20 potato chromosomes. Cells with 17 potato chromosomes in combination with a relatively small number (31) of N. plumbaginifolia chromosomes were found in one line. Preferential loss of species-specific chromosomes was not observed. Analysis of regenerating tissue from three lines of Cnx 20 + H7322 revealed that after 24 months of culture intra- and intergeneric translocations, fragments and deletions were present. Elimination of the potato and N. plumbaginifolia chromosomes had taken place before and after genome doubling.     

Nitrate and Nitrite Reduction in Relation to Nitrogenase Activity in Soybean Nodules and Rhizobium japonicum Bacteroids

Soybean (Glycine max L. cv Williams) seeds were sown in pots containing a 1:1 perlite-vermiculite mixture and grown under greenhouse conditions. Nodules were initiated with a nitrate reductase expressing strain of Rhizobium japonicum, USDA 110, or with nitrate reductase nonexpressing mutants (NR⁻ 108, NR⁻ 303) derived from USDA 110. Nodules initiated with either type of strain were normal in appearance and demonstrated nitrogenase activity (acetylene reduction). The in vivo nitrate reductase activity of N₂-grown nodules initiated with nitrate reductase-negative mutant strains was less than 10% of the activity shown by nodules initiated with the wild-type strain. Regardless of the bacterial strain used for inoculation, the nodule cytosol and the cell-free extracts of the leaves contained both nitrate reductase and nitrite reductase activities. The wild-type bacteroids contained nitrate reductase but not nitrite reductase activity while the bacteroids of strains NR⁻ 108 and NR⁻ 303 contained neither nitrate reductase nor nitrite reductase activities.

Addition of 20 millimolar KNO₃ to bacteroids of the wild-type strain caused a decrease in nitrogenase activity by more than 50%, but the nitrate reductase-negative strains were insensitive to nitrate. The nitrogenase activity of detached nodules initiated with the nitrate reductase-negative mutant strains was less affected by the KNO₃ treatment as compared to the wild-type strain; however, the results were less conclusive than those obtained with the isolated bacteroids.

The addition of either KNO₃ or KNO₂ to detached nodules (wild type) suspended in a semisolid agar nutrient medium caused an inhibition of nitrogenase activity of 50% and 65% as compared to the minus N controls, and provided direct evidence for a localized effect of nitrate and nitrite at the nodule level. Addition of 0.1 millimolar sucrose stimulated nitrogenase activity in the presence or absence of nitrate or nitrite. The sucrose treatment also helped to decrease the level of nitrite accumulated within the nodules.

     

Electrofusion,a simple and reproducible technique in somatic hybridization of Nicotiana plumbaginifolia mutants

Electrofusion of protoplasts from two complementary nitrate reductase deficient mutants of Nicotiana plumbaginifolia has resulted in somatic hybrid lines. Mesophyll protoplasts isolated from the cofactor mutant CNX 20 and fluorescein diacetate stained protoplasts derived from a cell suspension culture of the NA 36 line, being defective in the apoenzyme, were used in the fusion experiments. In total, 594 lines were recovered which could proliferate on a selective medium with nitrate as the sole nitrogen source. This is including 141 putative hybrid lines which were obtained after transfer of 1048 heterokaryons with a micromanipulator one day after electrofusion. The hybrid character of some of the selected lines was confirmed by nitrate reductase activity measurements. Plants were grown from hybrid calli.Abbreviations NR nitrate reductase - FDA fluorescein diacetate - 2,4-D 2,4-dichlorophenoxyacetic acid - BAP benzylaminopurine - NAA naphthaleneacetic acid - NED N-1-naphtyl-ethylenediamide hydrochloride - PEG polyethylene glycol - AC alternating current - DC direct current     

Characterization of a new type of molybdenum cofactor-mutant in cell cultures of Nicotiana tabacum

Summary Four allelic putative cnx (molybdenum-cofactor defective) cell lines (O42, P12, P31 and P47) of Nicotiana tabacum var. Xanthi, biochemically and genetically distinct from N. tabacum var. Gatersleben cnxA mutants, were examined further. Their molybdenum-cofactor could efficiently reconstitute NADPH-nitrate reductase activity from Neurospora crassa mutant nit-1 extract only in the presence of exogenous molybdenum unlike that of the wild-type cofactor which could reconstitute NADPH-nitrate reductase activity in either the absence or presence of exogenous molybdenum. Loss of cofactor activity in vivo was not due to a defect in molybdenum uptake into the cells. In vitro nitrate reductase complementation between extracts of each of these four lines and a nia mutant showed that they possessed a functional nitrate reductase haemoflavoprotein subunit. Both constitutive molybdenum cofactor and NADH cytochrome c reductase activity were derepressed in the four cell lines. These results show that the four cell lines are indeed altered at a cnx locus, called cnxB, that the defect is probably in molybdenum processing and that there is a link between synthesis of functional molybdenum cofactor and nitrate reductase aporprotein.     

Presence of the molybdenum-cofactor in nitrate reductase-deficient mutant cell lines of Nicotiana tabacum

Summary Nicotiana tabacum mutant cell cultures lacking nitrate reductase activity were assayed for the presence of the molybdenum-cofactor using its ability to restore NADPH-nitrate reductase activity in extracts of Neurospora crassa nit-1 mycelia. The molybdenum-cofactor of the tobacco wild-type line was shown to complement efficiently the N. crassa nit-1 mutant in vitro. The molybdenum-cofactor seems to exist in a bound form, as acid-treatment was required for release of cofactor activity. Molybdate (5–10 mM), ascorbic acid, and anaerobic conditions greatly increased the activity of the cofactor, demonstrating its high lability and sensitivity to oxygen. Similar results were obtained with two tobacco nia mutants, which are defective in the apoprotein of nitrate reductase. The four cnx mutants studied were shown to contain exclusively an inactive form of the molybdenum-cofactor. This inactive cofactor could be reactivated in vitro and in vivo by unphysiologically high concentrations of molybdate (1–10 mM), thereby converting the cnx cells into highly active cofactor sources in vitro, and restoring nitrate reductase and xanthine dehydrogenase in vivo to partial acitivity. Thus the defect of the cnx mutants resides in a lack of molybdenum as a catalytically active ligand metal for the cofactor, while the structural moiety of the cofactor seems not to be impaired by the mutation. The subunit assembly of the nitrate reductase was found to be independent of the molybdenum content of the cofactor.     

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.     

Studies of nitrate reductase in the fresh water dinoflagellatePeridinium cinctum

Nitrate reduction was studied in the dinoflagellatePeridinium cinctum collected from extensive algal blooms in Lake Kinneret (Israel).Among several methods tested for the preparation of cell free extracts, only the use of a ground-glass tissue culture homogenizer was found to be efficient. The assimilatory nitrate reductase ofP. cinctum was located in a particulate fraction. In this respect,P. cinctum did not behave like other eukaryotes, such as green algae, but as a prokaryote. Nitrite reductase activity was found in the soluble fraction.Nitrate reductase used NADH as a preferable electron donor; it reacted also with NADPH but only to give 16.5% of the NADH dependent rate. Methyl viologen and benzyl viologen could also serve as electron donors, with rates higher than the NADH dependent activity (3–6 times and 1.5–3 times, respectively). The Km of nitrate reductase for NADH was 2.8×10^–4 M and for NO₃-1.9×10^–4 M. Flavins did not stimulate the activity, nor was ferricyanide able to activate it. Carboxylic anions stimulated nitrate reductase activity 3–4 fold, an effect which was not mimicked by other anions.Chlorate, azide and cyanide were competitive inhibitors ofP. cinctum, nitrate reductase withK _i values of 1.79×10^–3 M, 2.1×10^–5 M and 8.9×10^–6 M respectively.     

Combination of kanamycin resistance and nitrate reductase deficiency as selectable markers in one nuclear genome provides a universal somatic hybridizer in plants

Summary The combination in the nuclear genome of a dominant resistance marker (to select against unfused wild-type cells) and a recessive deficiency marker (to select against unfused mutant cells) in a cell line should provide a system for selecting fusion hybrids between the mutant line and any wild-type line. To test this idea, we fused protoplasts from a non-morphogenic cell line of Nicotiana tabacum which was kanamycin resistant (by transformation) and deficient in nitrate reductase (NR^-K⁺) with protoplasts from N. tabacum cv. Petit Havana clone SR1, which provided resistance against streptomycin as an additional selectable marker (NR⁺K^-SR⁺). Putative hybrids were selected using a culture medium containing no available reduced nitrogen source and 50 mg/l kanamycin sulphate. After regeneration into plants, the hybrid character was demonstrated from: (i) the morphological variation of the regenerants; (ii) the chromosome number; (iii) the ability to grow on medium without a reduced nitrogen source and containing kanamycin sulphate at 50 mg/l; (iv) the presence of nitrate reductase activity; (v) the presence of the gene coding for neomycin phosphotransferase, which provides resistance to kanamycin sulphate; (vi) callus formation from leaves on medium containing 1 g/l streptomycin or 50 mg/l kanamycin sulphate; (vii) F₁ plants containing nitrate reductase and the gene for neomycin phosphotransferase. Fusions between the mutant cell line (NR^-K⁺) and three wild-type tobacco species and subsequent cultivation on medium containing no available nitrogen source but 50 mg/l kanamycin sulphate resulted in callus formation with all combinations, while hybrid plants were only regenerated when N. sylvestris was the fusion partner.     

Complementation analysis by somatic hybridisation and genetic crosses of nitrate reductase-deficient mutants of Nicotiana plumbaginifolia

Summary Fusion complementation experiments between nitrate reductase (NR) deficient lines CNX 20, 27, 82 and 103 of Nicotiana plumbaginifolia were performed with the already characterized N. plumbaginifolia mutants nx 1, 24 and 21, belonging respectively to the complementation groups cnx A, B and C. CNX 20 and 82 were identified as belonging to the group of cnx A. CNX 27 complemented with NX 1 and NX 21 but not with NX 24 indicating another B type. The fourth line, CNX 103 showed complementation with CNX 20, NX 21 and NX 24, revealing a fourth cnx complementation group, cnx D, that until now has not been described in higher plants. Genetic crosses inside respectively the NIA and the CNX group, and between NIA and CNX confirmed the fusion complementation results, and showed allelism for the nia mutants     

Non-coordinate expression of the neighbouring genes rplL and rpoB,C of Escherichia coli.

Summary Two types of nitrate reductase-deficient mutant cell lines (nia and cnx) of Nicotiana tabacum have been used for in vitro reconstitution of NADH-nitrate reductase. The cnx mutants simultaneously lack NADH-,FADH₂-, red benzyl viologen-nitrate reductase, and xanthine dehydrogenase activities, but retain the nitrate reductase-associated NADH-cytochrome c reductase activity. These mutants are interpreted to be defective in the molybdenum-containing cofactor necessary for nitrate reductase activity. In the nia lines xanthine dehydrogenase activity is unaffected, and the loss of NADH-nitrate reductase is accompanied by a loss of all partial activities of nitrate reductase, including NADH-cytochrome c reductase. When cnx cells (induced by nitrate) were homogenized together with nia cells (induced by nitrate or uninduced), NADH-nitrate reductase activity was detectable in the cell extract. No nitrate reductase was observed when the cnx mutants were homogenized together, or after cohomogenization of the nia mutants. Thus, the inactive nitrate reductase molecule formed in the cnx mutants has been complemented in vitro with the molybdenum-containing cofactor supplied by nia extracts, thus giving rise to NADH-nitrate reductase activity. This result gives additional support to the interpretation that the active nitrate reductase of Nicotiana tabacum is composed of at least the NADH-cytochrome c reductase moiety and a molybdenum-containing cofactor which is formed by the action of the cnx gene product(s).     

Mutation of the regulatory phosphorylation site of tobacco nitrate reductase results in high nitrite excretion and NO emission from leaf and root tissue

In wild-type Nicotiana plumbaginifolia Viv. and other higher plants, nitrate reductase (NR) is regulated at the post-translational level and is rapidly inactivated in response to, for example, a light-to-dark transition. This inactivation is caused by phosphorylation of a conserved regulatory serine residue, Ser 521 in tobacco, and interaction with divalent cations or polyamines, and 14-3-3 proteins. The physiological importance of the post-translational NR modulation is presently under investigation using a transgenic N. plumbaginifolia line. This line expresses a mutated tobacco NR where Ser 521 has been changed into aspartic acid (Asp) by site-directed mutagenesis, resulting in a permanently active NR enzyme [C. Lillo et al. (2003) Plant J 35:566–573]. When cut leaves or roots of this line (S₅₂₁) were placed in darkness in a buffer containing 50 mM KNO₃, nitrite was excreted from the tissue at rates of 0.08–0.2 mol (g FW)^–1 h^–1 for at least 5 h. For the control transgenic plant (C1), which had the regulatory serine of NR intact, nitrite excretion was low and halted completely after 1–3 h. Without nitrate in the buffer in which the tissue was immersed, nitrite excretion was also low for S₅₂₁, although 20–40 mol (g FW)^–1 nitrate was present inside the tissue. Apparently, stored nitrate was not readily available for reduction in darkness. Leaf tissue and root segments of S₅₂₁ also emitted much more nitric oxide (NO) than the control. Importantly, NO emission from leaf tissue of S₅₂₁ was higher in the dark than in the light, opposite to what was usually observed when post-translational NR modulation was operating.Abbreviations NR Nitrate reductase - NO Nitric oxide - Ser Serine - WT Wild type