Guard cell inward K+ channel activity in arabidopsis involves expression of the twin channel subunits KAT1 and KAT2.

Stomatal opening, which controls gas exchanges between plants and the atmosphere, results from an increase in turgor of the two guard cells that surround the pore of the stoma. KAT1 was the only inward K(+) channel shown to be expressed in Arabidopsis guard cells, where it was proposed to mediate a K(+) influx that enables stomatal opening. We report that another Arabidopsis K(+) channel, KAT2, is expressed in guard cells. More than KAT1, KAT2 displays functional features resembling those of native inward K(+) channels in guard cells. Coexpression in Xenopus oocytes and two-hybrid experiments indicated that KAT1 and KAT2 can form heteromultimeric channels. The data indicate that KAT2 plays a crucial role in the stomatal opening machinery.

Biochemical characterization of the Arabidopsis K+ channels KAT1 and AKT1 expressed or co-expressed in insect cells.

KAT1 and AKT1 belong to the multigenic family of the inwardly rectifying Shaker-like plant K+ channels. They were biochemically characterized after expression in insect cells using recombinant baculoviruses. The channels were solubilized from microsomal fractions prepared from infected cells (among eight different detergents only one, L-alpha-lysophosphatidylcholine, was efficient for solubilization), and purified to homogeneity using immunoaffinity (KAT1) or ion-exchange and size exclusion (AKT1) techniques. The following results were obtained with the purified polypeptides: (i) neither KAT1 nor AKT1 was found to be glycosylated; (ii) both polypeptides were mainly present as homotetrameric structures, supporting the hypothesis of a tetrameric structure for the functional channels; (iii) no heteromeric KAT1/AKT1 assembly was detected when the two polypeptides were co-expressed in insect cells. The use of the two-hybrid system in yeast also failed to detect any interaction between KAT1 and AKT1 polypeptides. Because of these negative results, the hypothesis that plant K+-channel subunits are able to co-assemble without any discrimination, previously put forward based on co-expression in Xenopus oocytes of various K+-channel subunits (including KAT1 and AKT1), has still to be supported by independent approaches. Co-localization of channel subunits within the same plant tissue/cell does not allow us to conclude that the subunits form heteromultimeric channels.

Tetramerization of the AKT1 plant potassium channel involves its C-terminal cytoplasmic domain.

All plant channels identified so far show high conservation throughout the polypeptide sequence except in the ankyrin domain which is present only in those closely related to AKT1. In this study, the architecture of the AKT1 protein has been investigated. AKT1 polypeptides expressed in the baculovirus/Sf9 cells system were found to assemble into tetramers as observed with animal Shaker-like potassium channel subunits. The AKT1 C-terminal intracytoplasmic region (downstream from the transmembrane domain) alone formed tetrameric structures when expressed in Sf9 cells, revealing a tetramerization process different from that of Shaker channels. Tests of subfragments from this sequence in the two-hybrid system detected two kinds of interaction. The first, involving two identical segments (amino acids 371-516), would form a contact between subunits, probably via their putative cyclic nucleotide-binding domains. The second interaction was found between the last 81 amino acids of the protein and a region lying between the channel hydrophobic core and the putative cyclic nucleotide-binding domain. As the interacting regions are highly conserved in all known plant potassium channels, the structural organization of AKT1 is likely to extend to these channels. The significance of this model with respect to animal cyclic nucleotide-gated channels is also discussed.

The IFH1 gene product interacts with a fork head protein in Saccharomyces cerevisiae.

FHL1 encodes a polypeptide closely related to the fork head protein family of transcriptional activators. Deleting this gene leads to a slow-growth phenotype with impaired rRNA maturation. IFH1 (located on chromosome IV) was isolated as a dosage-dependent suppressor partially correcting the growth defect of the fhl1 deletion. It codes for a highly hydrophilic protein with a predicted molecular weight of 122 kDa and a pI of 4.8, that is very rich in charged residues (mostly acidic) but otherwise unrelated to any known protein. Carboxy-terminal deletions removing the last third of the protein lead to a leaky growth phenotype with impaired rRNA maturation, as in the case of the fhl1 deletion. A full deletion of IFH1 is lethal, but growth was restored in a strain deleted for both IFH1 and FHL1. Thus, Ifh1p is essential for growth, but only in the presence of a functional Fhp1p protein. Conversely, its overexpression by increased gene dosage partially compensates for the genetic inactivation of Fhl1p. These data suggest a direct interaction between the Fhl1p and Ifh1p proteins, and are consistent with a model where Fhl1p is converted from a transcriptional repressor to an activator on binding of Ifh1p.

Isolation and characterization of nitrate reductase-deficient mutants in tomato (Lycopersicon esculentum Mill.).

Five nitrate reductase-deficient mutants of tomato were isolated from an M2 population after ethylmethanesulphonate (EMS) seed treatment by means of selection for chlorate resistance. All mutations were monogenic and recessive and complementation analysis revealed that they were non-allelic. Biochemical and molecular characterization of these mutants showed that four of them are cofactor mutants while one is an apoenzyme mutant.

Biochemical and Immunological Characterization of Nitrate Reductase Deficient nia Mutants of Nicotiana plumbaginifolia.

Sixty-five Nicotiana plumbaginifolia mutants affected in the nitrate reductase structural gene (nia mutants) have been analyzed and classified. The properties evaluated were: (a) enzyme-linked immunosorbent assay (two-site ELISA) using a monoclonal antibody as coating reagent and (b) presence of partial catalytic activities, namely nitrate reduction with artificial electron donors (reduced methyl viologen, reduced flavin mononucleotide, or reduced bromphenol blue), and cytochrome c (Cyt c) reduction with NADH. Four classes have been defined: 40 mutants fall within class 1 which includes all mutants that have no protein detectable in ELISA and no partial activities; mutants of classes 2 and 3 exhibit an ELISA-detectable nitrate reductase protein and lack either Cyt c reductase activity (class 2: fourteen mutants) or the terminal nitrate reductase activities (class 3: eight mutants) of the enzyme. Three mutants (class 4) are negative in the ELISA test, lack Cyt c reductase activity, and lack or have a very low level of reduced methyl viologen or reduced flavin mononucleotide-nitrate reductase activities; however, they retain the reduced bromphenol blue nitrate reductase activity. Variations in the degrees of terminal nitrate reductase activities among the mutants indicated that the flavin mononucleotide and methyl viologen-dependent activities were linked while the bromphenol blue-dependent activity was independent of the other two. The putative positions of the lesions in the mutant proteins and the nature of structural domains of nitrate reductase involved in each partial activity are discussed.

Nitrate reductases in hexaploid and tetraploid wheats and Aegilops.

Nitrate reductase activity (NR activity), protein content (NR protein) and polypeptides were compared in shoots of Triticum aestivum ssp. vulgare (L.) cv Fidel (bread wheat, AABBDD genome), Triticum dicoccum cv Vernal (AABB genome), Aegilops squarrosa var. strangulata (DD genome) and the amphiploid 365 (AABBDD genome), produced by crossing T. dicoccum cv Vernal and Ae. squarrosa var. strangulata. Constitutive NR protein and activity were found in shoots of all seedlings grown without nitrate, with the highest activity in the bread wheat. The inducible NR protein and activity developed upon the addition of nitrate. A 116-K polypeptide was identified as the main component of the NR from the bread wheat, while a faint, sometimes discernable 94-K band appeared on Western blots. Only one NR polypeptide could be identified in Ae. squarrosa -the 94 K. An intermediary situation was observed with the tetraploid T. dicoccum and the amphiploid: The 94-K polypeptide was the only one separated from NR of seedlings grown in the absence of nitrate. The 116-K polypeptide appeared after the addition of nitrate. The intensity of its band on the gel increased with the duration of the nitrate treatment. When comparing Ae. squarrosa and T. dicoccum, the constitutive isozyme (94-K polypeptide) was found in the D as well as in the AB genomes, while the inducible NR (116-K polypeptide) was absent from the D genome. Addition of the D genome into the AB genome slightly reinforced the expression of the inducible form (AB genome expression) in the amphiploid wheat. We postulate that the inducible form of NR in the bread wheat resulted from an evolutionary selection pressure favoured by cultivation.

Nitrate Reductase mRNA Regulation in Nicotiana plumbaginifolia Nitrate Reductase-Deficient Mutants.

Light and substrate regulation of nitrate reductase (NR) expression were compared in wild type and mutant lines of Nicotiana plumbaginifolia. Mutants affected in the NR structural gene (nia) or in the biosynthesis of the NR molybdenum cofactor (cnx) were examined. nia mutants expressing a defective apoenzyme, as well as cnx mutants, overexpressed NR mRNA, whereas nia mutants devoid of detectable NR protein had reduced or undetectable NR mRNA levels. Diurnal fluctuations of NR mRNA were specifically abolished in nia and cnx mutants, suggesting that the integrity of NR catalytic activity is required for the expression of diurnal oscillations. Unlike some fungal mutants, the nia and cnx mutants examined retained nitrate inducibility of NR expression. The possibility of autogenous control of NR expression in higher plants is discussed.

Cloning of DNA fragments complementary to tobacco nitrate reductase mRNA and encoding epitopes common to the nitrate reductases from higher plants.

Messenger RNAs encoding the nitrate reductase apoenzyme from tobacco can be translated in a cell-free system. Poly(A)+ mRNA fractions from the 23-32 S area of a sucrose gradient were used to build a cDNA library in the expression vector gt11 with an efficiency of cloning of approximately 10(4) recombinants/ng mRNA. Recombinant clones were screened with a rabbit polyclonal antibody directed against the corn nitrate reductase, which cross reacts specifically with the nitrate reductases from dicotyledons. Among 240000 recombinant plaques, eight clones were isolated containing inserts of sizes ranging from 1.6 kb to 2.1 kb and sharing sequence homologies. Seven of these clones contained a common internal 1.6 kb EcoRI fragment. The identity of these clones was confirmed as follows. A fusion protein of 170 kDa inducible by IPTG and recognized by the rabbit nitrate reductase antibody was expressed by a lysogen derived from one of the recombinants. The antibodies binding the fused protein were eluted and shown to be inhibitory to the catalytic activity of tobacco nitrate reductase. Two monoclonal antibodies directed against nitrate reductase were also able to bind the hybrid protein. The 1.6 kb EcoRI fragment was sequenced by the method of Sanger. The open reading frame corresponding to a translational fusion with the -galactosidase coding sequence of the vector shared strong homology at the amino acid level with the heme-binding domain of proteins of the cytochrome b5 superfamily and with human erythrocyte cytochrome b5 reductase. When the 1.6 kb EcoRI fragment was used as a probe for Northern blot experiments a signal corresponding to a 3.5 kb RNA was detected in tobacco and in Nicotiana plumbaginifolia mRNA preparations but no cross-hybridization with corn mRNAs was detected. The probe hybridized with low copy number sequences in genomic blots of tobacco DNA.

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

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 suggests 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 methylviologen-nitrate 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.

Bromphenol blue: nitrate reductase activity in Nicotiana plumbaginifolia: an immunochemical and genetic approach.

NADH: nitrate reductase (EC 1.6.6.1) was purified from Nicotiana plumbaginifolia leaves. As recently observed with nitrate reductase from other sources, this enzyme is able to reduce nitrate using reduced bromphenol blue (rBPB) as the electron donor. In contrast to the physiological NADH-dependent activity, the rBPB-dependent activity is stable in vitro. The latter activity is non-competitively inhibited by NADH. The monoclonal antibody ZM.96(9)25, which inhibits the NADH: nitrate reductase total activity as well as the NADH: cytochrome c reductase and reduced methyl viologen (rMV): nitrate reductase partial activities, has no inhibitory effect on the rBPB: nitrate reductase activity. Conversely, the monoclonal antibody NP.17-7(6) inhibits nitrate reduction with all three electron donors: NADH, MV or BPB. Among various nitrate reductase-deficient mutants, an apoprotein gene mutant (nia. E56) shows reduced terminal activities but a highly increased rBPB:nitrate reductase activity. rBPB:nitrate reductase thus appears to be a new terminal activity of higher plant nitrate reductase and involves specific sites which are not shared by the other activities.

Immunological comparisons of nitrate reductase of different plant species using monoclonal antibodies.

Six monoclonal antibodies against different epitopes of maize leaf nitrate reductase were used to compare plant nitrate reductases in enzyme linked immunosorbent assay and enzyme activity inhibition tests. The number of cross-reacting antibodies was shown to vary with species according to phylogenetic classification, ranging from five (sugarcane) to one (dicotyledonous species). Cross-reactions were restricted to higher plant nitrate reductases.

Monoclonal antibodies identify multiple epitopes on maize leaf nitrate reductase.

Nine hybridoma cell lines secreting antibodies against the maize leaf nitrate reductase have been distinguished by reciprocal competition for binding to the antigenic site. Inhibition of enzymatic activities, and western blots of native enzyme and denatured subunits revealed different behaviors of individual antibodies towards the antigen. Two classes of monoclonal antibodies are inhibitory of NADH and methyl viologen nitrate reductase activities, but only one affects also NADH cytochrome c reductase activity. The associated epitopes are sensitive to antigen conformation. Among the 4 other classes, one is specific for the native conformation of the molecule, another binds more strongly to the denatured antigen, and two recognize equally well the two forms.