Genetic analysis of nitrate reductase-deficient mutants in Chlamydomonas reinhardii

Summary Six mutants (305, 301, 203, 307, 104 and 102) of Chlamydomonas reinhardii, all defective in nitrate reductase (NR) activity, have been genetically analyzed. All except 102 carry single Mendelian mutations.Mutant 305, defective in diaphorase activity and mutant 301, defective in terminal enzyme activity, did not give rise to wild-type recombinants when crossed to each other or with the nit-1 mutant isolated from strain 137c (which is actually a double mutant nit-1 nit-2). Nit-1 was shown to lack both diaphorase and terminal activities. Whether the mutated sites in 305 and 301 are located in a unique cistron (nit-1) or in two adjacent cistrons (nit-1a and nit-1b) coding for a diaphorase subunit and a terminal subunit of NR is discussed in the light of previous biochemical findings.The 203 mutation affecting a regulatory gene did not recombine with nit-2, the other mutated locus present in strain 137c.Mutants 307, 104 and 102, all lacking molybdenum cofactor for both NR and xanthine dehydrogenase, where shown to be affected in different loci. The genes mutated in 307 and 104 have been designated nit-3 and nit-4, respectively. The 102 strain is mutated in two non-linked loci, nit-5 and nit-6, with both mutations required to confer the mutant phenotype. One of these cryptic mutations is present in the wild strain 21gr.The results indicate that at least six or seven loci are involved in the production of an active NR enzyme: one (nit-1) or two (nit-1a and nit-1b) cistrons to produce the NR apoproteins responsible for the partial activities diaphorase and terminal, one locus (nit-2) for the regulation of NR synthesis, and four loci (nit-3, nit-4, nit-5 and nit-6) to produce the molybdenum cofactor. The loci nit-1a and nit-2 seem to correspond to the nit-A and nit-B loci described by Nichols and Syrett (J Gen Microbiol 108:71–77, 1978).Abbreviations NR nitrate reductase - MNNG N-methyl-N-nitro-N-nitrosoguanidine - MoCo molybdenum-containing cofactor - PD parental ditype - NPD non-parental ditype - TT tetratype - WT wild type - BVH reduced benzyl viologen     

NIT2, the nitrogen regulatory protein of Neurospora crassa,binds upstream of nia,the tomato nitrate reductase gene,in vitro

Summary The nit-2 gene of Neurospora crassa encodes a trans-acting regulatory protein that activates the expression of a number of structural genes which code for nitrogen catabolic enzymes, including nitrate reductase. The NIT2 protein contains a Cys2/Cys2-type zinc-finger DNA-binding domain that recognizes promoter regions of the Neurospora nitrogen-related genes. The NIT2 zincfinger domain/-Gal fusion protein was shown to recognize and bind in a specific manner to two upstream fragments of the nia gene of Lycopersicon esculentum (tomato) in vitro, whereas two mutant NIT2 proteins failed to bind to the same fragments. The dissociation kinetics of the complexes formed between the NIT2 protein and the Neurospora nit-3 and the tomato nia gene promoters were examined; NIT2 binds more strongly to the nit-3 promoter DNA fragment than it does to fragments derived from the plant nitrate reductase gene itself. The observed specificity of the binding suggests the existence of a NIT2-like homolog which regulates the expression of the nitrate assimilation pathway of higher plants.     

Transformants of Neurospora crassa with the nit-4 nitrogen regulatory gene: copy number,growth rate and enzyme activity

Summary nit-4 is a pathway-specific regulatory gene which controls nitrate assimilation in Neurospora crassa, and appears to mediate nitrate induction of nitrate and nitrite reductase. The NIT4 protein consists of 1090 amino-acid residues and possesses a single GAL4-like putative DNA-binding domain plus acidic, glutaminerich, and polyglutamine regions. Several mutants with amino-acid substitutions in the putative DNA-binding domain and a nit-4 deletion mutant, which encodes a truncated NIT4 protein lacking the polyglutamine region, are functional, i.e., they are capable of transforming a nit-4 mutant strain. However, transformants obtained with most of these nit-4 mutant genes possess a markedly reduced level of nitrate reductase and grow only slowly on nitrate, emphasizing the need to examine quantitatively the affects of in vitro-manipulated genes. The possibility that some mutant genes could yield transformants only if multiple copies were integrated was examined. The presence of multiple copies of wild-type or mutant nit-4 genes did not generally lead to increased enzyme activity or growth rate, but instead frequently appeared to be detrimental to nit-4 function. A hybrid nit-4-nirA gene transforms nit-4 mutants but only allows slow growth on nitrate and has a very low level of nitrate reductase.     

Isolation and characterization of a methylammonium resistant mutant of Neurospora crassa

Summary A mutant of Neurospora crassa has been isolated which is resistant to methylammonium, a structural analog of ammonium. In contrast to wild type, this mutant, mea-1, has derepressed nitrate reductase and nitrite reductase activities in the presence of ammonium. However, glutamine still represses these nitrate assimilation enzymes in mea-1. The nit-2 mutant was epistatic to mea-1 since the mea-1; nit-2 double mutant has the nit-2 mutant phenotype. In addition, mea-1; nit-2 double mutants cannot utilize ammonium as a nitrogen source. We suggest therefore that nit-2 and mea-1 loci play a role in ammonia/methylamine uptake.     

Molybdate repair of molybdopterin deficient mutants from Chlamydomonas reinhardtii

Summary The phenotypically wild strain I₃ of Chlamydomonas reinhardtii, carrying a cryptic mutation at the nit-6 locus, was distinguished from strains 21gr (cryptic mutant at nit-5) and 6145c (wild type) because of the ability of I₃ to grow on nitrate media containing 2mM tungstate.Molybdopterin-cofactor (MoCo) mutants 102 (double mutant at nit-5 and nit-6) and 104 (mutant at nit-4) grew on nitrate media supplemented with high concentrations of molybdate, although final cell densities were 40–60% lower and generation times 3.5 to six fold longer than for wild type. Under these conditions, nitrate reductase (NR) activity of the mutants, when measured either in situ or in vitro, was practically undetectable. The MoCo defective mutant 307 (nit-3) was not molybdate repairable. Although NR activity was not restored in vitro by molybdate in any of the MoCo^– mutant strains, their extracts had free NR-diaphorase subunits together with NR-subunits assembled into high molecular weight species.Our results indicate that: a) nit-4, nit-5 and nit-6 loci are responsible for molybdate processing in the cell; b) nit-3 may encode a component of the pterin moiety biosynthetic route; c) NR subunits can assemble in the presence of an inactive MoCo; d) high concentrations of molybdate can replace partially in vivo but not in vitro the function of nit-4 and the combined function(s) of the nit-5 and nit-6 gene products.     

Biochemical characterization of the molybdenum cofactor mutants of Neurospora crassa: in vivo and in vitro reconstitution of NADPH-nitrate reductase activity

Summary Molybdenum cofactor (MoCo) mutants of Neurospora crassa lack both NADPH-nitrate reductase and xanthine dehydrogenase activity. In vivo and in vitro studies to further characterize these mutants are now reported. The MoCo mutants nit-9A and nit-9B are capable of growing, albeit poorly, with nitrate as the sole nitrogen source, provided high levels of molybdate are present. The MoCo mutants nit-9A, nit-9B and nit-9C, but not nit-1, nit-7 or nit-8, have significant levels of NADPH-nitrate reductase when grown in nitrate medium containing 30 mM molybdate. In vitro reconstitution experiments using cell free extracts of the N. crassa MoCo mutants and E. coli HB101 as a source of wild-type MoCo were performed. MoCo from E. coli was capable of reconstituting NADPH-nitrate reductase activity to nit-1, nit-7 and nit-8. Molybdate is required for the in vitro reconstitution of NADPH-nitrate reductase activity. It was not possible to in vitro reconstitute NADPH-nitrate reductase activity in the MoCo mutants nit-9A, nit-9B or nit-9C.     

The regulatory protein NIT4 that mediates nitrate induction inNeurospora crassa contains a complex tripartite activation domain with a novel leucine-rich,acidic motif

Expression ofnit-3 andnit-6, the structural genes which encode nitrate reductase and nitrite reductase inNeurospora crassa, requires the global-acting NIT2 and the pathway specific NIT4 regulatory proteins. NIT4, which consists of 1090 amino-acid residues, possesses a Cys₆/Zn₂ zinc cluster DNA-binding-domain. NIT4 was dissected to localize transactivation domains by fusion of various segments of NIT4 to the DNA-binding domain of GAL4 for in vivo analysis in yeast. Three separate activation subdomains, and one negative-acting region, which function in yeast were located in the carboxyl-terminal region of NIT4. The C-terminal tail of 28 amino-acid residues was identified as a minimal activation domain and consists of a novel leucine-rich, acidic region. Most deletions which removed even small segments of the NIT4 protein were found to lead to the loss of NIT4 function in vivo inN. crassa, implying that the central region of the protein which lies between the DNA-binding and activation domains is essential for function. The yeast two-hybrid system was employed to identify regions of NIT4 responsible for dimer formation. A short isoleucine-rich segment downstream from the zinc cluster, predicted to form a coiled coil, allowed dimerization in vivo; this same isoleucine-rich region also showed dimerization in vitro when examined via chemical cross linking. The enzyme nitrate reductase has been postulated to exert autogenous regulation by directly interacting with the NIT4 protein. This possible nitrate reductase-NIT4 interaction was investigated with the yeast two-hybrid system and by direct in vitro binding assays; both assays failed to identify such a protein-protein interaction.     

Cloning and preliminary characterization of a molybdenum cofactor gene of Neurospora crassa

Summary A Neurospora crassa library, constructed in a derivative of the plasmid pBR322 (pRK9), was used to transform two E. coli ch1D molybdenum cofactor mutants (ch1D, ch1D::Mu). Subsequently, one transformant from each of three independent transformation experiments was restriction mapped. All three transformants had an identical N. crassa DNA insert (4.2 kb). Southern Blot analysis with one of the plasmids (pMoCo, 1:4) showed hybridization to a single band of N. crassa genomic DNA. When pMoCo plasmid (1:4) was used to transform various E. coli nitrate reductase mutants (ch1A, ch1B, ch1C, ch1D, ch1E, ch1G and ch1M), the pMoCo plasmid was capable of restoring E. coli nitrate reductase activity to only the ch1D mutant. In vitro reconstitution experiments using wild-type, ch1D and ch1D; pMoCo cell-free extracts as a source of molybdenum cofactor (MoCo) were performed with the N. crassa MoCo mutants nit-1, nit-7 and nit-8. MoCo from wild-type E. coli cell-free extracts was capable of reconstituting NADPH : nitrate reductase activity to all three N. crassa mutants. MoCo from ch1D; pMoCo cell-free extracts was capable of reconstituting more NADPH : nitrate reductase activity to the N. crassa mutants than cell-free extracts from the original ch1D mutant.     

Mutations to constitutivity and derepression are separate and separable in a regulatory gene of Aspergillus nidulans

Summary Previous work has shown that expression of the structural genes for the enzymes of nitrate and nitrite assimilation in Aspergillus nidulans requires the products of two positively acting regulatory genes — nirA, mediating induction, and areA, mediating nitrogen metabolite repression. Here we show that, in addition to previously described mutations in nirA leading to constitutivity, other mutations can be selected in nirA leading to nitrogen metabolite derepression. These constitutivity and depression mutations in nirA are additive and separable by intragenic recombination. This suggests that the nirA gene product contains two separate domains, a co-inducer binding region, defined by constitutivity mutations, and a region interacting with the areA gene product or with initiator sites adjacent to structural genes under areA and nirA control, defined by derepression mutations. These findings might indicate a striking similarity of action between the eukaryotic regulatory gene nirA and a comparable prokaryotic regulatory gene.     

A new selection method for isolating mutants defective in acetate utilisation inAspergillus nidulans

Propionate medium is normally toxic for the growth ofAspergillus nidulans. Spontaneous mutations relieving the toxicity to propionate, which arose on propionate medium, have been shown to be mutations in acetate metabolism. Oneacu ^– mutant is allelic withacuA (the structural gene for acetyl-CoA synthetase), another withacuB (the regulatory gene involved in the induction of enzymes concerned with acetate metabolism, including acetyl-CoA synthetase), and a third mutants,acuO, represents a newacu ^– locus that maps on likage group V.     

Biosynthetic and regulatory role of lys9 mutants of Saccharomyces cerevisiae

Summary Derepression of lysine biosynthetic enzymes of Saccharomyces cerevisiae was investigated in lys9 auxotrophs which lack saccharopine reductase activity. Five enzymes (homocitrate synthase, homoisocitrate dehydrogenase, -aminoadipate aminotransferase, -aminoadipate reductase and saccharopine dehydrogenase) were constitutively derepressed in all lys9 mutants with up to eight-fold higher enzyme levels than in isogenic wild-type cells. Levels of these enzymes in lys2, lys14, and lys15 S mutants were the same or lower than those in wild-type cells. The regulatory property of lys9 mutants exhibited recessiveness to the wild-type gene in heterozygous diploids. Unlike the mating type effect, homozygous diploids resulting from crosses between lys9 auxotrophs exhibited even higher levels of derepressed enzymes than the haploid mutants. Addition of a higher concentration of lysine to the growth medium resulted in reduction of enzyme levels although they were still derepressed. These results suggest that lys9 mutants represent a lesion for the saccharopine reductase and may represent a repressor mutation which in the wild-type cells simultaneously represses unlinked structural genes that encode for five of the lysine biosynthetic enzymes.     

Identification and cloning of a mobile transposon fromAspergillus niger var.awamori

Aspergillus niger var.awamori contains multiple copies of a transposable element, Vader. This element was detected as a 437-bp insertion in four independently isolated spontaneous mutants of theniaD (nitrate reductase) gene. The Vader element is present in approximately 15 copies in bothA. niger var.awamori andA. niger. A single copy of Vader was detected from only one of the two laboratory strains ofA. nidulans which were also examined. Insertion of the Vader element into theniaD gene ofA. niger var.awamori caused a 2-bp duplication (TA) of the target sequence. The Vader element is flanked by a 44-bp inverted repeat. The genetic stabilities of the inserted Vader elements atniaD were examined by studying reversion frequencies resulting in colonies able to grow on nitrate as a sole nitrogen source. MutantsniaD392 andniaD436 reverted at a frequency of 9x10^-3 and 4x10^-2, respectively. Two of the mutants,niaD587 andniaD410, reverted at a lower frequency of 6x10^-4.     

Cloning of the nitrate reductase gene of Stagonospora (Septoria) nodorum and its use as a selectable marker for targeted transformation

The nitrate reductase gene (NIA1) of the phytopathogenic fungus Stagonospora (Septoria) nodorum has been cloned from a cosmid library by homologous hybridisation with a PCR-generated probe. A 6.7-kb fragment carrying the NIA1 gene was subcloned and partially characterised by restriction mapping. Sequencing of the gene indicated a high degree of homology, both at the nucleotide and amino-acid levels, with nitrate reductase genes of other filamentous fungi. Furthermore, consensus regulatory signals thought to be involved in the control of nitrogen metabolism are present in the 5′ flanking region. The cloned NIA1 gene has been used to develop a gene-transfer system based on nitrate assimilation. Stable nia1 mutants of S. nodorum defective in nitrate reductase were isolated by virtue of their resistance to chlorate. These were transformed back to nitrate utilisation with the wild-type S. nodorum NIA1 gene. Southern analyses revealed that transformation occurred as a result of the integration of transforming DNA into the fungal genome; in all cases examined, integration was targeted to the homologous sequence. Received: 30 March / 9 June 1998     

Novel mutations of <Emphasis Type="Italic">EVER1/TMC6</Emphasis> gene in a Japanese patient with epidermodysplasia verruciformis

Germline mutations of the EVER1/TMC6 gene are associated with epidermodysplasia verruciformis (EV), which is characterized by an abnormal susceptibility to human papillomaviruses that were considered to be innocuous for the general population. In this study, we have employed polymerase chain reaction and DNA sequencing analysis to characterize the EVER1 gene in a 65-year-old Japanese EV patient. Direct sequence analyses resulted in the identification of two novel mutations. One nonsense mutation consisting of a (C>A) transversion at nucleotide 744 in exon 8 in one EVER1 allele resulted in the introduction of a premature termination codon (Y248X). Another mutation was identified in the splice acceptor site of intron 8 (892-2, IVS8-2, A>T) in another allele. This is the second report of EVER1/TMC6 mutations in EV.     

NRE,the major nitrogen regulatory protein of Penicillium chrysogenum,binds specifically to elements in the intergenic promoter regions of nitrate assimilation and penicillin biosynthetic gene clusters

NRE, the nitrogen regulatory protein of Penicillium chrysogenum, contains a single Cys2/Cys2-type zinc-finger motif followed immediately by a highly basic region. The zinc-finger domain was expressed to Escherichia coli as a fusion protein with -galactosidase. In order to test the putative DNA-binding ability of NRE, the intergenic promoter region of the nitrate reductase/nitrite reductase gene cluster (niiA-niaD) of Penicillium was sequenced. Our results show that NRE is a DNA-binding protein and binds to the intergenic promoter regions of the P. chrysogenum niiA-niaD and acvA-pcbC gene cluster, encoding the first two enzymes in penicillin biosynthesis. Three of the four high-affinity NRE-binding sites contained two GATA core elements. In one of the recognition sites for NRE, one GATA motif was replaced by GATT. The two GATA elements showed all possible orientations, head-to-head, head-to-tail and tail-to-tail, and were separated by between 4 and 27 bp. Missing-contact analysis showed that all three purines in both of the GATA core sequences and the single adenine residue in each of the complementary TATC sequences were involved in the binding of NRE. Moreover, loss of purines in the flanking regions of the GATA elements also affect binding of NRE, as their loss causes reduced affinity.     

Generation of new mutants of nmr,the negative-acting nitrogen regulatory gene of Neurospora crassa,by repeat induced mutation

Summary The repeat induced point mutation (RIP) phenomenon has been used to generate new mutants of nmr, the negative nitrogen regulatory gene in Neurospora crassa. The wild-type nmr gene was cotransformed along with the hygromycin B resistance gene into wild-type cells by selecting for hygromycin B resistance. Following purification of primary transformants using microconidia, crosses to wild-type. Detailed analyses of some of the progeny revealed that we had generated authentic nmr mutants at high frequency. The polymerase chain reaction was used to amplify and clone a fragment of a mutagenized nmr copy from one of the mutants. The nucleotide sequence analysis showed that 14% of the guanine residues have been converted into adenines, resulting in numerous missense and nonsense mutations. The newly created nmr mutants were found suitable for use as host strains in transformation experiments.