Mutants of Aspergillus nidulans altered in the transport of methylammonium and ammonium

Summary Mutations to methylammonium resistance occur in at least two loci in Aspergillus nidulans, meaA in linkage group IV and meaB in linkage group III. Transport studies using methylammonium-¹⁴C, at a concentration which inhibits protein synthesis in the wild type but not in resistant mutants, show that meaA mutants are defective in methylammonium (and hence ammonium) transport. The ability of meaA mutations to be expressed in the absence of a substrate of the ammonium-methylammonium transport system suggests that ammonium efflux may be involved, although it has not been established whether ammonium influx is also affected.     

Methylammonium-resistant mutants ofNicotiana plumbaginifolia are affected in nitrate transport

This work reports the isolation and preliminary characterization ofNicotiana plumbaginifolia mutants resistant to methylammonium.Nicotiana plumbaginifolia plants cannot grow on low levels of nitrate in the presence of methylammonium. Methylammonium is not used as a nitrogen source, although it can be efficiently taken up byNicotiana plumbaginifolia cells and converted into methylglutamine, an analog of glutamine. Glutamine is known to repress the expression of the enzymes that mediate the first two steps in the nitrate assimilatory pathway, nitrate reductase (NR) and nitrite reductase (NiR). Methylammonium has therefore been used, in combination with low concentrations of nitrate, as a selective agent in order to screen for mutants in which the nitrate pathway is de-repressed. Eleven semi-dominant mutants, all belonging to the same complementation group, were identified. The mutant showing the highest resistance to methylammonium was not affected either in the utilization of ammonium, accumulation of methylammonium or in glutamine synthase activity. A series of experiments showed that utilization of nitrite by the wild-type and the mutant was comparable, in the presence or the absence of methylammonium, thus suggesting that the mutation specifically affected nitrate transport or reduction. Although NR mRNA levels were less repressed by methylammonium treatment of the wild-type than the mutant, NR activities of the mutant remained comparable with or without methylammonium, leading to the hypothesis that modified expression of NR is probably not responsible for resistance to methylammonium. Methylammonium inhibited nitrate uptake in the wild-type but had only a limited effect in the mutant. The implications of these results are discussed.     

NUT1, a major nitrogen regulatory gene inMagnaporthe grisea, is dispensable for pathogenicity

NUT1, a gene homologous to the major nitrogen regulatory genesnit-2 ofNeurospora crassa andareA ofAspergillus nidulans, was isolated from the rice blast fungus,Magnaporthe grisea. NUT1 encodes a protein of 956 amino acid residues and, likenit-2 andareA, has a single putative zinc finger DNA-binding domain. Functional equivalence ofNUT1 toareA was demonstrated by introducing theNUT1 gene by DNA-mediated transformation into anareA loss-of-function mutant ofA. nidulans. The introducedNUT1 gene fully complemented theareA null mutation, restoring to the mutant the ability to utilize a variety of nitrogen sources. In addition, the sensitivity ofAspergillus NUT1 transformants to ammonium repression of extracellular protease activity was comparable to that of wild-typeA. nidulans. Thus,NUT1 andareA encode functionally equivalent gene products that activate expression of nitrogen-regulated genes. A one-step gene disruption strategy was used to generatenutl ^– mutants ofM. grisea by transforming a rice-infecting strain with a disruption vector in which a gene for hygromycin B phosphotransferase (Hyg) replaced the zinc-finger DNA-binding motif ofNUT1. Of 31 hygromycin B (hyg B)-resistant transformants shown by Southern hybridization to contain a disruptedNUT1 gene (nut1::Hyg), 26 resulted from single-copy replacement events at theNUT1 locus. Althoughnut1 ^– transformants ofM. grisea failed to grown on a variety of nitrogen sources, glutamate, proline and alanine could still be utilized. This contrasts withA. nidulans where disruption of the zinc-finger region ofareA prevents utilization of nitrogen sources other than ammonium and glutamine. The role ofNUT1 and regulation of nitrogen metabolism in the disease process was evaluated by pathogenicity assays. The infection efficiency ofnut1 ^– transformants on susceptible rice plants was similar to that of the parental strain, although lesions were reduced in size. These studies demonstrate that theM. grisea NUT1 gene activates expression of nitrogen-regulated genes but is dispensable for pathogenicity.     

Regulation of nitrogen-metabolizing enzymes in the commercial Mushroom Agaricus bisporus

Mycelium of Agaricus bisporus strain Horst U1 was grown in batch cultures on different concentrations of ammonium, glutamate, and glucose to test the effect of these substrates on the activities of NADP-dependent glutamate dehydrogenase (NADP-GDH, EC 1.4.1.4), NAD-dependent glutamate dehydrogenase (NAD-GDH, EC 1.4.1.2.), and glutamine synthetase (GS, EC 6.3.1.2.). When grown on ammonium, the activities of NADP-GDH and GS were repressed. NAD-GDH activity was about 10 times higher than the activities of NADP-GDH and GS. At concentrations below 8 mM ammonium, NADP-GDH and GS were slightly derepressed. When glutamate was used as the nitrogen source, activities of NADP-GDH and GS were derepressed; compared with growth on ammonium, the activities of these two enzymes were about 10 times higher. Activities of GDHs showed no variation at different glutamate concentrations. Activity of GS was slightly derepressed at low glutamate concentrations. Growth of A. bisporus on both ammonium and glutamate as nitrogen sources resulted in enzyme activities comparable to growth on ammonium alone. Activities of NADP-GDH, NAD-GDH, and GS were not influenced by the concentration of glucose in the medium. In mycelium starved for nitrogen, the activities of NADP-GDH, NAD-GDH, and GS were derepressed, while in carbon-starved mycelium the activity of GS and both GDHs was repressed.     

Methylammonium Resistance in Aspergillus nidulans

Mutants of Aspergillus nidulans resistant to methylammonium toxicity are simultaneously derepressed in the presence of ammonium for apparently all ammonium-repressible activities. Enzyme assays directly demonstrate derepression of nitrate, nitrite, and hydroxylamine reductases, xanthine dehydrogenase, urate oxidase, and allantoinase, whereas in vivo tests show that ammonium and methylammonium repression or inhibition (or both) is relieved in these mutants in pathways of nitrate assimilation, purine transport and degradation, and amino acid, amine, and amide catabolism. Ammonium and methylammonium uptake is apparently not defective in these mutants, for they grow normally on limiting levels of these ions as sole nitrogen source. There is no evidence that more than one gene can mutate to produce the methylammonium resistance (mea^R) phenotype. Such mutations are semidominant in both heterocaryons and diploids. The ability of mea^R mutations to effect derepression of activities specified by genes within another nucleus in a heterocaryon shows that the action of the mea product is not restricted to the nucleus. Three types of hypotheses might explain this generalized derepression. First, ammonium and methylammonium might not themselves be co-repressors but might require a metabolic conversion, blocked in these mutants, to become co-repressors. Secondly, the mea locus might specify an activity expressed in mea^R but not wild-type (mea^S) strains, which diminishes the concentration of ammonium and methylammonium participating in co-repression. Finally, ammonium repression might involve a macromolecular control element specified by the mea^R locus and common to many or all ammonium-repressible systems. The existence of “regulation reversal mutations” at the mea^R locus and the lack of uniformity and coordination with which different enzymatic activities respond to mutational derepression is most compatible with the last type of hypothesis.     

Glutamine synthetase/glutamate synthase ammonium-assimilating pathway in Schizosaccharomyces pombe

Kinetic parameters of glutamine synthetase (GS) and glutamate synthase (glutamineoxoglutarate aminotransferase) (GOGAT) activities, including initial velocity, pH, and temperature optima, as well as K _m values, were estimated in Schizosaccharomyces pombe crude cell-free extracts. Five glutamine auxotrophic mutants of S. pombe were isolated following MNNG treatment. These were designated gln1-1,2,3,4,5, and their growth could be repaired only by glutamine. Mutants gln1-1,2,3,4,5 were found to lack GS activity, but retained wild-type levels of NADP-glutamate dehydrogenase (GDH), NAD-GDH, and GOGAT. One further glutamine auxotrophic mutant, gln1-6, was isolated and found to lack both GS and GOGAT but retained wild-type levels of NADP-GDH and NAD-GDH activities. Fortuitously, this isolate was found to harbor an unlinked second mutation (designated gog1-1), which resulted in complete loss of GOGAT activity but retained wild-type GS activity. The growth phenotype of mutant gog1-1 (in the absence of the gln1-6 mutation) was found to be indistinguishable from the wild type on various nitrogen sources, including ammonium as a sole nitrogen source. Double-mutant strains containing gog1-1 and gdh1-1 or gdh2-1 (mutations that result specifically in the abolition of NADP-GDH activity) result in a complete lack of growth on ammonium as sole nitrogen source in contrast to gdh or gog mutants alone.     

Ammonium regulation in Aspergillus nidulans

l-Glutamate uptake, thiourea uptake, and methylammonium uptake and the intracellular ammonium concentration were measured in wild-type and mutant cells of Aspergillus nidulans held in various concentrations of ammonium and urea. The levels of l-glutamate uptake, thiourea uptake, nitrate reductase, and hypoxanthine dehydrogenase activity are determined by the extracellular ammonium concentration. The level of methylammonium uptake is determined by the intracellular ammonium concentration. The uptake and enzyme characteristics of the ammonium-derepressed mutants, meaA8, meaB6, DER3, amrA1, xprD1, and gdhA1, are described. The gdhA mutants lack normal nicotinamide adenine dinucleotide phosphate-glutamate dehydrogenase (NADP-GDH) activity and are derepressed with respect to both external and internal ammonium. The other mutant classes are derepressed only with respect to external ammonium. The mutants meaA8, DER3, amrA1, and xprD1 have low levels of one or more of the l-glutamate, thiourea, and methylammonium uptake systems. A model for ammonium regulation in A. nidulans is put forward which suggests: (i) NADP-GDH located in the cell membrane complexes with extracellular ammonium. This first regulatory complex determines the level of l-glutamate uptake, thiourea uptake, nitrate reductase, and xanthine dehydrogenase by repression or inhibition, or both. (ii) NADP-GDH also complexes with intracellular ammonium. This second and different form of regulatory complex determines the level of methylammonium uptake by repression or inhibition, or both.     

Functional substitution of the recE gene of Bacillus subtilis by the recA gene of Proteus mirabilis

Summary Rec mutants of Bacillus subtilis have been tested for complementation by the recA gene of Proteus mirabilis (recApm) which was introduced into B. subtilis via the plasmid pHP334. In the recE4 mutant of B. subtilis the plasmid pHP334 restored significantly the defects in RecE functions tested: UV-sensitivity, homologous recombination (transduction and transformation) and prophage induction.Although serological methods to detect the presence of RecApm protein in B. subtilis have been unsuccessful, our results strongly indicate that the recE function of B. subtilis is analogous to the recA function of P. mirabilis.Abbreviations Cm^r resistance to chloramphenicol - Em^r resistance to erythromycin - Tc^r resistance to tetracycline - SDS sodium dodecyl sulfate - UV ultraviolet - AS ammonium sulfate     

The Presence of Glutamate Dehydrogenase Is a Selective Advantage for the Cyanobacterium Synechocystis sp. Strain PCC 6803 under Nonexponential Growth Conditions

The unicellular cyanobacterium Synechocystis sp. strain PCC 6803 has two putative pathways for ammonium assimilation: the glutamine synthetase-glutamate synthase cycle, which is the main one and is finely regulated by the nitrogen source; and a high NADP-dependent glutamate dehydrogenase activity (NADP-GDH) whose contribution to glutamate synthesis is uncertain. To investigate the role of the latter, we used two engineered mutants, one lacking and another overproducing NADP-GDH. No major disturbances in the regulation of nitrogen-assimilating enzymes or in amino acids pools were detected in the null mutant, but phycobiline content, a sensitive indicator of the nutritional state of cyanobacterial cells, was significantly reduced, indicating that NADP-GDH plays an auxiliary role in ammonium assimilation. This effect was already prominent in the initial phase of growth, although differences in growth rate between the wild type and the mutants were observed at this stage only at low light intensities. However, the null mutant was unable to sustain growth at the late stage of the culture at the point when the wild type showed the maximum NADP-GDH activity, and died faster in ammonium-containing medium. Overexpression of NADP-GDH improved culture proliferation under moderate ammonium concentrations. Competition experiments between the wild type and the null mutant confirmed that the presence of NADP-GDH confers a selective advantage to Synechocystis sp. strain PCC 6803 in late stages of growth.     

Toxicity of and mutagenesis by chlorate are independent of nitrate reductase activity in Chlamydomonas reinhardtii

Summary Spontaneous chlorate-resistant (CR) mutants have been isolated from Chlamydomonas reinhardtii wildtype strains. Most of them, 244, were able to grow on nitrate minimal medium, but 23 were not. Genetic and in vivo complementation analyses of this latter group of mutants indicated that they were defective either at the regulatory locus nit-2, or at the nitrate reductase (NR) locus nit-1, or at very closely linked loci. Some of these nit-1 or nit-2 mutants were also defective in pathways not directly related to nitrate assimilation, such as those of amino acids and purines. Chlorate treatment of wild-type cells resulted in both a decrease in cell survival and an increase in mutant cells resistant to a number of different chemicals (chlorate, methylammonium, sulphanilamide, arsenate, and streptomycin). The toxic and mutagenic effects of chlorate in minimal medium were not found when cells were grown either in darkness or in the presence of ammonium, conditions under which nitrate uptake is drastically inhibited. Chlorate was also able to induce reversion of nit ^– mutants of C. reinhardtii, but failed to produce His ⁺ revertants or Ara^r mutants in the BA-13 strain of Salmonella typhimurium. In contrast, chlorate treatment induced mutagenesis in strain E1F1 of the phototrophic bacterium Rhodobacter capsulatus. Genetic analyses of nitrate reductase-deficient CR mutants of C. reinhardtii revealed two types of CR, to low (1.5 mM) and high (15 mM) chlorate concentrations. These two traits were recessive in heterozygous diploids and segregated in genetic crosses independently of each other and of the nit-1 and nit-2 loci. Three her loci and four lcr loci mediating resistance to high (HC) and low (LC) concentrations of chlorate were identified. Mutations at the nit-2 locus, and deletions of a putative locus for nitrate transport were always epistatic to mutations responsible for resistance to either LC or HC. In both nit ⁺ and nit ^– chlorate-sensitive (CS) strains, nitrate and nitrite gave protection from the toxic effect of chlorate. Our data indicate that in C. reinhardtii chlorate toxicity is primarily dependent on the nitrate transport system and independent of the existence of an active NR enzyme. At least seven loci unrelated to the nitrate assimilation pathway and mediating CR are thought to control indirectly the efficiency of the nitrate transporter for chlorate transport. In addition, chlorate appears to be a mutagen capable of inducing a wide range of mutations unrelated to the nitrate assimilation pathway.     

Mutants of Azospirillum brasilense resistant to methylammonium

One hundred and twenty-nine mutants of Azospirillum brasilense strain Sp6, resistant to methylammonium, were isolated. Three of the mutants were found to be able to reduce acetylene in the presence of 4 mM ammonium or 120mM methylammonium, concentrations which strongly reduced the nitrogenase activity of the parental strain. Under N₂-fixing conditions, two mutants failed to switch off nitrogenase when NH₄Cl was added. Moreover, the three mutants showed a reduced capacity to incorporate [¹⁴C]methylammonium. The level of glutamine synthetase activity found in the mutants was not reduced as compared to that of the parental strain. All of the data indicate an impairement in the mechanism of ammonium uptake by the bacterial cell.Abbreviations MEA Methylammonium - MSP minimal medium (ammonium free) - PY complete medium - GS glutamine synthetase     

Nitrogen metabolite repression in Aspergillus nidulans

Summary In Aspergillus nidulans, mutations, designated areA^r, can result in the inability to utilise a wide variety of nitrogen sources including amino acids, purines, amides, nitrate, and nitrite, whilst not affecting growth on ammonium. Other allelic areA mutations, designated areA^d, lead to derepression of one or more activities which are ammonium repressible in wild type (areA⁺) strains, whilst not affecting their inducibility. Various areA mutations exhibit a wide variety of phenotypes: areA^r alleles can be temperature sensitive on some nitrogen sources while not on others, and different alleles can be temperature sensitive for utilisation of different nitrogen sources. areA^d alleles can be derepressed for one ammonium-repressible activity, be normally repressible for another, and lead to abnormally low levels for a third. Once again each areA^d allele has its own highly specific phenotype. The inability of areA^r strains to utilise most nitrogen sources is paralleled by low activities of certain ammonium-repressible enzymes. areA^r mutations appear to be epistatic to some but not all regulatory mutations leading to constitutive synthesis of inducible enzymes and also epistatic to gdhA mutations which lead both to loss of NADP-linked glutamate dehydrogenase and to derepression of ammonium-repressible activities. areA^r mutations do not interfere with repair of a large number of auxotrophies in double mutants. Furthermore, although areA^r mutations prevent utilisation of L-arginine, L-ornithine, and L--amino-n-butyrate as nitrogen sources, they do not prevent the metabolism of these compounds necessary for repairing auxotrophies for proline and isoleucine in the appropriate double mutants. Utilisation of acetamide and most amino acids as carbon or carbon and nitrogen sources is unaffected by areA^r mutations, and areA^r strains are able to utilise acetamide and L-proline (but not other amino acids) as nitrogen sources in the presence of non-catabolite-repressing carbon sources such as L-arabinose, glycerol, melibiose, and lactose. Suppressor mutations, designated creA^d, probably leading to loss of carbon catabolite repression, allow utilisation of acetamide and proline as nitrogen sources in areA^r double mutants in the presence of carbon catabolite-repressing carbon sources. creA^d mutations allow ethanol to serve as a source of acetate for pyruvate dehydrogenaseless (pdhA) strains in the presence of carbon catabolite-repressing carbon sources, whereas pdhA single mutants respond to ethanol as sole carbon source only in the presence of non-carbon catabolite-repressing carbon sources. Specific suppressor mutations, designated amd ^d and prn ^d, allow utilisation of acetamide or proline, respectively, in areA^r double mutants.The areA locus can be interpreted as specifying a protein which is capable of (and in most cases essential for) allowing the synthesis of a number of enzymes of nitrogen metabolism but which cannot function in the presence of ammonium (i.e., as specifying a positive regulatory element which mediates ammonium repression) although the possibility that the areA product also plays a negative regulatory role cannot at present be ruled out.     

Methylammonium-resistant mutants ofNicotiana plumbaginifolia are affected in nitrate transport

This work reports the isolation and preliminary characterization ofNicotiana plumbaginifolia mutants resistant to methylammonium.Nicotiana plumbaginifolia plants cannot grow on low levels of nitrate in the presence of methylammonium. Methylammonium is not used as a nitrogen source, although it can be efficiently taken up byNicotiana plumbaginifolia cells and converted into methylglutamine, an analog of glutamine. Glutamine is known to repress the expression of the enzymes that mediate the first two steps in the nitrate assimilatory pathway, nitrate reductase (NR) and nitrite reductase (NiR). Methylammonium has therefore been used, in combination with low concentrations of nitrate, as a selective agent in order to screen for mutants in which the nitrate pathway is de-repressed. Eleven semi-dominant mutants, all belonging to the same complementation group, were identified. The mutant showing the highest resistance to methylammonium was not affected either in the utilization of ammonium, accumulation of methylammonium or in glutamine synthase activity. A series of experiments showed that utilization of nitrite by the wild-type and the mutant was comparable, in the presence or the absence of methylammonium, thus suggesting that the mutation specifically affected nitrate transport or reduction. Although NR mRNA levels were less repressed by methylammonium treatment of the wild-type than the mutant, NR activities of the mutant remained comparable with or without methylammonium, leading to the hypothesis that modified expression of NR is probably not responsible for resistance to methylammonium. Methylammonium inhibited nitrate uptake in the wild-type but had only a limited effect in the mutant. The implications of these results are discussed.     

Impaired nitrogen fixation and glutamine synthesis in methionine sulfoximine sensitive (MSs) mutants of Rhizobium phaseoli

Summary Random Tn5 mutagenesis of antibiotic-resistant derivatives of Rhizobium phaseoli CFN42 yielded several independent mutants that were sensitive to methionine sulfoximine (MS^s), a specific inhibitor of glutamine synthetase (GS). These MS^s mutants were analyzed for GSI and GSII activities and for their symbiotic properties. Four classes of MS^s mutants have been distinguished. Class I strains are impaired in their synthesis of glutamine and in their symbiotic properties. Class II strains have wild type levels of GSI and GSII activities but have a reduced capacity to fix nitrogen. Class III strains have lost GSII activity, but their symbiotic properties are wild type. In class IV mutants neither glutamine synthesis nor symbiotic properties are affected. Mutants of classes I, III, and IV all have the Tn5 inserted into the chromosome, whereas in class II mutants the Tn5 is located in plasmid p42e, a plasmid different from the previously identified symbiotic plasmid p42d.     

Altered S5 and S20 ribosomal proteins in revertants of an alanyl-tRNA synthetase mutant of Escherichia coli

Summary An active transport system specific for ammonium and methylammonium is decribed in wild type cells of Aspergillus nidulans. This system has a Km of less than 5x10^-5 M for ammonium as measured by the uptake of ¹⁵NH⁺ ₄ and a Km of 2x10^-5 M and apparent Vmax of 11 nanomoles/min/mg dry weight for methylammonium, by the uptake of ¹⁴C methylammonium. The system concentrates methylammonium at least 120-fold and is probably regulated by the concentration of internal ammonium.Cells of the mutant strain DER-3 possess a reduced rate of ammonium and methylammonium transport under all conditions tested. DER-3 is a double mutant, one mutation being allelic with meaA8 and designated meaA21, the other is unlinked to meaA and designated mod meaA. The heterozygous diploid DER3/+ has wild type transport, indicating that the mutations are recessive. Cells of the mutant strain amrA1 have impaired transport of ammonium and methylammonium, but only under some conditions. amrA1 is recessive. The possible defects of these mutants are discussed.     

Mutational analysis of the C-terminal region of AREA,the transcription factor mediating nitrogen metabolite repression inAspergillus nidulans

InAspergillus nidulans the positive-acting, wide domain regulatory geneareA mediates nitrogen metabolite repression. Previous analysis demonstrated that the C-terminal 153 residues of theareA product (AREA) are inessential for at least partial expression of most genes subject to regulation byareA. Paradoxically,areA ^r 2, a ?1 frameshift replacing the wild-type 122 C-terminal residues with a mutant peptide of 117 amino acids, leads to general loss of function. To determine the basis for theareA ^r 2 mutant phenotype, and as a means of delineating functional domains within the C-terminal region of AREA, we have selected and characterisedareA ^r 2 revertants. Deletion analysis, utilising direct gene replacement, extended this analysis. A mutantareA product truncated immediately after the last residue of the highly conserved GATA (DNA-binding) domain retains partial function. TheareA ^r 2 product retains some function with respect to the expression ofuaZ (encoding urate oxidase) and the mutant allele is partially dominant with respect to nitrate reductase levels. Consistent with theareA ^r 2 product having a debilitating biological activity, we have demonstrated that a polypeptide containing both the wild-type DNA-binding domain and the mutant C-terminus of AREA2 is able to bind DNA in vitro but no longer shows specificity for GATA sequences.     

Regulation of nitrogen fixation in Rhizobium spp. Isolation of mutants of Rhizobium trifulii which induce nitrogenase activity

This communication describes the isolation and characterization of mutants of Rhizobium trifolii which can induce nitrogenase activity in defined liquid medium. Two procedures were used for the isolation of these mutants from R. trifolii strain DT-6: (1) following chemical mutagenesis, slow growin mutants were selected which were unable to utilize NH₄⁺ as sole source of nitrogen; (2) as spontaneous mutants resistant to the glutamate analogue L-methionine-DL-sulfoximine.Mutants (DT-71, DT-125) isolated by these procedures induced nitrogenase activity in the free-living state, whereas the parent strain lacked this property. Induction of nitrogenase activity in these mutants occurred during the late exponential phase of growth when the rate of protein synthesis was decreasing. The addition of NH₄⁺ to a medium containing glutamate as the nitrogen-source resulted in a 50–70% reduction (repression?) of nitrogenase activity; in contrast, the rate of protein synthesis or the rate of respiration was not influenced by exogenous NH₄⁺.Biochemistry analysis showed that these mutants (strains DT-71 and DT-125) have defects in both nitrogen and carbon metabolism. The levels of glutamate synthase (both NADP⁺-and NAD⁺-dependent activities) and glutamate dehydrogenase (NAD⁺-dependent activity) were markedly lower. In addition, the mutants were found to have no detectable ribitol dehydrogenase or β-galactosidase activity. These findings are discussed in relation to a mechanism of regulation of symbiotic nitrogen fixation.     

cysB and cysE mutants of Escherichia coli K12 show increased resistance to novobiocin

Summary Mutations in the cysB and cysE genes of Escherichia coli K12 cause an increase in resistance to the gyrase inhibitor novobiocin but not to coumermycin, acriflavine and rifampicin. This unusual relationship was also observed among spontaneous novobiocin resistant (Nov^r) mutants: 10% of Nov^r mutants isolated on rich (LA) plates with novobiocin could not grow on minimal plates, and among those approximately half were cysB or cysE mutants. Further analyses demonstrated that cysB and cysE negative alleles neither interfere with transport of novobiocin nor affect DNA supercoiling.     

Ammonium and methylammonium uptake in a fertilizer-degrading strain of Ochrobactrum anthropi

The transport of ammonium and methylammonium was studied in a strain of Ochrobactrum anthropi, a microorganism isolated from garden soil and able to degrade methyleneureas which are used as slow-release nitrogen fertilizer. The activity of both transport systems was determined using [¹⁴C]methylammonium. Differences between the two transport systems were observed with regard to their pH- and temperature dependence as well as their kinetic parameters and regulation during growth with various nitrogen sources. Ammonium transport was subject to repression by ammonium and to derepression in its absence, while the methylammonium carrier was induced in the presence of methylamine. The ammonium but not the methylammonium transport system was severely inhibited by ammonium, and metabolic poisons inhibited both uptake systems. The analysis of intracellular metabolites using thin-layer chromatography and matrix-assisted laser desorption/ionisation time-of-flight mass spectrometry indicated that methylammonium was rapidly metabolized to N-methylglutamate via -N-methylglutamine.