D. J. Cove

Nitrogen metabolite repression in Aspergillus nidulans

SummaryIn Aspergillus nidulans, mutations, designated areAr, 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 areAd, 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: areAr 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. areAd 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 areAd allele has its own highly specific phenotype. The inability of areAr strains to utilise most nitrogen sources is paralleled by low activities of certain ammonium-repressible enzymes. areAr 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. areAr mutations do not interfere with repair of a large number of auxotrophies in double mutants. Furthermore, although areAr mutations prevent utilisation of L-arginine, L-ornithine, and L-α-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 areAr mutations, and areAr 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 creAd, probably leading to loss of carbon catabolite repression, allow utilisation of acetamide and proline as nitrogen sources in areAr double mutants in the presence of carbon catabolite-repressing carbon sources. creAd 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 amdd and prnd, allow utilisation of acetamide or proline, respectively, in areAr 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.

The isolation and preliminary characterisation of auxotrophic and analogue resistant mutants of the moss, Physcomitrella patens

SummaryEighteen nutritional mutants have been isolated in the haploid, monoecious moss, Physcomitrella patens: five nicotinic acid auxotrophs, four p-aminobenzoic acid auxotrophs, four adenine auxotrophs, two amino acid requiring mutants and three nitrate non-utilising mutants. Seventeen of them were obtained using total isolation; one was isolated selectively. Strains resistant to the amino acid analogues, D-serine and p-fluorophenyl-alanine, and the purine analogue, 8-azaguanine, have been selected. Many of the auxotrophs are self-sterile. Crosses between auxotrophic strains have been effected and the progeny analysed. No linkage has been detected. Nicotinic acid auxotrophy has resulted from mutation in at least two genes. Self-sterility segregates as a pleiotropic effect of four mutations which produce nutritional dependence. A diploid strain has been obtained by aposporus regeneration from a hybrid sporophyte and the phenotypes of progeny resulting from the self-fertilisation of this strain have been analysed.

Analysis of gametophytic development in the moss, Physcomitrella patens, using auxin and cytokinin resistant mutants

Mutants altered in their response to auxins and cytokinins have been isolated in the moss Physcomitrella patens either by screening clones from mutagenized spores for growth on high concentrations of cytokinin or auxin, in which case mutants showing altered sensitivities can be recognized 3–4 weeks later, or by non-selective isolation of morphologically abnormal mutants, some of which are found to have altered sensitivities. Most of the mutants obtained selectively are also morphologically abnormal. The mutants are heterogeneous in their responses to auxin and cytokinin, and the behaviour of some is consistent with their being unable to make auxin, while that of others may be due to their being unable to synthesize cytokinin. Physiological analysis of the mutants has shown that both endogenous auxin and cytokinin are likely to play important and interdependent roles in several steps of gametophytic development. Although their morphological abnormalities lead to sterility, genetic analysis of some of the mutants has been possible by polyethyleneglycol induced protoplast fusion.

Chlorate toxicity in Aspergillus nidulans

SummaryIt had previously been held that chlorate is not itself toxic, but is rendered toxic as a result of nitrate reductase-catalysed conversion to chlorite. This however cannot be the explanation of chlorate toxicity in Aspergillus nidulans, even though nitrate reductase is known to have chlorate reductase activity. Among other evidence against the classical theory for the mechanism of chlorate toxicity, is the finding that not all mutants lacking nitrate reductase are clorate resistant. Both chlorate-sensitive and resistant mutants lacking nitrate reductase, also lack chlorate reductase. Data is presented which implicates not only nitrate reductase but also the product of the nirA gene, a positive regulator gene for nitrate assimilation, in the mediation of chlorate toxicity. Alternative mechanisms for chlorate toxicity are considered. It is unlikely that chlorate toxicity results from the involvement of nitrate reductase and the nirA gene product in the regulation either of nitrite reductase, or of the pentose phosphate pathway. Although low pH has an effect similar to chlorate, chlorate is not likely to be toxic because it lowers the pH; low pH and chlorate may instead have similar effects. A possible explanation for chlorate toxicity is that it mimics nitrate in mediating, via nitrate reductase and the nirA gene product, a shut-down of nitrogen catabolism. As chlorate cannot act as a nitrogen source, nitrogen starvation ensures.

The production of somatic hybrids by protoplast fusion in the moss, Physcomitrella patens

SummaryA technique has been developed for the isolation of large numbers of protoplasts from protonemal tissue of Physcomitrella patens, and for their regeneration to give whole plants. Somatic hybrids have been selected following treatment of mixtures of protoplasts from complementary auxotrophic strains with 50 mM CaCl2 at high pH. The hybrids have a morphology different from that of normal haploid strains, but similar to that of aposporously produced diploids. The progeny resulting from selffertilisation of the hybrids show a segregation which is consistent with their being the products of meioses in an autotetraploid.

The isolation and physiological analysis of mutants of the moss, Physcomitrella patens, which over-produce gametophores

Several phenotypically distinct classes of gametophore overproducing mutants have been isolated in P. patens. Mutants belonging to one class resemble the wild-type strain grown on medium containing a high concentration (5–50μM) of exogenously supplied cytokinin. Mutants of this type can increase the production of gametophores in the wildtype strain by cross-feeding it through the culture medium. Mutants belonging to another class resemble the wild-type strain cultured on medium containing a lower concentration (50–500 nM) of exogenous cytokinin. Mutants of this kind cannot cross-feed the wild-type strain through the culture medium. A component, required by the wild-type strain for the initiation of gametophores in response to cytokinin, either is not formed or is not activated in the dark. Gametophore over-producing mutants may also be unable to synthesize/activate this component in the dark and thus, like the wild-type strain, they produce no gametophores in the dark.

Molybdate metabolism inAspergillus nidulans

SummaryFurther evidence supports the hypothesis that nitrate reductase and xanthine dehydrogenase are molybdo-enzymes inAspergillus nidulans, probably sharing a molybdenum-containing cofactor. This evidence includes (1) five-fold greater toxicity of tungstate on nitrate and hypoxanthine than on other nitrogen sources, (2) locus-specific molybdate reparability of both nitrate reductase and xanthine dehydrogenase at one (cnxE) of five (cnx) loci where mutation can result in pleiotropic loss of both enzyme activities, and (3) an additional class of mutants (molB) which are both molybdate resistant and partially defective in utilization of nitrate and hypoxanthine as nitrogen sources. Moreover, the phenotypes on molybdate-containing media of various mutants altered in the regulation of nitrate reductase synthesis and the ability of nitrate to protect against molybdate toxicity suggest that incorporation of molybdenum into nitrate reductase or into something having the same control properties as nitrate reductase can detoxify molybdate. However, mutations affecting regulation of xanthine dehydrogenase synthesis do not affect growth responses to molybdate. The properties of another class of molybdate resistance mutations (molA) suggest that there is another nitrate-inducible intracellular molybdate detoxification mechanism in addition to the one having identical control properties to nitrate reductase.

Complementation analysis of auxotrophic mutants of the moss physcomitrella patens using protoplast fusion

SummaryFusion of protoplasts from the moss, Physcomitrella patens, was induced using polyethyleneglycol. Protoplasts were isolated from six nicotinic acid auxotrophic strains of independent origin and fusion was induced in all possible pairwise combinations. Complementation was detected by the ability to recover hybrids able to grow without nicotinic acid supplement. On the basis of the results presented, three nonoverlapping complementation groups were identified.

Formation of NADPH-nitrate reductase activity in vitro from Aspergillus nidulans niaD and cnx mutants

SummaryMutants of A. nidulans at several loci lack detectable NADPH-nitrate reductase activity. These loci include niaD, the structural gene for the nitrate reductase polypeptide, and five other loci termed cnxABC, E, F, G and H which are presumed to be involved in the formation of a molybdenum-containing component (MCC) necessary for nitrate reductase activity. When frozen mycelia from A. nidulans deletion mutant niaD26 were homogenized in a Ten Broeck homogenizer together with frozen mycelia from either enzA6, cnxE29, cnxF12, enxG4 or cnxH3 strains grown on urea+nitrate as the nitrogen source, nitrate reductase activity was detectable in the extract. Similar results were obtained by co-homogenizing niaD mycelia with Neurospora crassa nit-1 mycelia induced on nitrate. Thus, all A. nidulans cnx mutants are similar to the N. crassa nit-1 strain in their capacity to yield NADPH-nitrate reductase in the presence of the presumed MCC. As judged by the amounts of nitrate reductase formed, niaD26 mycelia grown on urea±nitrate contained much more available MCC than ammonium-grown mycelia. No NADPH-nitrate reductase activity was found in extracts prepared by co-homogenizing mycelia from all five A. nidulans cnx strains. Wild-type A. nidulans NADPH-nitrate reductase acid dissociated by adjustment to pH 2.0–2.5 and re-adjusted to pH 7 could itself re-assemble to form active nitrate reductase and thus was not a sueful source of MCC for these experiments. These results are consistent with the conclusion that the active nitrate reductase complex is composed of polypeptide components which are the niaD gene product, plus the MCC which is formed through the combined action of the cnx gene products. Further, the production of MCC may be regulated in response to the nitrogen nutrition available to the organism.

Pyrimidine biosynthesis in Aspergillus nidulans

SummaryMutants resistant to 5-fluorouracil, 5-fluorouridine and 5-fluorodeoxyuridine have been selected in Aspergillus nidulans. Growth tests combined with genetic analysis showed that mutations conferring resistance to fluoropyrimidines could occur in at least seven genes. Three of these, fulE, fulF and furA were concerned with either the uptake of pyrimidines or their conversion to uridine monophosphate. The other four genes did not affect these functions. Mutations in fulA probably confer resistance by lowering ornithine transcarbamoylase, thereby making the normally arginine-specific carbamoyl phosphate pool available for increased uracil synthesis. Mutations in fulD may make the arginine-specific carbamoyl phosphate synthetase insensitive to inhibition or repression by arginine, and so lead to increased carbamoyl phosphate pool sizes, and increased uracil synthesis. Both fulA and fulD mutants suppress pyrA mutants which lack the uracil-specific carbamoyl phosphate synthetase. Mutations in fulB and fulC do not suppress pyrA, and so may act more directly to increase uracil synthesis. The synthesis of aspartate carbamoyl transferase in fulB7 strains is not repressed by uracil. fulC mutants are closely linked to the pyrA, B, C, N region which codes for the first two enzymes of pyrimidine biosynthesis, and may result in these enzymes being less sensitive to inhibition by uracil.