Genetics - Theses
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ItemNitrogen utilization and its regulation in Aspergillus nidulans(University of Melbourne, 2006)The filamentous fungus Aspergillus nidulans is able to utilize a wide range of compounds as sources of nitrogen. The presence of preferred nitrogen sources (ammonium and glutamine) signals nitrogen sufficiency, and genes required for the utilization of alternative sources are not expressed. In the absence of preferred nitrogen sources regulatory proteins activate expression of these genes. This constitutes nitrogen metabolite repression, and ensures the most efficient use of available nitrogen. In A.nidulans nitrogen metabolite repression is mediated by AreA, a positively acting GATA transcription factor. This thesis describes the investigation of two genes whose expression is subject to nitrogen metabolite repression and controlled by AreA, and the characterization of a fourth AMT/MEP gene in A. nidulans. areA102 is a specific mutation of the areA gene which results in a protein with altered promoter binding specificity, and areA102 mutants grow more strongly on a range of amino acids as nitrogen sources. Mutations at the sarA locus were first isolated as suppressors of the strong growth of an areA102 strain on histidine. In this study the sarA gene was characterized and confirmed to encode an L-amino acid oxidase (LAO) with broad substrate specificity. A sarA gene inactivation abolished LAO activity and suppressed the areA102 phenotype on histidine. An areA102 mutant was found to have increased utilization and stronger growth on amino acids which are LAO substrates. Investigation of sarA dependent and independent amino acid catabolism further defined the substrate specificity of LAO, and the contribution of other catabolic pathways was assessed. In A.nidulans the LAO was found to be the sole pathway for the catabolism of some amino acids, while for others this enzyme represents only a minor pathway. A.nidulans is known to possess four ammonium permeases differentially regulated by AreA. meaA encodes a low affinity ammonium transporter responsible for the majority of ammonium uptake. mepA has been shown to encode a high affinity permease which scavenges low concentrations of ammonium during nitrogen limitation, and mepB encodes a second high affinity permease only expressed during nitrogen starvation. To confirm the role of the fourth permease in ammonium acquisition, the mepC gene was cloned and its DNA and protein sequences analysed. The MepC ammonium transporter motifs differed somewhat from the consensus, and topology predictions indicated that mepC was more structurally divergent than the other A.nidulans ammonium transporters. The mepC gene was inactivated and the deletion strain was found to be indistinguishable from wildtype and from meaA, mepA, and mepB single, double and triple deletion backgrounds. However, strains over-expressing mepC from the highly inducible xylP promoter were able to partially complement the poor growth of an meaA?; mepA?; mepB? strain, indicating that MepC is capable of transporting ammonium. In other fungal systems certain ammonium permeases act as sensors of cellular nitrogen status. MeaA, MepA, and MepB do not act as nitrogen sensors. To determine whether MepC played a role in nitrogen sensing, amdS
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ItemNitrogen utilization and its regulation in Aspergillus nidulans(University of Melbourne, 2006)The filamentous fungus Aspergillus nidulans is able to utilize a wide range of compounds as sources of nitrogen. The presence of preferred nitrogen sources (ammonium and glutamine) signals nitrogen sufficiency, and genes required for the utilization of alternative sources are not expressed. In the absence of preferred nitrogen sources regulatory proteins activate expression of these genes. This constitutes nitrogen metabolite repression, and ensures the most efficient use of available nitrogen. In A.nidulans nitrogen metabolite repression is mediated by AreA, a positively acting GATA transcription factor. This thesis describes the investigation of two genes whose expression is subject to nitrogen metabolite repression and controlled by AreA, and the characterization of a fourth AMT/MEP gene in A. nidulans. areA102 is a specific mutation of the areA gene which results in a protein with altered promoter binding specificity, and areA102 mutants grow more strongly on a range of amino acids as nitrogen sources. Mutations at the sarA locus were first isolated as suppressors of the strong growth of an areA102 strain on histidine. In this study the sarA gene was characterized and confirmed to encode an L-amino acid oxidase (LAO) with broad substrate specificity. A sarA gene inactivation abolished LAO activity and suppressed the areA102 phenotype on histidine. An areA102 mutant was found to have increased utilization and stronger growth on amino acids which are LAO substrates. Investigation of sarA dependent and independent amino acid catabolism further defined the substrate specificity of LAO, and the contribution of other catabolic pathways was assessed. In A.nidulans the LAO was found to be the sole pathway for the catabolism of some amino acids, while for others this enzyme represents only a minor pathway. A.nidulans is known to possess four ammonium permeases differentially regulated by AreA. meaA encodes a low affinity ammonium transporter responsible for the majority of ammonium uptake. mepA has been shown to encode a high affinity permease which scavenges low concentrations of ammonium during nitrogen limitation, and mepB encodes a second high affinity permease only expressed during nitrogen starvation. To confirm the role of the fourth permease in ammonium acquisition, the mepC gene was cloned and its DNA and protein sequences analysed. The MepC ammonium transporter motifs differed somewhat from the consensus, and topology predictions indicated that mepC was more structurally divergent than the other A.nidulans ammonium transporters. The mepC gene was inactivated and the deletion strain was found to be indistinguishable from wildtype and from meaA, mepA, and mepB single, double and triple deletion backgrounds. However, strains over-expressing mepC from the highly inducible xylP promoter were able to partially complement the poor growth of an meaA?; mepA?; mepB? strain, indicating that MepC is capable of transporting ammonium. In other fungal systems certain ammonium permeases act as sensors of cellular nitrogen status. MeaA, MepA, and MepB do not act as nitrogen sensors. To determine whether MepC played a role in nitrogen sensing, amdS