David K. Asch scite author profile

In Neurospora crassa, five structural genes and two regulatory genes control the use of quinic acid as a carbon source. All seven genes are tightly linked to form the qa gene cluster. The entire cluster, which has been cloned and sequenced, occupies a continuous DNA segment of 17.3 kb. Three pairs of genes are divergently transcribed, including the two regulatory genes that are located at one end of the cluster and that encode an activator (qa-1F) and a repressor (qa-1S). Three of the structural genes (qa-2, qa-3, and qa-4) encode inducible enzymes that catalyze the catabolism of quinic acid. One structural gene (qa-y) encodes a quinate permease; the function of the fifth gene (qa-x) is still unclear. Present genetic and molecular evidence indicates that the qa activator and repressor proteins and the inducer quinic acid interact to control expression at the transcriptional level of all the qa genes. The activator, the product of the autoregulated qa-1F gene, binds to symmetrical 16 base pair upstream activating sequences located one or more times 5' to each of the qa genes. A conserved 28 amino acid sequence containing a six cysteine zinc binding motif located in the amino terminal region of the activator has been directly implicated in DNA binding. Evidence for other functional domains in the activator and repressor proteins are discussed. Indirect evidence suggests that the repressor is not a DNA-binding protein but forms an inactive complex with the activator in the absence of the inducer.(ABSTRACT TRUNCATED AT 250 WORDS)

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FunSecKB2: a fungal protein subcellular location knowledgebase

Meinken¹,

Asch²,

et al. 2014

cmb

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Isolation and preliminary characterization of a plasmid mutant derepressed for conjugal transfer in Staphylococcus aureus

Asch

Goering

Ruff

1984

Plasmid

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Relationship of vector insert size to homologous integration during transformation of Neurospora crassa with the cloned am (GDH) gene

Asch

Kinsey

1990

Molec. Gen. Genet.

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We used lambda and plasmid vectors containing the am+ gene in an insert of from 2.7 to 9.1 kb, to transform am point mutant and deletion strains. A total of 199 transformants were examined with the potential to yield am+ transformants by homologous recombination. When we used vectors that had 9.1 kb of homology with the chromosomal DNA, 30% of the transformants obtained were the result of homologous recombination regardless of whether the vector was a lambda molecule, a circular plasmid, or a plasmid that had been linearized prior to transformation. When vectors with up to 5.1 kb of homology were used, very few transformants (1 of 89 tested) resulted from homologous recombination. Of a sample of 29 ectopic integration events obtained by transformation with the 9.1 kb fragment cloned in a lambda vector, 18 included a major part (usually almost all) of both arms of lambda with the entire Neurospora 9.1 kb insert between them. Four included only lambda long arm sequence together with an adjacent segment of the insert containing the am gene. The remaining seven were the result of multiple integrations. There was no evidence of circularization of the lambda vector prior to integration. All transformants that had multiple copies of the am gene appeared to be subject to the RIP process, which causes multiple mutations in duplicated sequences during the sexual cycle.

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Radioactivity-Based and Spectrophotometric Assays for Isoorotate Decarboxylase: Identification of the Thymidine Salvage Pathway in Lower Eukaryotes

Smiley

Angelot

Cannon

et al. 1999

Analytical Biochemistry

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David K. Asch

Organization and Regulation of the Qa (Quinic Acid) Genes in Neurospora crassa and Other Fungi

FunSecKB2: a fungal protein subcellular location knowledgebase

Isolation and preliminary characterization of a plasmid mutant derepressed for conjugal transfer in Staphylococcus aureus

Relationship of vector insert size to homologous integration during transformation of Neurospora crassa with the cloned am (GDH) gene

Radioactivity-Based and Spectrophotometric Assays for Isoorotate Decarboxylase: Identification of the Thymidine Salvage Pathway in Lower Eukaryotes

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