Regulation of biosynthesis of L-amino acid oxidase by Neurospora crassa.

L-Amino acid oxidase was purified from liquid cultures of Neurospora crassa induced by L-phenylalanine, D-phenylalanine, ATP and cycloheximide. Although the four enzyme species isolated were found to differ in size and electrophoretic mobility, they were the product of a single gene as demonstrated by genomic Southern analysis. Northern analysis of total cellular RNA showed a rapid increase of L-amino acid oxidase mRNA in response to the different inducing agents studied. These data suggest that the L-amino acid oxidase gene from N. crassa is regulated at the transcriptional level.

Molecular cloning of the L-amino-acid oxidase gene from Neurospora crassa.

The addition of D-phenylalanine to starved cultures of Neurospora crassa leads to de novo synthesis of L-amino-acid oxidase. Poly(A) RNA from D-phenylalanine-treated mycelium was therefore used to generate a cDNA library which was subsequently screened by hybrid-selected translation. A positive L-amino-acid oxidase clone served as a probe to isolate the complete gene from a genomic library of N. crassa. The nucleotide sequence obtained revealed an open reading frame coding for a protein of 695 amino acids. A comparison of the deduced primary structure with the partial amino-terminal sequence of the isolated enzyme showed that the protein is synthesized as a precursor. The proform exceeds the mature enzyme by 129 amino acids. The presence of a cluster of basic amino acid residues preceding Ala129 in the precursor suggests a post-translational modification brought about by limited proteolysis. N. crassa L-amino-acid oxidase shares a highly conserved region with many well-characterized flavoproteins that is known to constitute part of the flavin-adenine dinucleotide-binding site.

ATP-induced protyrosinase synthesis and carboxyl-terminal processing in Neurospora crassa.

The effects of 3'-5' cyclic AMP and ATP upon tyrosinase induction in Neurospora crassa were examined. Northern analysis of total cellular RNA revealed rapid de novo synthesis of protyrosinase after addition of these substances to stationary-phase mycelia. The maturation of protyrosinase in crude extracts of mycelia was followed by Western analysis. Polyclonal rabbit antiserum directed against the denatured carboxyl-terminal extension of protyrosinase does recognize the proform and several intermediate forms of different molecular weight but not mature tyrosinase. Disruption of ATP-induced mycelia in sodium phosphate buffer (pH 6.0) demonstrate processing at the carboxyl-terminal end of protyrosinase. The activity assays revealed that protyrosinase is an inactive precursor and that at least two active forms of slightly different molecular weight are present in crude extracts. Maturation of protyrosinase thus involves specific and sequential proteolytic cleavage at the carboxyl-terminus. These results suggest the presence of a tyrosinase activator in Neurospora crassa mycelia, which is kept apart from protyrosinase in the intact mycelium.

Isolation and characterization of the tyrosinase gene from Neurospora crassa.

A precursor form of Neurospora crassa tyrosinase has been identified by Western transfer from crude protein extracts and by immunoprecipitation of in vitro translated tyrosinase mRNA. The molecular weight of protyrosinase (75,000) exceeds that of mature tyrosinase (46,000) by about 50%. In order to deduce the primary structure and the nature of the extension, the tyrosinase gene was cloned. Poly(A) RNA isolated from tyrosinase-induced cultures of N. crassa was used as a template for cDNA synthesis, primed by a tyrosinase-specific, 32-fold degenerate heptadecanucleotide. Based on this sequence, a unique 21-mer was synthesized and used to screen a cDNA library constructed from tyrosinase-enriched mRNA. A partial genomic DNA library from wild-type strain TS and a genomic library from strain OR were screened using a 400-base pair nick-translated SalI fragment from a tyrosinase-positive cDNA clone as hybridization probe. The DNA sequences obtained revealed the presence of two allelic forms of this enzyme. The coding regions are interrupted by two short introns, of 52 and 99 base pairs. The encoded proteins differ in 3 out of 621 amino acid residues. A comparison of the deduced amino acid sequence with the known primary structure of mature tyrosinase alleles (Rüegg, C., Ammer, D., and Lerch, K. (1982) J. Biol. Chem. 257, 6420-6426) showed that the enzyme is synthesized as a precursor. Protyrosinase exceeds the mature protein by 213 amino acids at its carboxyl terminus. The possible involvement of carboxyl-terminal processing in enzyme activation is discussed.