Insertional Mutagenesis in Coprinus Cinereus: Use of a Dominant Selectable Marker to Generate Tagged, Sporulation-defective Mutants

Overview

Journal Curr Genet

Specialty Genetics

Date 2000 Feb 2

PMID 10654091

Citations 26

Authors

W J Cummings

M Celerin

J Crodian

L K Brunick

M E Zolan

Affiliations

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Abstract

We have constructed a dominant selectable marker, PHT1, for transformation of the basidiomycete Coprinus cinereus. PHT1 consists of a bacterial hygromycin B resistance gene fused to the promoter and terminator regions of the C. cinereus beta-tubulin gene. We found in transformation experiments that PHT1 confers hygromycin B resistance to all strains of C. cinereus tested, that it integrates without apparent bias into the genome, and that it is stable through meiotic crosses. We used a plasmid containing this marker, pPHT1, for restriction enzyme-mediated integration (REMI) and found that this technique could increase transformation efficiencies more than seven-fold. In REMI experiments using KpnI, the integrated DNA was flanked by intact KpnI sites in 53% of the cases examined, single-copy insertions represented 60% of the integration events, and most multicopy insertions were oriented head-to-tail. A screen of REMI-generated transformants yielded sporulation-defective mutants at a frequency of 1.2%. Genetic analysis showed that in six of nine mutants examined, the defect in spore formation is most likely a direct result of the pPHT1 insertion, and in three of these mutants a single pPHT1 locus was shown to cosegregate with the sporulation defect. We used semi-random PCR to isolate the genomic DNA adjacent to one pPHT1 insertion in a sporulation-defective mutant and found that we had disrupted the C. cinereus spo11 gene. Thus, REMI, in combination with pPHT1, is a powerful tool for the dissection of the meiotic process in C. cinereus.

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