Analysis of the gene for the elongation factor 1 alpha from the zygomycete Absidia glauca. Use of the promoter region for constructions of transformation vectors

Genetic damage following introduction of DNA in Phycomyces

Introduction of plasmids in Phycomyces blakesleeanus caused extensive changes in the exogenous DNA and in the resident genome. Plasmids with a bacterial gene for geneticin resistance under a Phycomyces promoter were either injected into immature sporangia or incubated with spheroplasts. An improved method produced about one viable spheroplast per cell. Colonies resistant to geneticin were rare and only about 0.1% of their spores grew in the presence of geneticin. The transformation frequency was very low, < or =1 transformed colony per million spheroplasts or per microg DNA. Few nuclei in the transformants contained exogenous DNA, as shown by a selective procedure that sampled single nuclei from heterokaryons. The exogenous DNA was not integrated into the genome and no stable transformants were obtained. The plasmids were replicated in the recipient cells, but their DNA sequences were modified by deletions and rearrangements and the transformed phenotype was eventually lost. The spores developed in injected sporangia were often inviable; a genetic test showed that spore death was caused by impaired nuclear proliferation and induction of lethal mutations. About one-fourth of the viable spores from injected sporangia formed abnormal colonies with obvious changes in shape, texture, or color. The abnormalities that could be investigated were due to dominant mutations. The results indicate that incoming DNA is not only attacked, but signals a situation of stress that leads to increased mutation and nuclear and cellular death.

Isolation and use of a homologous histone H4 promoter and a ribosomal DNA region in a transformation vector for the oil-producing fungus Mortierella alpina

Mortierella alpina was transformed successfully to hygromycin B resistance by using a homologous histone H4 promoter to drive gene expression and a homologous ribosomal DNA region to promote chromosomal integration. This is the first description of transformation in this commercially important oleaginous organism. Two pairs of histone H3 and H4 genes were isolated from this fungus. Each pair consisted of one histone H3 gene and one histone H4 gene, transcribed divergently from an intergenic promoter region. The pairs of encoded histone H3 or H4 proteins were identical in amino acid sequence. At the DNA level, each histone H3 or H4 open reading frame showed 97 to 99% identity to its counterpart but the noncoding regions had little sequence identity. Unlike the histone genes from other filamentous fungi, all four M. alpina genes lacked introns. During normal vegetative growth, transcripts from the two histone H4 genes were produced at approximately the same level, indicating that either histone H4 promoter could be used in transformation vectors. The generation of stable, hygromycin B-resistant transformants required the incorporation of a homologous ribosomal DNA region into the transformation vector to promote chromosomal integration.