Autonomously replicating plasmids and chromosome rearrangement during transformation of Nectria haematococca

A previously described, autonomously replicating plasmid was examined for its ability to replicate in the plant pathogenic fungus, Nectria haematococca (Nh). The plasmid, pFOLT4R4, replicates as a linear molecule, contains a subterminal inverted repeat, as well as the repeated hexanucleotide telomere consensus sequence, TTAGGG, at both ends, and increases frequency of fungal transformation approximately 100-fold compared to a similar integrative plasmid, pHRC. Transformation of Nh occurs by way of autonomous replication; the transformed, hygromycin B-resistant (Hy^R) phenotype is unstable without selection and in most cases pFOLT4R4 is maintained in the fungus, separate from chromosome-sized DNAs. Surprisingly, a non-autonomously replicating derivative of pFOLT4R4 (called pLD), lacking the subterminal inverted repeat and having the 5′-TTAGGG repeat in only one direction on the plasmid, transformed Nh at a rate as high as pFOLT4R4. Therefore, autonomous replication and high-frequency transformation are separable phenomena in Nh. In pLD transformants, plasmid sequences are integrated into chromosome-sized DNAs of Nh and these cultures generally have a stable Hy^R phenotype. Treatments involving ligation of Nh genomic DNA to pLD result in a lower frequency of transformation. In many cultures transformed with pLD plus genomic DNA, one wild-type chromosome-sized band is not visible, but another smaller chromosome-sized band is found. Mobility changes in some cases are consistent with deletions of over 1000 kb. Some Hy^S revertants of transformants appear to lack the entire chromosome into which integration had occurred. These results indicate that the Nh genome is extremely melleable and large portions may be non-essential for growth in culture.