Disruption of Botrytis cinerea class I chitin synthase gene Bcchs1 results in cell wall weakening and reduced virulence.

To get a better insight into the relationship between cell wall integrity and pathogenicity of the fungus Botrytis cinerea, we have constructed chitin synthase mutants. A 620 bp class I chitin synthase gene fragment (Bcchs1) obtained by PCR amplification was used to disrupt the corresponding gene in the genome. Disruption of Bcchs1 occurred at a frequency of 8%. Nine independent mutants were obtained and the Bcchs1 mutant phenotype compared to that of transformants in which the gene was not disrupted. These disruption mutants were dramatically reduced in their in vitro Mg2+, Mn2+, and Co2+-dependent chitin synthase activity. Chitin content was reduced by 30%, indicating that Bcchs1p contributes substantially to cell wall composition. Enzymatic degradation by a cocktail of glucanases revealed cell wall weakening in the mutant. Bcchs1 was transcribed at a constant level during vegetative exponential growth, suggesting that it was necessary throughout hyphal development. Bcchs1 mutant growth was identical to undisrupted control transformant growth, however, the mutant exhibited reduced pathogenicity on vine leaves. It can be assumed that disruption of Bcchs1 leads to cell wall weakening which might slow down in planta fungal progression.

Stability and modulated expression of a hygromycin resistance gene integrated in Botrytis cinerea transformants.

When transformation of Botrytis cinerea occurred in mononucleated protoplasts the hygromycin resistance phenotype was stable and integrated plasmid DNA although rearranged was transmitted through meiosis. We observed that transformants were often heterokaryotic and using serial conidial transfer, we showed failure of expression of the entire copies of integrated plasmids in some conidial isolates. A non-Mendelian segregation of the hygromycin resistance phenotype was observed in most crosses between these transformants and sensitive strains. However, a 1:1 segregation ratio of plasmid DNA hybridisation was observed. Mechanisms of gene silencing in B. cinerea, in both the asexual and the sexual cycle, are discussed.