clap1, a gene encoding a copper-transporting ATPase involved in the process of infection by the phytopathogenic fungus Colletotrichum lindemuthianum

A screen for insertional mutants of Colletrichum lindemuthianum, the causative agent of common bean anthracnose, led to the identification of a non-pathogenic, lightly colored transformant. This mutant is unable to induce disease symptoms on intact or wounded primary leaves of seedlings and plantlets of Phaseolus vulgaris. In vitro, it exhibits normal vegetative growth, sporulation and conidial germination, but the cultures remain beige instead of becoming black. Microscopic examination revealed that this mutant forms fewer appressoria than the wild-type strain, and these are misshapen and poorly melanized. Molecular analyses indicated that the mutagenic plasmid had targeted clap1, a gene encoding a putative copper-transporting ATPase sharing 35% identity with the human Menkes and Wilson proteins and the product of the CCC2 gene of Saccharomyces cerevisiae. Complementation of the non-pathogenic beige mutant with a wild-type allele of clap1 restored both pathogenicity and pigmentation. Conversely, replacement of the wild-type allele with a disrupted clap1 gene gave rise to non-pathogenic beige transformants. Compared with the wild-type strain, extracts from clap1 mutants were found to have very low levels of phenol oxidase activity. These observations suggest that the clap1 gene product may be involved in the pathogenicity of C. lindemuthianum strains because of its role in delivering copper to secreted cuproenzymes, such as the phenol oxidases that mediate the polymerization of 1,8-dihydroxynaphthalene to melanin.     

Evidence for a diffusible factor that induces susceptibility in the Colletotrichum–maize disease interaction

Colletotrichum graminicola, the causal agent of maize anthracnose, is a hemibiotrophic fungus that initially infects living host cells via primary hyphae surrounded by a membrane. A nonpathogenic mutant disrupted in a gene encoding a component of the signal peptidase complex, and believed to be deficient in protein processing and secretion, regained pathogenicity when it was inoculated onto maize leaf sheaths close to the wild‐type fungus. Evidence is presented suggesting that the wild‐type produces a diffusible factor(s) that induces the localized susceptibility of host cells at the borders of expanding colonies, causing them to become receptive to biotrophic invasion. The induced susceptibility effect is limited to a distance of approximately eight cells from the edge of the wild‐type colony, is dosage dependent and is specific to C. graminicola.     

CLNR1, the AREA/NIT2-like global nitrogen regulator of the plant fungal pathogen Colletotrichum lindemuthianum is required for the infection cycle

Nitrogen starvation is generally assumed to be encountered by biotrophic and hemibiotrophic plant fungal pathogens at the beginning of their infection cycle. We tested whether nitrogen starvation constitutes a cue regulating genes that are required for pathogenicity of Colletotrichum lindemuthianum, a fungal pathogen of common bean. The clnr1 (C. lindemuthianumnitrogen regulator 1) gene, the areA/nit-2 orthologue of C. lindemuthianum, was isolated. The predicted CLNR1 protein exhibits high amino acid sequence similarities with the AREA and NIT2 global fungal nitrogen regulators. Targeted clnr1- mutants are unable to use a wide array of nitrogen sources, indicating that clnr1 is the C. lindemuthianum major nitrogen regulatory gene. The clnr1- mutants are non-pathogenic, although few anthracnose lesions seldom occur on whole plantlets. Surprisingly, cytological analysis reveals that the clnr1- mutants are not disturbed from the penetration stage until the end of the biotrophic phase, but that they are impaired during the setting up of the necrotrophic phase. Thus, through CLNR1, nitrogen starvation constitutes a cue for the regulation of genes that are compulsory for this stage of the C. lindemuthianum infection process. Additionally, clnr1- mutants complemented with the Aspergillus nidulans areA gene are fully pathogenic, indicating that areA is able to activate the C. lindemuthianum suited genes, normally under the control of clnr1.     

A putative MAP kinase kinase kinase, MCK1, is required for cell wall integrity and pathogenicity of the rice blast fungus, Magnaporthe oryzae

Insertional mutagenesis of Magnaporthe oryzae led to the identification of MCK1, a pathogenicity gene predicted to encode mitogen-activated protein kinase kinase kinase (MAPKKK) homologous to BCK1 in Saccharomyces cerevisiae. Targeted disruption of MCK1 resulted in the fungus undergoing autolysis and showing hypersensitivity to cell-wall-degrading enzyme. The mck1 produced significantly reduced numbers of conidia and developed appressoria in a slightly retarded manner compared with the wild type. Appressorium of the mck1 mutant was unable to penetrate into plant tissues, thereby rendering the mutant nonpathogenic. Cytorrhysis assay and monitoring of lipid mobilization suggested that the appressorial wall was altered, presumably affecting the level of turgor pressure within appressorium. Furthermore, the mck1 mutant failed to grow inside plant tissue. Complementation of the mutated gene restored its ability to cause disease symptoms, demonstrating that MCK1 is required for fungal pathogenicity. Taken together, our results suggest that MCK1 is an MAPKKK involved in maintaining cell wall integrity of M. oryzae, and that remodeling of the cell wall in response to host environments is essential for fungal pathogenesis.     

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.     

Transposon-tagging identifies novel pathogenicity genes in Fusarium graminearum

With the increase of sequenced fungal genomes, high-throughput methods for functional analyses of genes are needed. We assessed the potential of a new transposon mutagenesis tool deploying a Fusarium oxysporum miniature inverted-repeat transposable element mimp1, mobilized by the transposase of impala, a Tc1-like transposon, to obtain knock-out mutants in Fusarium graminearum. We localized 91 mimp1 insertions which showed good distribution over the entire genome. The main exception was a major hotspot on chromosome 2 where independent insertions occurred at exactly the same nucleotide position. Furthermore insertions in promoter regions were over-represented. Screening 331 mutants for sexual development, radial growth and pathogenicity on wheat resulted in 19 mutants (5.7%) with altered phenotypes. Complementation with the original gene restored the wild-type phenotype in two selected mutants demonstrating the high tagging efficiency. This is the first report of a MITE transposon tagging system as an efficient mutagenesis tool in F. graminearum.     

Mutations in the CCGTTCACA DnaA box of Mycobacterium tuberculosis oriC that abolish replication of oriC plasmids are tolerated on the chromosome

The origin of replication (oriC) region in some clinical strains of Mycobacterium tuberculosis is a hot spot for IS6110 elements. To understand how clinical strains with insertions in oriC can replicate their DNA, we characterized the oriC regions of some clinical strains. Using a plasmid-based oriC-dependent replication assay, we showed that IS6110 insertions that disrupted the DnaA box sequence CCGTTCACA abolished oriC activity in M. tuberculosis. Furthermore, by using a surface plasmon resonance technique we showed that purified M. tuberculosis DnaA protein binds native but not mutant DnaA box sequence, suggesting that stable interactions of the DnaA protein with the CCGTTCACA DnaA box are crucial for replication of oriC plasmids in vivo. Replacement by homologous recombination of the CCGTTCACA DnaA box sequence of the laboratory strain M. tuberculosis H37Ra with a mutant sequence did not result in nonviability. Together, these results suggest that M. tuberculosis strains have evolved mechanisms to tolerate mutations in the oriC region and that functional requirements for M. tuberculosis oriC replication are different for chromosomes and plasmids.     

The properties of citrate transport catalyzed by CitP of Lactococcus lactis ssp. lactis biovar diacetylactis

Abstract The SC3 hydrophobin gene of Schizophyllum commune was disrupted by homologous integration of an SC3 genomic fragment interrupted by a phleomycin resistance cassette. The phenotype of the mutant was particularly clear in sealed plates in which formation of aerial hyphae was blocked. In non-sealed plates aerial hyphae did form but these were hydrophilic and not hydrophobic as in wild-type strains. Complementation with a genomic SC3 clone restored formation of hydrophobic aerial hyphae in sealed plates. In a dikaryon homozygous for the SC3 mutation normal sporulating fruiting bodies were produced but aerial hyphae were hydrophilic.     

Scooter, a new active transposon in Schizophyllum commune, has disrupted two genes regulating signal transduction

Two copies of scooter, a DNA-mediated transposon in the basidiomycetous fungus Schizophyllum commune, were characterized. Scooter is the first transposon isolated from S. commune. Scooter creates 8-bp target site duplications, comparable to members of the hAT superfamily, and has 32-bp terminal inverted repeats. Both copies of scooter are nonautonomous elements capable of movement. Southern blot hybridizations show that scooter-related sequences are present in all S. commune strains tested. Scooter-1 was identified initially as an insertion in the Bbeta2 pheromone receptor gene, bbr2, leading to a partial defect in mating. Scooter-2 spontaneously disrupted a gene to produce the frequently occurring morphological mutant phenotype known as thin. The scooter-2 insert permitted cloning of the disrupted gene, thn1, which encodes a putative regulator of G protein signaling (RGS) protein. Spontaneous insertion of scooter into genes with identifiable mutant phenotypes constitutes the first evidence of active transposition of a DNA-mediated transposon in a basidiomycete.