2005

Attard A. , Gout L. , Ross S. , Parlange F. , Cattolico L. , Balesdent, M.-H. , Rouxel, T. Truncated and RIP-degenerated copies of the LTR retrotransposon Pholy are clustered in a pericentromeric region of the Leptosphaeria maculans genome. Fungal Genetics and Biology 42 (1) , 30-41
Balesdent M.H., Barbetti M.J., Li H., Sivasithamparam K., Gout L., Rouxel T. Analysis of Leptosphaeria maculans race structure in a worldwide collection of isolates. Phytopathology 95 (9),1061-1071
Blenis P.V., Chow P.S. Evaluating fungi from wood and canola for their ability to decompose canola stubble. Canadian Journal of Plant Pathology 27 (2), 259-267
Dubuis P.-H., Marazzi C., Stadler E., Mauch F. Sulphur deficiency causes a reduction in antimicrobial potential and leads to increased disease susceptibility of oilseed rape. Journal of Phytopathology 153 (1), 27-36
Eckert M. , Gout L. , Rouxel T. , Blaise F. , Jędryczka M. , Fitt B. , Balesdent M.-H. Identification and characterization of polymorphic minisatellites in the phytopathogenic ascomycete Leptosphaeria maculans. Current Genetics 47 (1) , 37-48.
Eckert M., Maguire K., Urban M., Foster S., Fitt B. Lucas J., Hammond-Kosack K. Agrobacterium tumefaciens-mediated transformation of Leptosphaeria spp. and Oculimacula spp. with the reef coral gene DsRed and the jellyfish gene gfp. FEMS Microbiology Letters 253 (1), 67-74
Gardiner D.M., Jarvis R.S., Howlett B.J. The ABC transporter gene in the sirodesmin biosynthetic gene cluster of Leptosphaeria maculans is not essential for sirodesmin production but facilitates self-protection. Fungal Genetics and Biology 42 (3) , 257-263.
Gonianakis M., Neonakis I., Darivianaki E., Gonianakis I., Bouros D., Kontou-Fili K. Airborne Ascomycotina on the island of Crete: Seasonal patterns based on an 8-year volumetric survey. Aerobiologia 21 (1), 69-74
Guo X.W., Fernando W.G.D. Seasonal and diurnal patterns of spore dispersal by Leptosphaeria maculans from canola stubble in relation to environmental conditions. Plant Disease 89 (1) , 97-104
Guo X.W., Fernando W.G.D., Entz M. Effects of crop rotation and tillage on blackleg disease of canola. Canadian Journal of Plant Pathology 27 (1), 53-57
Hayden H.L., Howlett B.J. Genetic structure of a population of the fungus Leptosphaeria maculans in a disease nursery of Brassica napus in Australia. Current Genetics 48 (2),142-149
Huang Y.-J., Fitt B.D.L., Jedryczka M., Dakowska S., West J.S., Gladders P., Steed J.M., Li Z.Q. Patterns of ascospore release in relation to phoma stem canker epidemiology in England (Leptosphaeria maculans) and Poland (Leptosphaeria biglobosa). European Journal of Plant Pathology 111 (3), 263-277
Kruse T., Verreet J.A. Epidemiological studies on winter oilseed rape (Brassica napus L. var. napus) infected by Phoma lingam (teleomorph Leptosphaeria maculans) and the effects of different fungicide applications with Folicur® (tebuconazole). Zeitschrift fur Pflanzenkrankheiten und Pflanzenschutz 112 (1), 17-41
Kutcher H.R., Malhi S.S. Gill K.S. Topography and management of nitrogen and fungicide affects diseases and productivity of canola. Agronomy Journal 97 (2), 533-541
Li H., Barbetti M.J. , Sivasithamparam K. Hazard from reliance on cruciferous hosts as sources of major gene-based resistance for managing blackleg (Leptosphaeria maculans) disease. Field Crops Research 91 (2-3) , 185-198
Marcroft S.J., Sosnowski M.R., Scott E.S., Ramsey M.D., Salisbury P.A., Howlett B.J. Brassica napus plants infected by Leptosphaeria maculans after the third to fifth leaf growth stage in south-eastern Australia do not develop blackleg stem canker. European Journal of Plant Pathology 112 (3), 289-292
Mayerhofer R., Wilde, K., Mayerhofer, M., Lydiate, D., Bansal, V.K., Good, A.G., Parkin, I.A.P. Complexities of chromosome landing in a highly duplicated genome: Toward map-based cloning of a gene controlling blackleg resistance in Brassica napus. Genetics 171(4), 1977-1988
Pedras M.S., Chumala P.B. Phomapyrones from blackleg causing phytopathogenic fungi: Isolation, structure determination, biosyntheses and biological activity. Phytochemistry 66 (1), 81-87
Pedras M.S.C., Chumala P.B., Venkatesham U. New sesquiterpenic phytotoxins establish unprecedented relationship between different groups of blackleg fungal isolates. Bioorganic and Medicinal Chemistry 13 (7), 2469-2475
Pedras M.S.C., Jha M., Okeola O.G. Camalexin induces detoxification of the phytoalexin brassinin in the plant pathogen Leptosphaeria maculans. Phytochemistry 66 (22), 2609-2616
Pedras M.S.C., Suchy M. Detoxification pathways of the phytoalexins brassilexin and sinalexin in Leptosphaeria maculans: Isolation and synthesis of the elusive intermediate 3-formylindolyl-2-sulfonic acid. Organic and Biomolecular Chemistry 3 (10), 2002-2007
Rouxel T., Balesdent M.H. The stem canker (blackleg) fungus, Leptosphaeria maculans, enters the genomic era. Molecular Plant Pathology 6 (3), 225-241
Saal B., Struss, D. RGA- and RAPD-derived SCAR markers for a Brassica B-genome introgression conferring resistance to blackleg in oilseed rape. Theoretical and Applied Genetics 111 (2), 281-290
Sivasithamparam K., Barbetti M.J., Li H. Recurring challenges from a necrotrophic fungal plant pathogen: A case study with Leptosphaeria maculans (causal agent of blackleg disease in Brassicas) in Western Australia. Annals of Botany. 96 (3), 363-377
Sosnowski M.R., Scott E.S., Ramsey M.D. Temperature, wetness period and inoculum concentration influence infection of canola (Brassica napus) by pycnidiospores of Leptosphaeria maculans. Australasian Plant Pathology 34(3), 339-344
Subramanian B., Bansal V.K., Kav N.N.V. Proteome-level investigation of Brassica carinata-derived resistance to Leptosphaeria maculans. Journal of Agricultural and Food Chemistry 53 (2) , 313-324
Voigt K., Cozijnsen A.J., Kroymann J., Poöggeler S., Howlett B.J.Phylogenetic relationships between members of the crucifer pathogenic Leptosphaeria maculans species complex as shown by mating type (MAT1-2), actin, and β-tubulin sequences. Molecular Phylogenetics and Evolution 37 (2), 541-557
West J.S., Fitt B.D.L. Population dynamics and dispersal of Leptosphaeria maculans (blackleg of canola): Adapted from a keynote address at the 15th Biennial Conference of the Australasian Plant Pathology Society, 26-29 September 2005, Geelong. Australasian Plant Pathology 34 (4), 457-461
Wilson L.M., Howlett B.J. Leptosphaeria maculans, a fungal pathogen of Brassica napus, secretes a subtilisin-like serine protease. European Journal of Plant Pathology 112 (1), 23-29
Yu F., Lydiate D.J., Rimmer S.R. Identification of two novel genes for blackleg resistance in Brassica napus. Theoretical and Applied Genetics 110 (5),969-979