Home • Colletotrichum abscissum IMI 504890
Colletotrichum on its hosts.
Colletotrichum on its hosts.
Image Credit: Riccardo Baroncelli

The genome sequence and gene prediction of Colletotrichum abscissum IMI 504890 have not been determined by the Joint Genome Institute (JGI), but were provided by Riccardo Baroncelli at the University of Salamanca. In order to allow comparative analyses with other fungal genomes sequenced by the JGI, a copy of this genome is incorporated into Mycocosm. Please note that this copy of the genome is not maintained by Riccardo Baroncelli and is therefore not automatically updated. JGI tools were used to automatically annotate predicted proteins.

The genus Colletotrichum (phylum Ascomycota, subphylum Sordariomycetes, order Glomerelalles) contains at least 150 species divided into ten major clades. One of the largest of these is the Colletotrichum acutatum species complex (CAsc), which includes fungal pathogens that infect a wide diversity of plants in natural and managed ecosystems. The species complex has a very wide host range, and strains have been associated with diseases of more than 90 genera of plants and at least three insect species. The complex taxonomy of CAsc reflects a complexity in evolutionary history, likely brought about by recent host jumps and/or changes in host range followed by adaptation. The CAsc also display great diversity of reproductive behaviors although most species seem to have lost their mating capability. Thus, the CAsc are excellent candidates for studying the process of speciation, host adaptation and the evolution of mating behavior.

Members of CAsc also show significant expansions in gene families associated with carbohydrate metabolism, particularly in families of xyloglucanases and other plant cell wall degrading enzymes and possibly contain the largest diversity of carbohydrate active enzymes in the Ascomycetes. How this repertoire of enzymes has evolved, and why CAsc species maintain such diversity is unknown. Comparative analysis of these species will give us insight into the mode and tempo of gene duplications, selective pressures and other evolutionary processes that lead to expansion of carbohydrate active enzymes.