Article
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Citation
Peck LD, Nowell RW, Flood J, Ryan MJ & Barraclough TG (2021) Historical genomics reveals the evolutionary mechanisms behind multiple outbreaks of the host-specific coffee wilt pathogen Fusarium xylarioides. BMC Genomics, 22 (1). https://doi.org/10.1186/s12864-021-07700-4
Abstract
Background: Nearly 50% of crop yields are lost to pests and disease, with plants and pathogens locked in an
amplified co-evolutionary process of disease outbreaks. Coffee wilt disease, caused by Fusarium xylarioides, decimated
coffee production in west and central Africa following its initial outbreak in the 1920s. After successful management, it
later re-emerged and by the 2000s comprised two separate epidemics on arabica coffee in Ethiopia and robusta
coffee in east and central Africa.
Results: Here, we use genome sequencing of six historical culture collection strains spanning 52 years to identify the
evolutionary processes behind these repeated outbreaks. Phylogenomic reconstruction using 13,782 single copy
orthologs shows that the robusta population arose from the initial outbreak, whilst the arabica population is a
divergent sister clade to the other strains. A screen for putative effector genes involved in pathogenesis shows that
the populations have diverged in gene content and sequence mainly by vertical processes within lineages. However,
15 putative effector genes show evidence of horizontal acquisition, with close homology to genes from F.oxysporum.
Most occupy small regions of homology within wider scaffolds, whereas a cluster of four genes occupy a 20Kb
scaffold with strong homology to a region on a mobile pathogenicity chromosome in F.oxysporum that houses
known effector genes. Lacking a match to the whole mobile chromosome, we nonetheless found close associations
with DNA transposons, especially the miniature impala type previously proposed to facilitate horizontal transfer of
pathogenicity genes in F.oxysporum. These findings support a working hypothesis that the arabica and robusta
populations partly acquired distinct effector genes via transposition-mediated horizontal transfer from F.oxysporum,
which shares coffee as a host and lives on other plants intercropped with coffee.
Conclusion: Our results show how historical genomics can help reveal mechanisms that allow fungal pathogens to
keep pace with our efforts to resist them. Our list of putative effector genes identifies possible future targets for fungal
control. In turn, knowledge of horizontal transfer mechanisms and putative donor taxa might help to design future
intercropping strategies that minimize the risk of transfer of effector genes between closely-related Fusarium taxa
Keywords
Comparative genomics; Host adaptation; Fungi, Effector,; Proteome; Fusarium oxysporum
Journal
BMC Genomics: Volume 22, Issue 1
Status | Published |
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Funders | and |
Publication date online | 04/06/2021 |
Date accepted by journal | 11/05/2021 |
URL | |
Publisher | Springer Science and Business Media LLC |
eISSN | 1471-2164 |
People (1)
Lecturer in Animal Evolutionary Biology, Biological and Environmental Sciences