BMC Genomics (Aug 2012)

Sequencing the genome of <it>Marssonina brunnea</it> reveals fungus-poplar co-evolution

  • Zhu Sheng,
  • Cao You-Zhi,
  • Jiang Cong,
  • Tan Bi-Yue,
  • Wang Zhong,
  • Feng Sisi,
  • Zhang Liang,
  • Su Xiao-Hua,
  • Brejova Brona,
  • Vinar Tomas,
  • Xu Meng,
  • Wang Ming-Xiu,
  • Zhang Shou-Gong,
  • Huang Min-Ren,
  • Wu Rongling,
  • Zhou Yan

DOI
https://doi.org/10.1186/1471-2164-13-382
Journal volume & issue
Vol. 13, no. 1
p. 382

Abstract

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Abstract Background The fungus Marssonina brunnea is a causal pathogen of Marssonina leaf spot that devastates poplar plantations by defoliating susceptible trees before normal fall leaf drop. Results We sequence the genome of M. brunnea with a size of 52 Mb assembled into 89 scaffolds, representing the first sequenced Dermateaceae genome. By inoculating this fungus onto a poplar hybrid clone, we investigate how M. brunnea interacts and co-evolves with its host to colonize poplar leaves. While a handful of virulence genes in M. brunnea, mostly from the LysM family, are detected to up-regulate during infection, the poplar down-regulates its resistance genes, such as nucleotide binding site domains and leucine rich repeats, in response to infection. From 10,027 predicted proteins of M. brunnea in a comparison with those from poplar, we identify four poplar transferases that stimulate the host to resist M. brunnea. These transferas-encoding genes may have driven the co-evolution of M. brunnea and Populus during the process of infection and anti-infection. Conclusions Our results from the draft sequence of the M. brunnea genome provide evidence for genome-genome interactions that play an important role in poplar-pathogen co-evolution. This knowledge could help to design effective strategies for controlling Marssonina leaf spot in poplar.

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