Grapevine Botryosphaeria dieback fungi have specific aggressiveness factor repertory involved in wood decay and stilbene metabolization

PLoS One. 2017 Dec 20;12(12):e0188766. doi: 10.1371/journal.pone.0188766. eCollection 2017.

Abstract

Grapevine trunk diseases: Eutypa dieback, esca and Botryosphaeria dieback, which incidence has increased recently, are associated with several symptoms finally leading to the plant death. In the absence of efficient treatments, these diseases are a major problem for the viticulture; however, the factors involved in disease progression are not still fully identified. In order to get a better understanding of Botryosphaeria dieback development in grapevine, we have investigated different factors involved in Botryosphaeriaceae fungi aggressiveness. We first evaluated the activity of the wood-degrading enzymes of different isolates of Neofusicoccum parvum and Diplodia seriata, two major fungi associated with Botryosphaeria dieback. We further examinated the ability of these fungi to metabolize major grapevine phytoalexins: resveratrol and δ-viniferin. Our results demonstrate that Botryosphaeriaceae were characterized by differential wood decay enzymatic activities and have the capacity to rapidly degrade stilbenes. N. parvum is able to degrade parietal polysaccharides, whereas D. seriata has a better capacity to degrade lignin. Growth of both fungi exhibited a low sensitivity to resveratrol, whereas δ-viniferin has a fungistatic effect, especially on N. parvum Bourgogne S-116. We further show that Botryosphaeriaceae are able to metabolize rapidly resveratrol and δ-viniferin. The best stilbene metabolizing activity was measured for D. seriata. In conclusion, the different Botryosphaeriaceae isolates are characterized by a specific aggressiveness repertory. Wood and phenolic compound decay enzymatic activities could enable Botryosphaeriaceae to bypass chemical and physical barriers of the grapevine plant. The specific signature of Botryosphaeriaceae aggressiveness factors could explain the importance of fungi complexes in synergistic activity in order to fully colonize the host.

MeSH terms

  • Ascomycota / growth & development
  • Ascomycota / metabolism
  • Ascomycota / pathogenicity*
  • Cellulase / metabolism
  • Polysaccharides / metabolism
  • Stilbenes / metabolism*
  • Vitis / microbiology*
  • Wood*

Substances

  • Polysaccharides
  • Stilbenes
  • Cellulase

Grants and funding

E. Stempien PhD fellowship was financed by the Alsace Region (France) and CIVA (Conseil Interprofessionnels des Vins d’Alsace). This work has been supported by Interreg Rhin Supérieur V project "Vitifutur" http://www.interreg-rhin-sup.eu/projet/vitifutur-reseau-transnational-de-recherche-et-de-formation-en-viticulture/. This work has been supported by the Université de Haute Alsace (Ecovino Project). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.