Abstract

<i>Phytophthora cinnamomi</i> is one of the most invasive tree pathogens that devastates wild and cultivated forests. Due to its wide host range, knowledge of the infection process at the molecular level is lacking for most of its tree hosts. To expand the repertoire of studied <i>Phytophthora</i>-woody plant interactions and identify molecular mechanisms that can facilitate discovery of novel ways to control its spread and damaging effects, we focused on the interaction between <i>P. cinnamomi</i> and sweet chestnut (<i>Castanea sativa</i>), an economically important tree for the wood processing industry. By using a combination of proteomics, metabolomics, and targeted hormonal analysis, we mapped the effects of <i>P. cinnamomi</i> attack on stem tissues immediately bordering the infection site and away from it. <i>P. cinnamomi</i> led to a massive reprogramming of the chestnut proteome and accumulation of the stress-related hormones salicylic acid (SA) and jasmonic acid (JA), indicating that stem inoculation can be used as an easily accessible model system to identify novel molecular players in <i>P. cinnamomi</i> pathogenicity.