Molecular and Chemical Screening for Inherent Disease Resistance Factors of Norway spruce (Picea abies) Clones against Conifer Stem Rot Pathogen Heterobasidion parviporum

Abstract

Root and stem rot of conifer trees caused by Heterobasidion annosum species complex leads to huge economic losses in Europe, yet not much is known about the molecular and chemical basis for host resistance. To identify inherent chemical or molecular markers in clones found to be either resistant or susceptible, we sampled needle tissues of all the clones prior to pathogen inoculation. We conducted a short-term resistance screening by using the pathogen H. parviporum to inoculate 70 Norway spruce clones. Based on lesion size, subsets of highly susceptible and resistant clones were further analysed. Terpene detection and RNA sequencing were performed to explore inherent variations in genotypes differing in resistance to pathogenic challenge at chemical and transcriptional levels. A negative correlation emerged between resistance and growth. Terpene profiles of resistant clones showed higher content of monoterpenes and sesquiterpenes with concomitant increased transcript abundance of genes involved in the terpenoid pathway. A set of upregulated genes relevant to flavonoid biosynthesis was observed in resistant genotypes whereas higher transcripts of lignin biosynthetic genes were prevalent in susceptible clones. Genes involved in flavonoid and lignin biosynthesis as well as terpene content may potentially have a role in facilitating resistance of Norway spruce against H. parviporum. Our results provide strong support on the feasibility of sampling needle tissues prior to pathogen inoculation and the approach could be of value for large-scale screening of novel biomarkers for durable resistance. The additional insights could form a basis for further research on resistance screening in this pathosystem.