Functional dissection of the PME and PMEI super families in the protection of Populus pectin during Fusarium wilt

Abstract

Integration of the pectin homogalacturonan (HG) integrity and remodeling into defense immunity facilitates building blocks of stress resilience within the host and pathogen interactions in the forests. Recent advances in apoplastic pectin methylesterases (PMEs) and coordinated PME inhibitors (PMEIs) deployed immune signaling, highlighting their critical roles in regulating biotic stress adaptation. Nevertheless, the PME and PMEI multiple isoenzyme families involved in defense priming in the model tree species are largely unknown. The in silico demonstration of the molecular profile identified 70 PME- (50 type-I proPME and 20 type-II PME) and 49 PMEI-encoding genes in the Populus genome. Evaluation of the transcript abundance verified 20 PtproPMEs and 18 PtPMEIs that showed predominant expression in the root and genetic redundancy for type-II PtPMEs. Dynamic changes in the transcriptome and experimental evaluation revealed a minuscule number of type-I proPMEs and PMEIs that showed marked promotions during a time-course Fusarium solani (Fs) infection. Using GC/LC-mass-based non-targeted metabolomics to inspect structure-related carbohydrates and PME activities suggested a correlation between proPME-PMEI co-expression and deformed pectin HG biosynthesis. Further functional examination of the enzyme inhibitory affinities of recombinant PtPMEI1 and 39 in vitro and apoplastic patterns suggested a clustering of the type-I proPME in the regulation of the innate immunity by maintaining homeostasis of the pectin HG de-methylesterification (DME) in the cell wall. The coherent omics-wide survey of the fungi pathogen-induced PME-PMEIs and disturbed carbohydrate accumulation provide theoretical cues for in-depth mining of the biological significance of the underlying immune signaling networks within an apoplastic niche in trees.