To deliver on the aims above, we applied a multidisciplinary approach combining multiphoton single-cell ablation, laser-scanning confocal imaging, promoter–reporter lines with nuclear-localized fluorescent markers, RNA-seq, pyrolysis–GC–MS, and transmission electron microscopy (TEM).
We discovered, when plant roots are attacked by cyst nematodes, they rapidly induce localized ectopic lignin deposition as a defense mechanism. To disentangle the mechanical component of this response from pathogen-derived signals, we mimicked nematode-induced mechanical injury using highly precise multiphoton laser ablation. This revealed that ectopic lignin deposition is a cell-specific phenomenon, occurring in adjacent cells within ~ 10 hours of injury.
Reporter analyses revealed coordinated induction of the phenylpropanoid pathway that drives lignin biosynthesis after mechanical damage. In Arabidopsis roots, endodermal cells surrounding the vascular cylinder were the most responsive, while the epidermis (outermost layer) showed minimal activation. Pyrolysis-GC-MS analysis further demonstrated that the composition of ectopically induced lignin differs from that in undamaged tissues, consistent with enhanced resistance to pathogens. RNAseq analysis identified several MYB transcription factors potentially regulating lignin biosynthesis during mechanical damage. We focused on one transcription factor, MYB15 for functional characterisation using promoter–reporter lines, knockout mutants, and overexpression lines. Nematode infection assays confirmed that overexpression lines displayed increased resistance, as supported by phenotypic assessments and ultrastructural TEM analysis.
Overall, we provide a high-resolution, spatiotemporal map of injury-induced lignification in roots. The response is strongest in the endodermis (and cortex), while cells of the vascular cylinder remain available for secondary growth, allowing plants to fortify tissues against nematodes without sacrificing developmental capacity. These insights point to tractable regulatory nodes for engineering durable, tissue-targeted resistance.