A novel stress-inducible dCas9 system for solanaceous plants

Conditional manipulation of gene expression is essential in plant biology, yet a simple stimuli-based inducible system for regulating any plant gene is lacking. Here, we present an innovative stress-inducible CRISPR/dCas9based gene-regulatory toolkit tailored for intentional gene regulation in solanaceous plants. We have translationally fused the transmembrane domain of a tomato membrane-bound NAC transcription factor with dCas9 to utilize the reversible-tethering-based activation mechanism. This system sequesters dCas9 to the plasma membrane under normal conditions and allows membrane detachment in response to heat induction and NLSmediated nuclear transfer, enabling stress-inducible gene regulation. Transient assays with tomato codonoptimized dCas9-assisted inducible CRISPR activation and interference systems confirmed their superior ability on transcriptional control, rapid induction, and reversibility after stimulus withdrawal in solanaceous plants. The transformative potential of the toolkit was exemplified by enhancing tomato immunity against bacterial speck disease under elevated temperatures by precisely regulating crucial salicylic acid signalling components, SlCBP60g and SlSARD1. Additionally, it was instrumental in engineering heat-stress tolerance in tomato plants through multiplex activation of heat-responsive transcription factors, SlNAC2 and SlHSFA6b. These findings demonstrate the unprecedented temporal control offered by this novel stress-inducible toolkit over geneexpression dynamics, paving the way for favourable manipulation of complex traits in environmentallychallenged crops.