Engineering pathogen-inducible promoters for conferring disease resistance in tomato

Plant diseases pose a significant threat to global crop production. Most disease resistance genes used in crop breeding programs encode nucleotide-binding leucine-rich repeat receptors (NLRs) that are limited in pathogen specificity and durability. In this study, we leveraged synthetic biology to develop an inducible broad-spectrum resistance in tomatoes. Constitutive expression of autoactive NLRs in plants leads to robust resistance against multiple pathogens but significantly stunts growth. We expressed autoactive NLRs under the control of pathogen-inducible (PI) promoters to mitigate the fitness costs. Taking advantage of extensive, new genomic and transcriptomic resources, we identified PI promoters that responded to multiple pathogens but not abiotic stress. We further validated functionality of predicted elements through a promoter luciferase assay. We generated significant resistance in transgenic tomatoes but we also encountered unwanted expression induction of the native promoter regions in flowers which led to lethal fruit development. Thus, we pursued promoter engineering for fine-tuning the induction. We identified cis-regulatory regions responsible for pathogen-inducibility through promoter bashing experiments and recombined the native promoter with the inducible part and the core promoter. Furthermore, we rationally created synthetic promoters showing a gradient of expression levels, which will allow for selection for transgenic tomatoes with the best performance. We found that the spacing between functional sequences, repeat number of inducible sequences, and core promoters all influence the outcome of engineering. Our study outlines a framework for developing broad-spectrum synthetic immune constructs with reduced fitness cost and provides examples of pathogen-inducible promoter engineering.