Plant health is a major target in breading programs because crops are under constant biotic stress, and climate change is exacerbating pests and disease negative impacts in agriculture. Obtaining crop varieties armed with better defences is a potential strategy to reduce losses from biotic attacks. Plant cell walls perform crucial roles on many physiological processes, and under biotic stress, play crucial defensive roles as protecting barrier, as well as a source of integrity signalling molecules. Plant immunity has evolved a complex multi-layered system which first line of defence is initiated by conserved molecular patterns coming from pathogens, named pathogen-associated molecular patterns or PAMPs, or from their own corrupted cell walls due to pathogen invasion, named damaged-associated molecular patterns or DAMPs. Accumulating evidence from cell wall mutants has unveiled several components and mechanisms of plant innate immunity under biotic stresses, mostly in Arabidopsis, but still little is known from species with agronomic interest as strawberry. Our group has an established strawberry transgenic collection of cell wall mutants. Among them, RNAseq expression profiles of FaPG1 mutants has shown downregulation of other cell wall related genes than FaPG1 [1], but the mechanisms underneath required further investigation. FaPG genes code for enzymes with endo-PG activity related to oligogalacturonic acid (OGA) release, which would be associated to the changes in gene expression of other cell wall genes than FaPG. In this work, postharvest assays of FaPG1 fruits showed not only the increased fruit firmness typical of this mutant, but a better resistance to fungal infections by Botrytis cinerea, enhancing fruit shelf life in comparison with control fruits. OGAs are well known molecules with DAMP activity, and the alteration of quantity and/or structure of OGAs in this FaPG1 lines could be related to the increased resistance to B. cinerea. Then, next steps will be to determine whether the differential biotic resistance of this transgenic strawberry line is due to modified DAMPs and assess its potential use as strategic tools to enhance plant resistance in strawberry crops.

References

1. Paniagua et al (2020). Elucidating the role of polygalacturonase genes in strawberry fruit softening. Journal of Experimental Botany, 71(22), 7103-7117.

Acknowledgments

This study was supported by the project PID2020-118468RB-C21, Ministerio de Ciencia e Innovación of Spain and B1-2020_09 funds from the Universidad de Málaga. I would like to thank David Vela for kindly provide the Botrytis cinerea strain B05.10.