Study of Rapid Alkalinization Factor (RALF)genes as plant susceptibility agents during plant-pathogen interaction in strawberry

Rapid Alkalinization Factor (RALF) are cysteins-rich peptides ubiquitous in plant kingdom. They play multiple roles as hormone signals and recently their involvement in host-pathogen crosstalk as negative regulator of immunity in Arabidopsis has also been recognized. In addition, RALF homologue peptides are secreted by different fungal pathogens as effectors during early stages of infections. The aim of this work was to characterize RALF genes as susceptibility factors during plant pathogen interaction in strawberry. For this, the genomic organization of the RALF gene families in the octoploid strawberry (Fragaria × ananassa) and the re-annotated genome of Fragaria vesca were described , identifying 13 member in F. vesca (FvRALF) and 50 members in F. x ananassa (FaRALF). The changes in expression of fruit FaRALF genes was investigated upon infection with C.acutatum and B. cinerea showing that, among RALF genes expressed in fruit, FaRALF3 was the only one upregulated by fungal infection in the ripe stage. A role of FaRALF3 as susceptibility gene was then assessed trough Agrobacterium-mediated transient FaRALF3 overexpression and silencing in fruits, revealing that FaRALF3 expression promotes fungal growth and hyphae penetration in host tissues. In silico analysis was used to identify distinct pathogen inducible elements upstream of the FaRALF3 gene. Agroinfiltration of strawberry fruit with deletion constructs of the FaRALF3 promoter identified a 5’ region required for FaRALF3 expression in fruit, but failed to identify a region responsible for fungal induced expression. Furthermore, FaRALF3 and strawberry receptor FERONIA (FaMRLK47) were heterologously expressed in E. coli in order to purify active proteins forms and study RALF-FERONIA interaction in strawberry. However, it was not possible to obtain pure and active proteins. Finally RNAi transgenic plants silenced for the FvRALF13 gene were genotypically and phenotypically characterized suggesting a role of FvRALF13 in flowering time regulation and reproductive organs development.

Genome-wide analysis of G-type lectin genes in Fragaria vesca and functional characterization of FaMBL1 gene in defense response of F. × ananassa to fungal pathogens

Strawberry (Fragaria × ananassa) is an important soft fruit but easily to be infected by pathogens. Anthracnose and gray mold are two of the most destructive diseases of strawberry which lead to serious fruit rot. The first chapter introduced strawberry anthracnose caused by Colletotrichum acutatum. The infection strategy, disease cycle and management of C. acutatum on strawberry were reported. Likewise, the second chapter summarized the infection strategy of Botrytis cinerea and the defense responses of strawberry. As we already know white unripe strawberry fruits are more resistant to C. acutatum than red ripe fruits. During the interaction between strawberry white/red fruit and C. acutaum, a mannose binding lectin gene, FaMBL1, was found to be the most up-regulated gene and induced exclusively in white fruit. FaMBL1 belongs to the G-type lectin family which has important roles in plant development and defense process. To get insight into the role of FaMBL1, genome-wide identification was carried out on G-type lectin gene family in Fragaria vesca and the results were showed in chapter 3. G-type lectin genes make up a large family in F. vesca. Active expression upon biotic/abiotic stresses suggested a potential role of G-lectin genes in strawberry defenses. Hence, stable transgenic strawberry plants with FaMBL1 gene overexpressed were generated. Transformed strawberry plants were screened and identified. The results were showed in chapter 4, content of disease-related phytohormone, jasmonic acid, was found decreased in overexpressing lines compared with wild type (WT). Petioles inoculated by C. fioriniae of overexpressing lines had lower disease incidence than WT. Leaves of overexpressing lines challenged by B. cinerea showed remarkably smaller lesion diameters compared with WT. The chitinase 2-1 (FaChi2-1) showed higher expression in overexpressing lines than in WT during the interaction with B. cinerea, which could be related with the lower susceptibility of overexpressing lines.