Biochemistry and functional characterization of Xylella fastidiosa XadA3 adhesin.

Adhesion is a widely conserved mechanism of virulence among Gram-negative bacteria that is used by several pathogens to colonize their hosts, being the first step in biolfilm development. A variety of appendages and proteins are involved in bacterial adhesion, such as pili, fimbriae, fimbrial and afimbrials adhesins. The phytopathogen Xylella fastidiosa, causal agent of important diseases such as Pierce\'s disease of grapevines, citrus variegated chlorosis and olive quick decline syndrome, harbours on its surface several of these structures that are potentially responsible for efficient colonization of insect vectors and plant hosts. Among the afimbrial adhesins encoded in the genome of this bacterium, three XadAs (XadA1, Hsf/XadA2 and XadA3) are classified as trimeric autotransporters. Data from the literature suggest that XadA1 and XadA2 are important for biofilm formation, but XadA3 function has not been yet investigated. In this work, we aimed to biochemically and functionally characterize the XadA3 protein and gather additional information about the role played by XadA1 and XadA2 in X. fastidiosa adhesion and virulence. Using immunodetection with a polyclonal anti-XadA3 antibody, we have demonstrated that this protein localizes to the bacterial surface and mediates intercellular adhesion. Phenotypic characterization of the deletion mutants of XadA adhesins encoded genes revealed that the ΔxadA3 mutant has reduced cell aggregation capacity and biofilm formation when compared to both ΔxadA1 and ΔxadA2 mutants as well as to Temecula wild type strain. Deletion of the xadA genes marginally affects the global gene expression profile assessed by RNA-seq of the mutant strains compared to the wild-type strain, eventhough an increase in lipase/esterase transcripts levels was observed in the mutant strains. It has been reported that these enzymes appear to participate in the degradation of plant tissue that is associated with symptoms of Pierce\'s disease of grapevines. The deletion of xadA3 results in a phenotype of hypervirulence in grapevines but also of deficiency in insect-vector transmission. The results obtained in this work evidenced the important role played by XadAs adhesins, particularly XadA3, in X. fastidiosa intercellular adhesion, biofilm development and virulence. (AU)