Iron uptake and effect on growth and morphology of X. fastidiosa

Iron is an essential nutrient for bacteria, being involved in many metabolic processes. Despite its low solubility, bacteria present efficient and specific systems for uptake, utilization and storage of iron, meanwhile controlling metal concentration adequately to prevent potential toxic effects of free iron. Xylella fastidiosa is a Gram-negative bacterium which colonizes the xylem of a wide range of crops and wild species of plants worldwide. This bacterium is the agent of several diseases affecting economically important crops, such as citrus, grapevine and coffee. Among the proposed X. fastidiosa virulence mechanisms is the formation of biofilm which may occlude xylem vessels causing hydric stress. It is postulated that iron uptake might cause reduction of its concentration within the xylem of infected plants therefore constituting a virulence strategy during bacterial infection process. Our aims in this work were to investigate the process of iron uptake in X. fastidiosa and to evaluate the effect of iron concentration in the growth and morphology of this bacterium, expanding previous studies. For this we set to: (i) investigate the capacity of X. fastidiosa in producing siderophores, small biomolecules utilized for iron quelation; (ii) evaluate, under culture conditions at different iron concentrations, the expression profile of candidate genes that might be part of the iron stimulon; (iii) analyse the effect of iron concentration in growth and biofilm formation of X. fastidiosa. We observed that X. fastidiosa seems to produce a compound with iron quelating ability, such as a siderophore, and we point to a group of genes that might be involved in the synthesis of this compound. We confirmed that iron is necessary for growth of X. fastidiosa. At high concentrations of iron we observed higher biofilm production. Interestingly, we also observed that when grown in low iron concentration, X. fastidiosa secretes more exopolysaccharides (EPS) associated with the biofilm, suggesting a link between iron concentration and expression of an essential virulence factor to the infection process of X. fastidiosa. (AU)