Evaluation of Xylella fastidiosa genetic diversity by fAFPL markers

The first phytopathogenic bacterium with its DNA entirely sequenced is being detected and isolated from different host plants in several geographic regions. Although it causes diseases in cultures of economic importance, such as citrus, coffee, and grapevine little is known about the genetic relationships among different strains. Actually, all strains are grouped as a single species, Xylella fastidiosa, despite colonizing different hosts, developing symptoms, and different physiological and microbiological observed conditions. The existence of genetic diversity among X. fastidiosa strains was detected by different methodological techniques, since cultural to molecular methods. However, little is know about the phylogenetic relationships developed by Brazilian strains obtained from coffee and citrus plants. In order to evaluate it, fAFLP markers were used to verify genetic diversity and phylogenetic relationships developed by Brazilian and strange strains. fAFLP is an efficient technique, with high reproducibility that is currently used for bacterial typing and classification. The obtained results showed that Brazilian strains present genetic diversity and that the strains from this study were grouped distinctly according host and geographical origin like citrus-coffee, temecula-grapevine-mulberry and plum-elm.

Development of a scar marker for Pierce's Disease strains of Xylella fastidiosa

The objective of this research was to develop a primer for a polymerase chain reaction specific for Xylella fastidiosa strains that cause Pierce's Disease (PD) in grapes (Vitis vinifera). The DNA amplification of 23 different strains of X. fastidiosa, using a set of primers REP1-R (5'-IIIICGICGIATCCIGGC-3') and REP 2 (5'-ICGICTTATCIGGCCTAC-3') using the following program: 94 ºC/2 min; 35 X (94 ºC/1 min, 45 ºC/1 min and 72 ºC/1 min and 30 s) 72 ºC/5 min, produced a fragment of 630 bp that differentiated the strains that cause disease in grapes from the other strains. However, REP banding patterns could not be considered reliable for detection because the REP1-R and REP 2 primers correspond to repetitive sequences, which are found throughout the bacterial genome. The amplified product of 630 bp was eluted from the agarose gel, purified and sequenced. The nucleotide sequence information was used to identify and synthesize an specific oligonucleotide for X. fastidiosa strains that cause Pierce's Disease denominated Xf-1 (5'-CGGGGGTGTAGGAGGGGTTGT-3') which was used jointly with the REP-2 primer at the following conditions: 94 ºC/2 min; 35 X (94 ºC/1 min, 62 ºC/1 min; 72 ºC/1 min and 30 s) 72 ºC/10 min. The DNAs isolated from strains of X. fastidiosa from other hosts [almond (Prumus amygdalus), citrus (Citrus spp.), coffee (Coffea arabica), elm (Ulmus americana), mulberry (Morus rubra), oak (Quercus rubra), periwinkle wilt (Catharantus roseus), plums (Prunus salicina) and ragweed (Ambrosia artemisiifolia)] and also from other Gram negative and positive bacteria were submitted to amplification with a pair of primers Xf-1/REP 2 to verify its specificity. A fragment, about 350 bp, was amplified only when the DNA from strains of X. fastidiosa isolated from grapes was employed.