RESUMEN
Xylella fastidiosa is the etiological agent of Plum Leaf Scald (Greco et al. 2021). The disease was first reported in Argentina (Fernandez-Valiela et al. 1954) and then Brazil and Paraguay (French et al. 1978). In the USA, Plum Leaf Scald has been reported in the Southeastern United States (Wells et al. 1981a) and California (Hernandez-Martinez et al. 2009). In August 2021, during the Stone Fruit Survey of FY2020, plum trees (Mexican variety, Prunus mexicana) with symptoms of leaf scald, were observed in a Central Texas orchard with approximately 7% of trees exhibiting symptoms. Leaf margins were asymmetrically scorched, with necrotic areas that transitioned into chlorotic and healthy green tissues. To detect the presence of the pathogen, leaf sample petioles were tested using a double-antibody sandwich (DAS) ELISA® with X. fastidiosa specific antiserum (Agdia Inc., Elkhart, IN) according to manufacturer's guidelines. X. fastidiosa was detected in 20 of the 35 symptomatic samples. To confirm ELISA results, total DNA was extracted from the plant samples using the Plant DNeasy® kit (Qiagen Co. Hilden, Germany) following the manufacturer's protocol. All 20 ELISA-positive samples tested positive in a X. fastidiosa-specific real time PCR assay, using the primers XF1F and XF1R and probe XF1p (Schaad et al. 2002). Moreover, the ELISA-negative samples were also negative for PCR assay. Symptomatic samples were used to isolate the pathogen. Samples were debarked, surface-sterilized and xylem fluid collected. The fluid was gently imprinted on buffered charcoal yeast extract (BCYE) (Wells et al. 1981b) or periwinkle wilt modified (PWM) agar plates (Summer et al. 2010). After 10 days of incubation, individual colonies were observed. The colonies were slightly convex, white, opalescent, mucoid, circular with entire margins and with smooth surfaces on both media plates. Isolated colonies were triple-streak single colony purified and archived. Genomic DNA was extracted from four purified isolates using the DNeasy Blood and Tissue Qiagen® Kit, to conduct conventional PCR using HL5/HL6 (Francis et al. 2006), which identified the isolates as X. fastidiosa. Using the 16S rRNA primer pair U3/U4 (James 2010), amplicons were sequenced and compared against the NCBI database using the BLASTn algorithm. Comparative sequence analysis of amplicons from the four isolates were identical and indicated that the isolates were 100% identical to X. fastidiosa subsp. multiplex RIV5 (CP064326.1) from cherry plum, and IVIA5901 (CP047134.1) from almond. The sequences of all four isolates were deposited into NCBI GenBank, with the accession numbers OM617940 (467), OM617941 (470), OM617942 (471) and OM617943 (468). To our knowledge, this is the first report of X. fastidiosa associated with plum leaf scald in Texas, extending the geographical range of this important bacterial disease, in the Southern United States. This study highlights the importance of routine scouting of agricultural settings with a view to assessing and detecting early threats from either pests or disease and implementing relevant management strategies.
RESUMEN
The predicted repertoire of type III secretion system effectors (T3SEs) in Erwinia tracheiphila, causal agent of cucurbit bacterial wilt, is much larger than in xylem pathogens in the closely related genera Erwinia and Pantoea. The genomes of strains BHKY and SCR3, which represent distinct E. tracheiphila clades, encode at least 6 clade-specific and 12 shared T3SEs. The strains expressed the majority of the T3SE genes examined in planta. Among the shared T3SE genes, eop1 was expressed most highly in both strains in squash (Cucurbita pepo) and muskmelon (Cucumis melo) but the clade-specific gene avrRpm2 was expressed 40- to 900-fold more than eop1 in BHKY. The T3SEs AvrRpm2, Eop1, SrfC, and DspE contributed to BHKY virulence on squash and muskmelon, as shown using combinatorial mutants involving six T3SEs, whereas OspG and AvrB4 contributed to BHKY virulence only on muskmelon, demonstrating host-specific virulence functions. Moreover, Eop1 was functionally redundant with AvrRpm2, SrfC, OspG, and AvrB4 in BHKY, and BHKY mutants lacking up to five effector genes showed similar virulence to mutants lacking only two genes. The T3SEs OspG, AvrB4, and DspE contributed additively to SCR3 virulence on muskmelon and were not functionally redundant with Eop1. Rather, loss of eop1 and avrB4 restored wild-type virulence to the avrB4 mutant, suggesting that Eop1 suppresses a functionally redundant effector in SCR3. These results highlight functional differences in effector inventories between two E. tracheiphila clades, provide the first evidence of OspG as a phytopathogen effector, and suggest that Eop1 may be a metaeffector influencing virulence. [Formula: see text] Copyright © 2022 The Author(s). This is an open access article distributed under the CC BY 4.0 International license.
Asunto(s)
Cucurbita , Erwinia , Proteínas Bacterianas/genética , Proteínas Bacterianas/metabolismo , Cucurbita/microbiología , Erwinia/genética , Erwinia/metabolismo , Enfermedades de las Plantas/microbiología , Sistemas de Secreción Tipo III/genética , XilemaRESUMEN
Strains of Erwinia tracheiphila, causal agent of bacterial wilt of cucurbits, are divided into distinct clades. Et-melo clade strains wilt Cucumis spp. but not Cucurbita spp., thus exhibiting host specificity, whereas Et-C1 clade strains wilt Cucurbita spp. more rapidly than Cucumis melo, thus exhibiting a host preference. This study investigated the contribution of the effector proteins Eop1 and DspE to E. tracheiphila pathogenicity and host adaptation. Loss of eop1 did not enable Et-melo strains to infect squash (Cucurbita pepo) or an Et-C1 strain to induce a more rapid wilt of muskmelon (Cucumis melo), indicating that Eop1 did not function in host specificity or preference as in the related pathogen E. amylovora. However, overexpression of eop1 from Et-melo strain MDCuke but not from Et-C1 strain BHKY increased the virulence of a BHKY eop1 deletion mutant on muskmelon, demonstrating that the Eop1 variants in the two clades are distinct in their virulence functions. Loss of dspE from Et-melo strains reduced but did not eliminate virulence on hosts muskmelon and cucumber, whereas loss of dspE from an Et-C1 strain eliminated pathogenicity on hosts squash, muskmelon, and cucumber. Thus, the centrality of DspE to virulence differs in the two clades. Et-melo mutants lacking the chaperone DspF exhibited similar virulence to mutants lacking DspE, indicating that DspF is the sole chaperone for DspE in E. tracheiphila, unlike in E. amylovora. Collectively, these results provide the first functional evaluation of effectors in E. tracheiphila and demonstrate clade-specific differences in the roles of Eop1 and DspE.[Formula: see text] Copyright © 2021 The Author(s). This is an open access article distributed under the CC BY 4.0 International license.
Asunto(s)
Cucumis sativus , Erwinia , Enfermedades de las Plantas , VirulenciaRESUMEN
Glutamicibacter sp. FBE-19 was isolated based on its strong antagonism to the cucurbit bacterial blight pathogen Erwinia tracheiphila on plates. Members of the Glutamicibacter genus can promote plant growth under saline conditions and antagonize fungi on plates via chitinolytic activity; however, their production of antibacterial compounds has not been examined. Here, we report the genome sequence of strain FBE-19. The genome is 3.85 Mbp with a G+C content of 60.1% and comprises 3,791 genes. Genes that may contribute to its antagonistic activity include genes for the secondary metabolites stenothricin, salinosporamide A, a second ß-lactone compound, and a carotenoid. The Glutamicibacter sp. FBE-19 genome data may be a useful resource if this strain proves to be an effective biocontrol agent against E. tracheiphila.