Bruno Hostachy

Revisiting the Specificity of PCR Primers for Diagnostics of Xanthomonas citri pv. citri by Experimental and In Silico Analyses

Asiatic citrus canker disease, caused by Xanthomonas citri pv. citri, seriously impacts citrus production worldwide. Two pathogenic variants, A and A*/Aw, have been described within this pathovar. Two additional pathovars of X. citri with a limited geographic distribution and reduced pathogenicity, namely X. citri pvs. aurantifolii and bilvae, are also pathogenic to citrus and some rutaceous species. Rapid and reliable identification is required for these citrus pathogens, which are classified as a quarantine organism in citrus-producing countries. The specificity of nine polymerase chain reaction primers previously designed for the identification of X. citri pv. citri or citrus bacterial canker strains (both pvs. citri and aurantifolii) was assayed on a large strain collection (n = 87), including the two pathotypes of X. citri pv. citri, other genetic related or unrelated pathogenic xanthomonads, and saprophytic xanthomonads. This study gave congruent results with the original articles when testing the same strains or pathovars but the use of a broad inclusivity and exclusivity panel of strains highlighted new findings. Particularly, primers 2/3, 4/7, and KingF/R failed to provide amplification for three strains from the pathotype A*/Aw. Moreover, all pairs of primers detected at least one non-target strain. These data were supported by in silico analysis of the DNA sequences available from National Center for Biotechnology Information databases.

Development of a hydrolysis probe-based real-time assay for the detection of tropical strains of Fusarium oxysporum f. sp. cubense race 4

Fusarium oxysporum f. sp. cubense (Foc) is one of the most important threats to global banana production. Strategies to control the pathogen are lacking, with plant resistance offering the only long-term solution, if sources of resistance are available. Prevention of introduction of Foc into disease-free areas thus remains a key strategy to continue sustainable banana production. In recent years, strains of Foc affecting Cavendish bananas have destroyed plantations in a number of countries in Asia and in the Middle East, and one African country. One vegetative compatibility group (VCG), 01213/16, is considered the major threat to bananas in tropical and subtropical climatic conditions. However, other genetically related VCGs, such as 0121, may potentially jeopardize banana cultures if they were introduced into disease-free areas. To prevent the introduction of these VCGs into disease-free Cavendish banana-growing countries, a real-time PCR test was developed to accurately detect both VCGs. A previously described putative virulence gene was used to develop a specific combination of hydrolysis probe/primers for the detection of tropical Foc race 4 strains. The real-time PCR parameters were optimized by following a statistical approach relying on orthogonal arrays and the Taguchi method in an attempt to enhance sensitivity and ensure high specificity of the assay. This study also assessed critical performance criteria, such as repeatability, reproducibility, robustness, and specificity, with a large including set of 136 F. oxysporum isolates, including 73 Foc pathogenic strains representing 24 VCGs. The validation data demonstrated that the new assay could be used for regulatory testing applications on banana plant material and can contribute to preventing the introduction and spread of Foc strains affecting Cavendish bananas in the tropics.

A new semi-selective medium for the isolation of Xanthomonas axonopodis pv. dieffenbachiae, the etiological agent of anthurium bacterial blight

Aims:  Xanthomonas axonopodis pv. dieffenbachiae causes anthurium blight, which is regarded as the most threatening disease for the anthurium industry worldwide. The bacterium is listed as a quarantine pathogen in several regions, including Europe. We evaluated the use of Neomycin‐Cephalexin‐Trimethoprime‐pivMecillinam 4 (NCTM4) medium for its isolation.

First Report of Xanthomonas citri pv. citri-A Causing Asiatic Citrus Canker in Mayotte

Asiatic citrus canker, caused by Xanthomonas citri pv. citri, is a bacterial disease of major economic importance in tropical and subtropical citrus-producing areas. X. citri pv. citri pathotype A can cause severe infection in a wide range of citrus species and induces erumpent, callus-like lesions with water-soaked margins evolving to corky cankers and leading to premature fruit and leaf drop and twig dieback on susceptible/very susceptible cultivars. A chlorotic halo is typically visible around canker lesions on leaves and young fruit, but not on mature fruit and twigs. This quarantine organism can strongly impact both national and international citrus markets. Long distance dispersal is mainly through infected propagative material. Asiatic citrus canker occurs on most islands in the Southwest Indian Ocean region (Comoros, Mauritius, Reunion, Rodrigues, and Seychelles islands), but was not yet reported in Mayotte (EPPO-PQR available at http://www.eppo.int ). In May 2012, typical canker-like symptoms were observed on sweet orange (Citrus sinensis) groves on Mtsamboro islet and soon after on the main island of Mayotte, mostly on sweet oranges, but also on Tahiti limes (C. latifolia) and mandarins (C. reticulata). Eighty-one Xanthomonas-like strains were isolated using KC semi-selective medium (4) from disease samples collected from both commercial groves and nurseries on different Citrus species located all over the island. Sixteen Xanthomonas-like isolates were tentatively identified as X. citri pv. citri based on a specific PCR assay with 4/7 primers (3). All strains but the negative control, sterile water, produced an amplicon of the expected size similar to X. citri pv. citri strain IAPAR 306 used as positive control. Multilocus sequence analysis targeting six housekeeping genes (atpD, dnaK, efp, gltA, gyrB, and lepA) (1,2) fully identified three strains from Mayotte (LJ225-3, LJ228-1, and LJ229-11) as X. citri pv. citri (and not other xanthomonad pathovars pathogenic to citrus or host range-restricted pathotypes of pathovar citri), and more specifically as sequence type ST2 composed of pathotype A strains of X. citri pv. citri (2) (including all strains from the Southwest Indian Ocean region). Eight strains were inoculated by a detached leaf assay (2) to Mexican lime SRA 140 (C. aurantifolia), Tahiti lime SRA 58, sweet orange cv. Washington Navel, alemow SRA 779 (C. macrophylla), and tangor cv. Ortanique (C. reticulata × C. sinensis) and developed typical erumpent, callus-like tissue at wound sites for all Citrus species, fulfilling Kochs postulates. Xanthomonas-like yellow colonies were reisolated from symptoms produced by the eight strains inoculated on Mexican lime. Boiled bacterial suspensions were assayed by PCR with 4/7 primers (3) and produced the expected 468-bp amplicon in contrast with the negative control (sterile water). No lesions developed on the negative control consisting of inoculations by 10 mM tris buffer (pH 7.2). Citrus canker-free nurseries and grove sanitation should be implemented for decreasing the prevalence of Asiatic canker in this island territory. References: (1) N. F. Almeida et al. Phytopathology 100:208, 2010. (2) L. Bui Thi Ngoc et al. Int. J. Syst. Evol. Microbiol. 60:515, 2010. (3) J. S. Hartung et al. Phytopathology 86:95, 1996. (4) O. Pruvost et al. J. Appl. Microbiol. 99:803, 2005.

Genetic diversity of the Ralstonia solanacearum species complex in the Southwest Indian Ocean Islands

Epidemiological surveillance of plant pathogens based on genotyping methods is mandatory to improve disease management strategies. In the Southwest Indian Ocean (SWIO) islands, bacterial wilt (BW) caused by the Ralstonia solanacearum species complex (RSSC) is hampering the production of many sustainable and cash crops. To thoroughly analyze the genetic diversity of the RSSC in the SWIO, we performed a wide sampling survey (in Comoros, Mauritius, Reunion, Rodrigues, and Seychelles) that yielded 1,704 isolates from 129 plots, mainly from solanaceous crops. Classification of the isolates to the four major RSSC phylogenetic groups, named phylotypes, showed that 87% were phylotype I, representing the most prevalent strain in each of the SWIO islands. Additionally, 9.7% were phylotype II, and 3.3% were phylotype III; however, these isolates were found only in Reunion. Phylotype IV (2 isolates), known to be restricted to Indonesia-Australia-Japan, was reported in Mauritius, representing the first report of this group in the SWIO. Partial endoglucanase (egl) sequencing, based on the selection of 145 isolates covering the geographic and host diversity in the SWIO (also including strains from Mayotte and Madagascar), revealed 14 sequevars with Reunion and Mauritius displaying the highest sequevar diversity. Through a multilocus sequence analysis (MLSA) scheme based on the partial sequencing of 6 housekeeping genes (gdhA, gyrB, rplB, leuS, adk, and mutS) and 1 virulence-associated gene (egl), we inferred the phylogenetic relationships between these 145 SWIO isolates and 90 worldwide RSSC reference strains. Phylotype I was the most recombinogenic, although recombination events were detected among all phylotypes. A multilocus sequence typing (MLST) scheme identified 29 sequence types (STs) with variable geographic distributions in the SWIO. The outstanding epidemiologic feature was STI-13 (sequevar I-31), which was overrepresented in the SWIO and obviously reflected a lineage strongly adapted to the SWIO environment. A goeBURST analysis identified eight clonal complexes (CCs) including SWIO isolates, four CCs being geographically restricted to the SWIO, and four CCs being widespread beyond the SWIO. This work, which highlights notable genetic links between African and SWIO strains, provides a basis for the epidemiological surveillance of RSSC and will contribute to BW management in the SWIO.

The organization of proficiency testing in plant pathology (qualitative methods of analysis) according to the ISO/IEC 17043: example of the French national reference laboratory

The use of methods of analysis capable of producing reliable analytical results is a prerequisite to the effective control of quarantine plant pathogens. Proficiency testing is considered to be one of the most reliable ways to verify and coordinate analytical results. As a French national reference laboratory in plant pathology, the Anses Plant Health Laboratory organizes proficiency tests in order to ensure that officially approved laboratories (certified by government services) are capable of producing reliable analytical results for the detection of plant pathogens. Proficiency tests in plant pathology have a number of notable features including the processing of qualitative results. This paper presents the experience of the Anses Plant Health Laboratory’s Unit for Tropical Pests and Diseases (LSV-RAPT) as an organizer of proficiency tests in plant pathology. The LSV-RAPT has gained recognition for the methodology it has developed in the form of accreditation as a proficiency testing provider according to the ISO/IEC 17043. The methodology can be applied to many other disciplines that use qualitative detection methods.

First report of Xanthomonas hortorum pv. carotae causing bacterial leaf blight of carrot in Mauritius.

Bacterial blight of carrot (Daucus carota) is caused by Xanthomonas hortorum pv. carotae (4). The pathogen is seed transmitted and carrot seeds can be an important source of primary inoculum (2). A 2008-2009 outbreak of a disease resembling bacterial blight was observed in Mauritius in 10 ha of carrot crops, primarily in humid areas of the island, at an estimated incidence of 10%. Carrot leaves with angular, water-soaked leaf spots that turned necrotic were collected at Plaine Sophie, Mauritius in December 2008. Yellow, Xanthomonas-like colonies were isolated onto KC agar medium (3). MultiLocus sequence analysis (MLSA) with four genes (atpD, dnaK, efp, and gyrB) was performed as described previously (1) on five carrot strains together with two reference strains of X. hortorum pv. carotae (LMG 8643 and LMG 8644). The reference strains were identical. Of the five Mauritius strains, two (LG1-1 and LG1-4) were identical, and most closely related to, but distinct from, the reference strains (genetic distance of 0.02). The other three strains represented two sequence types identified as Xanthomonas sp. based on a phylogenetic tree derived from concatenated sequences, but were not related to any type strain. PCR assays with a 3S primer pair specific for X. hortorum pv. carotae (2) produced an amplicon of approximately 350 bp from isolates LG1-1, LG1-4, and each of the reference strains. A PCR assay with a 9B primer pair (2) yielded an amplicon of 0.9 kb for strains LG1-1, LG1-4, and LMG 8644, whereas LMG 8643 yielded an amplicon of approximately 2.0 kb (2). Foliage of 4-week-old plants (36 plants per strain) of the carrot cv. Senator F1 were spray inoculated with a suspension of each strain using an 18-h culture in sterile 0.01 M tris buffer (pH 7.2) with approximately 1 × 108 CFU/ml. Plants sprayed with tris buffer were used as a negative control treatment. Plants were incubated in a growth chamber at 26 ± 1°C at a relative humidity of 95 ± 5% and a photoperiod of 16 h. Water-soaked lesions that developed into necrotic areas were observed 12 to 15 days after inoculation of LG1-1, LG1-4, and the two reference strains. Bacteria were recovered from lesions onto KC medium (3) 3 weeks after inoculation with mean Xanthomonas populations of at least 1 × 107 CFU/lesion. Colonies with morphology typical of Xanthomonas were recovered and typed using atpD sequencing to fulfill Kochs postulates. Although Xanthomonas-like bacteria were isolated from symptomatic carrot leaves in Mauritius in 1989, the results of that study were not published. To our knowledge, this is the first report of molecular and pathological characterization of this pathogen in carrot crops in Mauritius. References: (1) L. Bui Thi Ngoc et al. Int. J. Syst. Evol. Microbiol. 60:515, 2010. (2) X. Q. Meng et al. Plant Dis. 88:1226, 2004. (3) O. Pruvost et al. J. Appl. Microbiol. 99:803, 2005. (4) L. Vauterin et al. Int. J. Syst. Bacteriol. 45:472, 1995.