Dolores Rodrı́guez-Jurado scite author profile

Pathogen-free certified planting material and accurate detection of Verticillium dahliae pathotypes infecting the plant are key components of successful management of Verticillium wilt of olive. Use of a nested-polymerase chain reaction (PCR) procedure developed in earlier studies for in planta detection of the defoliating (D) and nondefoliating (ND) V. dahliae pathotypes resulted in ambiguous detection of the pathogen in some cases, due to heterologous amplification of the D-associated marker in ND-infected olive plants. In the present study, an improved procedure was developed that eliminates ambiguity and reduces time and cost for detection of D and ND V. dahliae in olive. The improved procedure is based on the simultaneous amplification of both an ND- and a new D-specific marker by means of duplex, nested PCR. The procedure was effective in the rapid and unequivocal detection of the D and ND V. dahliae in both artificially inoculated, own-rooted olive plants and naturally infected adult olive trees of different cultivar, age, and growing conditions. Furthermore, the duplex, nested-PCR procedure detected simultaneously the D and ND pathotypes in adult olive trees naturally infected by both pathotypes and in young olive plants that were double-inoculated with D and ND isolates under controlled conditions.

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Genetic and Virulence Diversity in Verticillium dahliae Populations Infecting Artichoke in Eastern-Central Spain

Jiménez-Dı́az¹,

et al. 2006

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Severe Verticillium dahliae attacks have occurred in artichoke crops in the Comunidad Valenciana region of eastern-central Spain since the late 1990s. Knowledge of genetic and virulence diversity in the pathogen population is a key factor for the management of the disease through disease risk assessment as well as development and use of resistant cultivars. V. dahliae isolates from artichoke (109 isolates) and cotton (three isolates) in that region were characterized by vegetative compatibility grouping (VCG), and specific polymerase chain reaction assays using three sets of primer pairs that differentiate the cotton-defoliating (D) and -nondefoliating (ND) V. dahliae pathotypes. In all, 35 and 39 V. dahliae isolates representative of the identified VCGs and geographic origins were tested for virulence to artichoke cvs. Nun 6374 and Nun 9444, and cotton cv. Acala SJ-2, respectively. Four VCGs were identified among 107 artichoke isolates, and 2 isolates were heterokaryon self-incompatible: VCG1A (one isolate), VCG2A (31 isolates), VCG2B (72 isolates), and VCG4B (three isolates). The three cotton isolates were VCG1A. Isolates in VCG2B were distributed across the region and were the most prevalent isolates in the northern part. Conversely, 83.9% of isolates in VCG2A were recovered from the southern part of the region. Two subgroups of isolates were identified in VCG2B based on heterokaryon compatibility with either international or local tester isolates, which further showed diversity in the amplification of 334- and 824-bp DNA fragments which are markers of the D and ND pathotypes, respectively. Virulence of isolates to artichoke and cotton correlated with VCG but the pattern of correlation varied with the host. VCG1A isolates from artichoke and cotton induced defoliation in cotton but not in artichoke. Collectively, isolates of VCG2B and VCG4B were the most virulent and isolates of VCG1A or HSI were the least virulent to artichoke; but isolates of VCG1A were more virulent to cotton than those of any other VCG. Also, molecular subgrouping in VCG2B determined by amplification of the 334- and 824-bp markers correlated with virulence of isolates to the two hosts tested.

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Detection of the defoliating and nondefoliating pathotypes of Verticillium dahliae in artificial and natural soils by nested PCR

et al. 2005

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In Spain, Verticillium wilt, caused by Verticillium dahliae, is the most important disease of cotton and olive. Isolates of V. dahliae infecting these crops can be classified into highly virulent, defoliating (D), and mildly virulent, nondefoliating (ND), pathotypes. Infested soil is the primary source of inoculum for Verticillium wilt epidemics in cotton and olive, and severity of disease relates to the prevailing V. dahliae pathotype. In this work we have adapted the use of previously developed primer pairs specific for D and ND V. dahliae for the detection of these pathotypes by nested PCR in artificial and natural soils. Success in the detection procedure depends upon efficiency in extracting PCR-quality DNA from soil samples. We developed an efficient DNA extraction method from microsclerotia infesting the soil that includes the use of acid washed sand during the grinding process and skimmed milk to avoid co-purification of Taq-polymerase inhibitors with DNA. The specific nested-PCR procedure effectively detected 10 or more microsclerotia per gram of soil. The detection procedure has proven efficient when used with a naturally infested soil, thus demonstrating usefullness of the diagnostic method for rapid and accurate assessment of soil contamination by V. dahliae pathotypes.

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Detection of the nondefoliating pathotype of Verticillium dahliae in infected olive plants by nested PCR

et al. 2001

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An increasing incidence and distribution of verticillium wilt has occurred in the last few years in newly established olive orchards in southern Spain. This spread of the disease may result from use of Verticillium dahliae-infected planting material. The early in planta detection of the pathogen would aid the implementation of certification schemes for pathogen-free planting material. In this work, a nested polymerase chain reaction (PCR) method was developed for the in planta detection of the nondefoliating (ND) V. dahliae pathotype, aimed especially at nurseryproduced olive plants. For this purpose, specific primers were designed from the sequence of a 1958-bp random amplified polymorphic DNA (RAPD) marker of ND V. dahliae, and a procedure for the extraction of PCR-quality total genomic DNA from infected root and stem tissues of young olive plants was tested and further optimized. Nested PCR assays detected ND V. dahliae in 4-to 14-month-old artificially infected plants of three olive cultivars. The ND-specific PCR product was not amplified from total genomic DNA extracted from olive plants infected with the defoliating V. dahliae pathotype. Detection of the ND pathotype was effective from the very earliest moments following artificial inoculation of olive plants with a V. dahliae conidial suspension. Also, detection was achieved in inoculated, though symptomless, olive plants as well as in plants that were symptomatic but became symptomless by 217 days after inoculation.

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Quantitative monitoring of colonization of olive genotypes by Verticillium dahliae pathotypes with real-time polymerase chain reaction

Mercado‐Blanco¹,

Collado-Romero²,

Parrilla-Araujo³

et al. 2003

Physiological and Molecular Plant Pathology

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Spatiotemporal Analysis of Spread of Infections by Verticillium dahliae Pathotypes Within a High Tree Density Olive Orchard in Southern Spain

Navas‐Cortés¹,

Landa²,

Mercado‐Blanco³

et al. 2008

Phytopathology®

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The development of Verticillium wilt epidemics in olive cv. Arbequina was studied from November 1999 to May 2003 in a drip-irrigated, nontillage orchard established in a soil without a history of the disease at Córdoba, southern Spain. Disease incidence measured at 1-month-intervals increased from 0.2 to 7.8% during this period. Verticillium dahliae infecting the trees was characterized as defoliating (D) or nondefoliating (ND) pathotypes by a specific, multiplex-polymerase chain reaction (PCR) assay. Of the symptomatic trees, 87.2 and 12.8% were infected by the D or ND pathotypes, respectively. Dynamics of disease incidence were described by a generalized logistic model with a multiple sigmoid pattern. In the fitted model, the infection rate was highest in the winter to spring period and decreased to minimum values in the summer to fall period. Binary data of disease incidence was analyzed for point pattern and spatial correlation, either directly or after parsing them in contiguous quadrats. Overall, ordinary runs analysis indicated a departure from randomness of disease within rows. The binomial index of dispersion, interclass correlation, and Taylor's power law for various quadrat sizes suggested aggregation of diseased trees within the quadrat sizes tested. Spatial analysis by distance indices showed a nonrandom arrangement of quadrats containing infected trees. Spatial pattern was characterized by the occurrence of several clusters of infected trees. Increasing clustering over time was generally suggested by stronger values of clustering index over time and by the increase in the size of patch clusters. Significant spatial association was found in the clustering of diseased trees over time across cropping seasons; however, clustering was significant only for infections by D V. dahliae, indicating that infections by the D pathotype were aggregated around initial infections. The number and size of clusters of D V. dahliae-infected trees increased over time. Microsatellite-primed PCR assays of a representative number of V. dahliae isolates from diseased trees indicated that the majority of infecting D isolates shared the fingerprinting profile with D V. dahliae isolated from soil of a naturally infested cotton field in close proximity to the orchard, suggesting that short distance dispersal of the pathogen from this soil to the olive orchard may have occurred.

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Vegetative compatibility of cotton-defoliating Verticillium dahliae in Israel and its pathogenicity to various crop plants

et al. 2008

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Verticillium dahliae isolates recovered from a new focus of severe Verticillium wilt of cotton in the northeast of Israel were tested for vegetative compatibility using nitrate non-utilizing (nit) mutants and identified as VCG1, which is a new record in Israel. Other cotton isolates of V. dahliae from the northern and southern parts of the country were assigned to VCG2B and VCG4B, respectively. VCG1 isolates induced severe leaf symptoms, stunting and defoliation of cotton cv. Acala SJ-2, and thus were characterized as the cotton-defoliating (D) pathotype, whereas isolates of VCG2B and VCG4B were confirmed as the earlier described defoliatinglike (DL) and non-defoliating (ND) pathotypes, respectively. This is the first record of the Dpathotype in Israel. The host range of representative isolates of each VCG-associated pathotype was investigated using a number of cultivated plants. Overall, the D isolates were more virulent than DL isolates on all tested host plants, but the order of hosts (from highly susceptible to resistant) was the same: okra (Hibiscus esculentus local cultivar), cotton (Gossypium hirsutum cv. Acala SJ2), watermelon (Citrullus lanatus cv. Crimson Sweet), safflower (Carthamus tinctorius cv. PI 251264), sunflower (Helianthus annuum cv. 2053), eggplant (Solanum melongena cv. Black Beauty), and tomato (Lycopersicon esculentum cv. Rehovot 13). The pattern of virulence of ND isolates differed from that of D and DL isolates, so that the former were highly virulent on eggplant but mildly virulent on cotton. Tomato was resistant to all cotton V. dahliae isolates tested. RAPD and specific PCR assays confirmed that the D isolates from Israel were similar to those originating from other countries.

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