Identification and Characterization of Pythium, Globisporangium, and Phytopythium Species Present in Floricultural Crops from Long Island, New York.

Several Pythium, Globisporangium, and Phytopythium species cause Pythium diseases in greenhouse floricultural crops, resulting in significant seasonal losses. Four hundred and eighteen Pythium, Globisporangium, and Phytopythium isolates from flowering crops, growing media, or bench and floor debris were collected from Long Island greenhouses or clinic samples between 2002 and 2013. Isolates were identified to species based on morphology and internal transcribed spacer barcoding. Twenty-two species of Pythium, Phytopythium, and Globisporangium were identified, with Globisporangium irregulare sensu lato (s.l.) being the most common. To determine the origin of inoculum during the 2011 cropping season, 11 microsatellite loci were analyzed in 124 G. irregulare s.l. isolates collected in four greenhouses and six previously collected from clinic samples. Cluster analyses grouped G. irregulare s.l. isolates into four groups: G. irregulare sensu stricto, plus three G. cryptoirregulare clusters. The population structure defined by greenhouse and host was found in two clades. Additionally, the population dynamics of G. irregulare s.l. isolates associated with Pelargonium spp. from 2011 to 2013 were examined using 85 isolates and nine informative microsatellite loci to assess inoculum survival over multiple cropping seasons. Although most isolates had unique genotypes, closely related genotypes were found in the same locations over different years. Our results indicate that G. irregulare s.l. inocula have local as well as remote origins. Isolates may be initially brought into ornamental operations from common sources, such as infected plant materials or infested potting mixes. Our results support the hypothesis that established strains can serve as inocula and survive in greenhouse facilities over multiple seasons.

Discriminatory simplex and multiplex PCR for four species of the genus Sclerotinia.

Sclerotinia sclerotiorum (Lib.) de Bary, S. minor Jagger, S. trifoliorum Eriks, and S. homoeocarpa F.T. Benn are the most relevant plant pathogenic species within the genus Sclerotinia because of their large range of economically important hosts, including tomato, peanut, alfalfa, and turfgrass, among others. Species identification based on morphological characteristics is challenging and time demanding, especially when one crop hosts multiple species. The objective of this study was to design specific primers compatible with multiplexing, for rapid, sensitive and accurate detection and discrimination among four Sclerotinia species. Specific primers were designed for the aspartyl protease gene of S. sclerotiorum, the calmodulin gene of S. trifoliorum, the elongation factor-1 alpha gene of S. homoeocarpa, and the laccase 2 gene of S. minor. The specificity and sensitivity of each primer set was tested individually and in multiplex against isolates of each species and validated using genomic DNA from infected plants. Each primer set consistently amplified DNA of its target gene only. DNA fragments of different sizes were amplified: a 264 bp PCR product for S. minor, a 218 bp product for S. homoeocarpa, a 171 bp product for S. sclerotiorum, and a 97 bp product for S. trifoliorum. These primer sets can be used individually or in multiplex for identification of Sclerotinia spp. in pure culture or from infected plants. The multiplex assay had a lower sensitivity limit than the simplex assays (0.0001 pg/µL DNA of each species). The multiplex assay developed is an accurate and rapid tool to differentiate between the most relevant plant pathogenic Sclerotinia species in a single PCR reaction.