First Report of Root Rot of Bean and Soybean Caused by Rhizoctonia zeae in Turkey

To determine the species of Rhizoctonia on bean and soybean plants grown in Samsun (Turkey), field surveys were performed at 104 locations during 2001 and 2002. Rhizoctonia spp. were obtained from isolations from the necrotic lesions on the hypocotyl and rhizosphere soils. Species were identified according to Ogoshi (3) on the basis of hyphal and colony morphology and anastomosis reaction with known tester isolates (provided by M. Hyakumachi, Gifu University, Japan). Fifty Rhizoctonia spp. isolates obtained from these locations were identified as Rhizoctonia zeae (teleomorph Waitea circinata var. zeae). Nine of the 27 bean isolates and 8 of the 23 soybean isolates were recovered from plant tissues. These isolates had optimum temperature (32°C) for growth. Colonies were orange when young, becoming salmon colored with age. Sclerotia formed both on the agar surface or submerged in the medium. Superficial sclerotia were more uniform and nearly spherical, mostly 0.2 to 0.5 mm in diameter, and they were first orange and then turned brown. Pathogenicity was tested with three R. zeae isolates grown on sterile oat seeds at 25°C for 10 days. Bean and soybean seedlings grown in 1-liter plastic pots containing sterile potting mix (field soil/composted manure/sand 2:2:1 [v/v]) at true-leaf stage were inoculated by placing five infested oat seeds adjacent to the roots. Sterile oat seeds were used for controls. After 3 to 4 weeks of incubation at 17 to 25°C in a glasshouse, roots of the plants were cleaned with tap water and evaluated for disease severity. Four replicate pots were used for each isolate/plant combination. All isolates produced superficial brown lesions on roots and hypocotyls similar to those observed on plants used for isolations and root growth declined. R. zeae was reisolated from the lesions on all bean and soybean plants used for the pathogenicity test. While R. zeae was previously reported from Johnsongrass roots (1) and corn kernels (2), to our knowledge, this is the first report of R. zeae isolated from bean and soybean plants and rhizosphere soils in Turkey. References: (1) E. Demirci, and C. Eken. Plant Dis. 83:200, 1999. (2) E. Demirci and S. Kordali. Plant Dis. 83:879, 1999. (3) A. Ogoshi. Rev. Plant. Prot. Res. 8:93, 1975.

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First Report of Pathogenic Association Between Fusarium graminearum and Soybean

Plant Disease ◽

10.1094/pdis.2004.88.2.220a ◽

2004 ◽

Vol 88 (2) ◽

pp. 220-220 ◽

Cited By ~ 38

Author(s):

R. N. Pioli ◽

L. Mozzoni ◽

E. N. Morandi

Keyword(s):

Fusarium Graminearum ◽

Fusarium Species ◽

Block Design ◽

Phytopathogenic Fungi ◽

Fungal Mycelium ◽

First Report ◽

Interveinal Chlorosis ◽

Soybean Seedlings ◽

Randomized Block Design ◽

Soybean Plants

Fusarium graminearum, a pathogen of wheat and corn, was reported recently as a saprophytic fungus colonizing soybean (Glycine max L. Merr.) fruits and seeds at R7 in Argentina (2). To evaluate the capacity of F. graminearum obtained from stem and seeds of symptomatic soybean plants that cause disease on soybean seedlings, isolates were obtained during the 2001 to 2002 growing season from: (i) the basal one-third of stems from field-grown soybean plants, collected at R5, with light brown external and internal discoloration and leaves with interveinal chlorosis; and (ii) soybean seeds with pink tegument. The pathogen was isolated on potato glucose agar acidified with 0.2% lactic acid (PGAA). Isolates were identified as F. graminearum on the basis of growth rate and pigmentation of colonies on PGAA, lack of microconidia (1), and morphology and size of typical macroconidia in sporodochia developed on Spezieller Nährstoffarmer Agar (3). Isolates of F. graminearum, CE135 and CE136 (from wheat) and CE137 (from corn) deposited in the Centro de Referencia en Micología (CEREMIC), Fac. Farmacia y Bioquímica, UNR, Argentina, were used as references in identifying the soybean isolates. Plants (14-day-old) were inoculated separately with stem and seed isolates in the greenhouse at 26 ± 2 and 20 ± 2°C day/night temperature by inserting a piece of mycelium into a wound made with a scalpel in the hypocotyl. A completely randomized block design (RCB) was utilized with four replicate pots with four plants per pot. Plants wounded but without mycelium served as controls. This test was conducted twice (experiments 1 and 2). Another test was completed by burying a thin layer of wheat caryopsis colonized by fungal mycelium of the stem isolate CE170 in the soil of pots. Plants in pots with soil without inoculum served as controls (4). The experiment was conducted twice (experiments 3 and 4) in an RCB with five replications, four plants per replication. The progress of symptoms in experiments 1 and 2 were stem with light brown discoloration around the inoculation point that extended progressively along the stem, interveinal chlorosis or loss of turgence of unifoliate leaves, and interveinal chlorosis of trifoliate leaves followed by plant wilting and death. Twenty-one days after inoculation, average percentages of dead plants (%DP) was 42 and 21% for stem and seed isolates, respectively. For experiments 3 and 4, %DP was 56%, 45 days after emergence. These plants had roots with light brown, necrotic areas. Control plants remained healthy. The pathogen was reisolated from the stem (100%) and root (57%) tissues of symptomatic plants but not from similar tissues of control plants. To our knowledge, this is the first report of a pathogenic relationship between F. graminearum and soybean. References: (1) P. E. Nelson et al. Fusarium species: An Illustrated Manual for Identification. The Pennsylvania State University Press, University Park, PA, 1983. (2) R.N. Pioli et al. Fitopatología 35(2):111, 2000. (3) B. A. Summerell et al. Plant Dis. 87:117, 2003. (4) C. E. Windels. Fusarium. Pages 115–128 in: Methods for Research on Soilborne Phytopathogenic Fungi. L. L. Singleton, J. D. Mihail, and C. M. Rush, eds. The American Phytopathological Society, St. Paul, MN, 1992.

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First Report of Corynespora Leaf Spot of Eucalyptus in China

Plant Disease ◽

10.1094/pdis-07-14-0697-pdn ◽

2015 ◽

Vol 99 (3) ◽

pp. 419-419 ◽

Cited By ~ 1

Author(s):

C. K. Phan ◽

J. G. Wei ◽

F. Liu ◽

B. S. Chen ◽

J. T. Luo ◽

...

Keyword(s):

Leaf Spot ◽

Southern China ◽

Tap Water ◽

Pathogenic Fungi ◽

Leaf Spot Disease ◽

Pathogenicity Test ◽

Commonwealth Mycological Institute ◽

Conidial Suspension ◽

Single Spore ◽

First Report

Eucalyptus is widely planted in the tropics and subtropics, and it has become an important cash crop in Southern China because of its fast-growing nature. In the Guangxi Province of southern China, Eucalyptus is produced on approximately 2 million ha, and two dominant asexual clones, Guanglin No. 9 (E. grandis × E. urophylla) and DH3229 (E. urophylla × E. grandis), are grown. Diseases are an increasing threat to Eucalyptus production in Guangxi since vast areas are monocultured with this plant. In June 2013, a leaf spot disease was observed in eight out of 14 regions in the province on a total of approximately 0.08 million ha of Eucalyptus. Initially, the lesions appeared as water-soaked dots on leaves, which then became circular or irregular shaped with central gray-brown necrotic lesions and dark red-brown margins. The size of leaf spots ranged between 1 and 3 mm in diameter. The main vein or small veins adjacent to the spots were dark. The lesions expanded rapidly during rainy days, producing reproductive structures. In severe cases, the spots coalesced and formed large irregular necrotic areas followed by defoliation. The causal fungus was isolated from diseased leaves. Briefly, the affected leaves were washed with running tap water, sterilized with 75% ethanol (30 s) and 0.1% mercuric dichloride (3 min), and then rinsed three times with sterilized water. Small segments (0.5 to 0.6 cm2) were cut from the leading edge of the lesions and plated on PDA. The plates were incubated at 25°C for 7 to 10 days. When mycelial growth and spores were observed, a single-spore culture was placed on PDA and grown in the dark at 25°C for 10 days. A pathogenicity test was done by spraying a conidial suspension (5 × 105 conidia ml–1) of isolated fungus onto 30 3-month-old leaves of Guanglin No. 9 seedlings. The plants were covered with plain plastic sheets for 7 days to keep the humidity high. Lesions similar to those observed in the forests were observed on the inoculated leaves 7 to 10 days after incubation. The same fungus was re-isolated. Leaves of control plants (sprayed with sterilized water) were disease free. Conidiophores of the fungus were straight to slightly curved, erect, unbranched, septate, and pale to light brown. Conidia were formed in chains or singly with 4 to 15 pseudosepta, which were oblong oval to cylindrical, subhyaline to pale olivaceous brown, straight to curved, 14.5 to 92.3 μm long, and 3.5 to 7.1 μm wide. The fungus was morphologically identified as Corynespora cassiicola (1). DNA of the isolate was extracted, and the internal transcribed spacer (ITS) region (which included ITS 1, 5.8S rDNA gene of rDNA, and ITS 2) was amplified with primers ITS5 and ITS4. 529 base pair (bp) of PCR product was obtained and sequenced. The sequence was compared by BLAST search to the GenBank database and showed 99% similarity to C. cassiicola (Accession No. JX087447). Our sequence was deposited into GenBank (KF669890). The biological characters of the fungus were tested. Its minimum and maximum growth temperatures on PDA were 7 and 37°C with an optimum range of 25 to 30°C. At 25°C in 100% humidity, 90% of conidia germinated after 20 h. The optimum pH for germination was 5 to 8, and the lethal temperature of conidia was 55°C. C. cassiicola has been reported causing leaf blight on Eucalyptus in India and Brazil (2,3) and causing leaf spot on Akebia trifoliate in Guangxi (4). This is the first report of this disease on Eucalyptus in China. References: (1) M. B. Ellis and P. Holliday. CMI Descriptions of Pathogenic Fungi and Bacteria, No. 303. Commonwealth Mycological Institute, Kew, Surrey, UK, 1971. (2) B. P. Reis, et al. New Dis. Rep. 29:7, 2014. (3) K. I. Wilson and L. R. Devi. Ind. Phytopathol. 19:393, 1966. (4) Y. F. Ye et al. Plant Dis. 97:1659, 2013.

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First Report of Soybean Stem Canker Caused by Diaporthe phaseolorum var. caulivora in Argentina

Plant Disease ◽

10.1094/pdis.2001.85.1.95b ◽

2001 ◽

Vol 85 (1) ◽

pp. 95-95 ◽

Cited By ~ 6

Author(s):

R. N. Pioli ◽

E. N. Morandi ◽

V. Bisaro

Keyword(s):

Disease Incidence ◽

Low Frequency ◽

Principal Component ◽

Stem Canker ◽

Morphological Characters ◽

Santa Fe ◽

First Report ◽

Soybean Seedlings ◽

Diaporthe Phaseolorum ◽

Soybean Plants

A soybean stem canker (SSC) outbreak caused by Diaporthe phaseolorum (Cooke & Ellis) Sacc. var. meridionalis Fernández was reported in Santa Fe, Argentina, in 1997 (3). In 1999 an isolate, which was morphologically distinct from D. phaseolorum var. meridionalis, was obtained from stems of field-grown soybean plants exhibiting SSC symptoms, at Oliveros, Santa Fe, Argentina (Lat. 32° 33′S, Lon. 60° 51′W). Disease incidence was 76% in the field where samples were collected. The pathogen was isolated in darkness at 25°C on potatoglucose agar acidified with 0.2% lactic acid (3). The isolate produced white colonies with compact and tufted mycelium that changed to yellow and light tan with age. Stromata and pycnidia were not produced. After 35 days in culture, clustered perithecia were frequently observed on stem segments. Fifty asci, five from each of 10 perithecia, and bicellular, biguttulated ascospores were measured. Ascus mean length was 26.9 ± 2.5 μm and width was 5.3 ± 0.5 μm; ascospore mean length was 8.3 ± 0.6 μm and width was 2.6 ± 0.1μm. Based on these features, the new isolate was classified as D. phaseolorum var. caulivora Athou & Caldwell (1). To further compare the new isolate with previous identified ones, a principal component analysis (PCA, SAS Systems) was performed using seven isolates of D. phaseolorum var. meridionalis, three isolates of D. phaseolorum var. sojae, and two isolates of Phomopsis longicolla. Seventeen morphological characters, all related with the color and texture of the colonies, the presence and shape of the pycnidia and conidia, the presence and type of stromata and perithecia, and the length of the asci, were compared. According to the PCA analysis, the principal characters that discriminated SSC producing isolates (D. phaseolorum var. meridionalis and D. phaseolorum var. caulivora) from non-SSC producing ones (D. phaseolorum var. sojae and P. longicolla) were the development of perithecia (r = 0.98) and low frequency stromata (r = 0.98) in D. phaseolorum var. meridionalis and D. phaseolorum var. caulivora isolates. The principal components that discriminated SSC producing isolates were the more compact and tufted aspect of the mycelia (r = 0.95) and the shorter length of the asci (r = 0.83) in D. phaseolorum var. caulivora compared with D. phaseolorum var. meridionalis. Pathogenicity trials were performed under greenhouse conditions by inoculating D. phaseolorum var. caulivora mycelia in hypocotyls of soybean seedlings by the toothpick method (2). Typical SSC symptoms were observed on susceptible plants and the pathogen was re-isolated and identified from stem portions of the first internode above the inoculation point. Pathogenicity trials were repeated twice with similar results. This is the first report of D. phaseolorum var. caulivora in Argentina and, as far as we know, in all of South America. References: (1) F. A. Fernández et al. 1999. Stem canker. Pages 32–35 in: Compendium of Soybean Diseases, 4th ed. APS Press, St. Paul, MN. (2) B. L. Keeling. Phytopathology 72:807–809, 1982. (3) R. N. Pioli et al. Plant Dis. 81:1215, 1997.

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First report of Fusarium falciforme (FSSC 3+4) causing wilt disease of Phaseolus vulgaris in Mexico

Plant Disease ◽

10.1094/pdis-06-20-1160-pdn ◽

2020 ◽

Author(s):

José Francisco Díaz-Nájera ◽

Sergio Ayvar-Serna ◽

Antonio Mena-Bahena ◽

Emiliano Baranda-Cruz ◽

Mateo Vargas-Hernández ◽

...

Keyword(s):

Phaseolus Vulgaris ◽

Tap Water ◽

Wilt Disease ◽

Healthy Plant ◽

Pathogenicity Test ◽

Distilled Water ◽

Conidial Suspension ◽

Single Spore ◽

First Report ◽

Fusarium Falciforme

Bean (Phaseolus vulgaris) is the second most important crop in Mexico after corn due to the high consumption of beans in all regions of the country. In the winter (January 2016), bean plants showing wilting, root discoloration and necrosis were observed, with an incidence of approximately 30% in different fields (<1 ha) in Tecoanapa, Guerrero State, Mexico. Symptomatic fine roots (<2 mm) were cut into 0.5 cm long pieces, washed with tap-water, surface disinfected with 1.5% NaOCl for 3 min, and rinsed with sterile distilled water. Thirty-five pieces were placed on potato dextrose agar (PDA, Difco) and incubated at 25 ℃ for seven days. Then, single-spore isolates were obtained. Colonies on PDA showed abundant white aerial mycelium and a growth rate of 4.5 mm/day, and in reverse, colonies were white/pink with a brown centre. Microconidia were cylindrical to ellipsoid, aseptate, hyaline and 7.8-(6.0)-4.7 × 2.7-(2.1)-1.6 µm. On carnation leaf agar, macroconidia were 37.8-(29.4)-23.5 × 4.1-(3.5)-2.6 µm, hyaline, falcate, with slightly curved apexes, and 3-5 septa. Chlamydospores were round, intercalary, hyaline, single or in chains (Boot 1971). A representative strain (CSAEGRO-AyDi-Ef) was analyzed by PCR and the translation elongation factor 1-alpha (tef1) gene (GenBank accession number MK945757) was sequenced using the EF-1/EF-2 primers (O’Donnell 2000). FUSARIUM-ID (Geiser et al. 2004) analysis showed 100% similarity with the Fusarium solani species complex (FSSC 3+4) strain NRRL28562. In addition, Bayesian phylogenetic analysis placed this strain in the Fusarium falciforme clade. A pathogenicity test was performed by immersing healthy plant roots (cv. Negro Jamapa) in 200 mL of a conidial suspension (50×106 conidia mL-1) for 10 min, and then transplanting the plants into pots. Control plants were immersed in sterile distilled water. Similar symptoms as those in the field were observed at 10 days after inoculation, and the controls were healthy. The fungus was reisolated from infected plants and showed the same morphology and tef1 sequence as the original isolate, fulfilling Koch’s postulates. Recently, F. falciforme was reported to cause wilting of P. vulgaris in Cuba (Duarte et al. 2019); however, this is the first report of F. falciforme (FSSC 3+4) causing wilt disease of P. vulgaris in Mexico. This species was previously reported in Mexico affecting onion (Tirado-Ramírez et al. 2018), papaya, tomato (Vega-Gutiérrez et al. 2019a, b), and maize (Douriet-Angulo et al. 2019), suggesting an ample host range in the country.

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First report of Mycoleptodiscus terrestris causing root rot of soybean in Indiana

Plant Disease ◽

10.1094/pdis-09-20-2023-pdn ◽

2020 ◽

Author(s):

Christopher Detranaltes ◽

Guohong Cai

Keyword(s):

Root Rot ◽

Biological Control Agent ◽

Lateral Roots ◽

Its Region ◽

Selective Medium ◽

Internal Transcribed Spacers ◽

Root Tissue ◽

Pathogenicity Test ◽

First Report ◽

Soybean Seedlings

During the summers in 2019 and 2020, 137 soybean (Glycine max (L.) Merr) seedlings (V1-V3 stage) showing stunting, delayed emergence, and/or crown lesions were collected at Purdue’s Agronomy Center for Research and Education in West Lafayette, Indiana. Four seedlings were stunted with reddish-brown girdled lesions along the hypocotyl and crown, rotted tap and lateral roots, and brown discoloration of the cortex and vascular tissues. Four fungal isolates (AC4, AC58, AC96, and AC127) were recovered by plating surface-sterilized symptomatic root tissue onto water agar plates and incubating on the benchtop until mycelia emerged. The growing hyphal tips were transferred to the semi-selective medium DCPA (Andrews and Pitt 1986). On potato dextrose agar, the fungal colonies developed olivaceous green mycelia which melanized into a mat of black microsclerotia with time and no conidia were observed. On 1.5% water agar plates amended with twice autoclaved soybean leaf and root tissue collected from flowering soybean plants, conidia were formed in sporodochia in darkness at 28 οC within one week. Conidia were 1-2 septate, cylindrical with two setae on either end, and measured 20.8 to 26.4 x 4 to 5.6 μm (average 23.9 x 4.7 μm, n=20). The morphological characters matched with the description of Mycoleptodiscus terrestris (Gerd.) Ostaz (Gerdemann 1953). Species identification was further confirmed by sequencing the internal transcribed spacers (ITS) region of rDNA amplified by ITS1 and ITS4 primers (White et al. 1990) and the translation elongation factor 1 alpha (TEF1-α) gene using 983F and 1567R primers with annealing temperature at 53 ○C (Rehner and Buckley 2005). The sequences were deposited in GenBank under the following accession numbers: ITS: MW002684, MT998441, MW010258, and MW010260; and TEF1-α: MW015941-MW015944. The GenBank BLAST searches revealed 100% identity in the ITS region (accession NR_145373.1) and 99.75% identity in the TEF1-α region (MK495977.1) to M. terrestris. Pathogenicity test was conducted on soybean seedlings (cv. Williams) at V1 growth stage using a root dip assay. Isolate AC58 was grown in a modified cotton seed meal broth (CSMB) to produce microsclerotia as inoculum (Gray 1978; Shearer and Jackson 2006). Microsclerotia concentration was measured using a hemocytometer and adjusted to 1.5 x 104 per ml. Five soybean seedlings each were dipped into inoculum or sterile CSMB for 30 minutes then planted individually in vermiculite-filled Styrofoam cups placed on flooded trays in 16-hr photoperiod light racks at room temperature. Seven days after inoculation, all inoculated plants were visibly stunted with root and crown symptoms identical to field symptoms while all controls were healthy. M. terrestris was successfully re-isolated from inoculated plants, but not from the controls, and identified by morphology and sequencing as above. M. terrestris has been previously reported causing root rot of soybean in Illinois (Gray 1978) and Wisconsin (Smith et al. 1998). To our knowledge, this is the first report of M. terrestris infecting soybean in Indiana. Increased geographic distribution of this pathogen warrants more attention for its control. M. terrestris has been proposed as a biological control agent against multiple aquatic weeds (Verma and Charudattan 1993; Shearer and Jackson 2006). Introduction of this fungus into soybean production regions should be avoided.

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First Report of Lasiodiplodia theobromae and L. pseudotheobromae Causing Canker Disease of Sacha Inchi in Hainan, China

Plant Disease ◽

10.1094/pdis-11-20-2507-pdn ◽

2021 ◽

Author(s):

Weiwei Wang ◽

Xiqiang Song

Keyword(s):

Phylogenetic Analysis ◽

Tap Water ◽

Disease Incidence ◽

Gene Bank ◽

Sodium Hypochlorite Solution ◽

Pathogenicity Test ◽

Oilseed Crop ◽

Canker Disease ◽

First Report ◽

Sacha Inchi

Sacha inchi (Plukenetia volubilis L.) belongs to the family Euphorbiaceae. It is a perennial wooden oilseed crop, and also exhibits a good source of polyunsaturated fatty acids, protein and other bioactive compounds, such as tocopherols, carotenes and phytosterols (Chirinos et al. 2013). During 2017-2018 survey, canker disease showing greyish-brown sunken lesions was observed on the branches of sacha inchi in Danzhou campus, Hainan University, China. The disease incidence is less than 5%. However, it can lead to leaf yellowing, wilt, and eventually the whole plant death. In Nov. 2017, twelve branches showing the typical canker symptoms were collected and covered with parafilm at both ends of all samples to prevent desiccation and placed in black plastic bags keeping at 4°C until isolations were made. Samples were rinsed with tap water and dried with paper towels. Fragments, 5mm in length and cut from the junction of diseased and healthy parts of branches, were surface-sterilized with 2% sodium hypochlorite solution for 2 min, rinsed with sterilized distilled water for 5 times, dried by sterilized filter paper, plated on PDA medium amended with 100 μg/mL streptomycin (PDA-str) and incubated in the dark for 4 days at 28°C. Pure cultures of fungal isolates were obtained by transferring mycelial fragments from colony margins onto fresh PDA plates and incubated as described before. The colonies of cultures were initially white, and eventually turned black after 4 days on PDA medium (Fig S1A). The morphology characterization of conidia produced by the isolates was initially hyaline and aseptate (Fig S1B), and a single median septum formed in the mature conidia (Fig S1B). The average size of 50 conidia was 16.39±1.46ⅹ 8.52±0.92μm for J6, and 15.64±1.73ⅹ 8.94±0.86μm for J3. Three genes were used for phylogenetic analysis (Alves et al. 2006). ITS regions and the partial of TUB (β-tubulin gene) were amplified using the primer pairs ITS1 and ITS4 (White et al. 1990), Bt2a and Bt2b (Glass and Donaldson 1995), respectively, and EF1-688F/EF1-1251R for J3 and EF1-728F/EF1-986R for J6 were used to amplify TEF (translation elongation factor 1-alpha) (Alves et al. 2008). The sequences of ITS, TUB and TEF from J3 and J6 were deposited in Gene-Bank (Table S1). The blast searches in Gene-Bank with ITS, TUB and TEF amplified from isolates J3, respectively, revealed 100, 99, and 100% identities with L. pseudotheobromae, and isolate J6 showed 100, 100 and 99% of identity with L. theobromae. The phylogenetic analysis of the combined ITS, TUB and TEF sequences of J3, J6 and 28 reference strains retrieved from Gene-Bank was performed using the program MEGA 6.0 evaluated by 1000 bootstrap replications, and the result was consistent with the conclusion above (Fig S2). With the phylogenic studies supported by morphological characters, J3 was identified as L. pseudotheobromae and J6 was L. theobromae. For the pathogenicity test, J3 and J6 were used to inoculate 4-week-old healthy sacha inchi potted seedlings. One wound about 5 mm in depth per seedling stem was made using a sterile blade. A 5-mm-diameter mycelium plug of each isolate taken from the edge of 4-day-old culture growing on PDA was placed to the freshly wound of each plant stem and the inoculated area was wrapped with Parafilm. Sterile PDA plugs were placed onto the wounds of control seedlings. Nine healthy seedlings were inoculated with each isolate or PDA plugs in a completely randomized design. After inoculation, plants were placed in a greenhouse at room temperature (26 to 30°C, 80% RH) and were irrigated when needed. The experiment was conducted twice. Five days later, black or dark-brown canker lesions formed on the stems of inoculated plants, and expended upward and downward from the inoculation points. Pycnidia produced on the necrotic regions and were used to to observe the morphology of conidia (Fig S3). The fungus L. pseudotheobromae or L. theobromae can be re-isolated from the inoculated plants, but not from the control ones. L. pseudotheobromae was recorded to be collected from dead leaves of P. volubilis in Yunnan Province, China, but did not prove this fungus to be pathogenic (Tennakoon et al. 2016). This is the first report that L. theobromae and L. pseudotheobromae causing stem canker in sacha inchi in Hainan, China. The results pave the way for the development of management strategies for canker disease in sacha inchi.

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First Report of Rhizoctonia zeae in Turkey

Plant Disease ◽

10.1094/pdis.1999.83.2.200d ◽

1999 ◽

Vol 83 (2) ◽

pp. 200-200

Author(s):

E. Demirci ◽

C. Eken

Keyword(s):

Sandy Loam ◽

Vegetative State ◽

Low Frequency ◽

Pathogenic Fungi ◽

Disease Symptoms ◽

Soil Mixture ◽

First Report ◽

Waitea Circinata ◽

Rhizoctonia Zeae ◽

Control Disease

In 1997, during a study to determine the pathogenic fungi on Johnsongrass (Sorgum halepense) in the Yusufeli District of Artvin Province, 10 isolates of a Rhizoctonia sp. were obtained from necrotic roots. In anastomosis tests, Johnsongrass isolates fused at low frequency with the Rhizoctonia sp. (teleomorph: Waitea circinata var. circinata) and R. oryzae (teleomorph: W. circinata var. oryzae), and at high frequency with R. zeae (teleomorph: W. circinata var. zeae). Test isolates of the Rhizoctonia sp. (W. circinata var. circinata), R. oryzae, and R. zeae (isolate nos. W616, 231, and 590, respectively) were provided by R. H. Leiner (University of Alaska Fairbanks). In addition, Johnsongrass isolates were identified as R. zeae based on colony morphology of the vegetative state. Pathogenicity of two isolates (JR-3 and JR-8) was determined on Johnsongrass seedlings at 25°C. Six seeds were sown in a 10-cm-diameter pot containing a sterile soil mixture of coarse sandy loam and sand (1:1, vol/vol). Each pot was a replicate and each treatment was replicated four times. Four-week-old Johnsongrass seedlings were inoculated by gently removing the soil mixture from one side of the stem, placing a colonized potato dextrose agar (PDA) 4-mm-diameter plug in direct contact with the base of the stem, and covering the inoculum with the soil mixture. A sterile, uncolonized PDA plug was used as a control. Disease symptoms were observed 2 weeks after inoculation. Brownish, sunken lesions were observed on the base of stems and roots of seedlings inoculated with R. zeae. Stems and roots of uninoculated seedlings were lesion free. Isolates JR-3 and JR-8 were reisolated from plants grown in their respective treatments. This is the first report of R. zeae from Turkey.

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First Report of Tomato severe rugose virus, a Tomato-Infecting Begomovirus, in Soybean Plants in Brazil

Plant Disease ◽

10.1094/pdis-05-17-0644-pdn ◽

2017 ◽

Vol 101 (11) ◽

pp. 1959-1959 ◽

Cited By ~ 7

Author(s):

M. A. Macedo ◽

S. S. Barreto ◽

T. M. Costa ◽

G. A. Rocha ◽

E. C. Dianese ◽

...

Keyword(s):

First Report ◽

Soybean Plants

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First report of Rhizoctonia zeae on turfgrass in Ontario

Plant Pathology ◽

10.1111/j.1365-3059.2006.01467.x ◽

2007 ◽

Vol 56 (2) ◽

pp. 350-350

Author(s):

T. Hsiang ◽

P. Masilamany

Keyword(s):

First Report ◽

Rhizoctonia Zeae

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First Report of Stem and Foliage Blight of Chrysanthemum Caused by Phytophthora drechsleri in the United States

Plant Disease ◽

10.1094/pdis-03-21-0631-pdn ◽

2021 ◽

Author(s):

Charles Krasnow ◽

Nancy Rechcigl ◽

Jennifer Olson ◽

Linus Schmitz ◽

Steven N. Jeffers

Keyword(s):

United States ◽

South Carolina ◽

Sequence Similarity ◽

Morphological Characteristics ◽

The United States ◽

Universal Primers ◽

Broad Host Range ◽

Pathogenicity Test ◽

First Report ◽

Foliage Blight

Chrysanthemum (Chrysanthemum × morifolium) plants exhibiting stem and foliage blight were observed in a commercial nursery in eastern Oklahoma in June 2019. Disease symptoms were observed on ~10% of plants during a period of frequent rain and high temperatures (26-36°C). Dark brown lesions girdled the stems of symptomatic plants and leaves were wilted and necrotic. The crown and roots were asymptomatic and not discolored. A species of Phytophthora was consistently isolated from the stems of diseased plants on selective V8 agar (Lamour and Hausbeck 2000). The Phytophthora sp. produced ellipsoid to obpyriform sporangia that were non-papillate and persistent on V8 agar plugs submerged in distilled water for 8 h. Sporangia formed on long sporangiophores and measured 50.5 (45-60) × 29.8 (25-35) µm. Oospores and chlamydospores were not formed by individual isolates. Mycelium growth was present at 35°C. Isolates were tentatively identified as P. drechsleri using morphological characteristics and growth at 35°C (Erwin and Ribeiro 1996). DNA was extracted from mycelium of four isolates, and the internal transcribed spacer (ITS) region was amplified using universal primers ITS 4 and ITS 6. The PCR product was sequenced and a BLASTn search showed 100% sequence similarity to P. drechsleri (GenBank Accession Nos. KJ755118 and GU111625), a common species of Phytophthora that has been observed on ornamental and vegetable crops in the U.S. (Erwin and Ribeiro 1996). The gene sequences for each isolate were deposited in GenBank (accession Nos. MW315961, MW315962, MW315963, and MW315964). These four isolates were paired with known A1 and A2 isolates on super clarified V8 agar (Jeffers 2015), and all four were mating type A1. They also were sensitive to the fungicide mefenoxam at 100 ppm (Olson et al. 2013). To confirm pathogenicity, 4-week-old ‘Brandi Burgundy’ chrysanthemum plants were grown in 10-cm pots containing a peat potting medium. Plants (n = 7) were atomized with 1 ml of zoospore suspension containing 5 × 103 zoospores of each isolate. Control plants received sterile water. Plants were maintained at 100% RH for 24 h and then placed in a protected shade-structure where temperatures ranged from 19-32°C. All plants displayed symptoms of stem and foliage blight in 2-3 days. Symptoms that developed on infected plants were similar to those observed in the nursery. Several inoculated plants died, but stem blight, dieback, and foliar wilt were primarily observed. Disease severity averaged 50-60% on inoculated plants 15 days after inoculation. Control plants did not develop symptoms. The pathogen was consistently isolated from stems of symptomatic plants and verified as P. drechsleri based on morphology. The pathogenicity test was repeated with similar results. P. drechsleri has a broad host range (Erwin and Ribeiro 1996; Farr et al. 2021), including green beans (Phaseolus vulgaris), which are susceptible to seedling blight and pod rot in eastern Oklahoma. Previously, P. drechsleri has been reported on chrysanthemums in Argentina (Frezzi 1950), Pennsylvania (Molnar et al. 2020), and South Carolina (Camacho 2009). Chrysanthemums are widely grown in nurseries in the Midwest and other regions of the USA for local and national markets. This is the first report of P. drechsleri causing stem and foliage blight on chrysanthemum species in the United States. Identifying sources of primary inoculum may be necessary to limit economic loss from P. drechsleri.

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