Grafting has been widely and effectively used in cucumber (Cucumis sativus) cultivation for approximately 30 years in China to avoid Fusarium wilt caused by Fusarium oxysporum Schl. f. sp. cucumerinum Owen. In greenhouses, 90% of cucumbers are grafted onto pumpkin (Cucurbita moschata) rootstock. However, in March 2009, a severe crown rot causing yellowing and wilting of the leaves was observed on grafted cucumber in a large number of greenhouses in Lingyuan, western Liaoning Province in China. Symptoms consisted of dark brown, water-soaked lesions and a dense, white mycelial mat at the base of the stem. Lingyuan is the largest district for cucumber cultivation using grafting techniques in solar greenhouses in China. In 30 surveyed greenhouses in Sanshijiazi Village in the city of Lingyuan, the incidence of affected plants ranged from 10 to 40%, which caused serious economic losses. Fusarium spp. were isolated from the surface-sterilized basal stems of symptomatic plants on potato dextrose agar and incubated on potato sucrose agar for 4 days at 25°C. Colonies of the isolates produced a brown pigmentation and sparse, aerial mycelia, with a cream color on the underside. Conidiophores were elongated and branched or unbranched. Microconidia were abundant, hyaline, ellipsoid to ovoid, and 6 to 14 × 2.5 to 3.5 μm. Macroconidia were cylindrical, abundant, mostly two to six septate, 22 to 63 × 3.2 to 5.0 μm, with the apical cell rounded and blunt, and the basal cell rounded. On the basis of morphological characteristics, the fungus was identified as F. solani (C. Booth). For confirmation, the internal transcribed spacer region of rDNA was amplified and sequenced. A 449-bp sequence shared 99% homology with that of a F. solani GenBank accession previously reported from Japan (No. AF150473.1). The new sequence was deposited in GenBank (Accession No. HM015882). Pathogenicity of three isolates was determined in two experiments using different methods of inoculation. In one, 30 seedlings of pumpkin (C. moschata) with one true leaf each were inoculated by dipping their roots in a suspension of 106 spores ml–1, while control plants were mock inoculated with sterile water. Plants were then potted in a sterile mix of peat moss and vermiculite (2:1 vol/vol). In the other, pregerminated pumpkin seeds were sown in the same medium with a conidial suspension added at a rate of 106 spores ml–1, while other seeds were sown in sterile soil as controls. Plants for both experiments were maintained in a greenhouse at 25°C. Twelve days after inoculation, inoculated plants in both experiments showed a cortical rot on the crown and stem base with a brown, water-soaked appearance. Twenty-one days later, inoculated plants developed wilting and yellowed leaves. Disease incidence was 100%. No symptoms occurred on the control plants. Both experiments were repeated once with the same results. The pathogen was recovered from symptomatic tissue, confirming Koch's postulates. F. solani has been previously reported to cause root rot on cucurbit in California (2) and crown rot on grafted cucumber in the Netherlands (1). To our knowledge, this is the first report of crown rot of grafted cucumber caused by F. solani in China. References: (1) L. C. P. Kerling and L. Bravenboer. Neth. J. Plant Pathol. 73:15, 1967. (2) T. A. Tousson and W. C. Snyder. Phytopathology 51:17, 1961.
Common bean (Phaseolus vulgaris L.) is an economically important crop in China. In June 2008, a new foliar disease was observed on beans in Shunyi District, Beijing, China. The disease occurred in approximately 15% of the plants in a commercial field. Leaf spots were circular to irregular, reddish brown, zonate, and 8 to 20 mm in diameter. Black sporodochia with white tuffs were present on older lesions and black spore masses were present in moist weather. Ten isolates recovered from lesions produced white, floccose colonies and spore masses after 4 days on potato dextrose agar. The rod-shaped, hyaline conidia had rounded ends and averaged 6.8 × 2.5 μm. All characteristics were consistent with the description of Myrothecium roridum Tode ex Fr. (1). The internal transcribed spacer regions of one isolate were sequenced and deposited in GenBank (Accession No. GQ 381291). Sequences of the isolate from bean in China were 98% similar to sequences of M. roridum in GenBank. To determine pathogenicity, 30 healthy seedlings of common bean were inoculated by spraying a 1 × 105 conidia ml–1 suspension of M. roridum onto the foliage. Ten seedlings were sprayed with sterile water and served as controls. Plants were kept in a humid chamber at 27°C overnight and then placed in a growth chamber. After 6 days, the symptoms described above were observed on leaves in all inoculated plants, whereas symptoms did not develop on the control plants. The pathogen was reisolated from inoculated leaves, fulfilling Koch's postulates. There is one report of M. roridum on soybean in Korea (2). To our knowledge, this is the first report of Myrothecium leaf spot on common bean in China. References: (1) M. Fitton et al. CMI Mycol. Pap. No. 253, 1970. (2) K. J. Yum et al. Plant Pathol. J. 6:313, 1990.
Zantedeschia aethiopica (L.) Spreng. (calla lily), belonging to family Araceae, is a popular ornamental plant in China. In the summer of 2010, leaves of calla lily with typical symptoms of necrotic lesions were observed in a commercial glasshouse in Beijing, China (116°20′ E, 39°44′ N). The initial symptoms were circular to subcircular, 1 to 3 mm, and dark brown lesions on the leaf lamina. Under high humidity, lesions expanded rapidly to 5 to 10 mm with distinct concentric zones and produced black sporodochia, especially on the backs of leaves. Later, the infected leaves were developing a combination of leaf lesions, yellowing, and falling off; as a result, the aesthetic value of the plant was significantly impacted. Leaf samples were used in pathogen isolation. Symptomatic leaf tissues were cut into small pieces and surface sterilized with 70% ethanol for 30 s and then in 0.1% mercuric chloride solution for 1 to 3 min. After being washed in sterile distilled water three times, the pieces were plated on potato dextrose agar (PDA) and incubated at 25°C in darkness for 7 days (5). Initial colonies of isolates were white, floccose mycelium and developed dark green to black concentric rings that were sporodochia bearing viscid spore masses after incubating 5 days. Conidiophores branched repeatedly. Conidiogenous cells were hyaline, clavate, and 10.0 to 16.0 × 1.4 to 2.0 μm. Conidia were hyaline, cylindrical, both rounded ends, and 6.0 to 8.2 × 1.9 to 2.4 μm. Morphological characteristics of the fungus were consistent with the description of Myrothecium roridum Tode ex Fr. (3,4). To confirm the pathogenicity, three healthy plants of calla lily were inoculated with a conidial suspension (1 × 106 conidia per ml) brushed from a 7-day-old culture of the fungus. Control plants were sprayed with sterile water. The inoculated plants were individual with clear plastic bags and placed in a glass cabinet at 25°C. After 7 days, all inoculated leaves developed symptoms similar to the original samples, but control plants remained disease free. Re-isolation and identification confirmed Koch's postulates. For molecular identification, genomic DNA of a representative isolate (MTL07081001) was extracted by modified CTAB method (1), and the rDNA-ITS region was amplified by using primers ITS1 (5-TCCGTAGGTGAACCTGCGG-3) and ITS4 (5-TCCTCCGCTTATTGATATGC-3). The 465-bp amplicon (GenBank Accession No. KF761293) was 100% identity to the sequence of M. roridum (JF724158.1) from GenBank. M. roridum has an extensive host range, covering 294 host plants (2). To our knowledge, this is the first record of leaf spot caused by M. roridum on calla lily in China. References: (1) F. M. Ausubel et al. Current Protocols in Molecular Biology. John Wiley & Sons Inc, New York, 1994. (2) D. F. Farr and A. Y. Rossman, Fungal Databases. Syst. Mycol. Microbiol. Lab., ARS, USDA. Retrieved from http://nt.ars-grin.gov/fungaldatabases/ , October 2013. (3) M. T. Mmbaga et al. Plant Dis. 94:1266, 2010. (4) Y. X. Zhang et al. Plant Dis. 95:1030, 2011. (5) L. Zhu et al. J. Phytopathol. 161:59, 2013.
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