scholarly journals First Report of Cochliobolus sativus Causing Leaf Spot on Paper Mulberry in China

Plant Disease ◽  
2011 ◽  
Vol 95 (12) ◽  
pp. 1586-1586 ◽  
Author(s):  
P. S. Wu ◽  
K. Chen ◽  
H. Z. Du ◽  
J. Yan ◽  
Q. E. Zhang

Paper mulberry, Broussonetia papyrifera (L.) Vent., is a highly adaptable, fast-growing tree that is native to eastern Asia. Its ability to absorb pollutants makes it ideal for ornamental landscapes, especially in industrial and mining areas. During the summer of 2010, brown lesions were observed on leaves of paper mulberry in Baiwangshan Forest Park, Beijing, China. These lesions were ovoid to fusiform and 4 to 9 × 2 to 4 mm with dark brown centers and light brown irregular edges. Spots on severely infected leaves sometimes coalesced to form long stripes with gray centers. To isolate the causal agent of the lesions, 4-mm2 pieces of diseased leaf tissue from 12 leaves were collected at the lesion margins and surface disinfected in 0.5% NaOCl for 3 min, rinsed three times with sterile water, plated on water agar, and incubated at 25°C with a 12-h photoperiod. After 5 days, the cultures, which became dark brown to black, were observed. Conidiophores (120 to 220 × 4 to 7 μm) were solitary or in groups of two to five, straight or flexuous with swollen bases, and light or dark brown. Conidia were dark olive brown, spindle- or oval-shaped with truncated ends (60 to 120 × 15 to 30 μm), slightly curved, and containing 3 to 12 distoseptate (mostly 6 to 10). Pseudothecia, produced after 14 days in culture, were dark brown to black and flask shaped (420 to 530 μm in diameter with 85 to 100 × 75 to 90 μm ostiolar beaks). Asci were cylindrical (100 to 220 × 30 to 40 μm) and contained eight ascospores. Ascospores were filiform, (150 to 360 × 6 to 9 μm), hyaline, with 6 to 11 septations. Isolates were identified as Cochliobolus sativus (Ito & Kurib.) Drechsler & Dastur (anamorph Bipolaris sorokiniana (Sacc. & Sorok.) Shoem.) on the basis of culture color and dimensions and colors of pseudothecia, asci, ascospores, conidiophores, and conidia (2,3). The identity of one isolate was confirmed by ITS1-5.8S-ITS2 rDNA sequence (GenBank Accession No. HQ 654781) analysis that showed 100% homology to C. sativus listed in Berbee et al. (1). Koch's postulates were performed with six potted 3-month-old paper mulberry plants. An isolate was grown on potato dextrose agar for 14 days to obtain conidia for a conidial suspension (3 × 104 conidia/ml). Three of the potted plants were sprayed with the conidial suspension and three were sprayed with sterile water as controls. Each plant was covered with a plastic bag for 24 h to maintain high humidity and incubated at 25°C with a 12-h photoperiod. After 7 days, the inoculated plants showed leaf symptoms identical to those previously observed on paper mulberry trees in the Baiwangshan Forest Park, while control trees remained symptom free. Reisolation of the fungus from the inoculated plants confirmed that the causal agent was C. sativus. C. sativus is widely distributed worldwide causing a variety of cereal diseases. Wheat and barley are the most economically important hosts. To our knowledge, this is the first report of C. sativus as a pathogen causing leaf spot of paper mulberry in China. References: (1) M. L. Berbee et al. Mycologia 91:964, 1999. (2) M. B. Ellis. Dematiaceous Hyphomycetes. CABI, Oxon, UK, 1971. (3) A. Sivanesan et al. No.701 in: Descriptions of Pathogenic Fungi and Bacteria. CAB, Kew, Surrey, U.K., 1981.

Plant Disease ◽  
2011 ◽  
Vol 95 (7) ◽  
pp. 880-880 ◽  
Author(s):  
J. Yan ◽  
P. S. Wu ◽  
H. Z. Du ◽  
Q. E. Zhang

Paper mulberry, Broussonetia papyrifera (L.) Venten. (family Moraceae), is a fast-growing tree with luxuriant branches and leaves. Because of strong adaptability and tolerance to unfavorable environmental conditions, it is an important tree species for shade or shelter and reforestation in mined areas and on hillsides. During the summer of 2010, brown-to-black spots were observed on leaves of paper mulberry in Baiwangshan Forest Park in Beijing, China. Early symptoms were round or elliptic, light brown, small lesions that later extended to round or irregular spots (4 to 6 × 4 to 8 mm) that were dark brown or black in the center with brown or light brown margins. Several dozen spots were found on severely infected leaves. Leaf tissues (2 × 2 mm), cut from the margins of lesions, were surface disinfected in 0.5% NaOCl solution for 3 min, rinsed three times with sterile water, plated on potato dextrose agar (PDA) and incubated at 25°C with a 12-h light and 12-h dark period. Numerous waxy subepidermal acervuli with setae were observed after 3 days. Acervuli were brown or black, round or elongate, and 100 to 250 μm in diameter. Setae were dark brown, erect straight or slightly curved, and 60 to 74 × 4 to 8 μm with one to two septa. Conidiophores were hyaline or light brown, short with no branches, and cylindrical with dimensions of 12 to 21 × 4 to 5 μm. Conidia were 11 to 21 × 3 to 6 μm, hyaline, aseptate, and cylindrical. Mycelia on PDA were off white-to-dark gray on the reverse side of the colony. Six isolates (BP21-1 to BP21-6) were obtained from different infected leaves and identified as Colletotrichum gloeosporioides (Penz.) Penz. & Sacc. (teleomorph Glomerella cingulata (Stonem.) Spaulding & Schrenk) on the basis of reverse colony color, dimensions and colors of acervuli, conidiophores, and conidia (3). ITS1-5.8S-ITS2 rDNA sequence analysis was performed on all six isolates. The resultant sequences were identical (GenBank Accession No. HQ 654780) and revealed 99% similarity (100% coverage) with C. gloeosporioides isolates in the GenBank (Accession Nos. EU371022.1 and AY376532.1) (2). Pathogenicity was demonstrated using six potted 3-month-old paper mulberry trees. Isolate BP21-2 was grown on PDA for 14 days and conidia were harvested to prepare a suspension of 106 conidia/ml. Three plants were sprayed with the conidial suspension and three were sprayed with sterile water. All trees were covered with plastic bags for 24 h to maintain high humidity and incubated at 25°C for 6 days. All conidia-inoculated trees showed identical symptoms as the infected leaves in the park, while the control trees remained symptom free. Reisolation of the fungus confirmed that the causal agent was C. gloeosporioides. C. gloeosporioides is distributed worldwide causing anthracnose on a wide variety of plants including members of mulberry family Moraceae, e.g., mortality of stem cuttings and death of saplings on mulberry (Morus alba L.) in India (1). To our knowledge, this is the first report of C. gloeosporioides causing black spots on paper mulberry in China. References: (1) V. P. Gupta et al. Indian Phytopathol. 50:402, 1997. (2) K. D. Hyde et al. Fungal Divers. 39:147, 2009. (3) J. E. M. Mordue. No. 315 in: Descriptions of Pathogenic Fungi and Bacteria. CMI. Kew, Surrey, UK, 1971.


Plant Disease ◽  
2020 ◽  
Author(s):  
Quan Shen ◽  
Xixu Peng ◽  
Feng He ◽  
Shaoqing Li ◽  
Zuyin Xiao ◽  
...  

Buckwheat (Fagopyrum tataricum) is a traditional short-season pseudocereal crop originating in southwest China and is cultivated around the world. Antioxidative substances in buckwheat have been shown to provide many potential cardiovascular health benefits. Between August and November in 2019, a leaf spot was found in several Tartary buckwheat cv. Pinku1 fields in Xiangxiang County, Hunan Province, China. The disease occurred throughout the growth cycle of buckwheat after leaves emerged, and disease incidence was approximately 50 to 60%. Initially infected leaves developed a few round lesions, light yellow to light brown spots. Several days later, lesions began to enlarge with reddish brown borders, and eventually withered and fell off. Thirty lesions (2×2 mm) collected from three locations with ten leaves in each location were sterilized in 70% ethanol for 10 sec, in 2% sodium hypochlorite for 30 sec, rinsed in sterile water for three times, dried on sterilized filter paper, and placed on a potato dextrose PDA with lactic acid (3 ml/L), and incubated at 28°C in the dark for 3 to 5 days. Fungal colonies were initially white and later turned black with the onset ofsporulation. Conidia were single-celled, black, smooth, spherical to subspherical, and measured 9.2 to 15.6 µm long, and 7.1 to 11.6 µm wide (n=30). Each conidium was terminal and borne on a hyaline vesicle at the tip of conidiophores. Morphologically, the fungus was identified as Nigrospora osmanthi (Wang et al. 2017). Identification was confirmed by amplifying and sequencing the ITS region, and translation elongation factor 1-alpha (TEF1-α) and partial beta-tublin (TUB2) genes using primers ITS1/ITS4 (Mills et al. 1992), EF1-728F/EF-2 (Carbone and Kohn 1999; O’Donnell et al. 1998) and Bt-2a/Bt-2b (Glass et al. 1995), respectively. BLAST searches in GenBank indicated the ITS (MT860338), TUB2 (MT882054) and TEF1-α (MT882055) sequences had 99.80%, 99% and 100% similarity to sequences KX986010.1, KY019461.1 and KY019421.1 of Nigrospora osmanthi ex-type strain CGMCC 3.18126, respectively. A neighbor-joining phylogenetic tree constructed using MEGA7.0 with 1,000 bootstraps based on the concatenated nucleotide sequences of the three genes indicated that our isolate was closely related to N. osmanthi. Pathogenicity test was performed using leaves of healthy F. tataricum plants. The conidial suspension (1 × 106 conidia/ml) collected from PDA cultures with 0.05% Tween 20 buffer was used for inoculation by spraying leaves of potted 20-day-old Tartary buckwheat cv. Pinku1. Five leaves of each plant were inoculated with spore suspensions (1 ml per leaf). An equal number of control leaves were sprayed with sterile water to serve as a control. The treated plants were kept in a greenhouse at 28°C and 80% relative humidity for 24 h, and then transferred to natural conditions with temperature ranging from 22 to 30°C and relative humidity ranging from 50 to 60%. Five days later, all N. osmanthi-inoculated leaves developed leaf spot symptoms similar to those observed in the field, whereas control leaves remained healthy. N. osmanthi was re-isolated from twelve infected leaves with frequency of 100%, fulfilling Koch’s postulates. The genus Nigrospora has been regarded by many scholars as plant pathogens (Fukushima et al. 1998) and N. osmanthi is a known leaf blight pathogen for Stenotaphrum secundatum (Mei et al. 2019) and Ficus pandurata (Liu et al. 2019) but has not been reported on F. tataricum. Nigrospora sphaerica was also detected in vegetative buds of healthy Fagopyrum esculentum Moench (Jain et al. 2012). To our knowledge, this is the first report of N. osmanthi causing leaf spot on F. tataricum in China and worldwide. Appropriate strategies should be developed to manage this disease.


Plant Disease ◽  
2022 ◽  
Author(s):  
Xiang Xie ◽  
Shiqiang Zhang ◽  
Qingjie Yu ◽  
Xinye Li ◽  
Yongsheng Liu ◽  
...  

Camellia oleifera, a major tree species for producing edible oil, is originated in China. Its oil is also called ‘‘eastern olive oil’’ with high economic value due to richness in a variety of healthy fatty acids (Lin et al. 218). However, leaves are susceptible to leaf spot disease (Zhu et al. 2014). In May 2021, we found circular to irregular reddish-brown lesions, 4-11 mm in diameter, near the leaf veins or leaf edges on 30%-50% leaves of 1/3 oil tea trees in a garden of Hefei City, Anhui Province, China (East longitude 117.27, North latitude 31.86) (Figure S1 A). To isolate the causal agents, symptomatic leaves were cut from the junction of diseased and healthy tissues (5X5 mm) and treated with 70 % alcohol for 30 secs and 1 % NaClO for 5 min, and subsequently inoculated onto PDA medium for culture. After 3 days, hyphal tips were transferred to PDA. Eventually, five isolates were obtained. Then the isolates were cultured on PDA at 25°C for 7 days and the mycelia appeared yellow with a white edge and secreted a large amount of orange-red material to the PDA (Figure S1 B and C). Twenty days later, the mycelium appeared reddish-brown, and sub-circular (3-10 mm) raised white or yellow mycelium was commonly seen on the Petri dish, and black particles were occasionally seen. Meanwhile, the colonies on the PDA produced abundant conidia. Microscopy revealed that conidia were globular to pyriform, dark, verrucose, and multicellular with 14.2 to 25.3 μm (=19.34 μm, n = 30) diameter (Figure S1 D). The morphological characteristics of mycelial and conidia from these isolates are similar to that of Epicoccum layuense (Chen et al.2020). To further determine the species classification of the isolates, DNA was extracted from 7-day-old mycelia cultures and the PCR-amplified fragments were sequenced for internal transcribed spacer (ITS), beta-tubulin and 28S large subunit ribosomal RNA (LSU) gene regions ITS1/ITS4, Bt2a/Bt2b and LR0R/LR5, followed by sequencing and molecular phylogenetic analysis of the sequences analysis (White et al. 1990; Glass and Donaldson 1995; Vilgalys and Hester 1990). Sequence analysis revealed that ITS, beta-tubulin, and LSU divided these isolates into two groups. The isolates AAU-NCY1 and AAU-NCY2, representing the first group (AAU-NCY1 and AAU-NCY5) and the second group (AAU-NCY2, AAU-NCY3 and AAU-NCY4), respectively, were used for further studies. Based on BLASTn analysis, the ITS sequences of AAU-NCY1 (MZ477250) and AAU-NCY2 (MZ477251) showed 100 and 99.6% identity with E. layuense accessions MN396393 and KY742108, respectively. And, the beta-tubulin sequences (MZ552310; MZ552311) showed 99.03 and 99.35% identity with E. layuense accessions MN397247 and MN397248, respectively. Consistently, their LSU (MZ477254; MZ477255) showed 99.88 and 99.77% identity with E. layuense accessions MN328724 and MN396395, respectively. Phylogenetic trees were built by maximum likelihood method (1,000 replicates) using MEGA v.6.0 based on the concatenated sequences of ITS, beta-tubulin and LSU (Figure S2). Phylogenetic tree analysis confirmed that AAU-NCY1 and AAU-NCY2 are closely clustered with E. layuense stains (Figure S2). To test the pathogenicity, conidial suspension of AAU-NCY2 (106 spores/mL) was prepared and sterile water was used as the control. Twelve healthy leaves (six for each treatment) on C. oleifera tree were punched with sterile needle (0.8-1mm), the sterile water or spore suspension was added dropwise at the pinhole respectively (Figure S1 E and F). The experiment was repeated three times. By ten-day post inoculation, the leaves infected by the conidia gradually developed reddish-brown necrotic spots that were similar to those observed in the garden, while the control leaves remained asymptomatic (Figure S1 G and H). DNA sequences derived from the strain re-isolated from the infected leaves was identical to that of the original strain. E. layuense has been reported to cause leaf spot on C. sinensis (Chen et al. 2020), and similar pathogenic phenotypes were reported on Weigela florida (Tian et al. 2021) and Prunus x yedoensis Matsumura in Korea ( Han et al. 2021). To our knowledge, this is the first report of E. layuense causing leaf spot on C. oleifera in Hefei, China.


Plant Disease ◽  
2007 ◽  
Vol 91 (6) ◽  
pp. 772-772 ◽  
Author(s):  
J. A. Mangandi ◽  
T. E. Seijo ◽  
N. A. Peres

The genus Salvia includes at least 900 species distributed worldwide. Wild species are found in South America, southern Europe, northern Africa, and North America. Salvia, commonly referred to as sage, is grown commercially as a landscape plant. In August 2006, pale-to-dark brown, circular leaf spots 5 to 20 mm in diameter with concentric rings were observed on Salvia farinacea ‘Victoria Blue’. Approximately 5% of the plants in a central Florida nursery were affected. Lesions were visible on both leaf surfaces, and black sporodochia with white, marginal hyphal tuffs were present mostly on the lower surface in older lesions. Symptoms were consistent with those of Myrothecium leaf spot described on other ornamentals such as gardenia, begonia, and New Guinea impatiens (4). Isolations from lesions on potato dextrose agar produced white, floccose colonies with sporodochia in dark green-to-black concentric rings. Conidia were hyaline and cylindrical with rounded ends and averaged 7.4 × 2.0 μm. All characteristics were consistent with the description of Myrothecium roridum Tode ex Fr. (2,3). The internal transcribed spacer regions ITS1, ITS2, and the 5.8s rRNA genomic region of one isolate were sequenced (Accession No. EF151002) and compared with sequences in the National Center for Biotechnology Information (NCBI) database. Deposited sequences from M. roridum were 96.3 to 98.8% homologous to the isolate from salvia. To confirm pathogenicity, three salvia plants were inoculated by spraying with a conidial suspension of M. roridum (1 × 105 conidia per ml). Plants were covered with plastic bags and incubated in a growth chamber at 28°C for 7 days. Three plants were sprayed with sterile, distilled water as a control and incubated similarly. The symptoms described above were observed in all inoculated plants after 7 days, while control plants remained symptomless. M. roridum was reisolated consistently from symptomatic tissue. There are more than 150 hosts of M. roridum, including one report on Salvia spp. in Brunei (1). To our knowledge, this is the first report of Myrothecium leaf spot caused by M. roridum on Salvia spp. in the United States. Even the moderate level disease present caused damage to the foliage and reduced the marketability of salvia plants. Therefore, control measures may need to be implemented for production of this species in ornamental nurseries. References: (1) D. F. Farr et al. Fungal Databases. Systematic Botany and Mycology Laboratory. Online publication. ARS, USDA, 2006, (2) M. B. Ellis. Page 449 in: Microfungi on Land Plants: An Identification Handbook. Macmillan Publishing, NY, 1985. (3) M. Fitton and P. Holliday. No. 253 in: CMI Descriptions of Pathogenic Fungi and Bacteria. The Eastern Press Ltd. Great Britain, 1970. (4) M. G. Daughtrey et al. Page 19 in: Compendium of Flowering Potted Plant Diseases. The American Phytopathological Society. St. Paul, MN, 1995.


Plant Disease ◽  
2012 ◽  
Vol 96 (12) ◽  
pp. 1826-1826 ◽  
Author(s):  
M. Berbegal ◽  
A. Pérez-Sierra ◽  
J. Armengol

Hackberry (Celtis australis L.) is widely used for reforestation and as shade tree in parks and roadside plantings in southern Europe (4). In autumn 2011, a foliar disease was observed affecting several trees planted in a garden area located in Alzira (Valencia province, eastern Spain). Symptoms appeared on lower leaf surfaces as reddish to dark brown velvety irregular spots, later becoming grayish brown on the upper surface. Most of the infected trees were prematurely defoliated. Spots on lower leaf surfaces were covered by mycelium, conidiophores, and conidia. Fungal isolates were recovered directly from the structures present on the lesions and by surface-disinfecting small fragments of symptomatic leaf tissue in 0.5% NaOCl, double-rinsing the sections in sterile water, and plating the sections onto potato dextrose agar (PDA) amended with 0.5 g of streptomycin sulfate per liter. Single conidium cultures made onto PDA were maintained for 2 months at 25°C in darkness for morphological examination. Conidia were thick walled, dark reddish brown, often markedly curved or coiled, cylindrical to obclavate, smooth, wrinkled, or verrucose, typically multicellular, 2 to 40 transversely septate and occasionally with 1 to 3 longitudinal or oblique septa that were often constricted, 20 to 96 (44.9) × 6 to 9 (7.1) μm, with an inconspicuous scar at the base. Morphological characters corresponded to the description of Sirosporium celtidis (Biv. ex Spreng) M. B. Ellis published in 1963 (3). The internal transcribed spacer (ITS) region of the rDNA was amplified with the primers ITS1 and ITS4 from DNA extracted from the isolate AL1, and sequenced (GenBank Accession No. JX397963). The sequence was identical to that obtained from an isolate of S. celtidis from the Centraalbureau voor Schimmelcultures, Utrecht, The Netherlands (CBS 289.50). Pathogenicity tests were conducted on five 2-year-old hackberry trees by spraying onto the upper and lower leaf surfaces a conidial suspension of S. celtidis (approximately 50 ml/plant, 106 conidia/ml of water). Five control plants were sprayed with sterile water. Plants were covered with clear plastic bags and incubated in a growth chamber for 72 h at 25°C with a 12-h photoperiod. First leaf spots were visible on inoculated plants after 7 days, but symptoms were not observed on control plants. The fungus was reisolated from leaf lesions on inoculated plants, confirming Koch's postulates. S. celtidis was first described in Sicily in 1815 (3) and has been recorded on various hackberry species in Mediterranean countries and the USA (1,2). To our knowledge, this is the first report of the disease in Spain. The economic and ecological significance of the pathogen in natural ecosystems in Spain remains to be determined but it could certainly become a serious problem for nurseries and urban plantings. References: (1) S.O. Cacciola. 2000. Plant Dis. 84, 492. (2) D. H. Linder. 1931. Ann. Mo. Bot. Garden 18, 31. (3) M. B. Ellis. 1963. Mycological Papers, No. 87. Commonw. Mycol. Inst. Kew, England. (4) S. Pauleit et al., Urban For. Urban Green. 1:83, 2002.


Plant Disease ◽  
2008 ◽  
Vol 92 (4) ◽  
pp. 653-653 ◽  
Author(s):  
G. A. Bardas ◽  
G. T. Tziros ◽  
K. Tzavella-Klonari

Common bean (Phaseolus vulgaris L.) is cultivated extensively in Greece for dry and fresh bean production. During 2005 and 2006, a disease with typical blight symptoms was observed occasionally on dark red kidney, brown kidney, and black bean plants in most bean-producing areas of Greece. It rarely was destructive unless the crop had been weakened by some unfavorable environmental conditions. Infected leaves had brown-to-black lesions that developed concentric zones 10 to 30 mm in diameter and also contained small, black pycnidia. Concentric dark gray-to-black lesions also appeared on branches, stems, nodes, and pods. Infected seeds turned brown to black. Plants sometimes showed defoliation and pod drop. The fungus was consistently isolated on potato dextrose agar from diseased leaves and pods and identified as Phoma exigua var. exigua Sutton and Waterstone on the basis of morphological characteristics of conidia and pycnidia (1,2). Spores were massed in pycnidia from which they were forced in long, pink tendrils under moist weather conditions. Conidia were cylindrical to oval, allantoid, hyaline, pale yellow to brown, usually one-celled, and 2 to 3 × 5 to 10 μm. To satisfy Koch's postulates, a conidial suspension (1 × 106 conidia per ml) of the fungus was sprayed onto leaves and stems of bean seedlings (first-leaf stage) (cv. Zargana Hrisoupolis). Both inoculated and control seedlings (inoculated with sterile water) were covered with plastic bags for 72 h in a greenhouse at 23°C. Inoculated plants showed characteristic symptoms of Ascochyta leaf spot 12 to 15 days after inoculation. The fungus was reisolated from lesions that developed on the leaves and stems of all inoculated plants. The pathogen is present worldwide on bean. To our knowledge, this is the first report of P. exigua var. exigua on common bean in Greece. References: (1) D. F. Farr et al. Fungal Databases. Systematic Botany and Mycology Laboratory. Online publication. ARS, USDA, 2007. (2) B. C. Sutton and J. M. Waterstone. Ascochyta phaseolorum. No. 81 in: Descriptions of Pathogenic Fungi and Bacteria. CMI/AAB, Kew, Surrey, England, 1966.


Plant Disease ◽  
2012 ◽  
Vol 96 (8) ◽  
pp. 1227-1227 ◽  
Author(s):  
A. Nasehi ◽  
J. B. Kadir ◽  
M. A. Zainal Abidin ◽  
M. Y. Wong ◽  
F. Abed Ashtiani

Symptoms of gray leaf spot were first observed in June 2011 on pepper (Capsicum annuum) plants cultivated in the Cameron Highlands and Johor State, the two main regions of pepper production in Malaysia (about 1,000 ha). Disease incidence exceeded 70% in severely infected fields and greenhouses. Symptoms initially appeared as tiny (average 1.3 mm in diameter), round, orange-brown spots on the leaves, with the center of each spot turning gray to white as the disease developed, and the margin of each spot remaining dark brown. A fungus was isolated consistently from the lesions using sections of symptomatic leaf tissue surface-sterilized in 1% NaOCl for 2 min, rinsed in sterile water, dried, and plated onto PDA and V8 agar media (3). After 7 days, the fungal colonies were gray, dematiaceous conidia had formed at the end of long conidiophores (19.2 to 33.6 × 12.0 to 21.6 μm), and the conidia typically had two to six transverse and one to four longitudinal septa. Fifteen isolates were identified as Stemphylium solani on the basis of morphological criteria described by Kim et al. (3). The universal primers ITS5 and ITS4 were used to amplify the internal transcribed spacer region (ITS1, 5.8, and ITS2) of ribosomal DNA (rDNA) of a representative isolate (2). A 570 bp fragment was amplified, purified, sequenced, and identified as S. solani using a BLAST search with 100% identity to the published ITS sequence of an S. solani isolate in GenBank (1). The sequence was deposited in GenBank (Accession No. JQ736024). Pathogenicity of the fungal isolate was tested by inoculating healthy pepper leaves of cv. 152177-A. A 20-μl drop of conidial suspension (105 spores/ml) was used to inoculate each of four detached, 45-day-old pepper leaves placed on moist filter papers in petri dishes (4). Four control leaves were inoculated similarly with sterilized, distilled water. The leaves were incubated at 25°C at 95% relative humidity for 7 days. Gray leaf spot symptoms similar to those observed on the original pepper plants began to develop on leaves inoculated with the fungus after 3 days, and S. solani was consistently reisolated from the leaves. Control leaves did not develop symptoms and the fungus was not reisolated from these leaves. Pathogenicity testing was repeated with the same results. To our knowledge, this is the first report of S. solani causing gray leaf spot on pepper in Malaysia. References: (1) S. F. Altschul et al. Nucleic Acids Res. 25:3389, 1997. (2) M. P. S. Camara et al. Mycologia 94:660, 2002. (3) B. S. Kim et al. Plant Pathol. J. 15:348, 1999. (4) B. M. Pryor and T. J. Michailides. Phytopathology 92:406, 2002.


Plant Disease ◽  
2021 ◽  
Author(s):  
Lili Tang ◽  
Xixia Song ◽  
Liguo Zhang ◽  
Jing Wang ◽  
Shuquan Zhang

Industrial hemp is an economically important plant with traditional uses for textiles, paper, building materials, food and medicine (Li 1974; Russo et al. 2008; Zlas et al. 1993). In August 2020, an estimated 80% of the industrial hemp plants with leaf spots were observed in greenhouse in Minzhu town, Harbin City, Heilongjiang Province, China (45.8554°N, 126.8167°E), resulting in yield losses of 20%. Leaf symptoms began as small spots on the upper surface of leaves and gradually developed into brown spots with light yellow halos. These irregular spots expanded gradually and eventually covered the entire leaf; the center of the spots was easily perforated. To identify the pathogen, 20 diseased leaves were collected, and small sections of (3 to 5 mm) were taken from the margins of lesions of infected leaves. The pieces were sterilized with 75% alcohol for 30 s, a 0.1% mercuric chloride solution for 1 min, and then rinsed three times with sterile water. Samples were then cultured on potato dextrose agar at 28℃ in darkness for 4 days. A single-spore culture was obtained by monosporic isolation. Conidiophores were simple or branched, straight or flexuous, brown, and measured 22 to 61 μm long × 4 to 5 μm wide (n = 50). Conidia were solitary or in chains, brown or dark brown, obclavate, obpyriform or ellipsoid. Conidia ranged from 23 to 55 μm long × 10 to 15 μm wide (n = 50) with one to eight transverse and several longitudinal septa. For molecular identification (Jayawardena et al. 2019), genomic DNA of pathogenic isolate (MZ1287) was extracted by a cetyltrimethylammonium bromide protocol. Four gene regions including the rDNA internal transcribed spacer (ITS), glyceraldehyde-3-phosplate dehydrogenase (GAPDH), translation elongation factor 1-alpha (TEF1) and RNA polymerase II beta subunit (RPB2) were amplified with primers ITS1/ITS4, GDF1/GDR1, EF1-728F/EF1-986R and RPB2-5F/RPB2-7cR, respectively (White et al. 1990). Resulting sequences were deposited in GenBank with accession numbers of MW272539.1, MW303956.1, MW415414.1 and MW415413.1, respectively. A BLASTn analysis showed 100% homology with A. alternata (GenBank accession nos. MN615420.1, MH926018.1, MN615423.1 and KP124770.1), respectively. A neighbor-joining phylogenetic tree was constructed by combining all sequenced loci in MEGA7. The isolate MZ1287 clustered in the A. alternata clade with 100% bootstrap support. Thus, based on morphological (Simmons 2007) and molecular characteristics, the pathogen was identified as A. alternata. To test pathogenicity, leaves of ten healthy, 2-month-old potted industrial hemp plants were sprayed using a conidial suspension (1×106 spores/ml). Control plants were sprayed with sterile water. All plants were incubated in a greenhouse at 25℃ for a 16 h light and 8 h dark period at 90% relative humidity. The experiment was repeated three times. After two weeks, leaf spots of industrial hemp developed on the inoculated leaves while the control plants remained asymptomatic. The A. alternata pathogen was re-isolated from the diseased leaves on inoculated plants, fulfilling Koch's postulates. Based on morphology, sequencing, and pathogenicity test, the pathogen was identified as A. alternata. To our knowledge, this is the first report of A. alternata causing leaf spot disease of industrial hemp (Cannabis sativa L.) in China and is worthy of our attention for the harm it may cause to industrial hemp production.


Plant Disease ◽  
2008 ◽  
Vol 92 (3) ◽  
pp. 486-486
Author(s):  
M. Zhang ◽  
H. L. Li ◽  
A. L. Zhao ◽  
J. X. Zhang

Tree peony (Paeonia suffruticosa) is known as “the king of flowers” for its beautiful and showy flowers. It is regarded as the symbol flower of China and is cultivated throughout the country. During the summer of 2006, a leaf spot was observed on tree peony cultivated in the Zhengzhou area of Henan Province, and in 2007, the leaf spot was observed in the Luoyang area. In some gardens, the leaf spot affected more than 50% of the plants. Early symptoms appeared as small, round, water-soaked lesions on the leaves. Lesions expanded into 5 to 35-mm-diameter spots that were circular or irregular, brown to dark brown, with pale brown margins. Later, the center of some lesions dropped out. Signs of the suspected pathogen were usually seen on the leaf spots after an abundant rainfall. Lesions contained numerous, pale brown, cupulate conidiomata with salmon-colored spore masses. Conidiophores (70 × 1 to 2 μm) were hyaline, branched, septate, and filiform. Conidia (5.5 to 7.5 × 1.5 to 2 μm) were hyaline, aseptate, and cymbiform to allantoid. The pathogen was identified as Hainesia lythri on the basis of the morphology. This fungus infects a wide variety of hosts including P. suffruticosa, Acer pseudoplatanus, Calluna sp., Dissotis paucistellata, Epilobium angustifolium, and Eucalyptus saligna (3). The fungus was isolated on potato dextrose agar (PDA) medium using conidia from conidiomata found on symptomatic leaf tissue; the fungus produced gray-to-brown colonies. Pathogenicity was tested by inoculating 10 leaves on one 5-year-old tree with a mycelia plug from the colony (0.5 cm in diameter); leaves inoculated with plugs of PDA medium served as controls. Inoculated leaves were covered with plastic for 24 h to maintain high relative humidity and incubated at 25 to 28°C. After 5 days, 100% of the inoculated leaves showed symptoms identical to those observed on leaves from P. suffruticosa infected in the field while controls remained symptom free. Reisolation of the fungus from lesions on inoculated leaves confirmed that the causal agent was H. lythri. Thus, we concluded that H. lythri is the causal agent of leaf spots of P. suffruticosa. To our knowledge, this is the first report of H. lythri infecting P. suffruticosa in China. H. lythri has been previously reported on Paeonia in Japan and Korea (1,2). References: (1) W. D. Cho and H. D. Shin, eds. List of Plant Diseases in Korea. 4th ed. Korean Society of Plant Pathology, 2004. (2) M. E. Palm. Mycologia 83:787, 1991. (3) B. C. Sutton. The Coelomycetes. CAB International Publishing, New York, 1980.


Plant Disease ◽  
2015 ◽  
Vol 99 (3) ◽  
pp. 419-419 ◽  
Author(s):  
C. K. Phan ◽  
J. G. Wei ◽  
F. Liu ◽  
B. S. Chen ◽  
J. T. Luo ◽  
...  

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.


Sign in / Sign up

Export Citation Format

Share Document