scholarly journals First Report of Alternaria Black Spot of Pomegranate Caused by Alternaria alternata in Spain

Plant Disease ◽  
2014 ◽  
Vol 98 (5) ◽  
pp. 689-689 ◽  
Author(s):  
M. Berbegal ◽  
I. López-Cortés ◽  
D. Salazar ◽  
D. Gramaje ◽  
A. Pérez-Sierra ◽  
...  
Keyword(s):  
Black Spot ◽  
Fungal Isolate ◽  
Sodium Hypochlorite Solution ◽  
Conidial Suspension ◽  
Sterile Water ◽  
Single Spore ◽  
Beta Tubulin ◽  
Transparent Plastic ◽  
First Report ◽  
Black Spots

Since 2010, a new foliar and fruit disease was observed in pomegranate (Punica granatum L.) orchards in Alicante Province (eastern Spain). Symptoms included black spots on leaves and fruits, as well as chlorosis and premature abscission of leaves. Fungal isolates were obtained by surface-disinfecting small fragments of symptomatic leaf and fruit tissues in 0.5% NaOCl, double-rinsing in sterile water, and plating them onto potato dextrose agar (PDA) amended with 0.5 g/liter of streptomycin sulfate. Gray-to-black colonies were obtained, which were identified as Alternaria sp. based on the dark, brown, obclavate to obpyriform catenulate conidia with longitudinal and transverse septa tapering to a prominent beak attached in chains on a simple and short conidiophore (4). Conidia (n = 100) measured (12.2-) 20.2 (-27.6) × (5.7-) 9.2 (-12.0) μm, and had 3 to 6 transverse and 0 to 5 longitudinal septa. Single spore cultures were obtained and their genomic DNA was extracted. The internal transcribed spacer (ITS) region of rDNA and partial sequences of the beta tubulin gene were amplified and sequenced with primers ITS1-ITS4 and Bt1a-Bt1b, respectively (3). BLAST analysis of the sequences showed that they were 100% identical to a pathogenic A. alternata (Fr.) Keissl. isolate obtained from black spot disease of pomegranate in Israel (Accession No. JN247826.1, ITS and Accession No. JN247836.1, beta tubulin) (2). As all the sequences obtained showed 100% homology, ITS and beta tubulin sequences of a representative isolate (1516B) were submitted to GenBank (KF199871 and KF199872, respectively). In addition, a PCR reaction with specific primers (C_for/C_rev) designed to recognize highly virulent isolates of A. alternata causing black spot of pomegranate was used with all isolates (2). A characteristic fragment of ~950 bp was amplified in two isolates: 1552B and 1707B. Pathogenicity was assessed on plants and detached fruit of pomegranate cv. Mollar (1). Two-year-old pomegranate trees were inoculated with isolates 1552B and 1707B by spraying a conidial suspension (106 conidia/ml) onto the upper and lower leaf surfaces. Five plants per fungal isolate were used and five control plants were sprayed with sterile water. Plants were covered with transparent plastic bags and incubated in a growth chamber for 1 month at 25°C, with a 12-h photoperiod. One-month-old fruits were surface sterilized in 1.5% sodium hypochlorite solution for 1 min and rinsed twice in water. Two filter paper squares (5 × 5 mm) were dipped in the conidial suspensions and placed on the fruit surface. Inoculated fruit were incubated in a humid chamber in the dark at 25°C. Ten fruit per fungal isolate were used and 10 control fruit were inoculated with sterile water. Black spots were visible on inoculated leaves and fruit, 10 and 3 days after inoculation, respectively. Symptoms were not observed on controls. The fungus was re-isolated from leaf and fruit lesions, confirming Koch's postulates. Leaf black spot of pomegranate caused by A. alternata was first described in India in 1988, and later in Israel in 2010 affecting both fruit and leaves (1). To our knowledge, this is the first report of the disease in Spain, where it could represent a threat for pomegranate cultivation due to the increasing amount of area dedicated to this crop. References: (1) D. Ezra et al. Australas. Plant Dis. Notes 5:1, 2010. (2) T. Gat et al. Plant Dis. 96:1513, 2012. (3) N. L. Glass and G. C. Donaldson. Appl. Environ. Microbiol. 61:1323, 1995. (4) E. G. Simmons. Alternaria: An identification manual. CBS Fungal Biodiversity Center, Utrecht, Netherlands, 2007.

scholarly journals First Report of Black Spot Caused by Colletotrichum gloeosporioides on Paper Mulberry in China

Plant Disease ◽  
2011 ◽  
Vol 95 (7) ◽  
pp. 880-880 ◽  
Author(s):  
J. Yan ◽  
P. S. Wu ◽  
H. Z. Du ◽  
Q. E. Zhang
Keyword(s):  
Colletotrichum Gloeosporioides ◽  
Black Spot ◽  
Pathogenic Fungi ◽  
Conidial Suspension ◽  
Stem Cuttings ◽  
Sterile Water ◽  
First Report ◽  
Forest Park ◽  
Plastic Bags ◽  
Black Spots

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.

scholarly journals First Report of Epicoccum layuense Causing Leaf Brown Spot on Camellia oleifera in Hefei, China

Plant Disease ◽  
2022 ◽  
Author(s):  
Xiang Xie ◽  
Shiqiang Zhang ◽  
Qingjie Yu ◽  
Xinye Li ◽  
Yongsheng Liu ◽  
...  
Keyword(s):  
Leaf Spot ◽  
Brown Spot ◽  
Likelihood Method ◽  
Leaf Spot Disease ◽  
Original Strain ◽  
Conidial Suspension ◽  
Camellia Oleifera ◽  
Sterile Water ◽  
Beta Tubulin ◽  
First Report

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.

scholarly journals First Report of Alternaria tenuissima Causing Brown Spot Disease of Angelica dahurica in China

Plant Disease ◽  
2021 ◽  
Author(s):  
Shipeng Han ◽  
Qing Wang ◽  
Shuo Zhang ◽  
Xi Jin ◽  
Zhi Min Hao ◽  
...  
Keyword(s):  
Morphological Characteristics ◽  
Brown Spot ◽  
Angelica Dahurica ◽  
Sterile Water ◽  
Single Spore ◽  
Transparent Plastic ◽  
Alternaria Tenuissima ◽  
First Report ◽  
Spot Disease ◽  
Brown Spot Disease

Angelica dahurica (Fisch. ex Hoffm.) is an abundantly cultivated Chinese herbal medicine plant in China with about 4000 hectares grown, the annual production is up to 24,000 tons. The medicinal part of A. dahurica is its root, and mainly function for treat cold, headache, toothache, rhinitis, diabetes, etc. Besides, A. dahurica is also used as a spice in Asia. In September 2018, brown spot was observed on the leaves of A. dahurica in fields of Anguo City, Hebei Province, China. In the field investigated, the incidence of brown spot disease reached 15%. The infected leaves showed brown spots surrounded with pale yellow edge, resulting in withered of the whole leaf. It seriously endangers the growth of A. dahurica, reducing the yield and quality of medicinal materials, even leading to the death of plants. We isolated the pathogen from 10 leaves with same lesions, the small square leaf pieces of approximately 3 to 5 mm were obtained with the sterile scissors from the junction of infected and healthy tissues, sterilized with sodium hypochlorite (10%) for 1 min followed by washing in sterile water for 3 times, then incubated on potato dextrose agar (PDA) plates at 25°C for 4 days. The culture was transferred to new PDA plates and was cultivated in dark at 25°C for 10 days. A total of 3 species of fungi were isolated, and only one fungus species has been found to be able to cause the original pathological characteristics of A. dahurica leaves through the back-grafting experiment. The mycelium was black and began to sporulate after 8 days on PDA media by single spore separation. Multiple spores joined together to form spores chain. The spores were spindle-shaped, yellow to yellow brown, and size ranged from 45 to 55 × 15 to 20 µm (n=50), with zero to three longitudinal septa and one to five transverse septa. For pathogenicity tests, the spore suspension (3.5×105 spores/mL) were inoculated to healthy plants grown in experimental field, the test was repeated four times, and 10 leaves were inoculated in each repetition, and the sterile water was inoculated as the blank control. Inoculated leaves were covered with transparent plastic bags for 24 h to keep humidity. Nine days later, it was found that there were lesions on the leaves inoculated with the pathogen, and the traits were the same as those in the field, while the controls are healthy. The fungus was consistently isolated from the inoculated leaves. The similar isolates were re-isolated from the inoculated and infected leaves and identified as Alternaria tenuissima by DNA sequencing, fulfilling Koch’s postulates. Fungal genomic DNA was extracted from 7-day-old culture. PCR amplifications were performed using primers ITS1 / ITS4 and TEFF / TEFR respectively (Takahashi et al. 2006, Du 2008). The nucleotide sequence of PCR products, which have been deposited in Genebank under the accession numbers MN153514 and MN735428, showed 99.8%-100% identity with the corresponding sequences of A. tenuissima (MW194297 and MK415954). In order to further identify the pathogen species, we constructed a phylogenetic tree by combining TEF sequence and ITS sequence to distinguish the relationship between the pathogen and other minor species in the genus Alternaria, the isolate was clustered in the Alternaria clade. Therefore, the pathogen was identified as A. tenuissima based on the morphological characteristics and molecular identification. To our knowledge, this is the first report of A. tenuissima causing leaf spot on A. dahurica in China.

scholarly journals First report of black spot on Ophiopogon japonicus caused by Alternaria alternata in Zhejiang Province, China

Plant Disease ◽  
2021 ◽  
Author(s):  
Yiwen Xu ◽  
Zhenyan Cao ◽  
Yihua Yang ◽  
Jintian Tang ◽  
Yang Song ◽  
...  
Keyword(s):  
Alternaria Alternata ◽  
Early Stage ◽  
Black Spot ◽  
Zhejiang Province ◽  
Chemical Components ◽  
Conidial Suspension ◽  
Sterile Water ◽  
Internal Transcribed Spacer Region ◽  
First Report ◽  
Ophiopogon Japonicus

Ophiopogon japonicus (Linn. f.) Ker-Gawl, a traditional Chinese medicinal plant, is widely cultured in China. The root of O. japonicus, is used as the main ingredient in many presriptions. It is rich in chemical components for steroidal saponins, homoisoflavonoids and polysaccharides, which have various pharmacological activities, such as cardiovascular protection, anti-inflammation and anti-diabetes (Chen. et al. 2016). In May and July for 2018 and 2019, the symptoms of black spot on O. japonicus were observed with an incidence of 40% in Cixi County, Zhejiang Province, China. The pathogen mainly infected leaves causing severe black spots, which resulted in a 28% yield loss per acre. At the early stage of the disease, the tip of the leaf began to turn yellow, then the discoloration gradually spread to the base of the leaf and finally the whole leaf turned reddish brown with visible black spot. Symptomatic leaves were cut into small pieces (1.0 cm × 1.0 cm) and disinfected successively by submersion in 75% ethanol for 30s and 1% NaClO for 30s under aseptic conditions. After rinsing with sterile water three times and air drying, segments were placed on potato dextrose agar (PDA), and incubated at 28 ℃ in dark for a week. Then, pathogen on the PDA were transferred onto potato carrot agar (PCA), and incubated at 23 ℃ under the condition of alternation of day (12 h) and night (12 h) for a week. Colonies on PDA were dark gray in the center surrounded by white to gray on the upper side, and black with white margins on the back of the plate. Colonies on PCA were grayish with sparse hyphae. The conidia were obclavate or ellipsoid, pale brown, with 3~8 transverse septa and 1~4 longitudinal septa. Conidiophores were septate, arising singly, and measured (17.0~81.0) × (8.0~23.5) μm, Most conidia had a conical or columnar beak, approximately (0~23.5) × (2.5~9.0) μm in size. According to morphological and cultural characteristics, these isolates were preliminarily identified as Alternaria alternata. A. alternata is one of the most typical plant pathogen, more than 95% of which facultatively parasitize on plants, causing disease in numerous crops. To further confirm identification of pathogens, the internal transcribed spacer region (ITS), translation elongation factor 1-α gene (EF-1α), RNA polymerase Ⅱ second largest subunit (RPB2), major allergen Alt a 1 gene (Alt a 1), Histon 3 gene (His) and plasma membrane ATPase (ATP)were amplified with primer pairs ITS1/ITS4, EF1-728F/EF1-986R, RPB2-7cr/RPB2-5f2, Alt-for/Alt-rev, His 3-F/His 3-R, ATP-F/ATP-R (Lawrence D.P. et al. 2013; Hong, S.G., et al. 2005). BLASTN analysis of NCBI using ITS (Accession NO. MW989987), Alt a1 (Accession NO. MW995953), EF-1α (Accession NO.MW995955), ATP (Accession NO.MW995957), His (Accession NO. MW995954) and RPB2 (Accession NO. MW995956) showed 100%, 100%, 97%, 99%, 99% and 97% identity to A. alternata MN249500.1, MN304714.1, MK637432.1, MK804115.1, MK460236.1, MK605888.1, respectively. To verify pathogenicity, healthy plants (1-year-old) of O. japonicus in ten pots were spray-inoculated with conidial suspension (1 × 106 conidia/ml). Ten plants, which were treated with sterile water, were used as the control. All plants were maintained in a climatic chamber (26 ± 1 ℃, 70–80% relative humidity and a photoperiod of 16:8 [L: D] h). Fourteen days later, all inoculated plants showed typical symptoms of black spot identical to those observed in the fields. Control plants remained symptomless and healthy. The pathogenicity analysis was repeated three times. Pathogens re-isolated from symptomatic plants were identified as A. alternata by morphology observation and sequence analysis. To our knowledge, this is the first report of black spot caused by A. alternata on O. japonicus in Zhejiang, China.

scholarly journals First Report of Phaeoacremonium mortoniae Associated with Grapevine Decline in Iran

Plant Disease ◽  
2011 ◽  
Vol 95 (8) ◽  
pp. 1034-1034 ◽  
Author(s):  
H. Mohammadi
Keyword(s):  
Fungal Pathogens ◽  
Vascular Tissue ◽  
Sodium Hypochlorite Solution ◽  
Malt Extract ◽  
Fars Province ◽  
Distilled Water ◽  
Conidial Suspension ◽  
Single Spore ◽  
First Report ◽  
Grapevine Decline

In July 2009, a survey was conducted in individually owned rooted vineyards in Iran to determine fungal pathogens associated with grapevine decline. Symptoms of grapevine decline such as slow dieback, stunted growth, small chlorotic leaves, and reduced foliage were observed on 7-year-old grapevines (cv. Askari) in Bavanat (Fars Province, southwestern Iran). Internal wood symptoms such as black spots and dark brown-to-black vascular streaking were observed in cross and longitudinal sections of stems and trunks. Wood samples were collected from symptomatic trunks and cordons. The bark of each fragment was removed and 10 thin cross sections (2 to 3 mm thick) were cut from symptomatic vascular tissue of the samples. These disks were immersed in 1.5% sodium hypochlorite solution for 4 min, washed thrice with sterile distilled water, and plated onto malt extract agar (MEA) supplemented with 100 mg liter–1 of streptomycin sulfate. Plates were incubated at 25°C in darkness. All colonies were transferred to potato dextrose agar (PDA) and incubated at 25°C. Five isolates of a Phaeoacremonium sp. were obtained. Single-spore isolates were transferred to PDA, MEA, and oatmeal agar (OA) media and incubated at 25°C for 8 to 16 days in the dark (2). Colonies reached a radius of 9.5 to 12 mm after 8 days of incubation. Colonies were flat and yellowish white on PDA and OA and white-to-pale gray after 16 days of incubation on MEA. Conidiophores were short and unbranched, 14 to 38.5 (23.5) μm long, and often ending in a single terminal phialide. Phialides were terminal or lateral and mostly monophialidic. Conidia were hyaline, oblong to ellipsoidal or reniform, 2 to 6.5 (4.9) μm long, and 1.1 to 1.7 (1.4) μm wide. On the basis of these characteristics, the isolates were identified as Phaeoacremonium mortoniae (1,2). Additionally, identity of the PMH1 isolate was confirmed by sequencing a fragment of the -tubulin gene with primers T1 and Bt2b (GenBank Accession No. JF831449). The sequence of this isolate was identical to the sequence of P. mortoniae (GenBank Accession No. HM116767). Pathogenicity tests were conducted on 2-month-old grapevine seedlings of cv. Askari by watering the roots with 25 ml of a conidial suspension (107 conidia ml–1) harvested from 21-day-old cultures grown on MEA. Controls were inoculated with 25 ml of sterile distilled water. Fifteen replicates were used for each isolate with an equal number of noninoculated plants. All plants were grown under greenhouse conditions (25 to 30°C). Two months after inoculation, inoculated seedlings showed reduced growth, chlorotic leaves, epinasty, severe defoliation, and finally wilting, while control seedlings remained healthy. The fungus was reisolated from internal tissues of the stems of inoculated seedlings. To my knowledge, this is the first report of P. mortoniae causing grapevine decline in Iran. References: (1) M. Groenewald et al. Mycol. Res. 105:651, 2001. (2) L. Mostert et al. Stud. Mycol. 54:1, 2006.

scholarly journals First Report of Black Spot of Acanthus ilicifolius Caused by Fusarium solani in China

Plant Disease ◽  
2014 ◽  
Vol 98 (10) ◽  
pp. 1438-1438 ◽  
Author(s):  
H.-R. Su ◽  
H. He ◽  
Q.-Z. Huang ◽  
N.-H. Lu ◽  
Y.-B. Zhang
Keyword(s):  
Fusarium Solani ◽  
Morphological Characteristics ◽  
Black Spot ◽  
Morphological Observation ◽  
Molecular Characteristics ◽  
Beta Tubulin ◽  
First Report ◽  
Acanthus Ilicifolius ◽  
Black Spots ◽  
Initial Symptoms

Acanthus ilicifolius (family Acanthaceae) grows mainly in tropical coastal areas and is an important medicinal plant that can be used to treat asthma, rheumatism, etc. In July 2013, symptoms of black spots on the leaves of A. ilicifolius were observed in the Mangrove Conservation Area of Shenzhen Futian (22°32′ N, 114°03′ E) and Leizhou peninsula (20°12′~21°35′ N, 109°30′~110°55′ E), Guangdong Province, China. Initial symptoms of the disease were a small, dark brown spots (4 to 5 × 4 to 6 mm) surrounded by a yellow halo (1 to 2 mm in diameter), that would later extend to round or irregular black spots. Leaves eventually turned chlorotic and plants defoliated. Tissues from symptomatic leaves were excised, surface sterilized with 75% ethanol solution (v/v) for 20 s, soaked in 0.1% HgCl2 solution for 45 s, rinsed three times in sterile water, cut into small pieces (2 to 3 mm), plated on potato dextrose agar (PDA), and incubated 3 to 5 days at 28°C without light. Four isolates named from LSL-1 to LSL-4 with different morphological characteristics were obtained. To fulfill Koch's postulates, wounded and non-wounded leaves were inoculated. Fresh wounds were made with a sterile needle on detached leaves and on living plants. Mycelial plugs of each isolate were applied and covered with a piece of wet cotton to maintain moisture. For the control, the healthy leaves were inoculated with PDA plugs. All treatments were incubated at room temperature. Black spots were observed on the wounded leaves inoculated with isolate LSL-1 after 3 days, while the other three isolates and the control remained symptomless, and the pathogen similar to LSL-1 was re-isolated from the diseased leaves. Non-wounded leaves didn't become infected. The pathogenic test was repeated three times with the same conditions, and it was confirmed that LSL-1 was the pathogen causing the black spot of A. ilicifolius. Identification of the pathogen was conducted using morphological and molecular characteristics. Hyphal tips of LSL-1 were transferred to PDA medium in petri dishes for morphological observation. Two types of conidia were observed. The macroconidia were cylindrical to slightly curved, falciform shaped, with two to four septa, and measured 39 to 45 × 4.7 to 5.0 μm. The microconidia were oval to kidney shaped, single celled, 8 to 10 × 2.5 to 3.5 μm. Chlamydospores were also observed, produced singly or in pairs. Based on morphology (1,4), the isolate was tentatively identified as Fusarium solani. For molecular identification, the internal transcribed spacer (ITS) of ribosomal DNA, beta-tubulin gene, and translation elongation factor 1-alpha (EF-1α) gene was amplified using the ITS1/ITS4 (5), ITS4/ITS5 (5), T1/T2 (2) and EF1/EF2 (3) primer pairs. The gene sequences were deposited in GenBank (KJ720639 for the ITS1/ITS4 region, KF826493 for the ITS4/ITS5 region, KJ720638 for the beta-tubulin, and KF826492 for EF-1α region) and showed 99% identity to the F. solani strains (AY633746 for ITS1/ITS4 region, AM412637 for ITS4/ITS5 region, KF255996 for beta-tubulin region, DQ246859 for EF-1α region). According to these results, the pathogen of black spot of A. ilicifolius was identified as F. solani. To the best of our knowledge, this is the first report of F. solani causing black spot of A. ilicifolius in China. References: (1) J. F. Leslie and B. A. Summerell. The Fusarium Laboratory Manual. Blackwell, Ames, IA, 2006. (2) K. O'Donnell and E. Cigelnik. Mol. Phylogenet. Evol. 7:103, 1997. (3) K. O'Donnell et al. Proc. Natl. Acad. Sci. USA. 95:2044, 1998. (4) B. A. Pérez et al. Plant Dis. 91:1053, 2007. (5) A. W. Zhang et al. Plant Dis. 81:1143, 1997.

scholarly journals First Report of Fusarium proliferatum Causing Garlic clove Rot in Russian Federation

Plant Disease ◽  
2021 ◽  
Author(s):  
Olga K Anisimova ◽  
Timofey M Seredin ◽  
Olga A Danilova ◽  
Mikhail Filyushin
Keyword(s):  
Rna Polymerase Ii ◽  
Fruits And Vegetables ◽  
Fusarium Species ◽  
Taxonomic Status ◽  
Basic Research ◽  
Conidial Suspension ◽  
Sterile Water ◽  
Single Spore ◽  
First Report ◽  
Post Harvest

Garlic (Allium sativum L.) is a widely consumed bulbous crop both worldwide and in Russia. About 200,000 tons of garlic is produced in Russia annually (https://rosstat.gov.ru/). Significant pre- and post-harvest losses of garlic regularly occur due to Fusarium sp. (Taylor et al., 2013). Since September 2018, rotting has been observed in Russia during garlic bulb storage (data of the Federal Scientific Vegetable Center, FSVC, Moscow Region). The outer bulb surface looked healthy, but underneath the integumentary scales, the cloves had light brown and brown spots. When grown, diseased plants were characterized by root and bulb disruption and leaf drying; for some cultivars, up to 100% of plants died. In January 2020, cv. Strelets and Dubkovsky bulbs, collected in July 2019, with rot symptoms, were taken from the FSVC storage. Necrotic clove tissue fragments (0.2-0.5 cm) were cut, sanitized with 70% ethanol for 3 min, rinsed with sterile water, and incubated on potato dextrose agar (PDA) with 1 mg/ml ampicillin at 22°C in the dark. Four single-spore cultures were obtained from four diseased bulbs. After 6 days of incubation, the isolates produced abundant aerial white mycelia and acquired a purple pigmentation. The hyphae were hyaline with septation. All isolates (Dubkovsky, Dubkovsky 2, Strelets, and Strelets 2) produced numerous oval unicellular microconidia without septa, 4.1 to 11.6 × 1.3 to 3.4 µm (n = 50) and very few macroconidia with 3-4 septa (21 to 26 × 3 to 4 µm (n = 30)), narrowed at both ends. The cultural and conidial characteristics of the isolates corresponded to Fusarium species (Leslie and Summerell 2006). To determine the species, DNA was extracted from four isolates, and the internal transcribed spacer (ITS), and genes of translation elongation factor 1α (EF1α) and subunits 1 and 2 of DNA-directed RNA polymerase II (RPB1 and RPB2) were amplified and sequenced with primers ITS1/ITS4 (White et al. 1990), EF1/EF2 (O'Donnell et al. 1998a), RPB1-F5/RPB1-R8 (O’Donnell et al. 2010) and fRPB2-5F/fRPB2-7cR (Liu et al. 1999). The obtained sequences were identical for all four isolates. The isolate Strelets sequences were deposited in NCBI GenBank (MW149129 (ITS), MW161161 (EF1α), MW413302 (RPB1) and MW413303 (RPB2)); their analysis in MLST (http://fusarium.mycobank.org) showed 98.8-99.8% similarity to F. proliferatum (NRRL 13582, 13598 and others), which is part of the F. fujikuroi complex (O'Donnell et al. 1998b). The test on pathogenicity was performed two times according to (Leyronas et al. 2018). For this, three replicates of 10 cloves (cv. Strelets) were soaked in a conidial suspension (~106 conidia/ml; Strelets isolate) for 24 h. Ten control cloves were soaked in sterile water. The cloves were incubated on Petri dishes (5 cloves on a dish; on filter paper wettened with sterile water) in the dark at 23°C. After 5 days, brown lesions and white mycelium developed on the surface of the treated cloves. The taxonomic status of the fungus isolated from necrotic tissue was determined as F. proliferatum according to the ITS, EF1α, RPB1 and RPB2 analysis. Garlic basal and bulb rot is known to be caused by F. oxysporum f. sp. cepae and F. proliferatum (Snowdon 1990). This study is the first report of F. proliferatum causing rot of garlic bulbs during storage in Russia. F. proliferatum produces a variety of mycotoxins during bulb infestation, and our findings are important for diagnosing a Fusarium disease and the use of garlic crop in culinary and medicine. Funding The reported study was funded by Russian Foundation for Basic Research, project number 20-316-70009. References: Leslie, J. F., and Summerell, B. A. 2006. Page 224 in: The Fusarium Laboratory Manual. Blackwell, Oxford, UK. https://doi.org/10.1002/9780470278376 Leyronas, C., et al. 2018. Plant Dis. 102:2658 https://doi.org/10.1094/PDIS-06-18-0962-PDN Liu, Y.J. et al. 1999. Mol. Biol. Evol. 16: 1799 https://doi.org/10.1093/oxfordjournals.molbev.a026092 O'Donnell, K, et al. 1998a. Proc Natl Acad Sci USA. 95(5):2044. https://doi.org/10.1073/pnas.95.5.2044. O’Donnell, et al. 1998b. Mycologia 90:465 O’Donnell, K., et al. 2010. J. Clin. Microbiol., 48: 3708 https://doi.org/10.1128/JCM.00989-10 Snowdon, A. L. Pages 250–252 in: A Color Atlas of Post-Harvest Diseases and Disorders of Fruits and Vegetables. Vol. 1. 1990. Wolfe Scientific, London. Taylor, A, et al. 2013. Plant Pathol. 62:103. https://doi.org/10.1111/j.1365-3059.2012.02624.x White, T. J., et al. 1990. Page 315 in: PCR Protocols: A Guide to Methods and Applications. Academic Press, San Diego, CA.

scholarly journals First Report of Maize Stalk Rot Caused by Fusarium nelsonii in China

Plant Disease ◽  
2021 ◽  
Author(s):  
Xiaojie Zhang ◽  
Cheng Guo ◽  
Chunming Wang ◽  
Tianwang Zhou
Keyword(s):  
Fusarium Species ◽  
Morphological Characteristics ◽  
Molecular Characteristics ◽  
Conidial Suspension ◽  
Basal Cells ◽  
Sterile Water ◽  
Single Spore ◽  
First Report ◽  
Stalk Rot ◽  
Maize Plants

Maize (Zea Mays L.) is one of the main crops in Ningxia Province, China, and stalk rot has become a serious disease of maize in this area. Infected plants showed softening of the stalks at lower internodes, which lodged easily and died prematurely during grain filling, and the pith tissue internally appeared to be disintegrating and slightly brown to reddish. In September 2018, symptomatic tissue was collected from seventeen locations in Ningxia. The incidence ranged from 5% to 40% in surveyed fields, reaching as high as 86% in certain plots. The discolored stalk pith tissues from the lesion region were cut into small pieces (approximately 0.5 × 0.2 cm), superficially disinfected with 75% ethanol for 1 min and rinsed three times with sterile water before plating on potato dextrose agar (PDA) medium with chloromycetin. The purified strains were obtained by single-spore separation and transferred to PDA and carnation leaf agar (CLA) medium. Morphological and molecular characteristics confirmed the presence of nine Fusarium species in these samples, including Fusarium graminearum species complex and Fusarium verticillioides. Four isolates of Fusarium nelsonii were recovered from samples collected in Shizuishan and Wuzhong. On PDA plates, the floccose to powdery, white to rose-colored aerial mycelia were produced and covered plates after 8 days of incubation, producing abundant mesoconidia and chlamydospores. Mesoconidia were fusiform or lanceolate until slightly curved with 0-3 septa, and chlamydospores were initially smooth and transparent, and became verrucous and light brown. Macroconidia produced in CLA were straight or curved and falcate, usually having 3-5 septa, with beak-shaped strongly curved apical cells and foot-shaped basal cells. Two isolates (SS-1-7 and ZY-2-2) were selected for molecular identification, and the total DNA was extracted using a fungal genomic DNA separation kit (Sangon Biotechnology, Shanghai, China). Sequence comparison of EF-1α (GenBank accession numbers MW294197 and MW294198) and RPB2 (Accession MW294176 and MW294177) genes showed 97% homology with the sequences of F. nelsonii reported in GenBank (accession MN120760 for TEF and accession MN120740 for RPB2). Pathogenicity tests with two isolates (SS-1-7 and ZY-2-2) were performed by individually inoculating five 10-leaf stage maize plants at between the 2nd and 3rd stem nodes from the soil level with 20 μl conidial suspension at a concentration of 106 conidia/ml as described by Zhang et al. (2016). Five maize plants inoculated with sterile water were used as controls. The inoculated plants were kept at 25 ± 0.5°C in the greenhouse with a photoperiod of 12 h. After 30 days, all plants inoculated with the conidial suspension formed an internal dark brown necrotic area around the inoculation site, whereas the control plants showed no symptoms. The pathogen was re-isolated from the necrotic tissue of the inoculated plants and identified by morphological characteristics as F. nelsonii. This species was first described by Marasas et al. (1998), and it is expanding its host range and has been isolated from sorghum, Medicago, wheat, and cucumber (Ahmad et al. 2020). The pathogen should be paid more attention owing to a serious risk of trichothecene and aflatoxin contamination (Astoreca et al. 2019; Lincy et al. 2011). To our knowledge, this is the first report of maize stalk rot caused by F. nelsonii in China. References: Ahmad, A., et al. 2020. Plant disease.1542 https://doi.org/10.1094/PDIS-11-19-2511-PDN Astoreca, A. L., et al. 2019. Eur. J. Plant Pathol. 155:381. Lincy, S. V., et al. 2011. World J. Microbiol. Biotechnol. 27:981. Marasas, W. F. O., et al. 1998. Mycologia 90:505. Zhang, Y., et al. 2016. PLoS Pathog. 12:e1005485. Funding: This research was financially supported by National R & D Plan of China (No.2019QZKK0303); Ningxia Agriculture and Forestry Academy Science and Technology Cooperation Project (DW-X-2018019)

scholarly journals First Report of Colletotrichum fioriniae and C. godetiae Causing Apple Bitter Rot in Slovenia

Plant Disease ◽  
2014 ◽  
Vol 98 (9) ◽  
pp. 1282-1282 ◽  
Author(s):  
A. Munda
Keyword(s):  
Growth Rate ◽  
Economic Losses ◽  
Conidial Suspension ◽  
Single Spore ◽  
Average Growth Rate ◽  
Average Growth ◽  
First Report ◽  
Bitter Rot ◽  
Black Spots ◽  
Apple Bitter Rot

Bitter rot is a common disease of apple (Malus domestica Borkh.) in several apple growing regions worldwide. The disease affects the fruit pre-harvest in orchards and/or post-harvest in storage, resulting in considerable economic losses. The most frequently reported causal agents belong to Colletotrichum acutatum and C. gloeosporioides species complexes. Apple bitter rot was observed in Slovenia in 2011 and 2012 at harvest in three commercial apple orchards near Ljubljana. Symptoms were observed on approximately 10% of fruits in the orchard, and included circular, brown, slightly sunken necrotic lesions on fruit surface. When placed in high humidity, acervuli with orange conidial masses developed on the lesions. Eleven isolates were obtained from symptomatic apples by culturing pieces of necrotic tissue on potato dextrose agar (PDA). Single spore isolates were prepared and grown at 21°C and a 12-h photoperiod for 10 days. Total DNA was extracted and fragment of the β-tubulin-2 gene (exons 2-6) was amplified with primer pair T1 (3) and Bt-2b (2), and was sequenced (Macrogen, The Netherlands). BLAST analysis showed that six isolates had 100% identity to C. fioriniae (Marcelino & Gouli) R.G. Shivas & Y.P. Tan (4) including the ex-holotype strain CBS 128517. The remaining isolates showed 100% identity to sequences reported for C. godetiae Neerg. (1), including the ex-type strain CBS 133.44. One sequence of each species was deposited in GenBank (KJ650030 and KJ650029). Morphological characteristics of two isolates per species were recorded after 10 days of incubation on PDA at 21°C. C. fioriniae colonies were white to light gray on the upper side and brownish pink to vinaceous with black spots on reverse. Average growth rate was 56.5 mm in 7 days. Conidia were cylindrical to fusiform, pointed at both ends, and measured 7.5 to 16.7 μm (mean 13.1 μm) × 3.5 to 4.9 μm (mean 4.1 μm). C. godetiae colonies were light gray on the upper side and gray with black spots on reverse. Average growth rate was 48.5 mm in 7 days. Conidia were cylindrical to fusiform, pointed at one or both ends, and measured 7.9 to 18.1 μm (mean 12.2 μm) × 3.4 to 4.9 μm (mean 4.2 μm). Pathogenicity of both species was tested by inoculating surface-sterilized ‘Gala’ and ‘Golden Delicious’ apples with 10 μl of a conidial suspension (105 conidia ml–1) obtained from single spore cultures. Five mature apples were wound-inoculated with one isolate of each species and sterile distilled water was used for controls. After 10 days of incubation at 23°C and 100% relative humidity, symptoms, identical to those observed initially, developed around the inoculation point, while controls showed no symptoms. C. fioriniae and C. godetiae were re-isolated from inoculated apples. To our knowledge, this is the first report of apple bitter rot associated with C. fioriniae and C. godetiae in Slovenia. The disease can pose a threat to our apple production and cause substantial losses during storage. References: (1) U. Damm et al. Stud. Mycol. 73:37, 2012. (2) N. L. Glass and G. Donaldson. Appl. Environ. Microbiol. 61:1323, 1995. (3) K. O'Donnell and E. Cigelnik. Mol. Phylogenet. Evol. 7:103, 1997. (4) R. G. Shivas and Y. P. Tan. Fungal Divers. 39:111, 2009.

scholarly journals First Report of Peanut Pod Rot Caused by Neocosmospora vasinfecta in Northern China

Plant Disease ◽  
2012 ◽  
Vol 96 (3) ◽  
pp. 455-455 ◽  
Author(s):  
W. M. Sun ◽  
L. N. Feng ◽  
W. Guo ◽  
D. Q. Liu ◽  
Y. N. Li ◽  
...  
Keyword(s):  
Morphological Characteristics ◽  
Its Region ◽  
Northern China ◽  
Conidial Suspension ◽  
Sterile Water ◽  
Emerg Infect ◽  
First Report ◽  
Black Spots ◽  
Pathogenicity Tests ◽  
Average Size

From 2006 to 2010, peanut (Arachis hypogaea) pod rot became more prevalent in northern China, especially in the Sha River drainage area. The incidence of pod rot ranged from 30 to 100%. Typical symptoms were black rot of the pods, but no obvious morphological abnormality of the aboveground parts of infected plants was observed. Brown or black spots appeared on many pods when initially infected and then all peanut pods became black and rotten. The same fungus was isolated from 54 surface-disinfested lesions (85.2% of all lesions) on potato dextrose agar (PDA) media. One isolate, designated as HBXLb, was chosen for further characterization. In culture, both anamorph and teleomorph were present. Mycelia of the fungus grew quickly (colonies were 3.2 cm in diameter in 3 days) and became white and floccose on PDA at 28°C. The hyaline, elongated-to-cylindrical conidia aggregated on the slimy heads of conidiogenous cells that developed on undifferentiated hyphae after incubation for 3 to 4 days. Conidial sizes varied from 5 to 10 × 1.5 to 3 μm (n = 50) and were mostly single celled. Some conidia appeared slightly curved. The morphology was consistent with Acremonium spp. Numerous ascomata (perithecia) formed within 10 to 14 days when incubated at 28°C under light and dark conditions. Perithecia were orange-brown, strawberry shaped (300 to 400 μm in diameter), and ostiolate on the top. Cylindrical asci, with an average size of 90 to 110 × 7.5 to 9 μm, were present inside the ascomata with each containing eight ascospores in a row. The ascospores were brownish, spherical to ellipsoidal, and 10 to 15 × 8 to 12 μm. The cultural and morphological characteristics of isolate HBXLb matched the description of N. vasinfecta (2). The internal transcribed spacer (ITS) region of rDNA was amplified by the primer pairs ITS4/ITS5. A 525-bp amplicon (ITS4-5.8s-ITS5) was obtained and sequenced (GenBank Accession No. HM461901). The ITS sequence was a 100% match to N. vasinfecta strain N-JXLN01 (GenBank Accession No. GU213063) by BLASTn in GenBank. Pathogenicity tests were conducted on detached pods of peanut cultivar Jihua 4. Forty surface-disinfested peanut pods were soaked in a conidial suspension (105 conidia per ml) for 2 min and 40 pods were soaked in sterile water as a control. Then all peanut pods were maintained in moist petri dishes under darkness for 14 days at 28°C. Brown or black spots appeared on all pods inoculated with the fungus within 10 days, while the controls remained healthy. Symptoms were similar to those originally observed in the field, and N. vasinfecta could be reisolated from all infected pods. This fungus previously has been reported as the pathogen of foot rot of peanut in South Africa (1), Taiwan (4), and Australia (3). To our knowledge, this is the first report of peanut pod rot caused by N. vasinfecta in China. References: (1) S. W. Baard et al. Phytophylactica 17:49, 1985. (2) O. A. Cornely et al. Emerg. Infect. Dis. 7:149, 2001. (3) M. F. Fuhlbohm et al. Australas. Plant Dis. Notes 2:3, 2007. (4) J. W. Huang et al. Plant Pathol. Bull. 1:203, 1992.

Sign in / Sign up

Export Citation Format

Share Document