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Since the emergence of Ug99 wheat stem rust in Uganda in 1998 (Pretorius et al. 2000), the threat of movement into South Asia has been a concern due to long-distance dispersal capacity of airborne spores (Brown and Hovmøller 2002; Singh et al. 2008; Meyer et al. 2017). Increased preparedness by comprehensive rust surveillance efforts and development and deployment of resistant cultivars in advance of an incursion into South Asia has been one of the success stories of the Borlaug Global Rust Initiative (Sharma et al. 2013). In November 2023, an off-season rust survey was conducted in Marpha, Gandaki and Bagmati provinces in Nepal. Rust was only observed at two sites, Dangdunge of Dolakha district and Mude of Sindhupalchok district, where spring wheat was grown as fodder crop outside the main cropping season. Rust infected wheat leaves (10-15 leaves per site) were air dried and sealed in envelopes that were shipped under permit to the Global Rust Reference Center, Denmark. Bulk samples of stem rust, Puccinia graminis f.sp. tritici (Pgt), were recovered from both envelopes, and single pustule isolates were raised and multiplied on Morocco and McNair. Meanwhile, specimens of dry leaves were subjected to SSR genotyping according to standard procedures (Patpour et al. 2022). One distinct multi-locus Pgt genotype was observed, identical to and representing 99% of Ug99 isolates within Clade I collected in East Africa between 2012-2022. A Pgt single pustule isolate from each of the sampling sites were inoculated onto 20 internationally agreed stem rust differential lines using standard procedures, and 14 supplementary lines providing additional resolution of pathogen virulence (Patpour et al. 2022). The pathotyping was repeated in two independent experiments, which resulted in the infection type pattern of Pgt race TTKTT (Supplementary Table 1). Additional independent SSR genotype assays of recovered isolates confirmed the prevalent genotype of Clade I (Patpour et al. 2022; Szabo et al. 2022). This first detection of Ug99 race TTKTT in South Asia emphasizes the need for continued coordinated international surveillance efforts and utilization of diverse sources of resistance to control stem rust in wheat. New surveillance efforts in Nepal during February-March 2024 did not reveal additional cases of wheat stem rust. However, more detailed and sustained rust surveillance efforts, assessment of the vulnerability of current wheat crops to Ug99 and other races of stem-, stripe/yellow- and leaf rust, as well as intensified breeding for rust resistance throughout the region is strongly recommended to meet current and future plant health risks.
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Cucumber green mottle mosaic virus (CGMMV) was first discovered on cucumber in the United Kingdom in 1935 (Ainsworth, 1935), and has spread worldwide except to Antarctica (Jones, 2021). Given its extensive damage, it is considered an important pathogen on global cucurbit plants and fruit crops. In China, CGMMV was first reported on pumpkin in Guangxi Province in 2003 (Qin et al., 2005), and occurred on 34 plants species across 23 provinces (Liu et al., 2016). Cynanchum rostellatum is a member of the family Apocynaceae. In July 2021, leaves of C. rostellatum exhibiting virus-like symptoms (yellowing, severe crinkling, deformation) were observed and collected in Liaoning Province, China. Aphids were also observed on the leaves and stems (Fig. S1) of the plants and were collected. Total RNA was extracted from diseased leaves following the CTAB method, followed by the depletion of ribosomal RNAs (rRNA) with TIANSeq rRNA Depletion Kit (Tiangen, China). The RNAs were, then processed into a DNBSEQ LncRNA-Seq library, and sequenced on the MGISEQ-2000 platform at BGI Genomics (Wuhan, China). A total of 106.98 M clean reads were obtained after data filtering using SOAPnuke software (BGI, China). The clean reads were assembled into contigs using CLC Genomics Workbench 11 (Qiagen, USA) and Trinity v2.0.6 (Haas et al., 2013). A contig (4,760 reads, average coverage:73.76) of 6,391 nucleotides was found to share the highest sequence identity (99.83%) with CGMMV isolate GDLZ (MK933286), irrespective of other virus-like contigs related to Polerovirus and Totivirus. Based on the genome of GDLZ isolate, seven specific primers (Table S1) were designed to amplify the full viral genomic sequences using a PrimeScriptTM One-Step RT-PCR Kit. Seven expected amplicons were obtained, cloned, and sequenced. The complete genome was determined to be 6,423 nucleotides (GenBank accession number OR854819) in length and designated as LNMJ isolate. LNMJ shared 96.8%-99.7% nucleotide sequence identities with CGMMV isolates from China. Phylogenetic analysis based on the complete genome sequences showed that LNMJ clustered together with CGMMV isolates hn (GenBank accession number KC851866), GDLZ (GenBank accession number MK933286), and JD8 (GenBank accession number KM873784) from China. The specific primers LM-TJ-3F/3R were designed to determine the virus-symptom association for LNMJ, and all twelve symptomatic C. rostellatum plants collected from fields tested positive for LNMJ. Two out of six randomly selected aphids from the diseased plants also tested positive. To further prove its infectivity, LNMJ was inoculated mechanically onto ten healthy Nicotiana benthamiana plants, and the results indicated a high infection rate of 80% (8/10), at 30 days post-inoculation despite no distinct symptoms observed. To our knowledge, this is the first report of the natural infection of C. rostellatum plants with CGMMV. C. rostellatum is a widespread herb in China (Wei et al., 2019) and more surveys are needed to determine the distribution of CGMMV. The habitats of C. rostellatum span diverse agroecological zones, and thus our study underscores the potential spillover of CGMMV to neighboring crops as a significant risk.
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Smooth bromegrass (Bromus inermis Leyss.) is an important forage crop in northern China. In July 2021, leaf spot symptoms were observed on smooth bromegrass in Ewenki Banner, Hulunbuir, Inner Mongolia. In an area of approximately 0.12 hectares, 95% disease incidence was observed. Ten diseased plants were collected for pathogen isolation. Leaf tissues near the lesions were cut into 5 × 5 mm pieces, surface-disinfested in 75% ethanol for 3 min, and rinsed with sterile distilled water. The pieces were placed on water agar in petri plates and incubated at 25â for three days. The resulting colonies were flushed with sterile water and a spore suspension was serially diluted and plated on potato dextrose agar (PDA). A single-spore colony was obtained. Ten isolates were obtained and designated HE1 to HE10. The colony morphology was identical for all isolates, grayish white in color on the upper surface and light black on the underside. The mycelia were light gray and velvety. Conidia were light brown to brown in color and oblate, oblong or oval. The conidial dimensions were typically between 15 to 43 µm by 8 to 9 µm in size. The conidia possessed one to six transverse septa, with slight to distinct constrictions at each division, and zero to two longitudinal septa. These morphological characteristics resembled Alternaria alternata (Fr.) Keissl.. DNA was extracted from three isolates, HE3, HE4 and HE5, using the CTAB method. Polymerase chain reaction (PCR) was performed on the extracted DNA with a set of primers ITS1/ITS4, H31a/H31b, gpd1/gpd2, TEF1-728F/TEF1-986R, and RPB2-5F2/fRPB2-7cR. The amplicon sequences from the three isolates were analyzed using the BLAST in GenBank (https://www.ncbi.nlm.nih.gov/). The results showed a high sequence identity, ranging from 99 to 100%, with the A. alternata strain YTMZ-20-2 across all the genetic markers tested. The strong match reinforced the identification of the strains as A. alternata. The sequences were deposited in GenBank (Table S1). The three fungal isolates were identified as A. alternata based on their morphological and genetic data. To conduct Koch's postulates, the representative isolate HE4 was used. Smooth bromegrass seed was soaked in water for four days and sown in potting soil contained in plastic pots (10 cm diameter × 15 cm height, five seeds/pot) in a greenhouse under a 16-h photoperiod at temperatures between 20 to 25°C and 60% relative humidity. When the plants reached a height of approximately 20 cm, the plants in three pots (replicates) were sprayed with a spore suspension (106 conidial/ml) at 10 ml/pot, and three pots were sprayed with sterile water for control. Five days after inoculation, the plants exhibited leaf spot symptoms similar to those previously described, while the control plants remained unaffected. The causative fungus was successfully re-isolated from the diseased plants and confirmed morphologically and molecularly on its identity as described above. This experiment was independently conducted three times. This is the first report of A. alternata causing leaf spot on smooth bromegrass in China. Since there is risk that the disease could seriously reduce the yield of the forage crop smooth bromegrass, further research is needed.
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Passion fruit (Passiflora edulis Sims.) is popular for its rich taste and nutritional value. The planting area of passion fruit in Guangxi has reached 24,300 ha, with an annual output of 380,000 t (Qian 2023). In March 2023, leave spots on more than half of the plants (cv. Qinmi "NO.9"). Moreover, the incidence of disease on the leaves was approximately 20% in Shabu Town, Qinnan District, Qinzhou City, Guangxi, China (N20Ë54'-22Ë41', E107Ë27'-109Ë56'). Leaf diseases were orbicular or irregular in shape, white, whitish-grey, yellowish, or gray in color. When leaves were severely affected, larger blotches were formed with yellow halos. For pathogen isolation, three diseased leaf samples were collected from three gardens, respectively, and 5×5 mm tissues were cut from infected margins, surface-disinfected in 75% ethanol for 15 s, followed by 2% sodium hypochlorite for 1 min, rinsed three times with sterile water, and incubated on PDA at 25°C under 12/12 h light/darkness. After 5 days, ninety cultures were isolated, sixty isolates with similar morphology were retained, and three representative isolates BY-1, BY-2, and BY-4 were randomly selected for further study. On PDA, colonies of the three isolates displayed white or grayish-white. Conidia were single-celled, hyaline, and cylindrical, measuring 17.3±1.5 × 6.3±0.7 µm, 17.8±1.7 × 6.0±0.6 µm, and 16.3±1.4 × 6.4±0.6 µm (n=90) for BY-1, BY-2, and BY-4, respectively. Appressoria were single, brown or black, and irregular in shape, measuring 10.2±1.1×6.5±0.5 µm, 10.5±1.3×7.3±0.6, and 10.9±0.8×7.0±0.8 (n=90) for BY-1, BY-2, and BY-4, respectively. These morphological characteristics were similar to Colletotrichum spp. as previously described (Damm et al. 2019). The isolates were further identified by sequencing the internal transcribed spacer (ITS-ITS1/ITS4), glyceraldehyde-3-phosphate dehydrogenase (GAPDH-GDF/GDR), actin (ACT-512F/783R), partial sequences of the chitin synthase 1 (CHS-1-79F/354R), and beta-tubulin 2 (TUB2-T1/Bt2b) (Zhang et al. 2023). All sequences were deposited in GenBank (ITS: OR741759 to OR741761, GAPDH: OR767654 to OR767656, ACT: OR767657 to OR767659, CHS-1: OR767660 to OR767662, TUB2: OR767651 to OR767653). A phylogenetic tree was built with RAxML version 8.2.10 based on concatenated sequences of ITS-GAPDH-ACT-CHS-1-TUB2. The results revealed that the three isolates clustered with C. plurivorum. To confirm the pathogenicity of the three isolates, attached leaves of healthy 5-month-old passion fruit plants were injured in the middle region with sterile toothpicks and inoculated with 20 µL of spore suspension (106 conidia/mL), and the noninoculated control received 0.05% Tween-20 (6 leaves/plant, 3 plants/treatment). The inoculated plants were kept in a greenhouse at 25°C and covered with plastic bags to maintain high humidity. After 9 days, all inoculated leaves were symptomatic, whereas no symptoms were observed in the control. C. plurivorum was reisolated from infected leaves, confirming Koch's postulates. C. plurivorum has been reported to infect Abelmoschus esculentus (Batista et al. 2020) and Carya illinoinensis in China (Zhang et al. 2023). However, this is the first report of anthracnose caused by C. plurivorum on passion fruit in China. The results can provide a robust basis for scientific prevention and control of anthracnose.
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Cactus pear var. miúda (Nopalea cochenillifera L. Salm-Dyck) is an important crop for the Northeast region of Brazil, composing one of the main sources of animal feed. By April 2021, cladode rot caused death of several cactus pear plants in a production area located in Itaporanga, Paraíba state, Brazil (7°21'55.35" S and 38°11'38.68" W). The infected cladodes showed brown circular necrotic spots, and soft rot with perforations that extended throughout the cladode, followed by tipping over and death of the infected plants. The incidence of the disease ranged from 10 to 30% of the plants. Bisifusarium strains were isolated and cultured on potato dextrose agar (PDA) and syntetic-nutrient-poor-agar (SNA). The colonies showed purple color on PDA. On SNA, macroconidia (n = 100) were abundant, hyaline, slightly falcate, three-septate, measuring 11.0-23.1 x 2.3-4.1 µm. Microconidia (n = 100) were oval, generally aseptate, measuring 4.1-8.7 x 2.3-3.0 µm. Conidiogenic cells formed into short monophialides. Chlamydospores were not observed. According to these morphological features, the pathogen was initially identified as Bisifusarium lunatum (Gryzenhoutm et al. 2017). For further confirmation of the identification, the partial sequences of translation elongation factor 1-alpha (TEF1-α) and the second largest subunit of RNA polymerase II (RPB2) genes were sequenced for a representative isolate (CMA 34: GenBank accession no: TEF1-α: OR536502; and RPB2: OR553509) and compared to other Bisifusarium species from GenBank database. Subsequently, it was subjected to a phylogenetic analysis of maximum likelihood including previously published sequences. According to BLAST searches, the TEF1-α and RPB2 sequences were 99% (637/640 nt) and 100% (312/312 nt) similar to B. lunatum (COUFAL0213: TEF1-α (MK640219), and RPB2 (MK301291)), respectively. The isolate was also clustered in a clade containing the ex-type of B. lunatum with 100% support (SH-aLRT and UFboot), being confidently assigned to this species. The pathogenicity test was performed after Medeiros et al. (2015), by using healthy two months old cactus pear seedlings (n = 10) cultivated in a greenhouse. Sterile toothpicks were distributed over colonies of the representative isolate grown on PDA at 25 ± 2 °C for seven days. Seedling cladodes were stuck with the toothpicks, moistened with sterile water and covered with transparent plastic bags for 24h, thus simulating a humid chamber. Following three months, all control plants (stuck with sterile toothpicks) remained healthy, while those inoculated with the representative isolate exhibited rot symptoms. This test was performed twice. B. lunatum was reisolated from symptomatic cladodes and identified as previously described, thus fulfilling the Koch's postulates. To our best knowledge, this is the first report of B. lunatum causing soft rot on N. cochenillifera in Brazil. Besides N. cochenillifera, this species was also reported on Opuntia ficus-indica in India (Gryzenhoutm et al., 2017), which raises concern regarding its ability to infect other forage sources for cattle feed in Brazilian semiarid regions. The present study highlights that the precise identification of B. lunatum is a key factor to adjust control strategies and management of the disease to prevent the spread of this disease to prevent its spread to other crops.
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Mongolian snake gourd (Trichosanthes kirilowii Maxim) is a precious traditional Chinese herbal medicine and perennial liana plant in the family Cucurbitaceae, and the root, fruit, seed and peel all possess the medicinal value (Zhang et al. 2016). During 2021-2022, the root rot was observed in a 20-ha commercial farm and became a major disease limiting Mongolian snake gourd production in Zhenjiang City, Jiangsu Province, China (119°27'E, 32°12'N). Field investigations showed that disease incidence was estimated at approximately 70% and resulted in up to a 50% decrease in total production. Symptoms on snake gourd initially appeared as yellow mottling produced on the surface of the infected new leaves and systemic wilting on the upper leaves. With the development of the infection, the base of the stem began to brown and die, and has lots of filamentous hyphae attached to it. As the lesions coalesced, the whole plant gradually wilted and died. In order to explore the cause of the disease, six infected plants were randomly collected from the commercial farm. The roots of the plants were rinsed in sterile water to remove soil debris, and symptomatic roots were surface sterilized using 75% ethanol for 60s, rinsed three times in sterile water, then plated onto the potato dextrose agar (PDA), and incubated at 25°C for 3 days in the dark. White fungal colonies grew from the tissue pieces, then hyphal tips were transferred to PDA to obtain pure cultures. A total of six isolates with similar morphological characteristics were obtained from six of the infected plants. One representative isolate GL21091501 was chosen for further analysis. At 5 days after inoculation, the colonies on PDA began to grow as white, and with the incubated time was extended, the hyphae turned yellowish-brown with a yellowish-brown center on the reverse side. Observations under a light microscope showed conidia that were falculate, slender and slightly curved, and the cells at both ends were sharp. Macroconidia had four to five septa, measuring 22.4 ~ 33.5 µm. Microconidia without septa, elliptical, measuring 4.36 ~ 9.88 µm. On the tip of aerial hyphae can form conidiophore, and produce macroconidia (Wonglom et al. 2020; Lin et al 2018). The pathogen was typical Fusarium spp. by morphological characteristics. To identify the species level, the mycelia of the representative isolate GL21091501 was used for genomic DNA extraction (Tiangen, China). The internal transcribed spacer (ITS) region and partial translational elongation factor subunit 1-α (TEF-1α) of the cultures were amplified and sequenced using the primer pairs EF1/EF2 and ITS1/ITS4 respectively (White et al. 1990; O'Donnell et al. 1998). The obtained sequences were deposited in GenBank under the accesion numbers OP311409 and OP311410. BLAST searches of the deposited sequences showed 100% identity with the existing TEF sequences (MT563420.1) and ITS sequences (MN539094.1) of Fusarium incarnatum isolates in GenBank. In addition, BLASTn analysis of these in FUSARIUM-ID database showed 99.62% and 100% similarity with F. incarnatum-equiseti species complex (FIESC) NRRL13379 [ITS] and NRRL34004 [TEF-1α]), respectively. Phylogenetic analysis was conducted with the neighbor-joining (NJ) method using MEGA6.0 (Tamura et al. 2007). Combined phylogenetic analysis revealed that the isolate shared a common clade with the reference sequence of F. incarnatum in the F. incarnatum-equiseti species complex. Therefore, according to morphological and molecular characteristics confirming the identity of the isolated pathogen as F. incarnatum. In order to fulfill Koch's postulates, fresh isolate GL21091501 hyphae were cut into 3 × 3 mm agar plugs from a 7 cm PDA plate and inoculated in 200 mL the Potato Dextrose (PD) liquid medium on a shaker at 170 rpm, 25°C for 5 days. Spores were filtered through four layers of gauze, adjusted to 1 × 106 spores/ml with sterilized water. Then Mongolian snake gourd seedlings at the two true leaves stage were transplanted in (15-cm-diameter) pots (1 plants/pot) filled with mixture of sterilized soil: vermiculite: pearlite (2:1:1, v/v). The pathogenicity test was conducted on seedlings plants by root irrigation method (50 ml/plant, 1×106 conidia/mL), control plants were irrigation with sterilized water (50 ml/plant). Each treatment was repeated three times. After 15 days, all inoculated plants showed the same symptoms observed on the original diseased plants in the field, whereas, the control plants remained symptomless. The same pathogen was successfully re-isolated from the inoculated plants, and identical to those of the originals based on morphological and sequence data. To our knowledge, this is the first report of F. incarnatum causing root rot on Mongolian snake gourd in China. F. incarnatum has been reported to cause root and stem rot in many plants worldwide, including muskmelon (Wonglom et al. 2020), Cucurbita pepo (Thomas et al. 2019) and Bambusa multiplex (Lin et al. 2018). This discovery is of great importance for Mongolian snake gourd planters because the fungus is accurately identified in a certain geographic area and effective field management strategies are necessary to control this disease.
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Early leaf spot (Passalora arachidicola) and late leaf spot (Nothopassalora personata) are two of the most economically important foliar fungal diseases of peanut, often requiring seven to eight fungicide applications to protect against defoliation and yield loss. Rust (Puccinia arachidis) may also cause significant defoliation depending on season and location. Sensor technologies are increasingly being utilized to objectively monitor plant disease epidemics for research and supporting integrated management decisions. This study aimed to develop an algorithm to quantify peanut disease defoliation using multispectral imagery captured by an unmanned aircraft system. The algorithm combined the Green Normalized Difference Vegetation Index and the Modified Soil-Adjusted Vegetation Index and included calibration to site-specific peak canopy growth. Beta regression was used to train a model for percent net defoliation with observed visual estimations of the variety 'GA-06G' (0 to 95%) as the target and imagery as the predictor (train: pseudo-R2 = 0.71, test k-fold cross-validation: R2 = 0.84 and RMSE = 4.0%). The model performed well on new data from two field trials not included in model training that compared 25 (R2 = 0.79, RMSE = 3.7%) and seven (R2 = 0.87, RMSE = 9.4%) fungicide programs. This objective method of assessing mid-to-late season disease severity can be used to assist growers with harvest decisions and researchers with reproducible assessment of field experiments. This model will be integrated into future work with proximal ground sensors for pathogen identification and early season disease detection.[Formula: see text] Copyright © 2024 The Author(s). This is an open access article distributed under the CC BY 4.0 International license.
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Arachis , Fungicidas Industriais , Arachis/microbiologia , Fungicidas Industriais/farmacologia , Estações do Ano , Aeronaves , Doenças das PlantasRESUMO
Carica papaya (papaya) in Guam, USA may experience soft rot symptoms, often referred to as mushy canker disease. Disease symptoms first appear as expanding water-soaked dark-green stem lesions or leaf spotting with chlorotic halos. Defoliation at petiole-stem junctions and crown necrosis leads to plant death. Papaya diseases caused by Erwinia spp. are documented in nearby tropic regions such as the Northern Mariana Islands (Trujillo and Schroth 1982), the Philippines (Dela Cueva et al. 2017), Japan (Hanagasaki et al. 2020), and Indonesia (Suharjo et al., 2021). The pathogen was isolated from symptomatic papaya stem sections (cv. Red Lady) from a nursery at the University of Guam Agriculture and Life Sciences building in April 2023. Approximately 20% of seedlings collapsed from stem soft rot, with nearly all plants showing varying degrees of water-soaked lesions on leaves or stems. Stem tissue from lesion margins was excised, surface sterilized with 70% EtOH, and macerated in sterile water. Macerate was plated onto nutrient agar (NA) and incubated at 28°C, yielding colonies that were clear to white in color, smooth, circular and mucoid on NA plates for five suspect isolates (JGD231-235). Strains produced blue diffusible pigment on King's B (KB) media, were Gram-negative rods, and exhibited swimming motility on semi-solid (0.5% agar) NA plates. Crown stab inoculation of ten papaya plants (cv. Red Lady) with isolates resulted in mushy canker symptoms within seven days, while negative control plants stabbed with a sterile probe remained asymptomatic. Koch's postulates were fulfilled by drench-inoculating spontaneous rifampicin-resistant (100µg/ml) mutants, JGD233r and JGD235r, onto ten papaya plants (cv. Solo Sunrise). Nine days post-inoculation, bacterial strains were recovered from symptomatic stem tissue macerate plated on rifampicin (100µg/ml) NA and incubated at 28°C. No symptoms or bacterial cells were recovered from the tissue of negative control plants. Cell morphology, culture phenotypes, and disease symptoms suggested the isolates were Erwinia spp., and blue pigment production on KB further suggested E. papayae (Gardan et al. 2004). Partial 16S rDNA sequences of Guam strains JGD231-235 (sequenced using PCR forward primer 5' - AGAGTTTGATCMTGGCTCAG - 3' and reverse primer 5' - GGTTACCTTGTTACGACTT - 3', GENEWIZ (South Plainfield, NJ)) were deposited into GenBank (OR577627- 631). Highest NCBI BLAST results for all strains showed a 16S rDNA sequence identity of 98.17-98.91% with those of Erwinia sp. I-leaf (LC590218) and E. mallotivora BT-MARDI (HQ456230). A maximum likelihood phylogenetic tree based on concatenated partial atpD, infB, and rpoB sequences of strains JGD232 (PP669340, PP669346, PP669343), JGD233 (PP669341, PP669347, PP669344), and JGD235 (PP669342, PP669348, PP669345) (Brady et al. 2008) constructed using MEGA11 (Tamura et al. 2021) showed all strains formed a monophyletic group with Erwinia sp. I-leaf (Hanagasaki et al. 2020) and E. papayae NCPPB 4294T (Gardan et al. 2004), supported with 98% bootstrap. This note documents the first occurrence of E. papayae as a papaya pathogen in Guam. Papaya cultivation supports sustainable food security for Guam (Bevacqua and Sayama 2023), and Erwinia spp. pathogens threaten papaya on other Pacific islands like Hawaii. These findings convey the need for effective quarantine practices, local disease management, and further research on this pathogen.
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Anthracnose fruit rot affecting field peppers (Capsicum annuum L.) has been reported in Ontario, Canada, leading to significant crop losses of up to 80% over the past three years. Ten symptomatic fruits per field, exhibiting one or more soft, sunken lesions covered with salmon-colored spore masses (Fig. S1), were collected from one and two Banana pepper fields in August 2022 and 2023, respectively, all located in southwestern Ontario. Small sections of diseased tissue (0.5 cm in length) from lesion edges underwent surface sterilization and plated on 2% potato dextrose agar (PDA, Difco) supplemented with kanamycin (50 mg liter-1), neomycin sulfate (12 mg liter-1) and streptomycin sulfate (100 mg liter-1), and incubated at 22°C for 7 days in the dark. Fifteen fungal colonies were isolated and purified using the hyphal tipping method. All fungal isolates showed a pale gray colony morphology with a faint salmon tint on PDA (Fig. S1). Conidia, produced on PDA after incubating the 15 isolates at 22°C for 17 days in the dark, were hyaline, aseptate, smooth-walled, cylindrical with obtuse ends (Fig. S1), and measured 9.4 to 15.0 × 2.7 to 4.8 µm (mean ± standard deviation of 145 conidia = 11.3 ± 1.2 µm × 3.7 ± 0.5 µm), the typical morphology of Colletotrichum species (Damm et al. 2012). Internal transcribed spacer (ITS), actin (ACT), chitin synthase 1 (CHS-1), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), glutamine synthetase (GS), histone H3 (HIS3) and beta-tubulin 2 (TUB2) gene regions of all isolates were amplified and sequenced with primers ITS1/ITS4, ACT-512F/ACT-783R, CHS-79F/CHS-345R, GDF1/GDR1, GSF1/GSR1, CYLH3F/CYLH3R and Bt2a/Bt2b and deposited in GenBank (Accession Nos. ITS: PP060584 to PP060596; ACT, CHS-1, GAPDH, GS, HIS3 and TUB2: PP085919 to PP086005), respectively. The sequences were 100% identical to Colletotrichum scovillei strains from different hosts and countries (ITS: PP079643; ACT: MN718468; CHS-1: MN718466, GAPDH: MN718465.1, HIS3: MT592502, TUB2: MK462971). The maximum likelihood-based phylogenetic analysis of ITS, ACT, CHS-1, GAPDH, GS, HIS3, and TUB2 concatenated sequences was conducted using IQ-TREE 2.2.2.7 (Minh et al. 2020). All isolates from this study were grouped with high bootstrap support values with the holotype C. scovillei CBS 126529 (Fig. S2). Living cultures of these isolates were deposited in the Canadian Collection of Fungal Cultures (DAOMC 252833 to 252847). Pathogenicity was tested by inoculating 4 Banana (cv. Jumbo Stuff) and 4 Bell (cv. Archimedes) pepper fruits with 10 µl droplet of a 1 × 105 conidia ml-1 suspension of each isolate onto a wound made with a sterile pipette tip. Eight control fruits were mock-inoculated with sterilized water. Nine days post-inoculation, necrotic lesions measuring 24.7 ± 0.3 mm on Bell and 27.9 ± 0.2 mm on Banana peppers were observed. Colletotrichum scovillei was re-isolated from all symptomatic fruits, and its species identity was confirmed through morphology, fulfilling Koch's postulates. Control fruits remained symptom-free, and no fungi were isolated from them. This is the first report of C. scovillei in Canada. Previously identified as a pathogen causing anthracnose on peppers in eastern Asia, the United States, Brazil, and Kosovo (Farr and Rossman 2024; Xhemali et al. 2023), its emergence in Ontario raises significant concerns for pepper crops. Additional research is essential to better understand the epidemiology of the disease and develop effective phytosanitary strategies for control.
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In April 2023, soft rot symptoms were observed in broccoli (Brassica oleracea L. var. italica) commercial fields in Songming County, Yunnan province, China (103°12'E, 25°31'N). The disease incidence in these fields (6 ha in size) was high, exceeding 50%, and it caused significant yield loss. The affected plants displayed characteristic symptoms, with the roots and stems of broccoli becoming soft, yellowish-brown, rotten, and emitting a foul odor. To identify the causal agent, soft rot symptomatic stems were surface sterilized by dipping them in 75% ethanol for 30 seconds, followed by three successive rinses with sterile distilled water. Tissue specimens were then plated onto nutrient agar (NA) plates and incubated at 28°C for 24 hours. (Wang et al. 2022). Three representative bacterial isolates HYC22041801-HYC22041803 from broccoli were selected for further analysis. The colonies on NA plates appeared as white, small, round, and translucent with smooth edges. Physiological and biochemical tests were performed, along with 96 phenotypic screenings using the BIOLOG GENIII microplate system (Biolog, Hayward, CA, USA). Three isolates were negative for D-arabitol, maltose, and sorbitol, but were positive for cellobiose, α-D-glucose, sucrose, glycerol and gentiobiose tests, which are consistent with the reported type strain P. polaris NIBIO1006T (Chen et al. 2021). Total genomic DNA was extracted from three bacterial isolates using the QIAamp DNA Mini Kit (QIAGEN, USA). The 16S rRNA region and nine housekeeping genes (gapA, icdA, mdh, mtlD, pel, pgi, pmrA, proA and rpoS) were amplified with universal primers 27F/1492R (Monciardini et al., 2006) and designed specific primers (Xie et al., 2018), respectively. All amplicons were sequenced and deposited in GenBank with accession numbers ON723841-ON723843 and ON723846-ON723872. The BLASTn analysis of the 16S rRNA amplicons confirmed that the isolates HYC22041801-HYC22041803 belonged to the genus Pectobacterium. Phylogenetic trees based on 16S rRNA gene sequences and multilocus sequence analysis of other nine housekeeping genes of the three isolates were constructed and the results revealed that three isolates clustered with P. polaris type strain NIBIO1006T, which was previously isolated from potato (Dees et al., 2017). To confirm the pathogenicity, nine broccoli seedlings were stab inoculated with a bacterial suspension (108 CFU·ml-1), while sterile distilled liquid LB medium was used as a negative control. The seedlings were kept at 80% relative humidity and 28°C in a growth chamber. Three trials were conducted per isolate (HYC22041801-HYC22041803). After 3 days, the inoculated petioles showed soft rot symptoms similar to those observed initially in the field, while control plants remained asymptomatic. All three isolates were re-isolated successfully from symptomatic tissues to complete Koch's postulates. P. polaris has been previously reported as the causative agent of blackleg in potato in several countries, including Norway, Poland, Russia, and China (Handique et al. 2022; Wang et al. 2022). Additionally, it was reported to cause soft rot in Chinese cabbage in China (Chen et al. 2021). However, this is the first report of P. polaris causing soft rot disease in broccoli in China. This discovery is of great importance for vegetable growers because this bacterium is well established on Cruciferous vegetables in the local area, and effective measures are needed to manage this disease.
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Broccoli (Brassica oleracea L. var. italica) is one of the important cruciferous vegetables in China, known for its considerable economic and nutritional value (Li et al. 2021). In September 2023, leaf spot disease was observed on broccoli seedlings in the commercial fields in Weifang City, Shandong Province, China (119°15'E, 36°70'N). Further investigation revealed that the disease incidence was approximately 60% in 4.5 square hectometers (hm2) broccoli field, resulting in substantial economic losses. This disease primarily affects the leaves, manifesting distinct symptoms such as circular, dark necrotic spots that gradually lighten and are encircled by a chlorotic halo. Some lesions further develop a black or purplish border, exhibit concentric zonation, and eventually fall off, leaving behind holes, as shown in Figure S1B and C. In severe cases, decay originates from the central perforation and spreads outwards, as shown in Figure S1A. To identify the causal agent of this disease, infected leaf tissues were collected and surface disinfected by immersing in 75% ethanol for 30 seconds, followed by three rinses with sterile water. The samples were grinded in sterile deionized water, and the extract was plated on NA. After incubation at 28°C for 48 h, individual colonies were transferred to fresh NA plates. A total of 12 strains with the similar morphological characteristics were isolated from diseased samples collected from the three plots. After 48 hours of growth on NA medium at 28â, each colony attained a diameter ranging from 3 to 5 mm. These colonies appeared yellow, slightly elevated, nearly circular in shape, with a smooth and moist edge. Three representative strains were selected for further investigation. All strains were Gram-negative, aerobic, and rod-shaped. The analysis of BIOLOG GENIII microplate system revealed the capability of three isolates using cellobiose, trehalose, glucose, mannose, galactose, and sucrose. Furthermore, the isolates were unable to hydrolyze arginine and utilize rhamnose and inositol. The 16S rRNA gene was amplified and sequenced to confirm that three isolated bacteria belong to the genus Xanthomonas (OR772321-OR772323), followed by PCR amplification for 4 housekeeping genes atpD, dnaK, gyrB, and rpoD (Young et al. 2008; Saux et al. 2015). The obtained sequences were submitted to the GenBank under accessions OR789628-OR789630, OR785471-OR785473, OR789631-OR789633, and OR785468-OR785470. Gene sequences were aligned, concatenated, and used to generate a phylogenetic tree using the neighbor-joining method in MEGA11 (Tamura et al. 2021). The phylogenetic analysis revealed that all the three isolates were clustered with Xanthomonas campestris pv. raphani strains 5055 and 576, respectively (Figure S2). (Dubrow et al. 2022). These results were consistent with those of the reported X. campestris pv. raphanin (Cruz et al. 2015). To verify the pathogenicity of these strains, we used a spray inoculation method. In detail, bacterial suspensions (30 mL per treatment) containing approximately 108 CFU/ml were sprayed onto healthy, four-week-old broccoli plants and incubated in a phytotron at 28°C and above 90% RH. Negative controls were performed using sterile distilled water. Each isolate underwent three trials and each treatment included 12 broccoli seedlings. Leaf spot symptoms were observed on 5 days post inoculation, as shown in Figure S1E, F and G. Negative control plants showed no symptoms (Figure S1D). We further re-isolated the bacterium from the symptomatic plants and verifying the bacteria as X. campestris pv. raphanin with the aforementioned sequence analysis, thereby fulfilling Koch's postulates. To our knowledge, this is the first report of X. campestris pv. raphani causing leaf spot disease on broccoli in China. This study enhances our understanding of the pathogenic bacterium on broccoli and lays the groundwork for developing targeted management strategies.
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Chia (Salvia hispanica L., Lamiaceae) is an important commercial and medicinal crop recently popularized in India and widely cultivated in Karnataka (Joy et al., 2022). During the field survey of chia crop diseases, characteristic virescence like symptoms were observed at Main Agricultural Research Station, UAS, Raichur as well as at Mysuru and HD Kote region. The incidence was ranged from 2 - 4 per cent in an area of 30 hectares. Typical symptoms associated with chia are malformed shoot and/or inflorescence axis with reduced floral parts with greenish florets. The stem axis become thick, flattened, leaves are reduced towards terminal region. A total of five phytoplasma suspected samples and five suspected healthy samples were used for identification purpose. The Plant Genomic DNA Miniprep Kit (Sigma Aldrich, USA) was used to extract the DNA from five symptomatic and five asymptomatic samples and the DNA was used as template to amplify the phytoplasma-specific 16S rDNA gene using P1/P7 primers (Deng and Hiruki, 1991; Schneider et al., 1995) followed by nested PCR using R16F2n/R16R2 primers (Gundersen and Lee 1996). The expected 1.25-kb amplicon was detected from the suspected symptomatic samples. Nested PCR products were purified and sequenced from both the directions using ABIX370 Genetic Analyzer (Applied Biosystems, Waltham, MA). The analysis revealed that all five sequences shared 100 per cent identity with Candidatus Phytoplasma aurantifolia (OM649850, ON975012) and Tomato big bud phytoplasma (EF193359). The in-silico RFLP pattern of F2n/R2 primed region of 16S rDNA gene analyzed by using iPhyClassifier (Zhao et al. 2009) revealed that the sequence shared 98.72 per cent nucleotide sequence similarity with coefficient value of 1.00 to the reference strain RFLP pattern of 16Sr group II, subgroup D (witches'-broom disease of lime; U15442). Based on 16SrDNA sequences and in-silico RFLP analysis, the phytoplasma associated with the chia virescence was identified as a member of 16SrII-D group. Further, SecA gene was also amplified from the samples using SecAfor1/SecArev3 primer pair (Hodgetts et al., 2008). All samples produced ~400 bp products and sequenced as detailed above. Sequence analysis by nBLAST revealed 100 per cent similarity to Ca. P. australasia (MW020545) and Ca. P. aurantifolia isolate Idukki Kerala 1 (MK726369) both representing 16SrII-D group phytoplasma. The representative sequence (16Sr: PP359693, PP359694; secA:PP386558, PP386559) were deposited in GenBank. Chia virescence phytoplasma belonging to Ca. phytoplasma australasia has not been reported anywhere. The phytopathological studies associated with chia crop are very limited. Joy et al. (2022) reported the occurrence of foot rot disease caused by Athelia rolfsii. Several hosts are recorded to be associated with 16SrII D phytoplasma which includes china aster, eggplant and crotalaria (Mahadevakumar et al., 2017, Yadav et al., 2016a, b). Now the wide occurrence of the phytoplasma in the area might have transmitted by vectors. The occurrence of virescence is of great importance as it affects the overall yield which reduces the market value. To our knowledge, this is the first report of a group 16SrII-D phytoplasma associated with chia virescence in India.
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Wheat stripe rust (yellow rust), caused by Puccinia striiformis f. sp. tritici (Pst), is an important airborne disease worldwide. Pst inoculum strength in southern Henan in winter or early spring is important for spring epidemic in the main autumn-sown wheat-growing regions of China. However, there is limited knowledge about the source and time of initial infection on winter wheat in southern Henan. The first occurrence of wheat stripe rust in southern Henan was recorded annually from 2011-2022, from which we used the backward trajectory approach to infer the likely source of Pst inoculum responsible for the initial disease occurrence. The results suggested that the Pst inoculum responsible for initial rust established in the winter in southern Henan originated from the Gansu Pst oversummering area in China, whereas it originated from the adjacent winter Pst sporulation regions in southern Shaanxi and northwestern Hubei if Pst symptoms were first observed in early spring in southern Henan. Another possible Pst source is southern Hubei where Pst can also sporulate in the winter. Thus, early Pst development in winter in the main wheat production in China (Henan) is likely to be caused by Pst inoculum spread from the oversummering inocula or Pst epidemics in autumn seedlings in Gansu.
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Japanese brome (Bromus japonicus Thunb.) is a weed commonly found in roadsides, floodplain wetlands, and farmlands. During September 2020 and 2021, a leaf spot disease was observed on B. japonicus in greenhouses of Baodi district, Tianjin, China (117°15'E, 39°47'N). More than 10% of the weeds were infected. Initial irregular brown spots on leaf apices continued to expand until adjacent spots coalesced. Eventually, severely infected leaves became yellow, thinner, drier and withered. Small patches (3×3 mm) were cut from symptomatic leaves, sterilized with 75% ethanol for 30s, rinsed three times with sterile water and incubated on Petri dishes with potato dextrose agar at 25°C in darkness for 7 days. Three isolates, with uniform morphology were selected for further analysis. Colonies were cottony with entire edges and aerial white mycelia; and average growth rate of 4.5 mm/day. The upper side was pale white, and the reverse side was grayish-green. Conidia were aseptate, hyaline, subcylindrical with rounded ends, 8.6 to 18.7×4.4 to 8.3 µm (n = 50). Appressoria were dark brown, oval or irregular shaped with a few lobes, 5.7 to 9.4×4.5 to 7.8 µm (n = 50). Total genomic DNA of isolates was extracted with Fungal DNA Kit (GBCBIO, Guangzhou, China). Primers for sequences of internal transcribed spacer (ITS) regions, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), ß-tubulin (TUB2), and calmodulin (CAL) genes were amplified and sequenced (Weir et al., 2012). After aligned and trimmed, the sequences of TJBDA1, TJBDA2, and TJBDA3 were identical. TJBDA1 representative isolate sequences were deposited in GenBank ITS OP247554 with 99.83% (576/577) similarity to MT476809, GAPDH OP414834 with 99.59% (244/245) similarity to MT501009, TUB2 OP414836 with 100% (703/703) to MT501053, and CAL OP414835 with 100% (601/601) to MT500921. Maximum likelihood trees based on concatenated sequences of the four genes were constructed using MEGA7.0. The results showed that the strains isolated from B. japonicus were closely related to C. aenigma with 99% bootstrap support. Pathogenicity tests were conducted on 3-leaf stage B. japonicus seedlings. Conidial suspension of TJBDA1 (1×106 conidia/ml) brushed from a 7-day-old culture of the fungus were sprayed on 9 B. japonicus seedlings. Control plants were sprayed with sterile water. All treatments were replicated four times. The treatment plants were placed in an incubator (25°C, relative humidity > 80%, 12-h photoperiod). Typical leaf spot symptoms resembling ones in the fields were observed on inoculated leaves after 7 days, but control leaves remained symptomless. The fungi reisolated from diseased leaves were morphologically and molecularly identical to the inoculated isolatescompleting Koch's postulates. According to morphological, pathological characteristics and multilocus phylogenetic analysis, the isolated strains from B. japonicus were identified as C. aenigma. To our knowledge, this is a new host record for C. aenigma causing anthracnose on B. japonicus in China. Currently, B. japonicus has evolved a high level of resistance to herbicides in some regions of China (Li et al, 2022) and C. aenigma caused serious disease to B. japonicus. We hope to discover a biocontrol method against weed on non-host cultivated plants through the production of secondary metabolites by C. aenigma.
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Fusarium wilt of banana (FWB) is a serious soil-borne fungal disease. In the previous century, FWB already destroyed Gros Michel-based banana cultures in Central America, and currently, the disease threatens all major banana-producing regions of the world. The causal agents of these epidemics, however, are diverse. Gros Michel was infected by a wide range of Fusarium species, the so-called Race 1 strains, whereas the contemporary Cavendish-based cultures are affected by Fusarium odoratissimum, colloquially called Tropical Race 4 (TR4). TR4 was reported in Mozambique on two commercial banana farms in 2013, but no incursions were found outside the farm boundaries in 2015, suggesting that the disease was under control. Here we report the presence of TR4 outside of these farm boundaries. We obtained fungal samples from 13 banana plants in smallholder and roadside plantings at various locations throughout northern Mozambique. These samples tested positive for TR4 by molecular diagnostics and in greenhouse pathogenicity assays. The results were confirmed with reisolations, thereby completing Koch's postulates. To study the diversity of TR4 isolates in Mozambique, we selected five samples for whole-genome sequencing. Comparison with a global collection of TR4 samples revealed very little genetic variation, indicating that the fungus is clonally spreading in Mozambique. Furthermore, isolates from Mozambique are clearly genetically separated from other geographic incursions, and thus we cannot trace the origin of TR4 in Mozambique. Nevertheless, our data demonstrates the dissemination of TR4 in Mozambique, underscoring the failure of disease management strategies. This threatens African banana production.
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Fusarium , Musa , Musa/microbiologia , Moçambique , Doenças das Plantas/microbiologiaRESUMO
Phytophthora crown rot (PhCR) is an important disease of strawberry worldwide. Phytophthora cactorum is the most common causal agent, however, P. nicotianae was also recently reported causing PhCR in the U.S. Therefore, the goals of this study were to evaluate the resistance of strawberry cultivars from Florida and California, and to study the etiology of the two Phytophthora species causing PhCR. Sixteen strawberry cultivars were evaluated over three Florida seasons for susceptibility to P. cactorum, and P. nicotianae. Inoculations at different days after transplanting (DAT) were also carried out to evaluate the ability of both species to cause PhCR at different phenological stages of the plant. Plant wilting and mortality were assessed weekly, and disease incidence, and the area under the disease progress curve were calculated. Cultivars Sensation 'Florida127', 'Winterstar FL 05-107', and 'Florida Radiance' were susceptible, whereas 'Florida Elyana', 'Camarosa', 'Fronteras', 'Sweet Charlie', and 'Strawberry Festival' were highly resistant to both Phytophthora species. However, some cultivars exhibited stronger resistance to one species over the other. P. cactorum caused more PhCR when plants were inoculated at transplanting, 45, and 60 DAT, whereas P. nicotianae only caused disease when inoculated at transplanting. These results emphasize the importance of screening for disease resistance to guide management recommendations in commercial strawberry production as well as the need for proper pathogen identification since cultivar susceptibility might differ. Varying susceptibility to P. cactorum and P. nicotianae at different growth stages emphasizes the importance of considering both plant and pathogen biology when making management recommendations.
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Fragaria , Phytophthora , Doenças das Plantas , FloridaRESUMO
Moringa oleifera Lam. (Moringaceae) is one of the important leafy vegetable trees widely spread from India to Africa and widely used as food and medicine. During field investigation (July, 2021) of drumstick fields in Hiriyur (13°95'79" N; 76°64'45" E), Karnataka, fruits of drumstick plants showed a characteristic rot disease with an incidence ranging from 10-12% in an area of 5 hectares surveyed. Initially water soaked lesions turned to small necrotic lesions and later coalesced to form larger areas covered with white mycelial growth leading to softening and later mummification of fruits. Infected fruits were collected (n=5) and infected fruit parts (margins of healthy and infected tissues) were cut into small pieces, surface sterilized with sodium hypochlorite (2%, v/v) and blotter dried after three sterile water washes. An associated fungal species was isolated on PDA medium amended with Streptomycin (40 mg/L) and incubated at 28 ºC for 1 week. The fungal isolate grown on PDA had dense, white, aerial mycelium with light brown coloration on the reverse side of the agar medium. Morphological characteristics of conidia were determined for single-spore cultures grown on water agar media. Microconidia were single-celled, hyaline, non septate, ovoid, and 8.4 - 9.8 × 1.8 - 2.94 µm (n=20). Macroconidia were three- to five-septate, slightly curved, tapered at the apex, and 24.4 - 28 × 2 - 4 µm (n=20). Based on morphological characters' pathogen was identified as Fusarium sp. (Leslie and Summerell, 2006). Further, three representative isolate (SMG, MYS1 & MYS2) were subjected for molecular identification. The genomic DNA was extracted following CTAB method and ITS-rDNA was amplified using ITS1/ITS4 primers (White et al., 1990) and translation elongation factor (tef-1α) gene was amplified using EF1/EF2 primers (O'Donnell et al., 2009) respectively. ITS-rDNA sequence shared 100% sequence similarity (650bp / 650bp) with reference sequence F. incarnatum (ON226997) followed by 100% sequence identity to F. equiseti (KT277307 & MT953927). But, tef-1α gene sequence analysis in nBLAST showed that the sequence shared 100% (123/123bp) identity with F. incarnatum (F. incarnatum NEAU-TG1 MH920853; M2JP3 OP312673; WEH ON456146). Combined phylogenetic analysis revealed that the isolate shared a common clade with reference sequence of F. incarnatum in the Fusarium-incarnatum-equiseti species complex thus confirming the identity of the isolated pathogen as F. incarnatum (Rob. ex Desm.) Sacc. 1886. The sequences obtained in the present study are deposited in GenBank database (ITS: OP508729, OQ159019, OQ159020 and tef-1α: OP477394, OQ176254, OQ176255). To prove Koch's postulates, pathogenicity test was carried out by inoculating healthy drumstick fruits cv. Bhagya (n=10) with spore suspension (105 conidia/ml). Control fruits (n=5) were sprayed with sterile water. The experiments were conducted in triplicates and repeated twice. Inoculated and control fruits were kept in a moist chamber at 26 ± 2°C for 2 days and observed at regular intervals. Development of disease symptoms were recorded on 52 out of 60 inoculated fruits which were identical with symptoms seen in the field and all control fruits remained symptomless. Identity was confirmed after re-isolation by morphology and culture studies. To the best of our knowledge, this is the first report of F. incarnatum causing a fruit rot of drumstick in India. This disease affected the cost of drumstick production and contributed to the decline in production in India.
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Trials were carried out in apple orchards of Emilia-Romagna and Trentino-Alto Adige in northern Italy to investigate the effects of sprinkler irrigation on possible reduction in inoculum and subsequent disease pressure of Venturia inaequalis, the ascomycete causing apple scab. In spring, volumetric spore traps were placed above apple leaf litter containing pseudothecia with ascospores of the fungus. Pseudothecia matured more rapidly in irrigated plots, and 95% of the total number of spores trapped in a season was reached on average 164 degree days (base temperature 0°C) earlier in irrigated compared to non-irrigated plots. On average for seven location/year combinations, more than 50% of the ascospores were trapped following irrigations carried out for two hours on sunny days before a forecasted rainfall. Subsequently, a much lower number of spores were trapped on rainy days following irrigation. Field trials with scab susceptible apple cultivars were carried out in the two regions to evaluate the efficacy of sprinkler irrigation on disease. Irrigated and non-irrigated plots were either treated with different fungicide control strategies or not treated. Irrigation significantly reduced the incidence of apple scab at both sites, and the overall number of infected leaves and fruit was reduced by more than 50%. Mid-day sprinkler irrigation can significantly reduce the inoculum pressure of V. inaequalis in apple orchards. This may be a sustainable management strategy, especially in areas with extended dry periods.
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Blue honeysuckle (Lonicera caerulea L.) fruit is growing in popularity as a natural, functional 'super fruit', but its storage is challenged by pathogen infection. In June 2022, approximately 30% of 100 kg of blue honeysuckle fruits (cv. Lanjingling) obtained in Harbin, China (128.70°E, 44.87°N) showed postharvest fruit rot symptoms after 15 d of storage at 4°C, leading to whole fruit rotting with gray fungal growth (Fig.1 A). Small (1-2 mm) segments of infected tissue were obtained from 20 randomly selected fruits which were surface sterilized with 75% ethanol for 30 s and 5% sodium hypochlorite (NaOCl) for 3 min, rinsed three times with sterile distilled water, dried in paper towel, and plated in 9 cm Petri dishes containing potato dextrose agar (PDA). Five purified cultures were obtained and their front colonies were dark brown (Fig.1 C) on the PDA plates after 5 d at 25°C (Alam et al. 2019; Riquelme-Toledo et al. 2020). The conidia (n = 50) were single-celled, hyaline, either ellipsoid or ovoid, and measured 7.5-15.0 µm (11.7 µm average) × 6.0-11.4 µm (8.3 µm average). The conidiophores (Fig.1 E) were branched at the apex bearing bunches of conidia resembling grape clusters (Ellis 1971). For molecular confirmation, genomic DNA was extracted from a representative isolate LDGS-3 using the Ezup Column Fungi Genomic DNA Purification kit (Sangon Biotech, Shanghai, China). The internal transcribed spacer region (ITS, GenBank ON952502), heat shock protein (HSP60, GenBank OP039103), the second-largest subunit of RNA polymerase II (RPB2, GenBank OP186114) and glyceraldehyde 3-phosphate dehydrogenase (G3PDH, GenBank OQ658508) genes were partially amplified with the respective primers ITS1/ITS4, HSP60f/HSP60r, RPB2f/RPB2r, and G3PDH-F/G3PDH-R (Staats et al. 2005; White et al. 1990). BLAST analysis revealed that the sequences of the four genes showed 100% homology with the MH782039, MH796663, MN448501 and MH796662 sequences for isolates of Botrytis cinerea. Based on morphology and molecular characteristics, the isolate LDGS-3 was identified as B. cinerea. For pathogenicity, twenty healthy blue honeysuckle fruits (cv. Lanjingling) were superficially sterilized with 75% ethanol and washed with distilled water. Ten inoculated blue honeysuckle fruits, which were injected with 10 µL conidial suspension of isolate LDGS-3 (106 spores/mL) displayed fruit rot symptoms (Fig.1 B) inside 9 cm Petri dishes after 10 d at 4°C, while no symptoms were detected on ten fruits inoculated with sterile distilled water (Alam et al. 2019). The same isolate that was reisolated from infected fruits with the same morphological and molecular traits was also identified as B. cinerea, confirming Koch's postulates. B. cinerea was previously reported in Henan Province, China in hawthorn (Zhang et al. 2018). To our knowledge, this is the first report of postharvest fruit rot caused by B. cinerea on blue honeysuckle fruit in China, which will aid future management of this emerging postharvest disease.
RESUMO
Aegiceras corniculatum is an important mangrove plant that mainly grows in tropical and subtropical regions. It has important ecological, economic and social benefits (Bandaranayake 1998). In April 2021, a leaf disease on A. corniculatum was observed in Zhanjiang (21.21° N, 110.41° E), Guangdong province, China. Disease incidence and severity were 15% and 20% (n = 100 investigated plants), respectively. The disease symptoms on leaves primarily appeared as small brown spots, then enlarged and coalesced into regular or irregular gray necrotic lesions with dark margins. At the late stage of symptom development, black acervuli appeared on the necrotic lesions. Ten symptomatic leaves from 10 plants were collected. Small pieces of tissue (4 × 4 mm) were cut from lesion borders and were surfaced disinfected in 75% ethanol for 30 s, followed by 1 min in 1% NaClO, rinsed three times with sterile water, plated on potato dextrose agar (PDA), and incubated at 28°C. After 7 days, a total of 10 fungal isolates with 100% isolation frequency were obtained and three representative strains (THS-1, THS-2, and THS-3) were used for morphological and molecular characterization. Colonies were white with cottony aerial mycelium and irregular margins. Black viscous acervuli were scattered on the colony surface 10 days after incubation. Conidia were spindle shaped, five cells, four septa, 18.77-28.70 × 4.53-6.80 µm (mean 23.13 × 5.14 µm) in size (n = 50). Basal and apical cells were colorless while the three medium cells were dark brown and lightly versicolor. All conidia had one basal appendage of 3.51-7.27 µm (mean 5.49 µm; n = 50) and two to three apical appendages of 15.80-33.64 µm (mean 25.87 µm; n = 50). These morphological characteristics are consistent with those of Neopestalotiopsis clavispora (Maharachchikumbura et al. 2012). The ITS (OM698813-15), tub2 (OM810165-67) and tef1α (OM810186-88) sequences were 99.38%, 99.09%, and 99.17% identical to the type N. clavispora strain MFLUCC12-0281 (accession nos. JX398979, JX399014, and JX399045) through BLAST analysis, respectively. A phylogenetic tree was generated using the concatenated sequences of ITS, tub2, and tef1α. The result showed that these three isolates were clustered with N. clavispora strains including the type MFLUCC12-0281. To perform pathogenicity tests, 20 healthy potted seedlings of A. corniculatum (2-year-old) were selected. Ten surface-sterilized leaves of 10 seedlings were wounded and inoculated by spraying conidial suspension ( 105 conidia/ml). The same number wounded leaves of the other 10 plants treated with sterile water served as controls. All plants were wrapped in polyethylene bags for 24 h and incubated at 28°C in a growth chamber (at 90% relative humidity). After 10 days, all the inoculated leaves showed similar symptoms to those observed in the field, whereas control leaves were asymptomatic. N. clavispora was reisolated from the lesions in terms of morphology and molecular characterization, whereas no fungus was isolated from the control leaves. The pathogenicity test was repeated three times under the same conditions. Thus, Koch's postulates were fulfilled. This pathogen has been reported on a wide host range worldwide, such as leaf spot on strawberry in China (Zhao et al. 2016) and twig blight on blueberry in Spain (Borrero et al. 2018). This is the first report of N. clavispora causing leaf blight on A. corniculatum in China. This study provides valuable information for the identification and control of the disease.