RESUMEN
Macleaya cordata (Willd.) R. Br. is a perennial herbaceous medicinal plant (Papaveraceae) commercially cultivated in China which has been studied for detumescence, detoxification, and insecticidal effect (Lin et al. 2018). In August 2021, anthracnose was observed in 2-year-old M. cordata plants in Benxi county, northeast China (41°45'48â³N, 123°69'15â³E). Dozens of irregular reddish-brown spots (3-11 mm) were observed on each diseased leaf. The lesions were covered with a layer of gray-white mycelia. As the disease progressed, the spots became necrosis and perforation or they would merged into large lesions, ultimately resulting in wilted leaves (Fig. 1). More than 33% of the plants in a 16-ha field were infected in 2021. The diseased leaves were collected and cut into 3-8 mm pieces, surface-disinfested by immersing them into 1% NaOCl for 2 min, and rinsed three times with sterile distilled water. They were then dried with sterilized absorbent paper, placed on PDA medium amended with chloramphenicol (40 mg/L), and incubated in darkness at 25°C with a 12-h photoperiod. Twenty isolates (BLH1 to 20) were obtained and purified using a single-spore method. Isolate BLH12 was identified and used for the pathogenicity test. Colonies were sparsely fluffy with smooth edges, and gradually became gray to pale orange from the initial white. The underside of the colonies was pale orange towards the center. Conidia were single-celled, cylindrical, and transparent with broadly blunt ends, measuring (15.13 ± 1.14) × (5.80 ± 0.60) µm (n=50). Appressoria were single-celled, brown-to-dark brown, usually elliptical or irregular, and sometimes lobed. Setae were not observed. The isolate was initially identified as Colletotrichum gloeosporioides complex (Prihastuti et al. 2009). The identification was confirmed as described previously (Weir et al. 2012). The rDNA internal transcribed spacer region (OP415560), the glyceraldehyde-3-phosphate dehydrogenase (OP433642), chitin synthase (OP433643), calmodulin (OP433644), actin (OP433645), glutamine synthetase (OP433646), ß-tubulin (OP433647), and superoxide dismutase (OP433648) gene sequences were obtained (Carbone & Kohn 1999; Weir et al. 2012), and BLAST searches revealed 99-100% homology with the type culture ICMP 18608 (JX010244, JX010044, JX009683, JX009443, JX009744, JX010078, JX010389, and JX010311). A phylogenetic analysis of combining all loci indicated BLH12 and the type strain of C. aenigma were clustered in one group (Fig. 2). Based on the basis of morphological characteristics and phylogenetic relationships, BLH12 was identified as C. aenigma. For the pathogenicity test, healthy 2-year-old plants were sprayed with a BLH12 spore suspension (1 × 105/mL). Control plants were sprayed with sterile water.There were three replicates (five plants each) per treatment. All plants were incubated at 25°C (12-h photoperiod and 86% relative humidity) and examined after 7 days. The experiment was repeated twice. The inoculated plants showed lesions on the leaf surface, similar to those in the field, whereas the control plants were asymptomatic. The pathogen was successfully reisolated and identified as the methods mentioned above. This fungus reportedly infects the leaves of many woody plants in China (Wang et al. 2020; Zhang et al. 2021). This is the first report of C. aenigma causing anthracnose on M. cordata, which will provide an guideline for developing effective field control practices for the disease.
RESUMEN
Brachybotrys paridiformis Maxim. ex Oliv. (Boraginaceae) is a perennial medicinal plant and vegetable that is cultivated commercially in China. Anthracnose is a devastating disease of B. paridiformis, with annual production losses exceeding 33% based on our survey. In July 2021, anthracnose of B. paridiformis was observed on 2-year-old plants in Shenyang city, Northeast China, which is the most important region for B. paridiformis cultivation. Round or irregular-shaped black spots were exhibited on leaves, with the leaf edges most commonly infected. As the necrosis expanded, the leaves withered and dropped; young leaves were generally not infected (Fig. 1). More than 40% of the plants in a 21-ha sampling field were infected in 2021. Symptomatic leaves (n = 20) were collected and the diseased tissue was cut into small pieces, immersed in 1% NaOCl for 2 min, rinsed three times with sterile water, and placed on acidified potato dextrose agar (PDA) in Petri dishes. After a 3-day incubation in darkness at 25 °C, 18 suspected single-pure morphologically identical Colletotrichum isolates were obtained and sequenced. Isolate SQZ9 was randomly selected and identified. Colonies on PDA were initially white, but gradually became pale brownish with a reverse side that was pale yellowish to pinkish. Aerial mycelia were grayish-white, dense, and cottony, with microsclerotia detected on some aging mycelia. The detected single-celled conidia (11.65-17.25 × 4.25-6.15 µm; n = 50) were fusiform to cylindrical with obtuse to slightly rounded ends. Appressoria were ovoid to clavate and medium brown. Setae were not observed. The morphological characteristics were similar to those of Colletotrichum spp. (Prihastuti et al. 2009; Weir et al. 2012). Initial BLAST searches of the GenBank database revealed the SQZ9 rDNA internal transcribed spacer region (OP389109, 566 bp), glyceraldehyde-3-phosphate dehydrogenase (OP407730, 260 bp), chitin synthase (OP407731, 301 bp), calmodulin (OP407732, 712 bp), actin (OP407733, 282 bp), glutamine synthetase (OP407734, 909 bp), ß-tublin (OP407735, 498 bp), and superoxide dismutase (OP407736, 396 bp) sequences were respectively 99%-100% similar to the C. siamense type strain JX010278, JX010019, JX009709, GQ856775, GQ856730, JX010100, JX010410, and JX010332 sequences (Carbone & Kohn 1999; Moriwaki & Tsukiboshi 2009; Stephenson et al. 1997). The SQZ9 identity was confirmed by constructing a phylogenetic tree combining all loci, which grouped the isolate and the C. siamense type strain in the same clade (Fig. 2). For pathogenicity tests, 15 healthy 2-year-old plants (3 plants per pot) were spray-inoculated with SQZ9 conidial suspension (1 × 105 conidia/mL) at 2 mL per plant. Same number of plants sprayed with water were used as control. This experiment was repeated twice. All plants were covered with clear plastic bags for 72 h to maintain high humidity and then placed in a greenhouse (29 °C, natural light, and 85% relative humidity). After six days, the inoculated leaves exhibited symptoms that were similar to those observed in the field, but the controls were symptomless. The same fungus was recovered from inoculated symptomatic leaves, and its identity was confirmed by sequencing and a phylogenetic analysis. This is the first report of C. siamense causing anthracnose on B. paridiformis in China. Future studies should assess the effectiveness of chemical and biological control measures for managing this disease.
RESUMEN
Tribulus terrestris L. is an annual herbaceous medicinal plant of Zygophyllaceae, which is cultivated commercially in China. Subrotund or irregular gray, sunken, necrotic spots ranging from 2 to 9 mm were observed on diseased leaves of T. terrestris landrace in Fushun County, Liaoning Province of northeast China in July 2021, with more than 32% of the plants being infected in a 18-ha field. The symptoms first appeared on older leaves and gradually spread to younger leaves. The lesions developed a white center gradually and became perforated; multiple lesions could coalesce (Fig. 1). Ten symptomatic leaves were collected and the diseased tissues were cut into small pieces, immersed in 1% NaOCl for 2 min, rinsed three times with sterile water, and placed on acidified potato dextrose agar (PDA) in Petri dishes at 25°C in darkness. Fifteen suspected Colletotrichum single-spore fungal isolates (JL1 to JL15) with consistent morphological characteristics were obtained, and isolate JL6 was selected for identification and pathogenicity testing. Colonies on PDA were flat with an entire margin, dense and white at first, then became dark gray with numerous black microsclerotia and formed a concentric circular pattern with aging. Conidia were single-celled, sickle-curved with a tapered tip and truncate base, ranging from 16.46 to 20.26 µm in length and 2.81 to 3.96 µm in width (n=100). Setae were dark brown, septate, straight with a slightly acute tip, 75.45 to 135.63×3.19 to 4.95 µm in size. Appressoria were dark brown, round or irregular, mostly in groups. All characteristics were consistent with the descriptions of C. truncatum (Damm et al. 2009). Further confirmation of the identification was determined according to methods described previously (Damm et al. 2009). The rDNA internal transcribed spacer region (OP364400, 585 bp), and actin (OP380867, 290 bp), beta-tubulin (OP380868, 498 bp), chitin synthase 1 (OP380869, 277 bp), glyceraldehyde-3-phosphate dehydrogenase (OP380870, 280 bp), and histone (OP380871, 411 bp) genes were amplified by PCR and sequenced (Carbone and Kohn 1999; Glass and& Donaldson 1995; Guerber et al. 2003; O'Donnell and Cigelnik 1997). BLAST results showed 98-100% similarity at 85-97% coverage compared to the corresponding sequences of the type strain CBS 151.35 (GU227862, GU227960, GU228156, GU228352, GU228254, and GU228058). Phylogenetic analysis combining all loci revealed that the isolate JL6 and the type strains of C. truncatum clustered in one group (Fig. 2). One-year-old healthy seedlings of T. terrestris (cultivar: landrace) were used for pathogenicity test. Suspension (1×105 conidia/mL) of isolate JL6 was sprayed on ten seedlings, and ten seedlings sprayed with sterilized distilled water were used as the control. Three replicates were performed on each treatment. All plants were kept at 28±1°C (12 h photoperiod), and were evaluated after 7 days. The inoculated plants showed lesions on the leaf surface, similar to those in the field, and the control remained symptomless. The pathogen was successfully reisolated and identified using the methods mentioned above. To our knowledge, this is the first report of C. truncatum causing anthracnose on T. terrestris, which will provide valuable information for designing strategies to manage anthracnose on T. terrestris.
RESUMEN
Asian ginseng (Panax ginseng) is a valuable medicinal plant that is commercially cultivated in China. A long postharvest storage period is required before ginseng is processed. From October 2019 to May 2020, snow rot was observed on the roots of 4- and 5-year-old fresh ginseng stored in three cold storage facilities located in Tonghua and Changbai cities in northeastern China, which are the most important regions for Asian ginseng production. We sampled 1,000 ginseng roots from the three cold storage facilities, and the average disease incidence was 21%. Initially, sparse hyphae and microsclerotia appeared on the root epidermis. Lesions gradually softened and the epidermis detached easily. Multiple infected sites slowly converged, resulting in the formation of a dense complex of multiple sclerotia and thick hyphae on the surface of the ginseng root as well as internal decay. The infection eventually spread to the adjacent ginseng roots (Fig. 1). Sixteen diseased ginseng roots were collected and then sclerotia were removed from the root surface, immersed in 1% NaClO for 2 min, rinsed three times with sterile water, and placed on potato dextrose agar (PDA) containing streptomycin (40 µg/mL) in Petri dishes. After a 3-day incubation at 20 °C in darkness, 22 suspected Sclerotinia isolates were obtained. Isolates SN1 and SN2 were randomly selected for identification. On PDA, fast-growing colonies produced white, sparse, powdery, and cotton-like aerial mycelia, and the reverse side showed the same color (Fig. 2). Small and white sclerotial primordia formed 3 days later and a ring of sclerotia was detected at the plate periphery. At 7 to 10 days after incubation, the mature sclerotia were black, spherical-to-subspherical, and elongated or fused to form irregular shapes. Each Petri dish produced 55-65 sclerotia, measuring 1.1 × 1.2 to 3.2 × 3.9 mm (n = 100). The sclerotia were firmly attached to the agar surface. The isolates were initially identified as Sclerotinia sp. (Saito 1997). After sequencing the nuclear ribosomal internal transcribed spacer region (MW927134 and MW927135) and the ß-tubulin gene (MW929179 and MW929180) (White et al. 1990; Glass and Donaldson 1995), BLAST searches revealed 100% homology with JX262268 and JX296007 of the published S. nivalis strain KGC-S0601, respectively. The pathogenicity of the two isolates was tested using detached ginseng roots. Briefly, healthy roots were washed, surface-disinfested with 75% alcohol, and rinsed with sterile water. Mycelial plugs (5 mm diameter) removed from the margin of actively growing colonies on PDA were placed on the ginseng roots. For each isolate, four roots were inoculated, with two plugs per root. Additionally, PDA plugs without mycelia were used as the negative control. The roots were placed in a fresh-keeping box at 20 °C in darkness and evaluated after 7 days. The pathogenicity test was repeated twice. The symptoms on the inoculated roots were the same as those observed on the roots during cold storage, whereas the control roots remained symptomless. The same fungus was reisolated consistently from all infected roots and its identity was confirmed by resequencing, thereby fulfilling Koch's postulates. To the best of our knowledge, this is the first report of S. nivalis causing postharvest snow rot on Asian ginseng in China. The occurrence of this disease threatens the postharvest storage of Asian ginseng. Hence, effective management strategies must be developed.
RESUMEN
Objective: Prediction of therapy response to intravenous methylprednisolone pulses (ivMP) is crucial for thyroid-associated ophthalmopathy (TAO). Image histograms may offer sensitive imaging biomarkers for therapy effect prediction. This study aimed to investigate whether pretherapeutic, multiparametric T2 relaxation time(T2RT) histogram features of extraocular muscles (EOMs) can be used to predict therapy response. Materials and Methods: Forty-five active and moderate-severe TAO patients, who were treated with standard ivMP and underwent orbital MRI before therapy, were retrospectively included in this study. The patients were divided into responsive (n = 24, 48 eyes) and unresponsive group(n = 21, 42 eyes) according to clinical evaluation. Baseline clinical features of patients and histogram-derived T2RT parameters of the EOMs were analyzed and compared. Logistic regression model was conducted to determine independent predictors, and a histogram features nomogram was formulated for personalized prediction. Results: Responsive group displayed lower values for 5th, 10th percentiles (P < 0.050, respectively), and higher values for 75th, 90th, and 95th percentiles, skewness, entropy, and inhomogeneity (P < 0.050, respectively) than unresponsive group. Multivariate logistic regression analysis showed that 95th percentile of >88.1 [odds ratio (OR) = 12.078; 95% confidence interval (CI) = 3.98-36.655, p < 0.001], skewness of >0.31 (OR = 3.935; 95% CI = 2.28-6.788, p < 0.001) and entropy of >3.41 (OR = 4.375; 95% CI = 2.604-7.351, p < 0.001) were independent predictors for favorable response. The nomogram integration of three independent predictors demonstrated optimal predictive efficiency, with a C-index of 0.792. Conclusions: Pre-treatment volumetric T2RT histogram features of EOMs could function to predict the response to ivMP in patients with TAO. The nomogram based on histogram features facilitates the selection of patients who will derive maximal benefit from ivMP.