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1.
Plant Dis ; 2024 Jun 09.
Article in English | MEDLINE | ID: mdl-38853332

ABSTRACT

Nanhaia speciosa, commonly known as Niudali, is a medicinal woody vine belonging to the Leguminosae family. Valued for its culinary and medicinal properties, it is extensively cultivated, covering approximately 5,973 hm2 in the Guangxi Zhuang Autonomous Region of China. The edible tubers of this plant are reported to possess antibacterial and antioxidant effects (Luo et al., 2023; Shu et al., 2020). In July 2021, a Niudali plantation in Yulin, Guangxi, China (22°64'N; 110°29'E) exhibited leaf spot symptoms, with an incidence rate exceeding 40% across a 46,690 m2 area. Initially, small circular, pale yellow spots appeared on the leaves, which subsequently evolved into dark brown lesions surrounded by yellow halos, ultimately leading to foliage wilting. Leaves exhibiting typical symptoms were collected for pathogen investigation. The leaves were thoroughly washed with sterile water and small tissue fragments (5×5 mm) were excised from the lesion periphery. These fragments were surface-sterilized with 75% ethanol and 1% NaClO, rinsed three times with sterile water, and subsequently cultured on potato dextrose agar (PDA) at 28 °C in darkness for 7 days. Through single-spore isolation, seven isolates with similar morphological traits were obtained. After 7 days of incubation on PDA at 28 °C in dark, the colonies exhibited a white to grey coloration on the upper surface with abundant aerial hyphae, while the underside appeared dark black. The conidia, cylindrical or obclavate in shape, were straight, pale brown, and measured 30.1-128.9 µm × 4.8-15.0 µm (n=50). The morphological characteristics matched those of Corynespora sp.(Wang et al. 2021). For molecular identification, the isolate N5-2 underwent DNA sequence analysis using genomic DNA and primers ITS1/ITS4 and EF1-688F/EF1-1251R. The sequences (ITS: OP550425; TEF1-α: OQ117118) were deposited in GenBank, exhibiting 98% identity to C. cassiicola (OP981637) for TEF1-α and 99% homology to C. cassiicola (OP957070) for ITS. Based on the concatenated ITS and TEF1-α, a maximum likelihood phylogenetic analyses using MEGA7.0 clustered the isolate with C. cassiicola. Consequently, the fungus was identified as C. cassiicola based on its morphological and molecular features. In the pathogenicity test on 1-year-old Nanhaia speciosa seedlings, leaves were gently scratched and inoculated with mycelial plugs (5 mm). Control seedlings received PDA plugs. Five leaves per plant and five plants per treatment were selected for assessment. All seedling were maintained in a greenhouse (12/12h light/dark cycle, 25 ± 2°C, 90% humidity). After a 7-day incubation period, all leaves subjected to fungal inoculation exhibited symptoms consistent with those observed in the field, while control plants remained symptom-free. The fungus was successfully reisolated from the infected leaves in three successive trials, fulfilling Koch's postulates. While C. cassiicola is well-documented for inducing leaf spots on various plant species, including Jasminum nudiflorum, Strobilanthes cusia, Acanthus ilicifolius, Syringa species (Hu et al., 2023; Liu et al., 2023; Xie et al., 2021; Wang et al., 2021), this study represents the first report of C. cassiicola causing leaf spots on Nanhaia speciosa in China. The identification of this pathogen in Nanhaia speciosa has significant implications for future epidemiological investigations and serves as a valuable reference for controlling leaf spot disease in Nanhaia speciosa.

2.
Plant Dis ; 2024 Sep 21.
Article in English | MEDLINE | ID: mdl-39306684

ABSTRACT

Patchouli (Pogostemon cablin (Blanco) Benth) is an important medicinal and aromatic plant widely cultivated in China, India, and other Southeast Asian countries. It is renowned for its diverse applications in traditional medicine and its detoxification, antibacterial, anti-inflammatory, and other pharmacological properties (Wu et al. 2016; Fang et al. 2022). In May 2023, a severe leaf spot disease was observed on Pogostemon cablin plants grown in most plantations in Yulin, Guangxi, China (22°26'N; 109°83'E), with over 50% incidence rate. Symptoms began as small, circular, brown spots on leaves, enlarging with yellow halos. Lesions expanded into irregular shapes with necrotic centers. Advanced stages showed extensive yellowing, browning, and leaf senescence. A total of 20 symptomatic plants were sampled from 5 different locations within the detected area, with 4 plants sampled per location. To isolate the pathogen, 20 affected leaves were collected from these plants and preliminarily washed with sterile distilled water (SDW). Five small tissue pieces (5×5 mm) were excised from the lesion edge of each leaf, surface-disinfected with 75% ethanol and 1% NaClO, rinsed thrice with SDW, and placed on potato dextrose agar (PDA) at 28 °C in darkness for 7 days. Out of these, 18 plants (90%) yield fungal isolate with recurrent and similar morphological characteristics. Four representative isolates (X5-1-1, X5-1-3, X5-1-5, and X5-1-7) were selected for further analysis. On PDA, colonies were initially white, gradually turning black on the surface, with light yellow on the reverse side of the plate. Conidia were brown to black, globose, rough-walled, and 2.6 to 5.2 µm in diameter. Conidial heads were brown-black, and conidiophores were smooth and hyaline. Morphological characteristics matched those of Aspergillus sp. (Guo et al. 2017). For molecular identification, the internal transcribed spacer (ITS) region and the ß-tubulin (TUB) gene of all four isolates were sequenced (Lim et al. 2019). All four isolates (X5-1-1, X5-1-3, X5-1-5, and X5-1-7) showed consistent morphological characteristics and 100% identical ITS and TUB sequences. Representative sequences from isolate X5-1-5 were submitted to GenBank (ITS: PP789632; TUB: PP798205). The obtained ITS and TUB sequences showed 99% similarity to Aspergillus tubingensis (ITS: OP737633; TUB: MG991377). Based on morphological and molecular analyses, the fungus was identified as A. tubingensis (Palmer et al. 2019). For pathogenicity tests, a spore suspension (1 × 10^6 conidia/mL) was prepared from 7-day-old cultures of A. tubingensis grown on PDA. The suspension was sprayed onto leaves of 10 healthy Pogostemon cablin plants until runoff. Control plants were sprayed with SDW. All plants were kept in a controlled greenhouse (12/12h light/dark, 25 ± 2 °C, 90% humidity). After 7 d, symptoms identical to those observed in the field developed on all pathogen inoculated plants, while control plants remained asymptomatic. The fungus was successfully re-isolated from infected leaves in three successive trials, fulfilling Koch's postulates. Notably, A. tubingensis has previously been reported causing field diseases on strawberry in California, Jatropha curcas and Helleborus species in China (Palmer et al. 2019; Guo et al. 2017, Liaquat et al. 2019), and vine canker on table grape in Italy (Vitale et al. 2012). To our knowledge, this is the first report of A. tubingensis causing leaf spot on Pogostemon cablin in China. This finding provides a foundation for further investigate into the biology, epidemiology, and management of this disease.

3.
Plant Dis ; 2024 Aug 15.
Article in English | MEDLINE | ID: mdl-39146003

ABSTRACT

Millettia speciosa Champ, renowned for its diverse applications in traditional medicine, is extensively cultivated in the Guangxi region of China, spanning roughly 5,973 hectares. In July 2021, a plantation in Yulin, Guangxi, China (22°64'N; 110°29'E), exhibited severe leaf spot disease on M. speciosa. Notably, a 46,690 square meters area had over 40% leaf spot incidence. Initially, symptoms appeared as small, circular, pale-yellow lesions on the leaves, then turned into irregular, dark brown spots with yellow halos, leading to the wilt and defoliation of leaves. To identify the responsible pathogen, a total of five symptomatic leaves were collected and sterilized systematically. Small tissue segments (5×5 mm) from lesion peripheries were aseptically excised, then surface sterilized with 75% ethanol for 10 s, and 1% sodium hypochlorite (NaClO) for 3 min. Following this, the sterilized tissues were triple-rinsed with sterile water and cultured on potato dextrose agar (PDA) at 28 °C in the dark for 7 d. A total of seven isolates were obtained through single-spore isolation, and one representative isolate, N2-3, was selected for further analysis. After 7 d of incubation, colonies displayed flat, white, and extensively branched aerial hyphae. Over time, the reverse side of the colony changed from white to yellowish-white. The pycnidia were black with conidial droplets ranging from cream to pale yellow exuding from their ostioles. The α-conidia were one-celled, hyaline, ovoid to cylindrical, typically with one or two droplets, 2.6 to 5.9 ×1.4 to 3.9 µm (n=50). These morphological traits align with those of the genus Diaporthe, as reported by Li et al. (2022) and Crous et al. (2015). To identify the species, isolate N2-3 underwent sequencing of the internal transcribed spacer (ITS), ß-tubulin (BT), and translation elongation factor 1 alpha (EF1-α) sections (Huang et al. 2021). Obtained sequences of ITS, BT and EF1-α (Genebank accessions nos. OR600532, OR662169 and OR662168) displayed a 99% similarity to Diaporthe tulliensis (Genebank accessions nos. OP219651, ON932382, OL412437, respectively). Based on the concatenated ITS, BT and EF1-α, a neighbor-joining phylogenetic analyses using MEGA7.0 clustered with D. tulliensis. Therefore, the fungus was identified as D. tulliensis (teleomorph name) based on morphological and molecular features. A pathogenicity test was conducted on 1-year-old M. speciosa seedlings by gently abrading healthy leaves with sterilized toothpicks to create superficial wounds. Wounded leaves were then inoculated with 5 mm diameter mycelial plugs, while control seedlings received PDA plugs. Three leaves per plant and five plants per treatment were selected for assessment. All seedlings were kept in a controlled greenhouse (12/12h light/dark, 25 ± 2 °C, 90% humidity). After 7 d, the inoculated leaves showed symptoms like those in the field, while control plants remained healthy. The fungus was consistently reisolated from the infected leaves, satisfying Koch's postulates. Notably, D. tulliensis has caused Boston ivy leaf spot, bodhi tree leaf spot, cacao pod rot, and jasmine stem canker (Huang et al. 2021; Li et al. 2022; Serrato-Diaz et al. 2022; Hsu et al. 2023). This discovery is significant as it marks the first report of Diaporthe tulliensis causing leaf spot on Millettia speciossa in China, which has direct implications for the development of diagnostic tools and research into potential disease management strategies.

4.
Plant Dis ; 2023 Jul 06.
Article in English | MEDLINE | ID: mdl-37415360

ABSTRACT

Star anise (Illicium verum) is an important economic and medical plant widely cultivated in Guangxi province, China. Its fruit can be used as spice and medicine (Wang et al. 2011). In recent years, anthracnose led to a serious decline in the production of star anise in Guangxi. In 2021, a survey conducted in CenwangLaoshan Reserve of Guangxi (24°21'N; 106°27'E) showed that the 2500 ha planting area had disease incidence greater than 80%. The leaf symptoms initially appeared as small spots, then expanded to round spots, finally becoming withered with grayish-white centers, surrounded by dark brown margins. Sometimes, small black acervuli were observed in the later stage. To explore the pathogen, infected leaves were collected and cut into small pieces (about 5 mm2) from the edge of the lesion, disinfected with 75% ethanol for 10 s, 1% NaClO for 1 min, washed with sterilized water and incubated on potato dextrose agar (PDA) plates at 28 °C in the dark. Ten single-spore isolates were obtained from the cultures. After 7 days on PDA at 28 °C, the colonies of 7 isolates were white with abundant aerial hyphae, gray-black with white-gray margins, and the other 3 isolates were light gray on the upper surface, and pink or orange on the underside. Representative isolates BS3-4 and BS3-1 were selected from 3 isolates and 7 isolates, respectively. Conidia of BS3-4 and BS3-1 were both hyaline, cylindrical, aseptate, smooth, apex obtuse, base truncate, and no significant differences (P > 0.05) in size between BS3-1 (13.22 to 5.38 × 3.89 to 1.99 µm) (n = 50) and BS3-4 (12.04 to 4.34 × 3.48 to 1.64 µm) (n = 50). These morphological characteristics were consistent with the Colletotrichum ssp. (Damm et al. 2012). The species identification of BS3-4 and BS3-1 was performed based on DNA sequence analysis. Genomic DNA was extracted as a template. Partial sequences of the rDNA internal transcribed spacer (ITS), actin gene (ACT), ß-tubulin2 (TUB2) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) were amplified and sequenced (Weir et al. 2012). The sequences were deposited in GenBank (ITS:OQ062642-43; ACT:OQ067614-15; GAPDH:OQ067616-17;TUB2:OQ067618-19). Based on the concatenated sequences of the 4 genes (ITS-ACT- GAPDH -TUB2) of BS3-4 and BS3-1 as well as sequences of other Colletotrichum spp. obtained from GenBank, the Maximum likelihood (ML) tree which produced with IQ-TREE (Minh et al. 2020) revealed that the isolate BS3-1 was Colletotrichum horii, and BS3-4 was Colletotrichum fioriniae. Pathogenicity was confirmed on healthy leaves of 1-year-old star anise seedlings (cultivar Dahong), and the leaves were wounded by sterilized toothpicks, and were inoculated with 10 µl of conidial suspensions of BS3-1 and BS3-4 (106 conidia/ml). Control seedlings were inoculated with sterilized distilled water. Five leaves per plant and 3 plants per treatment were selected. All inoculated seedlings were maintained in the greenhouse (12/12h light/dark, 25 ± 2℃, 90% relative humidity). Wound sites inoculated with BS3-1 and BS3-4 both turned greenish-brown after 2 days and then turned light brown with water-soaked spots. Black (BS3-1) or orange (BS3-4) dots of acervuli developed after 6 days. The lesion diameter of BS3-1 (14.4 mm) was larger than that of BS3-4 (8.1 mm). No symptoms were observed on controls. BS3-1 and BS3-4 were re-isolated from inoculated leaves, fulfilling Koch's postulates. Anthracnose of star anise caused by C.horii has been reported in China (Liao et al. 2017). However, to our knowledge, this is the first report of C.fioriniae infecting star anise in China. Accurate pathogen identification in this study could provide a reference for the control of anthracnose on star anise.

5.
J Asian Nat Prod Res ; 23(2): 110-116, 2021 Feb.
Article in English | MEDLINE | ID: mdl-31885279

ABSTRACT

A couple of new cycloheximide epimers, 13(α)-acetoxy-anhydroisoheximide (1) and 13(ß)-acetoxy-anhydroisoheximide (2), together with six known compounds (3-8), were obtained from the cultures of Streptomyces sp. YG7. The structures were elucidated based on a comprehensive spectroscopic data analysis including 1D and 2D NMR, as well as HRESIMS, and by comparison with the literature. The X-ray crystal analysis of 1 further confirmed the structure. All the compounds were tested for antifungal activity. Compounds 1, 2 and 5-8 showed moderate Canidia albicans inhibitory activity, while 5 and 6 presented moderate Pyricularia oryzae inhibitory activity. [Formula: see text].


Subject(s)
Streptomyces , Antifungal Agents/pharmacology , Ascomycota , Cycloheximide , Molecular Structure
6.
J Wildl Dis ; 58(2): 450-453, 2022 04 01.
Article in English | MEDLINE | ID: mdl-35113986

ABSTRACT

Batrachochytrium dendrobatidis (Bd), which causes chytridiomycosis, mainly infects Anura and Caudata but is poorly known in Gymnophiona. We conducted a survey of Bd in the Yunnan caecilian (Ichthyophis bannanicus) and found that 6 of 71 samples (8.4%) tested positive for Bd. To our knowledge, this is the first detection of Bd in wild I. bannanicus.


Subject(s)
Chytridiomycota , Mycoses , Animals , Anura/microbiology , Batrachochytrium , China/epidemiology , Mycoses/epidemiology , Mycoses/microbiology , Mycoses/veterinary
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