Genome assembly of Medicago truncatula accession SA27063 provides insight into spring black stem and leaf spot disease resistance.

Medicago truncatula, model legume and alfalfa relative, has served as an essential resource for advancing our understanding of legume physiology, functional genetics, and crop improvement traits. Necrotrophic fungus, Ascochyta medicaginicola, the causal agent of spring black stem (SBS) and leaf spot is a devasting foliar disease of alfalfa affecting stand survival, yield, and forage quality. Host resistance to SBS disease is poorly understood, and control methods rely on cultural practices. Resistance has been observed in M. truncatula accession SA27063 (HM078) with two recessively inherited quantitative-trait loci (QTL), rnpm1 and rnpm2, previously reported. To shed light on host resistance, we carried out a de novo genome assembly of HM078. The genome, referred to as MtHM078 v1.0, is comprised of 23 contigs totaling 481.19 Mbp. Notably, this assembly contains a substantial amount of novel centromere-related repeat sequences due to deep long-read sequencing. Genome annotation resulted in 98.4% of BUSCO fabales proteins being complete. The assembly enabled sequence-level analysis of rnpm1 and rnpm2 for gene content, synteny, and structural variation between SBS-resistant accession SA27063 (HM078) and SBS-susceptible accession A17 (HM101). Fourteen candidate genes were identified, and some have been implicated in resistance to necrotrophic fungi. Especially interesting candidates include loss-of-function events in HM078 because they fit the inverse gene-for-gene model, where resistance is recessively inherited. In rnpm1, these include a loss-of-function in a disease resistance gene due to a premature stop codon, and a 10.85 kbp retrotransposon-like insertion disrupting a ubiquitin conjugating E2. In rnpm2, we identified a frameshift mutation causing a loss-of-function in a glycosidase, as well as a missense and frameshift mutation altering an F-box family protein. This study generated a high-quality genome of HM078 and has identified promising candidates, that once validated, could be further studied in alfalfa to enhance disease resistance.

Biocontrol potential and growth-promoting effect of endophytic fungus Talaromyces muroii SD1-4 against potato leaf spot disease caused by Alternaria alternata.

BACKGROUND: Alternaria alternata is the primary pathogen of potato leaf spot disease, resulting in significant potato yield losses globally. Endophytic microorganism-based biological control, especially using microorganisms from host plants, has emerged as a promising and eco-friendly approach for managing plant diseases. Therefore, this study aimed to isolate, identify and characterize the endophytic fungi from healthy potato leaves which had great antifungal activity to the potato leaf spot pathogen of A. alternata in vitro and in vivo. RESULTS: An endophytic fungal strain SD1-4 was isolated from healthy potato leaves and was identified as Talaromyces muroii through morphological and sequencing analysis. The strain SD1-4 exhibited potent antifungal activity against the potato leaf spot pathogen A. alternata Lill, with a hyphal inhibition rate of 69.19%. Microscopic and scanning electron microscope observations revealed that the strain SD1-4 grew parallel to, coiled around, shrunk and deformed the mycelia of A. alternata Lill. Additionally, the enzyme activities of chitinase and ß-1, 3-glucanase significantly increased in the hyphae of A. alternata Lill when co-cultured with the strain SD1-4, indicating severe impairment of the cell wall function of A. alternata Lill. Furthermore, the mycelial growth and conidial germination of A. alternata Lill were significantly suppressed by the aseptic filtrate of the strain SD1-4, with inhibition rates of 79.00% and 80.67%, respectively. Decrease of leaf spot disease index from 78.36 to 37.03 was also observed in potato plants treated with the strain SD1-4, along with the significantly increased plant growth characters including plant height, root length, fresh weight, dry weight, chlorophyll content and photosynthetic rate of potato seedlings. CONCLUSION: The endophyte fungus of T. muroii SD1-4 isolated from healthy potato leaves in the present study showed high biocontrol potential against potato leaf spot disease caused by A. alternata via direct parasitism or antifungal metabolites, and had positive roles in promoting potato plant growth.

First Report of Bacterial Leaf Spot Disease on Ginger Caused by Enterobacter quasiroggenkampii in China.

In autumn 2023, an unknown leaf spot disease has occurred on ginger (Zingiber officinale Roscoe) in two fields of approximately 1800 m2 in Yongning District (22°49'N; 108°48'E), Nanning, China, with a incidence of 20-30%. The symptoms began as yellow spots on the leaves, expanding into elliptical to irregular lesions with yellow edges, the middle of the lesion turning grey-white in dry weather. Finally, multiple spots caused necrosis of the whole leaf. Twelve diseased leaves from six plants of two fields were collected, surface disinfected and ground. The ground samples were diluted and plated on nutrient agar (NA) medium at 28 °C for 48-72 h. The purified colonies appeared milky white and round, with smooth edges. Three isolates (GL1, GL2 and GL3) were selected for identification and pathogenic determination. They were gram negative, could utilize sorbitol, mannitol, inositol, raffinose, melibiose, disaccharides, and citrate; negative for methyl red, phenylalanine decarboxylase, hydrogen sulfide, urease; positive for voges-proskauer test and ornithine decarboxylase. These characteristics were consistent with Enterobacter genus (Wu et al., 2020). Genomic DNA was extracted from three isolates. The 16S rDNA region was amplified using 27F/1492R primers (Weisburg et al. 1991) and sequenced (accession no. PP837703-PP837705). Blastn analysis revealed that 16S rDNA sequences for GL1 was 99% identical (1373/1387 nt), GL2 96% (1364/1422 nt) and GL3 95% (1365/1435 nt) to Enterobacter quasiroggenkampii WCHECL1060 (NR_179166). To determine the species, the sequences of gyrB, rpoB and atpD genes were amplified using primers gyrB 01-F/gyrB 02-R, rpoB CM7/rpoB CM31b, and atpD 01-F/atpD 02-R, respectively (Lin et al. 2015; Zhu at al. 2010; Zhang et al. 2013). The GenBank accession numbers for the sequences were PP857680-PP857688. A multilocus phylogenetic tree was constructed with the concatenated sequence of 16S rDNA-gyrB-rpoB-atpD by using the Neighbor-Joining (NJ) method with 1000 bootstrap replicates in MEGA6 software. The three isolates clustered with E. quasiroggenkampii. Fifteen Darou ginger variety plants at the 4-5 leaf stage were tested for pathogenicity. Two to three leaves of each ginger plant were pricked with a syringe needle of 0.36mm in diameter or not and inoculated by spraying the bacterial suspension (108 CFU/mL), sterile water was used as a control. Five plants were inoculated with each isolate and the test was repeated three times. After 3-4 days of inoculation, all wounded leaves and about 10% of the unwounded leaves showed symptoms similar to those observed in the field. Control plants did not develop symptoms. Enterobacter quasiroggenkampii isolates were re-isolated from the inoculated leaves with symptoms, and their identity was confirmed by gyrB sequencing and colony morphology, completing Koch's postulates. Enterobacter quasiroggenkampii is a pathogen of humans that can cause nosocomial infections (Wu et al., 2020). In Guangxi, E. quasiroggenkampii was identified as one of the pathogens causing mulberry wilt (Jiao, 2022). To our knowledge, this is the first report of E. quasiroggenkampii causing bacterial leaf spot disease of ginger. The results of this study not only have practical significance for the control of ginger leaf spot, but also can provide excellent materials for the study of the differentiation and pathogenic mechanism of the genus Enterobacter, which has important academic value.

First report of wheat leaf spot disease caused by Curvularia inaequalis in China.

Wheat (Triticum aestivum) is an economically important crop widely cultivated in China. In August 2022, brown oval leaf spots with yellow halos were observed on approximately 10% wheat seedlings over an area of about 1 hectare in Xining City, Qinghai Province, which adversely affected wheat growth and production. Six diseased leaves were collected from the field in Huangyuan county (101°69' E, 37°04' N). The 0.5 cm × 0.5 cm pieces were cut from the border between healthy and diseased regions of the sampled leaves, surface sterilized for 10 s in 75% ethanol, followed by a 1% NaClO for 90 s, and rinsed three times with distilled sterile water. The pieces of leaf tissue were dried with sterile tissue, and plated on potato dextrose agar (PDA) amended with streptomycin (0.02 g/L) and ampicillin sulfate (0.05 g/L) to eliminate bacterial contamination. The dishes were placed in an incubator at 25°C for 72 h in dark. Three isolates, WGC201, WGC202 and WGC203, were obtained by a single-spore culture method. Fungal colonies on PDA media were dark green (Fig. 1A and 1B). Conidiophores were septate and geniculate terminals, while conidia exhibited straight or slightly curved forms with four transverse septa, the central cell being notably longer and wider than the others. The size of such conidia were 27.34 µm to 40.62 µm× 11.61 µm to 15.97 µm (number = 50) (av. 32.71 µm× 13.11 µm) (Fig. 1C and 1D) (Moubasher et al. 2010). The internal transcribed spacer (ITS) region of nuclear ribosomal DNA and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) gene were amplified and sequenced using universal primers ITS1/ITS4 and GPDF/GPDR (White et al. 1990; Berbee et al. 1999). DNA sequences were deposited into the NCBI database (ITS, PP789629, PP801333, and PP801574; GAPDH, PP849124, PP849125, and PP849126). Phylogenetic analysis with a neighbor-joining method based on the concatenated sequences of ITS and GAPDH genes showed that the three isolates clustered within a C. inaequalis branch (Fig. 2). Based on morphological and molecular identification, the fungal isolates were identified as C. inaequalis. The pathogenicity test was conducted in a greenhouse at 25°C using a spore suspension method and three isolates were used. Conidia were produced on PDA media (25℃) for 14 days. Plates were washed with sterilized distilled water and filtered with cheese cloth. Conidial suspension was adjusted to a concentration of 1×107 conidia/mL. Fifteen healthy seedlings of a wheat cultivar Xiaoyan-6 at a 3-4 leaf stage were inoculated by evenly spraying a 100mL spore suspension. Plants inoculated with sterile water served as a control. All plants were covered with plastic bags for 3 days. At 7 days after inoculation, all pathogen-inoculated plants showed similar symptoms (brown leaf oval spots with yellow halos) with those observed in the field, while all plants inoculated with sterile water showed no symptoms (Fig. 1E and 1F). The pathogen was reisolated from the symptomatic leaves and proved to be C. inaequalis. Morphological, molecular and pathogenic results indicated that C. inaequalis is the pathogen causing wheat leaf disease in China. The results are consistent with a previous report in Azerbaijan (Özer et al. 2020). To our knowledge, this is the first report of C. inaequalis causing spot disease on wheat in China. The occurrence, spread and economic importance to different wheat cultivars of the emerging disease in China will be further investigated and evaluated.

First Report of Yellow Leaf Spots on Maize Caused by Colletotrichum siamense in Yunnan Province, China.

The southwest maize planting area is the third largest maize-producing region in China, including the entire provinces of Sichuan, Yunnan and Guizhou, parts of Guangxi and Hunan provinces. In June 2022, yellow leaf spot symptoms were observed commonly on maize in southern Yunnan province, including Pu'er City, Xishuangbanna Dai autonomous prefecture and Honghe Hani & Yi autonomous prefecture. The disease incidence on maize in Pu'er ranged from 10% to 20% from June to August. The initial symptoms appeared as needle-like spots scattered on the leaf surface with obvious yellow haloes, with a diameter ranging from 0.2 to 2 mm and were quite similar to maize Curvularia leaf spot. But the lesion size did not expand significantly and without reddish or dark brown margins. In July 2023, 30 diseased leaves were collected in Pu'er City, Yunnan Province. Leaf tissues (3×3 mm) were cut from the infected margins, surface disinfested with 75% ethanol for 30 s, 2% sodium hypochlorite for 2 min, and rinsed three times with sterile water, then placed on PDA at 25℃. Forty-eight isolates with the morphological characteristics of Colletotrichum ssp. were obtained by single-spore isolations (isolation frequency 42.5%). The fungal colonies on PDA were dense with white mycelia on the edges, and yellowish-white on the reverse side. The conidia were transparent, cylindrical, smooth-walled, and 6.8 to 17.5 × 3.8 to 6.5 µm. Two isolates (YNH-1 and YNH-2) were used for DNA extraction. The ribosomal internal transcribed spacer (ITS), actin (ACT), calmodulin (CAL), glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and ß-tubulin 2 (TUB2) regions were amplified by PCR. The PCR primers in this study were as described previously (Weir et al. 2012). The sequences of both isolates were 100% identical, and all sequences showed >98% identity with Colletotrichum siamense in the GenBank. The sequences were deposited in GenBank (ITS, PP237394; ACT, PP265410; CAL, PP265411; GAPDH, PP265412; TUB2, PP265413). A phylogenetic tree was constructed by MEGA_v. 11.0.13 with the Maximum Likelihood (ML) method. The isolate YNH-1 and YNH-2 clustered with C. siamense DAR 76934 (97% bootstrap support) in the same branch. Pathogenicity tests were performed on the susceptible maize variety B73. Twelve healthy maize seedlings were inoculated with a conidial suspension (1×106 conidia/ml) of isolate YNH-1. All the seedlings were kept in an incubator at 26℃, with a 90% humidity and a 12 h light/dark cycle. After 5 days, yellow spots appeared on the leaves of the plants. The symptoms on inoculated leaves were similar to those observed in the field after 10 days, whereas no symptoms appeared in the control. The pathogen C. siamensis was re-isolated from the infected leaves, which fulfilled the Koch's postulates. C. siamense can cause leaf diseases on a wide range of hosts. It has been reported causing anthracnose on tea (Camellia sinensis) (Wang et al. 2016) and wax apple (Syzygium samarangense) (Yao et al. 2023) in Yunnan Province, China. To our knowledge, this is the first report of C. siamense causing yellow leaf spots on maize in China as well as a new host record for C. siamense causing leaf disease. However, how C. siamense spreads among different host plants in the region is still unknown. This study provides important information for epidemiological study and comprehensive management of yellow leaf spot on maize.

Occurrence of Cassava (Manihot esculenta) Leaf Spot Disease Caused by Diaporthe ueckeri in China.

Cassava (Manihot esculenta) is a perennial crop of the family Euphorbiaceae, widely cultivated due to its phytopharmacological and economic values in China. In November 2022, a leaf spot disease on cassava was observed in Zhanjiang, Guangdong, China (21.17° N, 110.18° E), with 100% disease incidence. About 80 % of leaves were covered with spots on the infected plants. Typical symptoms initially appeared as irregular water-soaked lesions that became brown and whitish with the progress of the disease, lesions gradually expanded and coalesced, causing leaf withering, drying and final fall. Tissues (4 to 5 mm) were excised from the margin of lesions, sterilized in 3% H2O2 solution for 3 min, rinsed three times with sterile water, placed on potato dextrose agar (PDA) medium (containing 50mg/L penicillin), and incubated at 25-28 °C. Ten single hypha isolates with similar morphology were obtained and further purified as single conidium subcultures. The colony was grey whitish with sparse aerial mycelium and colony diameter reached 70.4 mm after four days incubation at 25-28℃ in the dark. Black pycnidia occurring as clusters were spherical or irregular, erumpent at maturity, often with a creamy whitish, conidial cirrus extruding from ostiole after 30-days incubation. Conidiophores were hyaline, smooth, unbranched. Alpha conidia were bi-guttulate, hyaline, ellipsoidal, aseptate, with dimensions of 5.1~7.5×1.9~3.4µm (mean 6.2×2.8 µm, n>50). Beta conidia were abundant, filiform, hyaline, smooth, curved in a hooked shape, with a truncate base and dimensions of 18.5-26.4 × 0.6-1.2µm (mean 23.4 × 1.0 µm, n= 40) . Gamma conidia were not observed. The morphological characteristics were similar to those of Diaporthe ueckeri (Udayanga et al. 2015). The internal transcribed spacer (ITS) region, large subunit (LSU) rRNA sequence, actin (ACT), calmodulin (CAL), histone H3 (HIS), translation elongation factor 1-alpha (TEF1-α), and ß-tubulin (TUB) genes of a representative isolate CCAS-MS-6 (ACCC 35497) were amplified and sequenced using primer pairs: ITS5/ITS4, LR0R/LR5, ACT-512F/ACT-783R, CAL228F/CAL737R, CYLH3F/ H3-1b, EF1-728F/ EF1-986R and Bt2a/Bt2b (Gao et al 2017；Udayanga et al 2014). All sequences were deposited in GenBank (OR361671, OR361672, and OR365605-9). BLAST search showed high similarities with sequences of Diaporthe ueckeri (Tab 1). Maximum likelihood analyses of the concatenated data of CAL, HIS, ITS, TEF and TUB using Mega 11 placed CCAS-MS-6 in the D. ueckeri clade. Thus, the fungus was identified as D. ueckeri. Three one-year old healthy plants were used for pathogenicity tests in pots. Two 15-day old leaves of each plant were cleaned with 75% alcohol, three sites on each leaf were wounded, and sites on one of the leaf were covered with fungal plugs from 15-day-old cultures on PDA, and sites on the other leaf with PDA plugs as a control. All plants were kept at ambient temperature (about 28℃) and covered with plastic bags containing sterile wet cotton to maintain the humidity. Seven days after inoculation, all inoculated sites showed symptoms of necrosis, while control sites showed no symptoms. The same fungus identified on the basis of morphological and molecular criteria was reisolated from symptomatic inoculated leaves. In China, D. ueckeri had been reported to cause diseases on Eucalyptus citriodora, Camellia sinensis, and Michelia shiluensis (Gao et al 2016; Liao et al 2023; Yi et al 2018), this is the first report on M. esculenta. The definition of the disease etiology is a prerequisite to develop effective management strategies.

First Report of Nigrospora oryzae Causing Leaf Spot Disease on Amorphophallus albus in Shaanxi Province of China.

Amorphophallus albus P. Y. Liu & J. F. Chen is a typical cash crop widely planted in southwest China (Gao et al., 2022). In early August of 2021, a peculiar leaf spot disease was first detected on A. albus in Ankang Academy of Agricultural Sciences manufacturing base (32°69'N, 109°02'E), Shaanxi, China. Small irregular yellow-brown spots (1 to 2 mm) were observed on the surface of A. albus leaf. Following infection of the leaf, it expanded (3 to 5 mm) and became necrotic. Nine planting bases were investigated, and approximately 75% of plants were symptomatic during the rapid expansion period of bulb growth in Hanyin, Langao and Hanbin counties, Ankang City, Shaanxi, China. Higher disease incidence was observed at temperatures above 30℃ and humidity above 80%. Twenty-seven symptomatic tissues of infected leaves were first surface sterilized by immersion in 75% ethanol for 1 minute, followed by rinsing three times in sterile distilled water. The tissues were then cut into 4-5 mm pieces, plated on 1.5% potato dextrose agar (PDA), and incubated at 28±2°C. The hyphal tip from the growing edge of colonies cultured for three days at 28±2℃ was transferred to PDA to obtain pure cultures. Fungal colonies were white, then grey to black with an unevenly distributed, fast-growing aerial mycelium covering the petri dish within five days at 28±2℃. The colony turned dark brown when maintained in the dark at 28±2℃ after seven days, then grayish brown upon sporulation after 15 days (Fig.1f-g). Conidia were brown or black, smooth, spherical to sub-spherical, single-celled (8-12 µm × 10-13µm, average 9-11.5 µm in diameter, n=5µm). The nutritional hyphae exhibited septa, and a portion of the aerial hyphae formed a long, rough conidium, giving rise to a nearly spherical apical sac (Fig.1h). The surface gave rise to several small peduncles bearing clusters of surfaced spherical conidia (Fig.1i). Surfaced spherical conidia were generated on the surface of the small peduncle (Fig.1j). These morphological features were consistent with Nigrospora oryzae (Li et al., 2017). Genomic DNA was extracted from mycelia of the pathogen using an Ezup column fungal genomic DNA extraction kit (Sangon Biotech, Shanghai, China). To confirm the identity of the pathogen, the genomic fragments for the internal transcribed spacer (ITS), LSU (28S) and BenA gene of the isolate were amplified by PCR (Wang et al., 2017) and sent for sequencing. The resultant sequence (GeneBank ID of gene ITS, LSU, BenA are OR723825, OR775345, OR277316, respectively) were compared with the voucher specimens. BLAST results showed >99% identity with those of N.oryzae (GeneBank ID of N.oryzae strain LC2707 ITS, LSU, BenA are KX985954, KY806242, KY019481, respectively). A neighbor joining phylogenetic tree with the concatenated sequences of these genes showed that A-pb169 had the closest match with N. oryzae (Fig. 2). For pathogenicity testing, fifty plants in a period of rapid expansion of bulb growth were selected. Four leaves per plant were inoculated by sprayed till runoff with a conidial suspension of the pathogen (50 µL, 1×106 conidia/ml sterile water), and incubated at 30±2℃ and 80 ± 5% humidity. Control plants received sterile water. On the third day after inoculation, a yellow-brown spot appeared on leave surfaces, the spot gradually expanded; the infection rate was 90 to 95%. Fifteen days after inoculation, infected leaves showed symptoms like those observed in the field, whereas 100 control leaves sprayed with sterile water remained symptomless (Fig.1 a-e). The pathogen was reisolated from infected leaves and confirmed as N. oryzae by morphology and molecular identification. To our knowledge, this is the first report of leaf spot disease of A. albus caused by N. oryzae in China. Since its one of the major cash crops of the southeastern China, further work is necessary to determine its spread and economic impact as well as developing sustainable disease management options.

Identification of Gonatophragmium mori Causing Mulberry Zonate Leaf Spot Disease and Characterization of Their Biological Enemies in Guangxi, China.

Mulberry zonate leaf spot disease (MZLSD) is an important fungal disease of mulberry trees, which seriously affects the productivity and quality of mulberry leaves. MZLSD has been widely reported in sericultural production areas in Guangxi, China, in recent years. In this study, the causal agent of MZLSD was isolated from symptomatic samples and identified as Gonatophragmium mori (Acrospermaceae) based on morphological characterization and molecular analyses using nucleotide sequences of the internal transcribed spacer (ITS) and large subunit ribosomal DNA (LSU rDNA). Pathogenicity tests confirmed that G. mori is the pathogen responsible for MZLSD. Furthermore, we isolated antagonistic endophytic bacteria (AEB) from healthy mulberry leaves. Plate confrontation experiments showed that the lipopeptide crude extracts (LPCE) of three endophytic bacteria can inhibit the growth of G. mori, and the diameter of the antibacterial circle reaches more than 60 mm when their concentration of LPCE is 200 mg/ml. Light microscopy and scanning electron microscopy revealed that LPCE caused drastic changes in mycelial morphology. Fluorescence microscopy and transmission electron microscopy showed that the LPCE-induced apoptosis-like cell death in G. mori hyphae. Finally, based on morphological and molecular features, we identified the three isolates as Bacillus subtilis DS07, B. subtilis DS32, and B. velezensis Q6, respectively. To our knowledge, this is the first time to identify G. mori by combining characterization and molecular analyses, and we provide timely information about the use of biocontrol agents for suppression of G. mori.

First Report of Leaf Spot Disease on Avocado Caused by Bipolaris setariae in China.

Avocado (Persea americana), which is native to Latin America, is mostly planted in southwest China. In November 2021, leaf spot symptoms were observed in a nursery in Chongzuo (22.2019°N, 106.4723°E), Guangxi, China. Approximately 90% of avocado seedlings in the nursery were affected. Symptomatic plant fully expanded leaves showed small brown spots that ranged from 1 to 3 mm, with a yellow halo around (Fig.1). Lesions gradually expanded and became nearly round and dark brown. Finally, leaves withered or curled. For pathogen isolation, 15 symptomatic leaves were randomly sampled from different plants of the nursery, five leaves were selected and four samples size 4×4mm were taken from each leaf and were plated on potato glucose agar. Identical fungus colonies were observed in 80% of the samples, and no bacteria were isolated. Single conidial isolation was performed. After 4 days, the colony diameter reached 74.6 mm, colonies appeared gray, and developed aerial hyphae. Conidiophores were mostly solitary with a few clustered erect or slightly curved, knee shaped, and 3.89 to 5.24 µm wide. Conidia were 39.33 -96.88 × 9.96 - 15.59 µm, slightly curved, rarely straight, light brown to yellowish brown, fusoid or navicular, and truncated at the base with 4 to 10 septa. Based on morphological and cultural characteristics, the fungus was identified as Bipolaris sp. (Manamgoda et al. 2014). An isolate named MP211122 was grown on Sachs' ager at 27℃ under 12-h light/dark for 1 week and consistently with Adhikari et al. (2021) no sexual from was observed. To confirm the tentative identification, genomic DNA was extracted, ITS and GAPDH gene were amplified and sequenced using primers ITS1/ITS4 and GPD/GPD2, respectively (Tan et al. 2022). The ITS sequence (GenBank ON248469) shared 100% identity with B. setariae (MN215632.1), and the GAPDH sequence (ON642344) shared 99.82% identity with B. setariae (MF490833.1, MK144540.1) and B. yamadae (MK026428.1). A maximum likelihood phylogenetic analysis based on GAPDH and ITS sequences using MEGA 7.0 revealed that the isolate clustered with B. setariae with 100% bootstrap support(Fig. 2). Healthy 11-month old potted avocado seedlings from disease-free nursery were selected , the conidial suspension (1 × 105 conidia/mL) of MP211122 isolate was prepared by harvesting conidia from a 10-day-old culture on water agar. Conidia were sprayed onto young leaves of six potted plants. Three additional seedlings sprayed with sterile distilled water served as controls. All plants were covered with plastic bags for 3 days to maintain high humidity and then maintained in a greenhouse at 30℃ with a 12-h/12-h light/dark cycle. After 5 days, typical symptoms of small brown spots were observed on all inoculated leaves (Fig.3). All leaves on control plants remained asymptomatic. The reisolated fungus was morphologically identical to the original isolate used for inoculation, fulfilling Koch's postulates. This is the first report of B. setariae as a pathogen causing leaf spot on avocado in China. This information will facilitate further studies, monitoring and control of the disease as accurate identification of the causal agent is a primary requisite for designing management strategies.

First Report of Panax notoginseng Leaf spot Disease Caused by Boeremia exigua in China.

Panax notoginseng a perennial herb native to China, is widely grown in the Yunnan Province. (Yang et al. 2022). From July to August 2022, a new leaf spot disease was observed on fully expanded leaves of P. notoginseng from a planting base in the Xundian, Yunnan Province, China. Approximately 250 ha. of P. notoginseng is the cultivated area, and the incidence of leaf spot disease was around 10-15%. Round spots appeared on the infected leaves and as the disease progressed these leaves fell off the plant. A total 21 symptomatic leaves were randomly collected from the planting base to isolate the pathogens and further study in the laboratory. The surface of infected leaves were sanitized with 0.5% sodium hypochlorite for 2 min. and 75% alcohol for 1 min., and then rinsed thrice with sterile water. Once drying, the samples were placed on potato dextrose agar (PDA), plates and incubated at 25 °C for 5 days. The fungus was isolated from the symptomatic tissue, but only three isolates were preserved for further identification. Pure cultures of the representative strain Zhaochanglin 118 were obtained using the singlespore method, and the colonies obtained were dark-green to dark-black in appearance. The pycnidia were dark brown, solitary, or congregated with an inconspicuous neck. The conidia were colorless, ellipsoidal, and measured between 4.5 to 7 × 2 to 3 µm (n = 30). These morphological characteristics were similar to those described for Boeremia exigua (Valenzuela-Lopezi et al. 2018). The genomic DNA of the isolate was extracted using the DN14 cetyltrimethylammonium bromide rapid plant genome extraction kit. The internal transcribed spacer (ITS), RNA polymerase second largest subunit (RPB2) and translation elongation factor 1-alpha (TEF1) genes were amplified via polymerase chain reaction using the primers ITS1/ITS4 (White et al. 1990), Af/Cf (Matheny et al. 2002), and EF1-983F/EF1-2218R (Chen et al. 2015), respectively. All sequences were deposited in GenBank (OQ996531 for ITS; OR291158 for RPB2 and OR291159 for TEF1). A BLASTN homology search using the ITS nucleotide sequence indicated that this has 99.6% identity with the sequence MH859059, named B. exigua from CBS culture collection (517/519 bp); the RPB2 sequence has 97.5% identity with sequence GU371780, named B. exigua from CBS culture collection (704/722 bp); and the TEF1 sequence has 98.4% identity with sequence GU349080, named B. exigua from CBS culture collection (871/885 bp). To test Koch's postulates, a pathogenicity test was carried out on the leaves of six fully expanded P. notoginseng plants in the Xundian planting base. Conidial suspensions were prepared for one isolates at a concentration of 106 spores per milliliter. Three leaflets on different plants were applied with 20µl spore suspension and the other three leaflets were drop of 20 µl sterile distilled water. The whole experiment was repeated three times. The P. notoginseng plants were incubated under sterile conditions at 25°C for 7 days. Inoculated leaves showed the characteristic brown round spots, while control leaves were asymptomatic so, Koch's postulates were fulfilled by re-isolating the pathogen from symptomatic tissue, which was subsequently confirmed as B. exigua through morphological and molecular analyses. Koch's postulates were fulfilled. To our knowledge, this is the first report of B. exigua causing leaf spot disease in P. notoginseng in China, which lays a foundation for further study and developing disease control methods.

In vivo and In vitro evaluation of the antifungal activity of the PGPR Bacillus amyloliquefaciens RaSh1 (MZ945930) against Alternaria alternata with growth promotion influences on Capsicum annuum L. plants.

Alternaria alternata that threatens pepper production and causes major economic harm is responsible for the leaf spot/blight disease. Chemical fungicides have been widely employed; unfortunately, fungicidal resistance is a current concern. Therefore, finding new environmentally friendly biocontrol agents is a future challenge. One of these friendly solutions is the use of bacterial endophytes that have been identified as a source of bioactive compounds. The current study investigates the in vivo and in vitro fungicidal potential of Bacillus amyloliquefaciens RaSh1 (MZ945930) against pathogenic A. alternata. In vitro, the results revealed that RaSh1 exhibited strong antagonistic activity against A. alternata. In addition to this, we inoculated pepper (Capsicum annuum L.) plants with B. amyloliquefaciens RaSh1 and infected them with A. alternata. As a result of A. alternata infection, which generated the highest leaf spot disease incidence (DI), the plant's growth indices and physio-biochemical characteristics significantly decreased, according to our findings. Our results also showed the abnormal and deformed cell structure using light and electron microscopy of A. alternata-infected leaves compared with other treatments. However, DI was greatly reduced with B. amyloliquefaciens RaSh1 application (40%) compared to pepper plants infected with A. alternata (80%), and this led to the largest increases in all identified physio-biochemical parameters, including the activity of the defense-related enzymes. Moreover, inoculation of pepper plants with B. amyloliquefaciens RaSh1 decreased electrolyte leakage by 19.53% and MDA content by 38.60% as compared to A. alternata infected ones. Our results show that the endophyte B. amyloliquefaciens RaSh1 has excellent potential as a biocontrol agent and positively affects pepper plant growth.

New report of endophytic bacterium Achromobacter xylosoxidans from root tissue of Musa spp.

BACKGROUND: Cavendish (AAA) banana plant (Musa spp.) worldwide cultivated crop harbors many endophytic bacteria. Endophytic bacteria are those that live inside plant tissues without producing any visible symptoms of infection. RESULTS: Endophytic bacterium (MRH 11), isolated from root tissue of Musa spp.was identified as Achromobacter xylosoxidans (ON955872) which showed positive effects in IAA production, phosphate solubilization, catalase production. A. xylosoxidans also showed in vitro antagonism against Curvularia lunata causing leaf spot disease of Cavendish (AAA) banana (G-9 variety). The GC-MS analysis of culture filtrate of A. xylosoxidans (ON955872) confirmed this finding. GC-MS analysis was carried by using two solvent etheyl acetate and chloroform and it showed several antifungal compounds. The identification of these bioactive secondary metabolites compounds was based on the peak area, retention time, molecular weight, molecular formula and antimicrobial actions. GC-MS analysis result revealed the presence of major components including Cyclododecane, 1-Octanol, Cetene, Diethyl phthalate. In vivo test to banana plants was carried out in separate field as well as in potted conditions. Appearance of leaf spots after foliar spray of spore of pathogen and reduction in leaf spots after application of bacterial suspension was found. CONCLUSION: The present study has highlighted the role of endophytic bacterium as antagonist to the pathogen Curvularia lunata.

Characteristics of Leaf Spot Disease Caused by Didymella Species and the Influence of Infection on Tea Quality.

Leaf spots are the most damaging and common foliar diseases of tea and are caused by several species of fungi. During 2018 to 2020, leaf spot diseases showing different symptoms (large and small spots) were observed in commercial tea plantations in Guizhou and Sichuan provinces of China. The pathogen causing the two different sized leaf spots was identified as the same species (Didymella segeticola) based on morphological characteristics, pathogenicity, and multilocus phylogenetic analysis using the combined ITS, TUB, LSU, and RPB2 gene regions. Microbial diversity analysis of lesion tissues from small spots on naturally infected tea leaves further confirmed Didymella to be present as the main pathogen. Results of sensory evaluation and quality-related metabolite analysis of tea shoots infected with the small leaf spot symptom indicated that D. segeticola negatively affected the quality and flavor of tea by changing the composition and content of caffeine, catechins, and amino acids. In addition, the significantly reduced amino acid derivatives in tea are confirmed to be positively associated with the enhanced bitter taste. The results improve our understanding of the pathogenicity of Didymella species and the influence of Didymella on the host plant, Camellia sinensis.

First Report of Leaf Spot Caused by Phyllosticta styracicola on Nageia nagi in China.

Nageia nagi (Thunb.) Kuntze belongs to the family Podocarpaceae with shiny green branches and leaves, which is widely distributed in East Asia and the Southern Hemisphere. The leaves, roots and fruits of N. nagi have been used as herbal medicine to treat rheumatism, arthritis and venereal diseases (Abdillahi et al. 2011). In September 2022, leaf spot symptoms were found on approximately 30% of the leaves of N. nagi trees in a community located at the Economic and Technological Development Zone, Nanchang City, Jiangxi Province, China. Following the initial infection, the leaf lesions extended outwards from the top in a circular pattern, appearing as a dark brick color, and later changed to yellow and became dry, with a darker brown margin surrounding them. Ten symptomatic leaves were randomly selected, and a small piece of leaf tissue (5mm ×5mm) located between the health and infected tissues was cut and surface-desinfected with 70% ethanol for 30 s and 1% sodium hypochlorite (NaClO) for 30 s sequentially. After rinsing three times in sterile distilled water, all the small pieces of leaves were placed on potato dextrose agar (PDA) plates, followed by incubation at 28℃ for 3 days. Ten isolates, cultured on each PDA plate, appeared olive green with a granular surface, and an uneven white edge, and finally turned greenish black. The conidia were hyaline, with ellipsoidal to subglobose shapes and spore sizes of 5.5-8.3 × 7.2-12.0 µm (width × length) (=7.2±0.71 × 9.9±1.3 µm, n=40). These morphological characteristics are consistent with those of Phyllosticta species. To confirm the species, three representative isolates, JFRL 03-768, JFRL 03-769 and JFRL 03-770 were selected for further identification. The internal transcribed spacer (ITS) region, actin (ACT), translation elongation factor 1-alpha (TEF1-a), and glyceradehyde-3-phosphate dehydrogenase (GPD) genes of the three isolates were amplified and sequenced with the primers V9G/ITS4 (Carbone and Kohn 1999), ACT-512F/ACT-783R (Carbone and Kohn 1999), EF-728F/EF-2 (O´Donnell et al. 1998) and Gpd1-LM/Gpd2-LM (Myllys et al. 2002; Guerber et al. 2003), respectively. All sequences had been deposited into GenBank (ITS: OQ195332, OQ195333 and OQ195334; ACT: OQ207621, OQ207622 and OQ207623; TEF1-a: OQ207624, OQ207625 and OQ207626; GPD: OQ207627, OQ207628 and OQ207629). A maximum likelihood phylogenetic tree was constructed using the IQtree V1.5.6 (Ngugen et al. 2015) based on the concatenation of multiple sequences (ITS, ACT, TEF1-a and GPD). In the cluster analysis, the representative isolates (JFRL 03-768, JFRL 03-769 and JFRL 03-770) were positioned within a clade comprising of Phyllosticta styracicola. Subsequently, the pathogenicity of P. styracicola was determined by wound inoculation of healthy 2 year-old N. nagi plants, and this experiment was repeated for three times. Briefly, for each isolates, six disinfected leaves were wounded with a sterile scalpel, and then inoculated with 10-µl drop of the conidial suspension (1 × 106 conidia/ml). Another six disinfected leaves were inoculated with 10-µl drop of sterile water as a control group, and all plants were incubated at 28°C with 80% humidity. After 15 days, a similar spot lesion appeared on the leaves of the experimental group. P. styracicola was successfully re-isolated, and then subjected to morphological identification and molecular sequencing (ITS, ACT, TEF1-a and GPD genes). Whilst, the control leaves showed no symptoms. Previous studies have reported that P. styracicola could result in the development of lesions on Styrax grandiflorus leaves in China (Zhang et al. 2013). To our knowledge, this is the first report that P. styracicola can cause leaf spot on N. nagi in China.

First Report of Leaf Spot Disease on Chamaedorea elegans Caused by Fusarium oxysporum in China.

Chamaedorea elegans, native to Mexico and Guatemala, is a commonly planted indoor and small-scale garden ornamental due to its stately appearance, tolerance of low light levels, and its ability to improve air quality (El-Khateeb et al. 2010). In December 2021, an unknow leaf-spot disease was observed on C. elegans in Ganzhou City of Jiangxi Province, China (25.83 °N, 114.93 °E). The symptoms were small brown spots on the leaves, gradually expanded into irregular dark brown spots with necrotic tissue forming in the center of the lesions (Figure 2 A-1 and A-2). To isolate the pathogen, the diseased leaves were surface sterilized in 75% ethanol for 30 s. Small pieces of tissue (5 × 5 mm) were taken from the margin between diseased and healthy tissue, disinfected 1% NaClO for 45 s, washed three times in sterile water, and then placed on PDA at 25 ± 1°C for 5 days. Later, five isolates were purified from single spores and each of the five isolates has the same properties as described below. The isolates had abundant pale purple flocculent hyphae with purple pigmentation (Figure 2 C-1 and C-2). Macroconidia were falciform, straight or slightly curved, 1-2 septate, 11.75 to 22.99 × 3.06 to 4.44 µm (µ=16.08 µm × 3.37 µm, n=50) (Figure 2 D-1). Microconidia were oval or elliptical, a septate, 4.03 to 9.19 × 1.92 to 3.73 µm (µ=5.88 µm × 2.66 µm, n=50) (Figure 2 D-2). Chlamydospores formed singly or in pairs, and were terminal or intercalary in hyphae (Figure 2 D-3). Based on morphological characteristics, the fungus was preliminarily identified as a Fusarium sp. (Leslie et al. 2006). To confirm the identification, primers ITS1/ITS4 (White et al. 1990), RPB2-5f2/RPB2-7cr (O'Donnell et al. 2010; Liu et al. 1999) and TEF 1-αF/TEF 1-αR (O'Donnell et al. 2000) were used to amplify and sequence apportion of the ITS, RPB2 and TEF (Table 1). The sequences (Genebank accession number: OM780148, OM782679, OM782680) shared 100% idnetity with Fusarium oxysporum (Genebank accession number: MH866024.1, MH484930.1, MH485021.1). The maximum likelihood (ML) phylogenetic analysis of the concantenated ITS, RPB2 and TEF sequences was performed in MEGA7.0. (Sudhir et al. 2016), assigning the isoaltes to the F. oxysporum species complex (Figure 1). To confirm the pathogenicity, nine pots of healthy 3-year-old C. elegans plants were inoculated in the greenhouse (12 h light/12 h dark cycle, RH 90 %, three for wounded inoculation, three for nonwounded inoculation and three for control). Fifty disinfected leaves were wounded with sterile needles and fifty remained unwounded. The wounded (Figure 2 B-1 and B-2) and unwounded leaves were inoculated with a 10 µL spore suspension (1.0 × 106 conidia/ml) which was taken from each of the five isolates cultured for 7 days. Fifty leaves were mock-inoculated with sterile water (Figure 2 B-3 and B-4). After incubation for 7 days, the wounded leaves inoculated with the spore suspension had similar symptoms to the original diseased leaves, while the unwounded leaves and the control leaves did not develop symptoms. The experiment was repeated three times and the pathogens was reisolated from wound-inoculated leaves with the same morphological characteristics to the original pathogens, and identified as F. oxysporum by morphological and molecular analysis, completing Koch's postulates. F. oxysporum, a pathogen with a broad spectrum of hosts, ranks 5th among the top 10 fungal plant pathogens (Amjad et al. 2018.) and has been reported to Carpinus betulus, Citrullus lanatus, Pinus pinea (Mao et al. 2021; Muhammad et al. 2021; Monther et al. 2021). To our knowledge, this is the first report of leaf spot disease on C. elegans caused by F. oxysporum in China. C. elegans is an important ornamental plant in China with high economic value, so the disease has the potential to be a threat to its cultivation industry.

First report of leaf spot on Chaste-Tree Caused by Alternaria alternata in China.

Chaste-tree (Vitex agnus-castus Linn.) is a perennial ornamental shrub that is native to Europe, which has been widely distributed in China. Since 2021, a serious leaf spot on chaste-tree leaves was observed in Nanjing Botanical Garden, Jiangsu Province, China (31°14'6″N, 118°22'12″E). The disease incidence on the leaves ranged from 20 to 40%. The disease symptom initially appeared as irregular small gray spots on leaves that gradually coalesced into larger lesions with diseased leaves turning black and withering. From August of 2021 to 2022, small pieces of leaf tissues (5×5mm) from the necrotic borders of five typical symptomatic infected leaves were collected and surface sterilized (with 75% ethanol), then incubated in darkness at 25°C for 7 days. A total of fifteen isolates were obtained by monosporic isolation (isolation frequency of 76%). The fungal colonies were initially grayish-white and turned into dark gray with abundant cotton-like aerial hyphae. Microscopic observations revealed light-brown conidia that were obclavate or obpyriform (inversely pear-shaped) with length between 10 and 20 µm (mean 13.3 ± 2.4 µm) and widths between 5 and 10 µm (mean 7.8 ± 1.2 µm), 2 to 4 transverse septa and 0 to 2 longitudinal septa per conidium (n=30) were observed. The fungus was identified as Alternaria alternata based on the colony characteristics (Simmons 2007) and the representative isolate Aa1 was used for further studies. To further identify Aa1, the region of internal transcribed spacer (ITS) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH), translation elongation factor 1-alpha (EF-1a) and RNA polymerase second largest subunit (RPB2) genes were amplified from genomic DNA and sequenced with the primer pairs ITS1/ITS4 (Jayawardena et al. 2019), EF-728F/EF-986R (Carbone and Kohn 1999), Gpd1/Gpd2 (Berbee et al. 1999) and RPB2-5F/RPB2-7cR (Liu et al. 1999) respectively. Sequences were deposited into GenBank (Accession No. OQ626644 and OQ630494-OQ630496), which showed 99.2 to 100% sequence homology with those A. alternata strains in GeneBank (ITS, MN394880; GAPDH, MN410920; EF-1a, MN410916; RPB2, MN410918). The multigenes phylogenetic analysis revealed that isolate Aa1 and Alternaria alternata TCS3002 + CBS 916.96 clustered within the same clade with 99% bootstrap support. To test pathogenicity, conidial suspension (1×106 spores/ml) of Aa1 was sprayed uniformly across the leaves of three 1-year-old healthy chaste-tree seedlings; sterilized distilled water sprayed on other trees were used as negative control and the experiment was repeated three times. All inoculated plants were kept in same condition (25°C, under a 16 h/8 h photoperiod and 70% relative humidity). One week later, black/gray spots were observed on the leaves of inoculated plants, similar to the symptoms that were observed on the original diseased plants, while controls remained asymptomatic. Cultures were re-isolated from the infected leaves and were again identified as Aa1 by both morphological characteristics and DNA sequence analysis. The pathogen reported here has a broad host range, and has also been reported on Magnolia grandiflora L. (Liu et al. 2019), Kalanchoe pinnata (Sanahuja et al. 2018) and Kadsura coccinea (Zhang et al. 2020) to cause leaf spot. To our knowledge, this is the first report of A. alternata causing leaf spot disease on chaste-tree and provides an important reference for further biology and epidemiology research.

First report of Neopestalotiopsis clavispora causing leaf spot on Photinia bodinieri in China.

Photinia bodinieri Lévl. is an evergreen broadleaf species widely cultivated in subtropical China as an ornamental value (Zhang et al. 2018). In July 2021, leaf spot symptoms were observed on the campus of Jiangxi Agricultural University (28°45'56″N, 115°50'21″E), Jiangxi province, China. The spots were circular to irregular, gray in the center, and dark brown on the lesion margin. The disease incidence was estimated 15%. Leaf pieces (5 × 5 mm) from the lesion borders were surface-sterilized in 70% ethanol for 30 s, followed by 2% NaOCl for 1 min, and then rinsed three times with sterile water. Tissues were placed on potato dextrose agar (PDA) and incubated at 25°C in the dark. Pure cultures were obtained by monosporic isolation, and the representative isolates, SN-3, SN-7, and SN-11 were used for morphological studies and phylogenetic analyses. The colonies of three isolates grown on PDA were white, cottony, and exhibited flocculent, contained undulate edges with dense aerial mycelium on the surface. Conidia were 5-celled, clavate to fusiform, smooth, 18.2-24.3 × 5.5-8.4 µm (n = 100). The 3 median cells were dark brown to olivaceous, central cell was darker than other 2 cells, and the basal and apical cells were hyaline. Conidia developed filiform appendages; one basal appendage (3.3-8.2 µm long; n = 100), and 2-3 apical appendages (16-29 µm long; n = 100). Morphological features were similar to Neopestalotiopsis sp. (Maharachchikumbura et al. 2014). Portions of internal transcribed spacer (ITS) regions, ß-tubulin 2 (TUB2) and translation elongation factor 1-alpha (TEF1-α) genes were amplified from genomic DNA for the three isolates using primers ITS1/ITS4, T1/Bt-2b, EF1-728F/EF-2 (Maharachchikumbura et al. 2014), respectively. All sequences were deposited into GenBank (ITS, OQ572345 - OQ572347; TUB2, OQ597847 - OQ597849; TEF1-α, OQ597844 - OQ597846). A maximum likelihood and Bayesian posterior probability analyses using IQtree v. 1.6.8 and Mr. Bayes v. 3.2.6 with the concatenated sequences placed SN-3, SN-7, and SN-11 in the clade of N. clavispora. Based on the multi-locus phylogeny and morphology, three isolates were identified as N. clavispora. Pathogenicity of the three isolates was verified on nine disease-free 7-year-old Photinia bodinieri plants, which were grown in the field. Two healthy leaves per plant were wounded with two pricks using a sterile needle (Φ=0.5 mm) and inoculated with 20 µL conidial suspension per leaf (106 conidia/mL). Another nine control plants were inoculated with sterile water. 36 leaves were used for the pathogenicity test of three isolates. All leaves were covered with plastic bags to maintain a humid environment for 2 days. The inoculated leaves showed similar symptoms to those observed in the field, whereas control leaves were asymptomatic after 10 days. The fungi were consistently reisolated only from the inoculated and symptomatic leaves, fulfilling Koch's postulates. N. clavispora can cause leaf diseases in a variety of hosts, including Kadsura coccinea (Xie et al. 2018), Photinia serratifolia (Yang et al. 2018), Camellia chrysantha (Zhao et al. 2020). Photinia spp. is an excellent landscape gardening plant, threatened with grey blight (Pestalotiopsis microspore) (Ye et al. 2022), anthracnose (Colletotrichum sp.) (Guan et al. 2013). However, this is the first report of N. clavispora infecting Photinia bodinieri in China. This work provided crucial information for epidemiologic studies and appropriate control strategies for this newly emerging disease.

First report of leaf spot disease caused by Alternaria alternata on Polygonatum cyrtonema Hua in Hunan Province of China.

Polygonatum cyrtonema Hua, a perennial plant of the Asparagaceae family, is an important herb in Chinese medicine and is mainly grown in the Chinese provinces of Guizhou, Hunan, Yunnan, Anhui, and Zhejiang (Chen et al. 2021). In June 2021, a new case of leaf spot disease was detected in an 80 m2 plantation of P. cyrtonema on Xuefeng Mountain, Huaihua City, Hunan Province (27°17'30″N, 110°24'20″E). It infected almost 40% of the total planted area. Initially, irregular light brown spots appeared on the leaves, gradually turning dark brown and coalescing to form large necrotic areas, after which the affected plant turned yellow and eventually died. Ten disease samples were collected from ten plants in the plantation area. The leading edge of necrotic tissues were rinsed with sterile water and then disinfected with 3% hydrogen peroxide for 30 s, followed by 75% ethanol for 90 s, and rinsed three times with sterile water. Samples were then placed on water agar plates and incubated in the dark in a constant temperature incubator at 28 ℃ for 3-5 days. After mycelial growth was observed in the media, the hyphae were transferred to potato dextrose agar plates and incubated for 3-5 days at 28 ℃ in the dark. Ultimately, 12 purified fungal isolates were obtained, some of which were morphologically similar, including 10 that were Alternaria (83.3% isolation rate). Three representative isolates (HJYB1, HJYB2, and HJYB3) were selected for further study. The initial colonies were grayish green with white fluffy mycelia on the surface and a prominent white rim, which became brown with dense, cottony aerial mycelia as the colonies matured. The conidia were obpyriform or ellipsoidal, pale to dark brown, with 0-4 transverse and 0-3 longitudinal septa, some with a short cylindrical beak at the tip. They measured 11.826-28.873 × 6.231-26.018 µm (n = 100). To further confirm the identity of the isolates, their rDNA internal transcribed spacer region (ITS), ß-microtubulin (TUB2) and translation elongation factor-1 (TEF-1) genes were amplified and sequenced using the ITS4/ITS5, TUB2F/R and EF-526F/1567R primers, respectively (Hong et al. 2006). The sequences were submitted to GenBank (ITS: OR513924, OR513964, OR519874; TUB2: OR526928, OR533421, OR526929; TEF: OR526926, OR533420, OR526927). A concatenated phylogenetic tree of the three genes showed that the isolate clustered significantly with Alternaria alternata. Based on morphological identification and phylogenetic tree analysis, the isolate was identified as A. alternata. We carried out pathogenicity tests on four uniformly growing P. cyrtonema plants. Three of these plants were used as experimental plants and one as a control. For each plant, three young leaves were selected and inoculated with 6 × 6 mm PDA blocks, while sterile PDA blocks were used as controls. The treated plants were subjected to 10 days of stable temperature in a climatic chamber set at 28°C, 80% constant relative humidity and 12 hours of light per day. The pathogenic lesions appeared and the pathogens re-isolated from the diseased leaves showed similar morphological characteristics to representative isolates and were confirmed as A. alternata by DNA sequencing, thus fulfilling Koch's postulates. A. alternata is the major causal agent of leaf spot on P. sibiricum (Zou et al. 2023) and Agrimonia pilosa (Jiang et al. 2023). As far as we know, leaf necrosis caused by A. tenuissima has been found on P. cyrtonema (Li et al. 2020). To our knowledge, this is the first report of A. alternata causing leaf spot disease in P. cyrtonema. These findings form the basis for the management of this leaf spot disease.

Chitosan Enhances Low-Dosage Difenoconazole to Efficiently Control Leaf Spot Disease in Pseudostellaria heterophylla (Miq.) Pax.

Pseudostellaria heterophylla (Miq.) Pax is a popular clinical herb and nutritious health food. However, leaf spot disease caused by fungal pathogens frequently occurs and seriously influences the growth, quality, and yield of P. heterophylla. In this work, the field control roles of difenoconazole, chitosan, and their combination in the leaf spot disease in P. heterophylla and their effects on the disease resistance, photosynthetic capacity, medicinal quality, and root yield of P. heterophylla are investigated. The results manifest that 37% difenoconazole water-dispersible granule (WDG) with 5000-time + chitosan 500-time dilution liquid had a superior control capacity on leaf spot disease with the control effects of 91.17%~88.19% at 15~30 days after the last spraying, which significantly (p < 0.05) exceeded that of 37% difenoconazole WDG 3000-time dilution liquid and was significantly (p < 0.01) higher than that of 37% difenoconazole WDG 5000-time dilution liquid, chitosan 500-time dilution liquid, or chitosan 1000-time dilution liquid. Simultaneously, this combination could more effectively enhance the disease resistance, photosynthetic capacity, medicinal quality, and tuberous root yield of P. heterophylla compared to when these elements were applied alone, as well as effectively reduce difenoconazole application. This study emphasizes that chitosan combined with a low dosage of difenoconazole can be proposed as a green, efficient, and alternative formula for controlling leaf spot disease in P. heterophylla and enhancing its resistance, photosynthesis, quality, and yield.

First Report of Leaf Spot Disease Caused by Alternaria brassicae on Cercidiphyllum japonicum in China.

Cercidiphyllum japonicum is a deciduous tree belonging to the genus Cercidiphyllum of the family Cercidiphyllaceae (Li et al., 2008). Fossil records indicated that this tree was once distributed throughout the Northern hemisphere during the tertiary period, whereas it is now only found in Japan and China as a consequence of quaternary glaciation. In 1989, C. japonicum was listed as a Rare and Endangered plant in China (Song et al., 1989). It is also highly valued for use in ornamental, medicinal, and research contexts, leading to its widespread planting and cultivation throughout China. In September 2021, a severe leaf spot infection (FigS1.A) was first detected on C. japonicum trees in Meigu County, Sichuan Province, China (N 28°33', E 103°14'). In a survey of twenty 100-year-old C. japonicum trees in this region, the incidence of such leaf spot was found to be approximately 95%. During the early stages of disease, infected leaves exhibited small punctate spots along the leaf center or margins. These spots were brown in the center with black edges. As the disease progressed, these spots expanded until they coalesced to yield large circular or irregularly shaped regions of necrotic tissue, and finally produced mildew. Samples of leaf tissue between symptomatic and healthy regions (5 mm×5 mm) were excised from five symptomatic leaves, surface disinfected for 30 s with 75% ethanol, soaked for 2 min in 3% NaClO, rinsed then plated on potato dextrose agar (PDA) medium supplemented with ampicillin and carbenicillin (50 µg/ml each). After cultured for 3 days in the dark at 25°C, emergent hyphae were purified by subculturing them on fresh PDA medium. In total, single spore culturing was performed by collecting and purifying seven fungal isolates. These isolates exhibited largely comparable morphological characteristics. Aerial hyphae had a cotton-like appearance and were white to pale gray in color (FigS1.B), turning pale reddish-brown with profuse sporulation (FigS1.C). Conidia were present in long chains, with conidiophores being present in clusters or in isolation (FigS1.D), with 1-5 transverse septa, 0-3 oblique and longitudinal septa and an ellipsoidal to obpyriform structure, measuring 9.0-38.6 µm in length and 5.1-12.6 µm in width (n = 40) (FigS1.E). These seven isolates thus exhibited morphological characteristics consistent with those of members of the Alternaria genus (Simmons, 2008). Molecular identification of a representative isolate (LGB9) was performed by amplifying the internal transcribed spacer (ITS) rDNA, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), translation elongation factor 1-alpha (TEF1), and partial RNA polymerase II largest subunit (RPB2) gene sequences with the ITS1/ITS4 (White et al.,1990), GDF/GDR (Templeton et al., 1992), TEF-728F/TEF-986R (Carbone & Kohn 1999) and RPB2-5F2/RPB2-7cR (Sung et al., 1990; Liu et al., 1999), and Bt-2a/Bt-2b (Glass and Donaldson 1995) primer pairs, respectively. The resultant sequences were deposited in GenBank (ITS, OL659190; GAPDH, OL685343; TEF, ON340848; RPB2, OL685344). Further phylogenetic analyses of isolate LGB9 revealed it to cluster in the A. brassicae clade with 97% bootstrap support. To confirm the pathogenicity of isolate LGB9, 15 healthy leaves from five one-year-old C. japonicum plants were spray-inoculated with a suspension containing 3×105 LGB9 conidia/mL, with control leaves instead being sprayed with distilled water. After 8 days, inoculated leaves exhibited symptoms similar to those observed on naturally infected leaves (FigS1.F-I), whereas the mock leaves were free of any symptoms. This is the first report to our knowledge of a case of leaf spot disease caused by A. brassicae affecting C. japonicum in China or anywhere else in the world. To ensure the protection of this living fossil species, appropriate interventional measures should be adopted to manage the development and spread of this disease.