First Report of Vacuiphoma oculihominis Causing Fruit Rot on Navel Orange (Citrus sinensis) in China.

Newhall navel orange [Citrus sinensis (L.) Osbeck] is an economically important agricultural product in China. In February 2022, a rare lesion symptom was observed on Newhall navel oranges that were harvested from an orchard Ganzhou city, Jiangxi province, China (25.53° N, 114.79° E) and stored for 90 days (18±2℃, 80 to 90% RH) at the Jiangxi Key Laboratory for Postharvest Technology and Non-destructive Testing of Fruits and Vegetables (28.68° N, 115.85° E). Approximately 2% (15/750) of the oranges exhibited symptoms, with normal appearance but ink-black flesh and juice, yellowish lesions on edges of the symptoms, and no unusual odor. To isolate the pathogen, three 5 × 5 mm pieces of symptomatic tissue from a diseased orange were disinfected in 75% ethanol for 30 s, rinsed three times with sterile water, and inoculated on potato dextrose agar (PDA) at 25±1℃ and a 12:12 h photoperiod for 7 days. A pure isolate named ND-hsp was obtained. The colony was light yellow center with pale edge on the top and brown on the bottom. Conidia and pycnidia were observed on PDA medium after 2 months. Conidia were long oval, no septa, 2.9 × 3.4 µm (n = 50), and pycnidia were solitary, 39.4 × 43.9 µm (n = 20), with one or no orifice, brown to dark brown. The morphological characteristics of ND-hsp strain on PDA, oatmeal agar and malt extract agar were similar to those of the Didymellaceae (Aveskamp et al. 2010). Ulteriorly, the genomic DNA of the ND-hsp isolate was extracted from its mycelia using a fungal genomic DNA extraction kit (Solarbio, Beijing, China) for subsequent phylogenetic analyses. Four primer sets, LR0R (Rehner and Samuels 1994) /LR7 (Vilgalys and Hester 1990), V9G (Hoog and Gerrits 1998) /ITS4 (White et al. 1990), Btub2Fd/Btub4Rd (Woudenberg et al. 2009) and RPB2-5F2 (Sung et al. 2007)/RPB2-7cR (Liu et al. 1999) were used to amplify the corresponding DNA fragments of large subunit ribosomal RNA (LSU), internal transcribed spacer region (ITS), beta-tubulin gene (TUB2) and RNA polymerase Ⅱ second largest subunit (RPB2), respectively. The obtained sequences were assigned GenBank accession numbers and showed 99 to 100% identity with their counterparts of Vacuiphoma oculihominis UTHSC DI16-308. A phylogenetic tree was constructed in MEGA 7.0 using the concatenated sequences, placing the isolate within the V. oculihominis clade by 100% bootstrap support. Pathogenicity experiments were performed in triplicate. Ten Newhall navel oranges were surface sterilized with 75% ethanol and inoculated with 15µL of a spore suspension (2×106 spores/ml) into a 3 mm-diameter wound on the equator. The control group received sterile water instead of the spore suspension. Treated and control oranges were incubated at 25±1 ℃ and about 90% relative humidity for 20 days. All oranges were cut longitudinally or transversely through the inoculated wound and examined internally. The oranges inoculated with ND-hsp exhibited ink-black flesh and juice symptoms consistent with the initial oranges. The control oranges remained asymptomatic. Under the Koch's rule, V. oculihominis was reisolated from diseased oranges and kept in Collaborative Innovation Center of Postharvest Key Technology and Quality Safety of Fruits and Vegetables in Jiangxi Province. GenBank database analysis confirms that V. oculihominis has been found in human eye secretions and decayed trees. This is the first report of V. oculihominis as a pathogen on navel oranges in China. Our findings contribute to understanding of citrus fruit pathogens.

First Report of Colletotrichum fructicola Causing Anthracnose on Paeonia lactiflora in China.

Paeonia lactiflora Pall is a traditional famous flower with long cultivated history in China, and has important medical and ornamental functions (Duan et al. 2022). In the middle of June 2022, anthracnose disease was observed nearly 25% (n=90) on P. lactiflora in Poyang County, Shangrao City, Jiangxi Province (29.00° N, 116.67° E) (Figure 1 E). The symptoms of the disease were small, round, light brown spots then grew bigger to round or irregular dark brown lesions (5 to 7 mm diameter) progressively on the leaves with disease spread (Figure 1 A). Subsequently, necrotic tissue was formed in the center and caused fade and wilt on the leaves ultimately, which reduced the medicinal and aesthetic value severely. Small pieces of diseased tissue (5 × 5 mm) were cut from the diseased junction, disinfected with 75% ethanol for 30 to 45 seconds, then 1% NaClO for 1 to 2 minutes, rinsed three times with sterile water. To identify the pathogen, tissues were placed on PDA and incubated for 3 days at 28°C. Single spore isolates were cultured on PDA, the colonies of one representative strain (SY4) were originally white with a lot of aerial mycelium after 5 to 7 days at 28°C in the incubator. The center of the colony turned greyish-white, released tiny orange-yellow particles (conidia) (Figure 1 F and 1 G), which were single, colorless, elongated ovals with rounded ends and measured 11.29 to 23.24 × 3.94 to 5.60 µm (av=15.89 µm × 4.74 µm, n=50) (Figure 1 H and 1 I). The isolate SY4 was identified to Colletotrichum fructicola based on morphological characteristics (Yang et al. 2021; Li et al. 2022b). For further molecular identification, the rDNA-ITS, actin gene (ACT), glyceraldehyde-3-phosphatedehydrogenase (GAPDH), chitin synthase (CHS) and calmodulin gene (CAL) genes were amplified and sequenced with primers of ITS1/ITS4 (Gardes et al. 1993), ACT-512F/ACT-783R, GDF/GDR (Templeton et al. 1992), CHS-79F/CHS-345R (Carbone et al. 1999) and CL1C/ CL2C (Weir et al. 2012) respectively. The accession numbers in GenBank were OP523977 (ITS-rDNA), OP547618 (ACT), OP605733 (GAPDH), OP605732 (CHS), and OP605731 (CAL). The BLAST analysis revealed that these sequences were identical more than 99% with those of C. fructicola (GenBank accession Nos. MZ437948.1, MN525803.1, MN525860.1, MZ13360.1 and ON188684.1) (Figure 2). To confirm pathogenicity, the leaves were cleaned with 75% ethanol, rinsed with sterile water. After the leaf surface was dried naturally, 20 leaves were pricked at two symmetrical places on either side of the main veins of the leaf with a sterilized inoculum needle (2.0 mm in diameter), half of the wounded leaves were inoculated with 20 µL spore suspension (1.0 × 106 spores/mL) (Figure 1 C and 1 D), while the other half were inoculated with sterile water as controls (Figure 1 B). Inoculated leaves were grown for 5 days in an incubator at 28 °C and above 90% relative humidity, repeated three times. The results demonstrated that the wounded leaves with C. fructicola showed the same signs of wilting with the original disease leaves, while control leaves remained healthy. The same fungus was reisolated from the diseased leaves which confirmed with Koch's postulates. The same fungus was re-isolated from the diseased leaves while it was not isolated from control leaves, confirmed with Koch's postulates. In China, it had been reported that C. fructicola caused anthracnose on Persea americana (Li et al. 2022a) and Myrica rubra (Li et al. 2022b). To the best of our knowledge, this is the first report of anthracnose on P. lactiflora caused by C. fructicola in China. The results will help to develop effective control strategies for anthracnose on P. lactiflora.

First Report of Colletotrichum gloeosporioides Causing Anthracnose on Wisteria sinensis in China.

Wisteria (Wisteria sinensis) is a well-known ornamental plant for environmental protection in the garden, which also has a high value for medicinal use. In December 2021, leaf spots were observed on W. sinensis plants growing on the campus of Jiangxi Agricultural University in Nanchang, Jiangxi Province (28.45° N, 115.49° E), with a incidence rate of 40% plants were infested (n = 100 investigated plants). Initially leaf spots were small and pale brown (Approx. 2 mm in diameter), which gradually expanded into round or irregular dark brown spots as disease progressed, and lesions developed greyish-white necrotic tissues in the center at later stages, eventually causing the leaves to rot. To isolate the pathogen, tissues (5 × 5 mm) at the margin of lesions were cut from ten symptomatic leaves, surface disinfected with 75% ethanol for 30 s followed by 2% sodium chloride (NaClO) for 1 min, rinsed three times with sterile distilled water, and the dried tissues were cultured on potato dextrose agar (PDA) at 28 ± 1℃ in darkness for 3 days. After culture purification, five isolates were obtained and the representative single spore isolate (ZTTJ1) was used for subsequent identification tests. After 10 days of incubation on PDA medium, colonies had dense aerial mycelium with a gray center and dark gray-green mycelium outward, with orange-red conidial masses distributed in a ring on the surface. The underside of the colonies was light gray to dark gray. Conidia were cylindrical, with ends obtuse-rounded, 11.83 to 20.74 × 3.34 to 5.33 µm (av=16.11 µm × 4.26 µm, n = 50) in size. These morphological characteristics were consistent with Colletotrichum gloeosporioides (Shi et al, 2019). Six conserved regions of isolate (ZTTJ1), internal transcribed spacer (ITS), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), calmodulin (CAL), ß-tublin (TUB), actin (ACT), and chitin synthase 1 (CHS1) gene regions were amplified using ITS1/ITS4 (Gardes et al, 1993), GDF/GDR (Templeton et al, 1992), CL1C/CL2C (Li et al, 2018), Bt2a/Bt2b (Prihastuti et al, 2009), ACT-512F/ACT-783R and CHS-79F/CHS-345R (Carbone et al, 1999) primers, respectively. Using BLAST, ITS, GAPDH, CAL, TUB, ACT, and CHS1 gene sequences (GenBank Accession No. OP703312, OP713773, OP713775, OP713776, OP713772, OP713774, respectively) were over 99% identical to C. gloeosporioides (GenBank Accession No. MK967281, MH594288, MT449307, MN624110, MN107239 and MN908602, respectively). A maximum likelihood (ML) phylogenetic analysis based on ITS-ACT-GAPDH-CHS1-CAL-TUB2 sequences using MEGA7.0, placed isolate (ZTTJ1) within C. gloeosporioides. To complete Koch's postulates, 10 µL spore suspension (1.0 × 106 conidia/mL) of ZTTJ1 (7-day-old culture on PDA medium) was dropped onto 10 leaves wounded with a sterilized needle and 10 non-wounded leaves, respectively. Ten wounded leaves were inoculated with sterile water as controls. All leaves were incubated at 28 ± 1 °C and 90 % relative humidity (12 h/12 h light/dark). After 7 days, all wounded leaves inoculated with C. gloeosporioides developed symptoms as previously observed, while the control and non-wounded leaves remained healthy. The fungus re-isolated from the inoculated leaves were identified as C. gloeosporioides by morphological and molecular identification; the pathogen causing disease in W. sinensis was determined to be C. gloeosporioides. To our knowledge, this is the first report of C. gloeosporioides causing anthracnose on W. sinensis in China. This work has identified the pathogenic species of the disease, which helps to take targeted measures to control its spread, providing a basis for the prevention and treatment of the disease.

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 Postharvest Fruit Rot on Citrus reticulata Blanco Caused by Fusarium concentricum in China.

Nanfeng tangerine (Citrus reticulata Blanco) is highly regarded for its nutritional and economic value. In January 2022, an unknown fruit rot was observed on Nanfeng tangerine fruits harvested from Nanfeng County (27.22 °N, 116.53 °E), Fuzhou City, Jiangxi Province after 70 days in storage (25 °C, 90% relative humidity). The disease mostly started from the pedicel or a wound. Symptoms initiated with dark brown lesions that rapidly expanded between the fruit center and pulp capsule causing total fruit rot. The surface of symptomatic fruit was sterilized with 75% ethanol for 30 s and 2% NaClO for 30 s. Small diseased tissue pieces (2 mm2) between diseased and healthy tissues were placed on potato dextrose agar (PDA) and put in an incubator (25 ± 1 °C) for 3 days. The representative isolate NFMJ-1 was subcultured onto PDA using single-spore purification. Colonies on PDA were light yellow to white, with abundant flocculent aerial hyphae. Microconidia were oval, obovoid to allantoid, 0 septate, occasionally 1 septate, 4.07 to 17.53 × 1.69 to 3.56 µm (average=7.40 µm × 2.55 µm, n=50). Macroconidia were slender, with a beaked apical cell and a foot-shaped basal cell, 3 to 5 septate, 22.99 to 81.12 × 2.34 to 3.81 µm (average=45.04 µm × 3.12 µm, n=50). According to morphological characteristics, the isolate was tentatively identified as Fusarium sp. (Leslie and Summerell 2006). To confirm the identification, the internal transcribed spacer (ITS), translation elongation factor 1-alpha (TEF), RNA polymerase II second largest subunit (RPB2), beta-tubulin gene (TUB2), and calmodulin gene (CaM) sequences were amplified with primers ITS1/ITS4 (Gardes et al. 1993), TEF1/TEF2 (O'Donnell et al. 2010), RPB2-5f2/RPB2-7cr (Liu et al. 1999), Bt2a/Bt2b (Glass and Donaldson 1995), and CL1C/CL2C (Weir et al. 2012), respectively. The obtained sequences (ON184033, ON212051, ON212052, ON212053, ON212054) showed homology with F. concentricum ITS (MW016417.1; 514/514 bp), TEF (MK609902.1; 667/667 bp), RPB2 (LC631461.1; 941/972 bp), TUB2 (MT942588.1; 331/337 bp), and CaM (MK609916.1; 558/597 bp). A phylogenetic analysis of concatenated ITS-RPB2-TEF sequences was performed by MEGA7.0 with the maximum likelihood and Kimura 2-parameter model, revealing that the isolate was placed in the F. concentricum clade. To confirm pathogenicity, 36 healthy tangerine fruits were surface sterilized with 75% alcohol, then 18 disinfected fruits were wounded with sterile needles and 18 remained unwounded. Half of the wounded and un-wounded fruits were inoculated with 10 µL of a conidial suspension (1.0 × 106 conidia/ml) of isolate NFMJ-1 cultured for 7 days on PDA. Half of the wounded and un-wounded fruits were mock-inoculated with sterile water as controls. After incubation in an incubator (25 ± 1°C, 90% relative humidity) for 7 days, the wounded fruits inoculated with F. concentricum showed similar symptoms to the original diseased fruits, while the mock-inoculated fruits were asymptomatic. The pathogenicity test was repeated three times. The pathogen was re-isolated from the wound-inoculated fruits and identified as F. concentricum by morphological and molecular analysis, completing Koch's postulates. F. concentricum has been reported as a pathogen of Podocarpus macrophyllus (Dong et al. 2022), Capsicum annuum (Wang et al. 2013) and Zea mays (Du et al. 2020) in China. This is the first report of fruit rot caused by F. concentricum on Citrus reticulata in China. Appropriate prevention and control measure of the pathogen need to be developed to preserve marketability of this economically important citrus fruit.

First Report of Colletotrichum karstii Causing Anthracnose of Begonia lanternaria Irmsch. in China.

Begonia lanternaria Irmsch., an ornamental plant endemic in China, which is commonly used in landscape and interior decoration. In March 2021, an estimated 30% B. lanternaria plants were observed with anthracnose-like symptoms at a botanical garden conservation greenhouse in Mengla County of Yunnan Province (21.91° N, 101.21°E). Initially, small black spots developed on the disease leaves, which gradually expanded into irregular necrotic lesions surrounded by a yellowish halo, eventually turned wilting and defoliating. Twenty diseased leaves were collected and surface-disinfested with 75% ethanol for 30 s. Small fragments (5 × 5 mm) from the margin of lesions were disinfected with 1% NaClO for 120 s, washed with sterile water three times, and cultured on potato dextrose agar (PDA) at 28 ± 1℃. After 3 days single spores from four fungal colonies with identical morphology were isolated. Colonies on PDA were 70-75 mm diam in 7 d (7.5-10.6 mm/d), with dense white to gray-white mycelia attached with brown to black-brown acervulus. The underside of the culture was yellow to yellowish-brown concentric circle. Conidia were single-celled, hyaline, straight to slightly curved, cylindrical, 12.88 to 16.66 × 6.25 to 7.97 µm (av=14.65 µm × 7.22 µm, n=50) in size. For molecular identification, genomic DNA was extracted from a representative isolate, and the internal transcribed spacer, glyceraldehyde-3-phosphate dehydrogenase, calmodulin gene, ß-tublin, actin, and chitin synthase 1 genes were amplified with ITS1/ITS4 (Gardes et al, 1993), GDF/GDR (Templeton et al, 1992), CL1C/CL2C (Li et al, 2018), Bt2a/Bt2b (Prihastuti et al, 2009), ACT-512F/ACT-783R and CHS-79F/CHS-345R (Carbone et al, 1999) primers, respectively. The obtained DNA sequences showed over 99% homology with Colletotrichum karsti (GenBank Accession No. ITS: NR144790; GAPDH: KX578772; CAL: KY039988; TUB2: KX578804; ACT: LC412408; CHS1: KU251855), and the results of sequences were deposited into GenBank with accession No. MZ496954 (522/522 bp), MZ504978 (238/238 bp), MZ504979 (737/737 bp), MZ504982 (472/472 bp), MZ504981 (273/273 bp), MZ504980 (282/284 bp). The phylogenetic tree combined with ITS-ACT-GAPDH-CHS 1-CAL-TUB2 concatenated sequences using the maximum likelihood methods showed that the isolate was C. karsti. To confirm pathogenicity, Koch's postulates were conducted on intact plants, 10 µl spore suspension (1.0 × 106 conidia/ml) of each of four isolates (7-day-old culture on PDA) was inoculated on 15 wounded with a sterilized needle or non-wounded healthy living leaves, and 15 wounded leaves were inoculated with sterile water as controls. All leaves were incubated at 28 ± 1°C and 90% relative humidity (12 h/12 h light/dark). After 5 days, all wounded leaves inoculated with C. karsti showed symptoms similar to those previously observed, while the control and non-wounded leaves remained healthy. Colletotrichum karsti was re-isolated from inoculated leaves. C. karsti was previously reported to cause disease on Nicotiana tabacum L. (Zhao et al, 2020), Stylosanthes guianensis (Jia et al, 2017) and Fatsia japonica (Xu et al, 2020) in China. To our knowledge, this is the first report of C. karsti causing anthracnose of B. lanternaria Irmsch. in China. This disease reduces the ornamental and economic value of B. lanternaria Irmsch., and this work will provide a basis for the prevention and treatment of the disease in the future.

First Report of Postharvest Fruit Rot in Solanum muricatum Aiton Caused by Alternaria alternata in southwest China.

Solanum muricatum is native to South America and well known for its sweet, attractive, nutritious fruits. S. muricatum has been cultivated in China since the 1980s and increasingly popular (Li et al. 2015). In November 2021, an unknown fruit rot was observed in Shilin County of Yunnan Province (24.77 °N, 103.28 °E). The incidence of this disease was about 16% of 500 postharvest S. muricatum fruits after 7 d in storage room (25°C, 90% relative humidity). The initial symptoms were small brown spots on the fruit surface, which gradually expanded into irregular brown or black lesions, and gray-white mold developed in the center of the lesions, eventually the fruit turned rot. To isolate the pathogen, ten fruits with typical symptoms were collected and surface-sterilized with 75% ethanol for 45 s. Small fragments (5 × 5 mm) from the margin of lesions on fruit were disinfected with 1% sodium hypochlorite for 60 s, washed three times with sterile water then transferred to potato dextrose agar (PDA), and incubated at 28 ± 1℃ for 3 days (Li et al. 2022). Two fungal isolates with the same morphology were obtained and purified by single-spore isolation method. The colony was covered with thick fluffy aerial mycelia and the center was dark brown or black with white margins. Conidia were brown, pyriform or ellipsoid, with 1 to 3 longitudinal and 2 to 6 transverse septa, 15.12 to 34.01 × 6.90 to 12.73 µm (21.22 × 9.69 µm on average, n=50) in size. These morphological characteristics were consistent with Alternaria alternata (Li et al. 2015; Xiang et al. 2021; Alberto. 1992). For molecular identification, genomic DNA was extracted from a representative isolate, and primers ITS1/ITS4 (Gardes et al. 1993), TEF-F/TEF-R (Lawrence et al. 2013), Alt-F/Alt-R (Hong et al. 2005), GPD-F/GPD-R (Berbee et al. 1999) and EPG-F/EPG-R (Peever et al. 2004) were used to amplify the internal transcribed spacer (ITS), translation elongation factor 1-alpha (TEF), Alternaria major allergen (Alt a1), glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and endo-polygalacturonase (endoPG), respectively. The obtained DNA sequences (ITS: OM049821; TEF: OM069656; Alt a1: OM069655; GAPDH: OM069654 and endoPG: OM069653) showed over 99% homology with that of A. alternata (GenBank Accession No. MN856355.1 (565/573 bp); MN258023.1 (267/267 bp); KY923227.1 (491/501 bp); LC131645.1 (608/609 bp) and MN698284.1 (452/454 bp)). A phylogenetic tree based on the combined ITS, TEF, Alt a1, GAPDH, and endoPG sequences using the maximum likelihood methods with Kimura 2-parameter model, bootstrap nodal support for 1000 replicates in MEGA7.0 (Li et al. 2019) revealed that the isolate was assigned to A. alternata. To confirm pathogenicity, 10 µL spore suspension (1.0 × 106 conidia/ml) obtained from 7-day-old PDA cultures of each isolate were inoculated on 15 needle-wounded and 15 non-wounded surface-disinfected fruits, respectively. Healthy fruits were inoculated with sterile water as controls and the experiment was repeated 3 times. All fruit were incubated at 25 ± 1℃, 90% relative humidity. After 7 days, all the wounded and non-wounded fruit inoculated with A. alternata showed similar symptoms to those observed on the previously fruits, while the control fruits remained healthy. The same pathogen was again isolated from the inoculated fruits, thus Koch's postulates were fulfilled. A. alternata causing fruit rot of Prunus avium and Mangifera indica in China were reported in previous studies (Ahmad et al. 2020; Liu et al. 2019). As far as we know, this is the first report of postharvest fruit rot on S. muricatum caused by A. alternata in southwest China. This work provides a basis for the development of control strategies of the disease in the future.

The involvement of the phenylpropanoid and jasmonate pathways in methyl jasmonate-induced soft rot resistance in kiwifruit (Actinidia chinensis).

Botryosphaeria dothidea is a major postharvest causal agent of soft rot in kiwifruit. Methyl jasmonate (MeJA) is an important plant hormone that participates as a plant defense against pathogens from a signal molecule. However, the impact and regulatory mechanism of MeJA on the attenuation of kiwifruit fungal decay remains unknown. This work investigated the effects of exogenous MeJA on the enzyme activity, metabolite content and gene expression of the phenylpropanoid and jasmonate pathways in kiwifruit. The results revealed that MeJA inhibited the expansion of B. dothidea lesion diameter in kiwifruit (Actinidia chinensis cv. 'Hongyang'), enhanced the activity of enzymes (phenylalanine ammonia lyase, cinnamate 4-hydroxylase, 4-coumarate: coenzyme A ligase, cinnamyl alcohol dehydrogenase, peroxidase and polyphenol oxidase), and upregulated the expression of related genes (AcPAL, AcC4H, Ac4CL, and AcCAD). The accumulation of metabolites (total phenolics, flavonoids, chlorogenic acid, caffeic acid and lignin) with inhibitory effects on pathogens was promoted. Moreover, MeJA enhanced the expression of AcLOX, AcAOS, AcAOC, AcOPR3, AcJAR1, AcCOI1 and AcMYC2 and reduced the expression of AcJAZ. These results suggest that MeJA could display a better performance in enhancing the resistance of disease in kiwifruit by regulating the phenylpropanoid pathway and jasmonate pathway.