In this research, the volatile organic compounds (VOCs) produced based on C. fimbriata exhibited strong antifungal activity against the fungal pathogen A. alternata . Our aim is to explore their bacteriostatic components.
Species of Ceratocystis and allied genera are pathogens of many trees, including Cunninghamia lanceolata. During a survey of 2020, we found a serious wilt disease of C. lanceolata in Yunnan Province, China. Three different fungi resembling Ceratocystis and allied genera were consistently isolated from discoloured foliage and stems on C. lanceolata. Morphological and DNA sequence comparisons based on 60S and LSU gene regions showed that the pathogens were Ceratocystis and related species. We included 4 isolates identified as C. acaciivora = C. manginecans, 10 isolates identified as Berkeleyomyces basicola ≡ Thielaviopsis basicola, and 1 isolate identified as Chalaropsis sp., from 3 geographical locations. Pathogenicity tests on potted plants showed that all three species were pathogenic. To our knowledge, this is the first report Ceratocystis acaciivora,B. basicola and Chalaropsis sp. causing C. lanceolata wilt in China.
Antifungal activity of the volatile organic compounds produced by Ceratocystis fimbriata strains WSJK-1 and Mby
Microorganism-produced volatile organic compounds (VOCs) are considered promising environmental-safety fumigants in food preservation. In this study, the VOCs from fungal Ceratocystis fimbriata strains (WSJK-1, Mby) were tested against postharvest fungi Monilinia laxa, Fusarium oxysporum, Monilinia fructicola, Botrytis cinerea, Alternaria solani, and Aspergillus flavus in vitro. The mycelial growth was significantly inhibited, in particular M. fructicola and B. cinerea (76.95, 76.00%), respectively. VOCs were identified by headspace solid-phase microextraction coupled with Gas Chromatography–Mass Spectrometry (HS-SPME-GC–MS); 40 compounds were identified. The antifungal activity of 21 compounds was tested by the minimum inhibitory concentrations (MIC) value. Benzaldehyde, 2-Phenylethanol, and 1-Octen-3-ol showed strong antifungal activity with the MIC in vitro ranging from 0.094 to 0.284 ml L−1 depending on the pathogen tested. The optical microscope showed serious morphological damage, including cell deformation, curling, collapse, and deficiency in mycelial or conidia cell structures treated with C. fimbriata VOCs and pure compounds. In vivo tests, C. fimbriata VOCs decreased brown rot severity in peaches, and compounds Benzaldehyde and 2-Phenylethanol could reduce peach brown rot in peaches at 60 μl L−1. The VOCs produced by C. fimbriata strain have good antifungal effects; low concentration fumigation could control peach brown rot. Its fragrance is fresh, safe, and harmless, and it is possible to replace chemical fumigants. It could be used as a potential biofumigant to control fruit postharvest transportation, storage, and food preservation. To the best of our knowledge, this is the first report on the antifungal activity and biocontrol mechanism of VOCs produced by C. fimbriata.
Elaeagnus conferta Roxb. is a perennial evergreen climbing shrub and is mainly native to India, Vietnam, Malaysia, and South China (Gupta & Singh, 2021). Various parts of this plant are used to treat multiple diseases(Gupta et al., 2021). Between during the months of March and April of 2021, in Kunming city of grower fields, Yunnan Province (N 25°02′; E 102°42′), southwest China. Some postharvest E. conferta fruits showed brown spots of decay with a greyish mycelium, which symptom only appears on fruit, and did not find it on this plant. The incidence of this disease in postharvest E. conferta fruits ranges from 45 % to 65 % in natural conditions. This pathogen is harmful and causes many plant diseases. Such as rice, oriental persimmon, pear, panicles of mango, and so on (Cho & Shin, 2004; Guillén-Sánchez et al., 2007; Lee et al., 2009). The infected fruit samples surface was disinfected with 75 % ethanol and 0.3 % NaClO for 30 s and 2 min respectively, then aseptic water washing three times. The fruit tissue is rich in carbohydrates and water content, which aid the growth of fungal species. Putting these diseased tissues on a potato dextrose agar (PDA) medium, cultured at 25 ± 1 ℃ for 7 days. The colonies grow on the PDA medium, then separated and puried again. Three pure cultures (YNGH01, YNGH03, YNGH05) were obtained, which were stored in 15 % glycerol at –80 ℃ refrigerator in the State Key Laboratory for Conservation and Utilization of Bio-Resources, Yunnan Agricultural University. After 7 days of cultivation, the colonies were round and the diameter attained up to 38 mm, the surface of the colony showed tiled, fluffy, with a velvet-like texture, greyish-green to smoke-gray, slightly raised in the middle, the edges were radial hollow and wrinkle (Fig. 1A). Conidiophores were solitary, erect, unbranched or rarely branched, slightly flexuous at the apex, septate, dark brown, 254 to 680 µm long, 3.6 to 4.5 µm wide, top of the conidiophores or the rostral were slightly swollen (Fig. 1B). Conidia were light gray or grey, solitary or bispora, irregular in shape and size (Fig. 1C), nearly circular (3.21 × 3.31 µm), oval to lemon-shaped (6.59 × 3.21 µm) or elliptical (8.35 × 4.65 µm). The CTAB method extracts 3 isolates (YNGH01, YNGH03, YNGH05) genomic DNA (Aboul-Maaty & Oraby, 2019). To confirm identity with molecular identification, performed by three different genomic DNA regions, fragments of internal transcribed spacer (ITS), partial translation elongation factor-1 alpha (TEF-1α), and actin (ACT) genomic regions. These genomic DNA were amplified with primers ITS1/4, EF1-728F/986R, and ACT-512F/783R, respectively (Carbone & Kohn, 1999). The sequences of these isolates were uploaded to GenBank (YNGH01: ON753810, ON868696, ON912090 YNGH03: ON753812, ON868698, ON912092, and YNGH05: ON753814, ON868700, ON912094). NCBI’s BLASTn search of those ITS sequences showed 99.81% similar to C. tenuissimum (MG873077.1), and sequences TEF-1α and ACT were 100% identical to several isolates of C. tenuissimum (OM256526.1 and MT154171.1). Combined the ITS region, TEF-1α, and actin (ACT) genomic regions of isolates YNGH01, YNGH03 and YNGH05 to construct a phylogenetic tree with MEGA11. Maximum likelihood phylogenetic analyses further confirmed the results (Fig. 2)(Santos et al., 2020). Healthy and mature E. conferta fruits were used for pathogenicity test. Pathogens were washed with sterilized water at a final concentration of 2× 106 spores/mL (Jo et al., 2018). The test was divided into A and B groups (A: The surface of fruits was pierced with a sterilized needle that carried pathogenic fungus of final concentration at 2×106 spores/mL B: Sprayed at the concentration of 2×106 spores/mL on fruits). The control fruits were treated with sterilized water and stored at 25 ± 1 ℃ with a relative humidity of 80 %, average group with 10 fruits in this test, which was repeated three times. After 7 days, the fruits of group A were initially sesame seed size of the disease spots, nearly round, irregular, with grayish-brown spots, and slightly depressed. Later, the lesion gradually turns dark brown (Fig. 1D). And group B began with small patches of brown fungal growth on the pericarp, with the development of the disease, the necrotic spots enlarged and developed irregular and coalesced, the color of spots became gray or black gradually (Fig. 1E). The symptoms were similar to previously observed and the pathogen was reisolated and identified as C. tenuissimum. Control fruits were healthy (Fig. 1F). The pathogens test fulfilled Koch’s postulates. According to morphology (Bensch et al., 2012), rDNA-ITS, TEF-1α, and ACT sequence analysis, phylogenetic analysis, and pathogenicity test, the pathogen was identified as C. tenuissimum. To our knowledge, this is the first report of C. tenuissimum occurring on E. conferta fruits in China.
Citron (Citrus medica L.) is a perennial evergreen woody tree of Rutaceae family and Genus of Citrus. The citron is cultivated for its economic, medicinal and ornamental values in the south of China. (Yang et al., 2015). The shapes range from spherical to ovate and the sizes range from 3 to 5 kg (Klein et al., 2016). In June 2021, some postharvest citron fruits (Citrus medica var. medica) were found to have decay with a green or greyish mycelium on part or whole citron in 2 farmer’s markets in Kunming city, Yunnan Province (N 25°02′; E 102°42′), southwest China. Initial symptoms appeared as white, brown, and irregular necrotic spots in the pericarp. The lesions enlarged gradually and developed into green, water-soaked areas which extend rapidly. Eventually, the diseased fruits were rotten, soften, and the green spore masses confined to the surface (Fig. 1A). The incidence of this disease in postharvest citron fruits ranges from 15 % to 35 %, which is extremely destructive to the fruit of Rutaceae family plants (Chen et al., 2019). Small pieces (5 mm2) of symptomatic citron fruits were surface disinfected in 75 % ethanol and 0.3 % NaClO for 30 s and 2 min respectively, rinsed with distilled water for three times, blotted dry, placed onto potato dextrose agar (PDA) medium aseptically and incubated in a growth chamber at 25 ± 1 ℃, after 7 days, different colonies grew on PDA plates that were isolated and purified on new PDA medium at 25 ± 1 ℃ for 7 days. Inoculating repeatedly until six single-strain (XY01 to XY06) were obtained, and these isolates were stored in 15 % glycerol at –80 ℃ in a refrigerator in the State Key Laboratory for Conservation and Utilization of Bio-Resources in Yunnan Agricultural University. The selected pathogens (XY01 to XY06) were inoculated on PDA medium, incubated at 25 ± 1 ℃. After 7 days, colonies of the isolate obverse are olive green, the white margin and greyish-green spores on the surface, and the reverse colorless to cream yellow or pale dull brown. Colonies texture was velutinous, with a special fragrance. The conidia structure was very fragile and break up easily into many cellular elements. Conidiophores were terverticillate, produced by subsurface or aerial hyphae, irregularly branched and composed of short stipes with few metulae and branches that terminate in whorls of three to six phialides, which are often solitary, cylindrical with a short neck. Conidia are hyaline to pale green, smooth-walled, without septate, partially ellipsoidal, or obovate (4.9 to11.9× 4.3 to 8.9 μm). Partial cylindrical (8.2 to 10.5× 2.7 to 5.3 μm), there are some small conidia, which were ellipsoidal or spherical (3.9 to 5.2× 2.7 to 5.2 μm). According to morphological characteristics, the fungus was identified as Penicillium digitatum (Pers.) Sacc. Isolate XY01 and XY02 were used for molecular identification and genomic DNA was extracted using the CTAB method (Aboul-Maaty & Oraby, 2019). The universal primers ITS1 and ITS4 were used to amplify and sequence the ITS1, 5.8S, and ITS2 rDNA region. Using NCBI’s BLASTn tools, the nucleotide sequences of XY01 and XY02 (Gen-Bank accessions MZ976843 and OK513274) show 100 % identity to MK450692 (P. digitatum strain CMV010G4). Pathogenicity tests have used the fruits (Citrus medica), which maturity was more than 80%. The pathogens (XY01, XY02) were cultured for 7 days on PDA medium, washed with sterilized water the resulting spore suspensions diluted to 1.0 × 106 spores/ml. Wounds (0.5 × 0.5 cm) were made on the surface of citron fruits by scraping with a sterile scalpel and then treated with 200 µl of spore suspension (Wild, 1994). Control citron fruits were treated with sterile water. citron fruits were incubated at 24-26 °C. Each treatment was performed in triplicate with 6 citron fruits. After 3 days, all fruits had developed lesions, in a water-stained, pale brown, and rapidly formed white hyphae, white mold layer was observed with a length of 1.5-2.5 cm and a width of 1-2 cm (Fig.1C), but control did induce infection. After 7 days, decay developed more quickly, the hyphae rapidly expanded on the surface of the pericarp, with vague and irregular edges, then a green mold layer was formed, the whole fruit was observed to rot and soften, When the citron was cut, the white flesh inside turned black and rotted (Fig.1B). P. digitatum was consistently reisolated from the inoculated plants but not from the controls. No symptoms developed on the control (Fig.1D). According to Koch’s postulates, the inoculated strains of XY01 and XY02 were the isolates causing citron decay disease. Based on symptoms, morphological characteristics, rDNA-ITS sequence analysis, and pathogenicity, this fungus was identified as P. digitatum. To our knowledge, this is the first report of the distribution of P. digitatum on Citron (Citrus medica) in China.
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