RESUMO
Bletilla striata Rchb.f., is a perennial herbaceous bulbous plant known as the Chinese ground or hyacinth orchid classified in the Orchidaceae. It is native to southeast Asia and mainly distributed in China, Japan and northern Myanmar (He et al. 2017). It has the functions of astringent hemostasis and analgesia, and can also be used to treat traumatic bleeding, ulcers, swelling and chapped skin. Therefore, it occupies an important position in traditional Chinese medicine (Xu et al. 2019). In June 2023, three farmers in Mengzi (103.39°N, 23.21°E), Yunnan Province, China, observed that some Bletilla striata Rchb.f. plants grew poorly with small and chlorotic leaves (Figure 1 A). We suspected that these symptoms were caused by root-knot nematode infection, but the galls on the roots were small and inconspicuous (Figure 1 A). The presence of nematode females in both the galled regions and the normal roots (Figure 1 B), revealed by fuchsin staining (Byrd et al. 1983), indicated that the symptoms were probably caused by root-knot nematode infection. To estimate the incidence rates, we randomly selected 100 B. striata Rchb.f. plants from each of five fields representing a total area of 3000 m2. In these fields, the occurrence of stained root-knot nematodes were 19.3%, 17%, 18.3%, 15%, and 13%, respectively. The gall rating of the infected plants in the B striata Rchb.f. samples collected from the five fields was 2 (rating scale of 0 to 5). Females (n=20), second-stage juveniles (J2s, n=20) and egg masses (n=20) were extracted and collected from roots and soil for morphological and molecular identification. The females had a white, pyriform body and their perineal patterns exhibited a high and square dorsal arch, lacking distinct lateral line (Figure 1. C & D). Measurements of females (n = 20) were: body length (BL) = 708.64±89.6 µm (554.36 to 844.51 µm); maximum body width (BW) = 461.73±47.44 µm (365.25 to 561.49 µm); stylet length (ST) = 15.49±3.15 µm (10.55 to 19.78 µm); and distance from dorsal esophageal gland opening to the stylet knobs (DGO) = 3.33±0.27 µm (2.77 to 3.93 µm). Measurements of J2s (n=20) were BL = 417.7±47.67 µm (342.16 to 499.68 µm); BW = 15.74±2.66 µm (11.05 to 25.63 µm); ST = 12.49±1.12 µm (10.19 to 15.02 µm); DGO = 2.64±0.59 µm (40.17 to 68.74 µm); tail length = 51.93±8.55 µm (10.43 to 27.22 µm); hyaline tail terminus = 18.23±3.99 µm (1.48 to 3.98 µm). These morphological features match the description of Meloidogyne incognita (Eisenback et al. 1981). To further confirm the species, we selected three infected plants from each field for molecular identification, the ITS region amplified using the primers 18S/26S (5'-TTGATTACGTCCCTGCCCTTT-3',5'-TTTCACTCGCCGTTACTAAGG-3') (Vrain et al. 1992) . A 729 bp PCR product of ITS region (accession nos. OR463907) was obtained from all infected plants. The amplicons from 18S/26S primer pair were sequenced and the sequences showed 95.29% homology with sequences of M. incognita (accession nos. MT209948.1). Moreover, a 835 bp DNA fragment (accession nos. OR469000) was obtained using the specific primers Mi-F/Mi-R (5'-GTGAGGATTCAGCTCCCCAG-3',5'-ACGAGGAACATACTTCTCCGTCC-3') for M. incognita (Meng et al. 2004), the sequence showed 99.28% homology with sequences of M. incognita (accession nos. ON416569). The morphological features and molecular data confirmed the identification of the root-knot nematode on B. striata Rchb.f. as M. incognita. To confirm the pathogenicity, ten healthy B. striata Rchb.f. seedlings were each inoculated with 500 freshly hatched J2s isolated from field Bletilla striata Rchb.f.. Five healthy seedlings without J2 inoculation were used as controls. At 60 days after inoculation, most of the inoculated plants exhibited similar symptoms to those initially observed by farmers in the field. On average, 1532 J2s were recovered from each inoculated plant, yielding a reproductive factor of 2.1. The gall rating for these inoculated plants was 2. Fuchsin staining revealed the presence of root-knot nematode females within the roots, with an average of 17 females detected per inoculated plant. No symptoms were observed in the control plants. This is the first report of M. incognita infecting B. striata Rchb.f. in China. M. incognita can cause severe infection and damage to some crops, resulting in serious economic losses (Eisenback, 2022). The growers need to take measures to prevent the spread of this nematode.
RESUMO
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.