Abstract
Cathaya argyrophylla [Chun & Kuang.] is an ancient relict plant and its embryonic development is similar to that of Pinus species. This has important scientific value for studying the phylogeny of Pinaceae (Wu et al. 2023). In July 2022, root rot was detected in the seedling cultivation base of C. argyrophylla in Daozhen County, Guizhou Province, China (28.89 °N, 107.6 °E). The incidence of the disease was 30% (n = 100); the susceptible plants wilted, leaves withered, and roots showed brown-to-black lesions and rot. Ten root tissues were randomly collected from the edges of the lesions of six symptomatic susceptible plants. The tissues were sterilized with 75% alcohol for 30 seconds, followed by 2-minute immersion in 3% sodium hypochlorite. After washing with sterile water, the tissues were incubated on potato dextrose agar (PDA; BoWei, Shanghai) at 28 ℃ for five days. Four single-spore cultures were obtained using a single-spore isolation method (Gong et al., 2010). Single-spore cultures grew rapidly on PDA. After five days of incubation, the colonies were white and pink, indicating a large amount of aerial mycelia. Microconidia were ovate or ellipsoid, measuring 5.0-10.0 × 1.5-3.0 μm (n = 50); Macroconidia were falcate, slightly curved or straight, measuring 19.5-28.5 × 2.0-6.0 μm (n = 50). Based on morphological features, the pathogen was considered to be Fusarium spp. (Leslie and Summerell 2006). Three representative strains, GF5, GF6, and GF7, were selected for molecular identification, and genomic DNA was extracted to confirm morphological diagnosis. The internal transcribed spacer (ITS) (White et al. 1990) was amplified using primers ITS1/ITS4, and the β-tubulin gene (Varga et al. 2011) was amplified using primers Bt2a/Bt2b. The ITS and β-tubulin sequences were aligned with GenBank, and amplification of the genes from the three isolates was consistent. The ITS (OP482273) and β-tubulin (OR825353) sequences of GF5 were stored in GenBank, and their homology with Fusarium oxysporum HC131(accession numbers MW600442 and MW670451) was 99 to 100%. Maximum likelihood analysis using MEGA 11.0 showed that isolate GF5 belongs to F. oxysporum. The reconstructed phylogenetic tree confirmed the phylogenetic position of the isolate GF5. The pathogenicity test was carried out using GF5 and GF6 isolates. The taproots of ten 3-year-old C. argyrophylla plants were washed, and then the roots were immersed in a 2 × 106/mL conidial suspension for one hour. Ten plants with sterile water were used as controls. After planting in pots (30 × 25 cm) with sterilized forest soil, the plants were cultured in a greenhouse (25 ℃ and 12-hour photoperiod). Thirty days after inoculation, all plants inoculated with the isolated pathogen showed wilting symptoms, and the roots showed typical root rot symptoms, whereas the control group showed no symptoms. The pathogens re-isolated from all inoculated plants were morphologically identical and had ITS sequences identical to F. oxysporum, validating Koch's hypothesis. The pathogenicity test was repeated twice and similar results were obtained. Although this fungus has been previously reported to cause root diseases in hosts, such as Musa nana Lour. and Pinus massoniana Lamb. (He et al. 2010; Luo et al. 2020), to our knowledge, this is the first report of F. oxysporum causing root rot in C. argyrophylla. These findings provide a basis for the development of management strategies for C. argyrophylla infection.
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