Alpinia oxyphylla Miq. is mainly distributed in Hainan, Guangdong and Guangxi provinces of China. Between July and August 2021, a leaf spot disease was observed in Ledong, Hainan Province, China… Click to show full abstract
Alpinia oxyphylla Miq. is mainly distributed in Hainan, Guangdong and Guangxi provinces of China. Between July and August 2021, a leaf spot disease was observed in Ledong, Hainan Province, China (18°70'20.50″ N, 109°25'25.47″E) on A.oxyphylla. The incidence of infected leaves ranged from 8% to 10%, and the incidence rate of infected plants was about 50%. Symptoms appeared as primary yellow-brown withered spots on the diseased leaves, which further developed into irregular red-brown spots. The center of the lesions was gray-black, and the tissue was irregularly necrotic, ruptured or perforated, and there were yellow chlorotic halos around the edges of the lesions (Figure 1A). Tissues 5 mm in diameter were taken from the junction of diseased and healthy tissue for pathogen isolation, Successively, a total of 8 isolates were obtained from the affected leaves. Three single spore isolates (YZ-HN-001, YZ-HN-043 and YZ-HN-051) were obtained and confirmed to be identical based on morphological characteristics. Therefore, the representative isolate YZ-HN-001 was selected for morphological and molecular identification. On Potato Dextrose Agar(PDA), the colony was gray-white at first and gradually turned dark green to dark brown with lead gray on the back, growth was slow, and mycelium was short and dense (Figure 1B and Figure 1C). Pycnidia were epiphyllous, globose, brown (about 120-140 µm in diameter), and conidia were elliptical, colorless, single celled and smooth (8-12×4-7 µm) (Figure 1D). Molecular identification was performed by partially sequencing the internal transcribed spacer gene (ITS), 18S rRNA gene and the actin gene (ACT) by using the primers ITS1/ITS4 (White et al. 1990), EF4/Fungi5 (Khodaparase et al. 2005) and ACT-512F/ACT-783R (Carbone and Kohn. 1999). The sequences of the amplified fragments were deposited in GenBank, the ITS sequence (ON005130, 616 bp) showed 100% identity with Phyllosticta capitalensis strain CGMCC3.14345 (JN791605.1), the 18S rRNA sequence (ON005129, 541 bp) showed 99% identity with P. capitalensis isolate MUCC0029 (AB454185.1) and the ACT sequence (ON049348, 251 bp) showed 100% identity with P. capitalensis strain DZSN202005-2 (MW533248.1). A phylogenetic analysis was conducted in MEGA X using the neighbor-joining method and showed that isolate YZ-HN-001 clustered together with P. capitalensis (Figure 2). Based on the above morphological and molecular characteristics, the isolate was determined to be P. capitalensis. Pathogenicity tests were conducted in three replicates by inoculating surface-sterilized leaves of A. oxyphylla. The leaves were wounded and inoculated with colonized PDA plugs (5×5 mm) from 15-day-old cultures. Control leaves wounded in the same way and were inoculated with sterile PDA plugs (5×5 mm). Leaves were moisturized by spraying with sterile water every three days. After 20 days at room temperature (23 to 28℃), similar symptoms were observed in the inoculated leaves as in the field (Figure 1E), but no symptoms were observed on the control leaves (Figure 1F). The same P. capitalensis was reisolated in the inoculated leaves, confirming Koch's postulates. Phyllosticta capitalensis has been reported to cause leaf spots or black spots on various host plants around the world (Wikee et al. 2013), including on oil palm (Nasehi et al. 2020), tea plant (Cheng et al. 2019 ), and castor (Tang et al. 2020). Nevertheless, to our knowledge, this is the first report of leaf spot caused by P. capitalensis on A. oxyphylla worldwide.
               
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