Photinia × fraseri is a well-known green plant mainly distributed in the Yangtze River and Yellow River Basin, east and southwest of China (Guan et al. 2013). In October 2020, typical leaf blight symptoms on roughly 10% leaves in a Photinia × fraseri shrub were observed in the campus of Sichuan Agricultural University (30°42′19″ N, 103°51′29″ E). Initially, chlorotic lesions with brown margins occurred on the leaf margin, then the large patches formed to cause leaves necrotic, finally lesions to dry and acervulus bred in 2–4 months later. Five single conidium isolates were carried out (Chomnunti et al. 2014) cultured on potato dextrose agar (PDA) at 25 ℃. All isolates shared similarly morphological characteristics, which was white and thin, and the reverse were yellowish. Mycelium was hyaline, sparsely septate, measuring 1–4 μm in diam. Conidiogenesis formed after 7 days. Conidiogenous cells were discrete, lageniform, smooth, thin-walled, colorless. Conidia were fusiform, straight to slightly curved, 4-septate, 21–30 × 5–7 μm (x ̅= 27 × 6.0 μm, n=30); basal cells were obconic with truncate base, hyaline, thin- and smooth-walled, 4–7 μm long (x ̅= 5.5 μm, n=30); three median cells were doliiform with thick walls, concolorous, olivaceous, constricted at the septa, and septa and periclinal walls were darker than the rest of the cell, 14–20 μm long (x ̅= 17 μm, n=30); apical cells were hyaline, conic to cylindrical, 3.0–6.5 μm long (x ̅= 4.5 μm, n=30), with 2–4 (mostly 3) tubular apical appendages arising from the upper portion, rarely branched, 7.5–18 μm long (x ̅= 12 μm, n=50); basal appendage was single, unbranched, 3–10 μm long (x ̅= 6.5 μm, n=30). DNA was extracted from the representative strain (SICAUCC 21-0012), and the internal transcribed spacer (ITS) region, the large subunit of the nrDNA (LSU), translation elongation factor 1-alpha (tef1-α), and partial sequences of β-tubulin (tub2) were amplified by polymerase chain reaction and sequenced with primers ITS5/ITS4, LR0R/LR5, 728F/1567R, and Bt2a/Bt2b, respectively (Zhang et al. 2012, Ariyawansa & Hyde 2018). The sequences were deposited in GenBank, viz. MZ453106, MZ453108, MZ467300, MZ467301, respectively. The nucleotide blast showed 99% (ITS, 0 gaps), 100% (tub2, 0 gaps), 100% (tef1-α, 0 gaps) identities with the ex-type Pestalotiopsis trachicarpicola Yan M. Zhang & K. D. Hyde (IFRDCC 2440). The fungus was identified as P. trachicarpicola combined with phylogeny and morphology (Maharachchikumbura et al. 2012, Zhang et al. 2012). To conduct Koch’s postulates, five healthy 6-year-old P. × fraseri were inoculated with 10 µl spore suspension (106 conidia/ml) onto the wounded sites (five leaves per plant, ~1 to 2 years old) via sterile pin, and five healthy plants treated with sterile dH2O as controls (Yang et al. 2021). The plants were placed in a greenhouse at 25°C with relative humidity >80%. After 2 months, leaf blight symptoms gradually emerged on inoculated leaves, and the controls were symptomless. Fungal isolates from symptomatic plants showed similar morphological characteristics as SICAUCC 21-0012, and the pathogen was not isolated from asymptomatic plants. To our knowledge, this is the first report of leaf blight caused by P. trachicarpicola on Photinia × fraseri in China. Disease management should be adopted properly to restore and improve its ornamental value.
Five Fungal Pathogens Are Responsible for Bayberry Twig Blight and Fungicides Were Screened for Disease Control