First Report of Leaf Spot Caused by Pseudocercospora sp. on Lonicera vidalii in Korea

Photinia × fraseri Dress, belonging to the Rosaceae family, is widely cultivated as an ornamental plant in China. In July 2022, the leaf spot symptoms were observed on over thirty P. × fraseri plants in an approximately 2-hectare park in Xinjian District, Nanchang City, Jiangxi Province, China (28°43′02″ N, 115°44′01″ E), with a disease incidences of roughly 10% . At first, small, grayish-white lesions appeared on the leaf edges, later expanding into 2 to 10 mm circular or irregular spots. These spots turned grayish-white to brown, with dark brown margins. Eventually, some lesions’ centers dried and died. For fungal isolation, ten symptomatic leaves were randomly collected. The edges between the diseased and healthy tissues were cut into small pieces (4 × 4 mm). These pieces were then surface-sterilized by dipping in 70% ethanol for 30 s and 1% NaClO for 30 s. Subsequently, they were rinsed three times with sterile distilled water. Leaf pieces were then transferred to potato dextrose agar (PDA) medium and incubated at 25 °C for 3–4 days. Eight isolates with similar colony morphology were collected from diseased leaves. Colonies of this fungus on PDA were nearly round, white, and had sparse aerial mycelium on the surface with black, gregarious conidiomata. The conidia were nearly cylindrical, smooth, hyaline, and 4-septate, measuring 16.7 to 24.3 × 4.2 to 6.6 µm (mean 20.9 × 5.3 µm, n=50). The three middle cells were smooth, doliiform, and brown, with concolorous septa that were darker than the rest of the cell. They measured 11.8 to 17.0 µm long (mean 14.1 µm, n=50). The basal and apical cells were triangular and transparent. The basal cells had a mean length of 4.7 µm and were equipped with a basal appendage, while the apical cells had two appendages with a mean length of 17.7 µm(n=50). The characteristics of these isolates match those of Pestalotiopsis species (Maharachchikumbura et al. 2014). To identify them accurately, three representative isolates, namely JFRL 03-161, JFRL 03-162, and JFRL 03-226, were selected for further analysis. The internal transcriptional spacer (ITS) region, β-tubulin (TUB2) and translation elongation factor 1-alpha (TEF1-α) gene were amplified and sequenced using primers ITS1/ITS4 (White et al. 1990), BT2a/BT2b (Glass and Donaldson 1995), and EF1-526F/EF1-1567R (Maharachchikumbura et al. 2012), respectively. All sequences (ITS: OR342044-OR342046, TUB2: OR343299-OR343301, and TEF1-α: OR343302-OR343304) were deposited in GenBank. A BLASTn homology search revealed 99-100% identity to Pestalotiopsis nanjingensis CSUFTCC16 (ex-type). The sequences included ITS (OK493602, 486/486 nucleotides), TUB2 (OK562377, 438/439 nucleotides), and TEF1-α (OK507972, 478/478 nucleotides). The maximum likelihood analyses were performed for the combined ITS, TUB2 and TEF1-α data sets using IQtree web server (Trifinopoulos et al. 2016). The resulting phylogenetic tree demonstrated a strong association: the three isolates clustered tightly with P. nanjingensis forming a clade with robust 99% bootstrap support. This clustering, consistent with both morphological and molecular characteristics, confirmed the identity of the fungus as P. nanjingensis. To evaluate its pathogenicity, we obtained 3-year-old P. × fraseri ‘Red Robin’ plants, which were purchased then potted in a controlled climate chamber. We surface sterilized six healthy leaves of P. × fraseri with 70% ethanol and created wounds using a sterile needle. Subsequently, we inoculated a 50 μL conidial suspension (1 × 106 conidia/mL) of the isolate JFRL 03-161 on these wounded leaves. In parallel, another six leaves from P. × fraseri were inoculated with sterile distilled water, serving as the control group. All potted plants were incubated under conditions of 26 °C and 80% humidity. After seven days, all leaves inoculated with isolate JFRL 03-161 displayed symptoms similar to those observed in the field, whereas the control leaves remained unaffected. To fulfill Koch’s postulates, we re-isolated P. nanjingensis plants from the symptomatic leaves and identified it based on morphological and molecular characteristics. It has been reported that two species of Pestalotiopsis, namely P. microspora and P. trachicarpicola can caused damage to the leaves of P. × fraseri in China (Xu et al. 2022; Zhu et al. 2021). However, to our best knowledge, this is the first report on leaf spot caused by P. nanjingensis on P. × fraseri in China. Therefore, it is necessary to pay more attention to the leaf spot disease of P. × fraseri caused by Pestalotiopsis species and develop appropriate control strategies.

Melia azedarach L., called chinaberry, is native to Southeast Asia and Australia. The trees are commonly planted as ornamentals in the southern part of Korea. In October 2010, a leaf spot disease was observed on trees for the first time in Wando, Korea. Further surveys conducted from 2010 to 2012 showed that the disease occurs on trees in Jeju, Seogwipo, and Tongyeong cities as well as Wando county with nearly 100% incidence. Leaf spots were circular to semicircular, later becoming angular, small, pale brown in the center with a dark brown margin, and later becoming milky white. Leaf spots sometimes coalesced to blight the entire leaf and were capable of rapidly defoliating whole trees in late September. Fruiting was amphigenous, but mostly hypogenous. Stromata were substomatal, globular, dark brown, and 25 to 70 μm in diameter. Conidiophores were densely fasciculate, pale olivaceous to pale brown, substraight to mildly curved, not geniculate, 10 to 30 μm long, 2.5 to 4.5 μm wide, and aseptate or uniseptate. Conidia were pale olivaceous, generally darker than conidiophores, cylindric to obclavate, substraight in shorter ones, curved to mildly sinuous in longer ones, obconically truncate at the base, obtuse at the apex, 2- to 14-septate, 16 to 120 × 3 to 5 μm, guttulate, and had inconspicuous hila. Morphological characteristics of the fungus were consistent with the previous descriptions of Pseudocercospora subsessilis (Syd. & P. Syd.) Deighton (2). Voucher specimens (n = 6) were deposited in the Korea University Herbarium (KUS). An isolate from KUS-F25395 was deposited in the Korean Agricultural Culture Collection (KACC45688). The complete internal transcribed spacer (ITS) region of rDNA was amplified with the primers ITS1/ITS4 (3) and sequenced. The resulting sequence of 517 bp was deposited in GenBank (Accession No. JX993904). A BLAST search in GenBank revealed that the sequence shows >99% similarity (1 bp substitution) with a sequence of P. subsessilis ex M. azedarach from Cuba (GU269815). For pathogenicity tests, hyphal suspensions were prepared by grinding 3-week-old colonies grown on potato dextrose agar with distilled water using a mortar and pestle. Five 3-year-old chinaberry trees were inoculated with hyphal suspensions using a fine haired paint brush. Three healthy trees of the same age, serving as controls, were sprayed with sterile water. The plants were covered with plastic bags to maintain 100% relative humidity for 24 h and then transferred to a greenhouse. Typical symptoms of necrotic spots that appeared on the inoculated leaves 10 days after inoculation were identical to the ones observed in the field. P. subsessilis was reisolated from symptomatic leaf tissues, confirming Koch's postulates. No symptoms were observed on control plants. The disease has been reported in several Asian countries as well as in Cuba and the United States (1). To our knowledge, this is the first report of leaf spot on chinaberry caused by P. subsessilis in Korea. The observed high incidence and severity suggest that this disease can be a limiting factor in utilizing this tree species as ornamentals in public areas.

Passion fruit (Passiflora edulis Sims), which is native to South America, is an important fruit crop in tropical and subtropical countries. Passion fruit growing areas have increased rapidly in southern China. In 2018 to 2019, circular spots on passion fruit were observed in Shangsi, Guangxi, China (21°15'N, 107°98'E). The disease occurred from June to April of the following year. The disease incidence was generally between 10% to 30%, but could reach up to 50% in purple passion fruit 'Tainong No.1'. The initial lesions on the fruits were small, with a brown center and a greasy margin, and then became sunken and lighter brown with a diameter of about 1 cm in later stages. The spots on the leaves were often surrounded by a yellow halo and turned into larger lesions after coalescence.. Five typical symptomatic fruit and leaves were collected from Shangsi county for the presumed pathogen isolation. Section of the samples were surface sterilized to isolate the fungus on potato dextrose agar (PDA) at 28°C. Five fungal isolates with similar morphology on PDA were obtained by single spore isolation. Colonies at the age of 7 days accompany with flourishing aerial hyphae, showed surface color varying from white to grey. Conidia were ovate or elliptic, light brown to brown, with 2 to 5 diaphragms, 0 to 4 longitudinal-oblique diaphragms, and mostly 8.2 to 36.7 μm × 5.4 to 15.8 μm. The morphology of the fungus resembled Alternaria alternata (Fr.) Keissl (Simmons, 2007). Each of the five isolates (SF-001, SF-002, SF-003, SF-004 and SF-005) was molecularly identified using genomic regions of 18S nrDNA (SSU), 28S nrDNA (LSU), RNA polymerase second largest subunit (RPB2), internal transcribed spacer (ITS), glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and translation elongation factor 1-alpha (TEF1) (Jayawardena et al., 2019). Nucleotide sequences of SSU (MZ275254, ON055696, ON055697, ON055698 and ON055699), LSU (MZ275253, ON062947, ON062948, ON062949, ON062950), RPB2 (MZ275251, ON055377, ON055378, ON055379 and ON055380), ITS (MW866522, MW866523, ON053451, ON053452 and ON053453), GAPDH (MZ286628, ON055381, ON055382, ON055383 and ON055384) and TEF1 (MZ275255, ON055373, ON055374, ON055375 and ON055376) were deposited in GenBank database. The LSU, GAPDH and TEF1 sequences showed 100% identity with A. alternata in NCBI (KX609773, MK683852 and MK637432, respectively). The SSU, RPB2 and ITS sequences showed 99% identity to A. alternata (U05194, MK605898 and MN856409, respectively). In pathogenicity test (Zhang et al., 2020), 3-month-old grafted 'Tainong No.1' seedlings and mature fruit were used. Five-mm-diameter mycelial plugs taken from 7-day-old PDA colonies of each of 5 isolates were placed on the leaves and fruit that were wounded with a sterilized needle to form 3 pinpricks. Sterile PDA plugs were used as control. Three plants and three fruits were used in each treatment, and the test was repeated twice. The inoculated plants and fruit were kept in plastic bags and grown in a chamber at 28℃. Typical lesions were observed on inoculated plants and fruit after 3 days, but the controls remained healthy. A. alternata was consistently reisolated from these typical lesions. Previously, leaf spot on passion fruit caused by A. alternata has only been recorded in New Zealand (Rheinländer, 2010). To our knowledge, this is the first report of A. alternata (Fr.) Keissl. causing leaf spot on passion fruit in China. The identification of the pathogen may help to take effective management strategies of controlling this disease.

Nageia nagi (Thunb.) Kuntze belongs to the family Podocarpaceae with shiny green branches and leaves, which is widely distributed in East Asia and the Southern Hemisphere. The leaves, roots and fruits of N. nagi have been used as herbal medicine to treat rheumatism, arthritis and venereal diseases (Abdillahi et al. 2011). In September 2022, leaf spot symptoms were found on approximately 30% of the leaves of N. nagi trees in a community located at the Economic and Technological Development Zone, Nanchang City, Jiangxi Province, China. Following the initial infection, the leaf lesions extended outwards from the top in a circular pattern, appearing as a dark brick color, and later changed to yellow and became dry, with a darker brown margin surrounding them. Ten symptomatic leaves were randomly selected, and a small piece of leaf tissue (5mm ×5mm) located between the health and infected tissues was cut and surface-desinfected with 70% ethanol for 30 s and 1% sodium hypochlorite (NaClO) for 30 s sequentially. After rinsing three times in sterile distilled water, all the small pieces of leaves were placed on potato dextrose agar (PDA) plates, followed by incubation at 28℃ for 3 days. Ten isolates, cultured on each PDA plate, appeared olive green with a granular surface, and an uneven white edge, and finally turned greenish black. The conidia were hyaline, with ellipsoidal to subglobose shapes and spore sizes of 5.5-8.3 × 7.2-12.0 μm (width × length) (=7.2±0.71 × 9.9±1.3 μm, n=40). These morphological characteristics are consistent with those of Phyllosticta species. To confirm the species, three representative isolates, JFRL 03-768, JFRL 03-769 and JFRL 03-770 were selected for further identification. The internal transcribed spacer (ITS) region, actin (ACT), translation elongation factor 1-alpha (TEF1-a), and glyceradehyde-3-phosphate dehydrogenase (GPD) genes of the three isolates were amplified and sequenced with the primers V9G/ITS4 (Carbone and Kohn 1999), ACT-512F/ACT-783R (Carbone and Kohn 1999), EF-728F/EF-2 (O´Donnell et al. 1998) and Gpd1-LM/Gpd2-LM (Myllys et al. 2002; Guerber et al. 2003), respectively. All sequences had been deposited into GenBank (ITS: OQ195332, OQ195333 and OQ195334; ACT: OQ207621, OQ207622 and OQ207623; TEF1-a: OQ207624, OQ207625 and OQ207626; GPD: OQ207627, OQ207628 and OQ207629). A maximum likelihood phylogenetic tree was constructed using the IQtree V1.5.6 (Ngugen et al. 2015) based on the concatenation of multiple sequences (ITS, ACT, TEF1-a and GPD). In the cluster analysis, the representative isolates (JFRL 03-768, JFRL 03-769 and JFRL 03-770) were positioned within a clade comprising of Phyllosticta styracicola. Subsequently, the pathogenicity of P. styracicola was determined by wound inoculation of healthy 2 year-old N. nagi plants, and this experiment was repeated for three times. Briefly, for each isolates, six disinfected leaves were wounded with a sterile scalpel, and then inoculated with 10-μl drop of the conidial suspension (1 × 106 conidia/ml). Another six disinfected leaves were inoculated with 10-μl drop of sterile water as a control group, and all plants were incubated at 28°C with 80% humidity. After 15 days, a similar spot lesion appeared on the leaves of the experimental group. P. styracicola was successfully re-isolated, and then subjected to morphological identification and molecular sequencing (ITS, ACT, TEF1-a and GPD genes). Whilst, the control leaves showed no symptoms. Previous studies have reported that P. styracicola could result in the development of lesions on Styrax grandiflorus leaves in China (Zhang et al. 2013). To our knowledge, this is the first report that P. styracicola can cause leaf spot on N. nagi in China.

Elaeagnus pungens Thunb. is a common traditional Chinese herbal medicine. It has high medicinal, edible, and ornamental value. In Sep. 2020, a leaf spot disease was found on E. pungens in the campus of Nanjing Forestry University, China (31°36'51"N, 119°11'8"E). The incidence rate was ca. 77%. The disease primarily appeared as small brown spots on the leaves. Then, the spots enlarged and coalesced into regular or irregular gray necrotic lesions with dark margins. At the late stage of symptom development, black spots (acervulus) appeared on the necrotic lesions (Fig. S2A-C). Eight symptomatic leaves were collected and surface-sterilized using 75% ethanol for 30 s followed by 1% NaClO for 1 min, and then washed three times in sterile distilled water. Cuttings (ca. 5×5 mm) were made from the margins of the lesions and placed on 2% of potato dextrose agar (PDA) in Petri plates and incubated at 25 ± 2 °C for 5 days. The isolation frequency of pathogens from diseased tissues was ca. 100%. A total of four fungal isolates 3-3-1, 3-3-2, 3-3-3, and 3-3-4 were obtained using the monosporic isolation method and stored in the Forest Pathology Laboratory at Nanjing Forestry University. For molecular identification, the internal transcribed spacer (ITS), partial translation elongation factor 1-alpha (TEF1-α), and partial β-tubulin (TUB2) were amplified from the isolate 3-3-1, 3-3-2, 3-3-3 and 3-3-4, with the corresponding primer sets published in Maharachchikumbura et al. (2014). The amplicons of ITS (ON510047, ON510048, ON510070, and ON510069), TEF1-α (ON808445, ON808446, ON808447, and ON808448), and TUB2 (ON808449, ON808450, ON808451, and ON808452) generated from the isolate 3-3-1, 3-3-2, 3-3-3, and 3-3-4 were sequenced and deposited in GenBank. The ITS, TEF1-α, and TUB2 of the isolate 3-3-1 shared the same nucleotide sequences with the corresponding sequences of the isolate 3-3-2, 3-3-3, and 3-3-4. The ITS, TEF1-α, and TUB2 sequences showed 100%, 97%, and 99% similarity to Neopestalotiopsis clavispora MFLUCC12-0281 (ex-type), respectively. Phylogenetic analysis using concatenated sequences of ITS, TEF1-α, and TUB2 also showed that isolate 3-3-1, 3-3-2, 3-3-3, and 3-3-4 clustered monophyletically with N. clavispora, and supported with a high bootstrap value (80%) (Fig. S1). Since these four isolates were same species based on phylogenetic analysis, isolate 3-3-4 was randomly chosen for the pathogenicity test and morphological analysis. Colonies of the isolate 3-3-4 grown on PDA were white, cottony, and flocculent, contained undulate edges with dense aerial mycelium on the surface, and averaged 12.2 mm d-1 growth at 25 °C (Fig. S2F). Black conidiomata formed superficially, scattered over the PDA at two weeks post incubation, 170.15-1820.32 × 90.33-1230.12 µm (n = 109), and contained slimy black conidial mass (Fig. S2G). Conidiogenous cells were pear-shaped to cylindrical, transparent, and colorless to pale yellow with smooth cell walls (Fig. S2H). Conidia were spindle shaped, five cells, four septa, 18.46-25.9 × 5.3-9.37 μm, (av ± SD = 23.31 ± 1.81 × 7.33 ± 1.07 μm, n = 34) (Fig. S2I). Apical and basal cells were lighter in color, mostly hyaline, and the middle three cells were darker in color, mostly brown. The apical cell showed two to three colorless, transparent unbranched accessory filaments, 9.68-30.59 μm in length, (av ± SD = 20.57 ± 4.52 μm, n = 95), whereas the basal cell only a single appendage, 3.52-9.4 μm in length, (av ± SD = 5.32 ± 1.29 μm, n = 34) (Fig. S2I). These morphological characteristics were similar to N. clavispora described by Daengsuwan et al. (2021). Based on phylogenetic analysis and morphological characteristics, isolate 3-3-1, 3-3-2, 3-3-3, and 3-3-4 were identified as N. clavispora. Healthy potted seedlings of E. pungens (63-85 cm in height, 0.7-1.6 cm in diameter) were selected for the pathogenicity test in vivo. The surface-sterilized leaves were wounded with sterilized needles (1 mm in dia.) and inoculated with mycelial plugs and conidial suspensions, respectively. One part of the leaves were inoculated with mycelial plugs (5 mm in dia.) of isolate 3-3-4. The other part of the leaves were inoculated with 10 μL of conidial suspensions (1×106 spores mL-1). The inoculated plants were kept in a growth chamber at ca. 25 ± 2 °C and ca. 90% RH under a 12-h photoperiod. PDA discs without fungi and sterilized dH2O were used as controls, respectively. All experiments were repeated twice, and each treatment had six replicates at least. After 10 and 12 days post-inoculation, the necrotic lesions appeared on the leaves inoculated with the mycelial plugs and conidial suspensions of the isolate 3-3-4, respectively (Fig. S2D and E). However, no lesions were found on the plants inoculated with PDA discs and dH2O (Fig. S2D and E). Fungal isolates were re-isolated from the infected leaves and shared similar morphological characteristics of colonies and conidia with the original one. Thus, Koch's postulates were fulfilled. Neopestalotiopsis clavispora was determined as the pathogens of a variety of plant diseases such as leaf spot on Taxus chinensis, gray blight on Camellia sinensis, and root and crown rot on strawberry (Kirschbaum et al., 2018; Wang et al., 2019a, b). To our knowledge, this is the first report of leaf spot caused by N. clavispora on E. pungens worldwide. The discovery will be helpful for monitoring and control of this disease in the future.

Bitter gourd (Momordica charantia L.), a member of the Cucurbitaceae family, is an economically important vegetable crop cultivated in India, valued for its nutritional and medicinal properties (Mallikarjuna et al. 2023). In May 2024, leaf spot disease symptoms were observed on bitter gourd in Dakshin Charilam (23.630 N, 91.320E), Sepahijala, Tripura, India with disease incidence of leaf spot ranged from 6% to 11% (n = 100 plants) in a 1-ha field. Symptoms included small, water-soaked, angular, gray or straw-colored spots with a yellow halo. As the disease progressed, spots became dry and dropped leaving irregularly shaped holes in the leaves. Ten symptomatic diseased leaves were randomly collected from 10 individual plants and cut into small pieces (5.0 mm2) at the junction between diseased and healthy tissue using a sterilized scalpel. The pieces were disinfected with 1% sodium hypochlorite (NaOCl) solution for 2 min and subsequently samples were washed thoroughly with sterilized distilled water three times. Disinfected tissue was transferred to Petriplates containing potato dextrose agar (PDA) and incubated at 25±2°C. Out of ten symptomatic leaves, eight isolates with similar morphological characterizations were isolated and purified. Two isolates (Bitter G-3 and Bitter G-3′) were selected for further morphological and molecular identification. After 7 days at 25±2ºC, colonies on PDA were fast growing, dark greyish black, with hyaline to olivaceous grey, septate, smooth-walled, 3–6.5 (x̄ = 4) μm wide, sporulating hyaline form. Conidia were aseptate, ovoid to ellipsoid (6.2 ± 1.01 × 14.5 ± 0.96 μm; n = 20). Genomic DNA was extracted from 7 days old freshly harvested mycelia using a fungus genomic DNA extraction kit (Biomiga, U.S.A.) and the partial internal transcribed spacer (ITS) region and translation elongation factor 1-alpha (tef1-α) gene were amplified, sequenced with primer pairs ITS4 / ITS5 (White et al. 1990) and EF1- 983F/EF1-2218R (Rehner and Buckley 2005), respectively, and submitted to GenBank (GenBank accession nos. PV248196, PV962840 for ITS and PV274565, PV976015 for tef1). BLASTn searches with the obtained sequences in GenBank revealed 99.79 % identity [466/467 bp; 100% Query Cover; and 0 gaps] with L. theobromae CBS 164.96 (Type; Sequence ID: NR_111174.1) based on ITS gene region and 100 % identity [314/314 bp; 100% Query Cover; and 0 gaps] with L. theobromae isolate CUZ044 (Sequence ID: PV441873.1) based on tef1 gene. A phylogenetic tree was constructed by MEGA11.0 using the Neighbor-Joining method (Saitou and Nei, 1987). Based on morphology and molecular analysis, the fungus was identified as L. theobromae. For pathogenicity test, twelve healthy leaves of three healthy bitter gourd plants were inoculated with a 5-mm-diameter mycelial disc and an additional three healthy plants inoculated with sterile PDA discs as control (He et al. 2021). After 5 days of inoculation, L. theobromae inoculated leaves of bitter gourd exhibited leaf spot symptoms similar to those observed in the field, while the control plants had no symptoms. The pathogen was reisolated (isolate Tri BG-3) from the symptomatic leaves in three successive trials, and identified as L. theobromae, thus fulfilling Koch’s postulates. DNA sequence for ITS and tef1-α gene were submitted to GenBank (GenBank accession nos. PV962841 for ITS and PV976016 for tef1). To the best of our knowledge, this is the first report of L. theobromae causing leaf spot in bitter gourd in India and it is crucial to monitor the occurrence of this pathogen in other bitter gourd growing areas as a potential threat to bitter gourd production.

Hemerocallis citrina is a popular vegetable crop. Its eatable flower buds contain abundant nutrients, especially lecithin (Guo et al., 2022). In March 2021, leaf spot disease was observed on 90% cultivated H. citrina seedlings in Dazhou city (31°17'56″ N, 107°31'59″ E), Sichuan, China. Totally, 15 diseased seedlings were sampled (three samples per 666 m2). The symptomatic leaves were cut into pieces (5 × 3 mm), superficially disinfected with 70% ethanol for 20 s and 1% Sodium hypochlorite (NaClO) for 40 s, and washed with sterile distilled water six times. The disinfected tissues were incubated on PDA amended with streptomycin sulfate (50 mg/L) in dark at 25 ℃. Two days later, hyphal tips from the edges of growing colonies were transferred to fresh PDA plates. Finally, 40 purified isolates were obtained. Using primer pairs ITS1/ITS4 (Glass & Donaldson, 1995), amplified rDNA internal transcribed spacer (ITS) regions indicated that these isolates belonged to different genera, mainly including Epicoccum, Fusarium and Colletotrichum. Six isolates of Epicoccum genus similar in morphology, named HHC46, HHC47, HHC491, HHC492, HHC51 and HHC58, were selected for identification. Cultured on oatmeal agar for 7 days, colonies were initially white and villose. Fourteen days later, mycelia started to secrete scarlet pigment. The NaOH spot test showed color changed from green to red, identical to that in Epicoccum species (Boerema et al., 2004). Meanwhile, colonies produced abundant conidia. Conidia were ellipsoidal, aseptate, and 4.1 to 6.5 × 1.3 to 2.9 µm (n = 30). Chlamydospores were also observed, globose to subglobose. The morphological features were similar to those of Epicoccum latusicollum (Xu et al., 2022). The DNA sequences of Beta-tubulin (TUB2) and DNA-directed RNA polymerase II second largest subunit (RPB2) of six isolates were amplified and sequenced, using primer pairs Bt2a/Bt2b (Glass & Donaldson, 1995), and RPB2-5f2/RPB2-7cr (O'Donnell et al., 2012), respectively. BLASTN searches indicated our ITS (OP107240 - OP107245), TUB2 (OP131865 - OP131870) and RPB2 (OP131871 - OP131876) sequences except one TUB2 (OP131867), showed 100% identity to the corresponding sequences of E. latusicollum CGMCC:3.18346 (KY742101, KY742343 and KY742174, respectively). There was a nucleotide divergence between OP131867 and reference sequence. Based on concatenated ITS, TUB2 and RPB2 sequences, the constructed phylogenetic tree of Epicoccum species, confirmed that our isolates were E. latusicollum. To test pathogenicity, 2-year-old healthy seedlings of cultivar "chuanhuanghua No.1" were sprayed with conidial suspension of HHC51 (105 conidia/mL), with controls treated with sterile distilled water. Each treatment (biological replicates = 3) was incubated in a greenhouse (at 25°C under 90% relative humidity, 16/8 h light/dark cycle). The experiment was repeated twice. After 18 days, leaf spot symptom in inoculated seedlings appeared. Whereas, non-inoculated controls showed no symptom. The pathogens were re-isolated from diseased leaves and identified as E. latusicollum, based on morphology and molecular methods described above. E. sorghinum was previously reported as causal agent of leaf spot in H. citrina (Ma et al., 2021). To our knowledge, this is the first report of E. latusicollum causing leaf spot in H. citrina worldwide. Our study will assist with monitoring disease distribution in H. citrina and host diversity of E. latusicollum (Chen et al., 2017).

Rose of Sharon, Hibiscus syriacus L., is a flowering shrub in the family Malvaceae planted as the national flower of South Korea. In September 2012, previously unknown leaf spots with premature defoliation were observed on dozens of Rose of Sharon plants growing in the shaded area in a park of Dongducheon, Korea. The same symptoms were found on Rose of Sharon in several localities of Korea in 2012. The symptoms usually started as small, dark brown to grayish leaf spots, eventually causing leaf yellowing with significant premature defoliation. The diseased leaves retained for a while green color at the margin of the spots. Representative samples (n = 5) were deposited in the Korea University Herbarium (KUS). Conidiophores of the fungus observed microscopically on the leaf spots were erect, brown to dark brown, single or in clusters, amphigenous but mostly hypophyllous, and measured 80 to 400 × 5 to 10 μm. Conidia were borne singly or in short chains, ranging from cylindrical to broadest at the base and tapering apically, straight to slightly curved, pale olivaceous brown, 2 to 16 pseudoseptate, 50 to 260 × 9 to 20 μm, each with a conspicuous thickened hilum. On potato dextrose agar, single-spore cultures of two isolates were identified as Corynespora cassiicola (Berk. & M.A. Curtis) C.T. Wei on the basis of morphological and cultural characteristics (1,2). Two monoconidial isolates were preserved at the Korean Agricultural Culture Collection (KACC46956 and KACC46957). Genomic DNA was extracted using the DNeasy Plant Mini DNA Extraction Kit (Qiagen Inc., Valencia, CA). The complete internal transcribed spacer (ITS) region of rDNA was amplified with the primers ITS1/ITS4 and sequenced. The resulting sequences of 520 bp were deposited in GenBank (Accession Nos. KC193256, KC193257). A BLAST search in GenBank revealed that the sequences showed 100% identity with those of numerous C. cassiicola isolates from diverse substrates. To conduct a pathogenicity test, a conidial suspension (ca. 2 × 104 conidia/ml) was prepared in sterile water by harvesting conidia from 2-week-old cultures of KACC46956, and the suspension was sprayed onto the leaves of three healthy 2-year-old plants. Inoculated plants were kept in humid chambers for the first 48 h and thereafter placed in the glasshouse. After 10 days, typical leaf spot symptoms developed on the leaves of all three inoculated plants. C. cassiicola was reisolated from the lesions, confirming Koch's postulates. Control plants treated with sterile water remained symptomless. C. cassiicola is cosmopolitan with a very wide host range (1,2). Though Corynespora hibisci Goto was recorded to be associated with brown spot disease of H. syriacus in Japan (4), there is no previous record of C. cassiicola on H. syriacus (3). To our knowledge, this is the first report of Corynespora leaf spot on Rose of Sharon in Korea. According to our field observations in Korea, this disease was found in August and September, following a prolonged period of moist weather. Severe infection resulted in leaf yellowing and premature defoliation, reducing tree vigor and detracting the beauty of green leaves.

Bletilla striata (named "Bai Ji" in Chinese) is a plant from the Orchidaceae family that has been employed in traditional Chinese medicine for thousands of years in China. Polysaccharides extracted from B. striata have been shown to have an effect on Alzheimer's disease (Lin et al. 2021). Since 2021, leaf spots have been observed in the B. striata plantation in Chongqing, China. Out of 200 plants, the disease incidence was estimated at 56%, and the disease index was estimated at 32%. The symptoms were necrotic lesions with brown edges and yellow halos; severe infection caused the infected leaves to become blighted, dry and fall off. To identify the causal agent, eighteen leaves with typical symptoms were collected from the B. striata plantation (30.60°N, 108.64°E). The margins of infected tissue areas were cut into small pieces (5×5 mm), surface sterilized with 70% ethanol for 1 min, and rinsed twice with sterile distilled water. The tissue was then surface sterilized in 3% sodium hypochlorite for 2 min, followed by three rinses with sterile water. The tissue was then placed onto potato dextrose agar (PDA) plates and incubated at 25°C for 3 days, pure cultures of fungal isolates were obtained by single-spore isolation, stored on PDA slants and maintained at 4°C. Colonies of the fungal isolates showed three color types, ranging from grayish white to green above with olive green on the reverse, but conidial characteristics were more similar and indicated this was a single fungus. Conidiophores were single, lateral from hyphae or terminal; straight or curved; smooth-walled with 1 to 8 septa; pale brown; usually with only one pigmented terminal conidiogenous site, sometimes with one additional lateral conidiogenous locus; sometimes slightly swollen at the apex; and 15 to 170 μm long, 2.5 to 4.5 μm wide. Conidia were in short or moderately long chains of 2-8 conidia normally, sometimes with more; rarely branched; normally 14.07 to 50 × 5.24 to 10 μm in size; ellipsoid, fusiform, long ellipsoid, obclavate or ovoid with 1 to 11 transverse septa and 2 to 4 longitudinal septa; beakless or with subcylindric or cylindric secondary conidiophores, analogous to the beak 4.25 to 58.6 μm long, 3.2 to 4.8 μm wide. The fungal isolates were tentatively identified as Alternaria sp. The representative isolate BJ8 was selected for the pathogenicity test. The leaves of six healthy plants of B. striata (two years old) grown in pots were washed with sterile water. Ten mL of conidial suspension (1×106 conidia mL-1) contained in 0.05% Tween 80 buffer was brushed onto upper and lower surfaces of all the leaves on three plants, while other plants were brushed with 10 mL 0.05% Tween 80 buffer to serve as controls. Plants were placed in a greenhouse at 25°C and 95±1% relative humidity after inoculation and observed for symptoms. The symptoms initially developed as irregular brown necrotic lesions on the inoculated leaves after 7 days, with a yellow halo around the lesions, consistent with the symptoms in the field. Leaves on the control plants did not produce any symptoms. For molecular identification, the genomic DNAs of representative isolates BJ5, BJ6, and BJ8 were extracted. The internal transcribed spacer (ITS) region and RNA polymerase II second largest subunit (RPB2), translation elongation factor 1-alpha (TEF1), and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) genes were used for polymerase chain reaction (PCR), using primers ITS5/ITS4, GPD1/GPD2, EF-1F/EF-1B and RPB27cR/RPB25F2, respectively (White et al. 1990; Berbee and Pirseyedi et al. 1999; Carbone and Kohn 1999; Liu et al. 1999). The neighbor-joining tree revealed that these isolates are clustered together with the reference strain of A. burnsii. The sequences were deposited in NCBI GenBank BJ5 [ITS: OP897263; GAPDH: OQ544937; TEF1: OQ544941; RPB2: OQ544939], BJ6 [ITS: OP897262; GAPDH: OQ544938; TEF1: OQ544942; RPB2: OQ544940], and BJ8 [ITS: OK285209; GAPDH: OK340046; TEF1: OK340047; RPB2: OQ544936]. All three isolates showed 100% similarity with A. burnsii CBS 107.38 [ITS: KP124420; GAPDH: JQ646305; TEF1: KP125198; RPB2: JQ646457] ex-type sequence, thus the pathogen causing the leaf spot on B. striata was identified as A. burnsii. A. burnsii is an important pathogenic fungus causing blight of cumin (Shekhawat et al. 2013). Furthermore, Al-Nadabi et al. (2018) found that A. burnsii can cause leaf spots on wheat and date palms, and Sunapao et al. (2022) reported that A. burnsii can infect coconuts (Cocos nucifera), causing dirty panicle disease. This is the first report of A. burnsii causing leaf spot on B. striata in China. The new discovery shows that since A. burnsii can readily adapt to a variety of climatic conditions, controlling the fungus is crucial for the healthy growth of B. striata in the future. This study will provide a basis for further elucidating the pathogenic mechanism and development of effective control measures for this disease.

As a globally cultivated economic crop, tobacco (Nicotiana tabacum) is known for its addictive properties, which arise from the mildly irritating and psychoactive compounds it contains (Hu et al. 2010). Tobacco leaves are susceptible to a range of fungal and bacterial diseases during production and curing, including target spots, brown spots, wildfire, and powdery mildew (Guo et al. 2024). During a survey conducted in June 2025 in Zhengan (107.43° N, 28.55° E), Guizhou Province, China, tobacco (cv. Yunyan 87) plants were found affected by a leaf spot disease, with an incidence rate ranging from 41% to 47%. Initially, symptomatic leaves developed irregular, yellowish-brown spots that gradually expanded and turned necrotic, eventually acquiring a whitish appearance. To investigate the disease, six severely symptomatic plants were selected for pathogen isolation using the tissue transplanting method. From each plant, pieces (5 × 5 mm) of leaf tissue taken from the border between diseased and healthy tissue were surface-sterilized with 75% ethanol for 30 s, followed by 1% sodium hypochlorite for 1 min, and then rinsed three times with sterile distilled water before being placed on potato dextrose agar (PDA) medium. After incubating at 25°C in the dark for 7 days, a total of nine fungal isolates with similar morphology were obtained. One representative isolate, designated YB13, was selected for further identification (Fig. S1). The fungal colonies on PDA exhibited abundant aerial mycelia and were white in color, and covered the whole plates (90 mm in diameter) in seven days. After 10 days of incubation at 28°C, the fungus produced black, ovoid, smooth, and aseptate conidia with 12-15 μm in diameter. For molecular identification, genomic DNA was extracted from isolate YB13. The internal transcribed spacer (ITS) region, along with the glyceraldehyde 3-phosphate dehydrogenase (GAPDH), beta-tubulin (TUB2), and translation elongation factor 1-alpha (TEF1-α) genes were amplified using primers ITS1/ITS4 (White 1990), gpd1/gpd2 (Berbee et al. 1999), BT2Fd/BT4Rd (Li et al. 2017), and EF1-728F/EF1-986R (Carbone and Kohn 2019) respectively. The resulting sequences have been deposited in GenBank under the following accession numbers: ITS: PX736263; GAPDH: PX556631; TUB2: PX556632; and TEF1-α: PX711191. BLAST analysis of the sequences from isolate YB13 revealed high identity with those of Nigrospora coryli isolate W18. Specifically, the ITS sequence shared 99.14% identity with isolate W18 (GenBank: PP218065), the TUB2 sequence shared 99.71% identity with isolate W18 (GenBank: PP320372), and the TEF1-α sequence shared 100.00% identity with isolate W18 (GenBank: PP461302). A multilocus phylogenetic analysis based on a concatenated dataset of ITS, TEF1-α, and TUB2 genes further confirmed that isolate YB13 clusters within the N. coryli clade (Fig. S2). Pathogenicity of the isolate YB13 was confirmed on five healthy tobacco plants (cv. Yunyan 87) at seedling stage (four to five leaves). To wound the leaves, a 4 mm² area on each was lightly scratched with a sterile needle, after which a 5-mm diameter mycelial plug was placed on the wound. Control leaves were inoculated with PDA-only plugs. Following inoculation, leaves were maintained under high humidity by enclosing the treated plants in transparent plastic bags containing sterile water-soaked cotton at the base to maintain approximately 80% relative humidity. Plants were incubated in a greenhouse at 25°C. All experiments were performed in triplicate. The leaf disease development was observed and recorded daily. After 7 days, all inoculated leaves developed leaf spots consistent with symptoms observed in the field. Lesions appeared as irregular to circular spots, 5–12 mm in diameter, with a yellowish-brown color and often a chlorotic halo. As symptoms progressed, the lesions turned necrotic, developing dry, whitish centers surrounded by a darker margin and a yellow halo. In contrast, control plants remained completely asymptomatic. The pathogen was re-isolated from lesion margins and confirmed to be identical to the original inoculated strain based on colony morphology and DNA sequencing, thereby fulfilling Koch’s postulates. N. coryli has previously been reported as an endophyte within the stem of Corylus heterophylla at Mycorrhizal Seedling Cultivation Center in Guizhou, China (Wang et al. 2024). To our best of knowledge, this is the first report of N. coryli causing leaf spot on tobacco in China. These findings underscore the importance of continued pathogen surveillance and provide a basis for epidemiological studies and the development of management strategies for this emerging disease.

Panax notoginseng a perennial herb native to China, is widely grown in the Yunnan Province. (Yang et al. 2022). From July to August 2022, a new leaf spot disease was observed on fully expanded leaves of P. notoginseng from a planting base in the Xundian, Yunnan Province, China. Approximately 250 ha. of P. notoginseng is the cultivated area, and the incidence of leaf spot disease was around 10-15%. Round spots appeared on the infected leaves and as the disease progressed these leaves fell off the plant. A total 21 symptomatic leaves were randomly collected from the planting base to isolate the pathogens and further study in the laboratory. The surface of infected leaves were sanitized with 0.5% sodium hypochlorite for 2 min. and 75% alcohol for 1 min., and then rinsed thrice with sterile water. Once drying, the samples were placed on potato dextrose agar (PDA), plates and incubated at 25 °C for 5 days. The fungus was isolated from the symptomatic tissue, but only three isolates were preserved for further identification. Pure cultures of the representative strain Zhaochanglin 118 were obtained using the singlespore method, and the colonies obtained were dark-green to dark-black in appearance. The pycnidia were dark brown, solitary, or congregated with an inconspicuous neck. The conidia were colorless, ellipsoidal, and measured between 4.5 to 7 × 2 to 3 μm (n = 30). These morphological characteristics were similar to those described for Boeremia exigua (Valenzuela-Lopezi et al. 2018). The genomic DNA of the isolate was extracted using the DN14 cetyltrimethylammonium bromide rapid plant genome extraction kit. The internal transcribed spacer (ITS), RNA polymerase second largest subunit (RPB2) and translation elongation factor 1-alpha (TEF1) genes were amplified via polymerase chain reaction using the primers ITS1/ITS4 (White et al. 1990), Af/Cf (Matheny et al. 2002), and EF1-983F/EF1-2218R (Chen et al. 2015), respectively. All sequences were deposited in GenBank (OQ996531 for ITS; OR291158 for RPB2 and OR291159 for TEF1). A BLASTN homology search using the ITS nucleotide sequence indicated that this has 99.6% identity with the sequence MH859059, named B. exigua from CBS culture collection (517/519 bp); the RPB2 sequence has 97.5% identity with sequence GU371780, named B. exigua from CBS culture collection (704/722 bp); and the TEF1 sequence has 98.4% identity with sequence GU349080, named B. exigua from CBS culture collection (871/885 bp). To test Koch's postulates, a pathogenicity test was carried out on the leaves of six fully expanded P. notoginseng plants in the Xundian planting base. Conidial suspensions were prepared for one isolates at a concentration of 106 spores per milliliter. Three leaflets on different plants were applied with 20µl spore suspension and the other three leaflets were drop of 20 µl sterile distilled water. The whole experiment was repeated three times. The P. notoginseng plants were incubated under sterile conditions at 25°C for 7 days. Inoculated leaves showed the characteristic brown round spots, while control leaves were asymptomatic so, Koch's postulates were fulfilled by re-isolating the pathogen from symptomatic tissue, which was subsequently confirmed as B. exigua through morphological and molecular analyses. Koch's postulates were fulfilled. To our knowledge, this is the first report of B. exigua causing leaf spot disease in P. notoginseng in China, which lays a foundation for further study and developing disease control methods.

Date palm (Phoenix dactylifera L.) is a popular landscape tree in Fujian province, in South China. In November 2018 and June 2019, a leaf spot disease was observed on date palm in Fuzhou city. A survey of date palm plants grown in four different locations revealed that the disease incidence was almost 20%. The spots were brown with a yellow margin, 1 to 20 mm in diameter, and oval to irregular. In later stages, the spots gradually expanded and coalesced, became dry and died. For isolation, small pieces (0.5 cm2) were cut from leaf spots obtained from seven trees and disinfested with 70% alcohol. Leaf pieces were then placed onto 2% potato dextrose agar (PDA) and incubated at 25±2°C for 3 to 4 days. One fungus was consistently isolated from fifteen leaves. Fungal colonies were white with undulating margins and a light cream on the reverse side. Black globose to oblate conidiomata were irregularly distributed throughout ten-day-old colonies. The conidiogenous cells were septate, colorless, smooth-walled, straight to slightly curved, ampulliform or subcylindrical, and 6.0 to 13.5 × 1.3 to 3.0 μm [(n=50); x̄ ± SD = 9.5 ± 2× 2 ± 0.5μm]. Conidia were fusiform and five-celled with constrictions at the septa, measuring 18.5 to 31.5 × 5.0 to 7.5 μm [(n=50); x̄ ± SD = 25.5 ± 2 × 6.5± 0.2μm]. The three median cells were light to dark brown and the two end cells were colorless. Apical cells had 2 to 4 appendages ranging from 10.2 to 22.5 μm long. Basal cells had one appendage ranging from 3.5 to 5.5 μm long. The internal transcribed spacer (ITS) region of the ribosomal DNA and translation elongation factor 1-alpha (TEF1-α) gene of fungus were amplified using primers ITS1/ITS4 and EF1728F/EF1986R, respectively. Amplified products (ITS: MN294700 and TEF1-α: MN970514) showed 99% sequence identity to Pestalotiopsis sp., and Pseudoestalotiopsis theae sequences in GenBank. A comparison of MRC12 sequences with the type culture sequences (ITS: JQ683727 and TEF1-a: JQ683743) also showed high similarity, where ITS sequences exhibited only a three-nucleotide difference at the start of the sequences. No differences, however, were found between the TEF1-α sequences. On the basis of morphology and molecular characteristics, the fungus was identified as Ps. theae (Sawada) Maharachch., K.D. Hyde & Crous Steyaert (Maharachchikumbura et al. 2014). To confirm pathogenicity, five disinfested leaves on three healthy five-year-old date palm plants in a nursery (average temperature 26°C), were punctured 3 to 5 times with a sterilized needle, and then 10 to 15 mL conidial suspension (105 conidia/mL in sterilized distilled water) was sprayed over punctured areas of the leaves. For the control treatment, punctured leaves were sprayed with sterilized distilled water. All inoculated leaves plus the control were covered with plastic bags. After 10 days, brown leaf spots similar in appearance to those observed in the field appeared on all wounded leaves, and Ps. theae was successfully re-isolated; the control leaves remained asymptomatic. Previously, Ps. theae was reported on oil palm (Elaeis guineensis Jacq.) from Sierra Leone and Thailand (Turner, 1971; Suwannarach et al. 2013). To our knowledge, this is the first report of Ps. theae on date palm in China. This report expands the host range Ps. theae to date palm and underscores the potential threat of an emerging leaf spot pathogen on Phoenix species. References Maharachchikumbura, K.D., et al. 2014. Stud. Mycol. 79: 121-186. Suwannarach, N., et al. 2013. J. Gen. Plant Pathol. 79: 277-279. Turner, P.D. 1971. Phytopathol. 14: 1-58.

Amaranthus hybridus (=A. patulus), often called green amaranth, is an annual herbaceous plant of the Amaranthaceae. This plant is considered a harmful weed in the agricultural context of North America and has expanded its distribution to Asia and Europe. In Korea, it has become a problematic invasive issue, leading to economic losses due to reduced crop yields and rising weed management costs (Park et al., 2014), although its seeds and young leaves are edible and frequently consumed. In October 2020, we observed leaf spot symptoms on A. hybridus plants that were growing within perilla farms (Perilla frutescens var. japonica) located in Damyang (35°14'07"N, 126°59'40"E), Korea, with a disease incidence of 20 to 30% of the inspected plants. The initial signs appeared as grey to brown dots on the leaves, which gradually expanded into irregular, brown patches with a diameter of 2-3 cm. A single spore was isolated from the diseased leaf under a dissecting microscope, placed onto a 2% water agar plate, and incubated in darkness at 25°C for three days. Pure cultures were obtained by transferring single hyphal tips onto potato dextrose agar (PDA) plates. Five single-spore isolates were the same in the cultural and morphological examination, and a representative isolate (P309) was preserved at the Korean Agricultural Culture Collection (KACC49813), Korea. Colonies appeared light gray to white with regular margins and reached 4 to 5 cm in diameter after a week. After two weeks, black patches of spores were often visible in the aerial mycelia. Conidiophores were brown to pale brown, often branched, thick-walled, and measured 6.8 × 2.7 µm (n = 30). Conidia were single-celled, dark brown, globose to ellipsoid, and measured 6.8 × 5.0 µm (n = 50), with a ratio of length/width of 1.1 to 1.6 (n = 50). These morphological characteristics matched those of Arthrinium arundinis (Crous et al., 2013). For molecular identification, genomic DNA was extracted from conidia and mycelia on two-week-old PDA culture of the KACC49813. PCR was performed for the internal transcribed spacer (ITS) (primers ITS1/ITS4, White et al. 1990), the large subunit (LSU) rDNA (primers LROR/LR5, Vilgalys et al. 1990), the beta-tubulin gene (TUB) (primers T1/Bt-2b, O'Donnell and Cigelnik 1997), and the translation elongation factor 1-alpha (TEF) (primers EF1-728F/EF-2, Crous et al. 2013). A BLASTn search of the resulting sequences of ITS (560 bp; OL744431), LSU (881 bp; OL744432), TUB (790 bp; PP084934), and TEF (445 bp; PP084935) revealed 100 % similarity (e-value=0.0, coverage=100%) to previously reported sequences of Arthrinium arundinis (e.g. MF627422 for ITS, KF144930 for LSU, KF144973 for TUB, and KY705146 for TEF), confirming the identity of the Korean isolate. Pathogenicity assays were performed twice by spraying 1 ml of a conidial suspension (1.1 × 104 conidia per mL) onto the leaf surface of sixteen healthy A. hybridus plants. Sixteen control plants were sprayed with sterile water. All plants were kept in a growth chamber at 80% relative humidity and 23 °C with a 12-h light/dark cycle. Three weeks after the inoculation, initial symptoms mirroring the aforementioned ones appeared, while the control plants remained symptomless. Fungal isolates were successfully re-isolated from the inoculated leaves, and their identity as A. arundinis was confirmed by DNA sequencing, thus fulfilling Koch's postulates. To our knowledge, this is the first report of leaf spot caused by A. arundinis on Amaranthus hybridus, not only in Korea but globally. Arthrinium arundinis has also been reported as a plant pathogen on some agricultural crops (Ji et al. 2020; Liao et al. 2022; Farr and Rossman 2023), suggesting its polyphagous behavior. Then, this pathogen could represent a potential risk to the cultivation of edible amaranth in Korea and other crops where Amaranthus species are spread as weeds. For this reason, continuous monitoring is necessary to assess the impact of this fungus on Amaranthus and other crops.

Bletilla striata (Thunb.) Rchb. f. (Orchidaceae) is traditionally used for hemostasis and detumescence in China. In April 2019, a leaf spot disease on B. striata was observed in plant nurseries in Guilin, Guangxi Province, China, with an estimated incidence of ~30%. Initial symptoms include the appearance of circular or irregular brown spots on leaf surfaces, which progressively expand into large, dark brown, necrotic areas. As lesions coalesce, large areas of the leaf die, ultimately resulting in abscission. To isolate the pathogen, representative samples exhibiting symptoms were collected, leaf tissues (5 × 5 mm) were cut from the junction of diseased and healthy tissue, surface-disinfected in 1% sodium hypochlorite solution for 2 min, rinsed three times in sterile water, plated on potato dextrose agar (PDA) medium, and incubated at 28°C (12-h light-dark cycle) for 3 days. Hyphal tips from recently germinated spores were transferred to PDA to obtain pure cultures. Nine fungal isolates with similar morphological characteristics were obtained. Colonies on PDA were villose, had a dense growth of aerial mycelia and appeared pinkish white from above and greyish orange at the center and pinkish-white at the margin on the underside. Macroconidia were smooth, and hyaline, with a dorsiventral curvature, hooked to tapering apical cells, and 3- to 5-septate. Three-septate macroconidia were 21.2 to 32.1 × 2.4 to 3.9 μm (mean ± SD: 26.9 ± 2.5 × 3.2 ± 0.4 μm, n = 30); 4-septate macroconidia were 29.5 to 38.9 × 3.0 to 4.3 μm (mean ± SD: 33.5 ± 2.6 × 3.6 ± 0.3 μm, n = 40); and 5-septate macroconidia were 39.3 to 55.6 × 4.0 to 5.4 μm (mean ± SD: 48.0 ± 3.9 × 4.5 ± 0.3 μm, n = 50). These morphological characteristics were consistent with F. ipomoeae, a member of the Fusarium incarnatum-equiseti species complex (FIESC) (Wang et al. 2019). To confirm the fungal isolate's identification, the genomic DNA of the single-spore isolate BJ-22.3 was extracted using the CTAB method (Guo et al. 2000). The internal transcribed space (ITS) region of rDNA, translation elongation factor-1 alpha (TEF-1α), and partial RNA polymerase second largest subunit (RPB2) were amplified using primer pairs [ITS1/ITS4 (White et al. 1990), EF-1/EF-2 (O'Donnell et al. 1998), and 5f2/11ar (Liu, Whelen et al. 1999, Reeb, Lutzoni et al. 2004), respectively]. The ITS (MT939248), TEF-1α (MT946880), and RPB2 (MT946881) sequences of the BJ-22.3 isolate were deposited in GenBank. BLASTN analysis of these sequences showed over 99% nucleotide sequence identity with members of the FIESC: the ITS sequence showed 99.6% identity (544/546 bp) to F. lacertarum strain NRRL 20423 (GQ505682); the TEF-1α sequence showed 99.4% similarity (673/677 bp) to F. ipomoeae strain NRRL 43637 (GQ505664); and the RPB2 sequence showed 99.6% identity (1883/1901 bp) to F. equiseti strain GZUA.1657 (MG839492). Phylogenetic analysis using concatenated sequences of ITS, TEF-1α, and RPB2 showed that BJ-22.3 clustered monophyletically with strains of F. ipomoeae. Therefore, based on morphological and molecular characteristics, the isolate BJ-22.3 was identified as F. ipomoeae. To verify the F. ipomoeae isolate's pathogenicity, nine 1.5-year-old B. striata plants were inoculated with three 5 × 5 mm mycelial discs of strain BJ-22.3 from 4-day-old PDA cultures. Additionally, three control plants were inoculated with sterile PDA discs. The experiments were replicated three times. All plants were enclosed in transparent plastic bags and incubated in a greenhouse at 26°C for 14 days. Four days post-inoculation, leaf spot symptoms appeared on the inoculated leaves, while no symptoms were observed in control plants. Finally, F. ipomoeae was consistently re-isolated from leaf lesions from the infected plants. To our knowledge, this is the first report of F. ipomoeae causing leaf spot disease on B. striata in China. The spread of this disease might pose a serious threat to the production of B. striata. Growers should implement disease management to minimize the risks posed by this pathogen.

Pecan (Carya illinoinensis K. Koch) is an important and widely planted nut tree species in Jiangsu Province, China (Mo et al. 2018). In July 2020, leaf spot symptoms were frequently observed on pecan in Jurong, Jiangsu Province (119°15'36"E, 32°1'6"N). Disease incidences ranged from 40 to 65% among 150 mature pecan trees from three nurseries. The disease severity index (DSI, Jiang et al. 2019) reached 58.4. Symptoms began as small brown spots scattered on leaves that gradually expanded to large, circular to irregular black and brown necrotic lesions. In severe cases, lesions developed on large portions of a single leaf, and eventually the dead leaves fell from the trees. Three monoconidial isolates (Chen2346, Chen2347, Chen2348) were isolated from lesion margins and cultured on potato dextrose agar (PDA) medium. Colonies on PDA were white and cottony, later becoming light gray with abundant reproductive structures. Sporangiophores were aseptate, hyaline, unbranched, and apically dilated to form a clavate vesicle, which produced sporangia. Sporangia were globular to ellipsoid, brown to dark brown, 103 to 128 µm in length, and 88 to 114 µm in width (n = 30). Sporangiola were brown, ellipsoid to ovoid, with longitudinal striae, and measured 13.9 to 18.8 × 7.9 to 10.8 μm (n = 60). The morphological characteristics of these isolates agreed with descriptions of Choanephora cucurbitarum (Kirk 1984). Genomic DNA of these three monoconidial isolates was extracted, and the partial sequences of the internal transcribed spacer (ITS) and large subunit (LSU) of rDNA were amplified using primer pairs ITS1/ITS4 (White et al. 1990) and LR0R/LR7 (Vilgalys and Hester 1990), respectively. The consensus sequences (GenBank accession nos.: OP315248 to OP315250 for ITS and OP315251 to OP315253 for LSU) were aligned using BLASTn and showed100% identity with the sequences from C. cucurbitarum found in GenBank (accession nos.: MF942131 for ITS and ON025788 for LSU). To further confirm the identity, a phylogenetic analysis was performed with MEGA (v.7.0) and MrBayes (v.3.1.2) software, using the maximum likelihood and Bayesian inference methods, respectively. The multigene phylogeny revealed that the three isolates in this study, as well as, C. cucurbitarum specimen, clustered as a strongly supported monophyletic group (99 bootstrap value; 0.95 posterior probabilities). Based on the morphological and molecular data, the isolates were identified as C. cucurbitarum. To confirm pathogenicity, healthy pecan seedlings (2 years old) were each inoculated with a mycelial block (3 × 3 mm) excised from the margin of a colony on the vein of each leaf. Seedlings treated with non-colonized PDA blocks were used as controls. The inoculated seedlings were maintained in sterile plastic boxes with moistened sheets of filter paper at 25 ± 1°C and a 12-h photoperiod. Fifteen leaves per isolate were tested for each treatment. The experiment was repeated twice. Three days after inoculation, symptoms similar to those in the field appeared, whereas the control leaves remained symptomless. Subsequently, C. cucurbitarum was reisolated from the lesions and morphologically identified, confirming Koch's postulates. To the best of our knowledge, this is the first report of C. cucurbitarum causing leaf spot on C. illinoinensis in China. This study provides the foundation to further investigate the biology, epidemiology, and management of this disease.