Aecial and Telial Host Specificity of Puccinia coronata var. coronata, a Eurasian Crown Rust Fungus of Two Highly Invasive Wetland Species in North America.

The Eurasian crown rust fungus Puccinia coronata var. coronata (Pcc) was recently reported in North America and is widespread across the Midwest and Northeast United States. Pcc is a close relative of major pathogens of oats, barley, and turfgrasses. It infects two highly invasive wetland plants, glossy buckthorn (Frangula alnus) and reed canarygrass (Phalaris arundinacea), and could be useful as an augmentative biological control agent. We conducted large greenhouse trials to assess the host specificity of Pcc and determine any threat to cultivated cereals, turfgrasses, or native North American species. A total of 1,830 accessions of cereal crop species and 783 accessions of 110 other gramineous species were evaluated. Young plants were first inoculated with a composite uredinial inoculum derived from aecia. Accessions showing sporulation were further tested with pure urediniospore isolates. Sixteen potential aecial hosts in the families Rhamnaceae and Elaeagnaceae were tested for susceptibility through inoculation with germinating teliospores. Thirteen grass species within five genera in the tribe Poeae (Apera, Calamagrostis, Lamarckia, Phalaris, and Puccinellia) and four species in Rhamnaceae (Frangula alnus, F. californica, F. caroliniana, and Rhamnus lanceolata) were found to be susceptible to Pcc, with some species native to North America. All assessed crop species and turfgrasses were resistant. Limited sporulation, however, was observed on some resistant species within Poeae and four other tribes: Brachypodieae, Bromeae, Meliceae, and Triticeae. Among these species are oats, barley, and Brachypodium distachyon, suggesting the possible use of Pcc in studies of nonhost resistance.

First Report of Anthracnose on Euonymus japonicus Thunb. Caused by a Provisionally Novel Species of Colletotrichum in the Magnum Complex in South Korea.

Euonymus japonicus Thunb., also known as the evergreen spindle tree, is an evergreen tree, which is widely planted as a hedge plant along streets in South Korea. In April 2022, severe anthracnose symptoms were observed on the leaves of this tree in Jangsu in the Jeonbuk Province of the country (35°43'49.44″N, 127°34'53.7″E). About 80% of the leaves of each affected tree within a 0.03-ha area showed incidence of the disease on approximately 30 trees were planted along the roadside (~30 m). These symptoms typically included circular or irregularly shaped whitish-gray lesions with a diameter of 2.0 to 3.0 cm. In cases where some leaves were severely affected, larger blotches formed. To isolate the pathogen, about ten leaves showing anthracnose symptoms on each tree were randomly selected and brought to the laboratory. Fungal isolations were made from acervuli filled with conidial masses on infected evergreen tissues, followed by plating onto 2% potato dextrose agar (PDA) as well as incubated at 25℃. On the PDA, colonies were circular, raised, green-grey or dark grey, and had a distinct white margin. The conidia were single-celled, transparent, cylindrical with rounded ends, had smooth walls, with a length ranging from 12 µm to 16.7 µm and a width raging from 4 µm to 6.5 µm (av. = 14.1 X 5.0 µm, n=40). Of those that were successfully recovered with approximately 90% frequency, two monoconidial isolates were deposited to the culture collection at Chungnam National University in South Korea (Accession number: CDH059-060). To ensure the identity of the fungus, genomic DNAs were extracted from the selected isolates, CDH059-060, and were sequenced. This was achieved based on partial sequences of the internal transcribed spacer (ITS), actin and beta-tubulin (TUB2) gene regions which were amplified using ITS1F / ITS4 (Gardes and Bruns 1993; White et al. 1990), ACT-512F / ACT-783R (Carbone and Kohn 1999), and T1 / Bt2b (O'Donnell and Cigelnik 1997; Glass and Donaldson 1995) primer pairs, respectively. The resulting sequences were deposited to GenBank (OR984424-425) for ITS, (OR996289-290) for actin, and (OR996291-292) for TUB2. For a phylogenetic analysis, sequences from different gene regions (ITS, actin and TUB2) retrieved from GenBank were aligned, concatenated, and analyzed as a single dataset based on a maximum likelihood analysis. The phylogenetic result revealed that the fungus isolated in this study was positioned in a clearly distinct lineage, provisionally representing an undetermined species of Colletotrichum, which is most closely related to Colletotrichum liaoningense (Y.Z. Diao, C. Zhang, L. Cai & X.L. Liu, CGMCC3.17616 (KP890104 for ITS, KP890097 for actin, and KP890111 for TUB, Diao et al. 2017). Sequence comparisons revealed that this pathogen differed from C. liaoningense at 20 of 494 characters (∼4.0%) in the ITS and 2 of 251 (∼1.0%) in the actin sequences. For pathogenicity tests, three seedlings of E. japonicus were used. The leaves for each tree were treated with 10 ml of a conidial suspension by spraying (1x106 conidia ml-1 of the isolate, CDH059), while the three seedlings were treated with distilled water as control. After sprayed, the treated areas were sealed with plastic bags for a day to maintain humidity. Anthracnose symptoms identical to those observed in the field appeared seven days after inoculations, while no symptoms were observed in the control. Re-isolations were successfully achieved from the treatments, fulfilling Koch's postulates. Anthracnose associated with the provisionally novel species of Colletotrichum sp. on E. japonicus has not been recorded elsewhere, and in this regard, this is the first report of anthracnose caused by Colletotrichum sp. on E. japonicus in Korea. To effectively control the disease, more attention should be paid to the host range of the pathogen and other regions where the disease caused by the pathogen might occur in the country.

First Report of Botryosphaeria dothidea Causing Leaf Blight on Parrotia subaequalis in China.

Parrotia subaequalis is of great ornamental value due to its unique bark, featuring interesting textures and colors, and its large, striking galls. These characteristics make it a popular choice for bonsai cultivation. (Yan et al. 2022) . In July 2023, an outbreak of leaf blight was observed on 40, six-month-old P. subaequalis seedlings in Anqing, Anhui, China, with an incidence rate of 80%. In the early stages of infection, small brown spots appear on the leaf surface, which gradually become round or irregular and darken to a deep brown color. As the disease progresses, the affected areas expand from the leaf margins towards the center, causing the leaf surface to become concave, wilt, and necrotize. This resulted in restricted plant growth, and in severe cases, partial or complete plant death. For isolation, 30 tissue slices (5 × 5 mm) were taken from the leaves of 10 symptomatic seedlings and surface sterilized with 75% ethanol for 5 seconds, followed by five rinses with sterilized distilled water. After two days of dark incubation at 28°C, hyphal tips of fungi were transferred onto new potato dextrose agar (PDA) plates and incubated until conidia production. Six unidentified isolates with similar morphological characteristics were obtained. The colonies, initially white, darken to black after 7 to 10 days of incubation. They produced colorless, aseptate conidia that were oblong or fusiform, measuring 18-26 µm in length and 5-8 µm in width (n=50). The morphological characteristics of the isolates resembled those of Botryosphaeria (Udayanga et al. 2015) . Isolate IS2116-1 was further confirmed through molecular methods. The rDNA internal transcribed spacer (ITS) region, translation elongation factor 1-α (TEF1-α), and beta-tubulin (TUB2) genes were amplified and sequenced using the primers ITS1/ITS4 (White et al., 1990), EF1-728F/EF1-986R, and Bt2a/Bt2b (Ferreira et al., 2021; Carbone et al., 1999), respectively. BLAST analysis revealed that the ITS (OR958722) sequence was 100% similar to the B. dothidea isolate HZ5(MH329650.1), TEF1-a (PP214058) sequence was 100% similar to the B. dothidea strain JZB310220(ON890458.1), and strain TUB2 (PP214057) sequence was 99.78% similar to the B. dothidea strain L14 (KR260833.1). Maximum likelihood analyses were performed for the combined ITS、TUB2、TEF datasets using PhyloSuite v1.2.2, the resulting phylogenetic tree indicated that isolate IS2116-1 clustered together with Botryosphaeria dothidea in a clade with 97% bootstrap support(Zheng et al. 2020) . Pathogenicity tests were conducted on 3-6 month-old P. subaequalis seedlings (n = 5) grown in a greenhouse. A conidial suspension (106 spores/ml) collected from the isolates was sprayed onto P. subaequalis seedlings, while the control was treated with distilled water. All plants were maintained in a growth chamber at 28°C with a 12-h photoperiod. The experiment was conducted twice independently . After 20 days of inoculation, brownish lesions similar to those observed in the field appeared on the treated plants, while the noninoculated control plants remained symptomless. The pathogen was reisolated from the leaves of the obviously diseased seedlings and confirmed as B. dothidea through morphological and sequence analysis. No isolates were obtained from uninoculated control plants, thus fulfilling Koch's hypothesis. This report marks the first record of B. dothidea causing leaf blight in P. subaequalis. In light of the rarity of natural P. subaequalis populations, it is imperative to assess both the extent of disease spread and its economic impact. These insights are crucial for devising strategies to protect this endangered species from disease threats and to preserve its ecological significance.

Vascular streak dieback: A novel threat to redbud and other woody ornamental production in the United States.

Eastern redbud (Cercis canadensis L.) is a popular and high-value woody ornamental plant native to the eastern and south-central United States of America (U.S.A.). In recent years, redbud production in the Southeastern U.S.A. has been greatly affected by a novel threat: vascular streak dieback (VSD). Infected plants exhibit a common set of symptoms, including leaf scorch, tip dieback, and vascular streaking that creates a marbled pattern in stem cross-section. Based on both conventional diagnosis and molecular identification, it has been found that the fungus Ceratobasidium sp. D.P. Rogers (Csp) is consistently associated with VSD-symptomatic eastern redbuds. However, the causal agent(s) of VSD has not yet been conclusively confirmed. Although eastern redbud has been the most frequently identified host tree, more than 25 other native plant genera have been confirmed to have VSD associated with Csp. The near-obligate nature of this fungus has made it challenging to culture, extract DNA, and conduct further studies to confirm its pathogenicity. This article highlights the emerging challenges of VSD, focusing on the following: 1) the recent history of VSD; 2) the increasing importance of VSD to woody ornamental nursery production in the U.S.A.; 3) the currently available protocols for isolating, culturing, storing, and maintaining the putative causal agent; 4) the rapid molecular detection of Csp; 5) phylogenetic findings on the origin and relatedness of Csp to previously recorded diseases, especially VSD in cacao (Theobroma cacao L.); and 6) preliminary results and observations from fungicide trials and cultivar screening in Tennessee. The article also outlines research needed to comprehensively understand VSD and accelerate the development of effective management strategies.

A Survey of Phytophthora spp. in Eastern Indian Nurseries and Their Sensitivity to Six Oomycete-Targeted Commercial Fungicides.

A survey of the flori-horticultural nurseries in eastern India found Phytophthora nicotianae to be the most widespread Phytophthora species associated with different foliar symptoms of nursery plants and identified the presence of P. palmivora in eastern Indian nurseries for the first time. The survey also led to the first worldwide finding of P. nicotianae on Dipteracanthus prostratus (Poir.) Nees; Ocimum tenuiflorum L. (syn. Ocimum sanctum L.); Philodendron xanadu Croat, Mayo & J. Boos; and Pyrostegia venusta (Ker-Gawl.) Miers and P. palmivora on Episcia cupreata (Hook.) Hanst., as well as the first report from India of P. nicotianae on Spathiphyllum wallisii Regel; Anthurium andraeanum Linden ex André; and Adenium obesum (Forsk.) Roem. & Schult. Sensitivity to commercial fungicides Glazer 35WS, Rallis India (metalaxyl, FRAC code 4); Ridomil Gold, Syngenta (mefenoxam + mancozeb); Revus, Syngenta (mandipropamid, FRAC code 40); Aliette Bayer (fosetyl-Al, FRAC code 33); Acrobat, BASF (dimethomorph, FRAC code 40); and Amistar, Syngenta (azoxystrobin, FRAC code 11) was analyzed, showing EC50 values ranging from 0.75 to 16.39 ppm, 0.74 to 1.45 ppm, 2.43 to 17.21 ppm, 63.81 to 327.31 ppm, 8.88 to 174.69 ppm, and 0.1 to 1.13 ppm, respectively, with no cross-resistance of the isolates to the fungicides. The baseline information produced about these Phytophthora spp. from ornamental and horticultural host associations could help prevent the pathogens from becoming primary drivers of new disease outbreaks and their large-scale distribution beyond their natural endemic ranges.

First Report of the Rust Fungus Melampsora ferrinii on Salix babylonica in China and a New Spermogonial and Aecial Host, Corydalis bungeana.

The occurrence of rust fungi on Corydalis bungeana Turcz. and Salix babylonica L. were found in same area of Hebei Province, China from 2022 to 2023. The life cycle connection of these rust fungi was suspected because Peng et al. (2022) reported the life cycle of Melampsora ferrinii Toome & Aime by inoculations, producing spermogonia and aecia on Corydalis species, and uredinia on S. babylonica. The morphology of the uredinial and telial stages on S. babylonica collected in the field was identical with the description of M. ferrinii by Toome and Aime (2015), and its identity was confirmed by phylogenetic analyses using the method of Ji et al. (2020) (LSU-PP087777, ITS-PP091274; Similarity with M. ferrinii: LSU-100%, ITS-99.85%). To confirm the life cycle of this rust fungus, inoculations were conducted on C. bungeana with basidiospores obtained from the teliospores on fallen leaves of Salix babylonica. The fallen leaves producing basidiospores were cut into small pieces (ca. 5 mm2) and placed on healthy leaves of C. bungeana. The inoculated plants were kept in a moist plastic box in darkness at 15-20℃ for 2 days and then transferred to the floor near windows at about 15-20℃ for observations. Ten days after inoculations small yellow spots of spermogonia appeared on the upper surface of the leaves of C. bungeana. About 7 days later, pale yellow aecia with aeciospores were produced mainly on the under surface of the leaves and petioles. The morphology of rust fungus on C. bungeana collected from the fields and obtained by inoculations was identical with the description by Peng et al. (2022). Phylogenetic analyses also showed that a specimen on C. bungeana collected from the field (LSU-OR607838, ITS-OR612063) were included into the same clade of M. ferrinii (Similarity: LSU-100 %, ITS-99.85). Based on morphology, inoculations and DNA sequence analyses, the rust fungi on C. bungeana and S. babylonica are identified as different stages of life cycle of M. ferrinii. This rust fungus has been reported to produce spermogonia and aecia on C. acuminata Franch., C. edulis Maxim. and C. racemosa (Thunb.) Pers. in China (Peng et al. 2022), and uredinia and telia on S. babylonica in USA, Argentina and Iran (Toome and Aime 2015, Abbasi et al. 2024), and on Salix sp. in Chile (Zapata 2016). Therefore, C. bungeana is a new host for M. ferrinii, and its field occurrence on S. babylonica is reported for the first time in China although Peng et al. (2022) reported successful results in its inoculations to S. babylonica in China. This report contributes to the control of rust diseases caused by this species. Specimens used in this experiment were deposited in the Fungal Herbarium of the Jilin Agricultural University, Changchun, China (HMJAU) and sequences newly analyzed were deposited in GenBank.

Effect of Plasma-Activated Water (PAW) Generated Using Non-Thermal Atmospheric Plasma on Phytopathogenic Bacteria.

Plasma-activated water (PAW) exhibits potent antimicrobial properties attributed to the generation of diverse reactive oxygen and nitrogen species. This study assessed the effectiveness of PAW in vitro against phytopathogenic Xanthomonas arboricola and Pseudomonas syringae pv. syringae, which cause diseases on ornamental plants. Extending the plasma activation time of water and the incubation time of bacterial suspension in PAW increased the effectiveness of PAW. Treatments consisting of PAW activation using a power output of 200 Watts and a frequency of 50 Hz at different activation times and target population incubation times revealed significantly different effectiveness against P. syringae pv. syringae and X. arboricola. X. arboricola (reduction of 4.946 ± 0.20 log10 CFU/mL) was more sensitive to PAW inactivation than P. syringae pv. syringae (reduction of 3 ± 0.15 log10 CFU/mL). The plasma activation of water for 20 min followed by incubation of bacterial population for 180 min was proven to be the most effective treatment combination. The plasma activation time dose required to reduce the population by 90% was 7.47 ± 1.09 min for P. syringae pv. syringae and 4.45 ± 1.81 min for X. arboricola incubated for 180 min in PAW. The results of this study have the potential to further contribute to assessment of the effects of PAW on pathogen infected plant tissues. In addition, the findings of this study could aid in further characterization of the reactive species formed during the plasma activation of water.

Evaluation of Anaerobic Soil Disinfestation to Reduce Soilborne Diseases in Soilless and Soil-Based Substrates for Specialty Cut Flower Production.

Anaerobic soil disinfestation (ASD) is a nonchemical soil treatment where an easily decomposable carbon source is incorporated into soil, which is then irrigated to saturation and tarped to create anaerobic conditions, which prompts shifts in the soil microbiota from aerobes to anaerobes. ASD has been tested successfully for soilborne disease management in a variety of cropping systems but has not been sufficiently investigated in ornamentals. In this study, ASD was evaluated in soil-based and soilless substrates commonly used in specialty cut flower production using two model pathosystems: Rhizoctonia solani-Zinnia elegans and Phytophthora drechsleri-Gerbera jamesonii. Each substrate was mixed with pathogen-infested vermiculite and amended with either wheat bran, tomato pomace, or soybean meal as the carbon source. Amended substrates were incubated at 25°C for 4 weeks and used as growing substrates for the two crops mentioned above, which were monitored weekly for disease development for up to 5 weeks posttransplant. Additional experiments tested the effect of plant age and inoculum concentration in the substrate on ASD efficacy. Results showed that ASD has the potential to be deployed successfully for the control of Rhizoctonia stem rot in both substrates. Conversely, ASD was not effective at controlling Phytophthora crown rot on gerbera daisy in any of the experiments conducted in this study. More research is needed to understand the influence of carbon amendments, inoculum thresholds, and environmental conditions on ASD efficacy.

First Report of Powdery Mildew Caused by Podosphaera xanthii on Youngia japonica subsp. elstonii in Hainan Province, China.

Youngia japonica (L.) DC. is a polymorphic annual herb of the Asteraceae family. Although this plant originated in Asia, it is now world-widely distributed. In China, Y. japonica is used for edible or folk medicine to treat viral infections and various kinds of inflammation (Yu et al. 2021). As a traditional Chinese medicinal herb, Y. japonica used for the treatment of inflammatory diseases, such as angina, leucorrhea, mastitis, conjunctivitis, and rheumatoid arthritis (Chen et al. 2006). During the spring of 2023, powdery mildew symptoms were observed on 60% of Y. japonica subsp. elstonii plants in a greenhouse on the Hainan Medical University campus (19° 58' 53″ N; 110° 19' 47″ E) in Haikou, Hainan Province, China. Powdery mildew colonies covered the leaf surfaces and stems of affected plants, causing discoloration and defoliation. Mycelia were superficial and hyphal appressoria were nipple-shaped. Conidiophores (n =30) were unbranched, cylindrical, 99 to 166 × 11 to 16 µm, and produced three to five immature conidia in chains with a crenate outline. Foot cells (n =30) were cylindrical, straight or sometimes curved at the base, and 35 to 61 µm long. Conidia (n =100) were ellipsoid-ovoid to doliiform, 21 to 40 ×13 to 21 µm (length/width ratio = 1.4 to 2.3), with well-developed fibrosin bodies, and produced germ tubes from the lateral position. Based on these morphological characteristics, the pathogen was provisionally identified as Podosphaera xanthii (Braun and Cook 2012). The teleomorph was not observed. A specimen was deposited in the Hainan Medical University Plant Pathology Herbarium as HMYJ-23. To confirm the genus identification and ascertain a putative species, genomic DNA was extracted from mycelium, conidiophores, and conidia using a fungal DNA kit (Omega Bio-Tek, USA). The rDNA internal transcribed spacer (ITS) region was amplified with primers ITS1/ITS4 (White et al. 1990) and sequenced directly. The resulting 575-bp sequence was deposited in GenBank (accession no. OR229712). A BLASTn search in GenBank of this sequence showed 99% similarity with the ITS sequences of P. xanthii isolates from China (MT260063, OP765400, MW422608, and MT739423), Thailand (LC270778, LC270779, and LC270780), and Argentina (AB525914). Additionally, the 613-bp 28S rDNA region was amplified using the primer pairs NL1 and NL4 (O'Donnell 1993; accession no. OR240257). This region shared 100% similarity with P. xanthii isolates (MK357436, LC371333, LC270780, OP765401, and AB936277) as well. To confirm pathogenicity, five healthy potted plants of Y. japonica subsp. elstonii were inoculated by gently pressing a powdery mildew-infected leaf onto the young leaves. Five non-inoculated plants served as controls. All plants were maintained in a greenhouse at 24 to 30°C, 70% relative humidity, with a 16-h photoperiod. After 7 days, inoculated leaves showed powdery mildew symptoms whereas no symptoms were observed on control plants. The fungal colonies observed on inoculated plants were morphologically identical to those found on the originally infected leaves collected from Hainan Province. Based on the morphological characteristics and molecular identification, the fungus was identified as P. xanthii. To our knowledge, this is the first record of P. xanthii infecting Y. japonica subsp. elstonii in Hainan province, China. We are concerned that the pathogen could become a threat to the widespread planting of Y. japonica subsp. elstonii in the future.

Podosphaera xanthii Causing Powdery Mildew on Salvia farinacea in Central China.

Salvia farinacea, commonly referred as mealycup sage, is a perennial herbaceous plant belonging to the Salvia genus of the Lamiaceae family. It originates from the Mediterranean region, North America, and Europe and is globally cultivated due to its appealing and captivating flowers. Moreover, mealycup sage is utilized as traditional Chinese medicinal plant for treatment of cardiovascular diseases (Li et al. 2018). In October 2023, powdery mildew-like symptoms were observed on Salvia farinacea plants cultivated in a garden located in Xinxiang City, Henan Province, China (113.93, 35.29). The leaves were covered with white and thin masses of mycelia, conidiophores and conidia of the fungus. About 100 plants were checked and 90 % were infected. There were a large number of white colonies with irregular or continuous round lesions on the adaxial and abaxial surfaces of the leaves, covering approximately 80% of the leaf area. The slightly or straight curved conidiophores (n = 30) were 46 to 145× 8 to 11 µm in size and consisted of foot cells, shorter cells and conidia. The ellipsoidal to oval conidia (n = 30), containing fibrosin bodies, were 24 to 35 × 12 to 19 µm in size and had a length/width ratio of 1.8 to 2.1. No chasmothecia were observed on leaves. These morphological features were consistent with those of Podosphaera xanthii (Braun and Cook 2012). Following the previously described method (White et al. 1990; Bradshaw et al. 2022; Zhu et al. 2022a), the sequences of ITS and Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) regions were amplified with specific primers ITS1/ITS4 (ITS1 5'-TCCGTAGGTGAACCTGCGG-3' ; ITS4 5'-TCCTCCGCTTATTGATATGC-3') and PMGAPDH1/PMGAPDH3R (PMGAPDH1 5'-GGAATGGCTATGCGTGTACC-3'; PMGAPDH3R 5'-CCCCATTCGTTGTCGTACCATG-3'), and the resulting sequences were uploaded in GenBank (Accession No. OR761885 and PP236082, respectively). BLASTn analysis showed that the sequence shared 560/565 (99%) and 272/272 (100%) homology with P. xanthii (MW301281) on Impatiens balsamina (Zhu et al. 2022b) and with P. xanthii (ON075658) on Cucumis melo (Bradshaw et al. 2022), respectively. The phylogenetic analysis clearly illustrated that the collected isolate of P. xanthii clustered in the same clade. The pathogenicity was tested according to the method previously described (Zhu et al. 2021). The fungus was inoculated onto the leaf surfaces of three healthy plants by blowing conidia from infected leaves with pressurized air. Non-inoculated plants were treated as control. Both the control and inoculated plants were separately placed in growth chambers under 60% humidity; light/dark, 16 h/8 h; and a temperature of 18°C. After a period of 12-15 days, the leaves of the inoculated plants exhibited signs of powdery mildew, whereas the control group remained unaffected. Therefore, the fungal pathogen was identified and confirmed as P. xanthii (isolate PXSF202310). Previously, P. xanthii was reported on Impatiens balsamina and S. farinacea from China and Korea (Zhu et al. 2021; Choi et al. 2022). As far as we know, this is the first documentation of P. xanthii on S. farinacea in central China. The presence of P. xanthii can lead to a deterioration in plant health and stunted growth, thereby negatively impacting both the decorative and medicinal value of S. farinacea. The recognition of P. xanthii on S. farinacea enhances our comprehension of this pathogen hosts and provides fundamental information for forthcoming disease control studies.

Occurrence of Neopestalotiopsis clavispora Causing Leaf Blight on Acer oblongum in China.

Acer oblongum is native to Southwest China and is also distributed in Nepal and Northern India. It is an excellent garden ornamental tree species, suitable for solitary planting in courtyards and parks. From June to August 2022, severe leaf blight occurred on A. oblongum in Baihe Wetland Park (32°5'42" N, 112°28'13" E) in Nanyang City, China. The foliar disease rate reached 59% (n=100). Early signs were yellow spots on the leaves, mainly on the middle and edge parts. Then, the lesions gradually expanded, became amorphous, and turned yellowish brown, eventually led to necrosis on leaves and branches. Twenty diseased leaves were collected and the junction areas between infected and healthy tissues were cut into 5 x 5 mm2 pieces. The collected plant materials were sterilized in 75% ethanol and 1% NaClO for 30 s and 1 minute, respectively, followed by rinsing in sterile water, and placing on a potato dextrose agar (PDA) plate supplemented with 50 µg ml-1 streptomycin at 25 °C for 3 days. Colony edges were cut and transferred to new PDA plates for purification culture. A total of 18 purified fungal strains were obtained, which showed similar phenotypes in morphological characteristics. All colonies had spread radially with wavy surfaces, and dense cream to white aerial hyphae. After 14 days in culture, black fruiting bodies appeared. Conidia were fusiform to slightly clavate, with five cells and two or three setae, 4.2 to 7.9 µm × 17.5 to 25.4 µm in diameter (n = 100). The apical and basal cells and setae were colorless, three median cells were brown, and the middle cell was dark brown. Morphological characteristics of all 18 strains were consistent with the genus description of Neopestalotiopsis spp. (Maharachchikumbura et al. 2014). Further molecular identification showed that the ITS region sequences of all strains have extremely high homology with Neopestalotiopsis spp. The ß-tubulin gene (TUB), and the translation elongation factor 1-alpha gene (TEF1) were amplified for molecular identification (Shu et al. 2020). The sequences of three representative strains (FE-05, 09, 16) from different regions were deposited in GenBank with accession Nos. OQ867279, OQ867288, OQ867289 (ITS), OQ870207, OQ870208, OQ870209 (TUB), and OQ870204, OQ870205, OQ870206 (TEF1). BLASTn analysis of these sequences showed 99 to 100% identity to Neopestalotiopsis clavispora strains (OK655673, MZ648263 for ITS, ON000362, MZ286974 fr TUB, MH423941, MK512481 for TEF1). These morphological features and molecular identification indicated that the pathogen has the same characteristics as N. clavispora. Pathogenicity was tested on ten healthy 3-month-old seedlings using the three representative strains through in vivo experiments. For each strain, the conidial suspension (106 conidia ml-1) in absorbent cotton balls (50 µl of inoculum) were inoculated onto the healthy leaves of two seedlings, while a total of two other plants were served with sterile water as a blank control. The plants were potted in a climate incubator at 28°C and a relative humidity of approximately 90%. Symptoms consistent with natural lesions were observed on the inoculated leaves after 5 days while the control plants remained healthy. The strains of N. clavispora were reisolated from the symptomatic inoculated leaves, fulfilling Koch's postulates. N. clavispora is known to cause disease in a variety of plants in China, such as Dendrobium officinale (Cao et al., 2022), Fragaria ananassa (Shi et al., 2022), and Garcinia mangostana (Qiu et al., 2019). To the best of our knowledge, this is the first report of N. clavispora causing leaf blight on A. oblongum in China. The yellowing and falling off of leaves would seriously affects the garden landscape. It is necessary to further clarify the host range of the pathogen to select appropriate landscape matching plants in future planning.

First report of Dactylonectria pauciseptata causing root rot on Eucalyptus cinerea in China.

Eucalyptus cinerea is an evergreen tree in the Myrtaceae. It is native to southern and eastern New South Wales and northern and eastern Victoria, Australia. It was introduced into China in the 1980s (Silva et al. 2011). Because of its unique shape, flexible stems, and rapid growth characteristics, it is widely used in the pulp industry and in decorative materials such as flower bouquets. In July 2022, 5- to 10-year-old E. cinerea showing symptoms of dehydration, withering and yellowing leaves, were found in forests and nurseries in Kunming and Songming, China. More than 37% of the trees showed these symptoms at each location, and disease severity was about 30%. Sixty symptomatic plants were collected from five tree nurseries. Diseased roots with 2-cm-long lesions were soaked in 75% ethanol for 15 s, 0.1% mercuric chloride for 2 min, rinsed with sterilized water, and placed on potato dextrose agar (PDA) at 25℃ for 3 days. Thirty samples were plated, and 21 isolates (YJLGF01 to YJLGF21) obtained, 11 strains with similar colony morphology (including representative strains YJLGF03 to YJLGF05). Three isolates (YJLGF03 to YJLGF05) were obtained by single-spore purification. On PDA, the colonies were circular with fluffy white to light yellow mycelium; the underside was yellowish brown. Conidiophores were bifurcated, with macroconidia borne terminally. The macroconidia were cylindrical with rounded, blunt ends, yellow to transparent, 1 to 3 septate (22.5 to 47.6 × 4.5 to 7.1 µm); microconidia were 0 to 1 septate (12.5 to 19.6 × 4.7 to 6.4 µm). Chlamydospores were spherical, rosary-like, and light yellow. Morphological characteristics were consistent with published descriptions of Dactylonectria pauciseptata (Piperkova et al. 2017). For molecular identification, the internal transcribed spacer (ITS), translation elongation factor 1- alpha (ef1-α) gene, and the beta-tubulin 2 (ß-tub2) gene were amplified and sequenced (ITS accessions OR735053, OR735054, OR735055; ß-tub2 accessios OR757447, OR757448, OR757449; ef1-α accessions OR757450, OR757451, OR757451) using published primers (White et al. 1990; Carbone et al. 1999). A phylogenetic tree was developed by Maximum Parsimony (MP) and Maximum Likelihood (ML) methods. These three isolates fell into the D. pauciseptata clade and were distinguished clearly from other species. Pathogenicity tests were performed using the same three isolates. Each isolate was cultured on PDA, and then subcultured in V8 juice broth on an orbital shaker at 180 RPM for 5 days. Conidia were collected by centrifugation at 6,000 RPM for 5 min, and then resuspended in sterilized distilled water (1×106 conidia/ml). Injured roots of one-year-old E. cinerea were soaked in the spore suspension for 1 h before being transplanted in sterile vermiculite. The plants were incubated at 25℃ with a 12 h photoperiod and 90% humidity. Five plants were inoculated as a group for each treatment and the entire experiment was completed three times. Among the inoculated plants, the incidence of disease development was 100%. A small sot appeared after 4 days, with a water-soaked lesion appearing and gradually expanding during days 5 to 7. After 10 days symptoms of root necrosis were similar to the those observed in the nursery, and aboveground plant parts had yellow, withering leaves and defoliation after 10 to 15 days. Control plants treated with sterile water showed no disease symptoms. The three strains were successfully reisolated from inoculated seedlings and confirmed them using DNA sequencing. No isolates were obtained from the control plants, thus fulfilling Koch's postulates. Dactylonectria pauciseptata was first reported from necrotic tissue of infected grape roots (Schroers et al. 2008). So far, it has been reported in Turkey, Canada, Brazil, Italy, and other countries (Erper et al. 2013; Úrbez-Torres et al. 2014; Santos et al. 2014). Based on our results, E. cinerea is a new host plant of D. pauciseptata in China. This disease is a threat to the nursery production of E. cinerea, potentially leading to a reduction in yields and economic losses.

First Report of Powdery Mildew Caused by Podosphaera xanthii on Acalypha indica in China.

Acalypha indica L. is an annual erect herb of the Euphorbiaceae family. This plant is found widely in the tropics and parts of Africa and Asia (Chakraborty et al. 2023). In China, A. indica is a vegetable and also used as a folk medicine due to its antipyretic and hemostatic, antibacterial and anti-inflammatory properties. In February 2022 and 2023, powdery mildew symptoms were observed on 70% of A. indica plants on the Hainan Medical University campus (19° 58' 53″ N; 110° 19' 47″ E) in Haikou, Hainan Province, China. Powdery mildew colonies covered the leaf surfaces and stems of affected plants, causing discoloration and defoliation. Mycelia were superficial and hyphal appressoria were nipple-shaped. Conidiophores (n =30) were unbranched, cylindrical, 66 to 150 × 10 to 15 µm, and produced three to five immature conidia in chains with a crenate outline. Foot cells (n =30) were cylindrical, straight or sometimes curved at the base, and 31 to 59 µm long. Conidia (n =100) were ellipsoid-ovoid to doliiform, 20 to 33 ×12 to 20 µm (length/width ratio = 1.3 to 2.4), with well-developed fibrosin bodies, and produced germ tubes from the lateral position. Based on these morphological characteristics, the pathogen was provisionally identified as Podosphaera xanthii (Braun and Cook 2012). The teleomorph was not observed. A specimen was deposited in the Hainan Medical University Plant Pathology Herbarium as HMAI-23. To confirm the genus identification and ascertain a putative species, genomic DNA was extracted from mycelium, conidiophores, and conidia using a fungal DNA kit (Omega Bio-Tek, USA). The rDNA internal transcribed spacer (ITS) region was amplified with primers ITS1/ITS4 (White et al. 1990) and sequenced directly. The resulting 575-bp sequence was deposited in GenBank (accession no. OR775733). A BLASTn search in GenBank of this sequence showed 99% similarity with the ITS sequences of P. xanthii on plants of Fabaceae, Malvaceae and Cucurbitaceae family from China (MH143485, MT242593, MK439611 and MH143483), Thailand (LC270779 and LC270778), Korea (MG754404), Vietnam (KM260704), and Puerto Rico (OP882310). Additionally, the 28S rDNA region was amplified using the primer pairs NL1 and NL4 (O´Donnell 1993; accession no. OR784547). This region shared 99% similarity with P. xanthii isolates (LC371333, LC270780, AB936277, and OP765401) as well. To confirm pathogenicity, five healthy potted plants of A. indica were inoculated by gently pressing a powdery mildew-infected leaf onto 15 young leaves. Five non-inoculated plants served as controls. All plants were maintained in a greenhouse at 24 to 30°C, 70% relative humidity, with a 16-h photoperiod. After 7 days, inoculated leaves showed powdery mildew symptoms whereas no symptoms were observed on control plants. The fungal colonies observed on inoculated plants were morphologically identical to those found on the originally infected leaves collected from Hainan Province. Based on the morphological characteristics and molecular identification, the fungus was identified as P. xanthii. In different countries and regions, P. xanthii has been previously reported on A. indica from Sudan and India (Amano 1986). To our knowledge, this is the first record of P. xanthii infecting A. indica in China. We are concerned that the pathogen could become a threat to the widespread planting of A. indica in the future.

First Report of Powdery Mildew Caused by Podosphaera xanthii on Sphagneticola trilobata in Hainan Province, China.

Sphagneticola trilobata (L.) Pruski is a perennial creeping herb of the Asteraceae family, which is native to South America. It was introduced into Southern China as a groundcover in the 1970s (Zhang et al. 2023). Now it is mainly used for folk medicine to treat various kinds of inflammatory, incuding joint pain, rheumatic diseases, arthritis, in addition to treating persistent wounds, ulcers, and edemas (Gonçalves et al. 2022). In February and November 2023, powdery mildew symptoms were observed on 60% of S. trilobata plants on the Hainan Medical University campus (19° 58' 53″ N; 110° 19' 47″ E) in Haikou, Hainan Province, China. Powdery mildew colonies covered the leaf surfaces and stems of affected plants, causing discoloration and defoliation. Mycelia were superficial and hyphal appressoria were nipple-shaped. Conidiophores (n =30) were unbranched, cylindrical, 74 to 161 × 10 to 14 µm, and produced three to five immature conidia in chains with a crenate outline. Foot cells (n =30) were cylindrical, straight or sometimes curved at the base, and 27 to 56 µm long. Conidia (n =100) were ellipsoid-ovoid to doliiform, 17 to 30 ×14 to 28 µm (length/width ratio = 1.1 to 1.9), with well-developed fibrosin bodies, and produced germ tubes from the lateral position. Based on these morphological characteristics, the pathogen was provisionally identified as Podosphaera xanthii (Braun and Cook 2012). The teleomorph was not observed. A specimen was deposited in the Hainan Medical University Plant Pathology Herbarium as HMST-23. To confirm the genus identification and ascertain a putative species, genomic DNA was extracted from mycelium, conidiophores, and conidia using a fungal DNA kit (Omega Bio-Tek, USA). The rDNA internal transcribed spacer (ITS) region was amplified with primers ITS1/ITS4 (White et al. 1990) and sequenced directly. The resulting 577-bp sequence was deposited in GenBank (accession no. OR784549). A BLASTn search in GenBank of this sequence showed 100% similarity with the ITS sequences of P. xanthii isolates from China (MT260063, MN203658, OP765400, and MT739423), Thailand (LC270780), and Vietnam (KM260731, KM260730, and KR779870). Additionally, the 28S rDNA region was amplified using the primer pairs NL1 and NL4 (O´Donnell 1993; accession no. OR784550). This region shared 100% similarity with P. xanthii isolates (LC371334, LC270782, AB936277, and OP765401) as well. Powdery mildew from Hainan sample belonged to the P. xanthii group with strong bootstrap values support 99% in maximum likelihood phylogenetic tree based on ITS and 28S gene sequences. To confirm pathogenicity, five healthy potted plants of S. trilobata were inoculated by gently pressing a powdery mildew-infected leaf onto 15 young leaves. Five non-inoculated plants served as controls. All plants were maintained in a greenhouse at 24 to 30°C, 70% relative humidity, with a 16-h photoperiod. After 7 days, inoculated leaves showed powdery mildew symptoms whereas no symptoms were observed on control plants. The fungal colonies observed on inoculated plants were morphologically identical to those found on the originally infected leaves collected from Hainan Province. Based on the morphological characteristics and molecular identification, the fungus was identified as P. xanthii. In different countries and regions, P. xanthii has been previously reported on S. trilobata in Taiwan (Yeh et al. 2021). To our knowledge, this is the first record of P. xanthii infecting S. trilobata in Hainan Province, China. S. trilobata is often planted as an ornamental plant on both sides of the road, and we are concerned that it may serve as a new host, spreading this pathogen to other economic crops.

First Report of White Mold Caused by Sclerotinia sclerotiorum on Hymenocallis glauca in Mexico.

In Mexico, there are 29 native species of the genus Hymenocallis, where H. glauca is one of the most cultivated bulbous plants. It holds economic importance as it is commercialized as a potted plant and cut flower (Leszczyñska and Borys, 2001). In October 2023, field sampling was conducted in the Research Center in Horticulture and Native Plants (18°55'55" N, 98°24'02.8"W) of UPAEP University. H. glauca diseased plants were found in an area of 0.4 ha, with an incidence of 35% and an estimated severity of 45% on infected plants in vegetative stage. The symptoms included chlorosis of foliage, necrosis at the base of the stem, and soft rot with abundant white to gray mycelium and abundant production of black, irregular sclerotia of approximately 3.5 mm diameter. Finally, the plants wilted and died. The fungus was isolated from 40 symptomatic plants. Sclerotia were collected, disinfested with 3% NaOCl for one minute, rinsed with sterile distilled water (SDW), and plated on Petri dishes containing potato dextrose agar (PDA) with sterile forceps. Subsequently, a sterile dissecting needle was used to place fragments of mycelium directly on Petri dishes with PDA. Plates were incubated at 23 °C in dark for 7 days. One isolate was obtained from each diseased plant by the hyphal-tip method (20 isolates from sclerotia and 20 from mycelium). After 7 days, colonies had fast-growing, dense, and cottony-white aerial mycelium forming irregular sclerotia of 3.57 ± 0.59 mm (mean ± standard deviation, n=100). In each Petri dish there were produced 21.5 ± 7.9 sclerotia (mean ± standard deviation, n=40), after 11 days; these were initially white and gradually turned black. The isolates were tentatively identified as Sclerotinia sclerotiorum based on morphological characteristics (Saharan and Mehta 2008). Two representative isolates were chosen for molecular identification and genomic DNA was extracted by the CTAB protocol. The ITS region and the glyceraldehyde 3-phosphate dehydrogenase (G3PDH) gene were amplified and sequenced (Staats et al. 2005; White et al. 1990). The sequences of a representative isolate (SsHg3) were deposited in GenBank (ITS- PP094578; G3PDH- PP101843). BLAST analysis of the partial sequences ITS (519 bp), and G3PDH (950 bp) showed 100% similarity to S. sclerotiorum isolates (GenBank: MG249967, MW082601). Pathogenicity was confirmed by inoculating 30 H. glauca plants in vegetative stage grown in pots with sterile soil. Ten sclerotia were deposited at the base of the stem, 10 mm below the soil surface. As control treatment, SDW was applied to 10 plants. The plants were placed in a greenhouse at 23 °C and 90% relative humidity. After 17 days, all inoculated plants displayed symptoms similar to those observed in the field, while no symptoms were observed on the controls. The fungus was re-isolated from the inoculated plants as described above, fulfilling Koch's postulates. The pathogenicity tests were repeated three times. S. sclerotiorum has been reported causing white mold on other bulbous plants, like fennel (Foeniculum vulgare) in Korea (Choi et al. 2015). To our knowledge, this is the first report of S. sclerotiorum causing white mold on H. glauca in Mexico. Information about diseases affecting this plant is very limited, so this research is essential for developing integrated management strategies and preventing spread to other production areas.

Southern blight of water lily: The first host record of Agroathelia rolfsii on Nelumbo nucifera discovered in Florida, USA.

Nelumbo nucifera Gaertn. (Nelumbonaceae, Eudicots), also known as water lily or sacred lotus, is a nonnative and invasive plant commonly found in artificial ponds and natural lakes throughout Florida (UF-IFAS 2023; Wunderlin et al. 2023). In August 2020, a single sample of water lily plants showing large leaf spots were collected at a residence in Dunnellon, Marion County, Florida (80% disease prevalence with 40% leaf coverage). Symptoms and signs of the disease were necrotized adaxial leaf spots only, bordered by whitish mycelia and hyphae with clamp connections, and whitish to light brown sclerotia formed in the center (<0.7 mm diameter). Symptomatic tissue was plated on acid potato dextrose agar (APDA) amended with chloramphenicol (100 mg/L) and ampicillin (30mg/L), and incubated at 20 °C for one week. Data supporting the molecular identification of this putative pathogen were gathered by PCR amplification and Sanger sequencing of the complete internal transcribed spacer (ITS) and a fragment of the large subunit (LSU) of the rRNA gene (~1.5 kb) using primers ITS1F and LR5 (FDACS-DPI PPST 2020-105211, GenBank OR492009) (White et al. 1990). The identification of the host was confirmed by Sanger sequencing of three plant barcode fragments: ITS2 (ITS2-S2F/ITS4, OR492008), ribulose 1,5-bisphosphate carboxylase/oxygenase large subunit (rbcL) (rbcLa-F/rbcLa-R, GenBank OR502388), and Maturase K (matK) (matK-KIM1R/matK-KIM3F, GenBank OR502389) (Fazekas et al. 2012). MegaBLAST queries of the ITS/LSU sequence obtained here recovered a 99.61% match to the fungal pathogen Agroathelia (=Athelia) rolfsii (Sacc.) Redhead & Mullineux. (Redhead and Mullineux 2023) (Amylocorticiaceae, Agaricomycotina) strain GP3 (GenBank JABRWF010000005) (Yan et al. 2021). MegaBLAST queries of three host plant DNA barcodes recovered matches of greater than 99.62% similarity to N. nucifera sequences. After diagnosis, symptomatic dried leaf samples were deposited at Plant Industry Herbarium Gainesville (PIHG 17807) and an axenic culture was deposited at the Agricultural Research Services Culture Collection (NRRL 66964). Koch's postulates were fulfilled by the inoculation of sclerotia (as in Terrones-Salgado et al. 2022) on adaxial leaf surface of four-week- old water lily transplants obtained from an artificial pond on campus (two plants with five leaves each). One additional transplant was not inoculated and served as a control; this plant remained asymptomatic during the experimentation period. Each transplant was kept in a 27-gallon plastic container (21W × 30L × 14H in) filled with tap water containing one tablespoon of 20-20-20 all-purpose-water-soluble plant fertilizer (VPG, TX, USA) in a plant biosafety level 2 greenhouse (23 °C, >50% relative humidity, and a 12-h/12-h photoperiod). All inoculated leaves showed necrotized areas after one week and new sclerotia were observed floating on the water surface after three weeks. Fungal pathogen was reisolated and reidentified subsequently. Agroathelia rolfsii is the causal agent of southern blight, also known as grey rot, and is reported from at least in 260 plant genera, including specialty crops such as citrus, cucumber, pepper, peanuts, pumpkin, and strawberry (Farr and Rossman 2018). Agroathelia rolfsii usually causes lower stem, crown, and root rots; consequently, leaf spots are a noteworthy presentation of symptoms for this fungus.

First Report of White Mold Caused by Sclerotinia sclerotiorum on Echeveria gigantea in Mexico.

Echeveria gigantea, native of Mexico (Reyes et al. 2011), holds economic importance as it is marketed as a potted plant and cut flower due to its drought-tolerant capabilities and aesthetic appeal. In September 2023, a field sampling was conducted at the Research Center in Horticulture and Native Plants (18°55'56.6" N, 98°24'01.5" W) of UPAEP University. Echeveria gigantea cv. Quilpalli plants with white mold symptoms were found in an area of 0.5 ha, with an incidence of 40% and severity of 50% on severely affected stems. The symptoms included chlorosis of older foliage, necrosis at the base of the stem, and soft rot with abundant white to gray mycelium and abundant production of irregular sclerotia resulting in wilted plants. The fungus was isolated from 30 symptomatic plants. Sclerotia were collected, sterilized in 3% NaOCl, rinsed with sterile distilled water (SDW), and plated on Potato Dextrose Agar (PDA) with sterile forceps. Subsequently, a dissecting needle was used to place fragments of mycelium directly on PDA. Plates were incubated at 23 °C in darkness. A total of 30 isolates were obtained using the hyphal-tip method, one from each diseased plant (15 isolates from sclerotia and 15 from mycelium). After 6 days, colonies had fast-growing, dense, cottony-white aerial mycelium forming irregular sclerotia of 3.67 ± 1.13 mm (n=100). Each Petri dish produced 32.47 ± 7.5 sclerotia (n=30), after 12 days. The sclerotia were initially white and gradually turned black. The isolates were tentatively identified as Sclerotinia sclerotiorum based on morphological characteristics (Saharan and Mehta 2008). Two isolates were selected for molecular identification. Genomic DNA was extracted using the CTAB protocol. The ITS region and the glyceraldehyde 3-phosphate dehydrogenase (G3PDH) gene were sequenced for two randomly selected isolates (White et al. 1990; Staats et al. 2005). The ITS and G3PDH sequences of the SsEg9 isolate were deposited in GenBank (ITS-OR816006; G3PDH-OR879212). BLAST analysis of the partial ITS (510 bp) and G3PDH (915 bp) sequences showed 100% and 99.78% similarity to S. sclerotiorum isolates (GenBank: MT101751 and MW082601). Pathogenicity was confirmed by inoculating 30 120-day-old E. gigantea cv. Quilpalli plants grown in pots with sterile soil. Ten sclerotia were deposited at the base of the stem, 10 mm below the soil surface. As control treatment, SDW was applied to 10 plants. The plants were placed in a greenhouse at 23 °C and 90% relative humidity. After 16 days, all inoculated plants displayed symptoms similar to those observed in the field. Control plants did not display any symptoms. The fungus was reisolated from the inoculated stems, fulfilling Koch's postulates. The pathogenicity tests were repeated three times. Recently S. sclerotiorum has been reported causing white mold on cabbage in the state of Puebla, Mexico (Terrones-Salgado et al. 2023). To the best of our knowledge, this is the first report of S. sclerotiorum causing white mold on E. gigantea in Mexico. Information about diseases affecting this plant is very limited, so this research is crucial for designing integrated management strategies and preventing spread to other production areas.

First report of Ralstonia pseudosolanacearum causing bacterial wilt on Rosa sp. in Greece.

In March 2021, a sample of nine-month-old, non-grafted, diseased rose (Rosa sp.) plants was sent by a grower to the Benaki Phytopathological Institute for examination. The plants exhibited symptoms of dieback with black necrosis of pruned shoots, brown discoloration of shoot and root vascular tissues, and whitish slime exudation on cutting wounds of the shoots. The symptoms resembled those caused by Ralstonia pseudosolanacearum (Tjou-Tam-Sin et al. 2016). According to the sample's information sheet, the sample had been collected in a commercial greenhouse rose crop for cut flowers with a 10% disease incidence in the area of Troizinia-Methana (Regional Unit of Islands, Greece). Microscopic examination of symptomatic shoot and root vascular tissues revealed masses of bacterial cells streaming out of them. Sections of symptomatic tissues were suspended in water and in the resulting suspension, bacteria of the R. solanacearum species complex (RSSC) were detected by an indirect immunofluorescence (IF) assay using polyclonal antibodies (Plant Research International, the Netherlands) and a qPCR assay (RS-I-F/RS-II-R primers, RSP-55T probe) (Vreeburg et al. 2016). Furthermore, colonies with typical characteristics of RSSC were isolated from vascular tissues of shoots and roots on non-selective (NA) and semi-selective (mSMSA) media (EPPO 2022), and their identification as RSSC was confirmed by the above-mentioned IF and qPCR assays. Also, the isolates were assigned to: i) biovar 3, based on their ability to metabolize three disaccharides (maltose, lactose, D(+) cellobiose) and three hexose alcohols (mannitol, sorbitol, dulcitol) producing acid (EU 2006) and ii) phylotype I, by multiplex conventional PCR (Opina et al. 1997; Fegan and Prior 2005). A representative isolate was selected for sequencing part of the genes: 16S rDNA (1464bp), mutS (729bp) and egl (795bp) with GenBank Accession Nos. OR102443, OR683617 and OR702781, respectively. Blast analysis of these sequences showed 100% identity with those of various RSSC strains (e.g. GenBank Ac. Nos. CP025741.1, CP021762.1, MF141029.1, respectively). The obtained egl sequence conforms with the characteristics of phylotype I based on the DNA barcoding tool (EPPO 2021) and is 100% identical to that of the Dutch strain PD7216 (MF141029.1) reported to be sequevar I-33 (Bergsma-Vlami et al. 2018). The pathogenicity of two isolates was tested by inoculating: i) tomato seedlings (cv. 'Belladona') at their stem between the cotyledons and the first true leaf (EU 2006) and b) rose plants (cv. 'Aqua' and 'Papa Meilland') at their shoot base (Tjou-Tam-Sin et al. 2016), with bacterial suspensions in water (108 cfu/ml). The inoculated plants were maintained at a day/night temperature about 28/20°C with tomato plants exhibiting leaf wilting (7-17 dpi) and rose plants exhibiting chlorosis and necrosis of leaves (17 dpi). The pathogen was re-isolated on mSMSA from both artificially infected plant species and identified by the IF assay described above, thus fulfilling Koch's postulates. This is the first diagnosis in Greece of: i) rose plants infected by a Ralstonia species and ii) a crop infected by R. solanacearum phylotype I that corresponds to the R. pseudosolanacearum species (EPPO 2022). Official phytosanitary measures imposed in the affected area include an annual survey of rose crops for the presence of this pathogen, aiming at an early detection and prevention of its spread in such a highly valued ornamental crop.

First report of a new Carlavirus provisionally named rose virus B and apple mosaic virus in mixed infections of Rosa sp. in Mexico.

Rose (Rosa sp.) is an important ornamental plant in the cut flower industry around the world. This species is prone to hosting several viruses since it is propagated vegetatively, mainly by grafting (Mollov et al., 2013). In 2021, rose plants of unidentified variety with mosaic, vein yellowing, chlorotic line patterns, and interveinal chlorosis were observed in a rose plantation established in open field in Temixco, Morelos (Supplementary Figure 1). To determine the cause of symptoms was due to viral infection, nucleic acids were extracted from leaves by in-house CTAB procedure and DNase treated. A pooled RNA sample extracted from 4 symptomatic plants was sent to BGI Genomics (China) for high-throughput sequencing (HTS). A stranded mRNA library was prepared and sequenced on the DNBSEQ platform (BGI). A total number of 13,646,715 paired 150-bp clean reads were generated. The reads were assembled de novo into 79,309 contigs ranging from 78 to 15,817 nucleotides (nt) using SPAdes (Prjibelskiet et al., 2020). The contigs were subjected to BLASTx and BLASTn for annotation. A contig with a length of 8,842 nt (208x average coverage per nt) showed 90.6% identity to rose virus B (RVB) (MT473961), and was deposited in GenBank under accession number ON165234. Additionally, three contigs (ON165235-ON165237) corresponding to RNA1 (3,443 nt; 154x coverage), RNA2 (2,938 nt; 231x coverage), and RNA3 (1,897 nt; 232x coverage) of apple mosaic virus (ApMV) were identified. These contigs showed up to 98.4%, 89.7%, and 98.6% identity, respectively, to each corresponding RNA sequences of ApMV. No other viral sequence was identified from the constructed contigs. Subsequently, the presence of RVB was confirmed by RT-PCR performed with an aliquot of the pooled RNAspan style="font-family:'Times New Roman'; font-size:11pt"> with specific primers targeting the replicase and CP (Diaz-Lara et al., 2021). For ApMV, a new set of primers were designed: ApMV_RNA1F (5'-AAATCTCCCGAAAGGGCCTG-3')/ApMV_RNA1R (5'-TCACTCGTCGCATGGATGGATAGC-3'), ApMV_RNA2F (5'-TTGGTACGAGTCGTGGTTGGTTGG-3')/ApMV_RNA2R (5'-GGAAAACTGACCGCAAACCC-3'), and ApMV_RNA3F (5'-GGAGGTTAGAGGCCCGAATG-3')/ApMV_RNA3R (5'-CGCACAGGTGGTAACTCACT-3') which amplify segments of 444 bp, 546 bp, and 434 bp, respectively. The amplicons obtained for both viruses were subjected to Sanger sequencing, confirming the identity of RVB and ApMV. The sequences from the RVB replicase (ON165241) and CP (ON165240) showed 93.9% and 97.0% nt identity with an RVB isolate reported in the USA (MT473961). On the other hand, sequences from RNA1 (ON165238), RNA2, (OP413436), and RNA3 (ON165239) of ApMV had 99.2%, 89.2%, and 99% nt identity, respectively. Finally, the four symptomatic plants were individually tested by RT-PCR to identify RVB and ApMV. Interestingly, both viruses were detected in all the plants analyzed. ApMV (genus Ilarvirus) is associated with mosaic and mottling symptoms in rose (Thomas, 1984). It has been accepted that ApMV is present in rose plants in Mexico (Cardenas-Alonso, 1994), with no evidence to confirm it. RVB was identified in rose in USA, and this virus was classified as a new species of the genus Carlavirus (Diaz-Lara et al., 2021). In addition to RVB, rose virus A and rose virus C have also been reported in rose; however, the symptomatology linked to these viruses is unknown (Xing et al. 2021; Diaz-Lara et al., 2020). Recently, RVB and ApMV were reported in rose plants in Taiwan (Chen et al., 2022). To our knowledge, this is the first report of RVB and ApMV in a mixed infection in rose in Mexico.

First Report of Phytophthora ramorum Causing Leaf Spots on Cornus capitata (Evergreen Dogwood) in United States.

Cornus capitata Wall. ex Roxb. (evergreen dogwood) is a bushy evergreen tree or shrub native to East Asia grown for its showy creamy bracts in late spring followed by attractive red fruit. In Feb 2023, a sample of foliage with leaf spots and tip dieback from C. capitata 'Mountain Moon' was submitted from a Humboldt Co. nursery as part of a CDFA inspection program for Phytophthora ramorum. The leaf spots were medium to dark brown, irregularly shaped, and ranged from 5 to 8 mm in diameter. They were located primarily along the leaf midrib and covered up to 1/4 of the leaf surface. Six 6-mm-diameter leaf discs taken from the margins of brown lesions and tip dieback were plated on Phytophthora selective CMA-PARP (PARP) media (Jeffers and Martin 1986). After 6 to 10 days, colonies resembling P. ramorum, with coralloid coenocytic hyphae, chlamydospores, ellipsoidal semi-papillate and caducous sporangia, and a relatively slow growth rate were recovered. Abundant sporangia formed on agar singly or in clusters on sympodially branched sporangiophores (n = 50), varying in size from 35 to 60 µm × 20 to 30 µm (mean 45.6 × 24.8 µm) with a length/breadth ratio ranging from 1.3 to 2.3 (mean 1.8). Chlamydospores (n = 50) ranged from 35 to 62 µm in diameter (mean 51.9 µm) on 14-day-old PARP cultures. The internal transcribed spacer region (ITS) using primers ITS5/ITS4 (White et al. 1990; accession no. OR636225) and cytochrome oxidase subunit 1 region (cox1) using primers OomCox1Levup/Fm85mod (Robideau et al. 2011; OR635665) of one isolate (0254-32A) were amplified and sequenced. BLAST analysis showed 100% identity of both regions to P. ramorum ex-type strain (MG865581 and MH136973). Microsatellite loci placed the P. ramorum isolate in the NA2 clonal lineage (Goss et al, 2011). Pathogenicity of P. ramorum isolate 0254-32A was tested using five C. capitata plants (2.5-year-old, 28-cm-tall, 3.78-liter pot). Zoospore inoculum was produced as described in Blomquist et al. (2021). Above ground parts of each plant were sprayed with inoculum (15 ml, 1.3 × 105 zoospores/ml). Inoculated plants were incubated in a dew chamber in the dark at 23°C for 72 h and then placed in a 23±1°C growth chamber with a 12-h photoperiod. Five control plants were treated as above but with sterile water instead of the zoospore suspension. Two days after inoculation, brown spots were visible on leaves on all inoculated plants, initiating from where the drops of inoculum had persisted. After 3 days, brown lesions, from water drop- to majority of entire leaf-sized, were observed on approximately 75% of inoculated leaves. After 6 days, lesions expanded to the edges of leaves, causing leaf curling and defoliation. Lesions stopped expanding after 3 weeks, and by 4 weeks, most infected leaves had abscised, with no new infections observed. Phytophthora ramorum was consistently isolated from foliar lesions of inoculated plants on PARP. It was not isolated from leaf or stem tissues of control plants, which remained asymptomatic during the 4-week experiment period. Phytophthora ramorum was detected on C. capitata in the UK in 2015 (DEFRA 2015). To our knowledge, this is the first report of P. ramorum infecting C. capitata in the United States and the completion of Koch's postulates on any Cornus spp. Incidence on C. capitata in the California nursery was low. However, their proximity to other infected foliar hosts suggests Cornus spp. may present a potential risk for the spread of P. ramorum.