First report of Phyllachora maydis causing tar spot on corn in Delaware

In October 2023, lesions consistent with descriptions of tar spot (Phyllachora maydis) were observed on corn (Zea mays) in Kent and Sussex County, Delaware (DE). Black, raised stromata were observed on leaves of commercially grown corn hybrids. Plants were at physiological maturity and disease severity was low with symptoms present on 1 to 10% of plants. In collected tissue, individual leaf severities ranged from 1 to 3% of leaf area with lesions. Hyaline conidia measuring approximately 15.5 µm in length and 0.5 µm in width were observed microscopically (n=5). Stromata were excised and sterilized in a 0.825% sodium hypochlorite solution for 30 s, rinsed in sterile deionized water for 30 s, and dried on a sterile paper towel for 30 s. Tissues were ground in a 1.5 mL microcentrifuge tube with a sterile plastic pestle. DNA was extracted using a DNeasy Plant Mini Kit (Qiagen). DNA was amplified at the internal transcribed spacer (ITS) region with ITS4 and ITS5 primers using polymerase chain reaction (PCR). NCBI BLAST search results yielded 100% sequence homology and 100% query cover (350/515 bp) to P. maydis accession MG881848.1 (Moura et al. 2023). Koch's postulates could not be completed due to the obligate nature of P. maydis. Tarspot was initially discovered in the United States in 2016 in Indiana and Illinois (Ruhl et al. 2016).This is the first report of tar spot on corn in DE. Yield losses from P. maydis can range depending on time of infection, environmental factors, and hybrid susceptibility and have been recorded up to 100% (Rocco da Silva et al. 2021). Because the disease did not enter the area until the end of the season, no yield impact was observed for 2023. Monitoring for the progression of disease will be crucial for future seasons (Telenko et al. 2020). High humidity and moisture levels favor disease development. Approximately half of DE corn acreage is irrigated due to sandy soils, current irrigation timing strategies may need to be reevaluated. Fungicide efficacy trials for management of tar spot have been conducted in other regions, but continued research will be needed to assess management options and optimize application timing for farmers in DE and the Mid-Atlantic region.

Anthracnose of Macleaya cordata Caused by Colletotrichum aenigma in China

Macleaya cordata (Willd.) R. Br. is a perennial herbaceous medicinal plant (Papaveraceae) commercially cultivated in China which has been studied for detumescence, detoxification, and insecticidal effect (Lin et al. 2018). In August 2021, anthracnose was observed in 2-year-old M. cordata plants in Benxi county, northeast China (41°45'48″N, 123°69'15″E). Dozens of irregular reddish-brown spots (3-11 mm) were observed on each diseased leaf. The lesions were covered with a layer of gray-white mycelia. As the disease progressed, the spots became necrosis and perforation or they would merged into large lesions, ultimately resulting in wilted leaves (Fig. 1). More than 33% of the plants in a 16-ha field were infected in 2021. The diseased leaves were collected and cut into 3-8 mm pieces, surface-disinfested by immersing them into 1% NaOCl for 2 min, and rinsed three times with sterile distilled water. They were then dried with sterilized absorbent paper, placed on PDA medium amended with chloramphenicol (40 mg/L), and incubated in darkness at 25°C with a 12-h photoperiod. Twenty isolates (BLH1 to 20) were obtained and purified using a single-spore method. Isolate BLH12 was identified and used for the pathogenicity test. Colonies were sparsely fluffy with smooth edges, and gradually became gray to pale orange from the initial white. The underside of the colonies was pale orange towards the center. Conidia were single-celled, cylindrical, and transparent with broadly blunt ends, measuring (15.13 ± 1.14) × (5.80 ± 0.60) μm (n=50). Appressoria were single-celled, brown-to-dark brown, usually elliptical or irregular, and sometimes lobed. Setae were not observed. The isolate was initially identified as Colletotrichum gloeosporioides complex (Prihastuti et al. 2009). The identification was confirmed as described previously (Weir et al. 2012). The rDNA internal transcribed spacer region (OP415560), the glyceraldehyde-3-phosphate dehydrogenase (OP433642), chitin synthase (OP433643), calmodulin (OP433644), actin (OP433645), glutamine synthetase (OP433646), β-tubulin (OP433647), and superoxide dismutase (OP433648) gene sequences were obtained (Carbone & Kohn 1999; Weir et al. 2012), and BLAST searches revealed 99-100% homology with the type culture ICMP 18608 (JX010244, JX010044, JX009683, JX009443, JX009744, JX010078, JX010389, and JX010311). A phylogenetic analysis of combining all loci indicated BLH12 and the type strain of C. aenigma were clustered in one group (Fig. 2). Based on the basis of morphological characteristics and phylogenetic relationships, BLH12 was identified as C. aenigma. For the pathogenicity test, healthy 2-year-old plants were sprayed with a BLH12 spore suspension (1 × 105/mL). Control plants were sprayed with sterile water.There were three replicates (five plants each) per treatment. All plants were incubated at 25°C (12-h photoperiod and 86% relative humidity) and examined after 7 days. The experiment was repeated twice. The inoculated plants showed lesions on the leaf surface, similar to those in the field, whereas the control plants were asymptomatic. The pathogen was successfully reisolated and identified as the methods mentioned above. This fungus reportedly infects the leaves of many woody plants in China (Wang et al. 2020; Zhang et al. 2021). This is the first report of C. aenigma causing anthracnose on M. cordata, which will provide an guideline for developing effective field control practices for the disease.

First report of Xanthomonas campestris pv. campestris causing black rot on oilseed rape (Brassica napus L.) in France

In October 2022, v-shaped necrotic lesions were observed on the leaf margins of field-grown winter oilseed rape (WOSR), Brassica napus L., in western France (Ille-et-Vilaine (35) and Maine-et-Loire (49) departments). Disease incidence on volunteers and cultivated WOSR was generally low (5-10 %) but occasionally up to 80% on some fields. Leaf sections sampled from the margin of necrotic leaf tissue were dilacerated in sterile deionized water and the extract was spread onto tryptone soya agar (TSA) with cycloheximide (100 mg.L-1) and Polyflor (Syngenta, France) (2ml.L-1, containing 5 mg.L-1 propiconazole) then incubated at 28°C for 2 days. Colonies were yellow-pigmented, mucoid, and convex, which are morphological characteristics of Xanthomonas spp. colonies. The partial fyuA and gyrB gene sequences were amplified for eight isolated strains (CFBP 9155, CFBP 9156, CFBP 9157, CFBP 9158, CFBP 9159, CFBP 9161, CFBP 9162, and CFBP 9163) using primers of Fargier et al. (2011), and sequenced (Genoscreen, France). The sequences were deposited under numbers OR232891 to OR232898 for fyuA and OR634932 to OR634939 for gyrB. BLASTN analysis of the sequenced fyuA amplicon showed 100% identity and query coverage with the fyuA fragment of Xanthomonas campestris pv. campestris (Xcc) CFBP 6865R (Bellenot et al., 2022). BLASTN analysis of the sequenced gyrB amplicon showed two allelic forms: one showed 100% identity and query coverage with the gyrB fragment of Xcc strain CFBP 6865R (Bellenot et al., 2022), the other one showed 100% identity and query coverage with the type strain Xcc CFBP 5241 (ATCC33913) (Vorhölter et al., 2003). Moreover, two qPCR tools were used to identify the strains successfully as Xcc (Köhl et al., 2011; Rezki et al., 2016) which target the same gene encoding a hypothetical protein and whose primers overlap. The pathogenicity of the eight isolated strains was validated using a bacterial suspension (108 CFU.ml-1) for i) leaf spraying until runoff onto the leaf surfaces of WOSR plants previously maintained at saturated humidity for 48 hours, ii) wound-leaf inoculation of the two youngest true leaves with scissors that had been dipped into the bacterial suspension. Both tests were performed on 3-week-old WOSR plants of the Aviso (INRAE) genotype. Deionized water was used as negative control. Strains CFBP 5241 and the strain CFBP 4954 (Fargier et al., 2007) were used as positive controls for disease expression. Tested plants (seven for spray inoculation and four for wound-leaf inoculation per strain and control condition) were incubated in a greenhouse at 20°C/24°C (night/day). Isolated strains and the strain CFBP 4954 caused yellow lesions with both inoculation methods that necrotized starting about 10 days post inoculation (dpi). The spots coalesced within 14 dpi to form necrotic areas. The type strain CFBP 5241 caused mild symptoms, with only yellow lesions that did not coalesce. Plants inoculated with water remained symptomless. To complete Koch's postulate, re-isolations were achieved. Re-isolated strains on TSA showed the same colony morphology as described above. All re-isolated strains were identified as Xcc based on partial gyrB sequencing and Xcc specific qPCR test (Rezki et al., 2016). This first report in France and the recent identification in Serbia (Popović et al., 2013) may illustrate the emergence of the disease on this crop in Europe. The prevalence and consequences of this disease should be evaluated over a wider geographic area.

First Report of Leaf Spot Caused by Paramyrothecium foliicola on Peanut in China

Peanut (Arachis hypogaea) is an important economic and oil crop in China. In September 2022, leaf spots were observed on peanut in Luoyang city, Henan province, China (34°49'N, 112°37'E). The disease occurred on about 30% of the peanut leaves in only one 0.5-acre field. Symptoms appeared primarily as brown spots, that varied in shape, and appeared round, oval or irregular. In addition, some disease patches exhibited a concentric ring pattern. Small pieces (5×5 mm) of five diseased leaves were surface disinfected in 3% NaClO for 2 minutes, rinsed three times in sterile distilled water, dried on sterilized filter paper, and cultured on potato dextrose agar (PDA) at 25°C for 3 days. Five isolates with uniform characteristics were obtained and subcultured by transferring hyphal tips to fresh PDA. The colonies of the isolates were circular and the margins were clean. The colonies showed white coloration, and after 5-7 days of incubation on PDA plates, concentric rings with dark green sporodochia appeared on the surface of the colonies. The conidiophores branched repeatedly. The conidiophore stipes unbranched, hyaline, 10.0 to 23.2×1.5 to 3.3 μm (n=50). The conidia were rod-shaped or long oval and single-celled, measuring 4.6 to 8.6×1.4 to 3.1 μm (n=100). Based on these characteristics, the five isolates were identified as Paramyrothecium foliicola (Lombard et al 2016). Genomic DNA was extracted from the representative isolates LH-1-1 and LH-1-2. The internal transcribed spacer (ITS), RNA polymerase II second largest subunit (RPB2), calmodulin (CmdA), and translation elongation factor 1-alpha (tef1) loci were amplified and sequenced using the following primer pairs: ITS1/ITS4 (White et al. 1990), RPB2-5F2/RPB2-7cR (O'Donnell et al. 2007), CAL-228F/CAL-2Rd (Carbone & Kohn 1999), and EF1-728F/EF2 (O'Donnell et al. 1998), respectively. BLASTn analysis revealed that the sequences of ITS (OR352397.1 and OR417392.1), RPB2 (OR413573.1 and OR420678.1), CmdA (OR413572.1 and OR420677.1), and tef1 (OR413574.1 and OR420679.1) had 99 to 100% (553/558 bp, 721/721 bp, 597/598 bp, and 384/389 bp) similarity to P. foliicola (MN593634.1, MN398038.1, OM801785.1, MK335967.1). A phylogenetic tree based on the Maximum Likelihood method also confirmed that the two isolates converge on the same branch as P. foliicola. Pathogenicity tests were performed using leaves of 60-day-old peanut plants (cv. Zhonghua 8). Briefly, uninfected healthy leaves (non-wounded) were inoculated with 30-µl drops containing a spore suspension (5×105 conidia/ml) of LH-1-2, and peanut leaves inoculated with sterile distilled water served as controls. All treatments were incubated in an incubator at 25℃ and high relative humidity with a 12:12 hour light-dark cycle. After 5-7 days, inoculated leaves showed symptoms similar to those observed in the field, while no symptoms were observed on control leaves. The pathogenicity tests were repeated three times. The fungus was reisolated from the infected leaves and identified as P. foliicola based on morphological and molecular characteristics, thus fulfilling Koch's postulates. P. foliicola has previously been reported to cause leaf spot of tomato and mung bean, stem canker of cucumber (Huo et al. 2022; Sun et al.2020; Huo et al. 2021). To our knowledge, this is the first report of P. foliicola causing leaf spot on peanut in the world. Identification of this pathogen will be helpful in monitoring peanut diseases and developing disease control strategies.

First report of anthracnose caused by Colletotrichum kahawae on Hypericum chinensis in China

Hypericum chinensis is growing in popularity amongst consumers in cut-flower and pop-flower market as an ornamental woody plant for its florid berry and colorful flower. In August 2019, a new leaf spot disease was observed on H. chinensis in three commercial nurseries in Kunming (25°05'N, 102°72'E), Yunnian province, China. Disease symptoms were observed on approximately 40% of the plants one year after planting and 30% of the leaves were infected. Leaf symptoms began as small, water-soaked lesions on young leaves which later became larger, dark brown and necrotic. The lesion size ranged from 0.2 to 2.8 cm in diameter. For pathogen isolation, three samples of symptomatic leaves were collected from four different nurseries. The leaves were cut into 0.5 mm pieces, surface sterilized using 70% ethanol for 30 s, and 3% NaOCl for 5 min, rinsed three times in sterilized distilled water and plated on potato dextrose agar (PDA) (Zhou et al. 2023). The plates were incubated at 26°C in the dark for 3 days. Eight isolates with comparable morphological characteristics were obtained. Initially, colonies produced pale gray to white aerial mycelia, turning dark gray after 5 days. The isolates produced hyaline, single celled, straight and cylindrical conidia, with mean size 9.7 to 14.8 μm long × 3.7 to 5.6 μm wide (n = 100). Morphological characteristics were consistent with Colletotrichum sp. (Bailey and Jeger 1992). For molecular analysis, genomic DNA was extracted from three representative isolates (XSD1, XSD3 and XSD5), amplified using the primers ITS1/ITS4 (Yin et al. 2012) and T1/Bt2b (Glass and Donaldson 1995) and submitted to sequencing (Weir et al. 2012). DNA sequences of the isolates XSD2, XSD3 and XSD8 were identical. DNA sequences of a representative isolate XSD2 were deposited in GenBank (accession no. MW202334 for ITS, and OR347007 for TUB 2). MegaBLAST analysis of the ITS and TUB2 sequences showed 99.5% and 99.3% similarity with C. kahawae strain ICMP 18539 (accession no. NR_120138.1 for ITS) and strain IMI319418 (JX145227.1 for TUB 2). Pathogenicity tests were conducted by inoculating the pathogen on healthy mature leaves of H. chinensis in the field. Ten leaves (two leaves/plant) were inoculated by spraying conidial suspension (106 spores/ml) of isolates XSD1, XSD3 and XSD5, and covered with plastic bags to maintain high humidity for 48 hours, respectively. Leaves treated with sterile distilled water served as a control. All inoculated leaves showed symptoms similar to those observed in the field at 23±5°C 10 days after inoculation. No symptoms developed on non-inoculated leaves. The pathogen was re-isolated from inoculated diseased leaves and identified as C. kahawae based on morphological and molecular characters. C. kahawae has been reported to cause leaf spot on cultivated rocket in Italy (Garibaldi et al. 2016), and anthracnose disease on tree tomato in Colombia (Rojas et al. 2018), to our knowledge, this is the first report of C. kahawae causing anthracnose on H. chinensis worldwide. Due to important ornamental and economic value of H. chinensis, the distribution of C. kahawae needs to be investigated and monitored for effective disease management strategies to be developed.

First report of Diplodia quercivora causing branch cankers on declining chestnut oak (Quercus montana) in Virginia

Since the beginning of the twentieth century oak decline has been documented in central and eastern hardwood forests of the United States as a stress-mediated disease (Oak et al. 2016). Opportunistic canker pathogens, including Diplodia corticola, D. quercivora, D. sapinea, and Botryosphaeria dothidea have been associated with crown dieback of declining oak trees in several mid-Atlantic states (Ferreira et al. 2021). On 02 August 2022, a survey was conducted at two natural hardwood sites in Fredrick and Shenandoah Counties, Virginia that exhibited symptoms of decline (Fig. 1A). At both sites, mature Quercus montana trees were observed with bole and branch cankers, bleeding and sooty lesions, and discolored sapwood. Pycnidia were present on the margin of seven branch cankers from three trees that were felled, with hyaline, elliptical to oblong conidia 19.0 - 26.8 × 8.5 - 11.2 µm (n = 40) in size (Fig. 1C and D). Six cultures were derived from single spores that were placed on PDA medium and incubated for 10 days in the dark at 22 ± 2°C. Additionally, a 4-mm piece of necrotic tissue was selected from the margin of each of the seven cankers, disinfected with 2.5% NaOCl, again with 70% ethanol, and air-dried before being placed on half-strength acidified PDA medium (pH 4.8) and incubated in the dark at 22 ± 2°C. After 5 days, seven colonies from each canker assayed were transferred to full-strength PDA plates and incubated for 10 days in the dark at 22 ± 2°C. Colonies derived from spores and the necrotic wood were morphologically identical, with white, aerial, floccose mycelium that turned dark gray to olivaceous after five days (Fig. 1B). DNA was individually extracted from four, 10-day-old cultures (two from spores and two from wood). Mycelia was harvested with a sterile pin and extracted using a Qiagen DNeasy Plant Pro Kit (Germantown, MD) according to the manufacturer's instructions. A segment of the internal transcribed spacer (ITS), large subunit rRNA (LSU), and translation elongation factor 1-α (tef1) loci were amplified using ITS4/ITS5 (White et al. 1990), LR5/LROR (Vilgalys and Hester 1990), and EF1-728F/EF1-986R (Carbone and Kohn 1999) primer sets, respectively. The PCR amplicons were purified with ExoSap-IT (Affymetrix, Santa Clara, CA) and sequenced at Eurofins (Louisville, KY). The nucleotide sequences were analyzed using Geneious 11.1.5 software (Biomatters, Auckland, NZ). The resulting ITS sequences from the four isolates were identical. A 544-bp, 1131-bp, and 273-bp segment of the ITS, LSU, and tef1 loci from isolate GS22-DSB-17 was deposited into the GenBank database (accessions OQ597712, OQ597714, and OR754429, respectively). A Genbank BLAST analysis revealed that the ITS and tef1 fragments shared 510/516 (99%) and 271/273 (99%) nucleotides with the D. quercivora ex-type BL8 (JX894205/JX894229). Koch's postulates were fulfilled by inoculating five healthy, containerized Q. montana trees (average stem caliper 6.5 cm) with D. qercivora isolate GS22-DSB-17, while five plants were used as controls. After disinfecting the bark with 70% ethanol, a 0.5 mm section of the bark was removed 13 cm above the soil line with a sterile scalpel, and a 0.5 mm agar plug taken from the edge of a 10-day-old PDA culture was placed in the wound with the mycelium facing the cambial tissue, sealed with Parafilm, and maintained at 22 ± 6°C. The same procedure was performed on the control plants using sterile PDA plugs. After six weeks the bark was carefully removed, and all five stems treated with D. quercivora had necrotic lesions with a mean canker linear growth ([length+width]/2) of 15.6 mm from the edge of the wound, which was significantly larger (P = 0.001) than the controls (2.3 mm; Fig. 1E-M). Necrotic stem tissue was sampled as previously described, and the isolate recovered was confirmed as D. quercivora based on morphology and 100% ITS sequence homology to isolate GS22-DSB-17. D. quercivora was not recovered from the control plants. In the United States, D. quercivora has been isolated from declining white oak trees in Maryland, Massachusetts, West Virginia, and Florida (Dreaden et al. 2014; Ferreira et al. 2021; Haines et al. 2019). More surveys are needed to understand the host range and distribution of D. quercivora in the United States, as well as the environmental and site factors that impact oak health and predispose trees to infection from opportunistic cankering pathogens.

First Report of Postharvest Fruit Rot Caused by Botrytis cinerea on Blue Honeysuckle (Lonicera caerulea L.) Fruit in China

Blue honeysuckle (Lonicera caerulea L.) fruit is growing in popularity as a natural, functional 'super fruit', but its storage is challenged by pathogen infection. In June 2022, approximately 30% of 100 kg of blue honeysuckle fruits (cv. Lanjingling) obtained in Harbin, China (128.70°E, 44.87°N) showed postharvest fruit rot symptoms after 15 d of storage at 4°C, leading to whole fruit rotting with gray fungal growth (Fig.1 A). Small (1-2 mm) segments of infected tissue were obtained from 20 randomly selected fruits which were surface sterilized with 75% ethanol for 30 s and 5% sodium hypochlorite (NaOCl) for 3 min, rinsed three times with sterile distilled water, dried in paper towel, and plated in 9 cm Petri dishes containing potato dextrose agar (PDA). Five purified cultures were obtained and their front colonies were dark brown (Fig.1 C) on the PDA plates after 5 d at 25°C (Alam et al. 2019; Riquelme-Toledo et al. 2020). The conidia (n = 50) were single-celled, hyaline, either ellipsoid or ovoid, and measured 7.5-15.0 μm (11.7 μm average) × 6.0-11.4 μm (8.3 μm average). The conidiophores (Fig.1 E) were branched at the apex bearing bunches of conidia resembling grape clusters (Ellis 1971). For molecular confirmation, genomic DNA was extracted from a representative isolate LDGS-3 using the Ezup Column Fungi Genomic DNA Purification kit (Sangon Biotech, Shanghai, China). The internal transcribed spacer region (ITS, GenBank ON952502), heat shock protein (HSP60, GenBank OP039103), the second-largest subunit of RNA polymerase II (RPB2, GenBank OP186114) and glyceraldehyde 3-phosphate dehydrogenase (G3PDH, GenBank OQ658508) genes were partially amplified with the respective primers ITS1/ITS4, HSP60f/HSP60r, RPB2f/RPB2r, and G3PDH-F/G3PDH-R (Staats et al. 2005; White et al. 1990). BLAST analysis revealed that the sequences of the four genes showed 100% homology with the MH782039, MH796663, MN448501 and MH796662 sequences for isolates of Botrytis cinerea. Based on morphology and molecular characteristics, the isolate LDGS-3 was identified as B. cinerea. For pathogenicity, twenty healthy blue honeysuckle fruits (cv. Lanjingling) were superficially sterilized with 75% ethanol and washed with distilled water. Ten inoculated blue honeysuckle fruits, which were injected with 10 μL conidial suspension of isolate LDGS-3 (106 spores/mL) displayed fruit rot symptoms (Fig.1 B) inside 9 cm Petri dishes after 10 d at 4°C, while no symptoms were detected on ten fruits inoculated with sterile distilled water (Alam et al. 2019). The same isolate that was reisolated from infected fruits with the same morphological and molecular traits was also identified as B. cinerea, confirming Koch's postulates. B. cinerea was previously reported in Henan Province, China in hawthorn (Zhang et al. 2018). To our knowledge, this is the first report of postharvest fruit rot caused by B. cinerea on blue honeysuckle fruit in China, which will aid future management of this emerging postharvest disease.

Novel magnesium-copper hybrid nanomaterials for management of bacterial spot of tomato

Bacterial spot of tomato (BST), predominantly caused by Xanthomonas perforans (Xp) in Florida, is one of the most devastating diseases in hot, humid environments. Bacterial resistance to copper-based bactericides and antibiotics makes disease management extremely challenging. This necessitates alternative solutions to manage the disease. In this study, we used two novel hybrid copper and magnesium nanomaterials noted as magnesium double-coated (Mg-Db) and magnesium-copper (Mg-Cu), to manage BST. In in vitro experiments, no viable cells were recovered following 4 h exposure to 500 µg/ml of both Mg-Db and Mg-Cu, while 100 and 200 µg/ml required 24 h of exposure for complete inhibition. In viability assay using live/dead cell straining method and epifluorescence microscopy, copper tolerant Xp cells were killed within 4 h by both Mg-Cu and Mg-Db nanomaterials at 500 µg/ml, but not by copper hydroxide (Kocide 3000). In the greenhouse, Mg-Db and Mg-Cu at 100-500 µg/ml significantly reduced BST severity compared to micron-sized commercial Cu bactericide Kocide 3000 and the growers' standard (copper hydroxide + mancozeb) (P < 0.05). In field studies, Mg-Db and Mg-Cu nanomaterials significantly reduced disease severity in two out for field trials. Mg-Db at 500 µg/ml reduced BST severity by 34% compared to the non-treated control without affecting yield in Fall, 2020. The use of hybrid nanomaterials at the highest concentrations (500 µg/ml) used in the field experiments can reduce copper use by 90% compared to the growers' standard. In addition, there was no phytotoxicity observed with the use of hybrid nanomaterials in the field. These results suggest the potential of novel magnesium-copper based hybrid nanomaterials to manage copper-tolerant bacterial pathogens.

First report of root-knot nematode, Meloidogyne javaniva, infecting Stachys byzantina on São Paulo, Brazil

Stachys byzantina belongs to the Labiatae and is known by the names "peixinho-da-horta" (Brazil) and "lamb's ear" (USA). Its importance is associated with its medicinal properties (Bahadori et al. 2020) and nutritional aspects (Milião et al. 2022). Root-knot nematodes cause severe damage to plants and suppress production. In January 2021, plants of S. byzantina in the municipality of Jaboticabal (21°14'38.7"S, 48°17'10.6"W) showed symptoms of reduced growth, yellowed leaves and the presence of galls in the roots. Initially, samples of roots from a S. byzantina were analyzed at the Nematology Laboratory (LabNema/UNESP), Jaboticabal, Brazil, estimating 20,000 eggs and juveniles of Meloidogyne sp. in 10 g of roots. To confirm the host ability of the species, a pathogenicity test was performed using Koch's postulate. For this purpose, the test was conducted in a greenhouse where 3,000 eggs and second-stage juveniles (J2) were inoculated onto three plants (n=3) of S. byzantina. After 90 days, the inoculated plants showed the same symptoms as those observed in the field. No symptom or nematode was detected in the uninoculated plant (control). Nematodes were extracted from the roots of inoculated plants and quantified. The perineal pattern of females (n=10) (Netscher and Taylor, 1974) and the labial region of males (n=10) (Eisenback and Hirschmann, 1981) were analyzed and compared with the morphological characteristics of the original description of the species (Chitwood, 1949). For analysis based on esterase isozyme phenotype, the α-method of Esbenshade and Triantaphyllou (1990) was used, and females (n=7) were examined. To confirm identification, whole genomic DNA from an adult female (n=1) was extracted using the Qiagen DNeasy® Blood & Tissue Kit and this sample was used for both genetic sequencing and the sequence-characterized amplified region techniques (SCAR). PCR amplifications were performed for the 18s rRNA gene using primers 988F and 1912R from Holterman et al (2006). Our sequence was deposited in GenBank (NCBI) under the identifier OP422209. Finally, species-specific SCAR primers (Fjav/Rjav, Me-F/Me-R, and Finc-F/Finc-R) designed by Zijlstra (2000) were used to identify Meloidogyne spp. Koch's postulate analysis yielded the following results: (n=1) 9,280 eggs and J2 (Reproduction factor, RF = 33.09); (n=2) 111,720 eggs and J2 (RF = 37.24); (n=3) 59,700 eggs and J2 (RF = 19.9) (RF mean = 30.08). The following characteristics were observed in the perineal region of females: Low and rounded trapezoidal dorsal arch with two distinct lateral lines clearly separating the dorsal and ventral arch regions, similar to the morphological features of the species description by Chitwood (1949). Males had a convex labial plate with a non-raised labial disk joining the submedial labia, a non-rugged labial region, the basal tubercles were usually wider than high, and a rounded tail tip (Eisenback and Hirschmann 1981). The α-esterase enzyme profile showed the J3 phenotype typical of M. javanica (Rm [×100] = 46.0, 54.5, and 58.9). The 18s rRNA sequences grouped Meloidogyne sp. with species such as M. enterolobii, M. incognita, and M. javanica. A DNA fragment of about 700 bp was amplified with Mj (Fjav/Rjav) primers, but not with Me (Me-F/Me-R) and Mi (Finc-F/Finc-R) primers, which confirmed the identification of M. javanica. Accurate identification and characterization of the occurrence of new hosts of M. javanica will allow us to determine the range and geographic distribution of the species. This is the first report on the occurrence of M. javanica on S. byzantina in Brazil. This report is important so that management strategies can be applied to prevent the spread of the pest to other areas.

First report of Colletotrichum plurivorum causing anthracnose on Cucumis sativus in Brazil

Cucumbers have great economic and social importance. Annual worldwide production is approximately 80 million tons (FAOSTAT, 2019), 184 thousand tons of which are produced in Brazil (IBGE, 2020). Leaves with symptoms of anthracnose (necrotic brown or angular spots) were observed on cucumber plants grown in organic systems in September 2021, Pernambuco, Brazil (8°7'45''S, 35°16'167''W). About 40% of the plants fields were infected. Samples were collected and fragments were cut from the margins of the symptomatic tissue. The fragments were superficially disinfected with 70% ethanol (30 s) and 2% sodium hypochlorite (2 min), then washed three times with sterile distilled H2O and dried on sterile filter paper. The fragments were placed on potato dextrose agar (PDA) containing chloramphenicol (50 mg/L) and incubated at 28 ± 2 °C for 3 days. From the fungal isolates obtained, a representative specimen of Colletotrichum spp. was isolated, purified by subculturing from emergent hyphae tips and used for morphological characterization, phylogenetic analysis, and pathogenicity testing. The fungus isolated on PDA formed gray to grayish-black colonies with white aerial mycelia after 7 days. Ascomata were globose to subglobose, 120-200 × 100-150 μm in size (n = 10). Setae formed directly on the hyphae. Asci were 50-70 × 10-12 μm in size, 8-spored, unitunicate, thin-walled, and clavate. Ascospores were 14-22 × 4-5 μm in size (n = 30), hyaline, slightly curved to curved with obtuse to slightly rounded ends. Conidia were hyaline, smooth-walled, aseptate, straight, cylindrical, the apex and base rounded, and 12-15 × 5 μm in size, (n = 30). For molecular identification, the nuclear ribosomal internal transcribed spacers (nrITS), actin (ACT), beta-tubulin (TUB), and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) genes were sequenced (Damm et al. 2019). The sequences obtained were deposited in GenBank (nrITS: OP720945, ACT: OP723523, TUB: OP723525, and GAPDH: OP723524). The sequences from the nrITS region, ACT, TUB2, and GAPDH were highly similar to those from C. plurivorum: nrITS - CBS 125474 (539/539 - 100%; NR_160828); ACT - CBS 125474 (270/271 - 99%; MG600925), TUB2 - CBS 125474 (517/518 - 99%; MG600985); and GAPDH - CBS 125474 (197/197 - 100%; MG600781), respectively. Multilocus phylogenetic analysis was performed using Bayesian inference, which showed that the isolate C. plurivorum FPO04 clustered in the same clade as the ex-type of C. plurivorum (CBS 125474). In the pathogenicity test, leaves of five healthy cucumber plants, previously injured in the middle region with sterile needles, were inoculated with 50 µl of a conidial suspension (1 × 106 spores mL -1) prepared from 7-day-old of colonies of C. plurivorum. Sterile distilled water was used as negative controls. The inoculated plants were maintained in a humid greenhouse chamber for 24 hours. After 7 days, the same anthracnose symptoms seen in the field were observed on the inoculated plants. Control plants remained healthy. Colletotrichum plurivorum was reisolated from symptomatic leaves, fulfilling Koch's postulates. This species has been reported from several crops, including Abelmoschus esculentus (okra) (Damm et al. 2019) and Glycine max (soybeans) (Zaw et al. 2019). To our knowledge, this is the first report of C. plurivorum causing anthracnose on cucumber leaves in Brazil. This report lays the groundwork for future studies to determine management practices for control of this disease in C. sativus.

First Report of Clover yellow vein virus Infecting Senna septemtrionalis (Arsenic bush)

Clover yellow vein virus (ClYVV) is a member of the genus Potyvirus, family Potyviridae and was reported to infect many plant species, such as Ammi majus L., Phaseolus vulgaris L., Vicia faba L., Lens culinaris L., Borago officinalis L., Cicer arietinum L., Gladiolous gandavensis L., Glycine max L., Trifolium repens L., and Dendrobium sp. (Irey et al. 2006; Ortiz et al. 2009; Park et al. 2014; Yoon et al. 2022). Senna septemtrionalis (Viv.) H.S.Irwin & Barneby (arsenic bush), a species in the subfamily Caesalpinioideae, is widely distributed in tropical and subtropical regions (Datiles et al. 2022). In June 2021, virus-like symptoms of mosaic, chlorosis, and leaf-curling were observed in arsenic bush in Kunming, Yunnan province, China. Symptomatic leaves were collected from four arsenic bush (SS1-4), and asymptomatic leaves were collected from 3 additional arsenic bush plants (SS5-7) (eXtra S1). To identify the putative causal virus, sap of symptomatic leaves (SS1) was stained with 1 % phosphotungstic acid and observed under a transmission electron microscope (TEM). Potyvirus-like particles (about 750-800 nm  13 nm) were observed from the sample (eXtra S1). Total RNA was extracted from sample SS1 using TRIzol Reagent (Invitrogen, USA) and subjected to the Illumina NovaSeq platform for RNA-Seq. After trimming and quality control of raw data, 24,125,963 high-quality clean reads were assembled into 72,835 Unigenes using Trinity software. BLAST searches indicated that the nucleotide sequence of Unigene c29731 (10,893 nt) and its deduced amino acid sequence shared 82.62% to 96.45% and 92.60% to 99.19% identity with several ClYVV isolates, respectively. Unigene c29731 had the highest coverage ratio (88%) and the highest nucleotide sequence identity (96.45%) with ClYVV isolate IA-2016 (GenBank accession No. MK292120.1). The complete genome of ClYVV SS1 isolate (ClYVV-SS, GenBank accession No. OP868578) was determined using RT-PCR and 5' and 3' rapid amplification of cDNA ends (RACE) (Chen et al. 2001). A total of 224,936 out of 24,125,963 reads were mapped to the ClYVV-SS1 genome, yielding an average depth of coverage of 3,056.823 (min=1, max=7,859) at nucleotides from 1 to 9,324 of ClYVV genome (eXtra S2). BLASTN results indicated that the complete genome of ClYVV-SS1 shared 96.45% nucleotide sequence identity and 99% coverage ratio with ClYVV isolate IA-2016 genome. Phylogenetic analysis showed that ClYVV-SS1 and other ClYVV isolates clustered together (eXtra S2). RT-PCR was performed on samples (SS2-7) using a pair of primers of the coat protein gene (5'- TCCGACAAAGATAAGTTGAATGCTGGTG-3' and 5'-GAATCGTGCTCCAGCAATGTGA-3') designed from multiple sequences alignment (MSA). Using SS1 sample as positive control, amplicons of ~813 bp were obtained from three symptomatic samples (SS2-4) but not the asymptomatic ones (SS5-7). A total of 17 of 20 arsenic bushes developed symptoms of mosaic and leaf-curling approximately two weeks after mechanical inoculation with arsenic bush (SS1) sap, with 10 uninoculated plants used as control (eXtra S1). RT-PCR was performed for all tested plants. 17 symptomatic arsenic bushes tested positive for ClYVV, while all other samples tested negative. This confirmed that the symptomatic arsenic bushes were infected with ClYVV. To our knowledge, this is the first report of ClYVV infecting arsenic bush.

First report of Pantoea anthophila causing shoot dieback disease of Ceylon ironwood (Mesua ferrea Linn.) in Malaysia

Ceylon ironwood (Mesua ferrea Linn.) or Penaga lilin is one of Asia's most popular tropical herbal plants, including Malaysia (Sharma et al., 2017). The trees are cultivated for their aesthetic value and pharmacological properties, especially as traditional remedies for asthma, dermatopathy, inflammation, and rheumatic conditions (Adib et al., 2019). In August 2022, a disease survey was conducted on Ceylon ironwood trees ranging from 5 to 12 years old in Botanical Park, Putrajaya, Malaysia, with 80% exhibiting shoot dieback disease of the 15 trees exhibiting shoot dieback disease. Symptoms include irregular, water-soaked with brown lesions on young leaves and shoots, where the small lesion coalesced and formed broad necrotic regions, subsequently causing dieback and gradual defoliation. Three infected shoots were collected from each tree, excised into small pieces (10 to 20 mm), immersed with 75% ethanol for 3 min, washed with 2% NaOCl solution for 1 min, and rinsed twice for 1 min in sterilized distilled water. A 10 µl aliquot of the sample suspension was streaked onto nutrient agar (NA) and incubated for 24 h to 48 h at 35 °C. A total of 15 isolates with similar morphology were obtained, and each isolate was re-streaked three times to obtain pure colonies that were round, smooth, with irregular edges, and produced yellow pigment in culture. All isolates were Gram-negative, negative for indole production, and utilized glucose, maltose, trehalose, sucrose, D-lactose, and pectin. Three representative isolates (C001, C002, and C003) with similar morphology were selected for further characterization. The total genomic DNA of all isolates was extracted from overnight cultures using Geneaid™ DNA Isolation Kit (Geneaid Biotech Ltd., Taiwan). PCR amplification of 16S rDNA (Zhou et al., 2015) and species-specific infB (Brady et al., 2008) genes was performed, and each of the ~1500 bp and ~900 bp amplicons were sequenced. BLASTn and phylogenetic analyses revealed all isolates were 100% identical to Pantoea anthophila (P. anthophila) LGM 2558 strains (Accession Nos. NR_116749 and NR_116113) for the 16S rDNA gene. They were 99% identical to P. anthophila CL1 strain (Accession Number CP110473) for infB gene. These sequences were later deposited in the GenBank (Accession Nos. OQ772233, OQ772234, and OQ772235 for 16S rDNA gene, and OQ803527, OQ803528, and OQ803529 for infB gene). For the pathogenicity test, healthy Ceylon ironwood seedlings' shoots were inoculated with 10 mL of each isolate suspension (1 x 108 CFU/ml) by spraying the inoculum on the young shoots using a sterilized spray bottle. Control seedlings were inoculated with sterile water. The inoculated shoots were covered with a sealed plastic bag to maintain the moisture and were kept in the greenhouse with temperatures ranging from 26 to 35 °C. The experiments were repeated twice, with three replicates for each treatment. Inoculated shoots showed dieback symptoms like natural infection, including irregular, water-soaked, and brown lesions on leaves and young shoots at 10 days post-inoculation. Control seedlings remained asymptomatic. The pathogen was re-isolated and identified via sequencing of the 16S rDNA and infB genes, thus fulfilling Koch's postulates. Previously, P. anthophila has been reported to cause soft rot in wampee plants in China (Zhou et al., 2015) and leaf blight of cotton in Pakistan (Tufail et al., 2020). To our knowledge, this is the first report of P. anthophila causing shoot dieback disease of Ceylon ironwood trees in Malaysia. Plant disease management strategies need to be established to reduce losses due to P. anthophila infection since the pathogen could limit Ceylon ironwood tree production in Malaysia.

First Report of Calonectria montana Causing Leaf Spot on Ligularia fischeri in China

Ligularia fischeri (Ledeb.) is a perennial herbal plant of Compositae that is cultivated commercially in China as a medicinal, ornamental, and edible plant. Leaf spots were observed in 2-year-old L. fischeri in Benxi County of northeast China, in August 2021. Irregular reddish brown spots ranging from 3 to 11 mm were observed on infected leaves, and each leaf had dozens of spots (Fig. 1). As the disease progressed, the diseased spots withered and the centers fell out, and multiple lesions merge into large diseased spots, causing leaf wilting. The roots and stem bases were not infected during the reproductive stage. More than 37% of the plants in a 18 ha field were infected in 2021. The ten diseased leaves were collected and cut into small (3-5 mm) pieces, which were surface-disinfested by immersing into 1% NaOCl for 2 min and rinsing with sterile distilled water three times. The leaf pieces were then placed on acidified potato dextrose agar (PDA) in petri plates and incubated in the dark at 25°C. Twenty isolates with the same morphological characteristics were obtained. Isolates were further purified by starting a new colony for each isolate from a single spore collected from water agar. Isolate TYTW7 was randomly selected for identification and pathogenicity testing. It grew rapidly and produced profuse aerial mycelia with a carmine red underside. The conidiophores had many fertile branches and formed an elongated stipe with a sphaeropedunculate vesicle at the tip. The one-septate conidia were cylindrical and almost straight with parallel walls and rounded ends. Their sizes ranged from 30.35 to 51.76 × 2.93 to 5.01 μm (n = 100) and the pathogens were initially identified as Calonectria sp. (Crous 2002; Crous et al. 2004; Lombard et al. 2015, 2016). Further confirmation of the identification was determined according to published method (Liu and Chen 2017; Shao and Li 2021). The partial gene regions including the translation elongation factor 1-alpha (GenBank accession no. OP290551), histone H3 (OP290552), calmodulin (OP290553) and β-tubulin (OP290554) were obtained, and BLAST searches showed 99-100% homology with the ex-type culture CERC 8952 (MF527049, MF527065, MF527081 and MF527107) and phylogenetic analysis combining all loci revealed that the isolate TYTW7 and the type strain of Ca. montana clustered in one group (Fig. 2). Based on morphological characteristics and phylogenetic analysis, isolate TYTW7 was identified as Ca. Montana. Healthy 2-year-old plants were used for the pathogenicity test. A spore suspension (1×105 spores/mL water) was used to inoculate three host plants; sterile water was sprayed on the same number plants serving as a control. The experiment was repeated three times. All plants were incubated at 27±2°C (12h photoperiod) and were evaluated after seven days. The inoculated plants showed lesions on the leaf surface, similar to those in the field, and the control remained symptomless. The pathogens were successfully reisolated and identified by sequencing, and no pathogens were isolated from symptomless control plants. To our knowledge, this is the first report of Ca. montana causing L. fischeri leaf spot. The disease poses a threat to the production and more control strategies are needed on management options to minimize losses.

First report of Diplodia bulgarica causing black canker on apple in California

California is the sixth largest apple-producing state in the United States with a production that reached 4,654 ha in 2021. During the late winter of 2023, black canker symptoms were observed on branches of 'Gravenstein' apple (Malus domestica) in two commercial orchards in Sonoma County, California. The prevalence of symptomatic trees ranged from 10 to 30%. External symptoms included charcoal looking-cankers with the bark peeling off from the primary and secondary branches. Internally, cankers were dark brown in color with a hard consistency. Pycnidia were observed on the surface of older cankers. Fungal isolations were performed from disinfected (70% ethanol, 30 s) symptomatic branch samples (n = 15). Small wood pieces (5 mm length) were taken from the margin of diseased and healthy tissues, and placed on potato dextrose agar acidified with 92% lactic acid at 0.5 mL per liter (APDA). Plates were incubated at room temperature (20-22 °C) for 7 days. Colonies of Botryosphaeriaceae species (Phillips et al. 2013) (n = 12) were consistently recovered and pure cultures were obtained by transferring a single hyphal tip onto fresh APDA. Colonies were light gray with irregular margins. To induce pycnidia formation, two isolates (UCD11350 and UCD11351) were grown on pistachio leaf agar for 21 days. Conidia (n = 50) were thick-walled and ovoid in shape, initially hyaline, then turned pale brown and dark brown at maturity, and some of them became 1-septate, ranging from 18.9 to 24.0 (21.9) × 11.5 to 14.7 (13.4) µm. Isolates were identified by sequencing a partial region of the beta-tubulin (tub2) gene using the primers Bt2a/Bt2b (Glass and Donaldson 1995). BLAST searches on NCBI GenBank revealed 99.5 % identity with the Diplodia bulgarica ex-type (CBS 1245254). To confirm the identity, the rRNA internal transcribed spacer (ITS) and the translation elongation factor 1-alpha (tef1) were also sequenced using ITS5/ITS4 (White et al. 1990), and EF1-688F/EF1-1251R (Alves et al. 2008), respectively. A maximum parsimony multi-locus phylogenetic analysis clustered Californian isolates with reference strains of D. bulgarica. Sequences were deposited in GenBank (nos. OR631209 to OR631210, OR637361 to OR637362, OR637363 to OR637364 for ITS, tub2, and tef1, respectively). Pathogenicity tests were conducted on 2 to 3-year-old branches (n = 5) of over 20-year-old trees by inserting a 5-mm segment of a toothpick, completely colonized with each of the two isolates mentioned above, into a 1-mm-diameter hole made with a sterile drill bit. The same number of branches where mock inoculated with a non-colonized toothpick as negative control. The experiment was performed twice. After ten weeks, inoculations resulted in dark brown necrotic lesions that ranged from 54.0 to 59.8 mm in length. Negative controls remained asymptomatic. Koch's postulates were fulfilled by successfully recovering the isolates from the lesion margins, which were confirmed by morphology. Diplodia bulgarica was first described affecting M. sylvestris in Bulgaria (Phillips et al. 2012), and then detected on M. domestica causing cankers in Iran (Abdollahzadeh 2015), India (Nabi et al. 2020), Germany (Hinrichs-Berger al. 2021) and Türkiye (Eken 2021). The pathogen was also identified causing postharvest fruit rot (Eken 2022). To our knowledge, this is the first report of D. bulgarica causing branch canker on apple in California, which provides important information for developing detection and control strategies.

First Report of Leaf Spot Disease on Pineapple Caused by Fusarium solani in China

Pineapple (Ananas comosus) is an economically important tropical fruit in Guangdong Province, China. The plants were seriously infected with a year-round leaf spot disease. During September to November 2022, the leaf spot disease of pineapple was found in Xuwen city and Zhanjiang city of Guangdong Province. A disease survey of 1 ha revealed that pineapple was affected at an incidence ranging from 30% to 50%. The disease caused economic loss to control plant diseases with chemicals. The initial symptoms were observed after 1 month of planting in October and included yellow spot and developed brown necrotic lesions. The leaves of pineapples showed symptoms of Large brown necrotic lesions appear on leaves especially on the tip of basal leaves. The diseased leaves were collected and surface-disinfested in 1% NaClO for 2-3 m, rinsed with sterilized water, air dried, placed on potato dextrose agar (PDA) medium, and incubated for 3 to 5 days at 28°C. Two isolates (PLF1 and PLF2) were collected and purified using the single-spore method. Colonies developing on PDA were in a circle with abundant white, densely fluffy aerial mycelium, pale to colorless after 3 d and pale orange 5-15 d later. Cultures of the isolates produced macroconidia which were falcate, 1-3-septate, hyaline, 18.2-43.4×4.8-6.8 µm(n=50). Cultures of the isolate also produced large amount of conidia which were hyaline, oblong, no septate, 5.2-10.6×2.7-5.2 µm (n=50). These characteristics were consistent with the description of Fusarium sp. (Chitrampalam et al. 2018). For molecular identification, the genomic DNA of the 2 isolates was extracted. The fragments of internal transcribed spacer (ITS), translation elongation factor 1α (EF1α) and β-tubulin were amplified and sequened using the primer pairs of ITS4/ITS5, EF1/EF2 (O'Donnell et al. 2008) and T1/T2 (O'Donnell et al. 1997). These sequences were deposited in GenBank (OR501466, OR501467 for the ITS; OR499874, OR499875 for elongation factor; OR499876, OR499877 for β-tubulin). Phylogenetic trees were constructed in MAGA 11 using the Maximum likelihood (ML) method based on the concatenated sequences of ITS, EF1α, and Tublin (Figure 1). The 2 isolates were grouped with F. solani A01-1 (GCA_027945525.1) with a bootstrap value of 100 in the phylogenetic tree. The morphology and multi-gene phylogenetic analysis indicated that the new isolates are F. solani. The 2 isolates were selected for pathogenicity tests to fulfill Koch's postulates. Six plants at seven- to ten-leaf stage were inoculated with each isolate separately. Three sites of each leaf were wounded with a sterile needle and covered with a piece of cotton drenched with 200 µl spore suspension (107 spores/ml) from each isolate cultured in PD medium. Leaves inoculated with PD medium served as negative controls. Inoculated plants were placed in an incubator at 28°C, and 80% humidity under a 12-h light/dark cycle for 7 days. After 7 days of incubation, necrotic spots were observed in all the inoculated plants except the negative control. The pathogenicity tests were conducted three times with similar results. The strains were then reisolated from the lesions and found to be Fusarium solani as those of the inoculum. F．ananatum， F. guttiforme and F. subglutinans have been reported to infect all parts of pineapplefusariosis disease (Jacobs et al. 2010; Stępień et al. 2013; Ventura et al. 1993). To our knowledge, this is the first report of fusariosis on Pineapple caused by F. solani. Identification of F. solani as a disease agent on pineapple will assist in disease management for this important fruit tree.

Occurrence of Neofusicoccum parvum Causing Canker and Branch Dieback of European Hazelnut in Maule Region, Chile

The European hazelnut (Corylus avellana) is an important fruit crop cultivated in Chile, with over 17,000 ha planted (46%) in the Maule region, central Chile. During a routine orchard survey in seasons 2020-2021 and 2021-2022, in the Maule region, canker and dieback symptoms were observed in two commercial orchards of European hazelnut cv. Tonda Di Giffoni in San Rafael (8-year-olds) and Linares (15-year-olds), with an incidence between 10% and 36%, respectively, based on external symptoms. Twenty symptomatic branches exhibiting cankers, reduced vigor, wilting, twig death, and dieback, were collected. A cross-section of diseased branches revealed mostly brown V or U-shaped cankers of hard consistency. Branches were cut, and pieces of cankers were surface sterilized in 96% ethanol for 3 s and briefly flamed. Small pieces of wood (5 mm2) from the edge of cankered tissues were placed on Potato Dextrose Agar (2% PDA) amended with 0.1% Igepal CO-630 and incubated at 25°C for five days in the dark (Díaz and Latorre 2014). Pure cultures were obtained by transferring a hyphal tip from growing colonies to fresh PDA media. Eight pure cultures (NP-Haz01 to NP-Haz08) developed dark to olive-brown fast-growing colonies with scarce aerial mycelium after seven days at 25°C on PDA under near-UV light. These isolates showed a dark-olive color on the reverse side of Petri dishes and developed abundant, aggregated, and dark-brown globose pycnidia after 21 days at 25°C. Conidia were hyaline, aseptate, ellipsoidal, densely granulate, externally smooth, and thin-walled dark, that measured (9.5-) 15.5 ±1.2 (-17.3) x (5.1-) 7.2 ± 0.6 (-9.1) µm (n = 30), with a length/width ratio of 2.15. These isolates were tentatively identified morphologically as Neofusicoccum sp. Molecular identification was performed using ITS1/ITS4, Bt2a/Bt2b and EF1-728F/EF1-986R primers of the internal transcribed spacer (ITS1-5.8S-ITS2) region, a portion of the beta-tubulin (BT) and part of the translation elongation factor (EF1-) genes, respectively (Dissanayake et al. 2015). A MegaBlast search in GenBank showed a 99% similarity to isolate CMW9081, the ex-type of Neofusicocum parvum (Pennycook & Samuels) Crous, Slippers & A.J.L. Phillips. The sequences were added to GenBank (OR393855 to OR393857 for ITS; OR400688 to OR400690 for BT; OR400691 to OR400693 for EF1-). Pathogenicity of three isolates (NP-Haz02, NP-Haz04, NP-Haz09) was studied on freshly made pruning wounds on attached branches of 3-year-old and one-year-old of European hazelnut cv. Tonda Di Giffoni in the San Rafael field. Fifteen pruning wounds were inoculated with 40 µL conidial suspension (105 conidia/mL) of each isolate of N. parvum. Sterile distilled water was used as a control treatment (n=15 branches) for branches of 3-year-olds and one-year-olds. Both pathogenicity tests were repeated once. Attached branches of 3-year-olds (6 months of incubation) and one-year-olds (4 months of incubation), developed necrotic streaks and cankers with a mean length of 33 to 82 mm and 25 to 51 mm, respectively. No necrotic streaks were observed in the branches treated with water. Neofusicoccum parvum was reisolated only from symptomatic tissues of inoculated branches, and morphological and molecularly (EF1-) identified, thus fulfilling Koch's postulates. Previously, other Botryosphaeriaceae spp. as Diplodia coryli (Guerrero and Pérez 2012) and D. mutila (Moya-Elizondo et al. 2023) have been obtained from canker and dieback of hazelnut in Chile. Recently, N. parvum was reported causing nut rot in hazelnuts in Italy (Wagas et al. 2022). To our knowledge, this is the first report of N. parvum causing canker and branch dieback of hazelnut trees in Chile and worldwide.

First Report of Powdery Mildew Caused by Podosphaera xanthii on Phasey Bean (Macroptilium lathyroides) in China

The forage legume phasey bean Macroptilium lathyroides (L.) Urb. is an annual or short-lived perennial of the family Fabaceae. It is native to the tropical and subtropical areas from North to South America, and is naturalized throughout the tropics and subtropics of the world (Tobisa and Nakano 2019). It is mainly used for forage, green manure, and slope protection (Silva et al. 2018). In addition, the nitrogen fixation ability of this plant can also improve the soil. In February 2022 and January 2023, powdery mildew symptoms were observed on 70% of M. lathyroides 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, 100 to 233 × 8 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 36 to 56 µm long. Conidia (n =100) were ellipsoid-ovoid to doliiform, 24 to 34 ×13 to 20 m (length/width ratio = 1.5 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 HMML-23. To confirm the identification, 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. OR240256). A BLASTn search in GenBank of this sequence showed 100% similarity with the ITS sequences of P. xanthii isolates from China (MT242593, MK439611 and MH143483), Korea (MG754404), Vietnam (KM260704), Japan (MZ604267), and Puerto Rico (OP882310). Additionally, the 28S rDNA region was amplified using the primer pairs NL1 and NL4 (O´Donnell 1993; accession no. OR240255). This region shared 100% similarity with P. xanthii isolates (MK357436, LC371333, OP765401, and MZ604267) as well. To confirm pathogenicity, five healthy potted plants of M. lathyroides 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. This fungus has been reported causing powdery mildew on M. atropurpureum in Thailand (Meeboon et al. 2016). In the United States phasey bean powdery mildew caused by Erysiphe fallax has been previously reported (Poudel and Zhang 2019). To our knowledge, this is the first record of P. xanthii infecting M. lathyroides in China. Over the past 50 years of introduction, phasey bean has become one of the main leguminous forages for establishing artificial mixed seeding grasslands in southern China. We are concerned that the pathogen could become a threat to the widespread planting of M. lathyroides in the future.

First Report of Pseudomonas oryzihabitans Causing Walnut Leaf Spot Disease in China

China ranks first in the production and harvest area of walnut (Juglans regia L.) worldwide. Currently, the poor health and low yield of walnut caused by pathogen infection is of concern. In 2022, severe walnut leaf spot disease was observed on the seedlings of four walnut nurseries (0.08 to 0.23 ha) in Liaocheng, Shandong, China, with an average incidence of 48.6% (from 34.6% to 65.3% on the cultivar Xiangling). From August to October, leaf spots mainly appeared on the edges of the leaflets, and occasionally between veins. The lesions were initially soft and rotten, and then light brown, round to semi-circular. Subsequently, the adjacent lesions fused, and the edges of the leaflets and entire leaflets showed symptoms of browning and wilting. For pathogen isolation, five leaflets with representative symptoms from one of the nurseries were collected and wiped three times with sterile absorbent cotton dipped in 75% alcohol and washed with distilled water. Leaflet pieces at the junction of the lesion and healthy tissues were removed, crushed in a sterile mortar, and soaked in a small amount of distilled water for 10 min. The diseased tissue suspension was streaked on a nutrient agar medium (NA) with a sterile inoculation ring and incubated at 28°C for 24 to 72 h. The bacterial colonies obtained were further cultured on NA. The purified colonies were uniform in shape, round, and yellow, with a raised, shiny surface and smooth margin. The isolates were Gram-negative, and the electron microscope analysis showed that the pathogens were short rods (0.35 to 0.52 × 0.90 to 1.24 μm, average = 0.44 ± 0.05 × 1.08 ± 0.11 μm, n = 25). For bacterial species identification, a single-colony culture was subjected to genomic DNA extraction and gene amplification and sequencing of 16S rRNA, rpoD, and gyrB. The universal primers 27F/1492R (Lane 1991) were used to amplify the 16S rRNA gene and the specific primers 70F/70R and UP-1E/APrU (Yamamoto et al. 2000) were used to amplify the rpoD and gyrB genes, respectively. In the BLAST analysis, the 16S rRNA sequence (GenBank OR195734) of the isolate shared 99% similarity (1409/1410 bp) with Pseudomonas oryzihabitans strain IAM 1568T (AM262973.1), and the rpoD (OR709708) and gyrB (OR709707) sequences showed >98% identity to rpoD (707/717 bp; FN554494.1) and gyrB (787/801 bp; FN554210.1) of P. oryzihabitans strain LMG 7040T. Based on the above results, the isolated bacterium was identified as P. oryzihabitans. For the pathogenicity test, healthy leaflets from 10 two-year-old potted walnut seedlings (cv. Xiangling) were used as inoculation materials. The leaflets were punctured with a sterile inoculation needle of 0.4 mm, and three small holes on each leaflet at an interval of about 5 mm were covered with a piece of sterile cotton. A bacterial suspension (1 ml) at 107 CFU/ml was spread onto the cotton, and wrapped with plastic film for 24 h. Water was used as a negative control. The inoculations were performed five times. Plants were grown outdoors at a daily average temperature of 22°C with relative humidity over 45%. Two days after inoculation, the disease began to develop in the leaflets with similar symptoms to those observed in the field. In contrast, control plants remained healthy and symptomless. Bacteria were reisolated from the inoculated walnut plants, and the morphology and 16S rRNA gene sequences of the isolates were the same as those of the original strains. Since it was discovered as an opportunistic human pathogenic bacterium in the 1970s (Keikha et al. 2019), P. oryzihabitans has also been shown to cause certain plant diseases, such as panicle blight and grain discoloration on rice (Hou et al. 2020), fruit black rot on prickly ash (Liu et al. 2021), and stem and leaf rot on muskmelon (Li et al. 2021). As far as we know, this is the first report of P. oryzihabitans causing walnut leaf spot disease in China. Leaf spot caused by P. oryzihabitans may be a threat to walnut cultivation, and this report of its occurrence is the first step in determining potential spread and effective control measures.

First Report of White Mold Caused by Sclerotinia sclerotiorum on Cabbage in Mexico

The state of Puebla is the main producer of cabbage (Brassica oleracea var. capitata) in Mexico, with an area of approximately 1,858 ha (SIAP 2023). In April 2023, a field sampling was conducted in the San Luis Ajajalpan, Tecali de Herrera (18°55.57'N, 97°55.607'W), Puebla, Mexico. The average temperature was 24°C and the relative humidity was 95% for five consecutive days. Cabbage plants cv. 'American Taki San Juan' close to harvest, with head rot symptoms were found in a commercial area of approximately 3 ha, at an estimated incidence of 35 to 45%. More than 70% of the leaves were symptomatic on severely affected plants. Typical symptoms included chlorosis of older foliage, soft rot with abundant white to gray mycelium, and abundant production of large and irregularly-shaped sclerotia. The fungus was isolated from 30 symptomatic plants. Sclerotia were collected from symptomatic heads, surface sterilized in 3% NaOCl, rinsed twice with sterile distilled water, 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 placed in an incubator at 25°C in the dark. A total of 30 representative isolates were obtained by the hyphal-tip method, one from each diseased plant (15 isolates from sclerotia and 15 from mycelial fragments). After 8 days, colonies had fast-growing, dense, cottony-white aerial mycelium forming irregular sclerotia of 3.75 ± 0.8 mm (mean ± standard deviation, n=100). Each Petri dish produced 14-25 sclerotia (mean = 18, n = 50), after 10 days. The sclerotia were initially white and gradually turned black. The isolates were 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 a CTAB protocol. The ITS region and the glyceraldehyde 3-phosphate dehydrogenase (G3PDH) gene were sequenced for two isolates (White et al. 1990; Staats et al. 2005). The ITS and G3PDH sequences of a representative isolate (SsC.1) were deposited in the GenBank (ITS- OR286628; G3PDH- OR333495). BLAST analysis of the partial sequences ITS (509 bp) and G3PDH (915 bp) showed 100% similarity to S. sclerotiorum isolates (GenBank: MT436756.1 and OQ790148). Pathogenicity was confirmed by inoculating 10 detached cabbage heads of 'American Taki San Juan', using the SsC.1 isolate, according to Sanogo et al. (2015). Heads were placed on the rim of a plastic container and inserted in a moisture box with 2 cm of water on its bottom. The box was covered with a plastic sheet to maintain humidity. The control plants were inoculated with a plug of noncolonized PDA. The inoculated cabbages were covered with white to gray mycelia and abundant sclerotia within 10 days, whereas no symptoms were observed on non-inoculated controls. The fungus was re-isolated from the inoculated cabbages as described above, fulfilling Koch's postulates. The pathogenicity tests were repeated three times. White mold caused by S. sclerotiorum on Brussels sprouts was recently reported in Mexico (Ayvar-Serna et al. 2023). In 2015, S. sclerotiorum was reported on cabbage in New Mexico, causing head rot (Sanogo et al. 2015). To our knowledge, this is the first report of S. sclerotiorum causing white mold on cabbage in Mexico. This research is essential for designing management strategies and preventing spread to other production areas.

First report of stem gray blight on Hylocereus megalanthus and Hylocereus polyrhizus caused by Diaporthe arecae in Brazil

In November 2021, stem gray blight symptoms were seen on two dragon fruit (pitaya) species (Hylocereus megalanthus and H. polyrhizus) in an orchard with 100% disease incidence in Fortaleza, Ceará, Brazil (3°44'24.5"S 38°34'30.8"W). The symptoms were initially yellowish to dark brown lesions, and as the symptoms progressed, the lesions turned grayish with small black pycnidia in the center. Isolation was carried out by disinfecting small pieces of the symptomatic stems in 70% ethanol for 1 min, followed by 1% NaOCl for 1 min, and then rinsed three times with sterile distilled water. Excess water was removed using sterile filter paper. Then the stem fragments were placed on PDA media. Colonies produced small black pycnidia with conidia and some were sterile after 68 days of incubation. Two monosporic isolates were obtained from the colonies: UFCM 0708 from H. megalanthus and the UFCM 0710 from H. polyrhizus, which were used for pathogenicity test, morphological and molecular identification. The colony on PDA was smoke gray with aerial mycelium and the reverse was smoke grey to dark grey. The α-conidia from UFCM 0708 and UFCM 0710 were hyaline, aseptate and fusiform and measured 6.4 to 9.7 (8.0) x 1.2 to 2.4 (1.7) µm and 6 to 13.1 (8.2) x 1.7 to 2.4 (2.0) µm, respectively. The β-conidia from UFCM 0708 and UFCM 0710 were hyaline, aseptate and filiform and measured 15 to 22.5 (18.8) x 0.6 to 1.7 (1.0) µm, and 17.2 to 27.5 (22.3) x 0.5 to 1.0 (0.8) µm (n=30), respectively. This morphology placed the isolates as Diaporthe sp. (Udayanga et al. 2012). For further confirmation, genomic DNA was extracted from the isolates (UFCM 0708 and UFCM 0710), and beta-tubulin (TUB2) and translation elongation factor 1-alpha (TEF1) gene fragments were amplified. BLASTn search results with isolates TEF1 and TUB2 sequences varied from 98.58% to 99.52% identity to the ex-type sequence of Diaporthe arecae (CBS 161.64). Phylogenetic analysis of concatenated sequences alignment carried out using the Maxinum-likelihood and Bayesian Inference analysis placed the isolates within D. arecae clade with 86% bootstrap and 0.99 posterior probabilities support. The sequences obtained in this study were deposited in GenBank (TEF1: OP534720 and OP534722; TUB2: OP534717 and OP534719). The isolates were confirmed as D. arecae based on molecular analysis and morphological characteristics (Gomes et al. 2013). Koch's postulates were completed as described by Karim et al. (2019) through the inoculation of six stems of each dragon fruit (pitaya) species. The stems were wounded by removing a 5 mm diameter disc and after that they were inoculated with a 5 mm diameter mycelial plug from 5 days old PDA plates. PDA plugs were used as control. Each stem was covered with a plastic bag and sterilized water was added into the sterilized filter paper to maintain humidity. The bags were kept in a room at day and night temperature of 25 ± 2 °C. The same symptoms seen in the field appeared on the stems 21 days after inoculation. The control stems remained symptomless. Diaporthe arecae have been reported on H. polyrhizus in Malaysia (Huda-Shakirah et al. 2021). To our knowledge, this is the first report of D. arecae on H. megalanthus and H. polyrhizus in Brazil.

First report of Phytophthora infestans lineage EU23 causing potato and tomato late blight in South Africa

In South Africa, potato (Solanum tuberosum) late blight epidemics from 1996 to 2007 were caused by Phytophthora infestans clonal lineage US-1 (McLeod et al. 2001; Pule et al. 2013). Similarly, surveys on tomatoes in the mid-1990s only identified the US-1 clonal lineage in South Africa (McLeod et al., 2001). On potatoes, populations from the Southern Cape and Western Cape regions consisted of persistent mefenoxam-resistant populations (McLeod et al. 2001; Pule et al. 2013). Limited mefenoxam (R-enantiomer of metalaxyl) screening in 2021 in the Western Cape showed that potato isolates were sensitive, which prompted our study. Potato late blight samples were collected in 13 potato fields in the 2021 to 2023 seasons in the Western Cape (n = 4), Free State (n = 7), Limpopo (n = 1) and Kwazulu-Natal (n = 1) Provinces, and one tomato sample in 2022 in the Limpopo Province. Fourteen samples, one per field, were simple sequence repeat (SSR) genotyped for 12 loci (Li et al. 2013) using as DNA template, FTA cards, or genomic DNA extracted from cultures. P. infestans isolations from lesions and DNA culture extractions were conducted as previously described (Pule et al. 2013). SSR genotyping revealed that all 14 P. infestans samples belonged to clonal lineage EU_23_A1 (EU23), which has a phenotype (A1 and metalaxyl sensitive) and SSR genotype matching the US-23 lineage (Saville et al., 2021). As expected, minor polymorphisms were detected among the samples at loci Pi02, G11, D13 and SSR4. Mefenoxam sensitivity testing of seven potato isolates from the Free State (n = 3) and Western Cape (n = 4), and one tomato isolate was conducted as previously described (Mcleod et al. 2001). All isolates were sensitive to mefenoxam since no infection and sporulation occurred at 3 µg/ml. This was expected since EU23 has been reported as mefenoxam sensitive in other countries (Kawchuk et al., 2011; McGrath et al., 2015). Replacement of the US-1 clonal lineage by EU23 suggests that the latter lineage is more aggressive or fit than US-1, but this must be verified especially on potatoes. On tomatoes, on the other hand, EU23 is known as a highly aggressive lineage (Kawchuk et al., 2011; McGrath et al., 2015; Saville et al., 2021). Therefore, population displacements may have first occurred on tomatoes from where the lineage spread to potatoes. In the Cape coastal potato production regions, population displacement may have been supported by the withdrawal of mefenoxam/metalaxyl from the region since 1996 because the EU23 lineage is mefenoxam sensitive, as opposed to the previously prevailing US-1 mefenoxam-resistant lineage. More severe potato late blight epidemics has not been observed in recent years in South Africa. However, tomato late blight has increased and is more prevalent in the Limpopo province. The source of the introduction of EU23 into South Africa is unknown. Only test-tube plants and/or greenhouse tubers may be imported into South Africa since 1997. Therefore, the illegal importation of planting material may have introduced the new genotype. Whether this could have occurred from neighbouring African countries is unknown since P. infestans genotyping has not been conducted in these countries. In Africa, EU23 has been reported in northern African countries (Tunisia, Algeria and Egypt) (Saville et al., 2021; El-Ganainy et al., 2023). Mefenoxam and metalaxyl applications will likely be effective again in the Western Cape, but more samples will have to be tested to confirm this. This will provide growers with a more cost-effective fungicide (metalaxyl) since alternative actives with comparable systemic and curative activity are more expensive.

Anthracnose of Brachybotrys paridiformis Caused by Colletotrichum siamense in Northeast China

Brachybotrys paridiformis Maxim. ex Oliv. (Boraginaceae) is a perennial medicinal plant and vegetable that is cultivated commercially in China. Anthracnose is a devastating disease of B. paridiformis, with annual production losses exceeding 33% based on our survey. In July 2021, anthracnose of B. paridiformis was observed on 2-year-old plants in Shenyang city, Northeast China, which is the most important region for B. paridiformis cultivation. Round or irregular-shaped black spots were exhibited on leaves, with the leaf edges most commonly infected. As the necrosis expanded, the leaves withered and dropped; young leaves were generally not infected (Fig. 1). More than 40% of the plants in a 21-ha sampling field were infected in 2021. Symptomatic leaves (n = 20) were collected and the diseased tissue was cut into small pieces, immersed in 1% NaOCl for 2 min, rinsed three times with sterile water, and placed on acidified potato dextrose agar (PDA) in Petri dishes. After a 3-day incubation in darkness at 25 °C, 18 suspected single-pure morphologically identical Colletotrichum isolates were obtained and sequenced. Isolate SQZ9 was randomly selected and identified. Colonies on PDA were initially white, but gradually became pale brownish with a reverse side that was pale yellowish to pinkish. Aerial mycelia were grayish-white, dense, and cottony, with microsclerotia detected on some aging mycelia. The detected single-celled conidia (11.65-17.25 × 4.25-6.15 µm; n = 50) were fusiform to cylindrical with obtuse to slightly rounded ends. Appressoria were ovoid to clavate and medium brown. Setae were not observed. The morphological characteristics were similar to those of Colletotrichum spp. (Prihastuti et al. 2009; Weir et al. 2012). Initial BLAST searches of the GenBank database revealed the SQZ9 rDNA internal transcribed spacer region (OP389109, 566 bp), glyceraldehyde-3-phosphate dehydrogenase (OP407730, 260 bp), chitin synthase (OP407731, 301 bp), calmodulin (OP407732, 712 bp), actin (OP407733, 282 bp), glutamine synthetase (OP407734, 909 bp), β-tublin (OP407735, 498 bp), and superoxide dismutase (OP407736, 396 bp) sequences were respectively 99%-100% similar to the C. siamense type strain JX010278, JX010019, JX009709, GQ856775, GQ856730, JX010100, JX010410, and JX010332 sequences (Carbone & Kohn 1999; Moriwaki & Tsukiboshi 2009; Stephenson et al. 1997). The SQZ9 identity was confirmed by constructing a phylogenetic tree combining all loci, which grouped the isolate and the C. siamense type strain in the same clade (Fig. 2). For pathogenicity tests, 15 healthy 2-year-old plants (3 plants per pot) were spray-inoculated with SQZ9 conidial suspension (1 × 105 conidia/mL) at 2 mL per plant. Same number of plants sprayed with water were used as control. This experiment was repeated twice. All plants were covered with clear plastic bags for 72 h to maintain high humidity and then placed in a greenhouse (29 °C, natural light, and 85% relative humidity). After six days, the inoculated leaves exhibited symptoms that were similar to those observed in the field, but the controls were symptomless. The same fungus was recovered from inoculated symptomatic leaves, and its identity was confirmed by sequencing and a phylogenetic analysis. This is the first report of C. siamense causing anthracnose on B. paridiformis in China. Future studies should assess the effectiveness of chemical and biological control measures for managing this disease.

First Report of Neofusicoccum ribis Causing Cankers and Dieback Diseases on Apricot Trees in Canada and Worldwide

Apricot trees (Prunus armeniaca L.) with cankers, gummosi and dieback symptoms were observed in a commercial orchard in Niagara-on-the-Lake, Ontario, Canada. In October 2018, up to 44.9% disease incidence (n = 318) was observed on 2-year-old 'Harostar™' trees grafted onto 'Haggith' rootstocks. Fungal colonies were consistently isolated and purified from small sections of wood collected from canker margins of symptomatic trunk and shoot tissue, as described by Ilyukhin et al. (2023). Purified mycelial isolates sharing similar morphological characteristics were categorized into five distinct morphotypes. One representative isolate from each morphotype was used to inoculate excised apricot shoots as described by Ilyukhin and Ellouze (2023). One morphotype displayed necrotic lesions on the shoots consistently yielded abundant white aerial mycelium that turned grey-brown on PDA after 7 days (Figure S1) and produced black pycnidia three weeks following incubtion at 22°C in the dark. Conidia were hyaline, one-celled, fusiform, with dimensions of 19.7 - 24.2 × 3.6 - 4.8 μm (average 22.1 × 4.3 μm, n = 30), the typical morphology of a Neofusicoccum sp. (Crous et al. 2006). Species identification was verified by extracting genomic DNA of the representative isolate M1-105, amplifying and sequencing the internal transcribed spacer (ITS), translation elongation factor 1-α (EF1-α) and β-tubulin (TUB2) gene regions with primers ITS1/ITS4, EF1-728F/EF1-986R and Bt2a/Bt2b. Nucleotide sequences (GenBank Accession No. ITS: OK287034; EF1-α: OK346636; TUB2: OK346633) have 100%, 99.61% and 99.55% identity with Neofusicoccum ribis isolates from different hosts and countries (MT587514, DQ235142, OL455952, respectively). Randomized accelerated maximum likelihood analysis (Stamatakis et al. 2008), using ITS, EF1-α and TUB2 sequence data, clustered M1-105 with the highest bootstrap support values with the N. ribis ex-epitype CBS 115475 (Figure S2). A living culture of M1-105 was deposited in the Canadian Collection of Fungal Cultures (DAOMC 252247). Pathogenicity was verified using 5 potted healthy 1-year-old 'Haroblush™' apricot cultivar grafted onto 'Krymsk® 86' rootstocks. Trunks and shoots were inoculated in a shallow wound made by a scalpel with mycelial plugs from a 5-day-old culture of M1-105. Five control trees were inoculated with sterile plugs. Trees were put in an open-air area and watered as needed. Canker symptoms appeared 7 days after inoculation, and spread above and below the inoculation point. Fifteen days post-inoculation, the upper portion of inoculated shoots showed necrosis, gummosis and wilt (Fig. S1). Neofusicoccum ribis was re-isolated from all infected trees and species identity was confirmed by sequencing as described above. Controls remained symptom-free and no fungi were isolated from the wood. Therefore, Koch's postulates were completed. Neofusicoccum ribis was reported to cause branch dieback of olive trees in Spain (Romero et al. 2005) and pistachio in Italy (Corazza et al. 1986), stem blight and dieback of blueberry in Michigan (Heger et al. 2023) and Florida (Wright and Harmon 2010) and postharvest decay of apple fruit from cold storage in Pennsylvania (Jurick et al. 2013). To the best of our knowledge, this is the first report of N. ribis causing canker and shoot dieback of apricot trees in Canada and worldwide. This report reveals N. ribis as a potential threat, causing canker and dieback. Without proper management, it could lead to significant losses in apricot orchards and the stone fruit industry. This study paves the way for crucial research on N. ribis outbreaks and effective disease control.

First report of Epicoccum nigrum causing leaf spots on Campomanesia guazumifolia (Camb.) Berg in Brazil

Campomanesia guazumifolia is a native tree that produces fruit that can be consumed fresh or used by industry (Donadio et al., 2002). In February 2022, in the experimental area of the Universidade Tecnológica Federal do Paraná - Brazil, disease was observed in 22 trees, with 50% to 80% severity in crown leaves. Symptoms were small, irregular, or circular-shaped, dark-brown lesions with yellow halos (Figure S1). As the disease progressed, the lesions increased in size, without distinction between mature and young tissues, causing complete leaf wilting. Twenty symptomatic leaves from 11 trees grown in the same orchard line were collected. For fungal isolation, the leaf surfaces were disinfected with 0.5% NaOCl solution for 1 min, rinsed in sterile distilled water, and dried on sterile filter paper. Five fragments of diseased leaf tissue were placed on a potato dextrose agar medium. The morphological characteristics of the colony, such as filamentous mycelium and golden yellow on the upper part, with the presence of circular to ovoid and multicellular conidia (mean 21.00 µm x 24.45 µm, n = 30) of the nine isolates, coincided with the description of the fungus of the genus Epicoccum (Valenzuela-Lopez et al., 2018). Further identification of one of these nine isolates was confirmed by amplifying and sequencing three loci (ITS, β-tubulin, and RPB2) using the ITS1/ITS4, Bt2a/Bt2b, and 5F2/7cR primer pairs, respectively (White et al., 1990, Glass and Donaldson, 1995, O'Donnell et al., 2007). A single representative isolate (Cgen01) was analyzed and submitted to GenBank (OR020968, OR079879, and OR079878). The Bayesian Inference was used to reconstruct the phylogenetic trees (Figure S2), starting from random trees for 5,000,000 generations, using MrBayes v. 3.2.1 (Ronquist et al., 2012). The isolate clustered together with the isolate of Epicoccum nigrum (Chen et al., 2017) with a high posterior probability (0.98). For the pathogenicity tests, four young, healthy branches containing 20 leaves were spray-inoculated with 1.5 mL of conidia suspension of Cgen01 (106 conidia mL-1), covered with perforated transparent plastic bags, and moistened with distilled water in the orchard. The air temperature ranged from 14ºC to 25ºC. Sterile distilled water was used as a control. Three replicates (pathogen and control) on different trees were evaluated. After five days, the fungus was re-isolated from the symptomatic lesion, showing morphological characteristics similar to those of Cgen01. Control branches did not show fungal growth. The inoculation test was conducted twice and similar symptoms were observed. This is the first report of leaf spots caused by E. nigrum on C. guazumifolia in Brazil. E. nigrum, an endophytic fungus described as a mycoparasite, showed phytopathogenic behavior in this study, causing spots and loss of leaves in C. guazumifolia, drastically reducing the production of photoassimilates and affecting the quality of the fruits.

First Report of Fruit Rot Caused by Fusarium incarnatum-equiseti species complex on Greenhouse Bell Pepper in Malaysia

In Malaysia, bell pepper (Capsicum annuum var. grossum), also known as sweet pepper or paprika, is one of the highly imported vegetable crops. In 2021 alone, Malaysia imported nearly 74 thousand metric tons of its chilies, including bell peppers, from other countries (DOSM, 2022). Often, farmers grow the bell peppers in moderate to cool conditions within highland regions for local commercial purposes. In June 2022, the Malaysian Agricultural Research and Development Institute (MARDI) in Serdang, Selangor, conducted a research study to grow lowland bell peppers under a glasshouse rain protection system. A disease inspection carried out found fruit rot on approximately 30% of mature bell pepper fruits in the greenhouse. Symptoms appeared as firm and sunken black lesions covered with white to light pink spore masses on the outer surface, which eventually fell off. Infected fruit parts were disinfected with 10% hypochlorite (NaOCl) for 2 min, followed by double washing with sterile distilled water, air-dried, and placed onto potato dextrose agar (PDA). After 3 days of incubation, the fungal colonies that grew from the symptomatic tissue pieces were transferred onto new PDA to obtain pure cultures. The pure fungal colony appeared dense, whitish aerial mycelium that slowly became cream to pinkish-orange after 7 days of incubation at room temperature (25±2 °C). To examine the morphology features, the pure cultures were subbed onto carnation leaf agar (CLA) and incubated at 25±2°C for 14 days. Macroconidia were abundant, slightly curved with tapered apical cells, 3- to 5-septate, and ranged between 21.8 and 34.0 x 3.0 and 5.1 μm. Microconidia were single-celled, often 1-septate, and ranged between 10.0 and 12.6 x 2.1 and 3.4 μm. Chlamydospores were globose and in chains. The fungus was identified as Fusarium sp. according to Fusarium key by Leslie and Summerell (2006). PCR amplification and DNA sequencing were performed using primers EF1F/EF2R and ITS1/ITS4 (O'Donnell et al., 1998; White et al., 1990) to amplify the partial elongation factor 1-alpha (TEF1-α) gene and internal transcribed spacer region (ITS), respectively. The TEF1-α and ITS sequences of this isolate were deposited in GenBank as OQ672911 and OR349657. BLAST analysis with TEF1-α gene sequences revealed 99.74% and 99.33% sequence identity with F. pernambucanum (accession no. ON330424) and Fusarium isolate NRRL 25134 (accession no. JF740755), respectively; both belonged to the Fusarium incarnatum-equiseti species complex (FIESC). BLAST search of the TEF1-α sequence in the database of the International Mycological Association (www.mycobank.org) showed 99.18% identity with FIESC (NRRL 36548). The ITS sequences were 100% identical to those of F. incarnatum (MT563420, MT563419, and MT563418). Pathogenicity test was conducted on three unwounded and three wounded mature red bell pepper fruits (SP299 Red Masta variety). Two healthy bell peppers were used as controls for each treatment. Prior to inoculation, the fruits were surface-sterilized by dipping in 70% ethanol and rinsed twice with sterile distilled water. Unwounded fruits were inoculated with fungal mycelium disks (5 mm diameter), whereas control fruits were inoculated with sterile PDA agar disks. For wound method, 6 µl of spore suspension (1x106 spores/ml) was obtained from 7-day-old cultures and injected (1 mm depth) into the fruit wall using a sterile syringe needle. Control fruits were inoculated with sterile distilled water only. Each fruit was inoculated with the inoculum at three distinct spots and kept in a humid chamber at a temperature of 25±2 °C. The pathogenicity test was done twice. Five days post-inoculation, the control fruits showed no symptoms, whereas all inoculated wounded and non-wounded fruits developed necrotic lesions with white mycelium growing on the inoculation points. The pathogen was successfully re-isolated from the infected fruits and morphologically identified as FIESC, fulfilling Kochs postulates. It has been reported previously that the members of FIESC are responsible for the fruit rot of bell peppers under greenhouse conditions (Ramdial et al., 2016). To the best of our knowledge, this is the first report of FIESC causing fruit rot on greenhouse bell peppers in Malaysia. This fruit rot disease may impose significant constraints on bell pepper production in Malaysia; hence, effective strategies to control the pathogen and prevent disease dispersal should be implemented.