Sodium alginate and carboxymethyl cellulose-based composite coating enriched Lactiplantibacillus plantarum reduced anthracnose disease and maintained the quality of “Cat Hoa Loc” mango fruits

Mangoes (Mangifera indica L.) are one of the most important export fruits in Peru and anthracnose, caused by several species in the Colletotrichum gloeosporioides species complex (CGSC), is one of their main postharvest diseases (Alvarez et al. 2020). Balsas is the major mango producing district in the Amazonas department, where farmers practice intercropping in orchards mostly of less than 5 ha (Cabezudo Cerpa 2022). In July 2021, mango fruits cv. Kent with anthracnose were detected at an incidence of 55 to 80% during postharvest in Balsas. Symptoms included sunken dark brown lesions with appearance of orange conidiomata at advanced stages of the disease. We collected two samples of infected mangoes from a farm located at 6°51'01" S, 77°59'48" W (1088 m.a.s.l.). One axenic culture (INDES-AM1) was obtained from a hyphal tip of a monosporic colony and cultivated on PDA medium at 25 °C in the dark. The growing rate of the colony was 8.1 mm.day-1. Conidia were hyaline, guttulate, unicellular and cylindrical with narrowing center, with dimensions of 15.8 to 23.5 × 4.5 to 7.6 μm (mean = 18.6 ± 0.03 × 6.0 ± 0.02 μm, SE, n = 50), consistent to the CGSC (Weir et al. 2012). Appressoria were dark brown, and ovoid to slightly irregular in shape, ranging from 5.3 to 10.1 × 4.7 to 8.3 μm (mean = 7.9 ± 0.02 × 6.0 ± 0.02 μm, SE, n = 50). Koch's postulates were fulfilled on mature mango fruits of the same cultivar and from the same district. Mangoes were washed with detergent and left to dry before inoculation. PDA-mycelial plugs of 0.5 cm wide were transferred on two different locations of two fruits, with four replicates. One location was previously wounded with five needle punctures of 3 mm depth. The inoculated fruits were maintained in a moist chamber at ambient light and temperature (18.9 ± 0.5 °C, SE). Symptoms appeared three-to-five days post inoculation (dpi), and the superficial diameter of the lesions were 8.3 ± 1.5 and 3.6 ± 2 mm with the invasive and the superficial inoculation approaches, respectively, at five dpi. Lesions were very similar to original symptoms. Macro and micromorphological characteristics of the re-isolated fungal colonies were the same as isolate INDES-AM1. Molecular identification of the pathogen was carried out following Weir et al. (2012). Total DNA was extracted using the Wizard® Genomic DNA Purification Kit (Promega Corp., Madison, Wisconsin) and the ribosomal internal transcribed spacer (ITS), and partial sequences of the chitin synthase (CHS1), actin (ACT), β-tubulin 2 (TUB2), calmodulin (CAL), and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) nuclear genes were sequenced (Accession numbers: OP425395, OP440444, OP440442, OP440443, OP555062, OP555063). ITS, CHS1, ACT, TUB2, CAL, and GAPDH sequences were 98.6, 100, 100, 99.5, 100, and 99.08% identical to Colletotrichum asianum type strain ICMP 18580 sequences, respectively. Additionally, a bootstrapped maximum likelihood midpoint-rooted phylogeny with a multilocus dataset with the six sequences from reference strains of C. asianum and closely related species within the CGSC revealed that strain INDES-AM1 is C. asianum. This species has been found causing anthracnose on M. indica in at least 15 different countries in Africa, America, Asia, and Oceania (Weir et al. 2012). It was originally described from coffee and has multiple other hosts (Prihastuti et al. 2009; Lima et al. 2015). To the best of our knowledge, this is the first report of C. asianum infecting mangoes in Peru.

Pepper (Capsicum annuum L.) is an important solanaceous vegetable crop, with high nutritional and economic value. However, it is susceptible to Colletotrichum spp. infection during its growth and development, which seriously affects production yield and quality. Chili anthracnose, caused by Colletotrichum spp., is one of the most destructive diseases of pepper. In August 2020, chili anthracnose was observed with widespread distribution in the horticulture field of Northwest A&F University (34.16° N, 108.04° E) in Shaanxi Province, China. Approximately 60% of the pepper plants had disease symptoms typical of anthracnose. Lesions on pepper fruits were dark, circular, sunken, and necrotic, with the presence of orange to pink conidial masses (Figure S1A). To perform fungal isolation, the tissue at the lesion margin was cut from eight symptomatic fruits, surface disinfested with 75% ethanol for 30 s, and 2% NaClO for 1 min, then rinsed three times with sterile distilled water and dried on sterile filter paper. The tissues were placed on potato dextrose agar (PDA) and incubated at 28 ºC in the dark. After 3 days, hyphae growing from tissue of each lesion were recultured on PDA (Liu et al. 2016). A representative single-spore isolate (NWAFU2) was used for morphological characterization, molecular analysis, phylogenetic analysis, and pathogenicity tests. NWAFU2 colonies had gray-white aerial mycelium, and the reverse side of the colonies was dark gray to light yellow after 10-days growth on PDA (Figure S1B-C). Conidia were cylindrical, aseptate, with obtuse to slightly rounded ends, and measured 10.1 to 16.9 (length) × 4.7 to 7.0 (width) μm (n=50) (Figure S1D). Based on morphological features, the isolate was consistent with the description of C. gloeosporioides species complex (Weir et al. 2012). For molecular identification, genomic DNA was extracted using a CTAB method and the internal transcribed spacer (ITS) region, glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and partial sequences of actin (ACT) genes were amplified and sequenced using primers ITS1F/ITS4, GDF1/GDR1 and ACT-512F/ACT-783R, respectively (Dowling et al. 2020). Using the BLAST, ITS, ACT, GAPDH gene sequences (GenBank accession nos. MW258690, MW258691 and MW258692, respectively) were 100%, 100% and 98.19% identical to ZJL-4 of C. gloeosporioides (GenBank accession nos. MN075757, MN058142 and MN075666, respectively). Phylogenetic analysis was conducted using MEGA-X (Version 10.0) based on the concatenated sequences of published ITS, ACT and GAPDH for Colletotrichum species using Neighbor-Joining algorithm. The identified isolate (NWAFU2) was closely related to C. gloeosporioides (Figure S2). To confirm the pathogenicity, ten healthy pepper fruits were surface-sterilized and 2 μL of conidial suspension (1×106 conidia/mL) was injected the surface of pepper. Five fruits were inoculated with 2μL sterile distilled water as controls. After inoculation, the fruits were kept in a moist chamber at 28°C in the dark. The experiment was repeated three times. Anthracnose symptoms similar to those observed in the field, were observed 7 days after inoculation (Figure S1F) and control fruits remained healthy. A similarly inoculated detached leaf assay resulted in water-soaked lesions 3 days after inoculation. C. gloeosporioides was reisolated from the infected pepper fruits, fulfilling Koch's postulates. C. gloeosporioides has been reported to cause chili anthracnose in Sichuan Province, China (de Silva et al. 2019; Liu et al. 2016). However, Shaanxi is one of the main pepper producing areas in china and it is geographically distinct from Sichuan; its climate and environmental conditions are different from Sichuan. Knowledge that C. gloeosporioides causes chili anthracnose of pepper in Shaanxi province, China may aid in the selection of appropriate management tactics for this disease. Reference: de Silva, D. D., Groenewald, J. Z., Crous, P. W., Ades, P. K., Nasruddin, A., Mongkolporn, O., and Taylor, P. W. J. 2019. Identification, prevalence and pathogenicity of Colletotrichum species causing anthracnose of Capsicum annuum in Asia. IMA Fungus 10:8. Dowling, M., Peres, N., Villani, S., and Schnabel, G. 2020. Managing Colletotrichum on Fruit Crops: A "Complex" Challenge. Plant Dis 104:2301-2316. Liu, F. L., Tang, G. T., Zheng, X. J., Li, Y., Sun, X. F., Qi, X. B., Zhou, Y., Xu, J., Chen, H. B., Chang, X. L., Zhang, S. R., and Gong, G. S. 2016. Molecular and phenotypic characterization of Colletotrichum species associated with anthracnose disease in peppers from Sichuan Province, China. Sci Rep 6. Weir, B. S., Johnston, P. R., and Damm, U. 2012. The Colletotrichum gloeosporioides species complex. Stud Mycol 73:115-180.

Mango Anthracnose: Economic Impact and Current Options For Integrated Managaement.

Strawberry anthracnose caused by Colletotrichum spp. is one of the most serious diseases in the strawberry fields of China. In total, 196 isolates of Colletotrichum were obtained from leaves, stolons, and crowns of strawberry plants with anthracnose symptoms in eastern China and were characterized based on morphology, internal transcribed spacer (ITS), and β-tubulin (TUB2) gene sequences. All 196 isolates were identified as the Colletotrichum gloeosporioides species complex. In total, 62 strains were further identified at the species level by phylogenetic analyses of multilocus sequences of ITS, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), actin (ACT), Apn2-Mat1-2 intergenic spacer and partial mating type (ApMat), calmodulin (CAL), and TUB2. Three species from the C. gloeosporioides species complex were identified: Colletotrichum siamense, C. fructicola, and C. aenigma. Isolates of C. siamense were tolerant to high temperatures, with a significantly larger colony diameter than the other two species when grown above 36°C. The inoculation of strawberry plants confirmed the pathogenicity of all three species. C. siamense isolates resulted in the highest disease severity. The in vitro sensitivities of C. siamense and C. fructicola isolates to azoxystrobin and three demethylation-inhibitor (DMI) fungicides (difenoconazole, tebuconazole, and prochloraz) were determined. Both species were sensitive to DMI fungicides but not to azoxystrobin. C. siamense isolates were more sensitive to prochloraz, while C. fructicola isolates were more sensitive to difenoconazole and tebuconazole. The present study provides valuable information for the effective management of strawberry anthracnose.

Citrus anthracnose, caused by Colletotrichum spp., is a major disease in many citrus-growing regions of the world. During the spring of 2019, symptoms of petal necrosis and necrotic lesions on fruits were detected on Mexican lime (Citrus aurantifolia), sweet orange (Citrus sinensis), and grapefruit (Citrus paradisi) trees in three commercial orchards distributed in northern Sinaloa (El Fuerte and Ahome municipalities), Mexico. Colletotrichum-like colonies were consistently isolated on potato dextrose agar (PDA) medium from symptomatic petals and fruits, and 30 monoconidial isolates (10 per orchard) were obtained. Five isolates were selected as representative for morphological characterization, multilocus phylogenetic analysis, and pathogenicity tests. The isolates were designated as FAVF355-FAVF359 and were deposited in the Culture Collection of Phytopathogenic Fungi of the Faculty of Agronomy of El Fuerte Valley at the Autonomous University of Sinaloa (Mexico). Colonies grown on PDA at 25ºC were cottony, dense, with grayish white aerial mycelium and with pink conidial masses. Conidia (n= 100) were cylindrical, hyaline, aseptate, 13.7 to 18.8 × 4.3 to 5.8 μm, with both ends rounded. Based on morphological features, the five isolates were tentatively identified in the Colletotrichum gloeosporioides species complex (Weir et al. 2012). For molecular identification, total DNA was extracted, and the internal transcribed spacer (ITS) region (White et al. 1990), and partial sequences of actin (ACT), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and β-tubulin (TUB2) genes were amplified by PCR (Weir et al. 2012), and sequenced. A phylogenetic tree based on Bayesian inference for species belonging to the C. gloeosporioides species complex was constructed. The multilocus phylogenetic analysis distinguished the isolates FAVF355-FAVF357 as C. gloeosporioides sensu stricto and the isolates FAVF358-FAVF359 as C. siamense. The sequences were deposited in GenBank (accession numbers ITS: MT850050-MT850054; ACT: MT834528-MT834532; GAPDH: MT855979-MT855982; TUB2: MT834533-MT834536). Pathogenicity of the five isolates was verified on healthy fruits of their original host species. Five fruits per isolate were inoculated using the colonized agar plug method. Fruits were wounded with a sterile toothpick and mycelial plugs (5 mm in diameter) removed from the margin of a 6-days-old culture were placed onto three wound sites in each fruit. Non-colonized agar plugs were placed on the wounds of 10 fruits used as the control. The fruits were kept in a moist chamber at 25°C for 8 days. The experiment was repeated twice. All inoculated fruits developed circular and necrotic lesions 6 days after inoculation, whereas the control fruits remained symptomless. The fungi were consistently re-isolated from the diseased fruits and were morphologically identical to that originally inoculated, fulfilling Koch´s postulates. To date, only C. gloeosporioides sensu lato and C. acutatum sensu lato has been associated with sweet orange and Mexican lime in Mexico (Farr and Rossman 2020), whereas C. gloeosporioides sensu stricto has been recently recorded in a different area (Iguala, Guerrero) of Mexico (Cruz-Lagunas et al. 2020). To our knowledge, this is the first report of C. gloeosporioides sensu stricto causing anthracnose on sweet orange, and of C. siamense on Mexican lime in Mexico, as well as C. gloeosporioides s. s. causing disease on grapefruit in Sinaloa, Mexico.

Florist's cyclamen (Cyclamen persicum) is an herbaceous perennial native to the Mediterranean region and has become an increasingly popular plant around the world. Leaves of these plants are cordate-shaped with varying green and silver patterns. Flowers vary in color from white through different shades of pink, lavender, and red. In September 2022, symptoms of anthracnose including leaf spots and chlorosis, wilting, dieback, and crown and bulb rot were observed on 20 to 30% of approximately 1,000 cyclamen plants in an ornamental production nursery in Sumter County, SC. Tissue samples surrounding the necrotic crowns were excised and sterilized in 10% bleach for 1 min, rinsed in sterile water, placed onto acidified potato dextrose agar (APDA), and incubated at 25°C with 24-h photoperiod. A total of five Colletotrichum isolates, 22-0729-A, 22-0729-B, 22-0729-C, 22-0729-D, and 22-0729-E were obtained by transferring hyphal tips to new plates. The morphology of these five isolates was identical, observed as gray and black with aerial gray-white mycelia and orange-colored spore masses. Conidia (n=50) measured 19.4 ± 5.1 mm (11.7 to 27.1 mm) in length and 5.1 ± 0.8 mm (3.7 to 7.9 mm) in width. Conidia were tapered with rounded ends. Setae and irregular appressoria were infrequently observed in aged cultures (> 60-day-old). These morphological features resembled those of members of the Colletotrichum gloeosporioides species complex (Rojas et al. 2010; Weir et al. 2012). Sequence of the internal transcript spacer (ITS) region of a representative isolate 22-0729-E (GenBank accession No. OQ413075) is 99.8% (532 / 533 nt) and 100% (533 / 533 nt) identical to those of the ex-neotype of Co. theobromicola CBS124945 (JX010294) and the ex-epitype of Co. fragariae (= Co. theobromicola) CBS 142.31 (JX010286), respectively. Its glyceraldehyde 3-phosphate dehydrogenase (GAPDH) gene sequence is 99.6% (272 / 273 nt) identical to those of CBS124945 (JX010006) and CBS 142.31 (JX010024). Its actin (ACT) gene sequence shares 99.7% (281 / 282 nt) and 100% (282 / 282 nt) identities with those of CBS124945 (JX009444) and CBS 142.31 (JX009516), respectively. Lastly, its beta-tubulin 2 (TUB2) gene sequence is 99.6% (704 / 707 nt) and 100% (707 / 707 nt) identical to those of CBS124945 (JX010447) and CBS 142.31 (JX010373), respectively. The causal agent causing anthracnose on cyclamen in SC was identified as Co. theobromicola. To confirm the pathogenicity, cyclamen 'Verano Red' plants grown in 2.5-inch pots were used in two pathogenicity assays using different inoculation methods. In the first assay, three plants were inoculated by spraying a conidial suspension (1 × 106 conidia per ml; 30 ml per plant) of isolate 22-0729-E onto the foliage. Three non-inoculated control plants were sprayed with distilled water. All six plants were placed in a plastic tray with wet paper towels. The tray was placed at 22°C for an 8-h photoperiod and covered for 7 days to maintain humidity. Early symptoms including small spots, marginal necrosis, and chlorosis were observed on leaves and flowers 8 days after inoculation (DAI) and the entire aboveground tissues of inoculated plants were blighted 13 to 21 DAI. Non-inoculated plants remained asymptomatic. In the second assay, sterile toothpicks were used to slightly wound the crown and bulb surface of three plants and secure a mycelial APDA plug of isolate 22-0729-E (5×5 mm2) onto each wound (three wounds per plant). Three control plants were wounded in the same manner, while sterile APDA plugs were used in place of mycelial plugs. All six plants were maintained in the same manner as in the first assay. Apparent leaf yellowing and wilting symptoms appeared as early as 13 DAI. On 21 to 28 DAI, severe crown rot on inoculated plants caused the entire foliage to collapse. At least one third of the inner crown and bulb tissues of each inoculated plant were rotten, while those of non-inoculated plants appeared healthy. Each assay was repeated once. Colletotrichum isolates resembling morphological characters of 22-0729-E were recovered from leaves and inner crown tissues of all inoculated plants in both assays, respectively, but not from non-inoculated control plants. Anthracnose diseases on Cyclamen persicum caused by Co. theobromicola (syn. Co. fragariae) have been reported in NC, USA (Lui et al. 2011) and Israel (Sharma et al. 2016). This is the first report of anthracnose on cyclamen in SC, USA. Colletotrichum gloeosporioides (teleomorph Glomerella cingulate) species complex on cyclamen has also been reported in Argentina (Wright et al. 2006), South Africa, and several other U.S. states (Farr and Rossman 2022). However, it remains unknown whether these previous reports in fact attributed to Co. theobromicola due to lack of molecular identification (Weir et al. 2012). Colletotrichum theobromicola can cause diseases on at least 30 other agricultural and horticultural crops such as strawberry, cacao, and boxwood (Farr and Rossman 2022). It may pose a threat to cyclamen in greenhouse and nursery productions. Therefore, management strategies are warranted in the future.

Ramulosis of cotton, caused by Colletotrichum gossypii var. cephalosporioides (CGC), is an important disease of cotton in Brazil. The main objective of this work was to test whether CGC is a phylogenetic species inside the Colletotrichum gloeosporioides species complex. A Bayesian inference phylogenetic analysis of a combined ITS and TUB2 dataset was conducted with 21 strains identified as CGC and five strains of Colletotrichum gossypii (CG), associated with cotton anthracnose, obtained from diseased plants from different regions of Brazil. All CGC strains formed a highly supported lineage inside the clade of Colletotrichum theobromicola, a member of the C. gloeosporioides species complex. CG strains formed another lineage in the same clade. These findings were supported by a second analysis conducted with three genes (ITS+TUB2+GAPDH) and a subset of five CGC and three CG strains. During pathogenicity tests, all five CGC strains tested induced typical symptoms of ramulosis on inoculated plants, including foliar necrosis, death of apical meristems and over sprouting. Plants inoculated with CG strains exhibited foliar necrotic spots two months after inoculation. These results give phylogenetic support for the placement of CGC in the C. gloeosporioides species complex, and the distinction between the ramulosis and anthracnose pathogens of cotton in Brazil.

Pitahaya (Hylocereus spp.), also called dragon fruit, is a cultivated cactus that is native to Mexico as well as Central and South America. In October 2021, anthracnose symptoms were observed on fruit of pitahaya (Hylocereus costaricensis) in a commercial orchard located in Culiacán, Sinaloa, Mexico. Lesions on fruit were circular, sunken, dark brown and with halo. To fungal isolation, small pieces from adjacent tissue to lesions of symptomatic fruits were surface disinfested by immersion in a 2% sodium hypochlorite solution for 2 min, rinsed in sterile distilled water, and placed in Petri plates containing potato dextrose agar (PDA). The plates were incubated at 25 ºC for 5 days in darkness. Colletotrichum-like colonies were consistently observed on PDA and five monoconidial isolates were obtained. An isolate was selected as a representative for morphological identification, multilocus phylogenetic analysis, and pathogenicity tests. The isolate was deposited as CCLF186 in the Culture Collection of Phytopathogenic Fungi at the Research Center for Food and Development (Culiacán, Sinaloa). On PDA, initially white colonies turned grey with abundant orange conidia masses at 8 days after incubation at 25 ºC. Conidia were cylindrical, with ends rounded, aseptate, hyaline, and measuring 15.2 to 18.9 × 4.3 to 6.4 μm (n= 100). Appressoria were terminal, subglobose to clavate, of 7.4 to 11.6 × 5.9 to 8.2 µm (n= 30). Setae were not observed. These morphological characters were consistent with those reported for the Colletotrichum gloeosporioides species complex (Weir et al. 2012). To determine the phylogenetic identity of the isolate CCLF186, genomic DNA was extracted following the CTAB method (Doyle and Doyle 1990), and the internal transcribed spacer (ITS) region, the ApMat intergenic region, as well as partial sequences of actin (act) and glyceraldehyde-3-phosphate dehydrogenase (gapdh) genes were amplified and sequenced using the primers pairs ITS5/ITS4 (White et al. 1990), AM-F/AM-R (Silva et al. 2012), GDF/GDR, and ACT-512F/ACT-783R (Weir et al. 2012), respectively. The sequences were deposited in GenBank under accession nos. OP269659 (ITS), OP302778 (gapdh), OP302777 (act), and OP302779 (ApMat). BLASTn searches revealed high identity with sequences of C. tropicale (CBS 124949) for ITS (100%), ApMat (100%), act (100%), and gapdh (100%). A phylogenetic tree based on Bayesian inference and Maximum Likelihood methods, including published ITS, ApMat, act, and gapdh sequence datasets for isolates in the Colletotrichum gloeosporioides species complex was generated. The phylogenetic analysis based on the concatenated sequences clustered the isolate CCLF186 with the C. tropicale reference isolates. Pathogenicity of the isolate CCLF186 was confirmed on 10 healthy pitahaya fruits without wounds. A drop of a conidial suspension (1 × 105 spores/ml) was placed on two locations on each fruit. Ten control fruits were treated with sterilized water. The fruits were kept in a moist plastic chamber at 25°C and 12 h light/dark for 8 days. The pathogenicity test was repeated twice. All inoculated pitahaya fruits exhibited sunken and necrotic lesions 6 days after inoculation, whereas no symptoms were observed on the control fruits. The fungus was consistently re-isolated only from the diseased fruits and found to be morphologically identical to the isolate used for inoculation. Recently, C. tropicale causing anthracnose in dragon fruit (Selenicereus monacanthus) was reported from Philippines (Evallo et al. 2022). Now, this is the first report of C. tropicale causing fruit anthracnose in H. costaricensis in Mexico and worldwide. These findings provide a basis for research about the distribution and effective disease-management strategies.

Tree peonies (Paeonia suffruticosa Andr. and hybrids) are well-known ornamental and medicinal plants cultivated in temperate and subtropical regions around the world. From June to September 2021, severe leaf spot disease was observed on 3 tree peony cultivars ('Luoyanghong', 'Moyushenghui', 'Roufurong') in Xinxiang (35º29´N, 113º95´E) and Luoyang (34º64´N, 112º49´E), Henan Province, China. Leaf spot incidence was as high as 28% ('Luoyanghong'), 45% ('Moyushenghui') and 67% ('Roufurong'), respectively. Symptoms appeared initially as small purple spots less than 1 mm in diameter in the middle and upper parts of the leaves, and then evolved to coalescent lesions, causing brown scorch ultimately. From each cultivar, 5 diseased leaves were collected. Leaflet tissues (3-4 mm2) cut from spot margins were surface sterilized in 75% alcohol for 45 s, washed 5 times with sterile distilled water, and then cultivated on potato dextrose agar (PDA) medium at 28 °C in the dark. Eleven isolates were obtained, and colonies grown from single conidia on PDA were 80-85 mm in diameter after 10 d, with scattered small, dark-based spikes on the surface of the colonies. The aerial mycelium was cottony, dense, and dark gray near the center on the reverse side. Conidia were cylindrical to clavate, with rounded apex and rounded base, and the conidia contents were granular, 8.44-14.06×3.60-4.31 μm (mean=11.28×3.69 μm, n=40). Appressoria were mostly subglobose or with a few broad lobes, pale to medium brown, 3.36-6.72×3.35-5.60 μm (mean=5.02×4.55 μm, n=20). Based on the culture representation and conidial morphology, the isolates were characterized as Colletotrichum gloeosporioides species complex (Weir et al. 2012; Fu et al. 2019). To further identity the species, the actin (ACT), calmodulin (CAL), chitin synthase (CHS-1), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and the ribosomal internal transcribed spacers (ITS) loci of isolates PSW0002, PSW0008 and PSW0009 were amplified using ACT-512F/ACT-783R, CL1C/CL2C, CHS-79F/CHS-345R, GDF/GDR, and ITS1/ITS4, primers (Weir et al. 2012; Schena et al; 2014; Kim et al. 2021; Li et al. 2021). Fifteen sequences were deposited in GenBank (ACT for OP225605, OP225606, and OP225607, CAL for OP225608, OP225609 and OP225610, CHS for OP225611, OP225612 and OP225613, GAPDH for ON321897, OP225614, and OP225615, and ITS for ON323473, OP214349 and OP214350 ), which showed 100% sequence similarity to Colletotrichum aenigma (JX009443 and JX009519 for ACT, JX009683 and JX009684 for CAL, JX009774 and JX009903 for CHS-1, JX010244 and JX009913 for GAPDH, JX010243 and JX010148 for ITS). Three isolates clustered with C. aenigma (ex-holotype culture ICMP 18608) in the multi-locus phylogenetic tree with a bootstrap value of 100%. To achieve Koch's postulates, pathogenicity was tested on 5-year-old healthy potted plants ('Luoyanghong'). Thirty leaves were inoculated with 10 µL conidial suspension (isolate PSW0002, 1×106 conidia/mL) and the controls were inoculated with sterile water. Plants were placed in a greenhouse at 28°C under conditions with 12 h photoperiod and 90% relative humidity. After 5 to 10 days, distinct spots were observed on the inoculated leaves, while the control leaves showed no symptoms. C. aenigma was reisolated from all inoculated leaves, but not from the control. C. aenigma has been reported to cause anthracnose on Pyrus pyrifolia (Weir et al. 2012), Camellia sasanqua (Chen et al. 2019), Juglans regia (Wang et al. 2020), Paeonia ostii (Ren et al. 2020), and Capsicum annuum (Sharma et al. 2022). A previous study reported C. gloeosporioides as a pathogen of anthracnose in tree peonies in China (Xuan et al. 2017), the typical symptoms were big necrotic lesions (5-10 mm diam) on leaves，which were significantly different from those caused by C. aenigma. To our knowledge, this is the first report of C. aenigma causing anthracnose in tree peonies in China. This finding may help to take effective control of anthracnose in tree peonies.

Zinnia elegans (syn. Zinnia violacea), known as common zinnia, is one of the most spectacular ornamental plants in the family Asteraceae. Zinnia plants are widely cultivated in China for their impressive range in flower colours and profuse bloom over a long period. In April 2019, Zinnia plants grown in Ningbo Botanical Garden (29°56'57″N, 121°36'20″E) were found to have many circular necrotic lesions. In the early infection stage, the lesions appeared as small circular specks which developed later into large spots (15 to 32 mm diameter). Typical symptoms appeared to be grayish white centers with a chlorotic edges and disease incidence reached approximately 80% of plants in the affected field. Moreover, the growth of Zinnia plants was seriously affected by the disease. To identify the causative pathogen associated with the disease, 10 symptomatic leaves were collected from ten different Zinnia plants. Leaf tissues were cut from the lesion margins, surface sterilized with 75% ethanol for 30 seconds and rinsed three times in sterile distilled water. The leaf tissues were then dipped into 10% sodium hypochlorite for 2-3 minutes, washed three times in distilled water and dried on a sterile filter paper. After drying, the surface-sterilized leaf discs were transferred to potato dextrose agar (PDA) plates and incubated at 28°C for 2 to 3 days under the 12 h photoperiod. A total of ten pure fungal isolates were obtained and all the isolates displayed the same colony structure. Afterwards, three pure strains were randomly selected (F1, F3 and F5) for further study. The fungal colonies showed gray to brownish aerial mycelia with pink-colored masses of conidia. Conidia were one-celled, hyaline, cylindrical to subcylindrical, spindle-shaped with obtuse ends, measuring from 15.6 to 17.3 × 4.6 to 5.1 μm with both ends rounded. These morphological characteristics were consistent with the description of Colletotrichum gloeosporioides complex (Weir et al. 2012). The identity of a representative isolate, F3, was confirmed by a multilocus approach. Genomic DAN of isolate F3 was extracted and partial sequences of actin (ACT), chitin synthase (CHS), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), ribosomal internal transcribed spacer (ITS), manganese-superoxide dismutase (SOD2) , glutamine synthatase (GS), beta-tubulin (TUB2) and calmodulin (CAL) were amplified and sequenced as previously described (Weir et al. 2012). These nucleotide sequences were deposited in GenBank (accession MN972436 to MN972440, and MT266559 to MT266561; all sequences in FASTA format are shown (Supplementary S1). BLAST analysis of ITS, ACT, CHS, GAPDH and GS sequences from the F3 isolate revealed similarity to C. gloeosporioides voucher strain ZH01 with 100%, 100%，99%, 99% and 99% identity, respectively. SOD, TUB2 and CAL sequences showed similarity to C. siamense with 100%, 100% and 100% identity, respectively. The phylogenetic trees were constructed by Maximum Likelihood method (ML) using JTT model implemented in the MEGA 7. Results inferred from the concatenated sequences (ACT, CHS, GAPDH, ITS, SOD, GS, TUB2 and CAL) placed the isolate F3 within the C. siamense cluster (Supplementary S2). To confirm pathogenicity of the fungus, Koch's postulates were conducted by spraying 20 Zinnia plants (60-day-old) with a 1 × 106 conidia/ml suspension. Plants were maintained in the growth chamber at 25°C and 85% relative humidity. After 10 to 15 days, symptoms were observed on all inoculated leaves and resembled those observed in the field, whereas the control plants remained asymptomatic. Here, C. siamense was isolated only from the infected Zinnia leaves and identified by morphological and gene sequencing analyses. C. siamense has been reported in many crops in China (Yang et al. 2019; Chen et al. 2019; Wang et al. 2019). However, to our knowledge, this is the first report of anthracnose caused by C. siamense on Zinnia elegans in China. References Chen, X., Wang, T., Guo, H., Zhu, P. K., and Xu, L. 2019. First report of anthracnose of Camellia sasanqua caused by Colletotrichum siamense in China. Plant Dis. 103:1423-1423. Wang, Y., Qin, H. Y., Liu, Y. X., Fan, S. T., Sun, D., Yang, Y. M., Li, C. Y., and Ai, J. 2019. First report of anthracnose caused by Colletotrichum siamense on Actinidia arguta in China. Plant Dis. 103:372-373. Weir, B. S., Johnston, P. R., and Damm, U. 2012. The Colletotrichum gloeosporioides species complex. Stud. Mycol. 73: 115-180. Yang, S., Wang, H. X., Yi, Y. J., and Tan, L. L. 2019. First report that Colletotrichum siamense causes leaf spots on Camellia japonica in China. Plant Dis. 103:2127-2127.

Crataegus is a genus classified in family Rosaceae and includes several tree species commonly called tejocote that are widely cultivated for their pome fruits in Mexico. During fall of 2014, 2015, and 2016, severe symptoms of anthracnose were observed on approximately 60% of tejocote (Crataegus gracilior) fruits in an orchard located in Tulancingo, Oaxaca, Mexico. Affected fruits showed sunken, prominent, dark brown to black necrotic lesions and were exuding salmon spore masses. To isolate the fungus, small pieces from tissue adjacent to the lesions of 10 symptomatic fruits were excised and surface disinfested by immersion in a 1% sodium hypochlorite solution for 2 min, rinsed three times in sterile distilled water, placed in Petri plates containing potato dextrose agar (PDA), and incubated at 25°C for 5 to 7 days in darkness. Mycelial plugs were excised from the edge of the actively growing fungal colony and aseptically transferred to fresh PDA medium and incubated at 25°C for 6 days. Five monoconidial cultures were obtained by transferring germinated spores to Petri plates with fresh PDA. One isolate was selected as representative for morphological and molecular identification. Colonies of pure cultures exhibited greyish-white aerial mycelium and abundant salmon-pink conidial masses. Conidia (n = 100) were subcylindrical, hyaline, straight, one-celled, with rounded ends, measuring 13.6 to 17.7 × 4.4 to 5.9 μm. Conidial appressoria were ovoid and brown to dark brown. Based on morphological characteristics, the fungus was identified within the Colletotrichum gloeosporioides species complex (Weir et al. 2012). The isolate was designated UACH-177 and deposited in the Culture Collection of Phytopathogenic Fungi at the Chapingo Autonomous University. For molecular identification, the internal transcribed spacer (ITS) region (White et al. 1990) and fragments of Apn2 (Rojas et al. 2010), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and β-tubulin 2 (TUB2) genes (Weir et al. 2012) were amplified by polymerase chain reaction and sequenced. The sequences were deposited in GenBank (accession nos.: ITS, MG821312; Apn2, MG821310; GAPDH, MG821311; and TUB2, MG821313). A phylogenetic analysis using Bayesian inference and including published ITS, Apn2, GAPDH, and TUB2 data for C. gloeosporioides and other Colletotrichum species was performed. The phylogenetic analysis showed the sequences were grouped into the clade of C. gloeosporioides. To confirm the pathogenicity of the fungus, 20 tejocote fruits were surface disinfested by immersion in a 1% sodium hypochlorite solution for 1 min, washed three times with sterile distilled water, and dried on sterilized filter paper. Inoculations were performed by deposition of 10 μl of a conidial suspension (10⁶ spores/ml) on the fruit surface. Ten fruit were mock inoculated with distilled water as a control. All fruits were kept in a moist chamber at 25°C for 10 days. The pathogenicity test was repeated twice. Disease symptoms were observed on all inoculated fruit after 7 days, whereas control fruit did not develop symptoms. Fungal colonies were reisolated from all symptomatic fruits and were found to be morphologically identical to the original isolate inoculated on tejocote fruits, thus fulfilling Koch’s postulates. In Mexico, Garcia-Alvarez (1976) reported Colletotrichum sp. on fruits of Crataegus mexicana; however, that report was not supported by morphological characterization nor pathogenicity tests. To our knowledge, this is the first report of C. gloeosporioides causing anthracnose of C. gracilior in Mexico and worldwide.

Apple bitter rot is a globally widespread disease that is observed on fruits both pre-harvest and post-harvest, contributing to considerable economic losses. While the Colletotrichum acutatum species complex are predominant in Europe (Baroncelli et al. 2014; Amaral Carneiro and Baric 2021), in recent years, the Colletotrichum gloeosporioides species complex are emerging, raising many concerns (Amaral Carneiro et al. 2023). Circular, slightly sunken, brown lesions with acervuli produced in concentric spots were observed on 'Story® Inored' cultivar harvested in September 2022 from an organic orchard in Masi (Padova province, Italy), with a disease incidence close to 30%. From ten diseased apples, tissue samples were excised under aseptic conditions from surface-cleaned fruit at the margin between healthy and diseased pulp tissue, transferred to potato dextrose agar medium and incubated in the dark at 25 °C for 7 days, whereafter five single-spore cultures were obtained. Pure colonies grown at 25 °C for 7 days appeared light gray-white on the upper side with floccose aerial mycelium, while the reverse side was dark gray with a distinct margin. Conidia were hyaline, cylindrical in shape with both ends rounded or one end acute and measured 16.6 ± 1.4 × 6.1 ± 0.5 μm [mean ± SD] (n=50) as described by Diao et al. 2017. To identify the species, genomic DNA of a representative isolate (C38) was extracted, beta-tubulin (TUB2), calmodulin (CAL), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), glutamine synthetase (GS), Apn2-Mat1-2 intergenic spacer (ApnMat) genes and the internal transcribed spacer (ITS) region, were amplified by PCR and Sanger sequenced (Rojas et al. 2010; Weir et al. 2012). The obtained DNA sequences of, TUB2, CAL, GAPDH, GS, ApnMat and ITS were submitted to GenBank under the accession numbers OR025589, OR025586, OR025587, OR025588, OR025585 and OR004800, respectively. A MegaBLAST analysis resulted 100 % identity to the epitype CAUG7 of Colletotrichum grossum (Diao et al. 2017) for GAPDH (KP890159), for TUB2 (KP890171), 99.85% for CAL (KP890147) and 99,5 % for ITS (KP890165). The phylogenetic tree constructed by concatenation with the obtained sequences, as well as references, revealed that the C38 isolate clustered within C. grossum, confirming the BLAST approach. Pathogenicity tests were performed on 40 'Story® Inored' apples cleaned and wounded with a sterilized needle and exposed to two different conditions: 20 apples (10 inoculated with 20 μl of spore suspension (105 ml-1) and 10 with sterile water as control) were incubated at 20°C with a 12-hour photoperiod for 14 days, while the remaining 20 apples, prepared with same approach, were placed at 1°C for 3 months, then at room temperature for 14 days. Symptoms appeared after 6 days on apples incubated at 20°C, whereas those stored at 1°C displayed symptoms at 11 days after being placed at room temperature. In both conditions, lesions were similar to those observed on the original fruits; while the controls remained asymptomatic. Identity of reisolated fungal colonies was confirmed by CAL, GAPDH and GS region sequence analysis. C. grossum has been reported rarely: in 2017 on Capsicum annuum var. grossum in China, in 2018 on Mangifera indica leaves in Cuba, and in 2021 on Rhyncospermum jasminoides in Italy (Diao et al. 2017; Manzano León et al. 2018; Guarnaccia et al. 2021). To the best of our knowledge, this is the first report of apple bitter rot caused by Colletotrichum grossum worldwide.

Black pepper (Piper nigrum L.) has been commonly cultivated as a spice crop in northeast India. In August 2021, anthracnose leaf spot was observed on black pepper vines with 50 to 60% of disease incidence in Assam Agricultural University, Jorhat (26.7509° N, 94.2037° E), Assam, India. On average, 80% of the leaves per individual vine were affected by this disease. Foliar symptoms initially appeared as chlorotic circular spots, which then coalesced into larger irregular lesions. The centers of the spots were brown, papery in texture, and surrounded by a yellow halo. Numerous acervuli at the center of the spots were observed. Ten vines from the orchard were sampled to identify the causal agent. Symptomatic leaves along with some healthy portion were cut (3 to 4.5 mm2), surface-sterilized in 70% ethanol for 30 s, rinsed in sterile distilled water twice, dried on sterilized filter paper, aseptically plated on potato dextrose agar (PDA) amended with Streptomycin sulphate (30 mg/L), and then incubated at 25°C for four days. Two Colletotrichum isolates were recovered from infected tissues and purified by the hyphal tip method. Fungal colonies on PDA were cottony, dense, white to gray in color, and with salmon pink conidial masses. Conidia (n = 50) were 13.6 to 19.8 × 4.2 to 6.4 μm, cylindrical, hyaline, single-celled, smooth-walled, and with rounded ends. Conidiophores were aseptate, hyaline, short and branched. Based on morphological features, the isolates were identified in the Colletotrichum gloeosporioides species complex (Weir et al. 2012). For accurate identification of two isolates, the DNA was extracted from pure culture. The internal transcribed spacer (ITS) region, actin (ACT), β-tubulin 2 (TUB2) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) genes were amplified by polymerase chain reaction (Weir et al. 2012) and sequenced. The sequences were deposited in the GenBank database (ITS: OP297054 and OP296876; ACT: OP327082 and OP327081; TUB2; OP327086 and OP327085; GAPDH: OP327084 and OP327083). A BLAST analysis of ITS, ACT, TUB2 and GAPDH sequences revealed 99.5-100%, 99.9-100%, 99.9-100% and 99.8-100% similarity respectively to C. siamense for both isolates in NCBI database. The pathogenicity tests were carried out on potted four months old vine cuttings of P. nigrum L., which were kept in a greenhouse. Ten healthy plants were sprayed with 50 µl of conidial suspension of each isolate (107 conidia ml-1, 10 ml/plant). Five control plants were sprayed with sterile distilled water. The plants were covered with sterilized plastic bags after inoculation to maintain humidity and kept in a greenhouse at day/night temperatures of 25 ± 2°C and 17 ± 2°C (Zhang et al., 2021). Within eight days, all the inoculated plants showed symptoms similar to those observed in the field, whereas control plants were asymptomatic. The pathogenicity test was repeated twice. C. siamense was consistently reisolated from the lesions and was confirmed by morphological characterization and molecular assays as described above in this note, whereas no fungus was isolated from control leaves. To our knowledge this is the first report of C. siamense causing black pepper anthracnose in northeast India. The pathogen has significant potential for causing high losses in black pepper production. These data will help researchers to develop effective management strategies for this disease.

Okra is highly perishable due to its high respiration rate and high-water content, thus reducing its marketability. Hence, this study was conducted to evaluate the effect of different polysaccharide-based edible coatings on the physicochemical and physiological properties of okra fruits. The experiment was laid out in a completely randomized design with nine treatments and three replications. Four edible coatings were assessed at two different concentrations. The treatments comprised T0: uncoated (control), T1: 1% sodium alginate (AL), T2: 2% sodium alginate, T3: 1% pectin, T4: 2% pectin, T5: 1% carboxymethyl cellulose, T6: 2% carboxymethyl cellulose, T7: 1% cornstarch and T8: 2% cornstarch. Okra fruits were stored in refrigerated conditions with the temperature ranging from 9 to 11 °C and relative humidity of 76 to 85%. Samples were collected on days 0, 3, 6, 9, 12 and 15 for analysis of weight loss, firmness, shriveling, pH, total soluble solids (TSS), titratable acidity (TA), vitamin C, respiration rate, ethylene production and microbial growth. The results indicated that the use of polysaccharide-based edible coatings significantly influenced moisture and dry matter content, weight loss, firmness, shriveling, pH, TSS, TA, vitamin C, respiration and microbial count of okra fruits. The various coatings, including alginate, pectin, carboxymethyl cellulose and cornstarch, significantly preserved the quality of okra compared with the control treatment. Among the four coatings used, 2% alginate (w/v) demonstrated the most effective preservation of the fruit quality of okra.

Mango fruit (cv. Seddik) is known as a delicate fruit for storage after harvest. Herein, carboxymethyl cellulose (CMC) and guar gum-based silver nanoparticles (AgNPs) were used as fruit coatings, and their effects on postharvest storage behavior and quality attributes were investigated. AgNPs were synthesized using a chemical reduction approach and then combined with CMC and guar gum as coating bases. Mango fruits were coated with the developed and pre-characterized CMC-AgNPs and guar gum-AgNPs, and then packed and stored at 13 °C for 4 weeks. The results showed an increase in weight loss, respiration rate, total soluble solids (TSS), total sugars, and total carotenoids over the storage period. However, this increase was comparatively less significant in coated fruits compared to uncoated fruits. Firmness and titratable acidity (TA) significantly decreased during storage, but this decrease was less in coated fruits. Silver traces in fruit pulp samples were not detected. These findings showed the efficacy of CMC-AgNP and guar gum-AgNP coatings in delaying mango fruit ripening and maintaining fruit quality during cold storage. Therefore, these coatings could be promising alternative materials for extending the postharvest life and marketing period of mango fruit.