Interventions based on alternative and sustainable strategies for postharvest control of anthracnose and maintain quality in tropical fruits.

Colletotrichum spp. is a phytopathogen causing anthracnose in a variety of tropical fruits. Strategies used to control postharvest diseases in tropical fruits typically rely on the use of synthetic fungicides, which have stimulated the emergence of resistant pathogens. Safer alternative strategies to control anthracnose in tropical fruits have been described in the literature. This review presents and discusses the main innovative interventions concerning the application of sustainable alternative strategies in the postharvest control of pathogenic Colletotrichum species in tropical fruits, with a particular emphasis on the studies published in the last 5 years. The available studies have shown the use of various methods, including physical barriers, natural antimicrobials, and biological control with antagonistic microorganisms, to reduce anthracnose lesion severity and incidence in tropical fruits. The available literature showed high inhibitory activity in vitro, reduced anthracnose incidence and lesion diameter, and total disease inhibition in tropical fruits. Most studies focused on the inhibition of Colletotrichum gloeosporioides on avocado, papaya, and mango, as well as of Colletotrichum musae on banana; however, the inhibition of other Colletotrichum species was also demonstrated. The application of emerging sustainable alternative methods, including natural antimicrobial substances, also stimulated the induction of defense systems in tropical fruits, including enzymatic activity, such as polyphenol oxidase, peroxidase, and phenylalanine ammonia-lyase. The retrieved data helped to understand the current state of the research field and reveal new perspectives on developing efficient and sustainable intervention strategies to control pathogenic Colletotrichum species and anthracnose development in tropical fruits.

Visualized detection of tobacco anthracnose by RPA-LFD.

Anthracnose caused by Colletotrichum spp. is a widespread fungal disease that is detrimental to tobacco growth and inflicts economic damage up to 100 million in tobacco-growing regions in China. An early diagnostic tool is vital for the accurate determination and management of anthracnose in the field. This study investigated the diversity of Colletotrichum spp. on tobacco leaves with anthracnose and developed a recombinase polymerase amplification-lateral flow dipstick (RPA-LFD) diagnostic method for the rapid and equipment-independent detection of the main Colletotrichum spp. causing tobacco anthracnose. This assay targeted the chitin synthase gene (chs1) and could be performed in a few minutes (6-10 min). All isolates of C. kastii, C. fructicola and C. gloeosporioides yielded positive results using the RPA-LFD assay, and no cross-reaction occurred with other fungal species from tobacco or other hosts. The detection threshold was 1 pg of genomic DNA under optimal reaction conditions. The entire RPA-LFD assay enabled the detection of pathogen visualization within 30 min without specialized equipment by combining a polyethylene glycol-KOH method for extracting DNA rapidly from tobacco leaves infected with C. kastii, C. fructicola and C. gloeosporioides. Based on these results, the RPA-LFD assay is easy to operate, rapid and equipment independent and is promising for development as a kit to diagnose tobacco anthracnose in resource-limited settings at point-of-care.

Heliconia subulata, a New Host of Colletotrichum tropicale Causing Anthracnose in China.

Heliconia subulata is a common ornamental plant, it has been widely planted in southern China for greening parks, roads, and residential areas. H. subulata plants with spots on their leaves were observed in East Coast Wetland Park (18°16'53.37″N, 109°30'19.36″E), Sanya City, Hainan Province, China on Aug. 31, 2023. The symptoms of the leaves are irregular gray-white, spots, that develop into brown and black, with yellow halos at the disease-health junction. Following an on-the-spot investigation, it was found that the incidence of the disease was 40 to 50%. The leaves were disinfected with 70% ethanol for 1 min, rinsed with sterile water 3 times, disinfected for 1 min with 0.1% HgCl2, rinsed with sterile water 3 times, dried, put on potato dextrose agar (PDA) and incubated at 28℃ for 7 days. The red conidia pile was selected from the culture, dispersed in sterile water and diluted to 20 µL containing 1 to 2 conidia. After absorbing 20 µL spore suspension for many times and inoculating it on the new PDA plate, five pure cultures of single spore, J-1-1 to J-1-5, were obtained. After 7 days of growth, the colonies were grayish aerial mycelium on the front and light orange conidia on the reverse. The white aerial mycelia, conidia, acervulus, and appressorium were observed (Supplementary Fig. S1). The morphological characteristics showed that the isolate had the same characteristics as the previously described Colletotrichum spp. (Wang et al. 2021). The genomic DNA of isolates J-1-1 and J-1-5 were extracted by Fungal DNA Kit (OMEGA bio-tek, Guangzhou, China). The internal transcribed spacer (ITS), glyceraldehyde-3-phosphate dehydrogenase (GADPH), and ß-tubulin 2 genes (TUB2) were amplified by primers ITS1/ITS4, GDF/GDR, and Bt2a/Bt2b, respectively (Weir et al. 2012). Based on sequencing and gene sequence alignment analysis, it was found that the consistency between the ITS sequences of isolates J-1-1 and J-1-5 was 99.82%. The consistency between GADPH and TUB2 sequences was 100%. The gene sequences of isolates J-1-1 and J-1-5 were submitted to GenBank with accession numbers PP455510/PP455511 (ITS), PP510210/PP510211 (GADPH) and PP510212/PP510213 (TUB2) respectively. Based on the BLAST analysis, the three sequences were more than 99% identical to those of the C. tropicale strain FC1 (ITS: MT192648, GAPDH: MT155819, TUB2: MT199874; Duan et al. 2022). A phylogenetic tree was constructed by MEGA 11 based on the ITS, GADPH, and TUB2 gene sequence by the maximum-likelihood method. The results showed that the isolates J-1-1 and J-1-5 were clustered with C. tropicale CBS:124949 (Supplementary Fig. S2). Based on morphological and molecular biological analysis, two isolates were identified as C. tropicale. To further test the pathogenicity of isolates J-1-1 and J-1-5, spore suspensions (1×106 conidia/mL) were prepared and 20 µL spore suspensions were inoculated on the leaves of healthy H. subulata potted plants stabbed with sterile toothpicks. Three leaves were inoculated in each treatment, and sterile water was inoculated as a control. The treated plants were placed in an incubator with a temperature of 28℃, relative humidity of 90%, and light/dark (12h/12h). After 15 days, the spore suspension treatment showed the same symptoms as the naturally diseased H. subulata plants in the field, but the leaves treated with sterile water were not infected (Supplementary Fig. S1). The morphology of the isolates obtained from diseased leaves was the same as that of isolates J-1-1 and J-1-5 on the PDA plate. To our knowledge, this is the first report of H. subulata, a new host of C. tropicale causing anthracnose in China.

Colletotrichum aeschynomenes Causing Anthracnose in Combretum indicum in Guangxi, China.

Combretum indicum（L.）Jongkind, distributed in Southeast Asia, is widely planted in southern China for its ornamental and medicinal value. In February 2023, anthracnose symptoms were observed on C. indicum leaves in Nanning Garden Expo (N22°43', E108°28'), Guangxi, China, causing severe defoliation of infected plants with a foliar disease incidence ranging from 40 to 60% (n = 100) in a 2 ha field. Disease symptoms began with small red spots (2 to 3 mm by 2 to 3 mm) on the leaves and gradually enlarged to larger irregular light grey lesions with yellowish halos (3 to 5 mm by 2 to 8 mm). In the late stage, spots merged into larger irregular lesions (5 to 15 mm by 6 to 13 mm) and the necrotic lesions abscised. Three diseased samples in total were collected from plants in three different locations. Symptomatic leaves were cut into small pieces (3×3 mm), disinfected with 75% ethanol solution for 10 s, 2% NaClO for 1 min followed by three washes in sterile distilled water. Tissue pieces were separately plated on potato dextrose agar (PDA) and incubated at 25°C for five days. One representative isolate from each sample (SJ-1, SJ2-1 and SJ3-1) were chosen for further analysis. Colonies were villiform, initially white, later turning gray in 7 days on PDA at 25℃. The average diameter for colonies were 8.1 cm, 8.0 cm and 8.1 cm for SJ1-1, SJ2-1 and SJ3-1, respectively. Conidia were aseptate, hyaline, cylindroid, and averaged 11.94 µm × 5.04 µm, 11.78 µm × 5.14 µm and 11.74 µm × 4.59 µm (n=90) for SJ1-1, SJ2-1 and SJ3-1, respectively. The characteristics were close to the descriptions of Colletotrichum spp. (Weir et al. 2012). Genomic DNA was extracted from 7-day-old aerial mycelia of these isolates. The internal transcribed spacer (ITS), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), actin (ACT), ß-tubulin (TUB2), chitin synthase (CHS-1), calmodulin (CAL) and the intergenic region between apn2 and MAT1-2-1 (ApMat) were amplified using primers ITS1/ITS4 (White et al. 1990), GDF/GDR, ACT-512F/ACT-783R, T1/Bt2b, CHS-79F/CHS-354R, CL1C/CL2C (Weir et al. 2012) and AM-F/AM-R (Silva et al. 2012), respectively. Sequences were deposited in GenBank (ITS: OR540240-OR540242; GAPDH: PP328968-PP328970; ACT: PP328959-PP328961; TUB2: PP328971-PP328973; CHS-1: PP328965-PP328967; CAL: PP328962-PP328964 and ApMat: OR548253-OR548255). A phylogenetic analysis was made via Bayesian inference based on the concatenated sequences (ITS, GAPDH, ACT, TUB2, CHS-1, CAL and ApMat). According to morphology and phylogenetic analysis, SJ1-1, SJ2-1 and SJ3-1 were identified as C. aeschynomenes. Pathogenicity was confirmed on leaves with and without wounds of 24 one-year-old C. indicum plants in a greenhouse in Nanning, Guangxi Province. The wound was made with a sterilized needle. Wounded and unwounded leaves were inoculated with 20 µl of conidial suspension (106 spores/ml in 0.1% sterile Tween 20) of the three isolates and control plants were inoculated with water containing 0.1% sterile Tween 20 (6 leaves/plant, 3 plants/treatment). All plants were covered with plastic bags to maintain a high humidity environment and placed in a 28°C growth chamber with constant light. After 7 days of incubation, necrotic lesions were observed on inoculated wounded leaves, whereas unwounded leaves and control plants showed no symptoms. The fungi were re-isolated from symptomatic leaves, completing Koch's postulates. These species can cause severe diseases in a variety of plants worldwide, such as Manihot esculenta, Theobroma cacao and Myrciaria dubia (Sangpueak et al. 2018; Nascimento et al. 2019; Matos et al. 2020). To our knowledge, this is the first report of C. aeschynomenes causing C. indicum leaf anthracnose in China. The results will provide valuable information for management of anthracnose in C. indicum.

Vernicia fordii leaf extract inhibited anthracnose growth by downregulating reactive oxygen species (ROS) levels in vitro and in vivo.

Background: Colletotrichum fructicola is a predominant anthracnose species in Camellia oleifera, causing various adverse effects. Traditional intercropping Vernicia fordii with C. oleifera may enhance anthracnose resistance, but the mechanism remains elusive. Methods: We utilized UPLC-MS/MS and acid-base detection to identify the major antimicrobial alkaloid components in the V. fordii leaf extract. Subsequently, by adding different concentrations of V. fordii leaf extract for cultivating C. fructicola, with untreated C. fructicola as a control, we investigated the impact of the V. fordii leaf extract, cell wall integrity, cell membrane permeability, MDA, and ROS content changes. Additionally, analysis of key pathogenic genes of C. fructicola confirmed that the V. fordii leaf extract inhibits the growth of the fungus through gene regulation. Results: This study discovered the alkaloid composition of V. fordii leaf extract by UPLC-MS/MS and acid-base detection, such as trigonelline, stachydrine, betaine, and O-Phosphocholine. V. fordii leaf extract successfully penetrated C. fructicola mycelia, damaged cellular integrity, and increased ROS and MDA levels by 1.75 and 2.05 times respectively, thereby inhibiting C. fructicola proliferation. By analyzing the key pathogenic genes of C. fructicola, it was demonstrated that the antifungal function of V. fordii leaf extract depends mainly on the regulation of RAB7 and HAC1 gene expression. Therefore, this study elucidates the mechanism of V. fordii -C. oleifera intercropping in strengthening anthracnose resistance in C. oleifera, contributing to efficient C. oleifera cultivation.

Fungicide resistance in Colletotrichum fructicola and Colletotrichum siamense causing peach anthracnose in China.

Peach is one of the popular and economically important fruit crops in China. Peach cultivation is hampered due to attacks of anthracnose disease, causing significant economic losses. Colletotrichum fructicola and Colletotrichum siamense belong to the Colletotrichum gloeosporioides species complex and are considered major pathogens of peach anthracnose. Application of different groups of fungicides is a routine approach for controlling this disease. However, fungicide resistance is a significant drawback in managing peach anthracnose nowadays. In this study, 39 isolates of C. fructicola and 41 isolates of C. siamense were collected from different locations in various provinces in China. The sensitivity of C. fructicola and C. siamense to some commonly used fungicides, i.e., carbendazim, iprodione, fluopyram, and propiconazole, was determined. All the isolates of C. fructicola collected from Guangdong province showed high resistance to carbendazim, whereas isolates collected from Guizhou province were sensitive. In C. siamense, isolates collected from Hebei province showed moderate resistance, while those from Shandong province were sensitive to carbendazim. On the other hand, all the isolates of C. fructicola and C. siamense showed high resistance to the dicarboximide (DCF) fungicide iprodione and succinate dehydrogenase inhibitor (SDHI) fungicide fluopyram. However, they are all sensitive to the demethylation inhibitor (DMI) fungicide propiconazole. Positive cross-resistance was observed between carbendazim and benomyl as they are members of the same methyl benzimidazole carbamate (MBC) group. While no correlation of sensitivity was observed between different groups of fungicides. No significant differences were found in each fitness parameter between carbendazim-resistant and sensitive isolates in both species. Molecular characterization of the ß-tubulin 2 (TUB2) gene revealed that in C. fructicola, the E198A point mutation was the determinant for the high resistance to carbendazim, while the F200Y point mutation was linked with the moderate resistance to carbendazim in C. siamense. Based on the results of this study, DMI fungicides, e.g., propiconazole or prochloraz could be used to control peach anthracnose, especially at locations where the pathogens have already developed the resistance to carbendazim and other fungicides.

First Report of Colletotrichum gigasporum causing Anthracnose of chili pepper in South Korea.

Anthracnose, a destructive fungal disease, poses a significant threat to chili pepper (Capsicum annuum L.) production worldwide (de Silva et al. 2019). In South Korea, anthracnose outbreaks have traditionally been attributed to several Colletotrichum species such as C. gloeosporioides and C. acutatum. About 10% of the yield (chili production) is lost annually in South Korea due to chili anthracnose (Oo et al. 2020). During field surveys conducted in August 2017, symptomatic lesions resembling anthracnose were observed on chili pepper in two farmer's fields (Gochang and Cheongyang) in South Korea. Affected fruits exhibited characteristic symptoms, including circular sunken lesions with dark margins and abundant orange spore masses on the surface. About 20% of chili pepper fruit were affected in each field with an area of about 0.2 ha. Five putative Colletotrichum spp. isolates were obtained from six affected fruits (three from each field) following the procedure described by Cai et el. (2009). Three isolates (C01049, C01111, and C01115), representing each location, were selected to identify at the species level. Colonies on potato dextrose agar (incubated at 25°C in the dark for 7 days) were cottony with entire margins, white aerial mycelium and dark gray in the center. Conidia were hyaline, aseptate, cylindrical with bothnds round, and 17.8 - 30.5 × 6.0 -10.0 µm (mean 23.8 ×7.9 µm, n = 30). Appressoria were dark brown, irregular but mostly ovoid with smooth walls. These morphological features align with those of Colletotrichum spp. within the Colletotrichum gigasporum species (Liu et al. 2014). The identity of the pathogen was further confirmed through multi-locus phylogenetic analysis. The target genes including ITS, ACT, CHS-1, GAPDH, TUB2, and GS were amplified and sequenced using the primer sets ITS1/ITS4, ACT 512F/ ACT-783R, CHS-79F/ CHS-345R, GDF/GDR, T1/Bt2b, and GSF1/GSR1, respectively (Weir et al. 2012; Liu et al. 2014). The resulting sequences were deposited in GenBank (accession no: ITS: MT605261, MT605262, LC823714; ACT: MT612991, MT612992, LC823718; CHS-1: MT612993, MT612994, LC823717; GAPDH: LC811375, LC811376, LC823716; TUB2: MT612997, MT612998, LC823715; GS: LC811377, LC811378, LC823719). The constructed Bayesian and maximum likelihood tree based on combined sequences of ITS, ACT, CHS-1, GAPDH, TUB2, and GS confirmed the identification of the isolates (C01049, C01111, C01115) as C. gigasporum. Pathogenicity tests were conducted by inoculating healthy chili fruit with 70 µL of a conidial suspension (1×106 conidia /mL) of pure cultures of the isolates. The conidial suspension was applied on 10 wounded or 10 non-wounded fruit. The same number of fruit were treated with sterile distilled water as controls. Within 5 days of inoculation, symptoms consistent with anthracnose developed on the inoculated wounded fruit, whereas non-wounded and control fruit remained asymptomatic. This experiment was repeated twice. Colletotrichum gigasporum was re-isolated from diseased tissue of inoculated fruit. Colletotrichum gigasporum has been identified as the cause of anthracnose on Dalbergia odorifera, Carica papaya in China, and Brassica oleracea in India (Wan et al., 2018; Saini et al. 2022; He et al. 2023). To the best of our knowledge, this report marks the first documented instance of C. gigasporum causing anthracnose of chili pepper in South Korea. These results indicate that various species of Colletotrichum can be the fungi causing chili pepper anthracnose. The findings of this study emphasize the need for effective disease management strategies to mitigate impact of C. gigasporum on chili pepper cultivation in the region.

Physical and biological properties of alginate-based cinnamon essential oil nanoemulsions: Study of two different production strategies.

Nanoemulsions are a promising alternative for essential oil incorporation into active coatings. The influence of the preparation steps order on nanoemulsions' physical properties is still little explored. This study aimed to analyze the effect of the sequence of preparation steps and of the oil and polymer concentration on the stability, physical properties, and antifungal activity of alginate-based cinnamon essential oil nanoemulsions. The nanoemulsions were produced by two strategies: (I) preparation directly into an alginate solution (Ultra-Turrax at 10,000 rpm for 5 min + Ultrasound 150 W for 3 min); and (II) preparation in water (Ultra-Turrax at 10,000 rpm for 5 min + Ultrasound 150 W for 3 min) followed by homogenization with a sodium alginate solution (Ultra-Turrax at 10,000 rpm for 1, 3 or 5 min). The nanoemulsion prepared by the second strategy showed better stability, physical properties, and antifungal activity. In general, the presence of alginate hindered the cavitation effects of ultrasound, leading to the increase of droplets size and consequently affecting emulsions stability, turbidity, and antifungal properties.

First report of Colletotrichum orbiculare causing anthracnose of pointed gourd in India.

Pointed gourd (Trichosanthes dioica Roxb.), of the Cucurbitaceae family, is widely cultivated as a vegetable in many countries such as Bangladesh, India, Pakistan, Myanmar, Nepal and Sri Lanka. Over 800,000 metric tons of pointed gourds are produced annually in India, where cultivation is estimated to occupy over 33,000 hectares of land (MoA & FW, Government of India). In summer 2018, significant losses (approximately 15-20%) occurred in the sub-Himalayan region in West Bengal state of India (21.14-21.30° N, 78.82-79.02°E) due to a disease with typical anthracnose-like symptoms on the fruits. Light yellowish, small sized round to irregular spots were also apparent on the leaves. These spots gradually increased in size and turned into light brown and were surrounded by yellow halo. The lesions on the fruits were circular, yellow-brown, necrotic and sunken. A survey of four fields (1.5 ha) was conducted and a disease incidence of 30-40% was observed. Necrotic tissues from fruit as well as leaves were cut into approximately 5 mm2, surface sterilized with 0.1% HgCl2, plated in potato dextrose agar and incubated at 28ºC for 7 days in the dark. A total of 50 morphologically similar colonies were obtained from 20 sampled fruits and 10 sampled leaves. Fungal colonies were initially white, becoming gray as the cultures aged on PDA. The cultures developed black acervuli around the center of the colony. Setae were brown in colour, 1-5 septate, 40-100 µm long. Conidia were also observed through light and scanning electron microscopy and exhibit as (4-6 ×13-19 µm) hyaline, aseptate, cylindrical to oblong, with one end round and other truncate. The morphological characteristics were found similar to Colletotrichum orbiculare Damm, P.F. Cannon & Crous as reported by Damm et al. (2013). Ten isolates were obtained by transferring hyphal tips to new PDA plates and incubating under the same conditions. To confirm the identity of the pathogen, genomic DNA was extracted from five pure isolates (PG-Pha, PG-Pha-2, PG-Pha-3, PG-Pha-4, PG-Pha-5) with the cetyltrimethylammonium bromide (CTAB). Further, the ITS1-5.8S-ITS2 region, D1/D2 region of the 28S rRNA large subunit (LSU), Actin (ACT) gene and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) gene were amplified using specific primers, ITS1/ITS4 (White et al. 1990), NL1/NL4, ACT1/ACT2 and GDF1/GDR1 respectively and PCR conditions described in Damm et al. (2012). A GenBank BLAST search showed 99-100% identity to the Colletotrichum orbiculare (Acc. Nos. KP898988 for ITS1-5.8S-ITS2, Z18997 for 28S rRNA, AB778553 for ACT gene, and KF178482 for GAPDH). All obtained sequences were submitted to the GenBank (Acc. Nos. MN006616, OP811046-OP811049, [ITS1-5.8-ITS2], MN006684, PP391616-PP391619 [28S rRNA], MN168524, PP400822-PP400825 [ACT gene], OP627091, PP400826-PP400829 [GAPDH]). For phylogenetic analysis, MEGA version 11 (Tamura et al. 2021) was used to construct a maximum likelihood tree with 1000 bootstrap replicates, based on a concatenation alignment of three gene sequences (ITS, Actin and GAPDH) of the all the five C. orbiculare isolates as well as sequences of other Colletotrichum species obtained from GenBank. The cluster analysis revealed that, isolate PG-Pha form a cluster with other C. orbiculare isolates. Pathogenicity tests were conducted to confirm Koch's postulates. Pathogenicity tests were performed in mature fruits by inoculating them (n=8) with 10 µl of a 1×106 conidia/ml suspension at needle puncture wound sites. In control set up sterile distilled water was pipetted on fruits. Fruits were placed on sterile trays covered with glasses and incubated at humid chambers at 28±2ºC with 12 h of light. Healthy one-month old potted pointed gourd plants (n=15) were sprayed with conidial suspension until run-off. A set of 15 plants were sprayed with sterile distilled water and maintained as control. The plants were kept in a greenhouse at 25ºC, >75% relative humidity, and a 16/8 h day/night cycle for 15 days. Sterile distilled water was sprayed on the plants at one day interval to maintain the humidity. Inoculated fruits started showing yellowing symptoms one day post inoculation and gradually yellow-brown sunken spots became visible at the place of puncture, whereas control fruits remain symptomless even after 7 days of inoculation. Inoculated leaves showed disease symptoms similar to those observed in the field whereas leaves of control sets were symptomless even after 15 days. The pathogenicity test was repeated thrice under the same conditions mentioned before. C. orbiculare was successfully re-isolated from all the symptomatic tissues of leaves as well as fruits, completing Koch's postulates. Previously, the pathogen has been reported as an important anthracnose pathogen of Cucurbitaceae, especially of cucumber (Cucumis sativus), melons (Cucumis melo), watermelon (Citrullus lanatus), pumpkin (Cucurbita pepo) and squash (Cucurbita maxima) (Farr and Rossman 2020). To our knowledge, this is the first report of C. orbiculare causing anthracnose of pointed gourd. This disease represents a threat to producers in India and central Asia. Further research may contribute to the development of management strategies for this disease.

Identification of the Ilex macrocarpa anthracnose pathogen and the antifungal potential of the cell-free supernatant of Bacillus velezensis against Colletotrichum fioriniae.

Introduction: Anthracnose is a significant fungal disease that affects tree growth and development, with Colletotrichum spp. exhibiting host non-specificity and targeting various organs, making disease control challenging. Methods: This study aimed to identify the pathogenic species causing anthracnose in Ilex macrocarpa in Nanchong, Sichuan Province, and screen effective fungicides, particularly biological ones. The pathogen was identified as Colletotrichum fioriniae through morphological observation, pathogenicity assays, and molecular biological methods. Three biological and five chemical fungicides were evaluated for their effects on the mycelial growth and spore germination rate of the pathogen. Results: The results indicated that prochloraz was the most effective chemical fungicide, while the cell-free supernatant (CFS) of Bacillus velezensis had the most significant inhibitory effect among the biological fungicides. Transcriptome analysis revealed that the CFS of B. velezensis significantly reduced the expression of genes associated with ribosomes, genetic information processing, membrane lipid metabolism, and sphingolipid biosynthesis in C. fioriniae. Additionally, the glutathione pathway's expression of various genes, including key genes such as GST, GFA, Grx, TRR, and POD, was induced. Furthermore, the expression of 17 MFS transporters and 9 ABC transporters was increased. Autophagy-related ATGs were also affected by the B. velezensis CFS. Discussion: These findings suggest that the B. velezensis CFS may inhibit C. fioriniae through interference with ribosomes, genetic information processing, cell membrane metabolism, and energy metabolism. These results provide potential target genes for the B. velezensis CFS and insights into the antifungal mechanism by which B. velezensis inhibits C. fioriniae.

The Identification of Kabatiella zeae as a Causal Agent of Northern Anthracnose of Sorghum in China and Estimation of Host Resistance.

Sorghum northern anthracnose is a leaf disease affecting sorghum, which results in plant death and substantial yield loss. This study aimed to effectively understand the disease, clarify its biological characteristics, and evaluate the resistance of germplasm resources. A field sample was collected to isolate and purify the pathogen. The pathogen, identified as Kabatiella zeae Narita et Hiratsuka using both morphological and molecular techniques, was further confirmed as the causative agent of northern anthracnose of sorghum following Robert Koch's principles. The results revealed the optimal culture temperature to be 25 °C, preferred dark culture conditions, and the best growth on potato glucose agar medium with sucrose and L-leucine as the optimal carbon and nitrogen sources, respectively. A total of 138 sorghum germplasm resources were inoculated and evaluated using the isolated pathogen, with 20 lines (14.49%) exhibiting high resistance, 18 lines (13.04%) showing disease resistance, 27 lines (19.57%) demonstrating medium resistance, 37 lines (26.81%) being susceptible, and 36 lines (26.09%) classified as highly susceptible. The indoor fungicide screening was conducted through pathogen medium application, and enilconazole, pyraclostrobin, methylthiophanate, and flusilazole were screened for the best fungicide inhibition with a 100% inhibition rate compared with the control. This study provides reference for field pharmaceutical control in sorghum production.

Exploring the genetic basis of anthracnose resistance in Ethiopian sorghum through a genome-wide association study.

BACKGROUND: Sorghum anthracnose is a major disease that hampers the productivity of the crop globally. The disease is caused by the hemibiotrophic fungal pathogen Colletotrichum sublineola. The identification of anthracnose-resistant sorghum genotypes, defining resistance loci and the underlying genes, and their introgression into adapted cultivars are crucial for enhancing productivity. In this study, we conducted field experiments on 358 diverse accessions of Ethiopian sorghum. Quantitative resistance to anthracnose was evaluated at locations characterized by a heavy natural infestation that is suitable for disease resistance screening. RESULTS: The field-based screening identified 53 accessions that were resistant across locations, while 213 accessions exhibited variable resistance against local pathotypes. Genome-wide association analysis (GWAS) was performed using disease response scores on 329 accessions and 83,861 single nucleotide polymorphisms (SNPs) generated through genotyping-by-sequencing (GBS). We identified 38 loci significantly associated with anthracnose resistance. Interestingly, a subset of these loci harbor genes encoding receptor-like kinases (RLK), nucleotide-binding leucine-rich repeats (NLRs), stress-induced antifungal tyrosine kinase that have been previously implicated in disease resistance. A SNP on chromosome 4 (S04_66140995) and two SNPs on chromosome 2 (S02_75784037, S02_2031925), localized with-in the coding region of genes that encode a putative stress-induced antifungal kinase, an F-Box protein, and Xa21-binding RLK that were strongly associated with anthracnose resistance. We also identified highly significant associations between anthracnose resistance and three SNPs linked to genes (Sobic.002G058400, Sobic.008G156600, Sobic.005G033400) encoding an orthologue of the widely known NLR protein (RPM1), Leucine Rich Repeat family protein, and Heavy Metal Associated domain-containing protein, respectively. Other SNPs linked to predicted immune response genes were also significantly associated with anthracnose resistance. CONCLUSIONS: The sorghum germplasm collections used in the present study are genetically diverse. They harbor potentially useful, yet undiscovered, alleles for anthracnose resistance. This is supported by the identification of novel loci that are enriched for disease resistance regulators such as NLRs, LRKs, Xa21-binding LRK, and antifungal proteins. The genotypic data available for these accessions offer a valuable resource for sorghum breeders to effectively improve the crop. The genomic regions and candidate genes identified can be used to design markers for molecular breeding of sorghum diseases resistance.

Identification, Pathogenicity, and Fungicide Sensitivity of Colletotrichum Species Associated with Anthracnose on Italian Ryegrass in Southwestern China.

Italian ryegrass (Lolium multiflorum L.) is widely cultivated as an important forage worldwide because of its high nutritional value and good palatability. Anthracnose caused by Colletotrichum species was a common and new emerging disease of Italian ryegrass. In this study, 88 Colletotrichum isolates were collected from diseased leaves of Italian ryegrass planting regions in Sichuan, Chongqing and Guizhou provinces of southwestern China between 2019 and 2022. By pure culture technique, 15 representative single-spore isolates were obtained for further study. Multi-locus phylogenetic analysis coupled with morphological features showed that these isolates were finally identified as six new record species: C. cereale of the C. graminicola species complex, C. fioriniae and C. nymphaeae of the C. acutatum species complex, C. boninense and C. citricola of the C. boninense species complex, and C. nageiae. Pathogenicity tests indicated that all species could induce anthracnose symptoms; of these, C. cereale was more invasive than other species, followed by C. fioriniae, C. nageiae, C. citricola and C. boninense; C. nymphaeae was weakest pathogenic to Italian ryegrass plants (P ≤ 0.05). Fungicide sensitivity assays showed that iprodione, propineb and oxime·tebuconazole had strong inhibitory effect on the mycelial growth of six Colletotrichum species; in addition, azoxystrobin and fludioxonil also significantly inhibited the mycelial growth of C. nymphaeae and C. fioriniae, respectively. These results provide the basis for the diagnosis and detection in the field, pathogen identification and management of anthracnose on Italian ryegrass.

Comparative physiological and transcriptomic analyses provide induction resistance mechanisms of Bacillus tequilensis against Colletotrichum fructicola in Camellia oleifera.

Bacillus tequilensis DZY 6715 was isolated from healthy leaves in Camellia oleifera, and the strain DZY 6715 significantly inhibited anthracnose disease resulting from Colletotrichum fructicola in C. oleifera, besides, its associated mechanism of disease resistance was explored. B. tequilensis DZY 6715 treatment controlled mycelial growth of C. fructicola in C. oleifera, and significantly decreased C. oleifera anthracnose incidence and disease index compared with the control group. B. tequilensis DZY 6715 has strong biofilm forming ability, and also secretes extracellular ß-1, 3-glucanase and chitinase, which could cause cell membranes damage and increased cellular compound leakage. C.oleifera treated with DZY 6715 also effectively enhanced enzyme activities and stimulated the synthesis the substances related to phenylpropane metabolism and reactive oxygen metabolism. Moreover, transcript profiling analysis revealed more differentially expressed genes related to phenylpropanoid pathway metabolism and antioxidant system inducing by DZY 6715 compared with the control in C. oleifera. Thus, it can be concluded that B. tequilensis DZY 6715 is a suitable bio-control agent to control anthracnose disease in C. oleifera.

Genome evolution and transcriptome plasticity is associated with adaptation to monocot and dicot plants in Colletotrichum fungi.

BACKGROUND: Colletotrichum fungi infect a wide diversity of monocot and dicot hosts, causing diseases on almost all economically important plants worldwide. Colletotrichum is also a suitable model for studying gene family evolution on a fine scale to uncover events in the genome associated with biological changes. RESULTS: Here we present the genome sequences of 30 Colletotrichum species covering the diversity within the genus. Evolutionary analyses revealed that the Colletotrichum ancestor diverged in the late Cretaceous in parallel with the diversification of flowering plants. We provide evidence of independent host jumps from dicots to monocots during the evolution of Colletotrichum, coinciding with a progressive shrinking of the plant cell wall degradative arsenal and expansions in lineage-specific gene families. Comparative transcriptomics of 4 species adapted to different hosts revealed similarity in gene content but high diversity in the modulation of their transcription profiles on different plant substrates. Combining genomics and transcriptomics, we identified a set of core genes such as specific transcription factors, putatively involved in plant cell wall degradation. CONCLUSIONS: These results indicate that the ancestral Colletotrichum were associated with dicot plants and certain branches progressively adapted to different monocot hosts, reshaping the gene content and its regulation.

Screening for resistance to four fungal diseases and associated genomic regions in a snap bean diversity panel.

Anthracnose, white mold, powdery mildew, and root rot caused by Colletotrichum lindemuthianum, Scletorinia sclerotiorum, Erysiphe spp., and Pythium ultimum, respectively, are among the most frequent diseases that cause significant production losses worldwide in common bean (Phaseolus vulgaris L.). Reactions against these four fungal diseases were investigated under controlled conditions using a diversity panel of 311 bean lines for snap consumption (Snap bean Panel). The genomic regions involved in these resistance responses were identified based on a genome-wide association study conducted with 16,242 SNP markers. The highest number of resistant lines was observed against the three C. lindemuthianum isolates evaluated: 156 lines were resistant to CL124 isolate, 146 lines resistant to CL18, and 109 lines were resistant to C531 isolate. Two well-known anthracnose resistance clusters were identified, the Co-2 on chromosome Pv11 for isolates CL124 and CL18, and the Co-3 on chromosome Pv04 for isolates CL124 and C531. In addition, other lesser-known regions of anthracnose resistance were identified on chromosomes Pv02, Pv06, Pv08, and Pv10. For the white mold isolate tested, 24 resistant lines were identified and the resistance was localized to three different positions on chromosome Pv08. For the powdery mildew local isolate, only 12 resistant lines were identified, and along with the two previous resistance genes on chromosomes Pv04 and Pv11, a new region on chromosome Pv06 was also identified. For root rot caused by Pythium, 31 resistant lines were identified and two main regions were located on chromosomes Pv04 and Pv05. Relevant information for snap bean breeding programs was provided in this work. A total of 20 lines showed resistant or intermediate responses against four or five isolates, which can be suitable for sustainable farm production and could be used as resistance donors. Potential genes and genomic regions to be considered for targeted improvement were provided, including new or less characterized regions that should be validated in future works. Powdery mildew disease was identified as a potential risk for snap bean production and should be considered a main goal in breeding programs.

Diversity of Colletotrichum species associated with anthracnose on Euonymus japonicus and their sensitivity to fungicides.

As an evergreen shrub, Euonymus japonicus plays a crucial role in urban landscape construction, and its growth is affected by severe foliar anthracnose caused by Colletotrichum spp. However, the biodiversity of Colletotrichum species associated with anthracnose on E. japonicus remains undetermined. This study involved a two-year collection of E. japonicus leaf samples with typical anthracnose symptoms from 9 districts in Beijing, China. A total of 194 Colletotrichum isolates were obtained, and eight Colletotrichum species were subsequently identified using morphological characteristics and molecular identification with the ACT, GADPH, CHS, TUB2, and CAL genes, as well as the rDNA-ITS region. These species included Colletotrichum aenigma, C. fructicola, C. gloeosporioides, C. grossum, C. hebeiense, C. karstii, C. siamense, and C. theobromicola with C. siamense being the most prevalent (57%), followed by C. aenigma and C. theobromicola. Furthermore, C. fructicola, C. grossum and C. hebeiense are reported for the first time as causal agents of anthracnose on E. japonicus worldwide, and C. karstii is newly reported to be associated with E. japonicus anthracnose in China. Pathogenicity tests revealed that all tested isolates exhibited pathogenicity in the presence of wounds, emphasizing the need to avoid artificial or mechanical wounds to prevent infection in E. japonicus management. The EC50 values of five fungicides, namely difenoconazole, flusilazole, tebuconazole, hexaconazole, and prochloraz, were found to be less than 10 mg/L, indicating their strong potential for application. Notably, the EC50 of prochloraz was less than 0.05 mg/L for C. theobromicola. These findings offer valuable insights for the management of anthracnose on E. japonicus.

Diversity, Prevalence and Virulence of Colletotrichum Species Causing Anthracnose on Cassava Leaves in the Northern Region of Brazil.

Cassava (Manihot esculenta Crantz) is a staple crop widely cultivated by small farmers in tropical countries. However, despite the low level of technology required for its management, it can be affected by several diseases, with anthracnose as the main threat. There is little information about the main species of Colletotrichum that infect cassava in Brazil. Thus, the objective of this work was to study the diversity, prevalence and virulence of Colletotrichum species that cause anthracnose in cassava leaves in northern Brazil. Twenty municipalities of the Pará and Tocantins states were selected, and leaves with symptoms were collected in those locations. Pure cultures were isolated in the laboratory. Species were identified using phylogenetic analyses of multiple loci, and their pathogenicity, aggressivity and virulence levels were assessed. Our results showed the greatest diversity of Colletotrichum associated with anthracnose in cassava plants of the "Formosa" cultivar in the Tocantins and Pará states. We determined the presence of Colletotrichum chrysophilum, C. truncatum, C. siamense, C. fructicola, C. plurivorum, C. musicola and C. karsti, with C. chrysophilum as the most aggressive and virulent. Our findings provide accurate identifications of species of Colletotrichum causing anthracnose in cassava crops, which are of great relevance for cassava breeding programs (e.g., the search for genotypes with polygenic resistance since the pathogen is so diverse) and for developing anthracnose management strategies that can work efficiently against species complexes of Colletotrichum.

Global transcriptome analysis reveals resistance genes in the early response of common bean (Phaseolus vulgaris L.) to Colletotrichum lindemuthianum.

BACKGROUND: Disease can drastically impair common bean (Phaseolus vulgaris L.) production. Anthracnose, caused by the fungal pathogen Colletotrichum lindemuthianum (Sacc. and Magnus) Briosi and Cavara, is one of the diseases that are widespread and cause serious economic loss in common bean. RESULTS: Transcriptome analysis of the early response of common bean to anthracnose was performed using two resistant genotypes, Hongyundou and Honghuayundou, and one susceptible genotype, Jingdou. A total of 9,825 differentially expressed genes (DEGs) responding to pathogen infection and anthracnose resistance were identified by differential expression analysis. By using weighted gene coexpression network analysis (WGCNA), 2,051 DEGs were found to be associated with two resistance-related modules. Among them, 463 DEGs related to anthracnose resistance were considered resistance-related candidate genes. Nineteen candidate genes were coexpressed with three resistance genes, Phvul.001G243600, Phvul.001G243700 and Phvul.001G243800. To further identify resistance genes, 46 candidate genes were selected for experimental validation using salicylic acid (SA) and methyl jasmonate (MeJA). The results indicated that 38 candidate genes that responded to SA/MeJA treatment may be involved in anthracnose resistance in common bean. CONCLUSIONS: This study identified 38 resistance-related candidate genes involved in the early response of common bean, and 19 resistance-related candidate genes were coexpressed with anthracnose resistance genes. This study identified putative resistance genes for further resistance genetic investigation and provides an important reference for anthracnose resistance breeding in common bean.

First Report of Colletotrichum aenigma Causing Anthracnose on Dragon Fruit in Korea.

Dragon fruit (Selenicereus undatus) is a valuable fruit crop in tropical and subtropical regions. It is renowned for its nutritional benefits, such as high sodium, potassium, and vitamin levels, and as a source of prebiotics and antioxidants (Balendres et al. 2019). In July 2023, anthracnose symptoms on stems were detected on dragon fruit plants in Jeju, South Korea. The typical anthracnose symptoms, such as sunken necrotic lesions (5-20 mm in diameter), were seen on the mature stems. The disease incidence ranged from 10% to 12% among the three surveyed greenhouses. To isolate the causative organism, infected stem samples were surface sterilized, cut into small pieces, and placed on potato dextrose agar (PDA). After two days of incubation at 24ºC, white hyphae appeared on the PDA around the plant tissues. Isolates CNU H23009 and CNU H23010 were purified from a single hypha under a stereoscope (e-Xtra Figure 1). Conidial morphology was examined from two-day-old fungal cultures grown on V8 juice agar. The conidia were transparent, aseptate, cylindrical to clavate, with a rounded apex and base, and measured 11.9 - 16.85 × 5.17 - 6.91 µm (mean = 15.28 × 5.93 µm, n = 30). No appressoria was observed. Morphological characteristics indicated the isolates were Colletotrichum sp. matching the description of the C. gloeosporioides species complex (Weir et al. 2012). To further identify the isolates, genomic DNA was extracted and the ribosomal internal transcribed spacer (ITS) region, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and actin (ACT) were amplified using ITS1/ITS4, GDF/GDR, and ACT-512F/ACT-783R, respectively (Weir et al. 2012). Based on phylogenetic analysis, the isolates clustered with C. aenigma (strains ICMP18608, ICMP18686, CSH2, and QSG1), with 71% bootstrap support, as determined using the maximum parsimony method in PAUP 4.0 (e-Xtra Figure 2). Based on morphological and molecular characteristics, isolates were identified as C. aenigma. Sequences of CNU H23009 and CNU H23010 were deposited in GenBank with accession numbers OR535144 and OR535145 for ITS, OR540725 and OR540726 for GAPDH, and OR540723 and OR540724 for ACT. The pathogenicity was tested on healthy dragon fruit stems using wound inoculation with mycelial plugs of the CNU H23009 isolate. Controls were inoculated with PDA plugs. The plants were covered with plastic bags to maintain humidity and incubated in a greenhouse at 25ºC. After two days, necrotic spots had developed on the inoculated tissues; after four days, black, irregular, and sunken necrotic lesions similar to those seen in the field were observed. No symptoms occurred in the controls. C. aenigma was re-isolated from the artificially inoculated plants and re-identified based on conidial morphology. The pathogenicity test was repeated three times with three replications for each treatment. Previous studies have reported that C. aenigma, C. gloeosoporioides, C. siamense, C. truncatum, and C. karsti cause anthracnose in dragon fruit. However, C. aenigma has been reported only in Thailand (Balendres et al. 2019; Meetum et al. 2015). To our knowledge, this is the first report of C. aenigma causing anthracnose in dragon fruit in Korea.