Blood disease in bananas caused by Ralstonia syzygii subsp. celebesensis (Rsce) is a bacterial wilt disease that causes major yield losses of banana in Indonesia and peninsular Malaysia. The disease has significantly increased its geographic distribution in the last decade. Diagnostic methods are an important component of disease management in vegetatively propagated crops such as banana to constrain incursions of plant pathogens. Therefore, the objectives of this study were: i) to design and rigorously validate a novel banana Blood disease (BBD) real-time PCR assay with a high level of specificity and sensitivity of detection. ii) to validate published PCR based diagnostic methods targeting either the intergenic region in the megaplasmid ("121 assay" with primer set 121) or the phage tail protein coding sequence in the bacterial chromosome ("Kubota assay" and "BDB2400 assay" with primer set BDB2400). Assay validation included 339 samples (174 Blood disease bacterium, 51 bacteria associated with banana plants, 51 members of the Ralstonia solanacearum species complex and 63 samples from symptomatic and healthy plant material). Validation parameters were analytical specificity (inclusivity and exclusivity), selectivity, limit of detection, accuracy, and ruggedness. The "121 assay" and our newly developed "BBD real-time PCR assay" detected all Rsce strains with no cross specificity during validation. Two different PCR assays using the primer set BDB2400 lacked specificity and selectivity. This study reveals that our novel "BBD real-time PCR assay" and the conventional PCR "121 assay" are reliable methods for Blood disease diagnostics as they comply with all tested validation parameters.
Dragon fruit (Hylocereus polyrhizus & H. undatus) is a rapidly growing commodity in Taiwan. The production acreage has been tripled since 2011, with an estimation of over 2,800 ha in 2019. From disease survey conducted in July 2020, reddish orange to blackish brown lesions similar to stem canker caused by Neoscytalidium dimidiatum on dragon fruit cladodes (Supplementary Fig. S1, Q) were observed from two orchards in Central Taiwan. Diseased cladodes were brought back to the lab, surface disinfested with 70% ethanol for 15 to 30 sec, and then blotted dried with a paper towel. Small pieces (about 3x3 mm) of necrotic spots were excised, placed on 2% water agar (WA) plates, and incubated with 12 h photoperiod at 28 ± 2 ℃ for 3 days. Among the necrotic spots that were used for fungal isolation, some were detected to have N. dimidiatum accounting for 21 isolates, while three isolates detected in other spots were unknown. Single hyphal tips of the three unknown fungal colonies with similar morphology were transferred on potato dextrose agar (PDA). Brownish- to grayish-white colonies with fluffy aerial mycelium were observed on PDA (Supplementary Fig. S1, A, B, E, F, I and J) after 8 days of incubation. To induce the sporulation, all the fungal isolates were cultivated on autoclaved cowpea pods on 2% WA plates with 12 h photoperiod at 25 ± 2 ℃ for 3 weeks. Black pycnidia embedded in cowpea tissues and creamy yellowish exudates with pycnidiospores extruding from the ostiole were observed (Supplementary Fig. S1, C, G and K). Alpha-conidia were characterized as aseptate, hyaline, smooth, ellipsoidal or fusiform, often bi-guttulate and measured about 6.0 to 6.5 μm × 2.0 to 2.3 μm (n = 50 for each isolate) (Supplementary Fig. S1, D, H and L). Beta-conidia were not observed. Morphological characteristics of these isolates were similar to Diaporthe spp. described by Udayanga et al. (2015). To further identify the fungal isolates, the internal transcribed spacer (ITS), β-tubulin (TUB) and translation elongation factor 1-α (EF1-α) regions were amplified using primer pairs ITS1/ITS4 (White et al. 1990), Bt2a/Bt2b (Glass & Donaldson 1995) and EF1-728F/EF1-986R (Carbone & Kohn 1999), respectively. BLAST analysis of isolates CH0720-010 (ITS: OK067377; TUB: OK149767; EF1-α: OK149764), CH0720-013 (ITS: OK067378; TUB: OK149768; EF1-α: OK149765) and TC0720-016 (ITS: OK067379; TUB: OK149769; EF1-α: OK149766) showed 99.78 to 100% of ITS identity, 98.8 to 99.2% of TUB identity, and 100% of EF1-α identity with Diaporthe ueckerae (ITS: KY565426; TUB: KY569384; EF1-α: KY569388). Phylogenetic trees were constructed using concatenated ITS, TUB, and EF1-α sequences based on maximum likelihood with HKY+G model, maximum parsimony, and Bayesian inference method in MEGA X and Geneious Prime 2020.2.4. All isolates were clustered in D. ueckerae with similar topology based on aforementioned methods, hence the phylogram of maximum likelihood was presented (Supplementary Fig. S2). To confirm the pathogenicity, detached dragon fruit (H. polyrhizus and H. undatus) cladodes (20 to 30 cm in length) were surface disinfested, wounded with sterilized syringe (about 2 mm in depth), and inoculated with mycelial plugs (6 mm in diam.) from 5-day-old colonies on PDA. Each isolate had three mycelial plugs and the PDA plugs without mycelium were inoculated as negative control. Inoculated cladodes were placed in a moisture chamber and incubated at 30 ± 2 ℃ with 12 h photoperiod. Two days after inoculation (DAI), the agar plugs were removed and symptom development on the cladodes was photo recorded every other day. The inoculation experiment was repeated twice. At 6 DAI, round to irregular, dark-brown, and water-soaking lesions were observed on the cladodes of both species inoculated with the three D. ueckerae isolates whereas all negative controls remained asymptomatic (Supplementary Fig. S1, M-P). Morphologically identical fungi were re-isolated from inoculated cladodes, fulfilling Koch's postulates. Several Diaporthe species have been reported infecting dragon fruit in the southeastern Asian countries such as Thailand, Bangladesh and Malaysia (Udayanga et al. 2012; Karim et al. 2019; Huda-Shakirah et al. 2021). To our knowledge, this is the first report of stem rot caused by D. ueckerae in Taiwan. Since the field symptoms may be easily confused with those caused by N. dimidiatum, the potential threat of Diaporthe species complex on dragon fruit should be aware and may warrant further study.
Banana Blood disease is a bacterial wilt caused by Ralstonia syzygii subsp. celebesensis and is an economically important disease in Indonesia and Malaysia. Transmission of this pathogen is hypothesized to occur through insects mechanically transferring bacteria from diseased to healthy banana inflorescences, and other pathways involving pruning tools, water movement and root-to-root contact. This study demonstrates that the ooze from the infected male bell and the sap from various symptomatic plant parts are infective and the cut surfaces of a bunch peduncle, petiole, corm, and the rachis act as infection courts for R. syzygii subsp. celebesensis. In addition, evidence is provided that R. syzygii subsp. celebesensis is highly tool transmissible, that the bacterium can be transferred from the roots of a diseased plant to the roots of a healthy plant and transferred from the mother plant to the sucker. We provide evidence that local dispersal of Blood disease is predominantly through mechanical transmission by insects, birds, bats or human activities from diseased to healthy banana plants and that long-distance dispersal is through the movement of contaminated planting material. Disease management strategies to prevent crop losses associated with this emerging disease are discussed based on our findings.
Aloe vera L. var. chinensis (Haw.) Berg. (family Asphodelaceae), locally known as 'Lidah Buaya', is an economically important plant as the gel from the leaves possesses anti-inflammatory, anti-arthritic, antibacterial, and hypoglycemic properties and is used for cosmetic, pharmaceutical and healing purpose in Malaysia. In July 2021, irregular black sunken spots (3- to 10-mm in diameter) were observed on the leaves of 'Lidah Buaya' plants under leaf development stage in the field located in the district Penampang of Sabah province (N5°56'37.1" E116°04'21.5"). The disease severity was about 30% with 10% incidence. The tissues surrounding the black spots became brown and dry when the plants grew older. No gel contained in the sunken zones. Symptomatic leaf tissues (5 x 5 mm) were cut from the infected margin, surface sterilised with 75% ethanol for 1 minute, washed with 2% sodium hypochlorite solution for 1 minute, rinsed, and air dried before plating on five potato dextrose agar (PDA) plates (pH 7). Plates were incubated at 25°C for 3 days in the dark. Greyish-white fluffy mycelia were observed, and then became dark grey with age. Dark pigmentation in each plate was produced after a week of incubation at 25°C. A representative isolate Penampang was further characterized morphologically and molecularly. Immature conidia were single-celled, aseptate, ellipsoid and hyaline, measuring 19.4 × 24.5 µm (n = 30). Mature conidia were brown, thick-walled and one-septate with longitudinal striations, 22.5 × 28.3 µm (n = 30). Genomic DNA was extracted from fresh mycelia of isolate Penampang based on the extraction method described by Khoo et al. (2021) with additional of mechanical disruption using micro pestle before heating. KOD One PCR master mix (Toyobo, Japan) containing hot-start modified KOD DNA polymerase was used for PCR amplification. The PCR condition were 94°C for 10 s, 55°C for 5 s and 72°C for 2 s, for 30 cycles, and initial denaturation of 94°C for 3 min and a final extension step of 72°C for 5 min. The internal transcribed spacer (ITS) region of rDNA and tubulin (TUB) genes were amplified using ITS1/ITS4 and T10/Bt2b primer sets, respectively (O'Donnell et al. 1997; White et al. 1990). The products were then sent to Apical Scientific Sdn. Bhd. for sequencing. The generated ITS (OK209451) and TUB (OL660667) were 100% identical to L. theobromae isolate MRR-161 and CPC:27690 (GenBank MW282884 and MT592639, respectively) in BLASTn analysis. Phylogenetic analysis using maximum likelihood based on the combined ITS and TUB sequences indicated that the isolates formed a supported clade (91% bootstrap value) to the related L. theobromae. The morphological and molecular characterization of the fungus matched L. theobromae described by Pečenka et al. (2021). Mycelial agar plugs (5-mm-diameter) from 7-day-old PDA culture of Penampang isolate were placed onto pinpricked leaves of three 2-month-old 'Lidah Buaya' plants. Pinpricked leaves of three 2-month-old 'Lidah Buaya' plants received sterile 5-mm-diameter PDA agar plugs to serve as controls. The inoculated 'Lidah Buaya' plants were covered with plastics for 48 h, and were incubated at 25°C. All inoculated leaves developed symptoms as described above 6 to 7 days post-inoculation, whereas no symptoms occurred on controls, thus fulfilling Koch's postulates. The experiments were repeated twice. The reisolated fungus was identical to representative isolate Penampang morphologically and molecularly. L. theobromae was reported previously on A. vera in Cuba (Urtiaga 1986) and India (Mathur 1979). To our knowledge, this is the first report of L. theobromae causing leaf spot on A. vera in Malaysia. The occurrence of this disease emphasizes the importance of disease surveillance in the region. Plant disease management strategies need to be established to reduce the losses.
Multiple diseases, including brown spot (Cochliobolus miyabeanus), leaf spot (Epicoccum sorghimum), and blast (Magnaporthe oryzae), can cause spot-like symptoms on the leaves of rice. In July 2021, a disease showing symptoms like brown spot was observed in an 8-hectare field of rice, with disease incidence of >30%, in Beaumont, Texas. Lesions started as small pinhead-size blackish spots on leaf tips or from the edges of leaf blades. The spots enlarged to become irregular (most) or oval brown spots with a slight chlorotic halo. Diseased leaves were collected, washed in running tap water and cut into small pieces. Pieces of the tissue were surface sterilized with 1%NaOCl for 2 min followed by 75% ethanol for 30 s and then washed in sterile distilled water three times with each time lasting for 1 min. The disinfected tissue pieces were air dried, placed on potato dextrose agar (PDA) medium and incubated at 25℃. Initially fungal colonies were hairy in texture with light dark brown center and whitish edge and dark brown pigmentation at the reverse side. Mature colonies turned to black in the center and dark brown toward the edge, with black at the reverse side after 2 or more weeks of incubation. Conidia were oval to narrowly oblong, rounded at the ends, with 2 to 6 distoseptate, and 15 to 35 × 6 to 10 µm in size. These morphological characteristics were similar to those described for Curvularia hawaiiensis (Aslam et al. 2019; Ellis 1971; Kusai et al. 2015). For molecular identification, DNA was extracted and the two different rRNA regions internal transcribed spacer (ITS) and large subunit (LSU), and the two genes RNA Polymerase II (RPB1) and translation elongation factor 1 alpha (EF1) of the fungus were amplified using the primers of ITS1/ITS4 (Wang et al. 2014), D1/D2 domain region of LSU (Fell et al. 200), and RPB1 and EF1 (Wang et al. 2014), respectively, and sequenced. The ITS sequence (OK397200) was 98.27% identical to C. hawaiiensis (KP131943); the EF1 sequence (OK492159) was 99.78% identical to C. hawaiiensis (KC503942); the LSU sequence (OK397295) was 98.96% identical to multiple C. hawaiiensis (MN055715, MH160813, MH875853, etc.); the RPB1 sequence (OK492160) was 97.41% identical to C. hawaiiensis (JN992363). To evaluate pathogenicity, three rice plants (cv. Presidio) at the 3-leaf stage were spray inoculated with a conidial suspension of 1 x 106 conidia/ml. Another set of three plants that were sprayed with sterilized distilled water served as the controls. Treated plants were maintained in a greenhouse with temperature ranging from 25 to 30℃. After 2 weeks, typical symptoms, like those observed in the field, developed on the inoculated plants while no symptoms developed on the control plants. The same fungus was consistently re-isolated from the diseased plants. The pathogenicity test was conducted three times with similar results. To our knowledge, this is the first report of brown leaf spot caused by C. hawaiiensis in rice in the United States. Curvularia species are frequently associated with rice grain and cause blackish discoloration symptoms on grain kernels. Recently, however, C. hawaiiensis has also been reported to cause brown leaf spot in Malaysia (Kusai et al. 2015) and Pakistan (Aslam et al. 2019). This research will help identify this disease from other leaf spot-like diseases and develop effective management strategies.
'Purple Dream' eggplant (Solanum melongena) is widely grown for its edible fruits in Malaysia. In July 2021, anthracnose symptoms were observed on fruit with a disease severity of approximately 80% and an incidence of 10% in a field (14.6 m2) (5°56'50.9"N, 116°04'31.9"E) located in the Penampang district of Sabah province. The symptoms initially appeared as irregular light brown spots. As the disease progressed, the spots enlarged and merged into extensive lesion patches that appeared in concentric circles. The symptomatic fruit tissues (5 x 5 mm) were surface sterilized based on Khoo et al. (2022), and plated onto potato dextrose agar (PDA), and incubated at 25°C in the dark. Colonies with gray-white fluffy mycelia developed after 7 days, and the reverse of the colonies was dark brown. A representative isolate named Penampang was characterized morphologically and molecularly. The conidia were one-celled, cylindrical, blunt at the ends, hyaline, smooth, and measured 13.3 to 16.1 x 3.9 to 6.0 µm (n= 20). Appressoria ranged in size from 7.6 to 9.3 m x 5.5 to 6.6 µm (n= 20) and were spherical to irregular in shape and dark brown in colour. Genomic DNA was extracted from fresh mycelia of isolate Penampang based on Khoo et al. (2021) and Khoo et al. (2022). ITS1/ITS4, CL1C/CL2C, ACT-512F/ACT-783R, CHS-79F/CHS-354R, and GDF1/GDR1 primer pairs were used to amplify the isolate's internal transcribed spacer region (ITS), and partial calmodulin (CAL), actin (ACT), chitin synthase (CHS-1), and glyceraldehyde-3-phosphate dehydrogenase genes (GAPDH) (Weir et al. 2012). PCR products were sequenced by Apical Scientific Sdn. Bhd. (Selangor, Malaysia). Sequences were deposited in GenBank under the accession numbers OL957466 (ITS), OL953035 (CAL), OL953032 (ACT), OL953038 (CHS-1), and OL953041 (GAPDH). They were 99% to 100% identical to the Colletotrichum ti ITS (NR_120143) (515 bp out of 519 bp), and C. siamense CAL (JX009714) (729 bp out of 731 bp), ACT (JX009518) (282 bp out of 282 bp), CHS-1 (JX009865) (299 bp out of 299 bp), and GAPDH (JX009924) (276 bp out of 277 bp) sequences. ITS sequences do not reliably resolve relationships within the C. gloeosporioides complex (Weir et al. 2012). The phylogenetic maximum likelihood analysis using the combined ITS, CAL, ACT, CHS-1, and GAPDH sequences indicated that the isolate was part of the C. siamense clade (100% bootstrap value) that also contained the type isolate ICMP 18578 of this species. Morphological and molecular characterization matched the description of C. siamense (Huang et al. 2021; Ismail et al. 2021). Koch's postulates were performed similarly as described by Chai et al. (2017) but using spray-inoculation (108 spores/ml) of three healthy 'Purple Dream' eggplant fruit with isolate Penampang. Water was sprayed on three additional fruits that served as controls. All the fruits were incubated at 25°C and less than 90% relative humidity. Symptoms similar to those observed in the field developed 5 days after inoculation. No symptoms occurred on controls. The experiment was repeated two more times. The reisolated fungi were identical to the pathogen morphologically and molecularly. To our knowledge, this is the first report of C. siamense causing anthracnose on fruit of 'Purple Dream' S. melongena in Malaysia as well as worldwide. Our findings expand the host range of C. siamense and indicate that the pathogen could potentially limit 'Purple Dream' eggplant production in Malaysia.
Production of watermelon (Citrullus lanatus) in Malaysia was 150,000 mt in 2020 (Malaysian Department of Agriculture, 2021). In November 2019, nine locally produced watermelon fruit (red flesh, seedless) from five local stores in the states of Kelantan, Terengganu, and Penang exhibited sunken, circular, brown lesions that enlarged to1.5 to 10 cm in diameter with scattered orange masses of conidia. Lesions coalesced to cover approximately 50% of the fruit surface. Lesions were surface sterilized by spraying 70% alcohol onto the fruit followed by drying with sterilized paper towels. A total of 153 tissue segments (1×1 cm) were excised from the rind, immersed in 1% sodium hypochlorite for 3 min, rinsed twice for 1 min in sterilized distilled water, air-dried, transferred to potato dextrose agar (PDA) plates, and incubated at 25±1°C for 7 days. Single-spore transfers produced pure cultures, resulting in 12 isolates. Colonies on PDA were initially white and turned pale gray with age. Conidia were hyaline, one end round and the other narrowly acute, aseptate, smooth-walled, straight, cylindrical to clavate, 10.5-16.5 µm × 3-4.5 μm (n = 30). Observed morphological characters matched published description of Colletotrichum spp. (Damm et al. 2012). Internal transcribed spacer (ITS) and glyceraldehyde-phosphate dehydrogenase (GAPDH) genes were amplified using primer sets ITS1/ITS4 and GDF1/GDF2, respectively. All sequences were deposited in GenBank (MW856808 for ITS; MZ219296 for GAPDH). A BLASTn search of both sequences on GenBank showed 99% identity with C. scovillei along with other closely related Colletotrichum species. Phylogenetic analysis of ITS and GAPDH alignments, using maximum likelihood along with reference strains of closely related species from Mycobank, confirmed species identity as C. scovillei. A pathogenicity test was conducted on two healthy watermelon fruit (red flesh, seedless). A 6-mm-diameter mycelial plug of a colony on PDA was positioned on a 0.5-cm-long wound on each fruit; a sterile PDA plug placed on a similar wound on the opposite side served as a control. Fruit were incubated at 25±1°C for 7 days in plastic-wrapped trays above distilled water to maintain high humidity. Small, sunken, circular brown lesions appeared and expanded at inoculation sites within 7 days. Symptoms were identical to those produced by natural infections, and the controls were asymptomatic. Isolates from the lesions at the inoculation sites were confirmed as C. scovillei based on morphological characteristics, fulfilling Koch's postulates. The pathogenicity test was conducted four times with a total of eight fruit. Many species in the C. orbiculare complex cause watermelon anthracnose (Keinath, 2018). To our knowledge, this is the first report of C. scovillei (C. acutatum species complex; Damm et al. 2012) causing anthracnose on watermelon in Malaysia. Anthracnose caused by C. scovillei has been confirmed on other crops such as pepper (Toporek and Keinath, 2021), banana (Zhou et al., 2017), and chili (Oo et al., 2017). This insight will inform efforts to improve management of watermelon anthracnose in Malaysia.
Ixora chinensis (family Rubiaceae), locally known as 'Bunga Jejarum', is widely grown as an ornamental shrub and as sources for phytochemicals with medicinal properties in Malaysia. In May 2021, irregular brown spots were found on the leaves of some 'Bunga Jejarum' in Universiti Malaysia Sabah (6°02'01.0"N 116°07'20.2"E) located in Sabah province. As the disease progressed, the spots enlarged and coalesced into large necrotic areas giving rise to drying of infected leaves. The disease severity was about 70% with 20% incidence. Five symptomatic leaves (5 x 5 mm) from five plants were excised and sterilized based on Khoo et al. (2022) before plated on five potato dextrose agar (PDA) and cultured at 25°C. After 5 days, white to pale honey and dense mycelia with lobate edge were observed on all PDA plates. Globose, black conidiomata semi-immersed on PDA were observed after a week. Two to four hyaline filamentous appendages 7.7 to 17.6 μm long attached to fusoid conidia (11.8 to 20.9 x 5.7 to 7.6 μm, n = 20), which consisted of a hyaline apical cell, basal cell, and three versicolored median cells. The upper two median cells were dark brown, while the lowest median cell was pale brown. The isolate of the causal pathogen was characterized molecularly. Genomic DNA of isolate UMS01 was extracted based on Khoo et al. (2021) and Khoo et al. (2022). Amplification of the internal transcribed spacer (ITS), tubulin (TUB) and translation elongation factor 1-α (TEF) region was performed based on Khoo et al. (2022) using primers ITS1/ITS4 (White et al. 1990), T1/Bt2b (Glass and Donaldson, 1995; O'Donnell and Cigelnik, 1997) and EF1-728/EF2 (O'Donnell et al. 1998; Carbone and Kohn, 1999), respectively. PCR products with positive amplicons were sent to Apical Scientific Sdn. Bhd. for sequencing. The isolate's sequences were deposited in GenBank as OM320626 (ITS), OM339539 (TUB) and OM339540 (TEF). They were 99% to 100% identical to ITS(KM199347) (545 out of 545 bp), TUB (KM199438) (768 out of 769 bp) and TEF (KM199521) (480 out of 481 bp) of the type sequences (CBS 600.96). Phylogenetic analysis using the maximum likelihood method based on the combined ITS, TEF and TUB sequences placed the isolate UMS01 in the same clade as the isolate CBS 600.96 of Neopestalotiopsis cubana. Thus, the pathogen was identified as N. cubanabased on the morphological description from Pornsuriya et al. (2020), molecular data in Genbank database and multigene sequence analysis. To further confirm its pathogenicity, the first and second leaves of three 'Bunga Jejarum' plants were inoculated by pipetting 1 ml aliquots of a 1 × 106 conidia/ml spore suspension. Three additional 'Bunga Jejarum' plants were mock inoculated by pipetting 1 ml of sterile distilled water on similar age leaves. The plants were covered with plastic bags after inoculation for 48 h before placing them in a glasshouse under room temperature. The leaves were sprayed with water to keep the leaf surfaces moist along the experiment. The incubation and disease observation were performed based on Chai et al. (2017) and Iftikhar et al. (2022). After 7 days post-inoculation, all infected leaves exhibited the symptoms observed in the field, whereas the controls showed no symptoms. The same fungus was isolated from the diseased leaves and, thus confirmed Koch's postulates. The experiment was repeated two more times. The reisolated fungi were visually and genetically identical to the original isolate obtained from the field samples. To our knowledge, this is the first report of N. cubana causing leaf blight on 'Bunga Jejarum' in Malaysia, as well as the world. Our finding has broadened the distribution and host range of N. cubana, indicating that it poses potential damage to the medicinal plant Bunga Jejarum in Malaysia.
Crinum asiaticum (family Amaryllidaceae), locally known as 'Pokok Bakung', is an ornamental medicinal plant grown in Malaysia. It contains chemical compounds used for antimicrobial, antioxidant, antitumor, antiemetic and wound healing (Patel, 2017). In July 2021, 'Pokok Bakung' leaves with anthracnose symptoms were collected from a park of Universiti Malaysia Sabah in the Sabah province. The disease severity was about 100% with 20% incidence. Red spots were primarily found on the leaf surfaces. Anthracnose developed as the disease progressed, and acervuli were observed in the spots. Small pieces of infected leaves (5 x 5 mm) were excised from spot margins, surface sterilized based on Khoo et al. (2022a), placed on potato dextrose agar (PDA) in Petri dishes, which were incubated for 5 days at 25°C in the dark. The colonies formed on the PDA plates were abundant with gray-white fluffy mycelia after 5 days, and the reverse view revealed brown. UMS01, a representative isolate, was used to morphologically and molecularly characterize the fungus. Conidia were one-celled, cylindrical, hyaline, smooth, and blunt at the ends, measuring 13.8 to 16.5 x 3.6 to 6.7 µm (n = 20). Appressoria ranged in size from 7.6 to 9.3 x 5.5 to 6.9 µm (n= 20) and were ovoid to clavate, spherical to irregular in shape and dark brown in color. Genomic DNA was extracted from fresh mycelia of isolate UMS01 based on Khoo et al. (2021) with the addition of mechanical disruption using a micro pestle before heating at 95°C. PCR amplification was performed based on Khoo et al. (2022a) using ITS1/ITS4, CL1C/CL2C, ACT-512F/ACT-783R, CHS-79F/CHS-354R, and GDF1/GDR1 primer pairs to amplify the internal transcribed spacer (ITS) region, calmodulin (CAL), actin (ACT), chitin synthase (CHS-1), and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) (Weir et al. 2012). PCR products with positive amplicons were sent to Apical Scientific Sdn. Bhd. for sequencing. The sequences were deposited in GenBank under accession numbers OK458683 (ITS), OL953033 (CAL), OL953030 (ACT), OL953036 (CHS-1), and OL953039 (GAPDH). Before BLAST, the search set were adjusted to exclude model sequences (XM/XP) and the uncultured/environmental sample sequences, and limit to sequences from type material. They were 99-100% similar to the Colletotrichum siamense ITS (JX010171), CAL (JX009714), ACT (FJ907423) and CHS-1 (JX009865), and Colletotrichum changpingense GAPDH (MZ664048) type sequences. The GAPDH marker did not reliably resolve the relationships within the C. gloeosporioides complex (Vieira et al. 2020). Phylogenetic analysis using maximum likelihood based on the combined ITS, CAL, ACT, CHS-1 and GAPDH indicated that the isolate formed a supported clade (100% bootstrap value) to the most related C. siamense. Morphological and molecular characterization matched the description of C. siamense (Huang et al. 2021). Pathogenicity tests were performed to fulfil Koch's postulates by spraying a spore suspension (106 spores/ml) on the leaves of three healthy four-month-old 'Pokok Bakung' plants, while three additional plants were sprayed with water as a control. The inoculated plants were covered with plastics for 48 h at 25°C in the dark. Incubation was performed based on Iftikhar et al. (2022). Symptoms similar to those of the field collection occurred after 6 days post inoculation. No symptoms occurred on the control plants. The experiment was repeated two more times. The reisolated fungal isolates were identical to C. siamense morphologically and molecularly. Previously, C. siamense has been reported to cause anthracnose on Allamanda cathartica (Huang et al. 2021) and avocado (Li et al. 2022) in China, and 'Purple Dream' eggplant in Malaysia (Khoo et al. 2022b). Colletotrichum fructicola has been reported to cause anthracnose on C. asiaticum in China (Qing et al. 2020). To our knowledge, this is the first report of C. siamense causing anthracnose on C. asiaticum in Malaysia. Our findings expand the geographic range of C. siamense and indicate that it could be a potential threat limiting the growth and production of C. asiaticum in Malaysia.
Peru is the ninth exporter of coffee (Coffea arabica) in the world, and Amazonas is among its most important producing departments (INIA 2019). In July 2021, in the nursery of the "Instituto de Investigación para el Desarrollo Sustentable de Ceja de Selva", in Huambo district (6° 26' 11.19'' S; 77° 31' 24.18'' W), four-month-old coffee seedlings cv. Catimor with 0.5-2.0 cm brown concentric leaf spots and rotten stems, bearing white mycelial tufts and black sporodochia, were observed at 30% incidence. Infected seedlings were collected. Foliar sections of 2-3 mm with infected tissue were surfaced disinfected in 2% NaClO and transferred onto Petri plates containing potato dextrose agar medium (PDA). The plates were incubated at 25° C for 7 days. We obtained three isolates (INDES-AFHP61, INDES-AFHP62 and INDES-AFHP66) with similar morphology from different seedlings. Colonies (16-17 mm diam.) formed concentric rings with white aerial mycelium, giving rise to viscous and olivaceous dark green sporodochial conidiomata. Conidia (4.82-5.77 × 1.34-1.65 µm; n = 30) were cylindric, hyaline, smooth, and aseptate. These morphological features correspond to Paramyrothecium spp. (Lombard et al. 2016). The DNA of isolates was extracted using the Wizard® Purification Kit (Promega Corp., Madison, Wisconsin), and the internal transcribed spacer 1 and 2 intervening the 5.8S subunit rDNA region (Accession numbers: OM892830 to OM892832), and part of the second-largest subunit of the RNA polymerase II, the calmodulin and the β-tubulin genes (OM919453 to OM919461) were sequenced following Lombard et al. (2016). All sequences had a percent identity greater than or equal to 99% to corresponding sequences of the P. roridum type specimen (CBS 357.89). Additionally, a multilocus Maximum Likelihood phylogenetic analysis incorporating sequence data from previous relevant studies (Lombard et al. 2016; Pinruan et al. 2022) grouped our three isolates together with the type and other specimens of P. roridum in a strongly supported clade, confirming the species identification. To evaluate pathogenicity, four-month-old coffee seedlings cv. Catimor were sprayed with 10 mL of conidial suspensions at 1 x 106 /mL. A set of control seedlings were inoculated with sterile water. Seedlings were maintained in a humidity chamber at 25 °C. After 15 days brown concentric foliar spots, stem rotting, mycelial tufts and sporodochia (same symptoms and signs observed originally at the nursery) arose in the non-control seedlings. The pathogen was re-isolated on PDA, confirming P. roridum was the causal agent of leaf spot and stem rot diseases of coffee. Paramyrothecium roridum has wide geographic distribution and host range (Lombard et al. 2016). This pathogen was reported to infect C. arabica in Mexico and Coffea sp. in Colombia (Pelayo-Sánchez et al. 2017; Lombard et al. 2016; Huaman et al. 2021). It was also reported in Africa infecting soybeans (Haudenshield et al. 2018), in Brazil infecting Tectona grandis (Borges et al. 2018), in Egypt infecting strawberries (Soliman 2020), and in Malaysia infecting Eichhornia crassipes (Hassan et al. 2021). To the best of our knowledge, this is the first time P. roridum is reported on coffee in Peru.
In Puerto Rico, the agricultural production of pineapple (Ananas comosus (L.) Merr.) comprises nearly 5,000 tons harvested annually from over 250 ha (USDA 2018). With an annual income of approximately $3 million USD, pineapple ranks fourth in importance among Puerto Rican crops (USDA 2018). Recently, the pineapple industry on the island underwent a change from growing a local cultivar known as "Cabezona" to cultivar MD2, introduced from Hawaii around 1996 (SEA 2015), because this cultivar produces fruit more than once during a single growing season. In August 2018 (when the rainy season normally starts in Puerto Rico), soft rot symptoms appeared at commercial fields in Manatí (WGS 84 Lat 18.42694, Lng -66.44779) and persisted through 2019. Symptoms observed in the field included foliar water-soaked lesions with gas-filled blisters, especially at the base of the leaf. Leaves exhibited brown discoloration and a fetid odor (rot) at the basal portion of the plant. Finally, leaves collapsed at the center of the pineapple crown, effectively killing the apex and preventing the fruit from developing. Disease incidence ranged from 25% to 40% depending on the weather and season; when there was more rain, there was higher disease incidence. Symptomatic leaves were collected in February 2019, disinfected with 70% ethanol, and rinsed with sterile distilled water. Tissue sections (5mm2) were placed in nutrient agar. Bacterial colony-forming units (CFU) were a translucent cream color, circular, with a flat convex surface and wavy edge. Biochemical analysis showed that bacteria were Gram-negative, oxidase positive, catalase positive, and facultatively anaerobic. Pathogenicity was tested on leaves of one-and-a-half-year-old pineapple seedlings in humid chambers. Bacteria were grown on sterile nutrient agar for 3 days at 25 ± 2°C. Inoculation assays (three replications) were performed using 1X108 CFU/ml of bacteria suspended in sterile water and applied with a cotton swab to leaves wounded with a needle. The inoculated tissue was incubated at 28°C and kept in a dark environment. Negative controls were inoculated with sterile water. Five days after inoculation, foliar water-soaked lesions were observed, followed by the formation of brown leaf tissue and gas-filled blisters, the same symptoms observed in the field. A partial DNA sequence of the 16S rRNA gene of the bacterial isolate and the re-isolated bacteria were amplified using primers 27F and 1492R (Lane et al. 1985) and sequenced. The isolate was determined to the genus Dickeya through a BLAST® search against sequences available in the database of the National Center for Biotechnology Information (NCBI). This partial 16S rRNA sequence of the bacterial isolate was deposited in GenBank® at NCBI (Accession no. MT672704). To determine the identity of the Dickeya species, we sequenced the genes dnaA, gyrB, dnaX, and recN (Marrero et al. 2013) for the bacterial isolate (GenBank accession nos. OM276852, OM276853, OM276854, and OM276855) and conducted a Multilocus Sequence Analysis including reference Dickeya sequences of Marrero et al., 2013. The Phylogenetic analysis (using WinClada) resolved the Puerto Rican isolate as belonging to a clade broadly ascribable to D. zeae, most closely related to strains isolated from earlier Hawaiian pineapple bacterial heart rot outbreaks. Dickeya zeae was responsible for bacterial heart rot of pineapple in Malaysia and was later reported as the causal agent for outbreaks in Costa Rica and Hawaii (Kaneshiro et al. 2008; Sueno et al. 2014; Ramachandran et al. 2015). D. zeae had not previously been reported as causing bacterial heart rot in pineapples in Puerto Rico and this study points to a close relationship with strains first detected in Hawaii and which should further be explored to determine the precise nature of this relationship. This information should facilitate the adoption of effective control measures for this disease on the island, promote more effective methods of preventing future introductions of pathogens, and encourage further investigations into the occurrence of D. zeae on the island.
Pometia pinnata (family Sapindaceae), locally known as 'Kasai', is a tropical hardwood and fruit tree species grown in Malaysia. The decoction of the bark is used for the treatment of fever, sores and colds, while the fruits are edible (Adema et al. 1996). In May 2021, irregular brown spots and necrotic lesions were observed on 'Kasai' with an incidence and severity of approximately 60% and 10% on 10 plants in a nursery (5°55'30.7"N 116°04'36.2"E) in Penampang, Sabah province. When the disease progressed, the spots coalesced into extended patches, blightening the leaves and, gradually, the entire foliage. Small pieces (5 x 5 mm) of infected leaves were excised from the infected margin, and then surface sterilized according to Khoo et al. (2022b), and plated on potato dextrose agar (PDA), and cultured at 25 °C. for 6 days. Colonies were dark brown in color initially whitish on the PDA. The color of fungal colony was dark as the culture aged. Semi-appressed mycelia were observed on the plates with abundant microsclerotia engrossed in the agar. Aggregation of hyphae formed black and round to oblong or irregular shaped microsclerotia. Thirty sclerotia from a representative isolate measured average 63-171 μM length x 57-128 μM wide. The morphological features matched the description of Macrophomina phaseolina (Abd Rahim et al. 2019). The fungal genomic DNA was extracted based on Khoo et al. (2022a and 2022b). PCR was performed using primer sets ITS1/ITS4 (White et al. 1990), EF1-728/EF2 (O'Donnell et al. 1998; Carbone and Kohn, 1999) and T1/T22 (O'Donnell and Cigelnik 1997) to amplify the internal transcribed spacer (ITS) region of rDNA, translation elongation factor 1-α (TEF-1α) region and partial β-tubulin (TUB) gene. PCR products with positive amplicons were sent to Apical Scientific Sdn. Bhd. in Malaysia for sequencing. According to results (GenBank Accession No. OK465197, OM677767, ON237461), they were 100% identical with the reference sequence of Macrophomina phaseolina containing approximately 537 bp, 438 bp and 659 bp of the presented ITS, TEF-1α and TUB region (GenBank Accession No. MN629245, MN136199 and KF952208, respectively). The pathogen was identified as M. phaseolina based on its morphological and molecular data (Abd Rahim et al. 2019). To confirm the pathogenicity test, three non-wounded and healthy leaves of one-month-old 'Kasai' seedlings were inoculated with mycelium plug (1 x 1 cm) of M. phaseolina. Additional three 'Kasai' seedlings were inoculated with sterile PDA agar plug (1 x 1 cm) to serve as controls. The seedlings were monitored and incubated in a greenhouse at ambient temperature based on Iftikhar et al. (2022). After 6 days of inoculation, all infected leaves exhibited the symptoms as observed in the nursery, while the controls remained asymptomatic. The experiment was repeated twice. Re-isolation was performed from the symptomatic leaves and controls. The reisolated fungal isolates were identical to M. phaseolina morphologically and molecularly. No pathogens were isolated from the mock controls. M. phaseolina has been reported to cause leaf blight on Jasminium multiflorum in India (Mahadevakumar and Janardhana, 2016), and Crinum asiaticum and Hymenocallis littoralis in Malaysia (Abd Rahim et al. 2019). To our knowledge, this is the first report of M. phaseolina causing leaf blight on 'Kasai' in Malaysia and worldwide. Our findings serve as a warning for the authorities and farmers that the disease threat has appeared for 'Kasai' in Malaysia.
'Thai Gold' yellow pitahaya (family Cactaceae, Selenicereus megalanthus) is a new crop being planted commercially in Malaysia. In May 2021, reddish-brown necrotic lesions were observed on the stems of approximately 60% of 'yellow pitahaya' plants in the field (~8 ha) located in the district Keningau of Sabah, Malaysia (5°20'53.1"N 116°06'23.0"E). As the disease progressed, the smaller lesions merged into larger irregularly shaped areas that formed dark brown in color. Stems with reddish-brown spot symptoms from ten plants were collected from the field and brought to the laboratory in sterilized paper bags. The symptom margin was excised into small blocks (5 x 5 x 5 mm). The blocks were surface sterilized based on Khoo et al. (2022), and placed on potato dextrose agar (PDA). The pathogens were isolated (three isolates were obtained) and cultured on potato dextrose agar (PDA) at 25°C for 5 days in the dark. The isolates developed floccose, white colony that darkened with age in PDA. Conidia (n = 30) were single celled, black, smooth, globose to subglobose, 13.9 to 18.7 μm in diameter, and borne singly on a hyaline vesicle at the tip of each conidiophore. Genomic DNA was extracted from fresh mycelia based on Khoo et al. (2021) and Khoo et al. (2022). Amplification of the internal transcribed spacer (ITS) region of rDNA, translation elongation factor 1-α (tef1-a) region and β-tubulin (tub2) genes were performed using ITS1/ITS4 (White et al. 1990), EF1-728F/EF2 (O'Donnell et al. 1998; Carbone and Kohn, 1999) and T10/Bt2b (Glass and Donaldson, 1995; O'Donnell and Cigelnik, 1997) primer sets, respectively. The products were sent to Apical Scientific Sdn. Bhd. for purification and sequencing. BLASTn analysis of the newly generated ITS (OK448496, OM832586, OM832589) were 100% identical to Nigrospora sphaerica isolate 1SS (MN339998) (507/507 bp), tef1-a (OM223859, OM826971, OM826972) were 100% identical to Nigrospora sphaerica isolate F (MT708197) (497/497 bp) and tub2 (OL697400, OM826973, OM826974) were 100% identical to Nigrospora sphaerica isolate SN180517 (MN719407) (434/434 bp). The isolates established a supported clade to the related N. sphaerica type sequences, according to phylogenetic analysis using maximum likelihood based on the concatenated ITS, tef1-a and tub2 sequences. Morphological and molecular characterization matched the description of N. sphaerica (Kee et al. 2019). Koch's postulates were performed by spray inoculation (106 spores/ml) of isolate Keningau on the stem of three 'Thai Gold' yellow pitahaya plants in growth stage 4 (BBCH code: 419) (Kishore, 2016), while water was sprayed on three mock controls. The experiment was repeated using isolate Keningau02 and Keningau03 as inoculants. The inoculated stems on yellow pitahaya plants were covered with plastics for 48 h, and the plants were maintained in a greenhouse at room temperature 25 to 28°C with a relative humidity of 80 to 90%. All the inoculated stems developed symptoms 5 days post-inoculation, whereas no symptoms occurred on mock controls, thus fulfilling the Koch's postulates. No pathogen was isolated from the mock controls. The experiments were repeated two more times for each isolate. The reisolated fungi were identical to N. sphaerica morphologically and molecularly. Previously, N. sphaerica has been reported to cause stem brown spot disease on S. megalanthus in the Philippines (Taguiam et al. 2020). To our knowledge, this is the first report of N. sphaerica causing stem brown spot on 'Thai Gold' S. megalanthus in Malaysia. Our findings serve as a warning for the authorities and farmers that the disease threat has appeared for the Malaysian yellow pitahaya production.
Selenicereus megalanthus (family Cactaceae), commonly known as yellow pitahaya is a new crop being planted commercially in Malaysia. In May 2021, stem canker symptoms with sign of black pycnidia formed on the surface of canker (30- to 55-mm in diameter) were observed on the stem of 80% of 'yellow pitahaya' plants in the field (~8 ha) located in the district Keningau of Sabah, Malaysia (5°20'53.1"N 116°06'23.0"E). The infected stems became rotted when black pycnidia formed. To isolate the pathogen, the symptom margin was excised into four small blocks (5 x 5 x 5 mm), and the blocks were surface sterilized based on Khoo et al. (2022) before plating on potato dextrose agar (PDA). Plates were incubated at 25°C for 7 days in the dark. Two isolates were obtained and were named Keningau and Keningau02. Powdery white mycelia were initially observed in two plates, and then became dark grey with age. Dark pigmentation in plates was observed after a week of incubation at 25°C in the dark. Arthroconidia (n= 30) were hyaline to dark brown, circular or cylindrical with round to truncate ends, with zero to one septum, measuring 8.9 x 5.6 µm in size. Conidia (n= 30) exuded in milky white cirrhus from pycnidia were one-celled, aseptate, oblong, measuring 10.3 × 4.6 µm in size. When reached the maturity stage, conidia were brown and septate. Genomic DNA from Keningau and Keningau02 were extracted from fresh mycelia based on Khoo et al. (2021) and Khoo et al. (2022). Amplification of the internal transcribed spacer (ITS) region of rDNA, translation elongation factor 1-α (TEF1) region and β-tubulin (TUB) genes were performed using ITS1/ITS4, EF1-728F/EF1-986R and T10/Bt2b primer sets, respectively (Carbone and Kohn, 1999; O'Donnell et al. 1997; White et al. 1990). The products were sent to Apical Scientific Sdn. Bhd. for sequencing. BLASTn analysis of the newly generated ITS (GenBank OK458559, OM649909), TEF1 (GenBank OM677768, OM677769) and TUB (GenBank OL697398, OM677766) indicated 99% identity to Neoscytalidium novaehollandiae strain CBS 122071 (GenBank MT592760). Phylogenetic analysis using maximum likelihood and Bayesian inference on the concatenated ITS-TEF1-TUB was constructed using IQ-Tree and MrBayes3.2.7. Neoscytalidium hyalinum, N. novaehollandiae and Neoscytalidium orchidacearum are reduced to synonymy with N. dimidiatum (Philips et al. 2013; Zhang et al. 2021). Although N. novaehollandiae is morphologically and phylogenetically similar to N. dimidiatum, but N. novaehollandiae produce muriform, Dichomera-like conidia that distinguish this species from other known Neoscytalidium species (Crous et al. 2006). No muriform, Dichomera-like conidia were observed in the Malaysia' isolates. The pathogen was identified as N. dimidiatum based on molecular data and morphological characterization (Serrato-Diaz and Goenaga, 2021). Pathogenicity tests were performed based on Mohd et al. (2013) by injection inoculation of 0.2 ml of conidial suspensions (1 x 106 conidia/ml) from isolate Keningau to three 30-month-old yellow pitahaya stems using a disposable needle and syringe. Distilled water was injected into three mock controls. The inoculated yellow pitahaya plants were covered with plastics for 48 h and incubated at 25°C. The pathogenicity test was also performed using isolate Keningau02. All inoculated stems developed symptoms as described after 6 days post-inoculation, whereas no symptoms occurred on controls, thus fulfilling Koch's postulates. The experiments were repeated two more times. The reisolated fungi were identical to the pathogen morphologically and molecularly. To our knowledge, this is the first report of N. dimidiatum causing stem canker on S. megalanthus in Malaysia. Our findings serve as a warning for the authorities and farmers that the disease threat has appeared in the Malaysian yellow pitahaya production.
Mango originated in the Indo-Burmese region (Alphonse de Candolle, 1885). In the Caribbean, Puerto Rico currently produces and exports mangoes to the United States and Europe. Globally, an important disease affecting mango production is dieback, caused by fungi belonging to Botryosphaeriaceae family. During a one-year survey from 2019 to 2020, conducted at the mango germplasm collection of the Agricultural Experiment Station of the University of Puerto Rico, located at Juana Díaz, PR, symptoms of dieback were observed in shoots, descending towards the woody part, and vascular necrosis. We sampled bimonthly, 35 Keitt trees for one year. At the end of the evaluation, we detected that a 74% disease incidence was caused by Botryosphaeriaceae. Lasiodiplodia mahajangana (syn. L. caatinguensis) was associated with 4% disease incidence. In addition, we identified other Botryosphaeriaceae species causing 70% of disease incidence. To identify the causal agent, sections of symptomatic tissue (4mm2) were surface disinfected by immersion in 70% ethanol, 10% sodium hypochlorite and rinsed with sterile-distilled water for 1 minute at each solution. Sections were transferred to petri dishes containing potato dextrose agar acidified with 85% lactic acid (aPDA). Ten fungal isolates were obtained with similar morphological characteristics such as colony color and texture, after 12 days. Of these, one representative (isolate 17) was selected and identified as L. mahajangana (Lm) using morphological parameters and sequences of four nuclear genes (Zhang, W. et al., 2021). In aPDA, Lm colonies showed sparse and slow-growing aerial mycelium with dark gray-greenish color at the center and light gray edges. Black pycnidia were observed after 15 days of incubation at 28°C and dark conditions. Hyaline, ovoid to ellipsoid immature conidia (n=40) with average size of 22 µm long and 12 µm wide were observed. Mature bicellular pigmented conidia (n=40) had longitudinal striate and its average size was 23 µm long and 12 µm wide. Internal transcribed spacer (ITS), β-tubulin (βtub), elongation factor 1-alpha (EF1-α) and large ribosomal subunit (LSU) genetic regions were amplified by PCR from the original and pathogenicity test recovered isolates. Sequences of PCR products were compared with NCBI database BLAST tool with other Lm sequences. Sequence accession numbers of the four genetic regions of Lm are as follows: OL375401 and OL375402 for the ITS region; OL405579 and OL405580 for β-tubulin; OL455922 and OL455923 for EF1-α; and OL375648 and OL375649 for LSU. All the sequences were grouped with the ex-type CMM1325 of Lm (BS=84). Pathogenicity tests were performed on 6-month-old mango trees of cv. Keitt. Three healthy trees were inoculated with 5 mm mycelial disks of Lm, on stems, with and without wounds. Controls were inoculated with aPDA disks only. Inoculated trees were covered for 3 days with plastic bags, keeping them in conditions of high relative humidity with constant irrigation, temperature of 28°C, and 12 hours of light and 12 hours of darkness for 12 days. Twelve days after inoculation, Lm isolates caused stem necrosis and canker, with differences in lesion severity from 2 to 17 mm2 with wound, and 0 to 6 mm2 without wound. Untreated controls showed no symptoms of canker. Lasiodiplodia mahajangana was re-isolated from diseased stems fulfilling Koch's postulates, and a sequence of the recovered isolate from the pathogenicity test was compared and included in the phylogenetic analysis. Lasiodiplodia mahajangana has been reported to cause stem-end rot of mango in Malaysia (Li, L. et. al., 2021). To our knowledge, this is the first report of Lm causing canker of mango in Puerto Rico. Knowing L. mahajangana as a new pathogen that causes canker of mango is important to establish an adequate and effective control management of this disease in mango producing countries worldwide.
Platostoma palustre (family Lamiaceae), locally known as 'Black Cincau', is an herb processed as herbal drinks in Malaysia. In November 2021, brown lesions were observed on leaf samples of P. palustre with an incidence of approximately 10% in a nursery in Penampang, Sabah province (5°55'30.4"N 116°04'35.7"E). The lesions developed into larger chlorotic spots with aging of leaves. Five samples of infected leaves were collected, excised (5 × 5 mm), and then surface sterilized with 75% ethanol for 1 minute, washed with 2% sodium hypochlorite solution for 1 minute, rinsed, and air dried before inoculated onto potato dextrose agar (PDA). Inoculated plates were incubated at 25°C. Three isolates were isolated from the samples, which showed cottony aerial mycelia with light purple concentric rings appeared on the reverse side of the colony after 3 days. Pycnidia which were spheroid and measured 64.0 to 114.1 × 41.2 to 88.0 μm (n= 30). Conidia, unicellular, hyaline, oval and measured 3.8 to 4.9 × 2.0 to 2.7 μm (n= 30). Chlamydospores were observed, either unicellular or multicellular. NaOH test on oatmeal agar positive, brownish red. Further, the genomic DNA of pathogens (UMS, UMS02 and UMS03) was extracted from fresh mycelia (7-day-old) using lysis buffer. Large Sub Unit (LSU), β-tubulin (tub) and RNA polymerase II (RPB2) gene were amplified using LR0R/LR7, T10/Bt2b and RPB2-5F2/RPB2-7cR primers (Rehner and Samuel, 1994; O'Donnell and Cigelnik, 1997; Liu et al. 1999) respectively. The sequences of isolate UMS, UMS02 and UMS03 which deposited in Genbank were OM238129, ON386254, ON386255 (LSU), OM048108, ON366806, ON366807 (tub), and ON003417, ON366804, ON366805 (RPB2). They had 99-100% homology to the LSU (1328/1328 bp) of Epicoccum sorghinum isolate Lido01 (OM501128), tub (422/425 bp) of isolate BJ-F1 (MF987525), and RPB2 (596/596 bp) of isolate HYCX2 (MK836295). Phylogenetic analysis by maximum likelihood method generated from the combined tub, LSU and RPB2 sequences indicated that the isolates formed a supported clade to the related Epicoccum sorghinum type sequences. Morphological, NaOH test and molecular characterization matched the description of E. sorghinum (Boerema et al. 2004; Li et al. 2020). Koch's postulates were performed by spray inoculation (106 conidia/mL) on the leaves of three healthy P. palustre seedlings with isolate UMS, while water was sprayed on three additional P. palustre seedlings served as controls. The plants were maintained in a greenhouse at room temperature 25 to 28°C with a relative humidity of 80 to 90%. All inoculated plants exhibited the symptoms similar to those of the nursery collection occurred after 8 days post inoculation. No symptoms occurred on controls. The experiment was repeated twice. The reisolated pathogen was morphologically identical to E. sorghinum. E. sorghinum was reported previously on Myrica rubra in China (Li et al. 2020). To our knowledge, this is the first report of E. sorghinum causing leaf spot on P. palustre in Malaysia. Our findings expand the host range of E. sorghinum in Malaysia.
Basella rubra (family Basellaceae), locally known as 'Remayong Merah', is an edible perennial vine served as leafy greens in Malaysia. In May 2021, leaves with circular brown spots ranging from 3 to 10 mm wide with purple borders were found on B. rubra growing in Penampang (5°56'55.6"N 116°04'33.5"E), Sabah province. The disease severity was 80% with 10% disease incidence on 50 plants. As the disease developed, the lesions grew larger and they developed necrotic centers. Leaves with brown spot symptoms from five plants were collected from the field. Five leaf pieces (5 x 5 mm) were excised from lesion margins, surface sterilized based on Khoo et al. (2022b), before incubation on water agar at 25°C. When five pure cultures were obtained, the fungi were cultured on potato dextrose agar (PDA) at 25°C. After 5 days, fluffy white mycelia tinged with pink pigmentation showing on the underside of the colony were observed on PDA. Mycelia became violet in color as the culture aged. The isolates were incubated on carnation leaf agar at 25°C with a 12-hour light/dark photoperiod for 10 days. Sickle-shaped, thin-walled and delicate macroconidia (n= 30), predominantly 3 septate, ranging from 21.6 to 38.3 μm long by 2.7 to 4.2 μm wide in size were observed. Kidney-shaped, aseptate microconidia (n= 30) ranged from 6.2 to 11 μm long by 2.6 to 3.9 μm wide in size, and were formed on monophialides in false heads. Chlamydospores were detected both terminally and intercalarily, singly or in pairs, with smooth or rough walls. Genomic DNA was extracted from fresh mycelia of a representative isolate from Penampang based on Khoo et al. (2022a). The primers ITS1/ITS4 (White et al. 1990) and EF1/EF2 (O'Donnell et al. 1998) were used to amplify the internal transcribed spacer (ITS) rDNA and translation elongation factor 1-α (TEF1α) region, respectively based on PCR conditions as described previously (Khoo et al. 2022b). The products were sent to Apical Scientific Sdn. Bhd. for sequencing. In BLASTn analysis, ITS sequence (OK469301) was 99% (506/507 bp) identical to isolate TSE07 (MT481761) of Fusarium oxysporum, and the TEF1α sequence (OM743433) was 100% (705/705 bp) identical to isolate BLBL5 of Fusarium oxysporum. The TEF1α sequence of Penampang was analyzed at the Fusarium MLST site (https://fusarium.mycobank.org/), and had 98% similarity to TEF1α of F. oxysporum (NRRL 22551). The pathogen was identified as F. oxysporum based on morphological (Leslie and Summerell 2006) and molecular data. A volume of 0.16 ml of spore suspensions (1 × 106 conidia/ml) were inoculated on a spot on each leaf of every three healthy B. rubra seedlings at the two-leaf stage. An additional three B. rubra seedlings were mock inoculated by pipetting sterile distilled water on similar aged leaf. The seedlings were maintained in a greenhouse at 25°C with a relative humidity of 80 to 90%. Six days after inoculation, all inoculated leaves exhibited the same symptoms as observed in the field, while the controls showed no symptoms. The experiment was repeated two more times. The reisolated fungi had the same morphology and DNA sequences as the original isolate obtained from the field samples, completing Koch's postulates. F. oxysporum has been reported previously in Bangladesh and India causing leaf spot disease on B. rubra (Dhar et al. 2015; Shova et al. 2020). To our knowledge, this is the first report of F. oxysporum causing leaf spot on B. rubra in Malaysia. The identification of leaf spot caused by F. oxysporum will enable plant health authorities and farmers to identify practices to minimize disease on this important crop.
Rice (Oryza sativa) is a staple food for most of the world's populations, particularly in Asia (Gumma et al. 2011). The rice sector provides Malaysians with a food supply, food sufficiency, and income for growers (Man et al. 2009). From January to February 2022, panicle samples showing symptoms of bacterial panicle blight (BPB) disease, including reddish-brown, linear lesions with indistinct margins on flag-leaf sheaths and blighted, upright, grayish straw-colored florets with sterile and aborted grains on panicles were collected in granary areas in Sekinchan, Selangor, Malaysia with 90% disease incidence in fields. Surface-sterilization of infected leaf tissue was performed using 75% ethanol and 1% sodium hypochlorite, followed by rinsing three times in sterilized water. Leaf tissue was macerated in sterilized water and aliquots were spread on King's B agar medium, then cultured for 24 h to 48 h at 35 °C. All isolated bacteria were Gram-negative rods, positive for catalase and gelatinase but negative for indole, oxidase and hydrogen sulfide (H2S), and utilized sucrose, inositol, mannitol, glucose, and citrate. Colonies were circular and smooth-margined, producing a diffusible yellowish-green pigment on King's B agar medium, which are characteristics of Burkholderia species (Keith et al. 2005). Five representative isolates (UPMBG7, UPMBG8, UPMBG9, UPMBG15, UPMBG17) were selected for molecular and pathogenicity tests. PCR using specific primers targeting the gyrB gene for molecular characterization was performed, and the ∼470 bp amplicons were sequenced (Maeda et al. 2006) and deposited in GenBank (OM824438 to OM824442). A BLASTn analysis revealed that the five isolates were 99% identical to the B. gladioli reference strains MAFF 302533, GRBB15041, and LMG19584 in GenBank (AB190628, KX638432, and AB220898). A phylogenetic tree using Maximum-likelihood analysis of the gyrB gene sequences showed that the five isolates were 99% identical to B. gladioli reference strains (AB190628, KX638432, and AB220898). To verify the identification of these isolates, the 16S rDNA gene was amplified using 16SF/16SR primers (Ramachandran et al. 2021), producing ~1,400 bp amplicons. The resulting sequences of the five isolates (OM869953 to OM869957) were 98% identical to the reference strains of B. gladioli (NR113629 and NR117553). To confirm pathogenicity, 10 ml suspensions of the five isolates at of 108 CFU/ml were inoculated into the panicles and crowns of 75-day-old rice seedlings of local rice varieties MR269 and MR219 grown in a glasshouse with temperatures ranging from 37 °C to 41 °C (Nandakumar et al. 2009). Control rice seedlings were inoculated with sterilized water. All isolates produced BPB disease symptoms like those originally found in the rice fields at four weeks after inoculation. Control seedlings remained asymptomatic. To fulfill Koch's postulates, the bacteria were reisolated from symptomatic panicles and were confirmed as B. gladioli by sequence analysis of the gyrB and 16S rDNA genes. To our knowledge, this is the first report of B. gladioli causing BPB disease of rice in Malaysia. Since BPB disease causes a significant threat to the rice industry, it is crucial to investigate the diversity of this destructive pathogen for effective disease management strategies in Malaysia.