Fusarium amaranthuense sp. nov. from amaranth is an emergent species closely related to Fusarium circinatum.

Amaranth (Amaranthus spp. L) is not native to South Korea but cultivated in small scales for ornamental purposes as well as leafy vegetables and pseudo cereals. In this study, a new species within the genus Fusarium was isolated from amaranth, showing stem rot symptoms from a farmer field in Hwaseong, South Korea. The disease is characterized by dark-brown spots with black borders, leading to withering. Phylogenetic analysis based on concatenated sequences of translation elongation factor 1-alpha (TEF1), beta-tubulin (tub2), calmodulin (cmdA), RNA polymerase largest subunit (RPB1) and RNA polymerase II second largest subunit (RPB2) genes, revealed that the obtained isolates were formed a distinct clade within the Fusarium fujikuroi species complex and closely related to F. circinatum. Cultural and morphological characteristics and pathogenicity on healthy amaranth plants (stem and leaves) were examined. The isolates readily differentiated from F. circinatum based on 1-5 septate macroconidia and the absence of sterile hyphae. Based on molecular and morphological characteristics, this fungus is demonstrated to be a new species and is described here as Fusarium amaranthuense, the causal agent of stem rot of amaranth in South Korea.

First Report of Root and Collar Rot caused by Phytophthora nicotianae on ⨯Graptoveria 'Silver Star' in Korea.

⨯Graptoveria 'Silver Star' (a cross between Graptopetalum filiferum and Echeveria agavoides) from the Crassulaceae family, are an evergreen succulent with lotus constellation-shaped flowers, making it consumer favorite ornamental plant in Korea. In 2019, Korea's ornamental production was estimated at KRW 517.4 billion (EUR 382 million), from 4,244 ha of farming area according to the Ministry of Agriculture, Food and Rural Affairs of Korea. In July 2023, ⨯Graptoveria 'Silver Star' plants with chlorotic leaves, root and collar rot were observed in a greenhouse in Yongin (37°14'27.9"N, 127°10'39.19"E), Korea. To isolate the causal agent, small pieces (1 mm2) of symptomatic tissues were surface-sterilized using 1% NaOCl for 1 min, then put onto a water agar (WA) plate and incubated in the dark at 25℃ for five days. Two isolates (FD00202, FD00203) were obtained from diseased leaves, stem and roots by isolating single sporangium. To investigate the morphological characteristics of the isolates, the mycelium from potato dextrose agar (PDA) were transferred to V8 agar (V8A) followed by incubation at 25°C in the dark for 7 days. The isolates produced dense cottony mycelium, with slightly petaloid and light rossette pattern, with coralloid edges measuring 70 to 83 mm diameter. Sporangium were spheroid (30.0-48.0 µm long, 25.0-35.0 µm wide) with globose chlamydospores (17.0-50.0 µm long, 18.0-38.0 µm wide). Oogonia were not observed. Morphological and cultural characteristics of these isolates were phenotypically similar to that of Phytophthora nicotianae (Faedda et al. 2013; Abad et al. 2023). For molecular identification, genomic DNA was extracted from 5 days old cultures using the Maxwell® RSC PureFood GMO and Authentication Kit (Promega). Two gene regions, the rDNA-ITS, COX I were amplified and sequenced using primers ITS1/ITS4 and FM83/FM84, respectively (White et al. 1990; Martin and Tooley 2003). The resulting sequences were deposited in GenBank with accession no. LC783858 to LC783861. A BLASTn search of the DNA sequences from ITS, COX I showed 99.81 and 98.94% identity to P. nicotianae isolate IMI 398853, respectively. Maximum likelihood phylogenetic analyses were performed for the combined data set with ITS, COX I using MEGA7 under the Tamura-Nei model (Kumar et al. 2016). The isolates formed a monophyletic group with P. nicotianae isolate IMI 398853, CPHST BL162, and CPHST BL 44. Based on morphological characteristics and molecular analysis, the isolates were identified as P. nicotianae. T confirm their pathogenicity, inoculum was prepared in accordance with Ann (2000). Artificially wounded healthy plant roots were dipped in zoospore suspension (3.0 × 106 zoospore/ml) for 24 hours, with mock-treated plants (control) dipped in sterile distilled water (Ann. 2000). Thereafter, the plants were transplanted into new medium and kept under high humidity. Symptoms were observed after 10 days of incubation. The plants inoculated with P. nicotianae showed similar symptoms of chlorotic leaves with root and collar rot, while control remained symptomless. The pathogen was re-isolated from all inoculated plants and confirmed as P. nicotianae by morphological and molecular analysis. but not from controls, fulfilling Koch's postulates. Phytophthora nicotianae was previously report on Echeveria derenbergii and Kalanchoe blossfeldiana causing brown spot on stems and roots in California and Korea, respectively (French 1989; Oh and Son 2008). To best of our knowledge, this is the first report of P. nicotianae causing root and collar rot on ⨯Graptoveria 'Silver Star' plants in the Korea.

Occurence of leaf spot on Narrow-head ragwort (Ligularia stenocephala) caused by Alternaria cinerariae in Korea.

Narrow-head ragwort (Ligularia stenocephala (Maxim.) Matsum. & Koidz.) has been used for medicinal purposes and a leafy vegetable in South Korea (Choi et al., 2007; Debnath et al., 2017). In May 2022, brown spots and blight were observed on the leaves in a farmer's field in Namwon (35°26'58.9"N, 127°28'55.9"E), Korea. About 80% of the plants in a 3000 m2 cultivation area were infected. To isolate the causal agent, small pieces (1 mm2) surface-sterilized (1% NaOCl for 1 min) symptomatic leaf tissues were put onto a water agar (WA) plate and incubated in the dark at 25℃. After five days of incubation, two isolates (FD00021, FD00022) were obtained from diseased leaves using a single spore isolation technique. Morphological characteristics were examined after seven days of incubation at 25℃ in the dark. Colonies were 51.6 to 65.3 mm in diameter, gray-green in the center, and ivory at the edge. Conidiophores were straight or curved and 10 - 34 × 4 - 5 µm. Conidia were solitary or two to four in a chain, long ellipsoid to obclavate, one to thirteen transverse septa, 52 - 169 ×14 - 34 µm, blunt-tapered beak variable in size 4 - 56 × 3 - 10 µm (n=75). The morphological and cultural characteristics of the isolates were consistent with that of Alternaria cinerariae (Nishikawa and Nakashima, 2015; Simmons, 2007). For molecular identification, genomic DNA was extracted from 5-day-old cultures using the Maxwell® RSC PureFood GMO and Authentication Kit (Promega). Five gene regions, including rDNA ITS, GPD, Alt a, RPB2, and EF1-α were amplified and sequenced using ITS1/ITS4, gpd1/gpd2, Alt-a1-for/ Alt-a1-rev, RPB2-5F2/RPB2-7cR, and EF1-728F/EF1-986R primer sets respectively (Wang et al., 2022; Garibaldi et al., 2022). The resulting sequences were deposited in GenBank with accession no. OP785152, OP785153 and OP832000 to OP832007). The concatenated genes (rDNA ITS, GPD, Alt a, RPB2, and EF1-α) sequence identity of the FD00021 and FD00022 against the reference strain A. cinerariae CBS 116495 is 99.92% (2572/2574) and 99.84% (2570/2574), respectively. Maximum Likelihood tree was inferred based on the concatenated sequences of the five gene regions using the Kimura 2-parameter model with 1,000 bootstrap replications. The phylogenetic tree showed that the present strains and A. cinerariae CBS 116495 fell into the same clade with high bootstrap support (100%). Based on morphological characteristics and molecular analysis, the isolates were identified as A. cinerariae. To confirm their pathogenicity, drops (70 µl) of conidial suspension (1×104 spores/ml) were applied on intact healthy leaves (3 leaves/plant) of plants (3 plants/isolate) that had been cultivated for one month after transplantation as seedlings. Controls were treated with sterile distilled water. The treated plants were covered with plastic boxes to maintain humidity around 90% and were maintained in an incubator at 25℃ in a 12-hour light-dark cycle. Symptoms appeared only on inoculated leaves after four days of inoculation, while controls remained asymptomatic. The A. cinerariae isolates were re-isolated from infected tissue of the inoculated leaves, thus fulfilling Koch's postulates. Alternaria cinerariae is an important plant pathogen that can cause leaf spot and blight on a variety of host plants including Cineraria spp. and Tussilago farfara (He et al. 2020). This is the first report on leaf spot on Narrow-head ragwort caused by A. cinerariae in the world. Leaf spot disease caused by Alternaria cinerariae is a significant threat to narrow-head ragwort agriculture in South Korea. Therefore, its control strategies are necessary for increasing productivity.

Diversity and pathogenic characteristics of the Fusarium species isolated from minor legumes in Korea.

Legumes are primarily grown agriculturally for human consumption, livestock forage, silage, and as green manure. However, production has declined primarily due to fungal pathogens. Among them, this study focused on Fusarium spp. that cause Fusarium wilt in minor legumes in Korea. Diseased legume plants were collected from 2020 to 2021, and diverse fungal genera were isolated from the internal tissues of the plant roots and stems. Fusarium spp. were the most dominant, accounting for 71% of the isolates. They were identified via morphological characteristics and molecular identification. In the pathogenicity test, Fusarium oxysporum and Fusarium fujikuroi generally exhibited high virulence. The host range investigation revealed that the NC20-738, NC20-739, and NC21-950 isolates infected all nine crops, demonstrating the widest host range. In previous studies, the focus was solely on Fusarium wilt disease in soybeans. Therefore, in this study, we aimed to investigate Fusarium wilt occurred in minor legumes, which are consumed as extensively as soybeans, due to the scarcity of data on the diversity and characteristics of Fusarium spp. existing in Korea. The diverse information obtained in this study will serve as a foundation for implementing effective management strategies against Fusarium-induced plant diseases.

First Report of Verticillium Wilt caused by Verticillium dahliae on Chilli in South Korea.

Chili pepper (Capsicum spp.) is an important crop in South Korea and is widely used in Korean cuisine, cultivated across a land area of roughly 29.8 thousand hectares, with a total production of 69 thousand tons (Lee et al., 2005; Statista, 2022). In September 2020, two farmer fields in Samcheok (37.444039°N, 129.135875°E; 37.633738°N, 128.911731°E), Gangwon province, South Korea, it is observed that chili pepper leaves showing yellowing and wilting symptoms, with an estimated disease incidence of approximately 10-15%. To identify the causal agents six affected plants were brought to lab. All the plants exhibited vascular discoloration in stem and root. After surface sterilizing small pieces of discolored tissue in 1% NaOCl for 30 s and rinsing twice in sterile distilled water, the tissue pieces were placed on water agar and incubated at 25°C for 10 days. Six pure isolates with consistent morphological characteristics were obtained by single spore isolation. Two representative isolates, NC17601 and NC20845 were selected for identification based morphological and molecular characters. Colonies on potato dextrose agar (PDA) during 10 days of incubation at 25°C in the dark were cottony white initially but progressively became dark as the formation of melanized microsclerotia. Conidiophores were hyaline, vertically branched or not, and had 2 - 4 phialides per node. Phialides were subulate and tapering from base to tip. The colonies produced abundant conidia, which were hyaline, single celled, smooth walled, cylindrical to oval, clustered on phialides, and 3.8 - 7.2 ×2.1 - 3.9 ㎛(mean ± SD: 5.2 ± 0.7 × 2.8 ± 0.5). Microsclerotia were aggregated form, various size and shape, and brown. These are the typical morphology of Verticillium dahliae (Inderbitiz et al. 2011; Yu et al. 2016). The molecular identification was later confirmed through PCR amplification, and sequencing targeting the translation elongation factor 1 alpha (TEF), actin (ACT), tryptophan synthase (TS), and glyceraldehyde-3-phosphate dehydrogenase (GPD) genes using the primer sets described by Inderbitiz et al. (2011). The resulting sequences were deposited in GenBank with accession numbers LC761935 to LC761942. The maximum likelihood tree based on combined sequences of ACT, GPD, TEF and TS was inferred using RAxML- HPC2 on XSEDE as implemented on the CIPRES web server. The phylogenetic tree showed that the isolates were sit together with V. dahliae isolates (Ex-type PD322, PD227 and PD502). Pathogenicity tests using two isolates (NC17601 and NC20845) were conducted in the greenhouse, where 10 two weeks old seedlings per isolates (cv. Bigstar) were root-tip cut and then soaked in a fungal spore suspension of 107 conidia ml-1 for 1 h, while 10 seedlings were treated with sterile distilled water as a control. All the treated plants were maintained at 25°C (night)/ 25°C (Day) under natural light. After three weeks, all inoculated plants exhibit growth stunting with vascular discoloration in the stem and roots as compared to asymptomatic control plants. The isolates of V. dahliae were consistently re-isolated from discolored root tissues and identified based on morphological characteristics, thus fulfilling Koch's postulates. In South Korea, V. dahliae has been reported to cause wilt disease in various crops, including Kimchi cabbage and radish (Dumin et al. 2020; Choi et al. 2023). To the best of our knowledge, this is the first report that V. dahliae causing Verticillium wilt of chili pepper in South Korea. Overall, Verticillium dahliae is considered to be a significant threat to agriculture in South Korea, and efforts are being made to develop effective control strategies to mitigate its impact on crops.

Past and Future Epidemiological Perspectives and Integrated Management of Rice Bakanae in Korea.

In the past, rice bakanae was considered an endemic disease that did not cause significant losses in Korea; however, the disease has recently become a serious threat due to climate change, changes in farming practices, and the emergence of fungicide-resistant strains. Since the bakanae outbreak in 2006, its incidence has gradually decreased due to the application of effective control measures such as hot water immersion methods and seed disinfectants. However, in 2013, a marked increase in bakanae incidence was observed, causing problems for rice farmers. Therefore, in this review, we present the potential risks from climate change based on an epidemiological understanding of the pathogen, host plant, and environment, which are the key elements influencing the incidence of bakanae. In addition, disease management options to reduce the disease pressure of bakanae below the economic threshold level are investigated, with a specific focus on resistant varieties, as well as chemical, biological, cultural, and physical control methods. Lastly, as more effective countermeasures to bakanae, we propose an integrated disease management option that combines different control methods, including advanced imaging technologies such as remote sensing. In this review, we revisit and examine bakanae, a traditional seed-borne fungal disease that has not gained considerable attention in the agricultural history of Korea. Based on the understanding of the present significance and anticipated risks of the disease, the findings of this study are expected to provide useful information for the establishment of an effective response strategy to bakanae in the era of climate change.

First report of Choanephora rot on Lettuce (Lactuca sativa L.) caused by Choanephora cucurbitarum in Korea.

Lettuce (Lactuca sativa L.) is a vegetable belonging to the family Asteraceae, and one of the major leafy vegetables in Korea. Lettuce has long been consumed as a fresh vegetable. In 2020, 96,774 tons were produced in about 3,800 ha according to Statistics Korea, and various types of lettuce have been bred for year-round production in line with consumer needs (Jang 2007). In August 2020, symptoms of a disease on young leaves of green lettuce (cv. Cheongpungyeoreumchima) were observed in the commercial greenhouse, Jeongeup (35°37'17.5"N, 126°53'40.4"E), Korea. About 60% of plants in 500 m2 of the cultivation area were infected. The tips of infected leaves appeared water-soaked, with brown to black lesions and were covered with dark masses of sporangiophores. Two fungal isolates NC20860 and NC20861 were isolated from monosporous sporangiola in infected leaves. Two isolates produced fast-growing colonies on potato dextrose agar medium (PDA) with abundant white mycelium at the top and bright yellow pigmentation at the underside in only 2 days. Morphological characteristics of the two fungal isolates were investigated from 30 days after inoculation on PDA. Sporangiophores bearing sporangia were erect, non-septate, unbranched, hyaline, and straight. Sporangia were hyaline to brown, globose to subglobose, 28.4 to 33.6 µm diameter. Sporangiospores from sporangia were brown to dark brown, ellipsoid to ovoid, distinctly longitudinally striate, with hyaline appendages at each pole, 6.3 to 7.5 µm wide and 13.0 to 16.0 µm long. Sporangiophores bearing sporangiola were erect, unbranched, hyaline and sporangiola were fusiform, ellipsoid to broadly ellipsoid, 7.6 to 9.8 µm wide, 13.3 to 17.8 µm long. Based on the morphological and cultural characteristics, this fungus was identified as Choanephora cucurbitarum (Berk.&Ravenel) Thaxt (Kirk 1984). To identify the species of the two isolates, DNA was extracted by using the Maxwell® RSC PureFood GMO and Authentication Kit (Promega). The internal transcribed spacer (ITS) region of ribosomal DNA was amplified using nTaq-Tenuto polymerase chain reaction (PCR) kit and therein specified protocol (Enzynomics). The primers ITS1F and ITS4 were used for PCR and sequencing (Gardes 1991). The ITS sequences of the isolates NC20860 and NC20861 from Korea (NCBI GenBank accession no.MZ960299, MZ960300) and the sequences of C. cucurbitarum strains CBS 150.51 (MH856791.1), and KUS-F29113 (KU316934.1) were compared. The sequences of the isolates were identical to those of the reference strains of C. cucurbitarum CBS 150.51 (reference/isolates base pairs, 566/566) and KUS-F29113 (572/572) at the 100% of sequence similarity. Pathogenicity test was conducted using seedlings of 8-week-old green lettuce (cv. Cheongsimchima) by spraying spore suspension (2⨉104 spores/ml). The plants were covered with plastic bags and incubated at 25 ℃ and 70 to 90% RH with a 12-h photoperiod for 20 days. The symptoms were observed only on the inoculated plants within 20 days after inoculation. The inner leaves of the inoculated lettuces had water-soaked lesions. No symptoms were observed in controls. C. cucurbitarum was reisolated from inoculated lettuce, fulfilling Koch's postulates. This fungus has been reported as the causal pathogen of fruit and blossom rot in cucurbits and other plants (Akwaji 2014). However, to our knowledge, occurrence of this pathogen on lettuce has not been reported as yet. This disease is crucial for producers because infected leaves directly results in yield loss of lettuce. This is the first report of Choanephora rot on lettuce caused by C. cucurbitarum in Korea and worldwide.

Optical regulation of endogenous RhoA reveals selection of cellular responses by signal amplitude.

How protein signaling networks respond to different input strengths is an important but poorly understood problem in cell biology. For example, RhoA can promote focal adhesion (FA) growth or disassembly, but how RhoA activity mediates these opposite outcomes is not clear. Here, we develop a photoswitchable RhoA guanine nucleotide exchange factor (GEF), psRhoGEF, to precisely control endogenous RhoA activity. Using this optical tool, we discover that peak FA disassembly selectively occurs upon activation of RhoA to submaximal levels. We also find that Src activation at FAs selectively occurs upon submaximal RhoA activation, identifying Src as an amplitude-dependent RhoA effector. Finally, a pharmacological Src inhibitor reverses the direction of the FA response to RhoA activation from disassembly to growth, demonstrating that Src functions to suppress FA growth upon RhoA activation. Thus, rheostatic control of RhoA activation by psRhoGEF reveals that cells can use signal amplitude to produce multiple responses to a single biochemical signal.

First Report of Fusarium ipomoeae causing Fusarium wilt on Glycine max in South Korea.

Soybean (Glycine max L.) is one of the most important crops worldwide. In South Korea, three species of Fusarium have been reported as causal pathogens of Fusarium wilt of soybean (KSPP, 2021). From 2017 to 2018, wilted soybeans were observed in two soybean fields in Daegu (36.62°126.91°) and Yesan (35.89°128.44°), South Korea. The incidence rate was about 2 to 5% of the total 0.1ha, respectively. The diseased soybeans were yellowed from the lower leaves or dried up, and the inside of the root and stem were turned brown. Fragments (each 5 mm × 5 mm) of the symptomatic vascular tissue were surface-sterilized with 1% NaOCl for 1 min, and then rinsed twice in sterilized distilled water. The seven pieces each from two diseased plants were placed on water agar and incubated at 25°C for 5 days. Two single spore isolates were cultured on carnation leaf agar at 25°C for 14 days under near ultra violet/dark conditions for 12 hours. Macroconidia of two isolates were mostly 3- to 5-septate, dorsiventral curvature, hyaline, apical cell hooked to tapering, basal cell foot-shaped, and measured 51.3 - 62.2 × 3.7 - 4.7 µm (DG43821) and 63.8-74.8×3.1-4.4 µm (YS37232). Microconidia were not observed. Chlamydospores were produced in chains or pairs, subglobose and thick walled. The color of the aerial mycelium was pinkish white and the reverse of the colony was brownish orange on potato dextrose agar. Based on morphological and cultural characteristics, the two isolates were identified as belonging to Fusarium incarnatum-equiseti species complex (Leslie and Summerell 2006). To confirm the accurate species identification of the two isolates, DNA sequencing of the internal transcribed spacers and intervening 5.8S (ITS), partial translation elongation factor 1-alpha (TEF) and RNA polymerase II largest subunit (RPB2) genes was carried out using primer sets of ITS1/ITS4, EF1 / EF2 and 7cf / 11ar, respectively (O'Donnell et al. 2010). The nucleotide sequences obtained of two isolates were deposited in GenBank with accession numbers of MW375694, MW375695, MW382963, MW382964, MZ364324 and MZ364325. Identities of the ITS region, TEF and RPB2 gene sequences of the two isolates were 490/492, 482/483, 632/633, 631/632, 870/870 and 931/931 with those of ex-type strain F. ipomoeae LC12165 (MK280832, MK289599 and MK289752) in GenBank, respectively. Thus, based on molecular characteristics, the two isolates were confirmed as F. ipomoeae. A pathogenicity test of the two isolates was conducted using root-dip inoculation on seedlings of one soybean cultivars, Pyeongwon. A spore suspension was prepared by flooding 10-day-old cultures on PDA with sterilized distilled water. Fifteen soybean seedlings at the VC stage per each isolate were inoculated by dipping the roots in the spore suspension (1 × 106 conidia/mL) for 2 hours. Inoculated plants were transplanted into pots containing sterilized soil and maintained in the greenhouse at 28±3°C with 14 h/10 h light/dark. An equal number of plants inoculated with sterilized distilled water served as controls. Five days after inoculation, withered symptoms were observed on two or four of the inoculated seedlings, and by 10 days after inoculation, all inoculated plants had withered and died. No symptoms were observed in the non-inoculated control soybeans. The pathogen was consistently re-isolated from only inoculated plants, thus fulfilling Koch's postulates. To our knowledge, this is the first report of F. ipomoeae causing Fusarium wilt on soybean in South Korea, as well as worldwide. This pathogen has been reported on peanut in China as a causal agent of leaf spot (Xu et al., 2021). Understanding the host range of this pathogen and the distribution of F. ipomoeae affecting legume crops in South Korea is important, to ensure an effective management of Fusarium wilt on soybeans.