Application of bulk segregant RNA-Seq (BSR-Seq) and allele-specific primers to study soybean powdery mildew resistance.

BACKGROUND: Powdery mildew (PM) is one of the important soybean diseases, and host resistance could practically contribute to soybean PM management. To date, only the Rmd locus on chromosome (Chr) 16 was identified through traditional QTL mapping and GWAS, and it remains unclear if the bulk segregant RNA-Seq (BSR-Seq) methodology is feasible to explore additional PM resistance that might exist in other varieties. RESULTS: BSR-Seq was applied to contrast genotypes and gene expressions between the resistant bulk (R bulk) and the susceptible bulk (S bulk), as well as the parents. The ∆(SNP-index) and G' value identified several QTL and significant SNPs/Indels on Chr06, Chr15, and Chr16. Differentially expressed genes (DEGs) located within these QTL were identified using HISAT2 and Kallisto, and allele-specific primers (AS-primers) were designed to validate the accuracy of phenotypic prediction. While the AS-primers on Chr06 or Chr15 cannot distinguish the resistant and susceptible phenotypes, AS-primers on Chr16 exhibited 82% accuracy prediction with an additive effect, similar to the SSR marker Satt431. CONCLUSIONS: Evaluation of additional AS-primers in the linkage disequilibrium (LD) block on Chr16 further confirmed the resistant locus, derived from the resistant parental variety 'Kaohsiung 11' ('KS11'), not only overlaps with the Rmd locus with unique up-regulated LRR genes (Glyma.16G213700 and Glyma.16G215100), but also harbors a down-regulated MLO gene (Glyma.16G145600). Accordingly, this study exemplified the feasibility of BSR-Seq in studying biotrophic disease resistance in soybean, and showed the genetic makeup of soybean variety 'KS11' comprising the Rmd locus and one MLO gene.

First Report of False Rust caused by Synchytrium psophocarpi on Winged Bean (Psophocarpus tetragonolobus) in Taiwan.

From September 2020 to January 2021, an unknown disease of winged bean (Psophocarpus tetragonolobus) was reported by local growers in the Toucheng Town, Yilan County (N24.91, E121.85). The disease occurs in all age of winged bean, and the occurrence tended to be higher in humid environment, such as branches in lower canopy or branches in high density. The disease symptoms, which also appeared to be the sign of the pathogen, were spherical pustules in yellow to orange color on the stems, leaves, and pods of winged bean. Severely infected plants also exhibited growth reduction, malformation, and curling of the leaves and pods. According to the disease literature of winged bean, this unknown disease was likely to be the false rust caused by a chytrid pathogen, Synchytrium psophocarpi (UK, CAB International. 1993); and the uredinia-liked pustules could be the sori, which contain numerous ovoid to globose sporangia inside. In order to characterize the pathogen identity, the sori were manually ruptured to assess the size of individual sporangium, which had an average of 26.71 ± 4.25 µm x 26.61 ± 4.60 µm (n=42), similar to the size reported in literature (Drinkall and Price. 1979). To confirm the molecular identity, the full genomic sequences from the small subunit (SSU) to the internal transcribed spacer-1 (ITS-1), 5.8S unit, and ITS-2 were amplified using the primer sets NS3 and ITS4. The 2,263 bp amplicon was cloned and sequenced to reveal the identity (Smith et al. 2014). The BLASTN results matched the SSU of our isolate (MW649126.1) to the Synchytrium minutum (HQ324138.1) with 96% similarity (1,075 out of 1,121 bp in length), Synchytrium decipiens isolate DAOM_87618 (KF160868.1) with 92% similarity (1,215 out of 1,326 bp in length) and S. decipiens isolate AFTOL-ID 634 (DQ536475.1) with 92% similarity (1210 out of 1316 bp in length). Phylogenetic analysis using the SSU sequence revealed this unknown pathogen was the grouped within the clade of Synchytrium genus with 100% bootstrapping confidence (Smith et al. 2014). Accordingly, the pathogen was confirmed to be a Synchytrium chytrid fungus. To complete the Koch's postulates, the sori were collected from infected tissue. After vortexing washing in 1% bleach for surface sterilization, the sori were gently crashed by a plastic tube pestle to harvest sporangia. The sporangia were sprayed onto healthy winged beans cultivated in pots, and the inoculated plants were kept in a moisture bag in 25 °C. While leaf curling and malformation could be observed about 14 days post inoculation, the yellow to orange sori could be observed around 30 to 40 days post inoculation on the whole plants cultivated in pots. The sori were collected to confirm the sporangia and the sequences were identical to the original pathogen. Collectively, this study not only presents the first report for the false rust of winged bean in Taiwan, but also documents the first reference sequence of S. psophocarpi that will be useful for future molecular diagnosis. Since S. psophocarpi has been only reported in tropic regions including Indonesia, Malay Peninsula, Malaysia, Papua New Guinea, and Philippines, this report provides the first observation of S. psophocarpi moving in the subtropic region.

Identification of Cyprodinil + Fludioxonil to Manage Soybean Red Crown Rot Using the Microplate-Based High-Throughput Screening and Pot Assay.

Red crown rot (RCR), caused by the soilborne fungus Calonectria ilicicola, is an emerging soybean disease in Taiwan, and fungicide screening is desired to identify effective management for C. ilicicola. This study screened 11 fungicides, including azoxystrobin, boscalid, cyprodinil, cyprodinil + fludioxonil, difenoconazole, fluopyram, flutolanil, mancozeb, prochloraz, pyraclostrobin, and tebuconazole, for their inhibitory effects on the mycelial growth of 10 C. ilicicola field isolates. Subsequently, a microplate-based high-throughput screening (MHTS) method was established to measure the fungicide sensitivity in a population composed of 80 C. ilicicola isolates to three effective fungicides, cyprodinil + fludioxonil, fluopyram, and tebuconazole. The MHTS was optimized for multiple factors, including the optical scanning pattern, absorption wavelength, conidial concentration, and measurement timing based on the quality controls of Z' factor and the log-phase growth curve. The population mean EC50 estimated by MHTS were 0.14, 2.34, and 2.46 ppm to cyprodinil + fludioxonil, fluopyram, and tebuconazole, respectively. In addition to the in vitro assessment, fungicide efficacy was evaluated by coating cyprodinil + fludioxonil, fluopyram, or tebuconazole on soybean seeds in the pot assay. The results showed that cyprodinil + fludioxonil significantly reduced both postemergence damping-off and disease severity, while fluopyram and tebuconazole reduced only the postemergence damping-off but not disease severity. Based on the MHTS and the pot assay results, this study demonstrated cyprodinil + fludioxonil to be a potential fungicide to manage soybean RCR.

A ß-lactamase gene of Fusarium oxysporum alters the rhizosphere microbiota of soybean.

The rhizosphere is a multitrophic environment, and for soilborne pathogens such as Fusarium oxysporum, microbial competition in the rhizosphere is inevitable before reaching and infecting roots. This study established a tritrophic interaction among the plant growth-promoting rhizobacterium Burkholderia ambifaria, F. oxysporum and Glycine max (soybean) to study the effects of F. oxysporum genes on shaping the soybean microbiota. Although B. ambifaria inhibited mycelial growth and increased bacterial propagation in the presence of F. oxysporum, F. oxysporum still managed to infect soybean in the presence of B. ambifaria. RNA-Seq identified a putative F. oxysporum secretory ß-lactamase-coding gene, FOXG_18438 (abbreviated as Fo18438), that is upregulated during soybean infection in the presence of B. ambifaria. The ∆Fo18438 mutants displayed reduced mycelial growth towards B. ambifaria, and the complementation of full Fo18438 and the Fo18438 ß-lactamase domain restored mycelial growth. Using the F. oxysporum wild type, ∆Fo18438 mutants and complemented strains with full Fo18438, Fo18438 ß-lactamase domain or Fo18438 RTA1-like domain for soil inoculation, 16S rRNA amplicon sequencing revealed that the abundance of a Burkholderia operational taxonomic unit (OTU) was increased in the rhizosphere microbiota infested by the strains with Fo18438 ß-lactamase domain. Non-metric multidimensional scaling and PICRUSt2 functional analysis revealed differential abundance for the bacterial ß-lactam-related functions when contrasting the genotypes of F. oxysporum. These results indicated that the Fo18438 ß-lactamase domain provides F. oxysporum with the advantage of growing into the soybean rhizosphere, where ß-lactam antibiosis is involved in microbial competition. Accordingly, this study highlights the capability of an F. oxysporum gene for altering the soybean rhizosphere and taproot microbiota.

Whole-Genome Sequence Resource of Calonectria ilicicola, the Casual Pathogen of Soybean Red Crown Rot.

Calonectria ilicicola (anamorph: Cylindrocladium parasiticum) is a soilborne plant-pathogenic fungus with a broad host range, and it can cause red crown rot of soybean and Cylindrocladium black rot of peanut, which has become an emerging threat to crop production worldwide. Limited molecular studies have focused on Calonectria ilicicola and one of the possible difficulties is the lack of genomic resources. This study presents the first high quality and near-completed genome of C. ilicicola, using the Oxford Nanopore GridION sequencing platform. A total of 16 contigs were assembled and the genome of C. ilicicola isolate F018 was estimated to have 11 chromosomes. Currently, the C. ilicicola F018 genome represents the most contiguous assembly, which has the lowest contig number and the highest contig N50 among all Calonectria genome resources. Putative protein-coding sequences and secretory proteins were estimated to be 17,308 and 1,930 in the C. ilicicola F018 genome, respectively; and the prediction was close to other plant-pathogenic fungi, such as Fusarium species, within the Nectriaceae family. The availability of this high-quality genome resource is expected to facilitate research on fungal biology and genetics of C. ilicicola and to support advanced understanding of pathogen virulence and disease management.[Formula: see text] Copyright © 2021 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license.

Phylogenomic Analysis of a 55.1-kb 19-Gene Dataset Resolves a Monophyletic Fusarium that Includes the Fusarium solani Species Complex.

Scientific communication is facilitated by a data-driven, scientifically sound taxonomy that considers the end-user's needs and established successful practice. In 2013, the Fusarium community voiced near unanimous support for a concept of Fusarium that represented a clade comprising all agriculturally and clinically important Fusarium species, including the F. solani species complex (FSSC). Subsequently, this concept was challenged in 2015 by one research group who proposed dividing the genus Fusarium into seven genera, including the FSSC described as members of the genus Neocosmospora, with subsequent justification in 2018 based on claims that the 2013 concept of Fusarium is polyphyletic. Here, we test this claim and provide a phylogeny based on exonic nucleotide sequences of 19 orthologous protein-coding genes that strongly support the monophyly of Fusarium including the FSSC. We reassert the practical and scientific argument in support of a genus Fusarium that includes the FSSC and several other basal lineages, consistent with the longstanding use of this name among plant pathologists, medical mycologists, quarantine officials, regulatory agencies, students, and researchers with a stake in its taxonomy. In recognition of this monophyly, 40 species described as genus Neocosmospora were recombined in genus Fusarium, and nine others were renamed Fusarium. Here the global Fusarium community voices strong support for the inclusion of the FSSC in Fusarium, as it remains the best scientific, nomenclatural, and practical taxonomic option available.

First Report of Soybean Seedling Disease caused by Rhizoctonia solani AG-7 in Taiwan.

From August to November 2020, reduced emergence and damping-off of soybean seedlings were observed in two fields (Benzhou and Wandan) in Taiwan. Disease incidence was approximately 40% in Benzhou by field scouting. The roots of damping-off seedlings were brown. Affected seedlings could be easily pulled out from the soil and the lesions on the roots/stem were generally dry and sunken. These symptoms suggested the possibility of Rhizoctonia infection. Soil surrounding symptomatic seedlings were collected to bait the potential pathogen and symptomatic plants were used for pathogen isolation. The diseased tissues were washed with tap water and surface-disinfected with 1% bleach before placing on the Dexon selection medium at 26°C for 2 days (Ko and Hora 1971). Hyphae were transferred to potato dextrose agar (PDA), and a brown colony with brown and irregular-shaped sclerotia grew from 90 out of 99 isolates. The hyphae exhibited typical characteristics of Rhizoctonia solani, including a constriction and a septum near the end of branching hyphae (Ajayi-Oyetunde and Bradely, 2018). Two isolates from Benzhou and two isolates from Wandan were tested for their pathogenicity, and eight surface-disinfected seeds were distributed evenly on the water agar plates covered by 2-day-old mycelia at 25°C in dark for 7 days. All isolates caused cotyledon rot and reduced germination. To verify their pathogenicity in pots, double-sterilized sorghum seeds were inoculated with two strains and incubated at 25°C for 2 weeks to be used as fungal inoculum (Ajayi-Oyetunde and Bradely, 2017). A layer of 15 ml of fungal inoculum was placed 5 cm beneath the soil surface in pots. Four soybean seeds were planted approximately 3 cm above the inoculum in each pot. After two weeks, reddish lesions on the hypocotyls or taproots of all seedlings in the inoculated pots were observed, while seedlings in the control pots inoculated with sterile sorghum seeds remained healthy. The pathogen was re-isolated from lesions and had identical morphology to the original isolates. To characterize the fungal identity, the internal transcribed spacer (ITS) was sequenced using the primers ITS1/ITS4 (Sharon et al., 2006). Using BLASTN in the NCBI database, the sequence (GenBank no. MW410857 and MW410858) showed 100% (639/639 bp) similarity to KF907734 and 99.83% (635/636 bp) similarity to AF354099, both belong to R. solani anastomosis group 7 (AG-7) (Hua et al. 2014; Gonzalez et al. 2001). Phylogenetic analysis comparing sequences with different AGs (Ajayi-Oyetunde and Bradely, 2017) grouped our isolates within the AG-7 clade with a 100% bootstrap confidence. In the anastomosis test, an incompatible zonation and unequal mycelial growth rates were observed when AG-7 isolates were paired with an AG-1 IA isolate. On the other hand, the compatible tuft reaction was observed when two AG-7 isolates were paired, and the compatible merge reaction was observed in the self-pairing tests (Macnish et al. 1997). Accordingly, the molecular and morphological characterizations confirmed the causal pathogen as R. solani AG-7. R. solani AG-7 was first reported on radishes in Japan (Homma et al., 1983), first found on carnation in Taiwan (Lo et al., 1990), and in field soils of various crops but not soybean (Chuang, 1997). It was suggested that Rhizoctonia diseases of soybean may be present in Taiwan, but molecular confirmation was lacking (Anonymus, 1979). As R. solani AG-7 causes diseases of soybean in the US and Japan (Baird et al., 1996), the importance of AG-7 as an endemic pathogen of soybean in Taiwan should be recognized and its prevalence determined as a first step to managing this disease.

First Report of Leaf Spot Caused by Diaporthe tulliensis on Boston Ivy (Parthenocissus tricuspidata) in Taiwan.

Starting from the May to August 2020 (average humidity 76.6% and temperature 25.2°C in Taipei), Boston ivy (Parthenocissus tricuspidata) plants on the campus of National Taiwan University (25°01'05.4"N 121°32'36.6"E) exhibited leaf rusts caused by Phakopsora ampelopsidis (Tzean et al., 2019) and leaf spots caused by an unknown pathogen. The leaf spots appeared reddish to brown color and mostly irregular to round shape on the simple and trifoliate leaflets (Supplemental Figure 1A-C). The leaf spots were surface-disinfected with 1% NaOCl for 30 seconds, and the margin of healthy and infected tissues was cut and placed onto water agar, which were incubated at room temperature. Hyphae grown out from leaf spots were sub-cultured on potato dextrose agar (PDA), and the majority of isolates exhibited white colony with black pycnidial conidiomata embedded in PDA. The pycnidial conidiomata of two-week-old has an average diameter of 463±193 µm (n=30) and the sizes of α-conidia were 5.71±0.49 µm in length and 2.42±0.32 µm in width (n=50) similar to the previous records (Crous et al. 2015). The α-conidium was one-celled, hyaline, and ovoid with two droplets (Supplemental Figure 1D-G). This putative pathogen was re-inoculated to confirm its pathogenicity on the leaves of Boston ivy plants. A PDA block with actively growing fungal edge was placed on the tiny needle-wounded leaves of detached branches (Supplemental Figure H-I) and the whole plants in pots (Supplemental Figure 1J-M) in a moist chamber at 28°C in dark. Reddish to brown leaf spots were observed by 2 days post-inoculation (dpi) and the leaf spots expanded by 5 dpi. To complete the Koch's postulates, the pathogen was re-isolated from inoculated leaves and the re-isolated pathogen exhibited identical morphology to the original isolate. The internal transcribed spacer (ITS), translational elongation factor subunit 1-α gene (EF1α), ß-tubulin (BT), and calmodulin (CAL) was amplified using the primers ITS1/ITS4 (Martin and Rygiewicz. 2005), EF1-728F/EF1-986R, Bt2a/Bt2b, and CAL-228F/CAL-737R, respectively (Manawasinghe et al. 2019). Using BLAST in the NCBI database, the ITS (MT974186), EF1α (MT982963), and ß-tubulin (MT982962) sequences showed 98.57% (NR_147574.1, 553 out of 561 bp), 98.04% (KR936133.1, 350 out of 357 bp), and 99.23% (KR936132.1, 518 out of 522 bp) identity to the Diaporthe tulliensis ex-type BRIP 62248a, respectively (Dissanayake et al. 2017). Phylogenetic analysis using concatenated sequences of ITS, EF1α, and ß-tubulin grouped the D. tulliensis isolated from Boston ivy leaf spots with the D. tulliensis ex-type (Supplemental Figure 1N). In summary, the morphological and molecular characterizations supported the causal pathogen of Boston ivy leaf spot as D. tulliensis. While Diaporthe ampelopsidis was reported to infect Parthenocissus quinquefolia and P. tricuspidata (Anonymous, 1960; Wehmeyer, 1933), there is no record for D. tulliensis infecting Boston ivy according to the USDA National Fungus Collections (Farr and Rossman. 2020). Because pathogens of Boston ivy such as P. ampelopsidis may also infect close-related crops like grape (Vitis vinifera L.) and D. tulliensis has been known to infect kiwifruits (Actinidia chinensis) and cocoa (Theobroma cacao) (Bai et al. 2016; Yang et al. 2018), the emergence of D. tulliensis should be aware to avoid potential damage to economic crops.

First Report of Corynespora cassiicola Causing Target Spot on Soybean in Taiwan.

Soybean (Glycine max [L.] Merr.) is an important crop in Taiwan. In October 2020, an unknown leaf spot disease was counted (n = 100) to occur over 70% of soybean cultivar 'Hualien No.1' in the Shoufeng Township of Hualien County, eastern Taiwan. Initial symptoms on leaves as tiny lesions approximately 3 mm in diameter, which later enlarged and developed into round, irregular, and reddish-brown spots with concentric rings surrounded by a yellowish halo. The symptoms appeared on both young and old leaves, but rarely on the stem or pods. The lesions at the margin of healthy and infected tissues were surface-disinfested in 1% NaOCl for 30 seconds, washed twice in sterilized distilled water, dissected and plated on potato dextrose agar (PDA) to isolate the potential pathogen. Colonies on PDA exhibited light to dark brown color at 24°C with 12-hours light after 7-days incubation. The average growth rate was 3 mm per day. Conidia were light brown in color and obclavate to cylindrical in shape. The size of a conidium was measured with an average of 110.8 ± 28.2 µm in length and 15.2 ± 2.8 µm in width, typically with 3 to 18 septa (n = 50). To confirm the pathogenicity of this fungus, conidial suspension (104 conidia/mL) of two isolates, HL_GM-6 and HL_GM-7, were sprayed on the healthy leaves of 4-weeks-old soybean. Plants sprayed with sterile distilled water were used as a control. After inoculation, the plants were covered with plastic bags to maintain a high humidity for 24 hours before moving into a greenhouse with a condition of 20 to 25°C and relative humidity of 75 to 80%. After 7 days of inoculation, foliar symptoms began to appear and which were identical with the field observations. To complete the Koch's postulates, pathogen isolation was attempted and the identical fungus was retrieved from the foliar spots of the inoculated leaves. The foliar symptoms as well as the morphology of the conidiophores and conidia suggested the pathogen to be Corynespora cassiicola (Ellis et al. 1971). Molecular characterization was performed using the sequences of internal transcribed spacer (ITS) region of rDNA, actin (act1), tubulin, and translation elongation factor 1 alpha (tef1) genes after a PCR with ITS1/ITS4 (White et al. 1990), ACT-512F/ACT-783R (Carbone and Kohn, 1999), BT2a/Bt2b (Udayanga et al. 2012), EF1-728F/EF1-986R (Udayanga et al. 2012), respectively. BLASTN sequence analyses of the ITS, act1, tubulin, and tef1 genomic regions of the isolate HL_GM-7 (GenBanK accessions MW548097 MW961420, MW961419 and MW961421) showed high similarity with the isolates of C. cassiicola including 99.58% with sequence KF810854 (Deon et al. 2014), 99.11% with FJ853005 (Dixon et al. 2009), 99.34% with MH763700 (Duan et al. 2019), and 99.33% with KY112719 (Zhang et al. 2018) respectively. Based on the morphology, pathogenicity, and sequence results, this study becomes the first report of C. cassiicola causing target spot on soybean in Taiwan. C. cassiicola is known to infect a broad host range (Dixon et al. 2009; Lopezet al. 2018), and it has been found to infect tomato, cucumber, papaya, and Salvia miltiorrhiza in Taiwan (Lu et al. 2019; Tsai et al. 2015). Therefore, the emergence of soybean target spot should be aware to avoid potential damage to soybean production in Taiwan.

Linkage Mapping for Foliar Necrosis of Soybean Sudden Death Syndrome.

Sudden death syndrome (SDS) foliar symptoms consist of foliar chlorosis, foliar necrosis, leaf marginal curling, and premature defoliation, but resistance screening has been evaluated mostly based on the overall SDS foliar severity rather than on a specific foliar symptom. This study generated an F2 population derived from crossing the susceptible variety Sloan and the resistant germplasm line PI 243518, which exhibits resistance to both foliar chlorosis and necrosis. A total of 400 F2 lines were evaluated for foliar chlorosis, foliar necrosis, and overall SDS foliar symptoms, separately. Genotyping-by-sequencing was applied to obtain single nucleotide polymorphisms (SNPs) in the F2 population, and linkage mapping using 135 F2 lines with 969 high-quality SNPs identified a locus on chromosome 13 for foliar necrosis and SDS foliar symptoms. The locus partially overlaps with loci previously reported for SDS on chromosome 13, which is the third time the region from 15.98 to 21.00 Mbp has been reproduced independently and therefore qualifies this locus for a new nomenclature proposed as Rfv13-02. In summary, this study generated a new biparental population that enables not only the discovery of a locus for foliar necrosis and SDS foliar symptoms on chromosome 13 but also the potential for advanced exploration of SDS foliar resistance derived from the germplasm line PI 243518.

Annotation resource of tandem repeat-containing secretory proteins in sixty fungi.

Fungal secretory proteins that interact with host plants are regarded as effectors. Because fungal effectors rarely contain conserved sequence features, identification and annotation of fungal effectors from predicted secretory proteins are difficult using outward comparison methods such as BLAST or hidden Markov model. In desire of more sequence features to prioritize research interests of fungal secretory proteins, this study developed a pipeline to identify tandem repeat (TR) domain within putative secretory proteins and tested a hypothesis that at least one type of TR domain in non-orthologous secretory proteins has emerged from convergent evolution for plant pathogenicity. There were 2804 types of TR domains and a total of 2925 TR-containing secretory proteins found from 60 fungi. There was no conserved type of TR domain shared only by plant pathogens, indicating functional divergence for different types of TR domain and TR-containing secretory proteins. The annotation resource of putative fungal TR-containing secretory proteins provides new sequence features that will be useful for the community interested in fungal effector biology.

Integration of sudden death syndrome resistance loci in the soybean genome.

KEY MESSAGE: Complexity and inconsistencies in resistance mapping publications of soybean sudden death syndrome (SDS) result in interpretation difficulty. This review integrates SDS mapping literature and proposes a new nomenclature system for reproducible SDS resistance loci. Soybean resistance to sudden death syndrome (SDS) is composed of foliar resistance to phytotoxins and root resistance to pathogen invasion. There are more than 80 quantitative trait loci (QTL) and dozens of single nucleotide polymorphisms (SNPs) associated with soybean resistance to SDS. The validity of these QTL and SNPs is questionable because of the complexity in phenotyping methodologies, the disease synergism between SDS and soybean cyst nematode (SCN), the variability from the interactions between soybean genotypes and environments, and the inconsistencies in the QTL nomenclature. This review organizes SDS mapping results and proposes the Rfv (resistance to Fusarium virguliforme) nomenclature based on supporting criteria described in the text. Among ten reproducible loci receiving our Rfv nomenclature, Rfv18-01 is mostly supported by field studies and it co-localizes to the SCN resistance locus rhg1. The possibility that Rfv18-01 is a pleiotropic resistance locus and the concern about Rfv18-01 being confounded with Rhg1 is discussed. On the other hand, Rfv06-01, Rfv06-02, Rfv09-01, Rfv13-01, and Rfv16-01 were identified both by screening soybean leaves against phytotoxic culture filtrates and by evaluating SDS severity in fields. Future phenotyping using leaf- and root-specific resistance screening methodologies may improve the precision of SDS resistance, and advanced genetic studies may further clarify the interactions among soybean genotypes, F. virguliforme, SCN, and environments. The review provides a summary of the SDS resistance literature and proposes a framework for communicating SDS resistance loci for future research considering molecular interactions and genetic breeding for soybean SDS resistance.

Identification of Multiple Phytotoxins Produced by Fusarium virguliforme Including a Phytotoxic Effector (FvNIS1) Associated With Sudden Death Syndrome Foliar Symptoms.

Sudden death syndrome (SDS) of soybean is caused by a soilborne pathogen, Fusarium virguliforme. Phytotoxins produced by F. virguliforme are translocated from infected roots to leaves, in which they cause SDS foliar symptoms. In this study, additional putative phytotoxins of F. virguliforme were identified, including three secondary metabolites and 11 effectors. While citrinin, fusaric acid, and radicicol induced foliar chlorosis and wilting, Soybean mosaic virus (SMV)-mediated overexpression of F. virguliforme necrosis-inducing secreted protein 1 (FvNIS1) induced SDS foliar symptoms that mimicked the development of foliar symptoms in the field. The expression level of fvnis1 remained steady over time, although foliar symptoms were delayed compared with the expression levels. SMV::FvNIS1 also displayed genotype-specific toxicity to which 75 of 80 soybean cultivars were susceptible. Genome-wide association mapping further identified three single nucleotide polymorphisms at two loci, where three leucine-rich repeat receptor-like protein kinase (LRR-RLK) genes were found. Culture filtrates of fvnis1 knockout mutants displayed a mild reduction in phytotoxicity, indicating that FvNIS1 is one of the phytotoxins responsible for SDS foliar symptoms and may contribute to the quantitative susceptibility of soybean by interacting with the LRR-RLK genes.

Genome-wide association and genomic prediction identifies associated loci and predicts the sensitivity of Tobacco ringspot virus in soybean plant introductions.

BACKGROUND: Genome-wide association study (GWAS) is a useful tool for detecting and characterizing traits of interest including those associated with disease resistance in soybean. The availability of 50,000 single nucleotide polymorphism (SNP) markers (SoySNP50K iSelect BeadChip; www.soybase.org ) on 19,652 soybean and wild soybean plant introductions (PIs) in the USDA Soybean Germplasm Collection allows for fast and robust identification of loci associated with a desired phenotype. By using a genome-wide marker set to predict phenotypic values, genomic prediction for phenotype-unknown but genotype-determined PIs has become possible. The goal of this study was to describe the genetic architecture associated with sensitivity to Tobacco ringspot virus (TRSV) infection in the USDA Soybean Germplasm Collection. RESULTS: TRSV-induced disease sensitivities of the 697 soybean PIs were rated on a one to five scale with plants rated as one exhibiting mild symptoms and plants rated as five displaying terminal bud necrosis (i.e., bud blight). The GWAS identified a single locus on soybean chromosome 2 strongly associated with TRSV sensitivity. Cross-validation showed a correlation of 0.55 (P < 0.01) to TRSV sensitivity without including the most significant SNP marker from the GWAS as a covariate, which was a better estimation compared to the mean separation by using significant SNPs. The genomic estimated breeding values for the remaining 18,955 unscreened soybean PIs in the USDA Soybean Germplasm Collection were obtained using the GAPIT R package. To evaluate the prediction accuracy, an additional 55 soybean accessions were evaluated for sensitivity to TRSV, which resulted in a correlation of 0.67 (P < 0.01) between actual and predicted severities. CONCLUSION: A single locus responsible for TRSV sensitivity in soybean was identified on chromosome 2. Two leucine-rich repeat receptor-like kinase genes were located near the locus and may control sensitivity of soybean to TRSV infection. Furthermore, a comprehensive genomic prediction for TRSV sensitivity for all accessions in the USDA Soybean Germplasm Collection was completed.

Genomic characterization of plant cell wall degrading enzymes and in silico analysis of xylanases and polygalacturonases of Fusarium virguliforme.

BACKGROUND: Plant cell wall degrading enzymes (PCWDEs) are a subset of carbohydrate-active enzymes (CAZy) produced by plant pathogens to degrade plant cell walls. To counteract PCWDEs, plants release PCWDEs inhibitor proteins (PIPs) to reduce their impact. Several transgenic plants expressing exogenous PIPs that interact with fungal glycoside hydrolase (GH)11-type xylanases or GH28-type polygalacturonase (PG) have been shown to enhance disease resistance. However, many plant pathogenic Fusarium species were reported to escape PIPs inhibition. Fusarium virguliforme is a soilborne pathogen that causes soybean sudden death syndrome (SDS). Although the genome of F. virguliforme was sequenced, there were limited studies focused on the PCWDEs of F. virguliforme. Our goal was to understand the genomic CAZy structure of F. viguliforme, and determine if exogenous PIPs could be theoretically used in soybean to enhance resistance against F. virguliforme. RESULTS: F. virguliforme produces diverse CAZy to degrade cellulose and pectin, similar to other necrotorphic and hemibiotrophic plant pathogenic fungi. However, some common CAZy of plant pathogenic fungi that catalyze hemicellulose, such as GH29, GH30, GH44, GH54, GH62, and GH67, were deficient in F. virguliforme. While the absence of these CAZy families might be complemented by other hemicellulases, F. virguliforme contained unique families including GH131, polysaccharide lyase (PL) 9, PL20, and PL22 that were not reported in other plant pathogenic fungi or oomycetes. Sequence analysis revealed two GH11 xylanases of F. virguliforme, FvXyn11A and FvXyn11B, have conserved residues that allow xylanase inhibitor protein I (XIP-I) binding. Structural modeling suggested that FvXyn11A and FvXyn11B could be blocked by XIP-I that serves as good candidate for developing transgenic soybeans. In contrast, one GH28 PG, FvPG2, contains an amino acid substitution that is potentially incompatible with the bean polygalacturonase-inhibitor protein II (PvPGIP2). CONCLUSIONS: Identification and annotation of CAZy provided advanced understanding of genomic composition of PCWDEs in F. virguliforme. Sequence and structural analyses of FvXyn11A and FvXyn11B suggested both xylanases were conserved in residues that allow XIP-I inhibition, and expression of both xylanases were detected during soybean roots infection. We postulate that a transgenic soybean expressing wheat XIP-I may be useful for developing root rot resistance to F. virguliforme.

Characterization of Disease Resistance Loci in the USDA Soybean Germplasm Collection Using Genome-Wide Association Studies.

Genetic resistance is a key strategy for disease management in soybean. Over the last 50 years, soybean germplasm has been phenotyped for resistance to many pathogens, resulting in the development of disease-resistant elite breeding lines and commercial cultivars. While biparental linkage mapping has been used to identify disease resistance loci, genome-wide association studies (GWAS) using high-density and high-quality markers such as single nucleotide polymorphisms (SNPs) has become a powerful tool to associate molecular markers and phenotypes. The objective of our study was to provide a comprehensive understanding of disease resistance in the United States Department of Agriculture Agricultural Research Service Soybean Germplasm Collection by using phenotypic data in the public Germplasm Resources Information Network and public SNP data (SoySNP50K). We identified SNPs significantly associated with disease ratings from one bacterial disease, five fungal diseases, two diseases caused by nematodes, and three viral diseases. We show that leucine-rich repeat (LRR) receptor-like kinases and nucleotide-binding site-LRR candidate resistance genes were enriched within the linkage disequilibrium regions of the significant SNPs. We review and present a global view of soybean resistance loci against multiple diseases and discuss the power and the challenges of using GWAS to discover disease resistance in soybean.

Melanin-independent accumulation of turgor pressure in appressoria of Phakopsora pachyrhizi.

Appressoria of some plant-pathogenic fungi accumulate turgor pressure that produces a mechanical force enabling the direct penetration of hyphae through the epidermis. Melanin functions as an impermeable barrier to osmolytes, which allows appressoria to accumulate high turgor pressure. Deficiency of melanin in appressoria reduces turgor pressure and compromises the infection process. In Phakopsora pachyrhizi, the soybean rust pathogen, the appressoria are hyaline. Our objective was to ensure the absence of a melanin layer specifically between the appressorial cell wall and plasma membrane, as well as to determine the turgor pressure of P. pachyrhizi appressoria. We demonstrated that two melanin biosynthesis inhibitors neither reduced turgor pressure nor compromised the infection process. Transmission electron microscopy also showed the absence of a melanin layer between the appressorial cell wall and plasma membrane. In addition, the turgor pressure of P. pachyrhizi appressoria was 5 to 6 MPa, based on extracellular osmolytes used to simulate different osmotic pressures. This is the first report showing that turgor pressure accumulation of P. pachyrhizi appressoria was independent of melanin.

Colonization compatibility with Bacillus altitudinis confers soybean seed rot resistance.

The plant microbiome and plant-associated bacteria are known to support plant health, but there are limited studies on seed and seedling microbiome to reveal how seed-associated bacteria may confer disease resistance. In this study, the application of antibiotics on soybean seedlings indicated that seed-associated bacteria were involved in the seed rot resistance against a soil-borne pathogen Calonectria ilicicola, but this resistance cannot be carried to withstand root rot. Using PacBio 16S rRNA gene full-length sequencing and microbiome analyses, 14 amplicon sequence variants (ASVs) including 2 ASVs matching to Bacillus altitudinis were found to be more abundant in the 4 most resistant varieties versus the 4 most susceptible varieties. Culture-dependent isolation obtained two B. altitudinis isolates that both exhibit antagonistic capability against 6 fungal pathogens. Application of B. altitudinis on the most resistant and susceptible soybean varieties revealed different colonization compatibility, and the seed rot resistance was restored in the 5 varieties showing higher bacterial colonization. Moreover, qPCR confirmed the persistence of B. altitudinis on apical shoots till 21 days post-inoculation (dpi), but 9 dpi on roots of the resistant variety TN5. As for the susceptible variety HC, the persistence of B. altitudinis was only detected before 6 dpi on both shoots and roots. The short-term colonization of B. altitudinis on roots may explain the absence of root rot resistance. Collectively, this study advances the insight of B. altitudinis conferring soybean seed rot resistance and highlights the importance of considering bacterial compatibility with plant varieties and colonization persistence on plant tissues.