Your search keyword '"Usovsky, M."' showing total 24 results

1. Identification of genomic loci conferring broad-spectrum resistance to multiple nematode species in exotic soybean accession PI 567305

Author

Vuong, T. D., Sonah, H., Patil, G., Meinhardt, C., Usovsky, M., Kim, K. S., Belzile, F., Li, Z., Robbins, R., Shannon, J. G., and Nguyen, H. T.

Published

2021

2. Registration of ‘S11‐17025C’ soybean: A high‐yielding and high‐oil conventional cultivar with broad resistance to diseases and nematodes

Author

Shannon, G., primary, Chen, P., additional, Lee, Y.‐C., additional, Vieira, C. C., additional, Nascimento, E. F., additional, Granja, M. O., additional, Lee, D., additional, Ali, M. L., additional, Scaboo, A., additional, Crisel, M., additional, Smothers, S., additional, Clubb, M., additional, Nguyen, H. T., additional, Li, Z., additional, Mitchum, M. G., additional, Bond, J., additional, Meinhardt, C., additional, Usovsky, M., additional, Robbins, R. T., additional, and Gillen, A. M., additional

Published

2023

3. Registration of ‘S16‐5503GT’ soybean cultivar with high yield, broad adaptation, and glyphosate tolerance

Author

Chen, P., primary, Ali, M. L., additional, Shannon, G., additional, Vieira, C. C., additional, Lee, Y.‐C., additional, Nascimento, E. F., additional, Granja, M. O., additional, Lee, D., additional, Crisel, M., additional, Smothers, S., additional, Clubb, M., additional, Selves, S., additional, Scaboo, A., additional, Usovsky, M., additional, Nguyen, H. T., additional, Li, Z., additional, Mitchum, M. G., additional, Averitt, B., additional, Bond, J., additional, Meinhardt, C., additional, Li, S., additional, Gillen, A. M., additional, Mengistu, A., additional, Robbins, R. T., additional, Mozzoni, L. A., additional, Zhang, B., additional, Smith, J. R., additional, and Moseley, D., additional

Published

2023

4. Registration of ‘S11‐16653C’ soybean: A high‐yielding conventional cultivar with broad resistance to diseases and nematodes

Author

Shannon, G., primary, Chen, P., additional, Lee, Y.‐C., additional, Canella Vieira, C., additional, Ali, M. L., additional, Lee, D., additional, Scaboo, A., additional, Crisel, M., additional, Smothers, S., additional, Clubb, M., additional, Nguyen, H. T., additional, Li, Z., additional, Mitchum, M. G., additional, Bond, J., additional, Meinhardt, C., additional, Usovsky, M., additional, and Robbins, R. T., additional

Published

2022

5. Registration of ‘S16‐14801C’: A high‐yielding determinate maturity group V soybean cultivar with multiple disease resistance, salt tolerance, and broad adaptation

Author

Chen, P., primary, Shannon, G., additional, Vieira, C. C., additional, Nascimento, E. F., additional, Ali, M. L., additional, Lee, D., additional, Scaboo, A., additional, Crisel, M., additional, Smothers, S., additional, Clubb, M., additional, Nguyen, H. T., additional, Li, Z., additional, Mitchum, M. G., additional, Bond, J., additional, Meinhardt, C., additional, Usovsky, M., additional, Li, S., additional, Mengistu, A., additional, Zhang, B., additional, Mozzoni, L., additional, Robbins, R. T., additional, and Moseley, D., additional

Published

2022

6. ‘S16‐14730C’: A high‐yielding conventional soybean cultivar with indeterminate growth habit and multiple disease resistance adapted to the Mid‐South

Author

Chen, P., primary, Shannon, G., additional, Scaboo, A., additional, Crisel, M., additional, Smothers, S., additional, Clubb, M., additional, Selves, S., additional, Vieira, C. C., additional, Ali, M. L., additional, Lee, D., additional, Lord, N., additional, Nguyen, H. T., additional, Li, Z., additional, Mitchum, M. G., additional, Bond, J., additional, Meinhardt, C., additional, Usovsky, M., additional, Li, S., additional, Mengistu, A., additional, Zhang, B., additional, Mozzoni, L., additional, and Robbins, R. T., additional

Published

2022

7. Registration of 'S11‐16653C' soybean: A high‐yielding conventional cultivar with broad resistance to diseases and nematodes.

Author

Shannon, G., Chen, P., Lee, Y.‐C., Canella Vieira, C., Ali, M. L., Lee, D., Scaboo, A., Crisel, M., Smothers, S., Clubb, M., Nguyen, H. T., Li, Z., Mitchum, M. G., Bond, J., Meinhardt, C., Usovsky, M., and Robbins, R. T.

Subjects

SOYBEAN cyst nematode, SOUTHERN root-knot nematode, SOYBEAN, NEMATODES, PHYTOPHTHORA sojae, ROOT rots, SUDDEN death

Abstract

The soybean [Glycine max (L.) Merr] line S11‐16653C (Reg. no. CV‐554, PI 700000) was developed and released as a cultivar by the University of Missouri, Fisher Delta Research, Extension, and Education Center (MU‐FDREEC). S11‐16653C is an early maturity group V (relative maturity 5.3), high‐yielding conventional (non‐genetically modified) cultivar with determinate growth habit. It is a chloride excluder and has a broad disease resistance package, including soybean cyst nematode (Heterodera glycines Ichinohe) races 1 (HG type 2.5.7), 2 (HG type 1.2.5.7), 3 (HG type 5.7), 5 (HG type 2.5.7), southern root‐knot nematode [Meloidogyne incognita (Kofold & White) Chitwood], peanut root‐knot nematode [Meloidogyne arenaria (Neal) Chitwood], reniform nematode (Rotylenchulus reniformis Linford & Oliveira), stem canker (Diaporthe aspalathi Jansen, Castlebury & Crous), Phytophthora root rot (caused by Phytophthora sojae M.J.Kaufmann & J.W.Gerdemann), and sudden death syndrome (Fusarium virguliforme O'Donell & T. Aoki). S11‐16653C was tested in 78 locations across nine states (Alabama, Arkansas, Kansas, Louisiana, Missouri, Mississippi, North Carolina, Tennessee, and Virginia) from 2012 to 2016. It was entered in internal yield tests at the MU‐FDREEC (2012–2014), USDA Uniform Soybean Tests (2014–2016), and soybean state variety tests (2015). It showed consistent high‐yielding performance and broad adaptability throughout the trials and locations. Overall, S11‐16653C is a high‐yielding conventional soybean cultivar that has potential for commercial production and serves as an exceptional germplasm for soybean breeding. Core Ideas: S11‐16653C is a high‐yielding conventional (non‐genetically modified) soybean cultivar.S11‐16653C has broad disease resistance.S11‐16653C is well adapted in the mid‐southern United States. [ABSTRACT FROM AUTHOR]

Published

2023

8. Registration of ‘S13‐3851C’ soybean as a high‐yielding conventional cultivar with high oil content and broad disease resistance and adaptation

Author

Chen, P., primary, Shannon, G., additional, Scaboo, A., additional, Crisel, M., additional, Smothers, S., additional, Clubb, M., additional, Selves, S., additional, Vieira, C. C., additional, Ali, M. L., additional, Lee, D., additional, Nguyen, H. T., additional, Li, Z., additional, Mitchum, M. G., additional, Bond, J., additional, Meinhardt, C., additional, Usovsky, M., additional, Li, S., additional, Mengistu, A., additional, and Robbins, R. T., additional

Published

2021

9. ‘S13‐1955C’: A high‐yielding conventional soybean with high oil content, multiple disease resistance, and broad adaptation

Author

Chen, P., primary, Shannon, G., additional, Scaboo, A., additional, Crisel, M., additional, Smothers, S., additional, Clubb, M., additional, Selves, S., additional, Vieira, C. C., additional, Ali, M. L., additional, Lee, D., additional, Nguyen, H. T., additional, Li, Z., additional, Mitchum, M. G., additional, Bond, J., additional, Meinhardt, C., additional, Usovsky, M., additional, Li, S., additional, Mengistu, A., additional, and Robbins, R. T., additional

Published

2021

10. Registration of ‘S14‐9017GT’ soybean cultivar with high yield, resistance to multiple diseases, and high seed oil content

Author

Chen, P., primary, Shannon, G., additional, Ali, M. L., additional, Scaboo, A., additional, Crisel, M., additional, Smothers, S., additional, Clubb, M., additional, Selves, S., additional, Vieira, C. C., additional, Mitchum, M. G., additional, Nguyen, H. T., additional, Li, Z., additional, Bond, J., additional, Meinhardt, C., additional, Usovsky, M., additional, Li, S., additional, Mengistu, A., additional, and Robbins, R. T., additional

Published

2020

11. Registration of ‘S14‐15138GT’ soybean as a high‐yielding RR1/STS cultivar with broad disease resistance and adaptation

Author

Chen, P., primary, Shannon, G., additional, Crisel, M., additional, Smothers, S., additional, Clubb, M., additional, Vieira, C. C., additional, Ali, M. L., additional, Selves, S., additional, Lee, D. H., additional, Scaboo, A., additional, Usovsky, M., additional, Nguyen, H. T., additional, Mitchum, M. G., additional, Meinhardt, C., additional, Li, Z., additional, Bond, J., additional, Robbins, R. T., additional, Li, S., additional, Smith, J. R., additional, and Mengistu, A., additional

Published

2020

12. Registration of 'S13‐3851C' soybean as a high‐yielding conventional cultivar with high oil content and broad disease resistance and adaptation.

Author

Chen, P., Shannon, G., Scaboo, A., Crisel, M., Smothers, S., Clubb, M., Selves, S., Vieira, C. C., Ali, M. L., Lee, D., Nguyen, H. T., Li, Z., Mitchum, M. G., Bond, J., Meinhardt, C., Usovsky, M., Li, S., Mengistu, A., and Robbins, R. T.

Subjects

SOYBEAN farming, CULTIVARS, DISEASE resistance of plants, PLANT adaptation, PLANT breeding

Abstract

'S13‐3851C' (Reg. no. CV‐541, PI 698653) is an early maturity group IV (relative maturity 4.4) conventional soybean [Glycine max (L.) Merr.] cultivar released by the University of Missouri–Fisher Delta Research Center Soybean Breeding Program. It was developed from a conventional breeding scheme focusing on parental traits including high oil content, multiple disease resistance, and high yielding potential. S13‐3851C has purple flowers, light tawny pubescence, tan pod wall, and indeterminate growth habit. Seeds of S13‐3851C have a black hilum and intermediate seed luster, with 230.8 g kg−1 of oil and 404.1 g kg−1 of protein content on a dry‐weight basis. S13‐3851C is resistant to stem canker, sudden death syndrome, charcoal rot, and Phytophthora root rot. S13‐3851C showed high yield potential and broad adaptability in 113 environments across 12 states, yielding 102% of the check average and 103% of the test average in Missouri and other southern states during the testing period (2014–2018). Core Ideas: Early maturity group provides flexibility for growers in the southern United States.'S13‐3851C' is a non‐GMO cultivar for premium incentives and specialty markets.High‐oil cultivar supports the ever‐growing demand for vegetable oil.Multiple disease resistances creates yield security across diverse yield‐limiting factors.Yield potential was determined by high performance and stability across 113 environments. [ABSTRACT FROM AUTHOR]

Published

2022

13. Genome scans for selection signatures identify candidate virulence genes for adaptation of the soybean cyst nematode to host resistance.

Author

Kwon KM, Viana JPG, Walden KKO, Usovsky M, Scaboo AM, Hudson ME, and Mitchum MG

Subjects

Animals, Virulence genetics, Selection, Genetic, Genetics, Population, Whole Genome Sequencing, Glycine max genetics, Glycine max parasitology, Polymorphism, Single Nucleotide genetics, Plant Diseases parasitology, Plant Diseases genetics, Disease Resistance genetics, Tylenchoidea genetics, Tylenchoidea pathogenicity

Abstract

Plant pathogens are constantly under selection pressure for host resistance adaptation. Soybean cyst nematode (SCN, Heterodera glycines) is a major pest of soybean primarily managed through resistant cultivars; however, SCN populations have evolved virulence in response to selection pressures driven by repeated monoculture of the same genetic resistance. Resistance to SCN is mediated by multiple epistatic interactions between Rhg (for resistance to H. glycines) genes. However, the identity of SCN virulence genes that confer the ability to overcome resistance remains unknown. To identify candidate genomic regions showing signatures of selection for increased virulence, we conducted whole genome resequencing of pooled individuals (Pool-Seq) from two pairs of SCN populations adapted on soybeans with Peking-type (rhg1-a, rhg2, and Rhg4) resistance. Population differentiation and principal component analysis-based approaches identified approximately 0.72-0.79 million SNPs, the frequency of which showed potential selection signatures across multiple genomic regions. Chromosomes 3 and 6 between population pairs showed the greatest density of outlier SNPs with high population differentiation. Conducting multiple outlier detection tests to identify overlapping SNPs resulted in a total of 966 significantly differentiated SNPs, of which 285 exon SNPs were mapped to 97 genes. Of these, six genes encoded members of known stylet-secreted effector protein families potentially involved in host defence modulation including venom-allergen-like, annexin, glutathione synthetase, SPRYSEC, chitinase, and CLE effector proteins. Further functional analysis of identified candidate genes will provide new insights into the genetic mechanisms by which SCN overcomes soybean resistance and inform the development of molecular markers for rapidly screening the virulence profile of an SCN-infested field., (© 2024 The Author(s). Molecular Ecology published by John Wiley & Sons Ltd.)

Published

2024

14. Loss-of-function of an α-SNAP gene confers resistance to soybean cyst nematode.

Author

Usovsky M, Gamage VA, Meinhardt CG, Dietz N, Triller M, Basnet P, Gillman JD, Bilyeu KD, Song Q, Dhital B, Nguyen A, Mitchum MG, and Scaboo AM

Subjects

Animals, Soluble N-Ethylmaleimide-Sensitive Factor Attachment Proteins genetics, Genes, Plant, Sequence Analysis, DNA, Plant Diseases genetics, Plant Diseases parasitology, Disease Resistance genetics, Glycine max genetics, Glycine max parasitology, Nematoda genetics

Abstract

Plant-parasitic nematodes are one of the most economically impactful pests in agriculture resulting in billions of dollars in realized annual losses worldwide. Soybean cyst nematode (SCN) is the number one biotic constraint on soybean production making it a priority for the discovery, validation and functional characterization of native plant resistance genes and genetic modes of action that can be deployed to improve soybean yield across the globe. Here, we present the discovery and functional characterization of a soybean resistance gene, GmSNAP02. We use unique bi-parental populations to fine-map the precise genomic location, and a combination of whole genome resequencing and gene fragment PCR amplifications to identify and confirm causal haplotypes. Lastly, we validate our candidate gene using CRISPR-Cas9 genome editing and observe a gain of resistance in edited plants. This demonstrates that the GmSNAP02 gene confers a unique mode of resistance to SCN through loss-of-function mutations that implicate GmSNAP02 as a nematode virulence target. We highlight the immediate impact of utilizing GmSNAP02 as a genome-editing-amenable target to diversify nematode resistance in commercially available cultivars., (© 2023. The Author(s).)

Published

2023

15. Cataloging SCN resistance loci in North American public soybean breeding programs.

Author

Mahmood A, Bilyeu KD, Škrabišová M, Biová J, De Meyer EJ, Meinhardt CG, Usovsky M, Song Q, Lorenz AJ, Mitchum MG, Shannon G, and Scaboo AM

Abstract

Soybean cyst nematode (SCN) is a destructive pathogen of soybeans responsible for annual yield loss exceeding $1.5 billion in the United States. Here, we conducted a series of genome-wide association studies (GWASs) to understand the genetic landscape of SCN resistance in the University of Missouri soybean breeding programs (Missouri panel), as well as germplasm and cultivars within the United States Department of Agriculture (USDA) Uniform Soybean Tests-Northern Region (NUST). For the Missouri panel, we evaluated the resistance of breeding lines to SCN populations HG 2.5.7 (Race 1), HG 1.2.5.7 (Race 2), HG 0 (Race 3), HG 2.5.7 (Race 5), and HG 1.3.6.7 (Race 14) and identified seven quantitative trait nucleotides (QTNs) associated with SCN resistance on chromosomes 2, 8, 11, 14, 17, and 18. Additionally, we evaluated breeding lines in the NUST panel for resistance to SCN populations HG 2.5.7 (Race 1) and HG 0 (Race 3), and we found three SCN resistance-associated QTNs on chromosomes 7 and 18. Through these analyses, we were able to decipher the impact of seven major genetic loci, including three novel loci, on resistance to several SCN populations and identified candidate genes within each locus. Further, we identified favorable allelic combinations for resistance to individual SCN HG types and provided a list of available germplasm for integration of these unique alleles into soybean breeding programs. Overall, this study offers valuable insight into the landscape of SCN resistance loci in U.S. public soybean breeding programs and provides a framework to develop new and improved soybean cultivars with diverse plant genetic modes of SCN resistance., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Mahmood, Bilyeu, Škrabišová, Biová, De Meyer, Meinhardt, Usovsky, Song, Lorenz, Mitchum, Shannon and Scaboo.)

Published

2023

16. Linkage analysis and residual heterozygotes derived near isogenic lines reveals a novel protein quantitative trait loci from a Glycine soja accession.

Author

Yang Y, La TC, Gillman JD, Lyu Z, Joshi T, Usovsky M, Song Q, and Scaboo A

Abstract

Modern soybean [ Glycine max (L.) Merr ] cultivars have low overall genetic variation due to repeated bottleneck events that arose during domestication and from selection strategies typical of many soybean breeding programs. In both public and private soybean breeding programs, the introgression of wild soybean ( Glycine soja Siebold and Zucc. ) alleles is a viable option to increase genetic diversity and identify new sources for traits of value. The objectives of our study were to examine the genetic architecture responsible for seed protein and oil using a recombinant inbred line (RIL) population derived from hybridizing a G. max line ('Osage') with a G. soja accession (PI 593983). Linkage mapping identified a total of seven significant quantitative trait loci on chromosomes 14 and 20 for seed protein and on chromosome 8 for seed oil with LOD scores ranging from 5.3 to 31.7 for seed protein content and from 9.8 to 25.9 for seed oil content. We analyzed 3,015 single F 4:9 soybean plants to develop two residual heterozygotes derived near isogenic lines (RHD-NIL) populations by targeting nine SNP markers from genotype-by-sequencing, which corresponded to two novel quantitative trait loci (QTL) derived from G. soja : one for a novel seed oil QTL on chromosome 8 and another for a novel protein QTL on chromosome 14. Single marker analysis and linkage analysis using 50 RHD-NILs validated the chromosome 14 protein QTL, and whole genome sequencing of RHD-NILs allowed us to reduce the QTL interval from ∼16.5 to ∼4.6 Mbp. We identified two genomic regions based on recombination events which had significant increases of 0.65 and 0.72% in seed protein content without a significant decrease in seed oil content. A new Kompetitive allele-specific polymerase chain reaction (KASP) assay, which will be useful for introgression of this trait into modern elite G. max cultivars, was developed in one region. Within the significantly associated genomic regions, a total of eight genes are considered as candidate genes, based on the presence of gene annotations associated with the protein or amino acid metabolism/movement. Our results provide better insights into utilizing wild soybean as a source of genetic diversity for soybean cultivar improvement utilizing native traits., Competing Interests: YY was employed by the company Benson Hill. Mention of any trademark, vendor, or proprietary product does not constitute a guarantee or warranty of the product by the USDA and does not imply its approval to the exclusion of other products or vendor that may also be suitable. USDA is an equal opportunity provider and employer. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Yang, La, Gillman, Lyu, Joshi, Usovsky, Song and Scaboo.)

Published

2022

17. Epistatic interaction between Rhg1-a and Rhg2 in PI 90763 confers resistance to virulent soybean cyst nematode populations.

Author

Basnet P, Meinhardt CG, Usovsky M, Gillman JD, Joshi T, Song Q, Diers B, Mitchum MG, and Scaboo AM

Subjects

Animals, Disease Resistance genetics, Plant Breeding, Plant Diseases genetics, Glycine max genetics, Cysts, Tylenchoidea

Abstract

Key Message: An epistatic interaction between SCN resistance loci rhg1-a and rhg2 in PI 90763 imparts resistance against virulent SCN populations which can be employed to diversify SCN resistance in soybean cultivars. With more than 95% of the $46.1B soybean market dominated by a single type of genetic resistance, breeding for soybean cyst nematode (SCN)-resistant soybean that can effectively combat the widespread increase in virulent SCN populations presents a significant challenge. Rhg genes (for Resistance to Heterodera glycines) play a key role in resistance to SCN; however, their deployment beyond the use of the rhg1-b allele has been limited. In this study, quantitative trait loci (QTL) were mapped using PI 90763 through two biparental F 3:4 recombinant inbred line (RIL) populations segregating for rhg1-a and rhg1-b alleles against a SCN HG type 1.2.5.7 (Race 2) population. QTL located on chromosome 18 (rhg1-a) and chromosome 11 (rhg2) were determined to confer SCN resistance in PI 90763. The rhg2 gene was fine-mapped to a 169-Kbp region pinpointing GmSNAP11 as the strongest candidate gene. We demonstrated a unique epistatic interaction between rhg1-a and rhg2 loci that not only confers resistance to multiple virulent SCN populations. Further, we showed that pyramiding rhg2 with the conventional mode of resistance, rhg1-b, is ineffective against these virulent SCN populations. This highlights the importance of pyramiding rhg1-a and rhg2 to maximize the impact of gene pyramiding strategies toward management of SCN populations virulent on rhg1-b sources of resistance. Our results lay the foundation for the next generation of soybean resistance breeding to combat the number one pathogen of soybean., (© 2022. The Author(s).)

Published

2022

18. Decades of Genetic Research on Soybean mosaic virus Resistance in Soybean.

Author

Usovsky M, Chen P, Li D, Wang A, Shi A, Zheng C, Shakiba E, Lee D, Canella Vieira C, Lee YC, Wu C, Cervantez I, and Dong D

Subjects

Genes, Plant, Genetic Research, Plant Breeding, Plant Diseases genetics, Potyvirus genetics, Glycine max genetics

Abstract

This review summarizes the history and current state of the known genetic basis for soybean resistance to Soybean mosaic virus (SMV), and examines how the integration of molecular markers has been utilized in breeding for crop improvement. SVM causes yield loss and seed quality reduction in soybean based on the SMV strain and the host genotype. Understanding the molecular underpinnings of SMV-soybean interactions and the genes conferring resistance to SMV has been a focus of intense research interest for decades. Soybean reactions are classified into three main responses: resistant, necrotic, or susceptible. Significant progress has been achieved that has greatly increased the understanding of soybean germplasm diversity, differential reactions to SMV strains, genotype-strain interactions, genes/alleles conferring specific reactions, and interactions among resistance genes and alleles. Many studies that aimed to uncover the physical position of resistance genes have been published in recent decades, collectively proposing different candidate genes. The studies on SMV resistance loci revealed that the resistance genes are mainly distributed on three chromosomes. Resistance has been pyramided in various combinations for durable resistance to SMV strains. The causative genes are still elusive despite early successes in identifying resistance alleles in soybean; however, a gene at the Rsv4 locus has been well validated.

Published

2022

19. Exploring Machine Learning Algorithms to Unveil Genomic Regions Associated With Resistance to Southern Root-Knot Nematode in Soybeans.

Author

Canella Vieira C, Zhou J, Usovsky M, Vuong T, Howland AD, Lee D, Li Z, Zhou J, Shannon G, Nguyen HT, and Chen P

Abstract

Southern root-knot nematode [SRKN, Meloidogyne incognita (Kofold & White) Chitwood] is a plant-parasitic nematode challenging to control due to its short life cycle, a wide range of hosts, and limited management options, of which genetic resistance is the main option to efficiently control the damage caused by SRKN. To date, a major quantitative trait locus (QTL) mapped on chromosome (Chr.) 10 plays an essential role in resistance to SRKN in soybean varieties. The confidence of discovered trait-loci associations by traditional methods is often limited by the assumptions of individual single nucleotide polymorphisms (SNPs) always acting independently as well as the phenotype following a Gaussian distribution. Therefore, the objective of this study was to conduct machine learning (ML)-based genome-wide association studies (GWAS) utilizing Random Forest (RF) and Support Vector Machine (SVM) algorithms to unveil novel regions of the soybean genome associated with resistance to SRKN. A total of 717 breeding lines derived from 330 unique bi-parental populations were genotyped with the Illumina Infinium BARCSoySNP6K BeadChip and phenotyped for SRKN resistance in a greenhouse. A GWAS pipeline involving a supervised feature dimension reduction based on Variable Importance in Projection (VIP) and SNP detection based on classification accuracy was proposed. Minor effect SNPs were detected by the proposed ML-GWAS methodology but not identified using Bayesian-information and linkage-disequilibrium Iteratively Nested Keyway (BLINK), Fixed and Random Model Circulating Probability Unification (FarmCPU), and Enriched Compressed Mixed Linear Model (ECMLM) models. Besides the genomic region on Chr. 10 that can explain most of SRKN resistance variance, additional minor effects SNPs were also identified on Chrs. 10 and 11. The findings in this study demonstrated that overfitting in GWAS may lead to lower prediction accuracy, and the detection of significant SNPs based on classification accuracy limited false-positive associations. The expansion of the basis of the genetic resistance to SRKN can potentially reduce the selection pressure over the major QTL on Chr. 10 and achieve higher levels of resistance., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Canella Vieira, Zhou, Usovsky, Vuong, Howland, Lee, Li, Zhou, Shannon, Nguyen and Chen.)

Published

2022

20. Classification Methods and Identification of Reniform Nematode Resistance in Known Soybean Cyst Nematode-Resistant Soybean Genotypes.

Author

Usovsky M, Robbins RT, Fultz Wilkes J, Crippen D, Shankar V, Vuong TD, Agudelo P, and Nguyen HT

Subjects

Animals, Genotype, Plant Diseases parasitology, Glycine max genetics, Glycine max parasitology, Cysts, Tylenchoidea genetics

Abstract

Plant parasitic nematodes are a major yield-limiting factor of soybean in the United States and Canada. It has been indicated that soybean cyst nematode (SCN; Heterodera glycines Ichinohe) and reniform nematode (RN; Rotylenchulus reniformis Linford and Oliveira) resistance could be genetically related. For many years, fragmentary data have shown this relationship. This report evaluates RN reproduction on 418 plant introductions (PIs) selected from the U.S. Department of Agriculture Soybean Germplasm Collection with reported SCN resistance. The germplasm was divided into two tests of 214 PIs reported as resistant and 204 PIs reported as moderately resistant to SCN. The defining and reporting of RN resistance changed several times in the last 30 years, causing inconsistencies in RN resistance classification among multiple experiments. Comparison of four RN resistance classification methods was performed: (i) ≤10% as compared with the susceptible check, (ii) using normalized reproduction index (RI) values, and using (iii) transformed data log 10 (x), and (iv) transformed data log 10 (x + 1) in an optimal univariate k-means clustering analysis. The method of transformed data log 10 (x) was selected as the most accurate for classification of RN resistance. Among 418 PIs with reported SCN resistance, the log 10 (x) method grouped 59 PIs (15%) as resistant and 130 PIs (31%) as moderately resistant to RN. Genotyping of a subset of the most resistant PIs to both nematode species revealed their strong correlation with rhg1-a allele. This research identified genotypes with resistance to two nematode species and potential new sources of RN resistance that could be valuable to breeders in developing resistant cultivars.

Published

2022

21. The Soybean High Density 'Forrest' by 'Williams 82' SNP-Based Genetic Linkage Map Identifies QTL and Candidate Genes for Seed Isoflavone Content.

Author

Knizia D, Yuan J, Bellaloui N, Vuong T, Usovsky M, Song Q, Betts F, Register T, Williams E, Lakhssassi N, Mazouz H, Nguyen HT, Meksem K, Mengistu A, and Kassem MA

Abstract

Isoflavones are secondary metabolites that are abundant in soybean and other legume seeds providing health and nutrition benefits for both humans and animals. The objectives of this study were to construct a single nucleotide polymorphism (SNP)-based genetic linkage map using the 'Forrest' by 'Williams 82' (F×W82) recombinant inbred line (RIL) population ( n = 306); map quantitative trait loci (QTL) for seed daidzein, genistein, glycitein, and total isoflavone contents in two environments over two years (NC-2018 and IL-2020); identify candidate genes for seed isoflavone. The FXW82 SNP-based map was composed of 2075 SNPs and covered 4029.9 cM. A total of 27 QTL that control various seed isoflavone traits have been identified and mapped on chromosomes (Chrs.) 2, 4, 5, 6, 10, 12, 15, 19, and 20 in both NC-2018 (13 QTL) and IL-2020 (14 QTL). The six QTL regions on Chrs. 2, 4, 5, 12, 15, and 19 are novel regions while the other 21 QTL have been identified by other studies using different biparental mapping populations or genome-wide association studies (GWAS). A total of 130 candidate genes involved in isoflavone biosynthetic pathways have been identified on all 20 Chrs. And among them 16 have been identified and located within or close to the QTL identified in this study. Moreover, transcripts from four genes ( Glyma.10G058200 , Glyma.06G143000 , Glyma.06G137100 , and Glyma.06G137300 ) were highly abundant in Forrest and Williams 82 seeds. The identified QTL and four candidate genes will be useful in breeding programs to develop soybean cultivars with high beneficial isoflavone contents.

Published

2021

22. Dissecting nematode resistance regions in soybean revealed pleiotropic effect of soybean cyst and reniform nematode resistance genes.

Author

Usovsky M, Lakhssassi N, Patil GB, Vuong TD, Piya S, Hewezi T, Robbins RT, Stupar RM, Meksem K, and Nguyen HT

Subjects

Animals, DNA Copy Number Variations, Disease Resistance genetics, Plant Diseases genetics, Glycine max genetics, Cysts, Tylenchoidea

Abstract

Reniform nematode (RN, Rotylenchulus reniformis Linford & Oliveira) has emerged as one of the most important plant parasitic nematodes of soybean [Glycine max (L.) Merr.]. Planting resistant varieties is the most effective strategy for nematode management. The objective of this study was to identify quantitative trait loci (QTL) for RN resistance in an exotic soybean line, PI 438489B, using two linkage maps constructed from the Universal Soybean Linkage Panel (USLP 1.0) and next-generation whole-genome resequencing (WGRS) technology. Two QTL controlling RN resistance were identified-the soybean cyst nematode (SCN, Heterodera glycines) resistance gene GmSNAP18 at the rhg1 locus and its paralog GmSNAP11. Strong association between resistant phenotype and haplotypes of the GmSNAP11 and GmSNAP18 was observed. The results indicated that GmSNAP11 possibly could have epistatic effect on GmSNAP18, or vice versa, with the presence of a significant correlation in RN resistance of rhg1-a GmSNAP18 vs. rhg1-b GmSNAP18. Most importantly, our preliminary data suggested that GmSNAP18 and GmSNAP11 proteins physically interact in planta, suggesting that they belong to the same pathway for resistance. Unlike GmSNAP18, no indication of GmSNAP11 copy number variation was found. Moreover, gene-based single nucleotide polymorphism (SNP) markers were developed for rapid detection of RN or SCN resistance at these loci. Our analysis substantiates synergic interaction between GmSNAP11 and GmSNAP18 genes and confirms their roles in RN as well as SCN resistance. These results could contribute to a better understanding of evolution and subfunctionalization of genes conferring resistance to multiple nematode species and provide a framework for further investigations., (© 2021 The Authors. The Plant Genome published by Wiley Periodicals LLC on behalf of Crop Science Society of America.)

Published

2021

23. Genetic characterization of qSCN10 from an exotic soybean accession PI 567516C reveals a novel source conferring broad-spectrum resistance to soybean cyst nematode.

Author

Zhou L, Song L, Lian Y, Ye H, Usovsky M, Wan J, Vuong TD, and Nguyen HT

Subjects

Animals, Chromosome Mapping methods, Chromosomes, Plant genetics, Disease Resistance immunology, Genetic Linkage, Phylogeny, Plant Diseases parasitology, Glycine max immunology, Glycine max parasitology, Disease Resistance genetics, Genetic Markers, Plant Breeding, Plant Diseases genetics, Quantitative Trait Loci, Glycine max genetics, Tylenchoidea physiology

Abstract

Key Message: The qSCN10 locus with broad-spectrum SCN resistance was fine-mapped to a 379-kb region on chromosome 10 in soybean accession PI 567516C. Candidate genes and potential application benefits of this locus were discussed. Soybean cyst nematode (SCN, Heterodera glycines Ichinohe) is one of the most devastating pests of soybean, causing significant yield losses worldwide every year. Genetic resistance has been the major strategy to control this pest. However, the overuse of the same genetic resistance derived primarily from PI 88788 has led to the genetic shifts in nematode populations and resulted in the reduced effectiveness in soybean resistance to SCN. Therefore, novel genetic resistance resources, especially those with broad-spectrum resistance, are needed to develop new resistant cultivars to cope with the genetic shifts in nematode populations. In this study, a quantitative trait locus (QTL) qSCN10 previously identified from a soybean landrace PI 567516C was confirmed to confer resistance to multiple SCN HG Types. This QTL was further fine-mapped to a 379-kb region. There are 51 genes in this region. Four of them are defense-related and were regulated by SCN infection, suggesting their potential role in mediating resistance to SCN. The phylogenetic and haplotype analyses of qSCN10 as well as other information indicate that this locus is different from other reported resistance QTL or genes. There was no yield drag or other unfavorable traits associated with this QTL when near-isogenic lines with and without qSCN10 were tested in a SCN-free field. Therefore, our study not only provides further insight into the genetic basis of soybean resistance to SCN, but also identifies a novel genetic resistance resource for breeding soybean for durable, broad-spectrum resistance to this pest.

Published

2021

24. Fine-mapping and characterization of qSCN18, a novel QTL controlling soybean cyst nematode resistance in PI 567516C.

Author

Usovsky M, Ye H, Vuong TD, Patil GB, Wan J, Zhou L, and Nguyen HT

Subjects

Animals, Chromosome Mapping, Disease Resistance immunology, Gene Expression Regulation, Plant, Phenotype, Plant Diseases immunology, Plant Diseases parasitology, Plant Proteins genetics, Polymorphism, Genetic, Glycine max parasitology, Chromosomes, Plant genetics, Disease Resistance genetics, Plant Diseases genetics, Plant Proteins metabolism, Quantitative Trait Loci, Glycine max genetics, Tylenchoidea physiology

Abstract

Key Message: The qSCN18 QTL from PI 56756C was confirmed and fine-mapped to improve soybean resistance to the SCN population HG Type 2.5.7 using near-isogenic lines carrying recombination crossovers within the QTL region. The QTL underlying resistance was fine-mapped to a 166-Kbp region on chromosome 18, and the candidate genes were selected based on genomic analyses. Soybean cyst nematode (SCN, Heterodera glycines, Ichinohe) is the most devastating pathogen of soybean. Understanding the genetic basis of SCN resistance is crucial for managing this parasite in the field. Two major loci, rhg1 and Rhg4, were previously characterized as valuable resources for SCN resistance. However, their continuous use has caused shifts in the virulence of SCN populations, which can overcome the resistance conferred by these two major loci. Reduced effectiveness became a major concern in the soybean industry due to continuous use of rhg1 for decades. Thus, it is imperative to identify sources of SCN resistance for durable SCN management. A novel QTL qSCN18 was identified in PI567516C. To fine-map qSCN18 and identify resistance genes, a large backcross population was developed. Nineteen near-isogenic lines (NILs) carrying recombination crossovers within the QTL region were identified. The first phase of fine-mapping narrowed the QTL region to 549-Kbp, whereas the second phase confined the region to 166-Kbp containing 23 genes. Two flanking markers, MK-1 and MK-6, were developed and validated to detect the presence of the qSCN18 resistance allele. Haplotype analysis clustered the fine-mapped qSCN18 region from PI 567516C with the cqSCN-007 locus previously mapped in the wild soybean accession PI 468916. The NILs were developed to further characterize the causal gene(s) harbored in this QTL. This study also confirmed the previously identified qSCN18. The results will facilitate marker-assisted selection (MAS) introducing the qSCN18 locus from PI 567516C into high-yielding soybean cultivars with durable resistance to SCN.

Published

2021