Resistance Gene Pyramiding and Rotation to Combat Widespread Soybean Cyst Nematode Virulence

Meinhardt, Clinton G.; Howland, Amanda D.; Ellersieck, Mark R.; Scaboo, Andrew; Diers, Brian W.; Mitchum, Melissa G.

doi:10.1094/pdis-12-20-2556-re

Cited by 14 publications

(18 citation statements)

References 27 publications

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“…Thus, the results highlight that a pyramid of the rhg1-a allele with rhg2 offers an advantage against the virulent SCN populations tested. Since rhg1-b is the most widely used resistance allele in more than 95% of resistant soybean cultivars planted in the USA, current efforts have focused on pyramiding of rhg1-b with other resistance loci to enhance resistance to virulent SCN (Brzostowski and Diers 2017 ; Yu and Diers 2017 ; Meinhardt et al 2021 ). Here, we demonstrated that a combination of rhg1-a and rhg2 genes provides resistance against virulent nematode populations and resistance allele pyramid focused on these genes would be an effective strategy for the management of virulent SCN populations.…”

Section: Resultsmentioning

confidence: 99%

“…PI 88788 has been excessively utilized as a resistance source in modern SCN-resistant soybean cultivars due to resistance being derived from a single rhg1-b allele which allows for convenient breeding by introgression of a single resistance locus (Concibido et al 2004 ; Niblack, 2005 ; Mitchum 2016 ; McCarville et al 2017 ). Consequently, the monoculture of PI 88788-resistant soybean cultivars has facilitated the selection of virulent nematode populations that are capable of overcoming this resistance (Niblack et al 2008 ; McCarville et al 2017 ; Howland et al 2018 ; Meinhardt et al 2021 ). A crucial step to a successful SCN management strategy is the use of resistance sources capable of limiting the selection of virulent nematode populations which has often been undermined while breeding for high-yielding SCN-resistant cultivars (Niblack 2005 ; Chen 2020 ; Meinhardt et al 2021 ).…”

Section: Introductionmentioning

confidence: 99%

“…Consequently, the monoculture of PI 88788-resistant soybean cultivars has facilitated the selection of virulent nematode populations that are capable of overcoming this resistance (Niblack et al 2008 ; McCarville et al 2017 ; Howland et al 2018 ; Meinhardt et al 2021 ). A crucial step to a successful SCN management strategy is the use of resistance sources capable of limiting the selection of virulent nematode populations which has often been undermined while breeding for high-yielding SCN-resistant cultivars (Niblack 2005 ; Chen 2020 ; Meinhardt et al 2021 ). Due to the limited understanding of SCN virulence genes referred to as ror genes (for the r eproduction o n a r esistant host), a strategic rotation of SCN resistance sources that can counter-select nematode populations is a potential solution for combating SCN (Gardner et al 2017 ; Meinhardt et al 2021 ).…”

Section: Introductionmentioning

confidence: 99%

“…A crucial step to a successful SCN management strategy is the use of resistance sources capable of limiting the selection of virulent nematode populations which has often been undermined while breeding for high-yielding SCN-resistant cultivars (Niblack 2005 ; Chen 2020 ; Meinhardt et al 2021 ). Due to the limited understanding of SCN virulence genes referred to as ror genes (for the r eproduction o n a r esistant host), a strategic rotation of SCN resistance sources that can counter-select nematode populations is a potential solution for combating SCN (Gardner et al 2017 ; Meinhardt et al 2021 ). Counter-selection studies using different virulent nematode populations on PI 88788, PI 90763, and Peking have contributed to insights on the potential use of these sources in rotation to limit virulent SCN population build-up (Luedders and Dropkin 1983 ; Anand and Shumway 1985 ; Gardner et al 2017 ; Meinhardt et al 2021 ).…”

Section: Introductionmentioning

confidence: 99%

“…Due to the limited understanding of SCN virulence genes referred to as ror genes (for the r eproduction o n a r esistant host), a strategic rotation of SCN resistance sources that can counter-select nematode populations is a potential solution for combating SCN (Gardner et al 2017 ; Meinhardt et al 2021 ). Counter-selection studies using different virulent nematode populations on PI 88788, PI 90763, and Peking have contributed to insights on the potential use of these sources in rotation to limit virulent SCN population build-up (Luedders and Dropkin 1983 ; Anand and Shumway 1985 ; Gardner et al 2017 ; Meinhardt et al 2021 ). Some of these studies have highlighted a strong counter-selection between virulence on PI 88788 and PI 90763 (Anand and Shumway 1985 ; Gardner et al 2017 ).…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2022

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Key message An epistatic interaction between SCN resistance loci rhg1-a and rhg2 in PI 90,763 imparts resistance against virulent SCN populations which can be employed to diversify SCN resistance in soybean cultivars. Abstract 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 90,763 through two biparental F3:4 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 90,763. 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.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

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

et al. 2022

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Genome-Wide Prediction of Disease Resistance Gene Analogs in Flax

You

2023

Compendium of Plant Genomes

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Deciphering the genetic basis of resistance to soybean cyst nematode combining IBD and association mapping

Tian

Wang

et al. 2023

Theor Appl Genet

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Key message IBD analysis clarified the dynamics of chromosomal recombination during the ZP pedigree breeding process and identified ten genomic regions resistant to SCN race3 combining association mapping. Abstract Soybean cyst nematode (SCN, Heterodera glycines Ichinohe) is one of the most devastating pathogens for soybean production worldwide. The cultivar Zhongpin03-5373 (ZP), derived from SCN-resistant progenitor parents, Peking, PI 437654 and Huipizhi Heidou, is an elite line with high resistance to SCN race3. In the current study, a pedigree variation map was generated for ZP and its ten progenitors using 3,025,264 high-quality SNPs identified from an average of 16.2 × re-sequencing for each genome. Through identity by decent (IBD) tracking, we showed the dynamic change of genome and detected important IBD fragments, which revealed the comprehensively artificial selection of important traits during ZP breeding process. A total of 2,353 IBD fragments related to SCN resistance including SCN-resistant genes rhg1, rhg4 and NSFRAN07 were identified based on the resistant-related genetic paths. Moreover, 23 genomic regions underlying resistance to SCN race3 were identified by genome-wide association study (GWAS) in 481 re-sequenced cultivated soybeans. Ten common loci were found by both IBD tracking and GWAS analysis. Haplotype analysis of 16 potential candidate genes suggested a causative SNP (C/T, − 1065) located in the promoter of Glyma.08G096500 and encoding a predicted TIFY5b-related protein on chr8 was highly correlated with SCN race3 resistance. Our results more thoroughly elucidated the dynamics of genomic fragments during ZP pedigree breeding and the genetic basis of SCN resistance, which will provide useful information for gene cloning and the development of resistant soybean cultivars using a marker-assisted selection approach.

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Resistance Gene Pyramiding and Rotation to Combat Widespread Soybean Cyst Nematode Virulence

Cited by 14 publications

References 27 publications

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

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

Genome-Wide Prediction of Disease Resistance Gene Analogs in Flax

Deciphering the genetic basis of resistance to soybean cyst nematode combining IBD and association mapping

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