Genome‐wide association analysis of resistance to <i>Pythium ultimum</i> in common bean (<i>Phaseolus vulgaris</i>)

Dramadri, Isaac Onziga; Amongi, Winnyfred; Kelly, James D.; Mukankusi, Clare Mugisha

doi:10.1111/pbr.12855

Cited by 8 publications

(9 citation statements)

References 58 publications

(114 reference statements)

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“…The traits Pyth_COL (P. myriotylum response in the greenhouse) RRD_field (root rot damage in the field) and RRD_all (root rot damage combining both datasets) were evaluated in the RR panel in Colombia (COL). The traits Fus_UGA (F. cuneirostrum), Pyth_UGA (P. ultimum), Rhiz_USA (R. solani) and Fus_USA (F. solani) were evaluated in the ADP panel in Uganda (UGA) (Amongi et al, 2020;Onziga Dramadri et al, 2020) and the USA (Oladzad et al, 2019;Zitnick-Anderson et al, 2020). The ALS response was evaluated in the extBALSIT panel in Colombia (COL) and Uganda (UGA) (Nay et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

“…We observed a similar trend in the RR and extBALSIT populations, but it was not the case for the ADP evaluations in Uganda (Figure 5), where the PA fell by around 40 points below the estimated heritability. This result can be attributable to the binary distribution with presence/absence scores that the original data display (Amongi et al, 2020;Onziga Dramadri et al, 2020), which confers high heritability estimates, and the RKHS model evaluated in this study, which performed the prediction of a trait with quantitative nature. Wen et al (2019) confirmed that traits with high heritability would have higher PAs.…”

Section: Genomic Prediction For Root Rot Diseasementioning

confidence: 98%

“…The ADP represents the genetic diversity of cultivated germplasm of the Andean genepool, containing landraces, breeding lines and varieties from public and private breeding programs (Cichy et al, 2015a,b;Kamfwa et al, 2015a;Tock et al, 2017;Oladzad et al, 2019;Zitnick-Anderson et al, 2020). The ADP was evaluated for Pythium ultimum (Pyth_UGA) and Fusarium cuneirostrum (Fus_UGA) under greenhouse conditions at the CIAT-Kawanda research station (Uganda) as described by Amongi et al (2020) and Onziga Dramadri et al (2020). This panel was also evaluated under greenhouse conditions for resistance to Rhizoctonia solani (Rhiz_USA) and Fusarium solani (Fus_USA) at North Dakota State University (United States) as described by Oladzad et al (2019) and Zitnick-Anderson et al (2020).…”

Section: Plant Materialsmentioning

confidence: 99%

“…To investigate a potential general quantitative tolerance to root diseases, we evaluated GP accuracies across previously published data sets on related traits. PAs across trials were investigated with data sets of Pythium, Fusarium (Fus), and Rhizoctonia (Rhiz) root rot evaluated in the Andean Diversity Panel (ADP) (Oladzad et al, 2019;Amongi et al, 2020;Onziga Dramadri et al, 2020;Zitnick-Anderson et al, 2020). Cross validation within this panel showed highest prediction accuracies for evaluations in Uganda (Pyth_Uga and Fus_Uga) ( Figure 6).…”

Section: Genomic Prediction For Root Rot Traits Across Populationsmentioning

confidence: 99%

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Genetic Analyses and Genomic Predictions of Root Rot Resistance in Common Bean Across Trials and Populations

et al. 2021

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Root rot in common bean is a disease that causes serious damage to grain production, particularly in the upland areas of Eastern and Central Africa where significant losses occur in susceptible bean varieties. Pythium spp. and Fusarium spp. are among the soil pathogens causing the disease. In this study, a panel of 228 lines, named RR for root rot disease, was developed and evaluated in the greenhouse for Pythium myriotylum and in a root rot naturally infected field trial for plant vigor, number of plants germinated, and seed weight. The results showed positive and significant correlations between greenhouse and field evaluations, as well as high heritability (0.71–0.94) of evaluated traits. In GWAS analysis no consistent significant marker trait associations for root rot disease traits were observed, indicating the absence of major resistance genes. However, genomic prediction accuracy was found to be high for Pythium, plant vigor and related traits. In addition, good predictions of field phenotypes were obtained using the greenhouse derived data as a training population and vice versa. Genomic predictions were evaluated across and within further published data sets on root rots in other panels. Pythium and Fusarium evaluations carried out in Uganda on the Andean Diversity Panel showed good predictive ability for the root rot response in the RR panel. Genomic prediction is shown to be a promising method to estimate tolerance to Pythium, Fusarium and root rot related traits, indicating a quantitative resistance mechanism. Quantitative analyses could be applied to other disease-related traits to capture more genetic diversity with genetic models.

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Section: Discussionmentioning

confidence: 99%

Section: Genomic Prediction For Root Rot Diseasementioning

confidence: 98%

Section: Plant Materialsmentioning

confidence: 99%

Section: Genomic Prediction For Root Rot Traits Across Populationsmentioning

confidence: 99%

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Genetic Analyses and Genomic Predictions of Root Rot Resistance in Common Bean Across Trials and Populations

et al. 2021

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“…The availability of high‐density, genome‐wide SNP markers has made genome‐wide association study (GWAS) a useful approach for identifying marker loci associated with causative variation in important traits in a diverse germplasm collection. In common bean, GWAS has been used for mapping genomic regions associated with a number of traits of economic importance, including phenology and yield component traits, cooking time, and disease resistance (Cichy et al., 2015; Dramadri et al., 2020; Hoyos‐Villegas et al., 2017; Kamfwa et al., 2015; Zuiderveen et al., 2016). The development of bean cultivars with enhanced tolerance to DS can be improved through the identification of genomic regions and associated key agronomic and PS traits and a better understanding of the genetic control and physiological mechanisms associated with the key traits regulating drought tolerance.…”

Section: Introductionmentioning

confidence: 99%

Genome‐wide association analysis of drought adaptive traits in common bean

Dramadri

Nkalubo

Kramer³

et al. 2021

Crop Science

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Genome‐wide association study (GWAS) was conducted to determine the genetic architecture of yield component and photosynthetic (PS) traits in 256 common bean (Phaseolus vulgaris L.) genotypes from the Andean gene pool. The panel was evaluated under drought stress (DS) and non‐stress (NS) conditions at two locations for two seasons in Uganda and genotyped with 260K single nucleotide polymorphism (SNP) markers. Significant association signals were detected for yield component and PS traits on chromosomes Pv02, Pv03, Pv04, Pv06, Pv09, Pv10, and Pv11. Colocalized GWAS signals were detected for pod weight per plant (PW) and seed yield per plant (SY) on Pv06 with ten significant markers and for PhiNPQ, LEF, Phi2, and PhiNO on Pv11 under DS. Positional candidate genes were identified within the 1.76 Mb common region for PW and SY under DS on Pv06 including Phvul.006G117500, Phvul.006G119800, and Phvul.006G130500 annotated as plant invertase/pectin methylesterase inhibitor (INH/PMEI) superfamily protein, involved in sucrose metabolism and signaling. Phvul.006G121200, 14.9Kb upstream of marker S06_23021418 (23.02Mb) on Pv06, encodes Protein phosphatase 2C family protein involved in ABA signaling pathway. Positional candidate genes for PS traits PhiNPQ, LEF, Phi2, and PhiNO on Pv11 under DS were identified including Phvul.011G178200, Phvul.011G178250, Phvul.011G178300, and Phvul.011G178500 between 48.94–49.96 Mb annotated as “RING/U‐BOX SUPERFAMILY PROTEIN”, ubiquitin ligase (E3) involved in ABA‐mediated responses. Significant markers associated with colocalized GWAS signal for SY and PW on Pv06 identified in this study can be validated for marker assisted breeding to improve drought tolerance in large‐seeded Andean beans.

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