Genetic Basis of Maize Resistance to Multiple Insect Pests: Integrated Genome-Wide Comparative Mapping and Candidate Gene Prioritization

Badji, Arfang; Kwemoi, Daniel Bomet; Machida, Lewis; Okii, Dennis; Mwila, Natasha; Agbahoungba, Symphorien; Kumi, Frank; Ibanda, Angele; Bararyenya, Astère; Solemanegy, Marta; Odong, Thomas; Wasswa, Peter; Otim, Michael; Asea, Godfrey; Ochwo-Ssemakula, Mildred; Talwana, Herbert; Kyamanywa, Samuel; Rubaihayo, Patrick

doi:10.3390/genes11060689

Cited by 22 publications

(21 citation statements)

References 115 publications

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“…Postharvest insect pest resistance is especially important in coun- Schön et al (1993), Bohn et al (2000), and Badji et al (2020and Badji et al ( , 2021, thus restricting gain from selection.…”

Section: In S Ec T Pe S T Re S Is Tan Ce B Reed Ing a Pproache Smentioning

confidence: 99%

“…The detected QTLs displayed large confidence intervals and their effects were usually not consistent across maize populations, thus the stability of the resistance is lacking. Nevertheless, presumably in the future, GS will provide more success in increasing insect resistance in plants including maize (Badji et al, 2020(Badji et al, , 2021, suggesting that entomologists and breeders should not be discouraged by less promising results at this early stage of research.…”

Section: In S Ec T Pe S T Re S Is Tan Ce B Reed Ing a Pproache Smentioning

confidence: 99%

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Global warming and increasing maize cultivation demand comprehensive efforts in disease and insect resistance breeding in north‐western Europe

Miedaner

Juroszek²

2021

Plant Pathology

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Maize productivity is threatened by global climate change. Climate change scenarios suggest that north‐western (NW) Europe will get warmer and drier during the main crop‐growing period. In general, more northerly regions will benefit, whereas more southerly regions will suffer suboptimal rain‐fed farming conditions. In these latter regions in particular, the resulting probable lower realized on‐farm maize grain and biomass yields must be safeguarded. Breeding for resistance against already existing and emerging diseases and insect pests is one component to achieve yield stability across years. Durable multiple‐disease resistance will become especially crucial. Herein, we focus on disease resistance breeding approaches in maize, especially related to northern corn leaf blight and Fusarium ear rots, although virus and bacterial diseases will become more important as well. Continuous adjustments of disease resistance breeding strategies will be required. Insect pest resistance breeding must be improved considerably, as in a warmer world insects will thrive, probably causing detrimental direct (feeding, sucking, etc.) and indirect (vectors of pathogens, feeding wounds creating gateways for many pathogens, passive transport of inoculum across maize plants) effects. Four case studies on insects that are already prevalent in NW Europe or may be expected in the near future are covered in this review. Maize cultivars need to combine both durable multiple‐disease and multiple‐insect resistance, although the implementation of many different effective resistance resources in breeding programmes will be challenging, particularly if trade‐offs among breeding goals appear.

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Section: In S Ec T Pe S T Re S Is Tan Ce B Reed Ing a Pproache Smentioning

confidence: 99%

Section: In S Ec T Pe S T Re S Is Tan Ce B Reed Ing a Pproache Smentioning

confidence: 99%

Global warming and increasing maize cultivation demand comprehensive efforts in disease and insect resistance breeding in north‐western Europe

Miedaner

Juroszek²

2021

Plant Pathology

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“…In addition, genetic linkage and genome-wide association mapping studies have seldom been explored in African germplasm [ 8 , 24 ], which further impedes the application of MAS in the development of insect resistance maize germplasm in Africa. In a previous study, we discovered several quantitative trait nucleotides and genes that are putatively associated with FAW and MW resistance, confirming the quantitative nature of these traits, hence the difficulty in improving these traits through MAS [ 25 ]. An alternative to both PS and MAS is genomic selection (GS), which uses whole-genome markers to perform genomic prediction (GP) of breeding values of unphenotyped genotypes, from which one can select superior candidate genotypes for crossing to produce hybrids or to advance to the next generation [ 26 ].…”

Section: Introductionmentioning

confidence: 68%

“…The differential performances of the different GP algorithms on the insect resistance traits evaluated in this study could be due to differences in the genetic structures (extent of additive vs. non-additive gene action) of the respective traits [ 23 , 38 , 47 , 49 ]. Maize resistance to FAW, which was moderately heritable across environments [ 25 ], would be expected to be controlled by both additive and non-additive genetic factors, including epistasis [ 102 , 103 , 104 ], whereas, MW-resistance traits such as GWL, AP, and AK with heritability values above 90% [ 25 ] were most likely characterized by a prevalence of additive gene action [ 105 , 106 ] in the current panel.…”

Section: Discussionmentioning

confidence: 99%

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Factors Influencing Genomic Prediction Accuracies of Tropical Maize Resistance to Fall Armyworm and Weevils

Badji

Machida²,

Kwemoi

et al. 2020

Plants

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Genomic selection (GS) can accelerate variety improvement when training set (TS) size and its relationship with the breeding set (BS) are optimized for prediction accuracies (PAs) of genomic prediction (GP) models. Sixteen GP algorithms were run on phenotypic best linear unbiased predictors (BLUPs) and estimators (BLUEs) of resistance to both fall armyworm (FAW) and maize weevil (MW) in a tropical maize panel. For MW resistance, 37% of the panel was the TS, and the BS was the remainder, whilst for FAW, random-based training sets (RBTS) and pedigree-based training sets (PBTSs) were designed. PAs achieved with BLUPs varied from 0.66 to 0.82 for MW-resistance traits, and for FAW resistance, 0.694 to 0.714 for RBTS of 37%, and 0.843 to 0.844 for RBTS of 85%, and these were at least two-fold those from BLUEs. For PBTS, FAW resistance PAs were generally higher than those for RBTS, except for one dataset. GP models generally showed similar PAs across individual traits whilst the TS designation was determinant, since a positive correlation (R = 0.92***) between TS size and PAs was observed for RBTS, and for the PBTS, it was negative (R = 0.44**). This study pioneered the use of GS for maize resistance to insect pests in sub-Saharan Africa.

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Fall‐armyworm invasion, control practices and resistance breeding in Sub‐Saharan Africa

Matova

Kamutando

Magorokosho³

et al. 2020

Crop Science

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Fall armyworm [Spodoptera frugiperda (J.E. Smith); FAW] invasion has exacerbated maize (Zea mays L.) crop yield losses in sub‐Saharan Africa (SSA), already threatened by other stresses, especially those that are climate‐change induced. The FAW is difficult to control, manage, or eradicate, because it is polyphagous and trans‐boundary, multiplies fast, has a short life cycle and migrates easily, and lacks the diapause growth phase. In this study, FAW and its impact in Africa was reviewed, as well as past and present control strategies for this pest. Pesticides, cultural practices, natural enemies, host‐plant resistance, integrated pest management (IPM), and plant breeding approaches were examined as possible control strategies. It was concluded that an IPM control strategy, guided by cultural approaches already being used by farmers, and what can be adopted from the Americas, coupled with an insect‐resistance management strategy, is the best option to manage this pest in Africa. These strategies will be strengthened by breeding for multi‐trait host‐plant resistance through stacking of genes for different modes of control of the pest.

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Genetic Basis of Maize Resistance to Multiple Insect Pests: Integrated Genome-Wide Comparative Mapping and Candidate Gene Prioritization

Cited by 22 publications

References 115 publications

Global warming and increasing maize cultivation demand comprehensive efforts in disease and insect resistance breeding in north‐western Europe

Global warming and increasing maize cultivation demand comprehensive efforts in disease and insect resistance breeding in north‐western Europe

Factors Influencing Genomic Prediction Accuracies of Tropical Maize Resistance to Fall Armyworm and Weevils

Fall‐armyworm invasion, control practices and resistance breeding in Sub‐Saharan Africa

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