Combination of linkage and association mapping with genomic prediction to infer QTL regions associated with gray leaf spot and northern corn leaf blight resistance in tropical maize

Omondi, Dennis O.; Dida, Mathews M.; Berger, Dave K.; Beyene, Yoseph; Nsibo, David L.; Juma, Collins; Mahabaleswara, Suresh L.; Gowda, Manje

doi:10.3389/fgene.2023.1282673

Cited by 8 publications

(1 citation statement)

References 104 publications

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“…Coupling forward breeding with genomic selection to simultaneously improve the germplasm for multiple traits, including those that are inherited quantitatively, such as GY, root, and stalk lodging, ear rot, GLS, TLB, and MLN would be an excellent strategy to increase genetic gains ( Poland et al., 2009 ; Larkin et al., 2019 ). KHMP can leverage current efforts by CIMMYT’s Global Maize Program to implement molecular breeding in conjunction ( Crossa et al., 2014 ; Prasanna et al., 2022b ; Omondi et al., 2023 ).…”

Section: Discussionmentioning

confidence: 99%

Genetic trends in the Kenya Highland Maize Breeding Program between 1999 and 2020

Ligeyo,

Saina,

Awalla

et al. 2024

Front. Plant Sci.

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Optimization of a breeding program requires assessing and quantifying empirical genetic trends made through past efforts relative to the current breeding strategies, germplasm, technologies, and policy. To establish the genetic trends in the Kenyan Highland Maize Breeding Program (KHMP), a two-decade (1999–2020) historical dataset from the Preliminary Variety Trials (PVT) and Advanced Variety Trials (AVT) was analyzed. A mixed model analysis was used to compute the genetic gains for traits based on the best linear unbiased estimates in the PVT and AVT evaluation stages. A positive significant genetic gain estimate for grain yield of 88 kg ha−1 year−1 (1.94% year−1) and 26 kg ha−1 year−1 (0.42% year−1) was recorded for PVT and AVT, respectively. Root lodging, an important agronomic trait in the Kenya highlands, had a desired genetic gain of −2.65% year−1 for AVT. Results showed improvement in resistance to Turcicum Leaf Blight (TLB) with −1.19% and −0.27% year−1 for the PVT and AVT, respectively. Similarly, a significant genetic trend of −0.81% was noted for resistance to Gray Leaf Spot (GLS) in AVT. These findings highlight the good progress made by KHMP in developing adapted maize hybrids for Kenya’s highland agroecology. Nevertheless, the study identified significant opportunities for the KHMP to make even greater genetic gains for key traits with introgression of favorable alleles for various traits, implementing a continuous improvement plan including marker-assisted forward breeding, sparse testing, and genomic selection, and doubled haploid technology for line development.

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Section: Discussionmentioning

confidence: 99%

Genetic trends in the Kenya Highland Maize Breeding Program between 1999 and 2020

Ligeyo,

Saina,

Awalla

et al. 2024

Front. Plant Sci.

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Emerging Approaches Based on Genome-Wide Association Studies (GWAS) for Crop Disease Tolerance

Dubey,

Mohanan

2024

Interdisciplinary Biotechnological Advances

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QTL mapping and genome-wide association analysis reveal genetic loci and candidate gene for resistance to gray leaf spot in tropical and subtropical maize germplasm

Pan,

Jiang,

Shaw

et al. 2024

Theor Appl Genet

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Key message Using QTL mapping and GWAS, two candidate genes ( Zm00001d051039 and Zm00001d051147 ) were consistently identified across the three different environments and BLUP values. GWAS analysis identified the candidate gene, Zm00001d044845 . These genes were subsequently validated to exhibit a significant association with maize gray leaf spot (GLS) resistance. Abstract Gray leaf spot (GLS) is a major foliar disease of maize ( Zea mays L.) that causes significant yield losses worldwide. Understanding the genetic mechanisms underlying gray leaf spot resistance is crucial for breeding high-yielding and disease-resistant varieties. In this study, eight tropical and subtropical germplasms were crossed with the temperate germplasm Ye107 to develop a nested association mapping (NAM) population comprising 1,653 F2:8 RILs, consisting of eight recombinant inbred line (RIL) subpopulations, using the single-seed descent method. The NAM population was evaluated for GLS resistance in three different environments, and genotyping by sequencing of the NAM population generated 593,719 high-quality single-nucleotide polymorphisms (SNPs). Linkage analysis and genome-wide association studies (GWASs) were conducted to identify candidate genes regulating GLS resistance in maize. Both analyses identified 25 QTLs and 149 SNPs that were significantly associated with GLS resistance. Candidate genes were screened 20 Kb upstream and downstream of the significant SNPs, and three novel candidate genes ( Zm00001d051039 , Zm00001d051147 , and Zm00001d044845 ) were identified. Zm00001d051039 and Zm00001d051147 were located on chromosome 4 and co-localized in both linkage ( qGLS4-1 and qGLS4-2 ) and GWAS analyses. SNP-138,153,206 was located 0.499 kb downstream of the candidate gene Zm00001d051039 , which encodes the protein IN2-1 homolog B, a homolog of glutathione S-transferase (GST). GSTs and protein IN2-1 homolog B scavenge reactive oxygen species under various stress conditions, and GSTs are believed to protect plants from a wide range of biotic and abiotic stresses by detoxifying reactive electrophilic compounds. Zm00001d051147 encodes a probable beta-1,4-xylosyltransferase involved in the biosynthesis of xylan in the cell wall, enhancing resistance. SNP-145,813,215 was located 2.69 kb downstream of the candidate gene. SNP-5,043,412 was consistently identified in three different environments and BLUP values and was located 8.788 kb downstream of the candidate gene Zm00001d044845 on chromosome 9. Zm00001d044845 encodes the U-box domain-containing protein 4 (P...

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Combination of linkage and association mapping with genomic prediction to infer QTL regions associated with gray leaf spot and northern corn leaf blight resistance in tropical maize

Cited by 8 publications

References 104 publications

Genetic trends in the Kenya Highland Maize Breeding Program between 1999 and 2020

Genetic trends in the Kenya Highland Maize Breeding Program between 1999 and 2020

Emerging Approaches Based on Genome-Wide Association Studies (GWAS) for Crop Disease Tolerance

QTL mapping and genome-wide association analysis reveal genetic loci and candidate gene for resistance to gray leaf spot in tropical and subtropical maize germplasm

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