Multienvironment Quantitative Trait Loci Mapping and Consistency across Environments of Resistance Mechanisms to Ferrous Iron Toxicity in Rice

Dufey, Inès; Hiel, Marie-Pierre; Hakizimana, Patrice; Lutts, Stanley; Koné, Brahima; Dramé, Khady Nani; Konate, Kadougoudiou Abdourasmane; Sié, Moussa; Bertin, Pierre

doi:10.2135/cropsci2009.09.0544

Cited by 45 publications

(42 citation statements)

References 69 publications

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“…The effects of these QTLs on chromosome 1 and 3 were confirmed by using CSSL carrying Kasalath introgressions in the genetic background on Nipponbare (Wu et al, 2014). Dufey et al (2012) have looked at the QTLs associated with yield components under Fe toxic field conditions in particular in West Africa. Although of relatively small-effects, some of these QTLs co-located with previous QTLs, e.g., leaf bronzing QTL on chromosome 1, and were consistent over different experimental conditions, different environments and even in independent mapping studies.…”

Section: Genetics Of Fe Toxicity Tolerancementioning

confidence: 95%

“…As an alternative to Fe-toxic soil, the use of sand supplemented with different doses of FeSO 4 has been reported (Sikirou, 2009;Dufey et al, 2012). Onaga et al (2013) slightly improved this protocol by adding not only nitrogen, phosphorus and potassium but also micronutrients in the Yoshida solution.…”

Section: Phenotypic Screening For Tolerance To Fe Toxicitymentioning

confidence: 99%

“…Although of relatively small-effects, some of these QTLs co-located with previous QTLs, e.g., leaf bronzing QTL on chromosome 1, and were consistent over different experimental conditions, different environments and even in independent mapping studies. These stable QTLs were located in six regions of the rice genome and could be major QTLs harboring genes involved somehow in the tolerance to Fe toxicity (Dufey et al, 2012). Recently, Dufey et al (2015a) constructed an integrated map with the previous QTLs identified using the annotated physical map of the rice reference variety Nipponbare.…”

Section: Genetics Of Fe Toxicity Tolerancementioning

confidence: 99%

See 2 more Smart Citations

Genetic Improvement of Iron Toxicity Tolerance in Rice-Progress, Challenges and Prospects in West Africa

Sikirou

Saito

Achigan‐Dako

et al. 2015

Plant Production Science

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Section: Genetics Of Fe Toxicity Tolerancementioning

confidence: 95%

Section: Phenotypic Screening For Tolerance To Fe Toxicitymentioning

confidence: 99%

Section: Genetics Of Fe Toxicity Tolerancementioning

confidence: 99%

See 1 more Smart Citation

Genetic Improvement of Iron Toxicity Tolerance in Rice-Progress, Challenges and Prospects in West Africa

Sikirou

Saito

Achigan‐Dako

et al. 2015

Plant Production Science

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“…This results as two implications: incorporation of plant residues i) can help to correct Fe-deficient occurring in upland rice as chlorosis (rain-induced scorching), ii) increasing soil Fe content in upland can provoke contamination of lowland throughout runoff creating iron toxicity that is also a serious threat of rice [11]. From this analysis, we assert that the studied technology should be recommended for foot slope ecology because to limit the possible enrichment of subsequent lowland soil in Fe.…”

Section: Discussion Cropping System Effects In the Soilmentioning

confidence: 99%

Bush Fallow and Cowpea Crop Use as Precedent and Organic Sources of Nutrients for Rice Cultivation on Acidic Plinthosol of Central Benin in West Africa

ASSIGBE¹,

Koné²,

JP³

et al. 2012

Int J of Agri Scie

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Abstract-Tropical soils have low fertility and chemical fertilizers are not affordable for most of the farmers, especially in West Africa. The development of low cost technologies for amending agricultural soils in this environment is needed. Biological and organic fertilizers were tested in 20 farmers' fields in central Benin for rainfed rice production on acidic plinthosol under monomodal rainfall pattern conditions. Short time matured cowpea and native grass fallow were preceding NERICA1 and Ina Okpè rice cultivars that are interspecific (Oryza glaberrima × Oryza sativa) and local varieties respectively. Cowpea and bush residues were incorporated into soil before rice seeding. Soil nutrients (C,N,K, Ca and Zn) contents were significantly depleted whereas null balance was observed for soil available-P content. An increased of soil content in Fe (>130 mg kg -1 ) was significantly observed in all the treatments. Highest yield of 1.6 t ha -1 was recorded in the treatment composed of cowpea and NERICA1. The study technology was deemed suitable in deficient-P acid soil whereas the land foot slope position was excluded to avoid potential increasing of Fe content (iron toxicity of rice) in soil of the subsequent lowland. Minimum chemical fertilizer was required for improving rainfed rice cultivation on plinthosol in monomodal rainfall pattern ecology.

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“…Introducing the traits of tolerant to iron toxicity from those varieties into the high yield popular varieties is the way to improved rice productivity in iron toxicity environment. Several study have been mapped on the rice genome related with traits involved in tolerance to Fe toxicity, under various environmental conditions and using different segregating populations issued from intra-specific populations (Dufey et al 2009(Dufey et al , 2012aShimizu 2009;Shimizu et al 2005;Wan et al 2003a, b;Wu et al 1997Wu et al , 1998Wu et al 2014) or interspecific (Dufey et al 2012b) crosses. These QTLs for traits directly or indirectly linked to iron toxicity tolerance have been localized but challenges of confident genomic localization remain huge, and with several hundred genes involved, their use in breeding programs is difficult.…”

Section: Introductionmentioning

confidence: 99%

Markers-traits association for iron toxicity tolerance in selected Indonesian rice varieties

et al. 2016

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Abstract. Nugraha Y, Utami DW, Rosdianti I, Ardie SW, Ghulammahdi M, Suwarno, Aswidinnoor H. 2016. Markers-traits association for iron toxicity tolerance in selected Indonesian rice varieties. . Ferrous iron toxicity is a mineral disorder frequently occurring under flooded soils condition where rice is cultivated. Here we study identification the Single Nucleotide Polymorphism (SNPs) markers associated with iron toxicity tolerance characters. The phenotypical data was collected from exploiting of twenty-four rice genotypes that were grown under Yoshida + 0.2% agar solution with treatment of 400 mg. L -1 Fe 2+ and control conditions. The same genotypes were grown in iron toxicity acute and control sites at Taman Bogo, Lampung Province, Indonesia. The Principle Component Analysis (PCA) of the phenotypic data showed that 18 rice genotypes were selected representing grouping of related characters to iron toxicity condition. The genotyping of selected genotypes was carried out using multiplexes of 384 SNPs Golden Gate Illumina© assay. We identified, TBGI380435 which located on 14.45 Mbp of chromosome 9 was associated to leaf bronzing and relative shoot weight characters in the greenhouse experiment. The marker was associated with heavy metal transport detoxification (HTDT). The results are expected to assist in locating the potential candidate genes or Fe toxicity tolerance and to allow for precise marker-assisted selection. This research will serve for rice improvement through marker-assisted breeding and genomic selection in Indonesia.

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Multienvironment Quantitative Trait Loci Mapping and Consistency across Environments of Resistance Mechanisms to Ferrous Iron Toxicity in Rice

Cited by 45 publications

References 69 publications

Genetic Improvement of Iron Toxicity Tolerance in Rice-Progress, Challenges and Prospects in West Africa

Genetic Improvement of Iron Toxicity Tolerance in Rice-Progress, Challenges and Prospects in West Africa

Bush Fallow and Cowpea Crop Use as Precedent and Organic Sources of Nutrients for Rice Cultivation on Acidic Plinthosol of Central Benin in West Africa

Markers-traits association for iron toxicity tolerance in selected Indonesian rice varieties

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