Fiskeby III × 中国春大豆群体中臭氧耐受性的表型变异及数量性状位点的鉴定。（注：这里“Mandarin (Ottawa)”直译为“中国春（渥太华）”，在大豆品种中“中国春”是一个常用名称，括号内“渥太华”可能是该品种的一些特殊标注或来源地相关信息，整体翻译尽量保持原文结构以符合专业文献翻译要求。）

Phenotypic variation and identification of quantitative trait loci for ozone tolerance in a Fiskeby III × Mandarin (Ottawa) soybean population.

作者信息

Burton Amy L, Burkey Kent O, Carter Thomas E, Orf James, Cregan Perry B

机构信息

Plant Science Research Unit, USDA-ARS, 3127 Ligon Street, Raleigh, NC, 27607, USA.

Department of Crop Science, North Carolina State University, Raleigh, NC, 27695-7631, USA.

出版信息

Theor Appl Genet. 2016 Jun;129(6):1113-25. doi: 10.1007/s00122-016-2687-1. Epub 2016 Feb 26.

DOI:10.1007/s00122-016-2687-1

PMID:26920548

Abstract

Soybean quantitative trait loci for ozone response. Ground-level ozone reduces yield in crops such as soybean (Glycine max (L.) Merr.). Phenotypic variation has been observed for this trait in multiple species; however, breeding for ozone tolerance has been limited. A recombinant inbred population was developed from soybean genotypes differing in tolerance to ozone: tolerant Fiskeby III and sensitive Mandarin (Ottawa). Plants were exposed to ozone treatment for 5 days in greenhouse chambers followed by visual scoring for foliar injury. Mean injury score in the mid-canopy was 16 % for Fiskeby III, and 81 % for Mandarin (Ottawa). Injury scores were lower in younger leaves for both parents and progeny, compared to scores in the older leaves. Segregation was consistent with multigenic inheritance. Correlation coefficients for injury between leaf positions ranged from 0.34 to 0.81, with the closer leaf positions showing the greater correlation. Narrow sense heritability within an ozone treatment chamber was 0.59, 0.40, 0.29, 0.30, 0.19, and 0.35 for the 2nd, 3rd, 4th, 5th, 6th, and combined 3rd-5th main stem leaf positions (numbered acropetally), respectively, based on genotypic means over three independent replications. Quantitative trait loci (QTL) analysis showed that loci were associated with distinct leaf developmental stages. QTL were identified on Chromosome 17 for the 2nd and 3rd leaf positions, and on Chromosome 4 for the 5th and 6th leaf positions. Additional loci were identified on Chromosomes 6, 18, 19, and 20. Interacting loci were identified on Chromosomes 5 and 15 for injury on trifoliate 4. The ozone sensitive parent contributed one favorable allele for ozone response.

摘要

大豆对臭氧反应的数量性状位点。地面臭氧会降低大豆（Glycine max (L.) Merr.）等作物的产量。在多个物种中都观察到了该性状的表型变异；然而，耐臭氧性育种一直受到限制。从对臭氧耐受性不同的大豆基因型培育出一个重组自交群体：耐臭氧的Fiskeby III和敏感的Mandarin（渥太华）。在温室中对植株进行5天的臭氧处理，然后对叶片损伤进行视觉评分。Fiskeby III植株中层冠层的平均损伤评分为16%，而Mandarin（渥太华）为81%。与老叶相比，双亲及其后代的幼叶损伤评分较低。分离情况符合多基因遗传。叶位间损伤的相关系数在0.34至0.81之间，叶位越近相关性越高。在一个臭氧处理室内，基于三个独立重复的基因型均值，第2、3、4、5、6个以及第3 - 5个主茎叶位（从顶部向下编号）的狭义遗传力分别为0.59、0.40、0.29、0.30、0.19和0.35。数量性状位点（QTL）分析表明，这些位点与不同的叶片发育阶段相关。在第17号染色体上鉴定出与第2和第3叶位相关的QTL，在第4号染色体上鉴定出与第5和第6叶位相关的QTL。在第6、18、19和20号染色体上鉴定出其他位点。在第5和第15号染色体上鉴定出与三出复叶4损伤相关的互作位点。臭氧敏感亲本贡献了一个对臭氧反应有利的等位基因。

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Phenotypic variation and identification of quantitative trait loci for ozone tolerance in a Fiskeby III × Mandarin (Ottawa) soybean population.Fiskeby III × 中国春大豆群体中臭氧耐受性的表型变异及数量性状位点的鉴定。（注：这里“Mandarin (Ottawa)”直译为“中国春（渥太华）”，在大豆品种中“中国春”是一个常用名称，括号内“渥太华”可能是该品种的一些特殊标注或来源地相关信息，整体翻译尽量保持原文结构以符合专业文献翻译要求。）

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Phenotypic variation and identification of quantitative trait loci for ozone tolerance in a Fiskeby III × Mandarin (Ottawa) soybean population.

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