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1.
水稻耐亚铁毒QTLs的定位 总被引:6,自引:0,他引:6
亚铁毒是潜育性水稻土中限制水稻产量的主要因子。利用龙杂8503/IR64的F2和等价的F3群体,在营养液中培养来定位耐亚铁毒的QTLs。通过构建101SSR标记的遗传连锁图谱来确定耐亚铁毒QTLs的位置和特性。借助叶片棕色斑点指数、株高和最大根长3个性状,利用营养液在水稻苗期来评价F2单株、F3群体和亲本龙杂8503、IR64,共检测到叶片棕色斑点指数、株高和最大根长的QTLs20个,分布在水稻的10条染色体上,表明这些性状受多基因控制。控制叶片棕色斑点指数的QTLs分别定位在第1染色体的RM315-RM212、第2染色体的RM6-RM240和第4染色体的RM252-RM451之间。与前人的研究结果比较发现:1)位于第4染色体RM252-RM451之间的控制叶片棕色斑点指数的QTL与水稻功能图谱上控制叶绿素含量减少的QTL的位置一致。另一个位于第1染色体的RM315-RM212之间的控制叶片棕色斑点指数的QTL与水稻功能图谱上位于C178-R2635之间控制叶绿素含量的QTL连锁。2)位于第2染色体RM6-RM240之间的第3个控制叶片棕色斑点指数的QTL与位于RZ58-CD0686的控制钾吸收的QTL连锁。 相似文献
2.
水稻光合功能相关性状QTL分析 总被引:7,自引:0,他引:7
利用粳稻Kinmaze/籼稻DV85杂交后代单粒传衍生的81个F11家系所组成的重组自交系(Recombinant Inbred Lines,RILs)群体,研究水稻光合功能相关性状的数量性状基因座(QTL)。在水稻抽穗后7d测定叶片全氮含量(TLN)、叶绿素a/b比值(Chl.a:b)和叶绿素含量(Chl)。共检测到6个QTL,各QTL的LOD值为2.66~4.81,贡献率为11.2%-29.6%,其中,在第1、2和11染色体上检测到3个与全氮含量相关的QTL,相应贡献率为17.3%、15.3%、13.7%;在第3和4染色体检测到2个与叶绿素a/b比值相关的QTL,贡献率为13.8%和29.6%;在第1染色体检测到1个与叶绿素含量相关的QTL,贡献率为11.2%。4个QTL为本研究新检测的基因座。有趣的是,控制叶绿素含量的qCC-1位于第1染色体上RFLP标记C122附近,与已报道的NADH-谷氨酸合成酶基因位置一致,而叶绿素合成始于谷氨酸,暗示该基因座与水稻光合功能关系极为密切。然而,对抽穗后30d叶绿素含量进行QTL分析,结果未检测到与其相关的QTL,表明控制叶绿素含量qCC-1效应随水稻叶片的衰老而降低。 相似文献
3.
水稻F2不育和抽穗期QTL分析 总被引:5,自引:1,他引:4
对台中65(粳稻)/Bhadua(籼稻)杂交F2代群体构建了RFLP连锁图谱,含94个分布较为均匀的标记。对F2小穗不育性状进行单点分析和区间分析的结果基本一致:有两个F2小穗不育QTL座位分别位于染色体1的XNpb113~XNpb346之间和染色体8的G187~XNpb397之间,而且该两个QTL均为新检测出的座位;检测出5个抽穗期TQL,其中3个座位在单点分析和区间分析中的结果一致,分别位于染色体1的XNpb113~XNpb346,染色体4的C891~C335,染色体的8的C166~C1121,另外,染色体6的XNpb27为单点分析结果,染色体10的R716~C405为区间分析结果。由于染色体1上的F2不育QTL和抽穗期QTL重叠,该QTL座位是由于遗传效应所至还是由于环境因素(迟抽穗)所至有待构建近等基因系进一步研究。;位于染色体1和10上的抽穗期QTL座位为新检测的座位。对新检测的F2不育和抽穗期QTL座位正在建立相应的近等基因系以精确定位和克隆上述基因。 相似文献
4.
水稻产量及其构成因子对空气CO2浓度增高响应的QTL分析 总被引:3,自引:0,他引:3
自由空气CO2浓度增加设施(Free air carbon dioxide enrichment.FACE)使得实际地模拟未来植物生长所处的CO2浓度增加环境变为可能。FACE下.作物生长和产量发生不同程度的加速和提高,而分析作物产量因子对CO2浓度增加响应的遗传基础将有利于对CO2环境变化做出敏感响应的遗传特性的认识,有利于适合未来空气CO2浓度增加环境的高产品种的培育。以粳稻品种Asominori与籼稻品种IR24的杂交组合所衍生的染色体片段置换系(CSSLs)为材料进行田间试验,分别在FACE(约570umol CO2/mol)和正常大气(约370umol CO2/mol)下对籽粒产量及其构成因子等数量性状位点(QTL)进行了分析。结果表明,在FACE下,Asominori和IR24的有效穗数、穗粒数和单株籽粒产量均显著高于对照下的,并且FACE下,65个置换系的变幅范围均大于对照下的;在第1.2,4,6.7,9和12染色体上检测到LOD值在2.5—5.7范围内的控制上述产量性状的20个QTL.其中有3个可以同时在FACE和正常大气下检测到.其余的则只是在某一种CO2环境下检测到。此外,还检测到2个QTL(qFT12 and qGP4)存在着与环境的加性互作效应。可以推论.空气中CO2浓度的增加诱导了部分对CO2浓度敏感的QTL表达,控制水稻产量性状的QTL与CO2增加的环境发生了互作效应。预计利用分子标记辅助育种途径可以培育出适用于未来CO2浓度增加环境下的高产水稻品种。 相似文献
5.
控制水稻重要农艺性状的QTL在盐胁迫与非胁迫条件下的对比研究 总被引:12,自引:0,他引:12
基因型与环境的互作(G×E)对数量性状的影响常常掩盖了遗传因子引起的性状变化. 在盐胁迫环境与非胁迫环境下分别调查了水稻(Oriza sativa L.) 5个重要的农艺性状, 总共检测到24个QTL, 分布在除第9, 11号染色体外的各染色体上. 盐胁迫环境中检出了9个QTL: 千粒重1个; 抽穗期2个; 株高1个; 每穗粒数2个; 有效分蘖3个, 占总数的37.5%; 非胁迫环境中则检出了17个QTL: 千粒重5个; 抽穗期6个; 株高3个; 每穗粒数2个; 有效分蘖1个, 占总数的70.8%; 有两个QTL在两种环境中都检测到, 占总数的8.3%, 它们分别是位于第4染色体上控制抽穗期的QTL和位于第6染色体上控制每穗粒数的QTL. 此外, 还检测出3个包含多个QTL的区间, 它们分别位于第1, 4和8染色体上, 其中第1染色体上RG612分子标记附近检出两个QTL, 在盐胁迫环境与非胁迫环境中分别控制有效分蘖和抽穗期这两个重要的农艺性状, 其加性效应均由来源于JX17的等位基因提供; 第4染色体上的C975-RG449区间检测到2个QTL, qrHD-4c在非协迫环境中控制抽穗期, qrGPP-4s则在胁迫环境中控制每穗粒数; 第8染色体上的RG885-GA408区间检测到3个QTL, 在非胁迫环境下分别控制抽穗期、千粒重、株高3个性状, 在胁迫环境下则未能检测到. 通过对水稻在盐胁迫环境与非胁迫环境下的QTL对比研究, 发现水稻第8染色体上几个控制水稻重要农艺性状的QTL明显受盐胁迫的影响. 相似文献
6.
水稻耐铁毒性的生理指标研究 总被引:7,自引:0,他引:7
1 引 言铁毒是热带和亚热带地区水稻栽培中常见的生理病害 ,主要原因是土壤溶液中积累过多的亚铁盐 ,严重影响了稻谷产量 .水稻遭受铁毒的外观症状是叶面产生棕褐色斑点 ,最初以叶片斑点的面积大小衡量铁毒伤害的严重程度[4 ] .但实际操作不方便 ,难以定量比较 ;且有试验表明 ,在部分品种中 ,叶片病斑面积和产量没有相关性[5] .目前普遍采用亚铁胁迫培养下植物干重相对受害 (减少 )率作为评价水稻耐铁毒能力的形态指标[1] ,但测定时会毁损植株 .为了在苗期筛选耐铁毒水稻时不毁损植株 ,建立评价水稻铁毒耐性的生理指标十分必要 .已有研… 相似文献
7.
水稻分蘖角度的QTL定位和主效基因的遗传分析 总被引:11,自引:0,他引:11
利用水稻籼粳亚种间组合Asominori×IR24重组自交系(RIL)群体71个株系和相应的全基因组染色体片段置换系(Chromosomesegmentsubstitutionline,CSSL)群体65个株系,在2种环境下对分蘖角度性状进行了数量性状基因座(QTL)定位和上位性效应的遗传分析。在两种群体中都出现了分蘖角度的超亲分离。在RIL群体中发现了5个主效QTLs和3对上位性双位点互作标记基因座,控制水稻分蘖角度。其中在第9染色体上位于XNpb108~C506RFLP分子标记区间的qTA-9基因座在2种环境中同时出现,其贡献率平均为28·6%,增加分蘖角度的等位基因来自籼稻品种IR24。利用CSSL群体图示基因型分析,证实在第9染色体上含有RFLP标记C609和C506约15cM的染色体区段,存在增加分蘖角度的基因,来源于染色体片段供体亲本IR24,在Asominori的遗传背景中能增加分蘖角度约15°,该基因的位置与RIL群体在第9染色体上定位的QTL相同,证实了qTA-9的存在。F1表型测定及F2代遗传分析表明,来自IR24的等位基因是一个不完全显性基因。除一对上位性位点存在显著的环境互作效应外,未发现其他位点存在与环境的互作效应。不同基因的加性效应和双位点的上位性效应的共同作用可能是造成水稻分蘖角度超亲分离的主要原因。 相似文献
8.
水稻种子活力QTL定位及上位性分析 总被引:6,自引:1,他引:5
利用1个粳/籼交来源(Lemont/Teqing)、包含264个重组自交系的作图群体,采用纸卷法在18℃培养箱中进行2次重复的发芽实验,考察了种子发芽7d、9d和1ld的发芽率,种子发芽15d后的芽长及干重等种子活力的相关性状。结合一张含有198个DNA标记的连锁图谱,用作图软件QTLMapper1.0定位与种子活力相关的QTL。共检测到13个主效应QTL,这些QTL对性状的贡献率为2.9%~12.7%,平均贡献率为6.2%。同时检测到18对贡献率≥5%的互作位点,其贡献率为5.1%~11.8%,平均贡献率为6.9%,比检测到的主效应QTL的平均贡献率稍大。种子活力相关性状的大多数主效应和互作QTL成串分布于少数几个染色体区段(Chromosome Regions,CRs),并且成串分布在同一染色体区段的QTL效应的方向总是一致,该结果与这些性状在表型上的正相关相一致。若将成串分布有3个及3个以上种子活力相关性状QTL的CRs视为与种子活力高度相关的CRs,则共检测到7个上述与种子活力高度相关的CRs,分别分布在水稻12条染色体中的7条染色体上。根据所含QTL的种类(主效应QTL或/和上位性QTL)可将这些CRs分成以下3种:1)M-CRs:只含有主效应QTL,如CR^sv-7;2)E-CRs:所含位点没有主效应,但与其他位点发生互作,如CR^sv-1、CR^sv-6和CR^sv-12;3)ME-CRs:既含有主效应QTL、也含有与其他位点产生互作的互作位点,如CR^sv-2、CR^sv-5和CR^sv-8。另外还发现,有的CR上的位点同时与多个不同CR上的位点互作,影响种子活力的相关性状。与前入的研究结果相比较,发现有些与种子活力高度相关的CR可在不同研究者所用的不同定位群体中被检测到,而有的CR只在特定的定位群体中被检测到。由此表明,水稻种子活力具有丰富的遗传多样性和复杂的遗传基础,其主效QTL和互作位点可能基于遗传背景的不同而相互转化。 相似文献
9.
缺磷是抑制全球水稻产量主要因素之一。本研究利用Asomonori(粳型)/IR24(籼型)杂交重组自交株系,对5个水稻苗期性状(相对苗高、相对根长、相对根重、相对苗重以及相对总重)在缺磷条件下的响应QTL进行定位。共检测到20个水稻苗期生长对缺磷响应的QTL位点,分别位于第1(4QTLs)、第4(4QTLs)、第5(2QTLs)、第7、第8(4QTLs)、第9(2QTLs)、第11(2QTLs)和第12号染色体上,其中13个QTLs位于与C3029C、XNpb302、C621B、C621C、R2976和C1263分子标记紧密连锁的6个基因组区域上。另外,每个性状均能从双亲中检测到正负效应QTL位点,这些能解释重组自交系群体中出现超亲和连续分布的现象。本文主要报道了水稻第5、第7和第11染色体上存在水稻苗期生长对缺磷响应的QTL位点。研究表明,该结果及其中检测到的QTLs两侧的连锁分子标记可用于水稻苗期耐低磷性分子育种。 相似文献
10.
水稻柱头外露率的QTL分析 总被引:18,自引:3,他引:15
利用高柱头外露率的籼稻窄叶青8号(ZYQ8)和极低外露率的粳稻京系17(JX17)以及由它们构建的加倍单倍体(DH)群体,在海南对各DH株系的柱头外露率进行调查,并使用该群体的分子连锁图谱进行数量性状座位(QTL)分析。共检测到2个控制水稻柱头外露率的QTL(qPES-2,qPES-3),分别位于第2、第3染色体;并发现控制柱头单边外露率的QTL与柱头外露率完全一致,而控制柱头双边外露率的QTL在第2染色体上检测到;其增效基因均来源于ZYQ8。同时定位的控制穗粒数的QTL位于第6染色体和第8染色体上,与柱头外露率之间没有连锁关系。 相似文献
11.
Chromosome segment substitution lines (CSSLs) are useful for the precise mapping of quartitative trait loci (QTLs) and dissection of the genetic basis of complex traits.In this study,two whole-genome sequenced rice cultivars,the japonica Nipponbare and indica 9311 were used as recipient and dtonor,respectively.A population with 57 CSSLs was developed after crossing and back-crossing assisted by mo lecular rnarkers,and genotypes were identified using a high-throughput resequencing strategy,Detailed graphical genotypes of 38 lines were constructed based on resequencing data.These CSSLs had a total of 95 substituted segments derived from indica 9311,with an average of about 2.5 segments pet CSSL and eight segments per chromosome,and covered about 87.4% of the rice whole genome.A multiple linear regression QTL analysis mapped four QTLs for 1000-grain weight.The largest-effect QTL was located in a region on chromosome 5 that contained a cloned major QTL GW5/qSW5 for grain size in rice.These CSSLs with a background of Nipponbare may provide powerful tools for future whole-genome discovery and functional study of essential genes/QTLs in rice,and offer ideal materials and foundations for japonica breeding. 相似文献
12.
水稻落粒性是与其生产密切相关的重要性状之一。以7个染色体片段置换系为材料, 采用重叠群代换作图法对控制落粒性的2个主效QTL进行定位。结果表明, 104个SSR标记在亲本间具有多态性, 多态率为68.0%; 4个置换系的落粒性与亲本日本晴的落粒性相似, 表现难落粒。3个置换系与亲本93-11的落粒性相似, 表现易落粒; 7个染色体片段置换系在第1和第6染色体上检出7个置换片段, 其长度分别为23.6、16.5、 6.6、 9.9、 10.4、 20.2和7.1 cM; qSH-1-1被定位在第1染色体RM472-RM1387之间, 遗传距离约为6.6 cM。qSH-6-1为新发现的落粒性主效QTL, 被定位在第6染色体RM6782-RM3430之间,遗传距离约为4.2 cM。利用染色体片段置换系能准确地定位水稻落粒性QTL, qSH-1-1与qSH-6-1的鉴定和初步定位为其进一步的精细定位、图位克隆及分子标记辅助选择奠定了基础。 相似文献
13.
Wenyin Zhu Jing Lin Dewei Yang Ling Zhao Yadong Zhang Zhen Zhu Tao Chen Cailin Wang 《Plant Molecular Biology Reporter》2009,27(2):126-131
Chromosome segment substitution lines (CSSLs) are powerful tools for detecting and precisely mapping quantitative trait loci
(QTLs) and evaluating gene action as a single factor. In this study, 103 CSSLs were produced using two sequenced rice cultivars:
93-11, an elite restorer indica cultivar as recipient, and Nipponbare, a japonica cultivar, as donor. Each CSSL carried a single chromosome substituted segment. The total length of the substituted segments
in the CSSLs was 2,590.6 cM, which was 1.7 times of the rice genome. To evaluate the potential application of these CSSLs
for QTL detection, phenotypic variations of seed shattering, grain length and grain width in 10 CSSLs were observed. Two QTLs
for seed shattering and three for grain length and grain width were identified and mapped on rice chromosomes. The results
demonstrate that CSSLs are excellent genetic materials for dissecting complex traits into a set of monogenic loci. These CSSLs
are of great potential value for QTL mapping and plant marker-assisted breeding (MAB). 相似文献
14.
Ochiai K Uemura S Shimizu A Okumoto Y Matoh T 《TAG. Theoretical and applied genetics. Theoretische und angewandte Genetik》2008,117(1):125-133
Boron toxicity tolerance of rice plants was studied. Modern japonica subspecies such as Koshihikari, Nipponbare, and Sasanishiki were tolerant, whereas indica subspecies such as Kasalath and IR36 were intolerant to excessive application of boron (B), even though their shoot B contents under B toxicity were not significantly different. Recombinant inbred lines (RILs) of japonica Nekken-1 and indica IR36 were used for quantitative trait locus (QTL) analysis to identify the gene responsible for B toxicity tolerance. A major QTL that could explain 45% of the phenotypic variation was detected in chromosome 4. The QTL was confirmed using a population derived from a recombinant inbred line which is heterogenic at the QTL region. The QTL was also confirmed in other chromosome segment substitution lines (CSSLs). 相似文献
15.
Characterization of tissue tolerance to iron by molecular markers in different lines of rice 总被引:4,自引:0,他引:4
Wu P. Hu B. Liao C.Y. Zhu J.M. Wu Y.R. Senadhira D. Paterson A.H. 《Plant and Soil》1998,203(2):217-226
Ferrous iron (Fe2+) toxicity is a major disorder in rice prod uction on acid, flooded soils. Rice ( Oryza sativa L.) genotypes differ widely in tolerance to Fe2+ toxicity, which makes it possible to bre ed more tolerant rice varieties. Tissue tolerance to higher iron concentrations in plants has been considered to be important to Fe2+ tolerance in ri ce. Segregation for leaf bronzing and growth reduction due to Fe2+ to xicity was observed in a doubled haploid (DH) population with 135 lines derived from a Fe2+ tolerant japonica variety, Azucena, and a sensitive indic a variety, IR64 in a solution culture with Fe2+ stress condition at a Fe2+concentration of 250 mg L-1 at pH 4.5. To better understand the mechanism of tissue tolerance, Leaf Bronzing Index (LBI), total iron concentration in shoot tissue and the enzymes of ascorbate peroxidase (AP), dehydroascorbate reductase (DR) and glutathione reductase (GR), and concentrations of ascorbate (AS) and dehydroascorbate (DHA), which are involved in the ascorbate-specific H2O2-scavenging system, were determined for the population under Fe2+ stress. A non-normal distribution of LBI was found. About 38 lines showed no bronzing, while the lines with non-zero LBI values ranged from 0.05 to 0.85 and showed a normal distribution. The other parameters measured showed normal distribution. The total iron concentrations in the 38 tolerant lines ranged from 1.76 mg Fe g-1 to 4.12 mg Fe g-1 and was in a similar range as in the non-tolerant genotype (2.04 – 4.55 mg Fe g-1). No significant differences in the activities of the enzymes were found between the parents under normal culture, but remarkably higher Fe2+ induced enzyme activities were observed in the tolerant parent. AS was similar between the parents under both normal and Fe2+ stress, but its concentration was sharply decreased under Fe2+ stress. DHA was much lower in the tolerant parent than in the sensitive parent under Fe2+ stress. Single locus analysis and interval mapping analysis based on 175 molecular markers revealed that the interval flanked by RG345 and RZ19 on chromosome one was an important location of gene(s) for Fe2+ tolerance. The ascorbate-specific system for scavenging Fe2+-mediated oxygen free radicals may be an important mechanism for tissue Fe2+ tolerance. A gene locus with relative small effect on root ability to exclude Fe2+ was also detected. 相似文献
16.
QTL mapping of root traits in a doubled haploid population from a cross between upland and lowland japonica rice in three environments 总被引:7,自引:0,他引:7
Li Z Mu P Li C Zhang H Li Z Gao Y Wang X 《TAG. Theoretical and applied genetics. Theoretische und angewandte Genetik》2005,110(7):1244-1252
To genetically dissect drought resistance associated with japonica upland rice, we evaluated a doubled haploid (DH) population from a cross between two japonica cultivars for seven root traits under three different growing conditions (upland, lowland and upland in PVC pipe). The traits included basal root thickness (BRT), total root number (RN), maximum root length (MRL), root fresh weight (RFW), root dry weight (RDW), ratio of root fresh weight to shoot fresh weight (RFW/SFW) and ratio of root dry weight to shoot dry weight (RDW/SDW). The BRT was significantly correlated with the index of drought resistance, which was defined as the ratio of yield under the stress of the upland condition to that under the normal lowland condition. A complete genetic linkage map with 165 molecular markers covering 1,535 cM was constructed. Seven additive quantitative trait loci (QTLs) and 15 pairs of epistatic loci for BRT and RN were identified under upland and lowland conditions, and 12 additive QTLs and 17 pairs of epistatic QTLs for BRT, RN, MRL, RFW, RFW/SFW and RDW/SDW were identified under the PVC pipe condition. Four additive QTLs and one pair of epistatic QTLs controlling IDR were also found. These QTLs individually explained up to 25.6% of the phenotypic variance. QTL × environment (Q × E) interactions were detected for all root traits, and the contributions of these interactions ranged from 1.1% to 19.9%. Five co-localized QTLs controlling RFW and RDW, RFW/SFW, RDW/SDW and IDR, BRT and RN, RN, MRL and IDR were found. Four types of QTLs governing BRT and RN were classified by their detection in the upland and lowland conditions. Some common QTLs for root traits across different backgrounds were also revealed. These co-localized QTLs and common QTLs will facilitate marker-assisted selection for root traits in rice breeding programs. 相似文献
17.
覆盖野生稻基因组的染色体片段替换系的构建及其米质相关数量性状基因座位的鉴定 总被引:13,自引:0,他引:13
染色体片段替换系(CSSL)是基因组水平快速初步定位数量性状基因座位(QTL)的良好材料,而水稻的品质性状是多基因控制的数量性状,因此可用替换系鉴定控制水稻品质性状的QTL。本文用分子标记辅助选择技术(MAS)构建了由133个株系组成的以‘特青’(籼稻品种)为轮回亲本,以海南的一种普通野生稻为供体亲本,覆盖绝大部分野生稻基因组的染色体片段替换系。利用这套替换系,初步定位了控制稻米外观和理化品质性状的15个QTL,为今后水稻品质性状QTL的克隆以及稻米品质相关性状的改良提供了依据。 相似文献
18.
利用染色体片段置换系定位水稻落粒性主效QTL 总被引:9,自引:3,他引:6
水稻落粒性是与其生产密切相关的重要性状之一。以7个染色体片段置换系为材料,采用重叠群代换作图法对控制落粒性的2个主效QTL进行定位。结果表明,104个SSR标记在亲本间具有多态性,多态率为68.0%;4个置换系的落粒性与亲本日本晴的落粒性相似,表现难落粒。3个置换系与亲本93-11的落粒性相似,表现易落粒;7个染色体片段置换系在第1和第6染色体上检出7个置换片段,其长度分别为23.6、16.5、6.6、9.9、10.4、20.2和7.1 cM;qSH-1-1被定位在第1染色体RM472-RM1387之间,遗传距离约为6.6 cM。qSH-6-1为新发现的落粒性主效QTL,被定位在第6染色体RM6782-RM3430之间,遗传距离约为4.2 cM。利用染色体片段置换系能准确地定位水稻落粒性QTL,qSH-1-1与qSH-6-1的鉴定和初步定位为其进一步的精细定位、图位克隆及分子标记辅助选择奠定了基础。 相似文献
19.
Genotypic variation in tolerance to elevated ozone in rice: dissection of distinct genetic factors linked to tolerance mechanisms 总被引:1,自引:0,他引:1
Tropospheric ozone concentrations are increasing in many Asian countries and are expected to reach levels that adversely affect crop production. Developing ozone-tolerant rice (Oryza sativa L.) varieties is therefore essential to prevent yield losses in the future. The aims of this study were to assess genotypic variation for ozone tolerance in rice, to identify quantitative trait loci (QTL) conferring tolerance, and to relate QTLs to physiological tolerance mechanisms. The response of 23 varieties to elevated ozone (120 nl l(-1)) was assessed based on leaf bronzing and dry weight loss. The traditional variety 'Kasalath' was highly tolerant, whereas the modern variety 'Nipponbare' showed significant dry weight reductions. Using the Nipponbare/Kasalath/Nipponbare mapping population, six QTLs associated with tolerance to elevated ozone were identified, of which three were subsequently confirmed in Nipponbare/Kasalath substitution lines (SLs). Two QTLs associated with leaf bronzing were located on chromosomes three and nine. Kasalath alleles on chromosome three increased bronzing, while alleles on chromosome nine reduced bronzing. SLs carrying these contrasting QTLs differed significantly in leaf ascorbic acid (AsA) content when exposed to ozone, suggesting AsA as a principal antioxidant counteracting ozone-induced oxidative damage. A further confirmed QTL related to dry weight was located on chromosome eight, where the Kasalath allele increased relative dry weight. A SL carrying this QTL exhibited a less reduced net photosynthetic rate under ozone exposure compared with its recurrent parent Nipponbare. Although the effect of these QTLs on crop yield has not yet been established, their identification could be an important first step in developing ozone-tolerant rice varieties. 相似文献