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1.
利用SSR标记定位水稻糊化温度的QTLs 总被引:27,自引:1,他引:26
糊化温度(GT)是决定稻米蒸煮食用品质的一个重要指标。研究了以碱消值表示的糊化温度(ASV-GT)的遗传和QTL位点,选择在ASV-GT上具有显著差别的灿稻品种南特号和粳稻品种Balilla杂交,并以Balilla回交得到含有142株的回交群体,ASV-GT的测定表明,在分离群体中ASV-GT表现为双峰连续分布,说明在该群体中ASV-GT是由一主效基因控制的,并伴有微效基因的修饰,进一步用119个在双亲间具有多态性的微卫星(SSR)标记构建了全基因组的分子标记连锁图,采用区间作图法对控制碱消值的基因进行了定位分析,结果表明,位于第6染色体的qASV6-1为一主效基因,其贡献率高达87.6%,来自于亲本南特号中的等位基因可降低碱消值3.26;其余5个QTLs(qASV2,qASV3,qASV6-2,qASV9,qASV11)为微效基因,分别位于第2,3,6,9和11染色体上,双亲中都带有增效和减效等位基因。 相似文献
2.
水稻耐淹涝性状的遗传分析和SSR标记的研究 总被引:5,自引:0,他引:5
淹涝胁迫对水稻生产造成了严重影响, 发掘可应用于耐淹涝辅助选择的分子标记(MAS), 将有助于水稻耐淹涝性状的遗传改良。应用耐淹涝材料FR13A和淹涝敏感材料IR39595-503-2-1-2为亲本做正反交获得F1和F2代群体。对正反交的F1群体的耐淹涝性状进行遗传分析, 发现正反交的F1代群体在耐淹涝性状上没有显著差异, 说明耐淹涝性状是核基因控制。从两次淹涝处理中F2代群体的分离情况来看, 来源于FR13A的耐淹特性表现出数量-质量性状遗传的特点。当淹涝胁迫压力比较轻时表现为数量性状遗传, 具有微效多基因的作用。当淹涝胁迫压力增大时, 表现为主效基因控制的质量性状。在SSR分析中, 187对SSR引物中有73对引物在两亲本间有明显的差异, 差异率为39%。用这73对差异引物, 对F2群体进行多态筛选, 结果筛选到一个与耐淹涝性状连锁的标记RM219, 验证了耐淹涝性状确实由主效基因Sub1控制, 因此, RM219在水稻耐淹涝育种中具有利用价值。 相似文献
3.
水稻是世界上最主要的粮食作物之一,目前农用耕地存在土壤重金属污染的问题,而水稻对镉(Cd)等重金属的耐受性较低,进而使水稻产量和质量受到影响。定位稻种耐Cd胁迫相关数量性状基因座(quantitative trait loci, QTLs),对于指导水稻耐Cd育种具有重要意义。为发掘Cd胁迫相关基因,以粳稻02428和籼稻昌恢891衍生的124个回交重组自交系群体(backcross recombinant inbred ines,BILs)为材料,对水稻萌芽期的根长、芽长进行了分析,并对萌芽期与Cd胁迫相关的QTLs进行了定位分析。结果显示:Cd胁迫处理下,02428和昌恢891根长和芽长均受到显著抑制(P<0.01),其中Cd对根长的抑制强于芽长;QTL分析共检测到5个萌芽期与Cd胁迫相关的QTLs:qCdBL3、qCdRL7、qCdBL8.1、qCdBL8.2和qCdBL9分别位于水稻第3、7、8、8和9号染色体上,贡献率为6.45%~19.46%。其中,qCdBL3、qCdBL8.1、qCdBL8.2和qCdBL9与芽长相关,qCdRL7与根长相关。同时,检测到2个在对照条件下(水溶液)影响根长和芽长的QTLs:qCKBL8、qCKRL4,分别位于第8和4号染色体上,贡献率为10.53%和10.89%。比较显示,对照和Cd处理条件下控制水稻萌芽期根长或芽长的QTLs均不相同,说明Cd胁迫条件下,控制水稻根长和芽长的遗传机制可能不同于非Cd胁迫条件。研究结果为耐Cd基因的克隆和耐Cd水稻新品种的选育提供了参考。 相似文献
4.
水稻RIL群体芽期耐冷性基因的分子标记定位 总被引:11,自引:0,他引:11
水稻芽期冷害是我国长江中下游的早稻种植区和东北、西北稻区及云贵高原的一季稻区水稻生产中的重要限制因子之一。研究中利用纸卷法测定1个水稻重组自交系群体对10℃低温的芽期耐冷性,结合1张高密度分子遗传图谱,进行QTL定位分析。检测到控制水稻芽期耐冷性的4个QTL,分别位于1、3、7和11号染色体上。其中,位于11号染色体上的QTL qSCT-11的效应最大,在10℃低温处理13d时,对性状的贡献率达26%~30%,被检测到的LOD值也高达16~19,其加性效应值为正,增效等位基因存在于亲本Lemont中,RM202为与QTL qSCT-11紧密连锁的SSR标记。该主效QTL的增效基因,可作为分子标记辅助选择的操作对象用于水稻芽期耐冷性的遗传改良。 相似文献
5.
水稻亚铁胁迫诱导ADH的基因定位及其遗传分析 总被引:2,自引:0,他引:2
籼稻品种IR64与粳稻品种Azucena及其DH群体135个系用于进行Fe^2+胁迫(250mg/L,pH4.5)及对照实验,对处理及对照条件下的ADH进行基因定位及遗传分析,结果表明,在Fe^2+胁迫条件下,ADH酶的活性大大提高,群体在Fe^2+胁迫条件下,表现低值的超亲现象,分布偏向IR64,单标记分析和最大似然区间作图结果表明,Fe^2+胁迫条件下,11号染色体上紧密连锁的3个标记位点RG 相似文献
6.
水稻籼粳交DH群体苗期耐冷性基因的分子标记定位 总被引:14,自引:1,他引:14
水稻苗期低温冷害导致的烂秧现象是水稻生产中重要的限制因素之一。以一个水稻籼粳交(圭630/02428)DH群体为材料,在幼苗3叶1心时用10℃低温处理3d,随后恢复培养,以恢复培养5d后的秧苗成活率(%)为指标,鉴定该DH群体的苗期耐冷性。利用已构建的RFLP连锁图谱和基于混合线性模型的定位软件QTLMapper1.0对水稻苗期耐冷性进行QTL分析,检测到控制水稻苗期耐冷性的3个QTLs,分别位于第3、11、12染色体上,贡献率分别为7.9%、18.3%和24.4%,其增效等位基因均来自于亲本“02428”。同时检测到控制水稻苗期耐冷性的上位性互作位点8个,分散分布于第2、7、8、9、11染色体上,其中有2对互作的贡献率在15%左右,这2对互作的增效基因型均为来自2个亲本的重组基因型。苗期耐冷性在2个亲本间差异很大,在DH群体中呈现出连续变异,有明显的超亲分离。这些结果表明,水稻苗期耐冷性是受多基因控制的数量性状,基因的上位性互作是其重要的遗传基础之一。 相似文献
7.
水稻芽期耐冷性的QTL分析 总被引:2,自引:0,他引:2
本研究以98个Nipponbare/Kasalath//Nipponbare回交重组自交家系(backcross-inbred lines,BILs)组成的群体为材料,进行水稻芽期耐冷性数量性状基因座的检测和遗传效应分析.25℃正常条件下水稻发芽7 d,芽长5~10 cm,5℃低温处理10d,之后升温至25℃,缓苗10d,调查活苗率,并以活苗率作为芽期耐冷性的表型值,分析亲本和98个BILs的芽期耐冷性表现.采用Windows QTL Cartographer 1.13a软件的复合区间作图法,共检测到4个苗期耐冷性数量性状基因座(quantative trait locus,QTL),分别位于第3、第7和第12染色体上,命名为qSCT-3-1、qSCT-3-2、qSCT-7和qSCT-12.4个QTL的加性效应分别为11.16、11.14、-8.8和-14.59,可解释表型变异的12.11%,12.66%,6.82%和15.86%. 相似文献
8.
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
9.
利用粳稻染色体片段置换系群体检测水稻抗亚铁毒胁迫有关性状QTL 总被引:17,自引:2,他引:17
潜育性水稻田广泛分布于中国、斯里兰卡、印度、印度尼西亚、塞拉里昂、利比亚、尼日利亚、哥伦比亚和菲律宾等国,其中我国南方稻区就有近700万公顷低产潜育性水稻田。该类水稻田还原性强,矿质营养失调,尤以Fe^2 过量积累,对水稻生长发育产生不良的逆境胁迫作用。培育抗亚铁毒的水稻品种是简便、经济有效地提高稻谷产量的重要途径之一。该文利用由粳稻品种Asominori与籼稻品种IR24杂交衍生的Asominori染色体片段置换系(Chromosome Segment Substitution Lines,CSSLs)群体为材料,检测与抗亚铁毒胁迫有关性状QTL。共检测到与抗亚铁毒胁迫有关性状QTL14个,各QTL的LOD值为2.72~6.63。其中检测到与抗亚铁毒胁迫直接有关的性状叶片棕色斑点指数QTL3个,分别位于第3、9、11染色体C515~XNpb279、R2638~C1263和G1465~C950之间,对应的贡献率分别为16.45%、11.16%和28.02%;与其他已发表的定位结果比较发现,位于第三染色体C515~XNpb279间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的QTL的位置一致;表明在亚铁毒胁迫条件下,水稻在其叶片表面出现棕色斑点,叶片衰老,产生一些叶绿素降解物或衍生物,以提高叶片细胞对亚铁等重金属毒害的耐受力。另外,在第11染色体G1465~C950之间检测到了控制叶片棕色斑点指数、茎干重和根干重QTL1个,为主效QTL。在第6染色体XNpb386~XNpb342之间检测到控制茎干重、株高、根长和根干重QTL1个,是否与水稻抗亚铁毒有关需要进一步研究。本研究旨在通过定位与抗亚铁毒有关的QTL,借助与之紧密连锁的分子标记有效地聚合这些QTL,培育出抗亚铁毒性强的水稻新种质材料。 相似文献
10.
为了检测水稻种子的耐盐相关数量性状位点,也为耐盐遗传机理的研究提供理论基础,本实验以Koshihikari(受体)和Nona Bokra(供体)为亲本构建的全基因组单片段代换系(154个)作为研究群体,采用培养皿培养,在水稻种子的萌发期进行浓度为1%的盐胁迫,以种子的发芽情况为指标,统计发芽率数据,利用分子标记技术,定... 相似文献
11.
J. J. Ni P. Wu D. Senadhira N. Huang 《TAG. Theoretical and applied genetics. Theoretische und angewandte Genetik》1998,97(8):1361-1369
The amplified fragment length polymorphism (AFLP) technique combined with selective genotyping was used to map quantitative
trait loci (QTLs) associated with tolerance for phosphorus (P) deficiency in rice. P deficiency tolerant cultivar IR20 was
crossed to IR55178-3B-9-3 (sensitive to P-deficiency) and 285 recombinant inbred lines (RILs) were produced by single-seed
descent. The RILs were phenotyped for the trait by growing them in P-sufficient (10.0 mg/l) and P-deficient (0.5 mg/l) nutrient
solution and determining their relative tillering ability at 28 days after seeding, and relative shoot dry weight and relative
root dry weight at 42 days after seeding. Forty two of each of the extreme RILs (sensitive and tolerant) and the parents were
subjected to AFLP analysis. A map consisting of 217 AFLP markers was constructed. Its length was 1371.8 cM with an average
interval size of 7.62 cM. To assign linkage groups to chromosomes, 30 AFLP and 26 RFLP markers distributed over the 12 chromosomes
were employed as anchor markers. Based on the constructed map, a major QTL for P-deficiency tolerance, designated PHO, was
located on chromosome 12 and confirmed by RFLP markers RG9 and RG241 on the same chromosome. Several minor QTLs were mapped
on chromosomes 1, 6, and 9.
Received: 21 April 1998 / Accepted: 9 June 1998 相似文献
12.
M. Wissuwa M. Yano N. Ae 《TAG. Theoretical and applied genetics. Theoretische und angewandte Genetik》1998,97(5-6):777-783
Phosphorus (P) deficiency of soils is a major yield-limiting factor in rice production. Increasing the P-deficiency tolerance
of rice cultivars may represent a more cost-effective solution than relying on fertilizer application. The objective of this
study was to identify putative QTLs for P-deficiency tolerance in rice, using 98 backcross inbred lines derived from a japonica×indica cross and genotyped at 245 RFLP marker loci. Lines were grown on P-deficient soil and P uptake, internal P-use efficiency,
dry weight, and tiller number were determined. Three QTLs were identified for dry weight and four QTLs for P uptake, together
explaining 45.4% and 54.5% of the variation for the respective traits. Peaks for both traits were in good agreement which
was to be expected considering the tight correlation of r=0.96 between dry weight and P uptake. For both traits the QTL linked to marker C443 on chromosome 12 had a major effect.
Two of the three QTLs detected for internal P-use efficiency, including the major one on chromosome 12, coincided with QTLs
for P uptake; however, whereas indica alleles increased P uptake they reduced P-use efficiency. We concluded that this was not due to the tight linkage of two
genes in repulsion but rather due to an indirect effect of P uptake on P-use efficiency. Most lines with high use efficiency
were characterized by very low P uptake and dry weight and apparently experienced extreme P-deficiency stress. Their higher
P-use efficiency was thus the result of highly sub-optimal tissue-P concentrations and did not represent a positive adaptation
to low P availability. The number of tillers produced under P deficiency is viewed as an indirect indicator of P-deficiency
tolerance in rice. In addition to the major QTL on chromosome 12 already identified for all other traits, two QTLs on chromosome
4 and 12 were identified for tiller number. Their position, however, coincided with QTLs for tiller number reported elsewhere
under P-sufficient conditions and therefore appear to be not related to P-deficiency tolerance. In this study P-deficiency
tolerance was mainly caused by differences in P uptake and not in P-use efficiency. Using a trait indirectly related to P-deficiency
tolerance such as tiller number, we detected a major QTL but none of the minor QTLs detected for P uptake or dry weight.
Received: 9 February 1998 / Accepted: 29 April 1998 相似文献
13.
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
14.
矮泰引-3中半矮秆基因的分子定位 总被引:6,自引:1,他引:5
矮泰引-3的矮生性状受两对独立遗传的半矮秆基因控制,利用SSR标记将这两个矮秆基因分别定位到第1和第4染色体上。等位性测交的结果表明,位于第1染色体上的矮秆基因与sd1是等位的,所以仍然称其为sd1;而位于第4染色体上的矮秆基因是一个新基因,暂命名为sdt2。利用SSR标记将sd1定位于RM297、RM302和RM212的同一侧,而与OSR3共分离,它们之间的位置关系可能是RM297-RM302-RM212-OSR3-sd1,遗传距离分别为4.7cM、0cM、0.8cM和0cM,这与sd1在第1染色体长臂上的确切位置是基本一致的。利用已有的SSR标记和拓展的SSR标记将sdt2定位于SSR332、RM1305和RM5633、RM307、RM401之间,它们的排列位置可能是SSR332-RM1305-sdt2-RM5633-RM307-RM401,它们之间的遗传距离分别为11.6cM、3.8cM、0.4cM、0cM和0.4cM。 相似文献
15.
Salinity and submergence are two very prominent abiotic stress conditions affecting rice yield adversely in the coastal agro ecosystem. Marker Assisted Backcross Breeding (MABB) is an efficient and fast track molecular tool to incorporate a desired stress tolerant QTL/gene into an improved cultivar. The present study was carried out for the introgression of Saltol QTL responsible for salinity tolerance and Sub1 gene responsible for submergence tolerance into the high yielding rice variety Aiswarya independently through MABB. Final objective of the study is to develop dual stress tolerant (tolerance to salinity and submergence) Aiswarya rice variety by pyramiding the both target QTLs introgressed BC2F2 progenies having maximum background homozygosity. The donors of Saltol QTL and Sub1 gene used in the present study were FL478 and Swarna Sub1, respectively. Based on the background genome analysis of the introgressed plants, the plants with > 85–90% background similarity were selected for pyramiding of Saltol QTL and Sub1 gene into the elite background of rice variety Aiswarya. Those selected introgressed lines with Saltol QTL and Sub1 gene will be again crossed to pyramid both Saltol QTL and Sub1 gene into the rice variety Aiswarya. Such a mega rice variety pyramided with dual stress tolerant QTLs is the expected outcome of this study and can be recommended for cultivation in the flood prone saline coastal agroecosystem. 相似文献
16.
水稻低温发芽力QTL定位和遗传分析 总被引:5,自引:0,他引:5
以Kinmaze(粳稻)/DV85(籼稻)的重组自交系F10世代群体检测了影响水稻低温发芽力性状的数量性状基因座(QTL)。通过测定不同时期的低温发芽率,确定了15℃低温、第10d为检测低温发芽率的最适处理温度和时间,该条件下能够充分检测到品种的差异和分离群体的变异。通过设置对照,证明所检测的低温发芽率不受休眠及二次休眠的影响。15℃低温、第10d时,Kinmaze的发芽率达35%,DV85的发芽率只有7%,两亲本之间存在明显差异,该群体81个家系的低温发芽率变幅在0%~99%之间。QTL分析结果检测到5个与低温发芽力相关的基因座,分别位于第2、6、7、11和12染色体上。位于第2、6和11染色体上的qLTG-2、qLTG-6和qLTG-11贡献率分别为27.1%、17.1%和15.0%,对低温发芽力性状的增效基因来自DV85;位于第7、12染色体上qLTG-7和qLTG-12的贡献率分别为22.9%和8.8%,增效基因来自Kinmaze。其中,qLTG-6和qLTG-11在染色体上的位置与已报道的有关低温发芽力QTL位置相似,而qLTG-2、qLTG-7和qLTG-12为新检测的低温发芽力基因座。上位性分析结果显示,第3与第5染色体上存在影响低温发芽力的互作位点,其互作可以提高低温发芽力,而第7染色体上的两位点之间的互作降低了低温发芽力。 相似文献
17.
水稻RIL群体苗期耐冷性QTL分析 总被引:7,自引:0,他引:7
水稻苗期冷害是影响早春季节和高纬度地区水稻成苗和秧苗生长的重要限制因素之一。为了鉴定控制水稻苗期耐冷性的QTL,研究采用了1个水稻“粳籼交”重组自交系(RIL)群体,结合1张高密度分子遗传图谱,对3叶期幼苗经过10℃冷处理3d、恢复培养2d和4d时的秧苗存活率进行复合区间作图。亲本Lemont和特青的苗期耐冷性具有极显著差异,Lemont的苗期耐冷性很强,而特青对低温敏感。在重组自交系群体中,苗期耐冷性表现为连续变异,在两个方向上均出现大量超亲分离。共检测到5个水稻苗期耐冷性QTL,分别位于水稻1、3、8和11号染色体上,单个QTL对性状的贡献率为7%~21%。其中,4个QTL的增效基因来源于亲本Lemont,另1个QTL的增效基因来源于亲本特青。2个主效QTL(qSCT-3和qSCT-8)分别位于3号染色体标记区间RM282-RM156和8号染色体标记区间RM230—RM264,对性状的贡献率达到或接近20%,被检测到的LOD值显著较高,其增效基因均来自于耐冷性亲本Lemont。研究结果进一步揭示了水稻苗期耐冷性QTL具有丰富的位点多样性,表明耐冷性普遍较强的粳稻是发掘苗期耐冷性优异基因的主要稻种资源。 相似文献
18.
Molecular Genetic Analysis of QTLs for Ferulic Acid Content in Dried Straw of Rice (Oryza sativa L.)
Dong Y Tsuzuki E Kamiunten H Lin D Terao H Matsuo M Cheng S 《Biochemical genetics》2005,43(1-2):25-34
Phenolic acids are secondary metabolic organic compounds produced by plants and often are mentioned as allelochemicals. This study was conducted to determine the genetic basis controlling the ferulic acid content of rice straw in a recombinant inbred (RI) population derived from a cross between a japonica variety, Asominori, with a higher content of ferulic acid, and an indica variety, IR24, with a lower content, using 289 RFLP markers. Continuous distributions and transgressive segregations of ferulic acid content were observed in the RI population, which showed that ferulic acid content in rice straw was quantitatively inherited. Single marker analysis and composite interval mapping identified three quantitative trait loci (QTLs) for ferulic acid content with LOD values of 2.03 (chromosome 3), 3.16 (chromosome 6), and 3.06 (chromosome 7); all three had increased additive effects (13.5, 18.3, and 18.1 g g –1) from the Asominori parent and accounted for 5.5, 16.9, and 12.8% of total phenotypic variation, respectively. This is the first report on the identification of QTLs associated with ferulic acid and their chromosomal localization on the molecular map of rice. The tightly linked molecular markers that flank the QTLs might be useful in breeding and selection of varieties with higher phenolic acid content. 相似文献
19.
N. S. Zenna F. C. Sta Cruz E. L. Javier I. A. Duka A. A. Barrion O. Azzam 《Journal of Phytopathology》2006,154(4):197-203
Balimau Putih [an Indonesian cultivar tolerant to rice tungro bacilliform virus (RTBV)] was crossed with IR64 (RTBV, susceptible variety) to produce the three filial generations F1, F2 and F3. Agroinoculation was used to introduce RTBV into the test plants. RTBV tolerance was based on the RTBV level in plants by analysis of coat protein using enzyme‐linked immunosorbent assay. The level of RTBV in cv. Balimau Putih was significantly lower than that of IR64 and the susceptible control, Taichung Native 1. Mean RTBV levels of the F1, F2 and F3 populations were comparable with one another and with the average of the parents. Results indicate that there was no dominance and an additive gene action may control the expression of tolerance to RTBV. Tolerance based on the level of RTBV coat protein was highly heritable (0.67) as estimated using the mean values of F3 lines, suggesting that selection for tolerance to RTBV can be performed in the early selfing generations using the technique employed in this study. The RTBV level had a negative correlation with plant height, but positive relationship with disease index value. 相似文献