矮泰引-3中半矮秆基因的分子定位

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。     

普通小麦Qz180中一个抗条锈病基因的分子作图

普通小麦(Triticum aestivum L.)材料Qz180具有良好的抗条锈病特性,经基因推导发现其含有一个优良的抗条锈病的基因,暂定名为YrQz.用Qz180与感病材料铭贤169和WL1分别杂交构建了两个F2群体,用条中30号条锈菌小种对这两个群体进行的抗性测验表明,YrQz为显性单基因遗传.通过SSR和AFLP结合BSA的方法对这个基因进行了分子作图,结果鉴定出与YrQz连锁的2个SSR标记和2个AFLP标记.根据SSR标记的染色体位置,该基因被定位在2B染色体的长臂上,位于两个SSR位点Xgwm388和Xgwm526之间;两个AFLP标记P35M48(452)和P36M61(163)分别位于该基因的两侧,遗传距离分别为3.4 cM和4.1cM.     

水稻长穗颈基因eui紧密连锁SSR标记获得

02428h是从半矮秆材料02428体细胞培养后代中发现的隐性高秆突变体, 其株高性状由1对长穗颈基因eui和1对半矮秆基因sd-1共同控制。以02428h与半矮秆材料南京11杂交的F₂为作图群体, 利用Gramene公布的SSR标记和根据NCBI中的BAC序列自己新开发的SSR标记, 将eui基因定位在第5染色体上的RM3673和RM0012之间, 两侧遗传距离分别为0.3 cM和1.0 cM, 为该基因的分子标记辅助选择奠定了基础。     

普通小麦Qz180中一个抗条锈病基因的分子作图(英文)

普通小麦(Triticum aestivum L.)材料Qz180具有良好的抗条锈病特性,经基因推导发现其含有一个优良的抗条锈病的基因,暂定名为YrQz。用Qz180与感病材料铭贤169和WL1分别杂交构建了两个F_2群体,用条中30号条锈菌小种对这两个群体进行的抗性测验表明,YrQz为显性单基因遗传。通过SSR和AFLP结合BSA的方法对这个基因进行了分子作图,结果鉴定出与YrQz连锁的2个SSR标记和2个AFLP标记。根据SSR标记的染色体位置,该基因被定位在2B染色体的长臂上,位于两个SSR位点Xgwm388和Xgwm526之间;两个AFLP标记P35M48(452)和P36M61(163)分别位于该基因的两侧,遗传距离分别为3.4cM和4.1cM。     

小麦纹枯病抗性的QTL分析和抗病基因的分子标记

对RIL-8群体纹枯病抗性进行QTL检测,检测到一个加性QTL,位于1A染色体上,贡献率为21.57%;检测到4对QTL间互作位点,涉及7条染色体,互作贡献率分别为11.63%、6.54%、14.04%、20.01%,互作总贡献率为52.23%.通过对RIL-SES群体118个系检测,发现1个SSR标记Xgwm526,位于2B染色体上,与纹枯病抗病基因距离为27.9cM;一个ISSR标记IS840,与纹枯病抗病基因距离为16.9cM.     

大麦多节分枝多穗矮秆突变基因的染色体定位

采用全套染色体形态性状标记系, 对大麦多性状综合突变基因mbd进行了染色体定位。结果表明,mbd在大麦的1H染色体上,处于矮秆基因br和裸粒基因n之间,可能由1H的短臂携带。其中,与短臂上br之间的遗传距离为29 .7cM,与长臂上n的遗传距离是42cM。 Abstract:In this paper a mutation gene mbd of 93-597,a multimode,branched and dwarf syndrome artificially induced in barley was localized on the short arm of the chromosome 1,between the kriown dwarf gene br and the naked kernel gene n.The genetic distances of mbd to br and n were 29.7cM and 42.9cM respectively.     

玉米抗南方锈病基因的QTL定位

为发掘新的抗南方锈病基因资源,本研究以感病自交系黄早四为母本、抗病自交系W456为父本,构建F2群体并开展抗病基因定位研究。采用人工接种鉴定的方法对两个亲本、F1、F2群体及对照材料进行表型鉴定和遗传分析。利用均匀覆盖10条染色体的200个SSR标记,分析240个F2单株的基因型并构建含有200个SSR位点的遗传连锁图,连锁图总长度3331 cM,标记间平均距离16.6 cM。使用QTL IciMapping V4.1软件中的完备区间作图法对抗病QTL进行分析,共检测到6个控制南方锈病的QTL:qSCR3、qSCR7、qSCR8-1、qSCR8-2、qSCR9和qSCR10,邻近标记分别为umc2105和umc1729、umc1066和bnlg2271、umc1904和umc1984、umc1984和bnlg1651、umc1957和bnlg1401、umc2034和umc1291,分别位于3、7、8、9和10号染色体上,其中8号染色体上有两个位点,标记区间长度在5～19 cM之间。单个QTL的表型贡献率在2.61%～24.19%之间,可以解释表型总变异的62.3%,其中3个QTL贡献率大于10%,位于10号染色体上的qSCR10贡献率最大,可解释表型变异的24.19%。通过对目标区间标记加密,将该位点的定位区间进一步缩小到2.51 cM内,与两侧标记的距离分别是2.15 cM和0.36 cM。初步定位得到10号染色体上存在抗南方锈病的主效QTL,可为抗病品种的培育提供参考。     

水稻中大麦Mlo和玉米Hm1抗病基因同源序列的分析和定位

大麦抗病基因Mlo和玉米抗病基因Hm1编码的产物不具有绝大多数植物抗病基因产物所含有的保守结构域。这两个抗病基因的作用机理也不符合基因对基因学说。从水稻中分离克隆了Mlo基因的同源序列OsMlo-1和玉米Hm1基因的同源序列DFR－1。利用水稻分子标记遗传连锁图,将OsMlo-1定位于水稻第六染色体的两俱RZ667和RG424之间;Osmlo-1距离这两个分子标记分别为20．6和6．0cM(centi-Morgan)。将DFR－1定位于水稻第一染色体两个分子标记R2635和RG462之间;DFR－1距离这两个分子标记分别为11．3和23．9cM。参照已发表的水稻分子标记连锁图,发现OsMlo-1和DFR－1的染色体位点分别与两个报道的水稻抗稻瘟病数量性状位点（QTL）有较好的对应关系。结果提示,水稻中与大麦Mlo 和玉米Hml同源的基因可能也参于抗病反应的调控。     

水稻品种‘沈农606’抗稻瘟病基因定位和连锁的SRAP片段分析

选用抗稻瘟病水稻品种‘沈农606’为抗病亲本与感病品种‘丽江新团黑谷’配制杂交组合.鉴定亲本、F_1正反交及其F_2群体的抗病性的结果表明,‘沈农606’的抗性受一对显性基因控制.采用相关序列扩增多态性(SRAP)和简单序列重复(SSR)标记,以及分离体分组混合分析法(BSA)将该基因定位于8号染色体上,其与SRAP标记m5e1-500的遗传距离为2.8 cM,与SSR标记RM25的遗传距离为9.8 cM,暂命名为Pi-SN606.m5e1-500序列位于8号染色体上,它能编码大于40个氨基酸的阅读框有2个,在NCBI网站上没有比对到同源性序列。     

两系杂交小麦恢复系MR168抗条锈病基因遗传分析及分子标记定位

小麦条锈病是影响杂交小麦普及推广的重要因素。文章利用基因推导法和SSR分子标记技术,研究了温光型两系杂交小麦恢复系MR168的抗条锈性遗传规律及其控制基因染色体位置。结果表明,MR168对CY29、CY31、CY32、CY33等条锈菌生理小种表现高抗至免疫;对SY95-71/MR168杂交组合的正反交F1、BC1、F2和F3群体分单株接种鉴定显示,MR168对CY32号小种的抗性受1对显性核基因控制,该抗病基因来源于春小麦品种辽春10号。利用集群分离分析法(Bulked segregant analysis,BSA)和简单重复序列(Simple sequence repeat,SSR)分子标记分析抗病亲本MR168、感病亲本SY95-71及183个F2代单株,发现了与MR168抗条锈病基因连锁的5个微卫星标记Xgwm273、Xgwm18、Xbarc187、Xwmc269、Xwmc406,并将该基因初步定位在1BS着丝粒附近,暂命名为YrMR168;构建了包含YrMR168的SSR标记遗传图谱,距离YrMR168最近的两个微卫星位点是Xgwm18和Xbarc187,遗传距离分别为1.9 cM和2.4 cM,这两个微卫星标记可用于杂交小麦抗条锈病分子标记辅助育种。     

A genetic linkage map of an apple rootstock progeny anchored to the Malus genome sequence

An apple rootstock progeny raised from the cross between the very dwarfing ??M.27?? and the more vigorous ??M.116?? (??M.M.106???×???M.27??) was used for the construction of a linkage map comprising a total of 324 loci: 252 previously mapped SSRs, 71 newly characterised or previously unmapped SSR loci (including 36 amplified by 33 out of the 35 novel markers reported here), and the self-incompatibility locus. The map spanned the 17 linkage groups (LG) expected for apple covering a genetic distance of 1,229.5?cM, an estimated 91% of the Malus genome. Linkage groups were well populated and, although marker density ranged from 2.3 to 6.2?cM/SSR, just 15 gaps of more than 15?cM were observed. Moreover, only 17.5% of markers displayed segregation distortion and, unsurprisingly in a semi-compatible backcross, distortion was particularly pronounced surrounding the self-incompatibility locus (S) at the bottom of LG17. DNA sequences of 273 SSR markers and the S locus, representing a total of 314 loci in this investigation, were used to anchor to the ??Golden Delicious?? genome sequence. More than 260 of these loci were located on the expected pseudo-chromosome on the ??Golden Delicious?? genome or on its homeologous pseudo-chromosome. In total, 282.4?Mbp of sequence from 142 genome sequence scaffolds of the Malus genome were anchored to the ??M.27???×???M.116?? map, providing an interface between the marker data and the underlying genome sequence. This will be exploited for the identification of genes responsible for traits of agronomic importance such as dwarfing and water use efficiency.     

中国大麦矮秆种质资源的基因分析——Ⅱ.矮秆基因的染色体定位

根据连锁遗传原理,利用全套染色体形态性状标记系,对２０份中国大麦矮秆种质资源的矮秆基因,进行了染色体定位。结果表明：１５份单基因矮秆中,有１份其矮秆基因与宽护颖基因Ｚ连锁,位于２（２Ｈ）染色体短臂上;１０份的矮秆基因与ｕｚ基因等位,由３（３Ｈ）长臂携带;４份的矮秆基因与钩芒基因Ｋ连锁,位于４（４Ｈ）长臂上。５份双基因矮秆中,有３份的矮秆基因分别位于２（２Ｈ）短臂和４（４Ｈ）长臂上;１份的矮秆基因各由其３（３Ｈ）和４（４Ｈ）长臂携带;其余１份的两对矮秆基因,１对与ｕｚ基因等位,由３（３Ｈ）长臂携带,另１对则与宽护颖基因ｗ连锁,位于２（２Ｈ）短臂之上。     

中国大麦矮秆种质资源的基因分析Ⅱ．矮秆基因的染色体定位

根据连锁遗传原理,利用全套染色体形态性状状标记系,对２０份中国大麦筹秆南资源的矮秆基因,进行了染色体定位,结果表明,１５份单基因矮杆中,有１份其矮秆基因与宽护颖基因w连锁,位于２（２Ｈ）染色体短臂上;１０份的矮秆基因与uz基因等等位,由３（３Ｈ）长臂携带;４份的矮秆基因与钩芒K ,锁位于４（４Ｈ）长臂上,５份双基因矮秆中,有３份的筹秆基因分别位于２（２Ｈ）短臂和４（４Ｈ）长 臂上;１份的筹秆基因各由其３（３Ｈ）和４（４Ｈ）长臂携带;其余１份的两对矮秆基因,１对与uz基因等位,由于３（３Ｈ）长臂携带,另１对则与宽护颖基因w连锁,位于２（２Ｈ）短臂之上。     

特矮稻ED基因的遗传定位和分析

赤霉素（GA3）鉴定表明,一种新型特矮稻（命名为‘特矮稻-2’）的GA3信号转导途径正常,施加外源GA3不能恢复到正常植株的高度,说明此种矮稻的矮化机制与GA3无关。来源于组合‘特矮稻-2’ב日本晴’的F2群体的遗传分析表明,‘特矮稻-2’的特矮性状受1对隐性基因控制。采用SSR分子标记,将该矮秆基因定位于第12染色体上的RM519和RM235标记之间,遗传距离分别为15.9和22.0cM,该基因暂命名为ED。     

Molecular mapping of genes for opposite leafing in maize using simple-sequence repeat markers

Maize with opposite phyllotaxy (OP) and also initiating ears in opposite pairs is an aberrant mutant and also precious material for maize breeding and plant evolution studies. Mapping and identifying the markers closely linked to genes for the OP trait are essential for cloning the gene and marker-assisted selection in breeding. We established H14D, a near-isogenic line of the OP trait with H53 genetic background. We found that the OP trait is regulated by two independent dominant genes with mutually complementary relations, named Opp-1 and Opp-2. Screening of seven simple-sequence repeat (SSR) markers among the 105 pairs of SSR primers showed polymorphism between the inbred lines H14D and H53. The polymorphic SSR markers were then used to determine linkage with the trait in an F(2) population with 441 progeny, suggesting that SSR marker umc2094 in the Bin2.01 region is linked with Opp-1 at 6.7 cM, and bnlg1831 in Bin2.06 is linked with Opp-2 at 6.1 cM. Further investigation showed that bnlg1092 and umc1028 are linked to Opp-1 and Opp-2 genes, with genetic distances of 12.2 and 1.9 cM. It was also found that the four SSR markers flank the two OP genes, respectively. These results will be useful for marker-assisted selection breeding of OP maize and will also strengthen the basis for cloning of the opposite leafing gene.     

Molecular mapping of two semidwarf genes in an indica rice variety Aitaiyin3 (Oryza sativa L.)

Genetic analysis established that Aitaiyin3,a dwarf rice variety derived from a semidwarf cultivar Taiyin1,carries two recessive semidwarf genes.By using simple sequence repeat(SSR)markers,we mapped the two semidwarf genes,sd-1 and sd-t2 on chromosomes 1 and 4,respectively.Sd-t2 was thus named because the semidrawf gene sd-t has already been identified from Aitaiyin 2 whose origin could be traced back to Taivin1.The result of the molecular mappingof sd-1 gene revealed it is linked to four SSR markers found on chromosome 1.These markers are:RM297,RM302,RM212,and OSR3 spaced at 4.7 cM,0 cM,0.8cM and 0 cM,respectively.Sd-t2 was found to be located on chromosome 4 using five SSR markers:two markers,SSR332 and RM1305 located proximal to sd-t2 are spaced 11.6 cM,3.8 cM,respectively,while the three distally located primers,RM5633,RM307,and RM401 are separated by distances of 0.4 cM,0.0 cM,and 0.4 cM,respectively.     

A comparison of genetic maps constructed from haploid and BC1 mapping populations from the same crossing between Gossypium hirsutum L. and Gossypium barbadense L.

Simple sequence repeat (SSR) genetic maps have been separately constructed based on doubled haploid (DH) and (or) haploid and BC1 populations from the same cross between Gossypium hirsutum L. 'TM-1' and Gossypium barbadense L. 'Hai7124'. The BC1 population was produced by pollinating individual plants of the 'TM-1' x 'Hai7124' F1 with 'TM-1', whereas the DH and (or) haploid population developed from the offspring of Vsg x ('TM-1' x 'Hai7124'). Vsg is a virescently marked semigamy line of Gossypium barbadense L. Pima. The BC1 map included 34 linkage groups with an average distance between markers of 9.80 cM (Kosambi, K) and covered 4331.2 cM (K) or approximately 78.7% of the tetraploid cotton genome constructed using 440 SSR and 2 morphological marker genes. Among them, 26 were assigned to 20 chromosomes, 7 to A or D subgenomes, and 1 was unassigned. The haploid map comprised 444 SSR markers mapped to 40 linkage groups with an average distance of 7.35 cM (K) between markers, covering 3262.9 cM (K) or approximately 60.0% of the tetraploid genome. Twenty-nine linkage groups were assigned to all 19 identified chromosomes, 10 to A or D subgenomes, and 1 was unassigned. Fairly good collinearity of marker order was observed along most of the chromosomes or linkage groups. Significant differences in recombination between maps was observed at the chromosomal and genomic level and possible reasons were discussed. Map comparison and combined data provided an essential basis for further mapping of interested genes and QTLs and for studies of diversity, population structure, and phylogeny in Gossypium species.     

小麦“BS20×Fu3”DH群体SSR遗传图谱的构建及不育基因的QTL定位

以小麦光温敏核雄性不育系BS20×Fu3双单倍体(DH)群体的289个系为材料,从1112对SSR和EST-SSR引物中筛选出多态性引物243对,利用其中128个SSR和6个EST-SSR标记构建遗传连锁图谱,该图谱覆盖长度为2749.2 c M,分布在小麦的19个连锁群(除4D、6A),不同连锁群标记数为2~15个,长度在15.3~244.4 c M之间,平均长度为144.7 c M,标记之间平均遗传距离为17.4 c M。同时构建3个DNA池(包括恢复池、北京不育池和阜阳不育池),用分离群体分组分析法(BSA)对育性进行分析,筛选出的多态性引物为Wmc264、Wmc73、Xgwm350,分布在3A、5B、2A/7D染色体上。同时用混合线性复合区间作图法(MCIM)对育性进行QTL分析,当F7.5时,检测到6个主效QTL,用复合区间作图法(CIM)对育性进行QTL分析,当LOD值2.5时,共检测到13个主效QTL,两种方法检测到一致的QTL有3个,分别为1BL的Wmc365-cfa2129、2BS的Wmc602-Xgwm148和3AL的Wmc264a-cfa2262区间的QTL。综合BSA和QTL的结果,位于1BL、2BS和3AL上的小麦光温敏不育基因是真实的。     

Molecular mapping of two semidwarf genes in an indica rice variety Aitaiyin3 (Oryza sativa L.)

Genetic analysis established that Aitaiyin3, a dwarf rice variety derived from a semidwarf cultivar Taiyin1, carries two recessive semidwarf genes. By using simple sequence repeat (SSR) markers, we mapped the two semidwarf genes, sd-1 and sd-t2 on chromosomes 1 and 4, respectively. Sd-t2 was thus named because the semidrawf gene sd-t has already been identified from Aitaiyin 2 whose origin could be traced back to Taiyin1. The result of the molecular mapping of sd-1 gene revealed it is linked to four SSR markers found on chromosome 1. These markers are: RM297, RM302, RM212, and OSR3 spaced at 4.7 cM, 0 cM, 0.8cM and 0 cM, respectively. Sd-t2 was found to be located on chromosome 4 using five SSR markers: two markers, SSR332 and RM1305 located proximal to sd-t2 are spaced 11.6 cM, 3.8 cM, respectively, while the three distally located primers, RM5633, RM307, and RM401 are separated by distances of 0.4 cM, 0.0 cM, and 0.4 cM, respectively. __________ Translated from Acta Genetica Sinica, 2005, 32 (2) [译自: 遗传学报, 2005,32(2)]