药用野生稻抗褐飞虱基因的RAPD标记研究

以药用野生稻1665(O.officinals)和栽培稻桂99远缘杂交的抗褐飞虱近等基因系B3F4分离群体为材料,利用随机引物对其抗褐飞虱基因进行了RAPD标记研究,获得3个与抗褐飞虱基因表现连锁的RAPD分子标记(S229703、S403783和S11591408)。采用MAPMAKER/EXP.Version 3.0分析,结果表明3个RAPD分子标记与抗褐飞虱基因属于同一连锁群,覆盖大小为18.1cm,标记间平均距离为4.53cm,为下一步水稻抗褐飞虱基因的精确定位和克隆奠定坚实的基础。     

小麦品种Triticum spelta album中抗条锈病基因Yr5的RAPD标记

共用520个10碱基随机引物对小麦抗条锈基因Yr5的近等基因系进行了RAPD分析,发现了3个特异性DNA片段S1496、S14181950与Yr5基因连锁,其中S1496761与Yr5基因紧密连锁,遗传距离为2．7cM。经对特异性DNA片段S1496 761进行克隆,测序,设计了PCR扩增用专化引物SC－S1496 761a和SC－S149676b,用该引物可扩增出与原RAPD引物扩增出的相似的特异DNA片段,由于该引物还可扩增出迁移率极为相近的另1条非特异带,在琼脂糖凝胶上难以分辨,需用聚丙烯酰胺凝胶电泳结合银染进行检测,经用F2分离群体及部分相关品种材料检测,已证明该标记的可靠性。     

小麦农家品种红麦(京2747)主效抗条锈病基因的RAPD标记

小麦农家品种红麦(京2747)可抗中国小麦条锈菌多个生理小种。遗传分析表明,该品种对于小麦条锈菌条中19号生理小种的抗性由1对显性基因控制。本研究采用铭贤169×红麦的F2分离群体建立抗、感DNA池,用RAPD方法进行DNA多态性分析。共筛选236个10碱基随机引物,其中引物S1167所扩增出的1条约245 bp的多态性DNA片段只出现在抗病DNA池和红麦中,而不出现在感病DNA池和感病品种铭贤169中。经用201株杂交F2植株对多态性DNA片段S1167245与目的基因的遗传连锁性进行分析,在164株抗病单株中有156株可稳定扩增出该特异DNA片段,而在37株感病单株中则有34株不能扩增出该特异DNA片段,经统计共有11株发生了交换,标记S1167245与目的抗病基因间的遗传距离为6.1cM。本研究得到的RAPD标记S1167245表现稳定、重复性强,可用于小麦抗锈育种中的标记辅助选择,促进红麦的抗条锈基因的利用。     

与苹果Co基因紧密连锁的RAPD标记的筛选及其SCAR标记转换

以短枝富士(Spur Fuji)X舞姿(Telamon)的105株F1群体为试材,利用RAPD技术,结合集群分类分析法(BSA)进行了苹果柱型基因(Co)分子标记的研究。通过对300条随机引物的筛选,获得一个与Co基因紧密连锁的RAPD标记S1142682,连锁距离为2．86cM。对该标记片段进行序列测定,然后根据序列特点设计了4条特异引物(其中正向引物与反向引物各两条)。PCR结果显示,这4条引物的4种组合都可以扩增出柱型性状的特征带。选其中之一进行群体上的分析,结果表明该SCAR标记特征带与柱型性状的共分离行为与原RAPD标记表现一致。可见,此组合的引物可以作为该SCAR标记的特异引物。通过对S1142682标记片段序列分析发现,在 45～ 251区域含有一个可编码68个氨基酸残基的ORF。     

大麻性别的RAPD和SCAR分子标记

利用随机扩增多态性DNA（random amplified polymorphic DNA,RAPD)技术获得与大麻性别连锁的分子标记,将10株雄性大麻或10株雌性麻的单个DNA样品等量混合分别组成雄性或雌性DNA池（DNApool),以提供具有相同遗传背景的雄,雄性DNA样品。每个随机引物分别用三个不同的循环程序进行PCR扩增,在30个随机引物中,用引物S401扩增得到一条约2．5kb雄性多态性片段,对该片段进行了克隆和序列分析 ,并根据序列分析结果将上述RAPD分子标记转化为重复性和特异性更好的SCAR（Sequence characterized amplified regions)分子标记。     

家蚕抗核型多角体病分子标记筛选

对家蚕抗核型多角病毒病以不同的杂交方式,构建3种近等基因系,用RAPD技术筛选出抗病主基因连锁分子标记OPA-18700和感病连锁分子标记OPY-11400。同时在F2群体中验证了抗性分子标记的有效性。     

小麦条锈菌鉴别寄主抗条锈病基因Yr9的微卫星标记

以含有Yr9的抗条锈病近等基因系Taichung29＊6／Yr9及其轮回亲本Taichung29为材料,用目的基因所在1B染色体上32对微卫星引物对其基因组DNA进行PCR扩增,发现引物Xgwm582在近等基因系与轮回亲本间可扩增出特异性DNA片段。经F2代分离群体177个抗、感单株检测证实,该片段位点与抗条锈病基因Yr9紧密连锁,遗传距离为3．7cM,确定Xgwm582可作为抗条锈病基因Yr9的标记。     

大麻性别的RAPD和SCAR分子标记

利用随机扩增多态性DNA(randomamplifiedpolymorphicDNA,RAPD)技术获得与大麻性别连锁的分子标记.将10株雄性大麻或10株雌性大麻的单个DNA样品等量混合分别组成雄性或雌性DNA池(DNApool),以提供具有相同遗传背景的雌、雄性DNA样品.每个随机引物分别用三个不同的循环程序进行PCR扩增.在30个随机引物中,用引物401扩增得到一条约2.5kb雄性多态性片段.对该片段进行了克隆和序列分析,并根据序列分析结果将上述RAPD分子标记转化为重复性和特异性更好的SCAR(sequencecharacterizedamplifiedregions)分子标记.     

谭清苏铁性别连锁的RAPD和SCAR分子标记

利用RAPD(Random amplified polymorphic DNA)分子标记技术,寻找谭清苏铁（Cycas tanqingii）中与性别相关的分子标记,筛选了160个10bp的随机引物,产生了2500多个RAPD条带。只有引物S0465 (CCCCGGTAAC)产生了一条大约500bp的雌性特异RAPD标记,该分子标记出现在所有的供试雌性植株中,而所有的供试雄性植株都不具有该标记。对该特异片段进行了克隆和序列测定,并根据序列分析结果将RAPD标记转化为重复性和特异性更好的特异特征序列扩增区域（SCAR）分子标记,并命名为STQC-S465-483。分子标记的建立可用于谭清苏铁幼苗性别的早期鉴定,为谭清苏铁就地保护和迁地保护提供技术支持。     

谭清苏铁性别连锁的RAPD和SCAR分子标记

利用RAPD(Random amplified polymorphicDNA)分子标记技术,寻找谭清苏铁(Cycas tanqingii)中与性别相关的分子标记,筛选了160个10bp的随机引物,产生了2500多个RAPD条带。只有引物S0465(CCCCGGTAAC)产生了一条大约500bp的雌性特异RAPD标记,该分子标记出现在所有的供试雌性植株中,而所有的供试雄性植株都不具有该标记。对该特异片段进行了克隆和序列测定,并根据序列分析结果将RAPD标记转化为重复性和特异性更好的特异特征序列扩增区域(SCAR)分子标记,并命名为STQC-S465-483。分子标记的建立可用于谭清苏铁幼苗性别的早期鉴定,为谭清苏铁就地保护和迁地保护提供技术支持。     

Inheritance and Mechanism of Resistance to Rice Stripe Disease in cv. Zhendao 88, a Chinese Rice Cultivar

Mechanisms of resistance to rice stripe disease in a Chinese rice cultivar (Oryza sativa L., cv. Zhendao 88) were determined, and molecular markers for the resistance gene were identified. Single tillers at the seedling stage were inoculated with Rice stripe virus (RSV) and its vector, the small brown planthopper (SBPH) Laodelphax striatellus Fallen, to test for non‐preference and antibiosis. The inheritance of resistance in the F₂ and F_{2 : 3} lines from the cross cvs Zhendao 88× Wuyujing No. 3 was also examined by single‐tiller inoculation. Cv. Zhendao 88 was highly resistant to RSV and weakly resistant to SBPH. The resistance gene was mapped by SSR and RAPD analyses to rice chromosome 11 within 4.7 cm of a SSR marker RM229 and a RAPD marker OPO11. Data and inheritance analysis indicated that rice stripe disease resistance in cv. Zhendao 88 was derived principally from resistance to RSV and controlled by a single dominant gene. Breeding for rice stripe resistance could be accelerated by using cv. Zhendao 88 as a resistant parent if the linked marker for virus resistance were used in a marker‐assisted progeny selection programme.     

利用分子标记定位农垦58S的光敏核不育基因

对农垦５８Ｓ（Ｏｒｙｚａｓａｔｉｖａｓｐ．ｊａｐｏｎｉｃａ）／大黑矮生标记基因系ＦＬ２组合组建可育集团和不育集团,并以亲本为对照进行了ＲＦＬＰ、ＲＡＰＤ和双引物ＲＡＰＤ分析,结果第１２染色体上的一个单拷贝标记Ｇ２１４０与光敏核不育基因连锁遗传,二者间的遗传图距为１４．１ｃＭ（ｃｅｎｔｉｍｏｒｇａｎ）。在筛选过的１０４０个随机单引物和１９０个双引物中,仅引物ＯＰＡＵ１０扩增出与光敏核不育基因连锁的１．５ｋｂＤＮＡ片段,回收、克隆该ＤＮＡ片段并制备探针,将其转换成共显性的ＲＦＬＰ标记并命名为ＯＰＡＵ１０１５００。分离群体连锁分析表明该标记与标记Ｇ２１４０紧密连锁,将农垦５８Ｓ的一对光敏核不育基因定位于第１２染色体上。     

SCAR标记在茶树种质资源鉴定中的应用

SCAR标记是一种在RAPD技术的基础上发展起来的新型分子标记技术,提高了分子标记辅助选择育种的效率,在茶树种质资源的合理开发与利用中具有广阔的应用前景.运用优化后的RAPD反应体系对10个茶树品种的基因组DNA进行遗传差异分析,随机引物S89、S4分别在白毫早和福云6号中扩增得到长度为498 bp、1 622 bp的差异片段,命名为BHZ498、FY1622.根据它们的测序结果分别设计了一对特异引物,BHZ498的特异引物为SB1/SB2;FY1622的特异引物为SC1/SC2,用这两对特异引物对10个茶树品种的基因组DNA进行扩增.引物SB1/SB2和SC1/SC2分别在白毫早和福云6号中扩增出唯一的一条扩增带,而这两对引物在其他供试茶树材料中均无相应的扩增带,结果表明已将BHZ498、FY1622标记成功转化成SCAR标记.     

RAPD技术在微生物生物多样鉴定中的应用

RAPD（随机放大多态性DNA）是1种新的DNA分子标记技术。与RFLp、AFLP及ARDRA相比,RAPD具有可在一次试验中同时观察到大量的DNA多态性片段,方法更具简单、敏感、花费少等优点。阐述了RAPD的原理方法,及目前在微生物分类鉴定研究中的应用,并分析了RAPD技术在共生固氮放线菌Frankia分类鉴定及系统发育研究中的应用前景。     

山羊经济性状标记辅助选择的遗传效应分析

本研究以辽宁绒山羊、柴达木绒山羊和柴达木山羊3个群体共147只山羊为研究对象,运用PAGE和RAPD技术对山羊的体重、绒产量和绒细度3个性状进行了与标记基因关系的遗传分析,结果表明：EsD2-2型、LAPBB型和PA-32-2型分别为体重、绒产量和绒细度性状的优势标记基因型;可利用标记辅助预测的方法充分利用多基因座标记基因间的互作效应;在体重上,寻找到有显著选择效应的RAPD条带11个,在绒产量和绒细度上分别为9和6个;在多目标性状选择中,CY0818/A0型和OPW19/C1型为体重和绒产量的双重优势RAPD标记,CY0818/G1型为体重和绒细度的双重优势RAPD标记。Abstract: The genetic relationships between economic traits and genetic markers were studied in 147 goats including Chaidamu goat (CS), Chaidamu Cashmere goat (CRS) and Liaoning Cashmere goat (LRS) in Qinghai province, China. CRS was the population of CS×LRS crossbred. The results showed as follows: the selection reaction of these blood protein polymorphisic loci were great, such as EsD, LAP and PA-3; and EsD2-2, LAPBB and PA-32-2 were the superior marker genotypes on body weight ,Cashmere yield and Cashmere fineness respectively by Least Square method. The interaction between marker genotypes at double loci was found frequently, and their ratio between interaction variance component and genetic variance was higher. With the method of marker assisted prediction( MAP), some interaction effect could be used effectively in the crossbreed population. On the aspect of random amplified polymorphic DNA (RAPD), the number of the superior RAPD marker bands were 11 on body weight trait, 9 and 6 RAPD marker bands on Cashmere yield and Cashmere fineness. For multi-goal traits, CY0818/A0 type and OPW19/C1 type were superior RAPD markers of body weight and Cashmere yield, CY0818/G1 type was superior one of body weight and Cashmere fineness.     

葡萄感霜霉病基因的分子标记(英文)

 在葡萄抗病育种中 ,幼苗期排除感霜霉病的后代具有特别重要的意义 .用 BSA,RAPD和SCAR方法研究了葡萄感霜霉病基因的分子标记 .分析了两个种间杂交组合 [毛葡萄 (抗病 )×欧洲葡萄 (感病 ) ]88- 1 1 0和 88- 84与 88- 1 1 0的 F1代自交或互交所得的 3个 F2 代 ,以及欧洲葡萄品种和中国野生葡萄种 .共筛选了 2 80个随机引物 .引物 OPO1 0产生了一个 RAPD标记 OPO1 0 - 80 0与葡萄感霜霉病主效基因紧密联锁 .将该 DNA片段克隆并测序 .OPO1 0 - 80 0的实际长度为 835bp,所以 OPO1 0 - 80 0应为 OPO1 0 - 835.据其两端序列 ,设计了一对长度为 2 6bp和 2 8bp的特异引物分别扩增上述试材 ,获得了与该 RAPD标记相同大小的一条带 ,将 RAPD标记转化为 SCAR标记SCO1 0 - 835.并证实了此 SCAR标记的通用性 ,该 SCAR标记可用于葡萄抗病育种中杂种后代对霜霉病的抗病与感病性鉴定 .     

SCAR分子标记技术在香菇菌株鉴定上的应用研究

为了建立一套基于DNA分子标记技术快速鉴定香菇菌株的有效方法,本研究首先通过对生产上常用的14个香菇菌株进行RAPD多态性分析,从香菇菌株162中扩增获得了一个片段长为1166bp的特异RAPD标记XG1166,随之利用分子克隆技术将该特异RAPD标记成功转化为稳定的SCAR标记。用同样的方法,本研究又从另一香菇菌株申香10号中获得了一段长度为347bp的特异SCAR标记SX347。试验结果表明,利用本研究获得的香菇菌株162和申香10号的特异SCAR标记,能在一天时间内准确鉴定出香菇菌株162或申香10号菌株的真伪。由此可见,SCAR分子标记是一种快速、稳定、准确鉴定香菇菌株的新方法, 可应用于食用菌种质资源保护利用、品种分类与鉴定和假种辨别。     

Identification,cloning and sequence analysis of a dwarf genome-specific RAPD marker in rubber tree [<Emphasis Type="Italic">Hevea brasiliensis</Emphasis> (Muell.) Arg.]

High-yielding dwarf clones of Hevea brasiliensis are tolerant to wind damage and therefore useful for high-density planting. The identification of molecular markers for the dwarf character is very important for isolating true-to-type high-yielding dwarf hybrid lines in the early stage of plant breeding programs. We have identified a dwarf genome-specific random amplified polymorphic DNA (RAPD) marker in rubber tree. A total of 115 random oligonucleotide 10-mer primers were used to amplify genomic DNA by PCR, of which 19 primers produced clear and detectable bands. The primer OPB-12 generated a 1.4-kb DNA marker from both natural and controlled F₁ hybrid progenies (dwarf stature) derived from a cross between a dwarf parent and a normal cultivated clone as well as from the dwarf parent; it was absent in other parent (RRII 118). To validate this DNA marker, we analyzed 22 F₁ hybrids (13 with a dwarf stature and nine with a normal stature); the dwarf genome-specific 1.4-kb RAPD marker was present in all dwarf-stature hybrids and absent in all normal-stature hybrids. This DNA marker was cloned and characterized. DNA marker locus specificity was further confirmed by Southern blot hybridization. Our results indicate that Southern blot hybridization of RAPD using probes made from cloned DNA fragments allows a more accurate analysis of the RAPD pattern based on the presence/absence of specific DNA markers than dye-stained gels or Southern blot analysis of RAPD blots using probes made from purified PCR products. Detection of RAPD markers in the hybrid progenies indicates that RAPD is a powerful tool for identifying inherited genome segments following different hybridization methods in perennial tree crops.     

Conversion of an RAPD marker to an STS marker for barley variety identification

Barley (Hordeum vulgare L.) variety identification is important to the malting and brewing industries. Because many new malting cultivars (varieties) are closely related, new and more effective identification techniques are needed. We report on a series of techniques used to convert an RAPD marker to a more stable STS marker that can identify barley Stander from Robust, an important distinction for the American malting and brewing industries. The techniques included DNA extraction, RAPD amplification, random cloning of all amplified fragments, selection of clones by insert size, DNA sequencing of select inserts, design of a barley-based primer pair, and detection of a single nucleotide polymorphism using restriction endonucleaseAlu I. The barley-based primer pair was used to further sequence the RAPD fragment. Five single nucleotide polymorphisms between Robust and Stander exist, one of which was detected by electrophoresing DNA fragments differentially restricted byAlu I. The conversion technique was different from ones previously reported in that it did not require manual extraction of DNA fragments from a gel. This could be applied to other situations in which RAPD marker conversion would be desirable.