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1.
青海大黄油菜粒色性状分子标记的开发和图谱整合 总被引:2,自引:1,他引:1
利用青海大黄油菜和褐籽白菜型油菜09A-126构建BC4和F2分离群体, 结合AFLP与群体分离分析法(bulked segregant analysis, BSA)筛选引物, 获得5个与黄籽基因Brsc1紧密连锁的分子标记Y11~Y15。5个AFLP特异片段的序列, 均与白菜型油菜的A9染色体部分序列表现同源。将5个AFLP标记成功转化为5个SCAR标记(SC11~SC15)。利用目标基因所在染色体区段序列筛选到7个与目标基因紧密连锁的SSR标记(BrID10607、KS10760、B089L03-3和A1~A4)。利用SCAR和SSR标记扫描F2群体中部分单株, 发现SC14和A1为共显性标记。用BC4群体将Brsc1定位在标记Y06和A4之间1.7 Mb的区间内, 遗传距离分别为0.115 cM和0.98 cM。标记Y05和Y12与Brsc1共分离。本研究为黄籽油菜分子标记辅助选择育种体系的建立及目标基因的进一步精细定位和图位克隆奠定了基础。 相似文献
2.
芥菜型油菜黄籽性状的遗传、基因定位和起源探讨 总被引:6,自引:1,他引:5
油菜种皮颜色既是一个形态指示性状, 又与种子休眠和品质有关。以芥菜型油菜种皮颜色分离的2个BC6F2群体为作图群体,用微卫星(SSR)等标记进行连锁定位, 并用定位标记对22份材料进行关联分析, 通过反转录-聚合酶链反应(RT-PCR)分析12份材料种皮中4-二氢黄酮醇还原酶(DFR)、花色素合酶(ANS)和花色素还原酶(ANR)基因的表达, 对6份黄籽材料的种皮颜色基因等位性进行测定, 结果将芥菜型油菜控制种皮颜色的2个基因位点分别定位到A9和B3连锁群, 并找到其两侧紧密连锁标记, 发现黄籽材料种皮颜色基因位点附近0.9 cM和1.5 cM区域高度保守, 所有黑色种皮中DFR、ANS和ANR基因均表达, 所有黄色种皮中DFR和ANS均不表达,但ANR基因表达或不表达,黄籽材料的种皮颜色基因等位。根据这些结果结合前人研究, 认为芥菜型油菜种皮颜色基因是调控基因,黄籽为单一起源。 相似文献
3.
大黄油菜是源于青海湟源的地方品种,种皮颜色鲜黄,其大黄油菜的黄籽性状受1对隐性基因(Brsc1)控制,该基因被定位于白菜A9染色体上一段1.7 Mb的区间内。为了更好地利用这一黄籽资源,对Brsc1基因进一步精细定位。利用青海大黄油菜和褐籽白菜型油菜09A-126构建BC4及F2分离群体。利用白菜同源区段内已公布的SSR标记,同时利用该区段序列信息开发新的SSR引物,共获得6个与目标基因紧密连锁的标记(Br ID10711、Br A5~Br A9),其中Br A5与目标基因共分离,Br A9为一侧最近标记,它与目标基因之间的遗传图距为0.69 c M。至此,Brsc1基因进一步被限定于标记Y06和Br A9之间约1.2 Mb的区间内。利用本研究中获得的标记检测F2群体中3种类型单株,鉴定出一个共显性标记Br A8。将本研究中获得的SSR标记与前人研究结果进行整合,加密了Brsc1基因所在区间的标记密度。同时,特异片段与拟南芥基因组进行序列比对的结果表明,共有5个标记与拟南芥的第1染色体有较好的共线性关系,暗示Brsc1基因的同源基因可能位于拟南芥的第1染色体上。本研究中获得的标记将为Brsc1基因的克隆及利用Brsc1基因进行黄籽油菜的分子辅助育种提供有利条件。 相似文献
4.
普通小麦品种Brock抗白粉病基因分子标记定位 总被引:4,自引:2,他引:2
为明确利用Brock转育成的小麦抗白粉病品系3B529(京411*7//农大015/Brock, F6)抗性的遗传基础,将高感白粉病小麦品系薛早和3B529杂交,获得F1代、F2分离群体和F2:3家系。抗病性鉴定和遗传分析结果表明,3B529对E09小种的抗性受1对显性基因控制,暂被定名为MlBrock。利用BSA和分子标记分析,获得了与MlBrock连锁的3个SSR标记Xcfd81、Xcfd78、Xgwm159和2个SCAR标记SCAR203和SCAR112,根据SSR和SCAR标记在中国春缺体四体、双端体和缺失系的定位结果,将MlBrock定位在小麦染色体臂5DS Bin 0~0.63区间上。MlBrock与Xcfd81和SCAR203共分离,与SCAR112的遗传距离为0.5 cM。这些分子标记的建立有利于今后Brock抗白粉病基因分子标记辅助选择和基因聚合。综合抗白粉病基因MlBrock的染色体定位和抗谱分析结果,推测MlBrock很可能是Pm2基因。 相似文献
5.
芥菜型多室油菜的产量比普通两室油菜更高,定位乃至克隆多室基因可为油菜遗传改良及解释多室角果形成机制创造条件。本研究通过验证JD11-2家系衍生群体仅在BjMc2位点上存在差异,可用于BjMc2的定位。采用AFLP结合BSA法分析BC5和BC6群体,筛选到1个与BjMc2连锁的AFLP标记并转化为SCAR标记SC1。基于该AFLP标记序列信息,利用白菜同源序列设计SSR引物和SCAR引物,获得11对SSR标记和1对SCAR标记。通过在芥菜型油菜BAC文库中的挑选,获得2个覆盖目标区域的单克隆,由此开发1个SSR标记。将获得的SCAR和SSR标记扫描BC7群体,构建了两室性状基因BjMc2的遗传连锁图,两侧最近标记ZX17和BACsr96与目标基因之间的遗传距离分别为0.048 cM和0.340 cM,并定位到白菜A7 scaffold000019的946~1014 kb之间,约68 kb物理距离。 相似文献
6.
Juthaporn Khampila Kamol Lertrat Weerasak Saksirirat Jirawat Sanitchon Nooduan Muangsan Piyada Theerakulpisut 《Euphytica》2008,164(3):615-625
Exserohilum turcicum causes northern corn leaf blight (NCLB), an important disease occurring in maize producing areas throughout the world. Currently,
the development of cultivars resistant to E. turcicum seems to be the most efficient method to control NCLB damage. Marker-assisted selection (MAS) enables breeders to improve
selection efficiency. The objective of this work was to identify random amplified polymorphic DNA (RAPD) and sequence characterized
amplified region (SCAR) markers associated with NCLB resistance. Bulked segregant analysis (BSA) was used to search for RAPD
markers linked to NCLB resistance genes, using F2 segregating population obtained by crossing a susceptible inbred ‘209W’ line with a resistant inbred ‘241W’ line. Two hundred
and twenty-two decamer primers were screened to identify four RAPD markers: OPA07521, OPA16457, OPB09520, and OPE20536 linked to NCLB resistance phenotype. These markers were converted into dominant SCAR markers: SCA07496, SCA16420, SCB09464, and SCE20429, respectively. The RAPD and SCAR markers were developed successfully to identify NCLB resistant genotypes in segregating
progenies carrying NCLB resistant traits. Thus, the markers identified in this study should be applicable for MAS for the
NCLB resistance in waxy corn breeding programs. 相似文献
7.
Rye (Secale cereale L. and S. strictum) offers potential to increase the genetic variability and to introduce desirable characters for wheat improvements. Cytogenetic
techniques have been used to screen wheat lines containing rye chromatin. These techniques are not adequate since they are
highly technical and time consuming. They are not suitable for breeding programs that require rapid screening of large numbers
of genotypes. The main objective of this study was to develop and characterize ISSR and SCAR markers that can distinguish
wheat from rye genome. Total DNA from wheat, rye, and triticale accessions from different provenances were amplified with
ISSR primers in PCR assays. Three wheat-diagnostic sequences were identified. In addition three rye-diagnostic ISSR markers
of which, one marker specifically diagnostic for Secale strictum were characterized. Pairs of primers flanking these specific sequences were designed to produce SCAR markers. Two SCAR markers
were rye genome-specific. One SCAR was present in all the seven rye chromosome, and another was specific to rye chromosomes
two, three, four, and seven. These newly developed ISSR and SCAR markers should be useful to wheat breeders screening genotypes
that may contain rye chromatins. 相似文献
8.
水稻早衰突变体esl5的鉴定及其基因精细定位 总被引:1,自引:0,他引:1
叶片早衰直接影响作物产量和品质, 鉴定早衰突变体、图位克隆调控基因对于研究植物衰老机理具有重要的意义。以甲基磺酸乙酯诱变水稻籼型恢复系缙恢10号, 获得一个早衰突变体esl5 (early senescent leaf mutant 5), 本文对其进行了形态鉴定、细胞学观察、理化分析和基因定位等研究。结果表明, 与野生型相比, esl5的苗期叶片正常, 分蘖期呈黄绿色, 孕穗期开始叶片中上部逐渐黄化衰老; 衰老部位的细胞结构异常, 细胞膜降解, 叶绿体基质片层疏松、排列不规则, 光合色素含量和光合速率极显著下降。此外, esl5的·OH和H2O2含量极显著升高, SOD和CAT的活性则极显著降低。与野生型相比, esl5的生育期延长了20 d左右, 千粒重显著增加, 穗粒数、实粒数和结实率则显著降低。esl5受1对隐性核基因调控, 精细定位在第3染色体Indel标记Indel03-1和Indel03-2之间83.4 kb的物理范围内, 包含11个注释基因, 这为ESL5的克隆和功能研究奠定了基础, 也有利于水稻品种的遗传改良。 相似文献
9.
Molecular mapping of Aegilops speltoides derived leaf rust resistance gene Lr28 in wheat 总被引:2,自引:0,他引:2
Durga Prasad Cherukuri Sudhir Kumar Gupta Ashwini Charpe Sunita Koul Kumble Vinod Prabhu Ram Badan Singh Qazi Mohammad Rizwanul Haq 《Euphytica》2005,143(1-2):19-26
In a segregating homozygous F2 population of bread wheat involving a leaf rust resistance gene Lr28 derived from Aegilops speltoides, six randomly amplified polymorphic DNA (RAPD) markers, three each in coupling and repulsion phase were identified as linked to Lr28, mapped to a region spanning 32 cM including the locus. The F2 and F3 populations were studied in the phytotron challenged with the most virulent pathotype 77-5 of leaf rust. A coupling phase linked RAPD marker S464721 and a repulsion phase linked RAPD marker S326550 flanked the gene Lr28 by a distance of 2.4± 0.016 cM on either side. The flanking markers genetically worked as co-dominant markers when analyzed together after separate amplification in the F2 population by distinguishing the homozygotes from the heterozygotes and increased the efficiency of marker assisted selection by reducing the false positives and negatives. One of the three RAPD markers, S421640 was converted to locus specific SCAR marker SCS421640 which was further truncated by designing primers internal from both ends of the original RAPD amplicon to eliminate a non-specific amplification of nearly same size. The truncated polymorphic sequence characterized amplified region marker (TPSCAR) SCS421570 was 70 bp smaller, but resulted in a single band polymorphism specific to Lr28 resistance. The TPSCAR marker was validated for its specificity to the gene Lr28 in nine different genetic backgrounds and on 43 of the 50 Lr genes of both native and alien origin, suggesting the utility of the SCAR markers in pyramiding leaf rust resistance genes in wheat. 相似文献
10.
11.
X. L. Zhou D. J. Han H. L. Gou Q. L. Wang Q. D. Zeng F. P. Yuan G. M. Zhan L. L. Huang Z. S. Kang 《Euphytica》2014,196(2):251-259
Stripe rust (or yellow rust), caused by Puccinia striiformis f. sp. tritici, is one of the most destructive diseases of wheat worldwide. Growing resistant cultivars is the best approach to control the disease. To identify and map genes for stripe rust resistance in wheat cultivar ‘Wuhan 2', an F2 population was developed from a cross between the cultivar and susceptible cultivar Mingxian 169. The parents, 179 F2 plants and their derived F2:3 lines were evaluated for responses to Chinese races CYR30 and CYR31 of the pathogen in a greenhouse. A recessive gene for resistance was identified. DNA bulked segregant analysis was applied and resistance gene analog polymorphism (RGAP) and simple sequence repeat (SSR) techniques were used to identify molecular markers linked to the resistance gene. A genetic map consisting of five RGAP and six SSR markers was constructed. The recessive gene, designated Yrwh2, was located on the short arm of chromosome 3B and flanked by SSR markers Xwmc540 and Xgwm566 at 5.9 and 10.0 cM, respectively. The chromosomal location of the resistance gene and its close marker suggest that the locus is different from previously reported stripe rust resistance genes Yr30, QYr.ucw-3BS, Yrns-B1, YrRub and QYrex.wgp-3BL previously mapped to chromosome 3B. Yrwh2 and its closely linked markers are potentially useful for developing stripe rust resistance wheat cultivars if used in combination with other genes. 相似文献
12.
小麦品系5R625苗期和田间均对小麦叶锈病有良好抗性,但其所携带的抗病基因还不清楚。利用36个携带已知抗叶锈病基因的对照品系和15个中国小麦叶锈菌小种对5R625携带的抗病基因进行了苗期人工接种鉴定和基因推导,结果 5R625对这15个叶锈菌生理小种的侵染型与Lr9、Lr19、Lr24、Lr28、Lr39、Lr47、Lr51、Lr53相同。利用5R625和感病品种郑州5389的杂交后代F1、F2和F2:3群体对5R625的抗病性进行了遗传分析,苗期和成株期的分析结果均表明5R625对小麦叶锈菌的抗性由1个显性基因控制。进一步利用F2:3家系和分子标记方法将该基因定位在3DL染色体上。与5R625携带的抗病基因连锁的5个分子标记中,STS标记24-16和SCAR标记OP-J09此前已经被证明与已知抗叶锈病基因Lr24共分离,因此,推测5R625携带的抗病基因与Lr24可能为同一基因。 相似文献
13.
Jin Liu Jiayu Wang Xiaoyun Yao Yu Zhang Jinquan Li Xiaoxue Wang Zhengjin Xu Wenfu Chen 《Breeding Science》2015,65(2):161-169
Chlorophyll content is one of the most important traits controlling crop biomass and economic yield in rice. Here, we isolated a spontaneous rice mutant named thermo-sensitive chlorophyll deficit 1 (tscd1) derived from a backcross recombinant inbred line population. tscd1 plants grown normally from the seedling to tiller stages showed yellow leaves with reduced chlorophyll content, but showed no significant differences after the booting stage. At temperatures below 22°C, the tscd1 mutant showed the most obvious yellowish phenotype. With increasing temperature, the yellowish leaves gradually turned green and approached a normal wild type color. Wild type and tscd1 mutant plants had obviously different chloroplast structures and photosynthetic pigment precursor contents, which resulted in underdevelopment of chloroplasts and a yellowish phenotype in tscd1. Genetic analysis indicated that the mutant character was controlled by a recessive nuclear gene. Through map-based cloning, we located the tscd1 gene in a 34.95 kb region on the long arm of chromosome 2, containing two BAC clones and eight predicted candidate genes. Further characterization of the tscd1 gene is underway. Because it has a chlorophyll deficit phenotype before the tiller stage and little influence on growth vigor, it may play a role in ensuring the purity of hybrids. 相似文献
14.
Novel male-specific molecular markers (MADC5, MADC6) in hemp 总被引:8,自引:0,他引:8
Ottó Törjék Nándor Bucherna Erzsébet Kiss Hajnalka Homoki Zsuzsanna Finta-Korpelová Iván Bócsa István Nagy László E. Heszky 《Euphytica》2002,127(2):209-218
Decamer RAPD primers were tested on dioecious and monoecious hemp cultivars to identify sex-specific molecular markers. Two
primers (OPD05 and UBC354) generated specific bands in male plants. These two DNA fragments were isolated, cloned and sequenced.
Both markers proved to be unique, since no sequence with significant homology to OPD05961 and UBC354151 markers were found in databases. These markers were named MADC3 (OPD05961) and MADC4 (UBC354151) (Male-Associated DNA from Cannabis sativa). The markers were converted into sequence-characterized amplified region (SCAR) markers. The SCAR markers correlated with
the sex of the segregating F2 population and proved the tight linkage to the male phenotype. Results of F2 plant population analysis suggest these markers are to be linked to the Y chromosome.
This revised version was published online in August 2006 with corrections to the Cover Date. 相似文献
15.
Development and Validation of SCAR Markers Co-Segregating with an Agropyron Elongatum Derived Leaf Rust Resistance Gene Lr24 in Wheat 总被引:1,自引:0,他引:1
Summary An Agropyron elongatum-derived leaf rust resistance gene Lr24 located on chromosome 3DL of wheat was tagged with six random amplified polymorphic DNA (RAPD) markers which co-segregated with the gene. The markers were identified in homozygous resistant F2 plants taken from a population segregating for leaf rust resistance generated from a cross between two near-isogenic lines (NILs) differing only for Lr24. Phenotyping was done by inoculating the plants with pathotype 77-5 of Puccinia triticina. To enable gene-specific selection, three RAPD markers (S1302609, S1326615 and OPAB-1388) were successfully converted to polymorphic sequence characterized amplified region (SCAR) markers, amplifying only the critical DNA fragments co-segregating with Lr24. The SCAR markers were validated for specificity to the gene Lr24 in wheat NILs possessing Lr24 in 10 additional genetic backgrounds including the Thatcher NIL, but not to 43 Thatcher NILs possessing designated leaf rust resistance genes other than Lr24. This indicated the potential usefulness of these SCAR markers in marker assisted selection (MAS) and for pyramiding leaf rust resistance genes in wheat. 相似文献
16.
Seed coat wrinkling is a major factor affecting the germinability of soybean [Glycine max (L.) Merr.] seed produced in high-temperature environments, such as in the Early Soybean Production System of the midsouthern United States. Exposure of seed to high temperatures, coupled with alternating periods of wet and dry conditions, promotes seed coat wrinkling. This can predispose the seed to mechanical damage at harvest, further reducing germinability, and reducing the usability of the grain for seed beans. Previous studies identified a single recessive gene (shr) in a mutant line (T-311), located on chromosome 13 (linkage group F), which causes seed shriveling and seed coat wrinkling. The current study was undertaken to identify and genetically map new gene(s) that affect seed coat wrinkling. Crosses were made between a smooth-seeded accession (PI 567743) and a wrinkled-seeded accession (PI 87623). The parents, F1, F2, and BC1 generations were phenotyped for seed coat wrinkling in a greenhouse in Stoneville, MS during the summer of 2006. Genetic analysis indicated that the wrinkled seed coat trait in PI 87623 was inherited as a single recessive gene. A test for allelism, conducted in the greenhouse with a segregating F2 population derived from T-311?×?PI 87623, showed that the gene from PI 87623 is different from the shr gene in T-311. A field study of a larger population, derived from a reciprocal cross of the same parents, confirmed these results, but also suggested epistatic interactions between the genes. A linkage map was developed using 195 SSR and SNP markers on 168 F2 individuals of the cross PI 567743?×?PI 87623. Linkage analysis identified only one significant locus which was located on chromosome 5 (linkage group A1), confirming identification of a new gene that controls seed coat wrinkling in soybean. This study demonstrates genetic control of seed coat wrinkling, which offers the potential for selecting cultivars with less seed coat wrinkling for heat-stressed production environments. 相似文献
17.
Peng Xu Jiawu Zhou Jing Li Fengyi Hu Xianneng Deng Sufeng Feng Guangyun Ren Zhi Zhang Wei Deng Dayun Tao 《Breeding Science》2014,63(5):476-482
Hybrid sterility hinders the transfer of useful traits between Oryza sativa and O. glaberrima. In order to further understand the nature of interspecific hybrid sterility between these two species, a strategy of multi-donors was used to elucidate the range of interspecific hybrid sterility in this study. Fifty-nine accessions of O. glaberrima were used as female parents for hybridization with japonica cultivar Dianjingyou 1, after several backcrossings using Dianjingyou 1 as the recurrent parent and 135 BC6F1 sterile plants were selected for genotyping and deducing hybrid sterility QTLs. BC6F1 plants containing heterozygous target markers were selected and used to raise BC7F1 mapping populations for QTL confirmation and as a result, one locus for gamete elimination on chromosome 1 and two loci for pollen sterility on chromosome 4 and 12, which were distinguished from previous reports, were confirmed and designated as S37(t), S38(t) and S39(t), respectively. These results will be valuable for understanding the range of interspecific hybrid sterility, cloning these genes and improving rice breeding through gene introgression. 相似文献
18.
粳稻品系Y98149是从离子束诱变的后代中获得的显性半矮秆突变体,与野生型Y98148是一对株高近等基因系。将已经获得的3个与水稻显性半矮秆基因紧密连锁的RAPD标记分别克隆、测序,根据测序结果设计了3对特异性PCR引物,成功地将RAPD标记S1041525、S1076549和S1272403转化成更稳定的SCAR标记SCS1041498、SCS1076510和SCS1272388。通过Y98148×Y98149的F2代分离群体的分析,这3个SCAR标记与显性半矮秆基因的遗传距离分别为12.6 cM、7.5 cM和16.3 cM, 且位于基因的同一侧。序列同源性比较表明,标记S1272403为单拷贝,其核苷酸序列与水稻第7染色体上两个BAC克隆B1249D05(AP006451)和OJ1212-C12(AP005604)同源性为99%,B1249D05与OJ1212-C12有23 kb的重叠区域,标记S1272403位于这个重叠区域,据此初步将显性半矮秆基因定位,为进一步精确定位和图位克隆奠定了基础。 相似文献
19.
Masayasu Saruta Yoshitake Takada Akio Kikuchi Tetsusya Yamada Kunihiko Komatsu Takashi Sayama Masao Ishimoto Akinori Okabe 《Breeding Science》2012,61(5):625-630
The peanut stunt virus (PSV) causes yield losses in soybean and reduced seed quality due to seed mottling. The objectives of this study were to determine the phenotypic reactions of soybean germplasms to inoculation with two PSV isolates (PSV-K, PSV-T), the inheritance of PSV resistance in soybean cultivars, and the locus of the PSV resistance gene. We investigated the PSV resistance of 132 soybean cultivars to both PSV isolates; of these, 73 cultivars exhibited resistance to both PSV isolates. Three resistant cultivars (Harosoy, Tsurunotamago 1 and Hyuga) were crossed with the susceptible cultivar Enrei. The crosses were evaluated in the F1, F2 and F2:3 generations for their reactions to inoculation with the two PSV isolates. In an allelism test, we crossed Harosoy and Tsurunotamago 1 with the resistant cultivar Hyuga. The results revealed that PSV resistance in these cultivars is controlled by a single dominant gene at the same locus. We have proposed Rpsv1, as the name of the resistance gene in Hyuga. We also constructed a linkage map using recombinant inbred lines between Hyuga × Enrei using 176 SSR markers. We mapped Rpsv1 near the Satt435 locus on soybean chromosome 7. 相似文献
20.
Identification and characterization of RAPD and SCAR markers linked to anthracnose resistance gene in sorghum [Sorghum bicolor (L.) Moench] 总被引:1,自引:0,他引:1
Anthracnose, one of the destructive foliar diseases of sorghum growing in warm humid regions, is incited by the fungus Colletotrichum graminicola.The inheritance of anthracnose resistance was studied using the parental cultivars of Sorghum bicolor (L.) Moench, HC 136 (susceptible to anthracnose) and G 73 (anthracnose resistant). The F1 and F2 plants were inoculated with the local isolates of C. graminicola cultures. The F2 plants showed a segregation ratio of 3 (susceptible): 1(resistant) indicating that the locus for resistance to anthracnose in sorghum accession G 73 segregates as a recessive trait in a cross to susceptible cultivar HC 136. RAPD (random amplified polymorphic DNA) marker OPJ 011437 was identified as marker closely linked to anthracnose resistance gene in sorghum by bulked segregant analysis of HC 136 × G73 derived recombinant inbred lines (RILs) of sorghum. A total of 84 random decamer primers were used to screen polymorphism among the parental genotypes. Among these, only 24 primers were polymorphic. On bulked segregant analysis, primer OPJ 01 amplified a 1437 bp fragment only in resistant parent G 73 and resistant bulk. The marker OPJ 011437 was cloned and sequenced. The sequence of RAPD marker OPJ 011437 was used to generate specific markers called sequence characterized amplified regions (SCARs). A pair of SCAR markers SCJ 01-1 and SCJ 01-2 was developed using Mac Vector program. SCAR amplification of resistant and susceptible parents along with their respective bulks and RILs confirmed that SCAR marker SCJ 01 is at the same loci as that of RAPD marker OPJ 011437 and hence, is linked to anthracnose resistance gene. Resistant parent G 73 and resistant bulk amplified single specific band on PCR amplification using SCAR primer pairs. The RAPD marker OPJ 011437 was mapped at a distance of 3.26 cM apart from the locus governing anthracnose resistance on the sorghum genetic map by the segregation analysis of the RILs. Using BLAST program, it was found that the marker showed 100 per cent alignment with the contig{_}3966 located on the longer arm of chromosome 8 of sorghum genome. Therefore, these identified RAPD and SCAR markers can be used in the resistance-breeding program of sorghum anthracnose by marker-assisted selection.An erratum to this article can be found at 相似文献