SCAR and RAPD markers associated with 18-carbon fatty acids in rapeseed, Brassica napus

Breeding rapeseed for enhanced oil quality includes the development of varieties with low linolenic acid content. The breeder also aims to develop varieties with a high linoleic acid content because of its nutritional value. Restriction fragment length polymorphism (RFLP) and random amplified polymorphic DNA (RAPD) markers have been developed for linolenic acid content, but they are not best suited for a direct application in marker-assisted selection. The RFLP technique is too complex and time-consuming and RAPD markers lack codominance, precluding the distinction of homozygous from heterozygous individuals. In this report the conversion of a RAPD marker to a codominant sequence characterized amplified region (SCAR) marker named L1L9 is described. One of the alleles consisting of an 899 bp fragment (allele A), is associated with low linolenic acid content. The other allele consists of an 641 bp fragment (allele B) and is associated with high linolenic acid content. This marker explains approximately 25% of the genetic variation for this trait. Linkage analysis in the mapping population indicates that the SCAR marker probably tags an ω-3 desaturase gene in B. napus. Two RAPD markers were found to be associated with oleic/linoleic acid content. Markers M14-350 and I06-650 explained approximately 10% and 7% of the genetic variation for linoleic acid content, respectively. These two markers were found linked at 12.3cM in the segregating B. napus F₂ progeny used for mapping. All the markers reported in this paper should be useful in breeding programmes for developing high linoleic and low linolenic acid rapeseed varieties.     

Conversion of the RAPD OPC021150 marker of the Rfo restorer gene into a SCAR marker for rapid selection of oilseed rape

The Rfo fertility restorer gene for the Ogura cytoplasmic male sterility (CMS) applied for oilseed rape hybrid seed production can be monitored with the use of the RAPD OPC02₁₁₅₀ marker while molecular breeding. The aim of this work was to convert the RAPD marker into a more suitable SCAR marker. Total DNA was isolated from a doubled haploid line derived from the line BO20 (INRA, France). A fragment of 1150‐bp linked to the Rfo gene was PCR amplified with the use of the RAPD OPC02 primer, cloned and sequenced. A pair of primers was designed and PCR amplification was performed to develop a SCAR marker for the Rfo gene. The new marker was applied for analysis of 220 oilseed rape lines comprising doubled haploid and inbred restorer lines, restored hybrids as well as F₁ and F₂ recombinant generations involving restorer lines. Simultaneously, the RAPD OPC02 marker was used and it revealed that the markers are equivalent to each other. However, the developed new SCAR marker has made the analysis more practical, rapid and efficient.     

Marker-assisted selection for oleic acid content in spring turnip rape

The efficiency of marker-assisted selection for oleic acid content was studied in an F₂ population of spring turnip rape, Brassica rapa ssp. oleifera, using a sequence characterized amplified region (SCAR) marker, the distance of which from the oleic acid gene is 11.5 cM, and allele-specific markers which are located at the gene locus. As expected, the allele-specific markers recognized the oleic acid genotypes more precisely than the SCAR marker. A further complication in the use of the SCAR was the existence of null alleles and polymorphism in almost all the lines/cultivars tested. Therefore, parents have to be carefully selected to find informative combinations in different crosses. Allele-specific markers are very efficient in selection since heterozygous plants can be identified. This is not possible when selection is based on the commonly applied gas chromatography analysis of oil composition. The allele-specific detection was further simplified by using direct staining of PCR products instead of electrophoresis.     

RAPD and SCAR markers for resistance to acochyta blight in lentil

Resistance to ascochyta blight of lentil (Lens culinaris Medikus),caused by the fungus Ascochyta lentis, is determined by a single recessive gene, ral ₂, in the lentil cultivar Indian head. Sixty F₂ individuals from a cross between Eston (susceptible) and Indian head (resistant) lentil were analyzed for the presence of random amplified polymorphic DNA (RAPD) markers linked to the ral ₂gene, using bulked segregant analysis (BSA). Out of 800 decanucleotide primers screened, two produced polymorphic markers that co-segregated with the resistance locus. These two RAPD markers, UBC227₁₂₉₀and OPD-10₈₇₀, flanked and were linked in repulsion phase to the gene ral ₂ at 12 cm and 16 cm, respectively. The RAPD fragments were converted to SCAR markers. The SCAR marker developed from UBC227₁₂₉₀ could not detect any polymorphism between the two parents or in the F₂. The SCAR marker developed from OPD-10₈₇₀ retained its polymorphism. The polymorphic RAPD marker UBC227₁₂₉₀ and the SCAR marker developed from OPD-10₈₇₀ can be used together in a marker assisted selection program for ascochyta blight resistance in lentil. This revised version was published online in July 2006 with corrections to the Cover Date.     

Development of RAPD and ISSR derived SCAR markers linked to <Emphasis Type="Italic">Xca1Bo</Emphasis> gene conferring resistance to black rot disease in cauliflower (<Emphasis Type="Italic">Brassica oleracea</Emphasis> var. <Emphasis Type="Italic">botrytis</Emphasis> L.)

Black rot caused by Xanthomonas campestris pv. campestris (Xcc) (Pam.) is the most devastating disease of cauliflower (Brassica oleracea var. botrytis L.; 2n = 2x = 18), taking a heavy toll of the crop. In this study, a random amplified polymorphic DNA (RAPD) and inter simple sequence repeat (ISSR) derived sequence characterized amplified region (SCAR) markers linked to the black rot resistance locus Xca1bo were developed and evaluated as a screening tool for resistance. The RAPD marker OPO-04₈₃₃ and ISSR marker ISSR-11₆₃₅ were identified as closely linked at 1.6 cM distance to the black rot resistance locus Xca1bo. Both the markers OPO-04₈₃₃ and ISSR-11₆₃₅ were cloned, sequenced and converted into SCAR markers and validated in 17 cauliflower breeding lines having different genetic backgrounds. These SCAR markers (ScOPO-04₈₃₃ and ScPKPS-11₆₃₅) amplified common locus and showed 100% accuracy in differentiating resistant and susceptible plants of cauliflower breeding lines. The SCAR markers ScOPO-04₈₃₃ and ScPKPS-11₆₃₅ are the first genetic markers found to be linked to the black rot resistance locus Xca1bo in cauliflower. These markers will be very useful in black rot resistance marker assisted breeding.     

Identification of SCAR markers linked to <Emphasis Type="Italic">or</Emphasis>, a gene inducing beta-carotene accumulation in Chinese cabbage

The or mutation in Chinese cabbage (Brassica rapa L. ssp. pekinensis) is a recessive, single-locus mutation that causes the head leaves of the plant to accumulate carotenoids and turn orange. In China, considerable attention has been focused in recent years on breeding the variety with orange head leaves. In this study, sequence-characterized amplified region (SCAR) markers linked to the or gene were identified based on random amplified polymorphic DNA (RAPD) and amplified fragment length polymorphism (AFLP) by performing a bulked segregant analysis (BSA) using a doubled haploid (DH) population derived from the F₁ cross between 91-112 (white head leaves) and T12-19 (orange head leaves) via microspore culture. Two RAPD markers—OPB01-845 and OPAX18-656—and 1 AFLP marker, namely, P67M54-172, were identified to be linked to the or gene, and they were successfully converted into the SCAR markers SCR-845, SCOR204, and SCOR127, respectively. In a linkage analysis, these 3 SCAR markers and 2 previously published simple sequence repeat markers, namely, BRMS-51 and Ni4D09 (located on R9 linkage group), were mapped to the same linkage group with the or gene at a LOD score of 6.0, indicating that the or gene should be located on the linkage group R9 of the A genome. In addition, accuracies of 92%, 90%, and 89.1% were obtained when 110 different inbred breeding lines of Chinese cabbage were used for investigation with these 3 SCAR markers, indicating that these makers could be used in marker-assisted selection in orange head leaf breeding programs for Chinese cabbage.     

Novel male-specific molecular markers (MADC5, MADC6) in hemp

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.     

大葱雄性不育分子标记辅助选择的研究

大葱雄性不育在杂种优势利用中具有重要价值,传统方法选育不育系效率低,分子标记辅助育种可提高育种效率。本研究试图建立大葱雄性不育辅助育种的技术体系,加快大葱不育系、保持系的育种进程。利用RAPD技术分析了多态性片段S132800、S38960、S72300、S731100、S2002400与大葱育性的连锁关系,重组率分别为0、7．5％、0、4．2％、0。其中S132800、S2002400能在多数品种中区分N、S胞质,且重组率接近0,用于胞质鉴定具有很高的准确率,因而具有较高的利用价值。以S132800、S2002400为探针对不育系和保持系mtDNA的酶切片段进行了Southern杂交分析,结果表明它们在N、S胞质中存在多态性。预示着它们可能是与大葱CMS相关的片段。鉴于RAPD标记的应用有一定局限性,进一步对特异片段S132800、S2002400进行了克隆、测序和SCAR标记转化,其中S132800成功转化为SCAR标记,而S2002400转化后多态性消失。为进一步降低成本,简化了SCAR扩增产物的检测技术,初步建立了大葱不育系、保持系分子标记辅助选择的技术体系。研究表明,SCAR产物加入EB直接检测存在一定误差,而通过快速电泳可以快速、准确地鉴定单株的胞质类型。RAPD标记和SCAR标记在育种中应用有望提高大葱不育系、保持系的育种效率。     

Morphological evaluation of olive germplasm present in Tuscany region

Undesirable characteristic of rapeseed oil is a relatively high level of linolenic acid (18:3), which is easily oxidized leading to rancidity and a shortened shelf life of the oil. Previous attempts to reduce linolenic acid levels in rapeseed oil through breeding have been impaired by complex genetics and strong environmental sensitivity of this trait. Therefore, our objective was to develop molecular markers for low linolenic acid that could facilitate the breeding of low linolenic rapeseed. Bulked segregant analysis was employed to identify two RAPD markers associated with 18:3 in a doubled haploid population segregating for linolenic and erucic acid levels. Based on analysis of individual DH lines, the markers RM350 and RM574, representing two independent loci, accounted for a total of 39% of the genetic variability in this population. This marker RM350 alone accounted for 25% genetic variation for this trait with no evidence of recombination. Significant interlocus interaction found between the markers RM350 and RM574 suggested that epistasis was involved in the genetic control of 18:3 level in this population. Another marker designated as RM322, which was independent of the other two, was found significantly associated with the erucic acid level and oil content. RAPD markers identified in this study should be a useful tool for the early detection of low linolenic, or low or high erucic acid genotypes in rapeseed breeding programs based on doubled haploids. This revised version was published online in July 2006 with corrections to the Cover Date.     

Identification of RAPD and SCAR markers linked to northern leaf blight resistance in waxy corn (Zea mays var. ceratina)

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.     

Development of PCR-based markers linked to a restorer gene for cytoplasmic male sterility in radish (Raphanus sativus L.)

A random amplified polymorphic DNA (RAPD) marker named OPC06-1900 was previously found linked to a fertility restorer gene (Rfw) for cytoplasmic male sterility (CMS) in radish (Raphanus sativus L.). The RAPD marker was converted to a dominant sequence characterized amplified region (SCAR) marker SCC06-1894 by molecular cloning and nucleotide sequencing. A BLAST search revealed that the SCAR marker SCC06-1894 showed significant homology to the corresponding regions of Arabidopsis and Brassica sulfate transporter genes. The presence of the intron and exon of the DNA fragment SCC06-1894 was demonstrated by comparing RT-PCR and PCR products. Thus, allele-specific oligonucleotide primers were designed to amplify the SCAR marker SCC06-415. PCR test with F₂ plants and sequence analysis showed that SCC06-1894 and SCC06-415 were allelic, linked to Rfw/rfw gene at 8.0 cM. Nine oligonucleotide primers were designed based on a single radish nuclear restorer gene mRNA. A survey of these primer combinations by bulked segregant analysis (BSA) identified three polymorphisms. The three PCR-based markers were co-segregant in the coupling phase and distant from the Rfw gene by 1.4 cM. These specific markers distributed on both sides of the Rfw gene and will be helpful for breeding new rapseed (Brassica napus L.) restorer lines.     

甘蓝型油菜高油酸性状研究进展

油酸是单不饱和脂肪酸,无论食用还是工业用都具有非常重要的作用,提高油酸含量是作物脂肪酸改良的重要目标。综述了高油酸油菜的特点、高油酸油菜获得途径及育种成就、高油酸性状遗传规律、分子标记和QTL定位等方面的研究进展,提出高油酸和油菜杂种优势利用相结合应是我国油菜高油酸育种的主攻方向。     

Identification of PCR-based markers linked to the powdery-mildew-resistance gene Pl1 from Malus robusta in cultivated apple

The availability of molecular markers linked to mildew resistance genes would enhance the efficiency of apple-breeding programmes. This investigation focuses on the identification of random amplified polymorphic DNA (RAPD) markers linked to the Pl₁ gene for mildew resistance, which has introgressed from Malus robusta into cultivated apples. The RAPD marker technique was combined with a modified ‘bulked seg-regant analysis’ mapping strategy. About 850 random decamer primers used as single primers or in combinations were tested by PCR analysis on the basis of resistant and susceptible DNA pools. Selected primers producing RAPD fragments were applied in an additional selection step to M. robusta and genotypes representing intermediate breeding stages of the breeding population 93/9, for which a 1:1 segregation could be observed for the resistance trait. Seven RAPD markers, all representing introgressed DNA sequences from M. robusta, were identified and arranged with the Pl₁ locus in a common linkage group. The two most tightly-linked RAPD markers, OPAT20₄₅₀ and OPD2₁₀₀₀ were mapped with a genetic distance of 4.5 and 5 cM, respectively, from the Pl₁ gene. Both markers are suitable for marker-assisted selection in apple breeding. The polymorphic DNA fragment OPAT20₄₅₀ was cloned and sequenced, and longer primers for the generation of a sequence-characterized amplified region (SCAR) marker have been constructed; this marker was easier to score than the original RAPD marker.     

Evaluation of cytoplasmic effects on agronomic and seed quality traits in two doubled haploid populations of Brassica napus L.

Cytoplasmic effects have been occasionally implicated in the inheritance of several traits in oilseed rape (Brassica napus L.), including linolenic acid concentration (18:3) in the oil. It is important that these be considered when choosing the direction of cross for producing new breeding populations. To study this phenomenon, a reciprocal cross was made between two genotypes of oilseed rape, Reston and LL09, which differed for their erucic and linolenic acid concentrations in the seed oil. Two DH populations, which were produced by microspore culture from reciprocal F₁ plants, were evaluated in the growth room for one generation and in the field at two locations in Southern Ontario in 1993and 1994. Field notes were taken on days to flower, days to maturity,plant lodging, plant height and, seed quality traits. In the growth room study, the phenotypic distribution of 18:3 differed significantly between the two reciprocal DH populations. In the field, significant reciprocal differences between the population means were detected for 18:3,flowering date and protein content in both years and for days to maturity and oil content in 1993 only. To further study the parental lines,chloroplast (cp) and mitochondrial (mt) DNA from parental lines were isolated and subjected to RFLP and RAPD analysis. Several random primers revealed reproducible DNA polymorphism (RAPD) between the parental mt DNA. It is concluded that the direction of cross should be taken into consideration by oilseed rape breeders relying solely on doubled haploids for developing genotypes with modified seed quality traits in Brassica napus L. This revised version was published online in July 2006 with corrections to the Cover Date.     

A mutant of Brassica napus with increased palmitic acid content

An induced mutant from European winter oilseed rape with increased palmitic acid content was phenotypically characterized and genetically analysed. The mutant showed a palmitic acid content of 9.2% compared with 4.5% in the parental cultivar. The oleic acid content decreased from 61.6% to 44.2%, whereas the linoleic and linolenic acid contents increased. The mutant plants grew poorly and their seed oil content was only 31.2% compared with 42.8% in the parental cultivar. The inheritance of the mutant was oligogenic and determined by at least four genes. In the F₂ generation, palmitic acid content was negatively correlated with oil content. This mutant may be useful to improve understanding of the genetic regulation of storage lipid synthesis, but has no immediate value for oilseed rape improvement.     

Development and Validation of SCAR Markers Co-Segregating with an Agropyron Elongatum Derived Leaf Rust Resistance Gene Lr24 in Wheat

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.     

New mutants of winter rapeseed (Brassica napus L.) with changed fatty acid composition

Seeds of the winter oilseed rape (Brassica napus L.) line PN 3756/93 were treated with ethyl methanesulphonate to induce mutations in the fatty acid biosynthetic pathway. The seed mutagenic treatment was repeated in the M₂ generation. After treatments, individual seed and plant selections were made for changes in fatty acid composition during several generations of inbreeding. Self‐pollinated plants with changed fatty acid compositions were inbred to obtain genetically homozygous and stable mutant lines. Two mutants, M‐10453 and M‐10464, with increased levels of oleic acid (approximately 76%) and reduced linoleic and linolenic acid contents (8.5% and 7.5%, respectively) were selected. Gene or genes controlling desaturation of oleic acid were probably mutated in these plants. The third mutant, M‐681 had a very low linolenic acid content (approximately 2.6%) and increased linoleic acid content (approximately 26%). This would suggest the occurrence of mutations in genes controlling linoleic acid desaturation. The results of selection work during several generations showed that the environment had substantial influence on the composition of seed oil. This made the search for mutants with modify fatty acid compositions difficult. The induced mutants are not directly usable as new varieties, but can be used as parents in crosses for the development of high quality rapeseed varieties.     

Identification and characterization of RAPD and SCAR markers linked to anthracnose resistance gene in sorghum [Sorghum bicolor (L.) Moench]

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     

Marker-assisted selection of common beans for resistance to common bacterial blight: efficacy and economics

The possibility of using random amplified polymorphic DNA (RAPD) markers previously mapped in the common bean PC50/XANI59 population to select for resistance to common bacterial blight (CBB) in different populations was examined. Two out of 02 selected RAPD markers were polymorphic in HR56 and W0633d, the parental lines used in this experiment. Cosegregation analysis of the two polymorphic markers and disease reaction in a recombinant inbred (RI) population derived from HR67/W1744d confirmed that one of the two RAPD markers, BC420₉₀₀, was significantly associated with a major quantitative trait locus‐conditioning resistance to CBB in HR67. This locus accounted for approximately 51) of the phenotypic variation. The RAPD marker was transformed into a sequence characterized amplified region (SCAR) marker and used for selection in a different population derived from ‘Envoy’/HR67. Prediction for resistance to CBB with the BC420_.990 SCAR marker was 94.2% accurate in this population. A comparison between marker‐assisted selection (MAS) and conventional greenhouse screening showed that the cost of MAS is about one‐third less than that of the greenhouse test.     

Molecular mapping of Aegilops speltoides derived leaf rust resistance gene Lr28 in wheat

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.