Development of RAPD and SCAR markers linked to the Russian wheat aphid resistance gene Dn2 in wheat

 RAPD (random amplified polymorphic DNA) analysis was used to identify molecular markers linked to the Dn2 gene conferring resistance to the Russian wheat aphid (Diuraphis noxia Mordvilko). A set of near-isogenic lines (NILs) was screened with 300 RAPD primers for polymorphisms linked to the Dn2 gene. A total of 2700 RAPD loci were screened for linkage to the resistance locus. Four polymorphic RAPD fragments, two in coupling phase and two in repulsion phase, were identified as putative RAPD markers for the Dn2 gene. Segregation analysis of these markers in an F₂ population segregating for the resistance gene revealed that all four markers were closely linked to the Dn2 locus. Linkage distances ranged from 3.3 cM to 4.4 cM. Southern analysis of the RAPD products using the cloned RAPD markers as probes confirmed the homology of the RAPD amplification products. The coupling-phase marker OPB10_880c and the repulsion-phase marker OPN1_400r were converted to sequence characterized amplified region (SCAR) markers. SCAR analysis of the F₂ population and other resistant and susceptible South African wheat cultivars corroborated the observed linkage of the RAPD markers to the Dn2 resistance locus. These markers will be useful for marker-assisted selection of the Dn2 gene for resistance breeding and gene pyramiding. Received: 1 July 1997 / Accepted: 20 October 1997     

RAPD and ISSR-assisted identification and development of three new SCAR markers specific for the Thinopyrum elongatum E (Poaceae) genome

Diploid Thinopyrum elongatum, a wild relative of wheat, contains many agronomically desirable traits and has potential for increasing genetic variability and introducing desirable characters in this crop. Few molecular markers are available for rapid screening of T. elongatum genome segments in the wheat genetic background. We used 36 RAPD primers and 33 ISSR primers to screen for polymorphisms in the common wheat variety Chinese Spring and in T. elongatum. Two RAPD markers and one ISSR marker, designated OPF03(1407), LW10(1487) and UBC841(701), were identified and were specific for the T. elongatum E genome. Three pairs of primers flanking these specific sequences were designed to produce SCAR markers. All three SCAR markers were T. elongatum E genome-specific. Two of these SCAR markers, SCAR(807) and SCAR(577), were present in all seven T. elongatum chromosomes, while SCAR(839) was specific for T. elongatum chromosomes 2E and 3E. These newly developed SCAR markers should be useful for detecting alien genome chromatin or chromosome segments in the genetic background of common wheat.     

Development and Study of SCAR Markers in Pea (<Emphasis Type="Italic">Pisum sativum</Emphasis> L.)

In order to develop more specific markers that characterize particular regions of the pea genome, the data on nucleotide sequences of RAPD fragments were used for choosing more extended primers, which may be helpful in amplifying a fragment corresponding to the particular DNA region. Of the 14 STS markers obtained from 14 polymorphic RAPD fragments, 12 were polymorphic, i.e., they are SCAR markers that can be used in genetic analysis. The transition from complex RAPD spectra to amplification of a particular SCAR marker substantially facilitates analysis of large samples for the presence or absence of the examined fragment. Inheritance of the developed SCAR markers was studied in F₁ and F₂. SCAR markers were used to identify various pea lines, cultivars, and mutants. It was established that the study of amplification of STS markers in various pea genotypes at varying temperatures of annealing and the comparison with amplification of the original RAPD fragments in the same genotypes provide an approach for analysis of RAPD polymorphism origin.     

CHARACTERIZATION OF GENETIC MARKERS LINKED TO SEX DETERMINATION IN THE HAPLOID‐DIPLOID RED ALGA GRACILARIA CHILENSIS1

Bulk segregant analysis, random amplified polymorphic DNA (RAPD), and sequence characterized amplified region (SCAR) methods were used to identify sex‐linked molecular markers in the haploid‐diploid rhodophyte Gracilaria chilensis C. J. Bird, McLachlan et E. C. Oliveira. One hundred and eighty 10 bp primers were tested on three bulks of DNA: haploid males, haploid females, and diploid tetrasporophytes. Three RAPD primers (OPD15, OPG16, and OPN20) produced male‐specific bands; and one RAPD primer (OPD12), a female‐specific band. The sequences of the cloned putative sex‐specific PCR fragments were used to design specific primers for the female marker SCAR‐D12‐386 and the male marker SCAR‐G16‐486. Both SCAR markers gave unequivocal band patterns that allowed sex and phase to be determined in G. chilensis. Thus, all the females presented only the female band, and all the males only the male band, while all the tetrasporophytes amplified both male and female bands. Despite this sex‐specific association, we were able to amplify SCAR‐D12‐386 and SCAR‐G16‐486 in both sexes at low melting temperature. The differences between male and female sequences were of 8%–9% nucleotide divergence for SCAR‐D12‐386 and SCAR‐G16‐486, respectively. SCAR‐D12‐386 and SCAR‐G16‐486 could represent degenerated or diverged sequences located in the nonrecombining region of incipient sex chromosomes or heteromorphic sex chromosomes with sequence differences at the DNA level such that PCR primers amplify only one allele and not the other in highly specific PCR conditions. Seven gametic progenies composed of 19 males, 19 females, and the seven parental tetrasporophytes were analyzed. In all of them, the two SCAR markers segregated perfectly with sexual phenotypes.     

Development of 5Ns chromosome-specific SCAR markers for utilization in future wheat breeding programs

In previous studies, we developed a wheat-Psathyrostachys huashanica Keng disomic addition line 3-8-10-2, which exhibited high stripe rust resistance and could be used as a donor source for introducing novel disease resistance gene(s) into wheat in future breeding programs. It was identified using cytology, genomic in situ hybridization (GISH), EST-SSR, EST-STS and morphological analyses. However, these techniques are not suitable for breeding programs that require the rapid screening of large numbers of genotypes because they are highly technical and time-consuming. In this study, three Ns genome-specific SCAR markers were developed via random amplified polymorphic DNA (RAPD) markers. These SCAR markers were further validated using a complete set of wheat-P. huashanica disomic addition lines, which segregated the 5Ns disomic addition line individuals. Our results indicated that the SCAR markers associated with the 5Ns chromosome of P. huashanica and they provide a low cost, high efficiency, alternative tool for screening 5Ns chromosomes in a wheat background. These newly developed SCAR markers that species-specificity of the markers was proved by analysis of a wide range of cereal species, and specific for 5Ns chromosome, which should be useful in marker-assisted selection for wheat breeders who want to screen genotypes that may contain 5Ns chromatin.     

小麦抗白粉病基因Pm21的分子鉴定和标记辅助选择

利用小麦抗白粉病基因Ｐｍ２１的ＲＡＰＤ标记、ＳＣＡＲ标记和荧光源位杂交技术对小麦抗病育种材料中的抗白粉病Ｐｍ２１基因进行了分子鉴定和标记辅助选择。     

SCAR markers for discriminating species of two genera of medicinal plants, Liriope and Ophiopogon

The development of DNA markers that can closely discriminate between Liriope and Ophiopogon species is vital for efficient and accurate identification of these species, and to ensure the quality, safety, and efficacy of medicines made from these plants. We developed species-specific molecular markers for these two genera. Forty RAPD primers were tested to detect polymorphism; species-specific RAPD bands were gel-purified, cloned, and sequenced. Primers for sequence-characterized amplified regions (SCARs) were then designed, based on nucleotide sequences of specific RAPD primers. SCAR markers SA06 and SB05, specific to Ophiopogon japonicus, amplified 460- and 553-bp DNA fragments, respectively. The marker SA12 amplified a 485-bp fragment specific to Liriope platyphylla. This is the first report of a species-specific SCAR marker for this group. These markers will be useful for rapid identification of closely related Liriope and Ophiopogon species.     

Identification of RAPD and SCAR markers associated with yield traits in the Indian tropical tasar silkworm Antheraea mylitta drury

The tropical tasar silkworm, Antheraea mylitta, is a semi-domesticated vanya silk-producing insect of high economic importance. To date, no molecular marker associated with cocoon and shell weights has been identified in this species. In this report, we identified a randomly amplified polymorphic DNA (RAPD) marker and examined its inheritance, and also developed a stable diagnostic sequence-characterized amplified region (SCAR) marker. Silkworms were divided into groups with high (HCSW) and low (LCSW) cocoon and shell weights, and the F₂ progeny of a cross between these two groups were obtained. DNA from these silkworms was screened by PCR using 34 random primers and the resulting RAPD fragments were used for cluster analysis and discriminant function analysis (DFA). The clustering pattern in a UPGMA-based dendogram and DFA clearly distinguished the HCSW and LCSW groups. Multiple regression analysis identified five markers associated with cocoon and shell weights. The marker OPW16_{905 bp} showed the most significant association with cocoon and shell weights, and its inheritance was confirmed in F₂ progeny. Cloning and sequencing of this 905 bp fragment showed 88% identity between its 134 nucleotides and the Bmc-1/Yamato-like retroposon of A. mylitta. This marker was further converted into a diagnostic SCAR marker (SCOPW 16_{826 bp}). The SCAR marker developed here may be useful in identifying the right parental stock of tasar silk-worms for high cocoon and shell weights in breeding programs designed to enhance the productivity of tasar silk.     

Seed-specific identification of Larix gmelinii,Larix olgensis,and Larix principis-rupprechtii using sequence-characterised amplified region markers

Larix gmelinii, Larix olgensis, and Larix principis-rupprechtii are the three native and sympatric larch species in North China, and each of these species has a distinctive ecological niche. It is difficult to identify them based only on certain morphological characters, particularly the seed appearance. In this study, the seed endosperms of these three larch species were analysed using the random amplified polymorphic DNA (RAPD) technique to screen for interspecific differences. The following three RAPD markers linked to species-specific segments were observed in the different species: 1475-bp (Larix gmelinii and L. olgensis), 505-bp (Larix principis-rupprechtii), and 1121-bp (Larix gmelinii) markers. The three seed-specific fragments amplified by the RAPD markers were sequenced, and the sequences were used to design and synthesise species-specific SCAR markers. The size of the SCAR fragments was concordant with that of the RAPD species-specific fragments. Therefore, these SCAR markers can be used to identify the seeds of different larch species, thereby providing a new molecular tool for the identification of larch seeds that leads to considerable savings in terms of time and economic resources.     

Identification and characterization of RAPD–SCAR markers linked to glyphosate-susceptible and -resistant biotypes of Eleusine indica (L.) Gaertn

Eleusine indica is one of the most common weed species found in agricultural land worldwide. Although herbicide-glyphosate provides good control of the weed, its frequent uses has led to abundant reported cases of resistance. Hence, the development of genetic markers for quick detection of glyphosate-resistance in E. indica population is imperative for the control and management of the weed. In this study, a total of 14 specific random amplified polymorphic DNA (RAPD) markers were identified and two of the markers, namely S4R727 and S26R₆976 were further sequence characterized. Sequence alignment revealed that marker S4R727 showing a 12-bp nucleotides deletion in resistant biotypes, while marker S26R₆976 contained a 167-bp nucleotides insertion in the resistant biotypes. Based on these sequence differences, three pairs of new sequence characterized amplified region (SCAR) primers were developed. The specificity of these primer pairs were further validated with genomic DNA extracted from ten individual plants of one glyphosate-susceptible and five glyphosate-resistant (R2, R4, R6, R8 and R11) populations. The resulting RAPD–SCAR markers provided the basis for assessing genetic diversity between glyphosate-susceptible and -resistant E. indica biotypes, as well for the identification of genetic locus link to glyphosate-resistance event in the species.     

Evaluation of the Use of SCAR Markers for Screening Genetic Diversity of Lentinula edodes Strains

In this study, three molecular marker systems including sequence related amplified polymorphism (SRAP), random amplified polymorphic DNA (RAPD), and inter-simple sequence repeats (ISSR) were screened to select polymorphisms of 24 main commercial strains of Lentinula edodes cultivated widely in China. Twenty-nine sequence characterized amplified region (SCAR) markers were developed to set up a dendrogram using UPMGA based on nucleotide sequences of some SRAP, RAPD, and ISSR polymorphic fragments. The grouping showed that the 24 strains were apparently clustered into five groups at a level of 0.68 similarity coefficient, and those that have similar breeding background clustered preferentially into the same subgroup. Results also revealed that the 24 strains had a low level of genetic diversity, and the breeding source of L. edodes should be broadened by exploiting wild types and introducing exotic strains. In addition, the tested strains of L. edodes could be clearly distinguished and identified from others by using different combinations of SCAR primers. Thus, results of this work demonstrated that SCAR was an excellent genetic marker system to characterize and investigate genetic diversity of L. edodes. Furthermore, this provided an alternative method to identify the genetic relationship of different strains of other fungi.     

Direct sequencing of RAPD fragments using 3'-extended oligonucleotide primers and dye terminator cycle-sequencing.

Random amplified polymorphic DNA (RAPD) markers are used widely to develop high resolution genetic maps and for genome fingerprinting. Typically, single oligomers of approximately 10 nucleotides are used to PCR amplify characteristic RAPD marker fragments. We describe an efficient method for the direct end-sequencing of gel-purified RAPD fragments using one primer from a set of four 3'-terminal extended (A, T, C or G) oligonucleotides, identical to the RAPD primer but for the single nucleotide extension. Strand-specific DNA sequence could be independently read from each of the RAPD fragments without recourse to strand separation or fragment cloning. Informative RAPD fragments could be readily converted into mapped STS or SCAR loci using this technology. The 3'-extended primers may also be used to amplify independent genomic RAPD markers.     

DNA markers for sex: Molecular evidence for gender dimorphism in dioecious Mercurialis annua L.

Male specific Random Amplified Polymorphic DNA (RAPD) markers, OPB01-1562 and OPC07-303, were identified and sequenced in dioecious Mercurialis annua. Sequence Characterized Amplified Region (SCAR) primers were designed. Several internal segments of OPB01-1562 were amplified as male specific SCAR markers. These markers were PCR amplified from strong, intermediate and weak male subtypes selected according to their resistance to feminization by cytokinin. Nucleotide sequence of OPB01-1562 isolated from three male subtypes were near identical. The OPB01-1562 and derived SCAR markers were absent in females as well as hexaploid Mercurialis male and monoecious individuals. The gender relationship of the markers was maintained in all ecotypes tested. There were 2 internal fragments of OPB01-1562, which were PCR amplified from all genotypes of diploid and hexaploid Mercurialis. It is argued that identification of gender specific DNA suggests a dimorphic differentiation of the genome of dioecious Mercurialis annua.     

Development and study of SCAR markers in pea (Pisum sativum L.)

In order to develop more specific markers that characterize particular regions of the pea genome, the data on nucleotide sequences of RAPD fragments were used for choosing more extended primers, which may be helpful in amplifying a fragment corresponding to the particular DNA region. Of the 14 STS markers obtained from 14 polymorphic RAPD fragments, 12 were polymorphic, i.e., they are SCAR markers that can be used in genetic analysis. The transition from complex RAPD spectra to amplification of a particular SCAR marker substantially facilitates analysis of large samples for the presence or absence of the examined fragment. Inheritance of the developed SCAR markers was studied in F1 and F2. SCAR markers were used to identify various pea lines, cultivars, and mutants. It was established that the study of amplification of STS markers in various pea genotypes at varying temperatures of annealing and the comparison with amplification of the original RAPD fragments in the same genotypes provide an approach for analysis of RAPD polymorphism type.     

Identification of SCAR marker linking to longer frond length of <Emphasis Type="Italic">Saccharina japonica</Emphasis> (Laminariales,Phaeophyta) using bulked-segregant analysis

To construct a molecular-marker-assisted selection (MAS) system, research was done on identifying molecular markers linking to longer frond length, a crucial selection index in the breeding of the commercially important seaweed Saccharina japonica. An F₂-segregant population of 92 individuals was obtained by crossing two prominent S. japonica strains. Genomic DNA from ten individuals with the longest frond and ten individuals with the shortest frond in the F₂-segregant population were mixed to create two DNA pools for screening polymorphic markers. In bulked-segregant analysis (BSA), out of 100 random amplified polymorphic DNA (RAPD) primers only two produced three polymorphic RAPD markers between the two DNA pools. In conversion of the three RAPD markers into sequence-characterized amplified region (SCAR) markers, only one was successfully converted into a SCAR marker FL-569 linking to the trait of longer frond. Test of the marker FL-569 showed that 80% of the individuals with longest fronds in a wild population and 87.5% of individuals with the longest fronds in an inbred line “Zhongke No. 2” could be detected by FL-569. Additionally, genetic linkage analysis showed that the SCAR marker could be integrated into the reported genetic map and QTL mapping showed that FL-569 linking to qL1-1. The obtained marker FL-569 will be beneficial to MAS in S. japonica breeding.     

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.     

Design of grapevine (Vitis vinifera L.) cultivar-specific SCAR primers for PCR fingerprinting

Among 34 grapevine cultivars (Vitis vinifera L.), eight putative genotype-specific RAPD markers, from ’Albariño’, ’Caíño blanco’, ’Chardonnay’, ’Folle blanche’, ’Grenache blanc’, ’Malvasía Sitges’, ’Torrontés’ and ’Treixadura’ respectively, were selected to transform into SCAR markers. Of these, seven markers were cloned and then five which showed a positive specific hybridization signal were sequenced. For these five markers, 30 sequence-specific primers ranging from 14 to 29 bases were designed to amplify genomic DNA from 64 grapevine cultivars under more-stringent PCR conditions. Only, two primer pairs, OpA11₁₁₇₅p17R/ p17F and OpD10₈₀₀p14R/p14F, still produced a specific SCAR marker, the ’Folle blanche’ ScA11₁₁₇₅ and the ’Malvasía Sitges’ ScD10₈₀₀ respectively. Moreover, the ScA11₁₁₇₅ marker was amplified only in ’Folle blanche’ among the 64 cultivars tested with a large annealing temperature range using either two different Taq DNA polymerases or two separate thermocyclers. In addition, we discuss the initial polymorphism originated by the RAPD technique and suggest a new design of SCAR primers to obtain reliable cultivar-specific SCAR markers from single PCR-based bands for identification purposes.     

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。     

Thinopyrum 7Ai-1-derived small chromatin with Barley Yellow Dwarf Virus (BYDV) resistance gene integrated into the wheat genome with retrotransposon

Thinopyrum intermedium is a useful source of resistance genes for Barley Yellow Dwarf Virus (BYDV), one of the most damaging wheat diseases. In this study, wheat/Th. intermedium translocation lines with a BYDV resistance gene were developed using the Th. intermedium 7Ai-1 chromosome. Genomic in situ hybridization (GISH), using a Th. intermedium total genomic DNA probe, enabled detection of 7Ai-1-derived small chro-matins containing a BYDV resistance gene, which were translocated onto the end of wheat chromosomes in the lines Y95011 and Y960843. Random amplified polymorphic DNA (RAPD) analyses using 120 random 10-mer primers were conducted to compare the BYDV-resistant translocation lines with susceptible lines. Two primers amplified the DNA fragments specific to the resistant line that would be useful as molecular markers to identify 7Ai-1-derived BYDV resistance chromatin in the wheat genome. Additionally, the isolated Th. intermedium-specific retrotransposon-like sequence pTi28 can be used to identify Th. intermedium chromatin transferred to the wheat genome.     

The Development of 7E Chromosome-Specific Molecular Markers for Thinopyrum elongatum Based on SLAF-seq Technology

Thinopyrum elongatum is an important relative of wheat, it is favored by many researchers for the disease resistant genes that exist in its E genome. Some studies have showed that the 7E chromosome of Th. elongatum contains resistance genes related to Fusarium head blight and wheat rust. Therefore, developing 7E chromosome-specific molecular markers linked to resistance genes will provide an important tool for exploring and using the resistant genes of Th. elongatum. In addition, it would greatly contribute in the effort to cultivate disease-resistant wheat varieties. Featured in high throughput, high-accuracy and low-cost, SLAF-seq technology has been widely used in molecular breeding, system evolution, and germplasm resource detection. Based on SLAF-seq, 518 specific fragments on the 7E chromosome of Th. elongatum were successfully amplified. A total of 135 primers were designed according to 135 randomly selected fragments, and 89 specific molecular markers of Th. elongatum were developed, with efficiencies up to 65.9%. These markers were all detected in a variety of materials, and they are all proved to be specific and stable. These markers can be used not only for detecting the 7E chromosome of Th. elongatum but also for providing an important theoretical and practical basis for wheat breeding by marker-assisted selection (MAS). This paper reports the first application of SLAF-seq technology with a high success rate in developing specific molecular markers for Th. elongatum, providing a strong case for the application of this new technology.