Rapid identification of white-Engelmann spruce species by RAPD markers

Fragments of random amplified polymorphic DNA (RAPDs) were used as markers to distinguish Picea glauca (Moench) Voss (white spruce) and Picea engelmannii Parry (Engelmann spruce). These species and their putative hybrids are difficult to differentiate morphologically and are collectively known as interior spruce. Four oligodeoxynucleotide decamer primers showed species-specific amplification products between white spruce and Engelmann spruce. These fragments are highly conserved among seed lots and individual trees of each species from diverse geographic origins. The consistency and reproducibility of these species-specific amplification products were tested in more than two amplification reactions. Therefore, RAPD markers can provide genetic markers for easy and rapid identification of the specific genetic entry of these spruce species and their reported putative hybrids. According to the frequencies of the species-specific RAPD markers, it is possible to estimate the hybrid fraction, indicative of true introgression between the two species. These results are useful for quick identification of both species and their hybrid swarms at any stage in the sporophyte phase of the life cycle, for determining the occurrence and the magnitude of introgressive hybridization in an overlap zone between the two species, and for certification purposes in operational re-forestation and tree-improvement programs.     

Comparison of RFLP and RAPD markers to estimating genetic relationships within and among cruciferous species

Restriction fragment length polymorphism (RFLP) and random amplified polymorphic DNA (RAPD) markers are being used widely for evaluating genetic relationships of crop germplasm. Differences in the properties of these two markers could result in different estimates of genetic relationships among some accessions. Nuclear RFLP markers detected by genomic DNA and cDNA clones and RAPD markers were compared for evaluating genetic relationships among 18 accessions from six cultivated Brassica species and one accession from Raphanus sativus. Based on comparisons of genetic-similarity matrices and cophenetic values, RAPD markers were very similar to RFLP markers for estimating intraspecific genetic relationships; however, the two marker types gave different results for interspecific genetic relationships. The presence of amplified mitochondrial and chloroplast DNA fragments in the RAPD data set did not appear to account for differences in RAPD- and RFLP-based dendrograms. However, hybridization tests of RAPD fragments with similar molecular weights demonstrated that some fragments, scored as identical, were not homologous. In all these cases, the differences occurred at the interspecific level. Our results suggest that RAPD data may be less reliable than RFLP data when estimating genetic relationships of accessions from more than one species.     

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.     

Differentiation of isolates of Discula umbrinella (Teleomorph: Apiognomonia errabunda) from beech, chestnut, and oak using randomly amplified polymorphic DNA markers.

Genetic variation in 30 isolates of Discula umbrinella derived from beech, chestnut, and oak was assessed using randomly amplified polymorphic DNA (RAPD) and restriction fragment length polymorphic markers. Polymerase chain reaction amplifications with 17 primers produced 134 different DNA fragments. Three RAPD fragments were subsequently used for Southern hybridization. By these techniques up to four different individuals could be detected in the same leaf. The presence of several individuals within a single leaf indicates a finely tuned balance between the endophyte and its host. Cluster analysis of all arbitrary primed amplified DNA fragments showed that the isolates could be placed into four groups corresponding to their host origin. The high percentage of private RAPD variants within groups is consistent with low gene flow.     

Detection of section-specific random amplified polymorphic DNA (RAPD) markers in Lilium

Random amplified polymorphic DNA (RAPD) markers were utilized for the identification of Lilium species and inter-specific hybrids. The optimum annealing temperature of the polymerase chain reaction (PCR) for the RAPD assay in Lilium was 54 °C, which is relatively higher than the temperature used for other genera reported by previous researchers. Among 76 primers used to amplify genomic DNA by PCR, 18 primers (24%) generated polymorphic DNA fragments in Lilium species and hybrids. Cultivars were also identified by RAPD markers. Some amplified fragments were unique to species of each section and to hybrids derived from these species; that is, they were the section-specific DNA markers. Sections, Sinomartagon, Leucolirion b, Leucolirion a and Archelirion could be identified by 6 section-specific markers amplified with five primers. Seven inter-section hybrids showed the section-specific bands of both parental sections, indicating that these markers would be useful for identifying the parental sections of inter-section hybrids.     

Identification of RAPD markers linked to a fertility restorer gene for theOgura radish cytoplasmic male sterility of rapeseed (Brassica napus L.)

Bulked segregant analysis was employed to identify random amplified polymorphic DNA (RAPD) markers linked to the restorer gene (Rfo) used in theOgura radish cytoplasmic male sterility of rapeseed. A total of 138 arbitrary 10-mer oligonucleotide primers were screened on the DNA of three pairs of bulks, each bulk corresponding to homozygous restored and male sterile plants of three segregating populations. Six primers produced repeatable polymorphisms between paired bulks. DNA from individual plants of each bulk was then used as a template for amplification with these six primers. DNA polymorphisms generated by four of these primers were found to be completely linked to the restorer gene with the polymorphic DNA fragments being associated either with the fertility restorer allele or with the sterility maintainer allele. Pairwise cross-hybridization demonstrated that the four polymorphic DNA fragments did not share any homology. Southern hybridization of labelled RAPD fragments on digested genomic DNA from the same three pairs of bulks revealed fragments specific to either the male sterile bulks or to the restored bulks and a few fragments common to all bulks, indicating that the amplified sequences are low copy. The four RAPD fragments that were completely linked to the restorer locus have been cloned and sequenced to develop sequence characterized amplified regions (SCARs). This will facilitate the construction of restorer lines used in breeding programs and is the first step towards map-based cloning of the fertility restorer allele.     

用RAPD和AFLP的方法对中国卤虫(Artemia)种及亲缘关系的研究

利用ＲＡＰＤ（随机扩增多态ＤＮＡ）和ＡＦＬＰ（扩增片段长度多态性）技术对不同种及种群卤虫的关系进行分析。 １０１个随机引物对４种卤虫Ａｆｒａｎｃｉｓｃａｎａ、Ａ ｕｒｍｉａｎａ、Ａ ｓｉｎｉｃａ和Ａ．ｐａｒｔｈｅｎｏｇｅｎｅｌｉｃａ基因组ＤＮＡ进行扩增,平均每个种获得７５１条带,其中４５８条带为多态性标记,每个引物提供平均７４个标记信息,聚类结果表明Ａ．ｓｉｎｉｃａ是不同于其他旧大陆两性生殖卤虫的一个独立的种。对来自 １５个种及品系的卤虫的 ＡＦＬＰ分析显示了非常好的遗传多态性,采用 １２对引物检测到 ５９４条带,其中 ４８０个为多态性标记。聚类结果表明来自西藏的两性生殖卤虫为不同于中国内陆两性生殖卤虫的新种。而孤雌生殖卤虫在进化过程中可能是多源的,中国内陆和沿海的孤雌生殖卤虫是沿着不同的途径进化的,内陆和沿海的孤雌生殖卤虫可能为不同的种。     

RAPD identification of microsatellites in Daphnia

Simple sequence repeats (SSRs, or microsatellites) have been constantly gaining importance as single-locus DNA markers in population genetics and behavioural ecology. We tested a PCR-based strategy for finding microsatellite loci in anonymous genomes, which avoids genomic library construction and screening, and the need for larger amounts of DNA. In the first step, parts of a genome are randomly amplified with arbitrary 10mer primers using RAPD fingerprinting. Labelled SSR-oligonucleotides serve as probes to detect complementary sequences in RAPD products by means of Southern analyses. Subsequently, positive RAPD fragments of suitable size are cloned and sequenced. Using GA and GT probes, we applied this approach to waterfleas ( Daphnia ) and revealed 37 hybridization signals in 20 RAPD profiles. Thirteen positive RAPD fragments from three Daphnia species and two hybrid 'species' were cloned and sequenced. In all cases simple sequence repeats were detected. We characterized seven perfect repeat loci, which were found to be polymorphic within and between species.     

Identification of RAPD markers linked to A and B genome sequences in Musa L.

Plantains and bananas (Musa spp. sect. eumusa) originated from intra- and interspecific hybridization between two wild diploid species, M. acuminata Colla. and M. balbisiana Colla., which contributed the A and B genomes, respectively. Polyploidy and hybridization have given rise to a number of diploid, triploid, and tetraploid clones with different permutations of the A and B genomes. Thus, dessert and highland bananas are classified mainly as AAA, plantains are AAB, and cooking bananas are ABB. Classification of Musa into genomic groups has been based on morphological characteristics. This study aimed to identify RAPD (random amplified polymorphic DNA) markers for the A and B genomes. Eighty 10-mer Operon primers were used to amplify DNA from M. acuminata subsp. burmannicoides clone 'Calcutta 4' (AA genomes) and M. balbisiana clone 'Honduras' (BB genomes). Three primers (A17, A18, and D10) that produced unique genome-specific fragments in the two species were identified. These primers were tested in a sample of 40 genotypes representing various genome combinations. The RAPD markers were able to elucidate the genome composition of all the genotypes. The results showed that RAPD analysis can provide a quick and reliable system for genome identification in Musa that could facilitate genome characterization and manipulations in breeding lines.     

Genetic validity of RAPD markers at the intra- and inter-specific level in wild Brassica species with n=9

The sequence homology of co-migrating RAPD markers within a genus, across species, and among populations of a species was investigated. DNA was isolated from ten wild Brassica species with n=9 and the RAPD patterns were established using three random primers. Five RAPD markers which appeared to be characteristic for the n=9 species (genus level), four markers which appeared to be species specific, and one population-specific marker were isolated from agarose gels and hybridized to the RAPD profiles of the ten Brassica species. Two RAPD markers were cloned for comparison with gel-isolated RAPD fragment probes in hybridization experiments. Non-specific and background hybridization, occurring when gel-isolated fragments were used as probes, disappeared when cloned fragments were used. A total of 250 RAPD-marker hybridizations were scored according to visual presence or absence in a gel lane. All except three markers hybridized as expected, resulting in an error rate of 1.2%. The deviating results included a lack of hybridization although a band was visible in the gel, a length polymorphism for one marker, and a dual hybridization signal for two single-band markers.     

RAPD-marking of genomes of representative Hordeum species

Random amplification of polymorphic DNA (RAPD) was used to analyze six species, three populations, and seven regional cultivars of barley. A unique pattern of amplified DNA products was obtained for each species of the genus Hordeum. High polymorphism of barley species was revealed. Specific fragments were found in most RAPD patterns; the fragments can be used as molecular markers of corresponding species and subspecies. Several other DNA fragments were shown to serve as molecular markers of the H genome. Specific RAPD patterns were obtained for each population and each cultivar of H. vulgare sensu lato. In total, variation between the populations and between the cultivars was substantially lower than between species. Cluster analysis (UPGMA) was used to estimate genetic distances between the Hordeum species, between the H. spontaneum populations, and between regional H. vulgare cultivars and a dendrogram was constructed.     

Genetic segregation of random amplified polymorphic DNA in diploid cultivated alfalfa.

Polymerase chain reaction was used, with single 10-mer primers of arbitrary sequence, to amplify random regions of genomic DNA from a diploid cultivated alfalfa backcross population. Segregation of the random amplified polymorphic DNA (RAPD) fragments was analysed to determine if RAPD markers are suitable for use as genetic markers. Of the 19 primers tested, 13 amplified a total of 37 polymorphic fragments, of which 28 (76%) segregated as dominant Mendelian traits. RAPD markers appear useful for the rapid development of genetic information in species like alfalfa where little information currently exists or is difficult to obtain.     

Genetic relationships and discrimination of ten influential Upland cotton varieties using RAPD markers

Influential Upland cotton ( Gossypium hirsutum L.) varieties are those that have the higher genetic contributions to modern Upland cultivars than other germplasms. Our previous research has shown significant differences in general combining ability (GCA) effects for yield, yield components, and fiber properties among ten influential cotton varieties. In this study, we used random amplified polymorphic DNA (RAPD) data to evaluate DNA variation of these ten varieties. Of 86 random decamer primers screened for their capability of amplifying DNA via the polymerase chain reaction (PCR), 63 generated a total of 312 DNA fragments. Forty two bands were polymorphic, which showed a low percentage (13.5%) of DNA variation among these influential varieties. Genetic similarities among the ten varieties based on RAPD data were from 92.7% to 97.6%. All of the varieties were individually identified by variety specific markers in genetic fingerprinting. One primer, UBC-149, amplified a 1,430-bp DNA fragment that was absent in five varieties and present in the other five varieties. This RAPD marker had significant negative relationships with GCA-effect estimates for seed cotton yield, lint yield, number of bolls per plant and micronaire, and significant positive relationships with GCA effects for boll size and seed index. This finding, for the first time, identifies a DNA fragment in cotton that is a potential DNA marker linked to a yield gene(s) or a yield-related gene(s).     

Molecular characterization and identification of markers for toxic and non-toxic varieties of <Emphasis Type="Italic">Jatropha curcas</Emphasis> L. using RAPD,AFLP and SSR markers

Jatropha curcas L., a multipurpose shrub has acquired significant economic importance for its seed oil which can be converted to biodiesel, is emerging as an alternative to petro-diesel. The deoiled seed cake remains after oil extraction is toxic and cannot be used as a feed despite having best nutritional contents. No quantitative and qualitative differences were observed between toxic and non-toxic varieties of J. curcas except for phorbol esters content. Development of molecular marker will enable to differentiate non-toxic from toxic variety in a mixed population and also help in improvement of the species through marker assisted breeding programs. The present investigation was undertaken to characterize the toxic and non-toxic varieties at molecular level and to develop PCR based molecular markers for distinguishing non-toxic from toxic or vice versa. The polymorphic markers were successfully identified specific to non-toxic and toxic variety using RAPD and AFLP techniques. Totally 371 RAPD, 1,442 AFLP markers were analyzed and 56 (15.09%) RAPD, 238 (16.49%) AFLP markers were found specific to either of the varieties. Genetic similarity between non-toxic and toxic verity was found to be 0.92 by RAPD and 0.90 by AFLP fingerprinting. In the present study out of 12 microsatellite markers analyzed, seven markers were found polymorphic. Among these seven, jcms21 showed homozygous allele in the toxic variety. The study demonstrated that both RAPD and AFLP techniques were equally competitive in identifying polymorphic markers and differentiating both the varieties of J. curcas. Polymorphism of SSR markers prevailed between the varieties of J. curcas. These RAPD and AFLP identified markers will help in selective cultivation of specific variety and along with SSRs these markers can be exploited for further improvement of the species through breeding and Marker Assisted Selection (MAS).     

Genetic variation in monoploids of diploid potatoes and detection of clone-specific random amplified polymorphic DNA markers

Randomly amplified polymorphic DNA (RAPD) markers have been used to study the genetic variation among androgenetic monoploids of diploid Solanum species. Cluster analysis of pairwise genetic distances was used to construct a genetic relationship among anther donor and anther-derived potato plants. The clustering based on Rogers' distances resembled classifications based on parental origins and hybrid combinations. Six of the 32 RAPD primers used resulted in the selective amplification of DNA fragments which were polymorphic between the two S. phureja parental clones, 1.22 and A95. It should be possible to construct a genetic linkage map, without making crosses, using monoploids derived from a single heterozygous diploid clone and RAPD markers.     

Identification of larch species (Larix decidua, Larix kaempferi and Larix X eurolepis) and estimation of hybrid fraction in seed lots by RAPD fingerprints

Species-specific RAPD markers were used to identify the different larch species (Larix decidua and Larix kaempferi) and their interspecific hybrid (Larix X eurolepis). Although morphological differences between pure species and the hybrids exist, differentiation is not always possible, especially at an early stage (seed or plantlet). Eleven RAPD markers differentiated the two larch species, and 4 species-specific markers were sufficient to estimate the F₁ hybrid fraction in a seed lot. The species-specific markers were tested on individual trees of European and Japanese larches of diverse geographic origins and on several seed lots of different origins (F₁, F₂ hybrids and pure species). The 4 specific markers found for the European larch and the Japanese larch were monomorphic and present in all provenances and in all F₁ hybrid trees tested. Polymorphic SCAR fragments were obtained for 3 of the 11 fragments originally selected for the RAPD screening phase. For 2 of them, the sequence had some homology with the mitochondrial genome of other organisms and is thus mitochondrial. The two mitochondrial fragments and the OPF-13₁₀₀₀ fragment exhibited one polymorphic band, thereby maintaining its species-specific identity: OPF-13₁₀₀₀ is specific to the European larch. The 4 RAPD primers selected in this study offer a reliable, quick and cheap tool for the identification of different larch species (Larix decidua and Larix kaempferi) and their interspecific hybrid (Larix X eurolepis). Received: 28 February 1999 / Accepted: 29 April 1999     

Development and utilization of new sequenced characterized amplified region markers specific for E genome of Thinopyrum

Species containing E genome of Thinopyrum offered potential to increase the genetic variability and desirable characters for wheat improvement. However, E genome specific marker was rare. The objective of the present report was to develop and identify sequenced characterized amplified region (SCAR) markers that can be used in detecting E chromosome in wheat background for breeding purpose. Total 280 random amplified polymorphic DNA (RAPD) primers were amplified for seeking of E genome specific fragments by using the genomic DNA of Thinopyrum elongatum and wheat controls as templates. As a result, six RAPD fragments specific for E genome were found and cloned, and then were converted to SCAR markers. The usability of these markers was validated using a number of Egenome-containing species and wheat as controls. These markers were subsequently located on E chromosomes using specific PCR and fluorescence in situ hybridization (FISH). SCAR markers developed in this research could be used in molecular marker assisted selection of wheat breeding with Thinopyrum chromatin introgressions.     

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.     

Random amplified polymorphic DNA in cattle and sheep: application for detecting genetic variation

The present study investigated the use of the random amplified polymorphic DNA (RAPD) method to detect genetic variation in cattle and sheep. The animals studied consisted of samples from five Finnish cattle breeds: native Eastern (18 animals), Northern (24), Western Finncattle (24), Finnish Ayrshire (24), and Finnish Friesian (18); as well as a white (6 animals) and a grey (9) colour type of Finnsheep. The cattle and sheep populations were analysed with 11 and 13 RAPD primers demonstrating the most repeatable amplification pattern. Two out of ten RAPD fragments tested by cross hybridization showed homology between the two species. The RAPD method did not prove efficient for finding new polymorphisms in either species, because we found only three polymorphic RAPD markers for cattle and seven markers for sheep with different allele frequencies between the breeds. Although there is a greater presence of polymorphic RAPD markers in sheep, according to the similarity indices the sheep populations showed a higher degree of homogeneity than the cattle breeds. However, the interbreed and intrabreed similarity indices for cattle did not suggest any significant differentiation of the Finnish breeds, contrary to earlier results based on blood group and protein polymorphism.     

Molecular Differentiation of Sexually Incompatible Strains of Agaricus bitorquis Using RAPD and AFLP Markers

Twenty RAPD primers amplified 216 DNA fragments in nine germplasm strains and two newly developed hybrids of Agaricus bitorquis, out of which 98.61% were polymorphic. Six AFLP primer-combinations generated a total of 271 AFLP fragments in nine germplasm strains and six newly developed hybrids, out of which 91.14% were polymorphic. Dendrograms based on UPGMA algorithm and SAHN clustering clearly showed two major phylogenetic groups with both the DNA markers in the germplasm and the hybrids clustered with their parental groups. Genetic similarity between the two groups was 6.52% with RAPD and 18.13% with AFLP markers. Ten most informative primers were identified for initial screening of uncharacterized germplasm using RAPD analysis. Further, AFLP revealed a great power of detection of genetic diversity and validated its usefulness for guiding breeding programmes. The findings are of immediate value to breeders to explore hybridization between genetically diverse parents within the sexually compatible groups. Present study is the first report on the exploitation of AFLP markers in button mushroom for molecular characterization and mushroom breeding.