Patterns of inheritance with RAPD molecular markers reveal novel types of polymorphism in the honey bee

Summary The polymerase chain reaction (PCR) was used to generate random amplified polymorphic DNA (RAPD) from honey bee DNA samples in order to follow the patterns of inheritance of RAPD markers in a haplodiploid insect. The genomic DNA samples from two parental bees, a haploid drone and a diploid queen, were screened for polymorphism with 68 different tennucleotide primers of random sequence. Parents were scored for the presence or absence of individual bands. An average of 6.3 bands and 1.3 polymorphisms for presence/absence were observed per primer between the parents. Thirteen of these primers were used to determine the inheritance of RAPD marker alleles in the resulting progeny and in haploid drones from a daughter queen. Four types of polymorphisms were observed. Polymorphisms for band presence/absence as well as for band brightness were inherited as dominant markers, meeting Mendelian expectations in haploid and diploid progeny. Polymorphisms for fragment-length were also observed. These segregated in a near 11 ratio in drone progeny. The last type of polymorphism was manifested as a diploid-specific band. Mixing of amplification products after PCR showed that the diploid-specific band was the result of heteroduplex formation from the DNA of alternate alleles in heterozygotes. In two of the four cases of heteroduplex formation, the alternative alleles were manifested as small fragment-length polymorphisms, resulting in co-dominant markers. This is the first demonstration that a proportion of RAPD markers are not inherited in a dominant fashion.     

Genetic Mapping of Soybean [Glycine max (L.) Merr.] Using Random Amplified Polymorphic DNA (RAPD)

Random amplified polymorphic DNA (RAPD) is based on DNA amplification by polymerase chain reaction (PCR) of random DNA segments using single arbitrary nucleotide sequences. We have adapted the assay to soybeans by using Stoffel Fragment DNA polymerase and by optimizing the reaction conditions. To increase the percentage of RAPD polymorphisms, the DNA template was digested with restriction enzymes before amplification. The combination of twenty-four primers and five DNA template treatments (Undigested, DraI, EcoRI, HindIII, and TaqI digested) revealed 94 polymorphic DNA fragments differing between soybean lines PI437654 and BSR101. Many polymorphic DNA bands were found unreliable or non-scoreable after re-screening of primers and verification of marker-allele segregation with 20 recombinant inbred lines (RILs). However, 28 RAPD markers were consistently polymorphic between the parental lines and followed Mendelian expectations. The use of DNA templates digested with DraI, EcoRI, HindIII or TaqI increased three times the number of RAPD markers compared to undigested DNA template alone. The 28 RAPD markers obtained were further screened with 72 RILs and placed on an existing RFLP map.     

Inheritance of polymorphic markers generated by DNA amplification fingerprinting and their use as genetic markers in soybean

DNA amplification fingerprinting (DAF) using a high primer-to-template ratio and single, very short arbitrary primers, was used to generate amplified fragment length polymorphic markers (AFLP) in soybean (Glycine max (L.) Merr.). The inheritance of AFLPs was studied using a cross between the ancestral Glycine soja PI468.397 and Glycine max (L.) Merr. line nts382, F1 and F2 progeny. The amplification reaction was carried out with soybean genomic DNA and 8 base long oligounucleotide primers. Silver-stained 5% polyacrylamide gels containing 7 M urea detected from 11 to 28 DAF products with primers of varying GC content (ranging from 50 to 100% GC). Depending on their intensity, AFLPs were classified into three classes. DAF profiles were reproducible for different DNA extractions and gels. Forty AFLPs were detected by 26 primers when comparing G. soja and G. max. Most AFLPs were inherited as dominant Mendelian markers in F1 and F2 populations. However, abnormal inheritance occured with about 25% of polymorphisms. One marker was inherited as a maternal marker, presumably originating from organelle DNA while another showed apparent paternal inheritance. To confirm the nuclear origin and utility of dominant Mendelian markers, three DAF polymorphisms were mapped using a F11 mapping population of recombinant inbred lines from soybean cultivars Minsoy × Noir 1. The study showed that DAF-generated polymorphic markers occur frequently and reliably, that they are inherited as Mendelian dominant loci and that they can be used in genome mapping.     

26种冬青属植物遗传多样性分析

以26种冬青属植物种质资源为研究材料,利用RAPD和AFLP技术对基因组DNA进行扩增,以研究其物种间遗传多样性以及亲缘关系.结果表明:在RAPD分析中,从400条10个碱基的寡核苷酸引物中筛选出反应稳定、扩增性强、重复性好的引物20个,共扩增出312条多态性条带,多态率为95.41%;聚类分析显示26种冬青属植物间,布利奥特夫人枸骨叶冬青和黄果在AFLP分析中,10对选择性引物组合均扩增出了丰富的多态性片段,共扩增出350条谱带,其中336条具有多态性,占95.96%.综合RAPD和AFLP聚类结果,枸骨、无刺枸骨和日拉斯纳尔逊枸骨的亲缘关系较近,钝齿冬青、金宝石钝齿冬青和龟甲冬青三者的亲缘关系较近,可为冬青属植物的杂交育种与种质创新提供理论依据.     

DNA polymorphisms amplified by arbitrary primers are useful as genetic markers.

Molecular genetic maps are commonly constructed by analyzing the segregation of restriction fragment length polymorphisms (RFLPs) among the progeny of a sexual cross. Here we describe a new DNA polymorphism assay based on the amplification of random DNA segments with single primers of arbitrary nucleotide sequence. These polymorphisms, simply detected as DNA segments which amplify from one parent but not the other, are inherited in a Mendelian fashion and can be used to construct genetic maps in a variety of species. We suggest that these polymorphisms be called RAPD markers, after Random Amplified Polymorphic DNA.     

Qualitative and quantitative characterization of RAPD variation among snap bean (Phaseolus vulgaris) genotypes

Ten snap bean (Phaseolus vulgaris) genotypes were screened for polymorphism with 400 RAPD (random amplified polymorphic DNA) primers. Polymorphic RAPDs were scored and classified into three categories based on ethidium bromide staining intensity. An average of 5.19 RAPD bands were scored per primer for the 364 primers that gave scorable amplification products. An average of 2.15 polymorphic RAPDs were detected per primer. The results show that primer screening may reduce the number of RAPD reactions required for the analysis of genetic relationships among snap-bean genotypes by over 60%. Based on the analysis of the distribution of RAPD amplification, the same number of polymorphic RAPDs were amplified from different genotypes for all RAPD band intensity levels. A comparison of RAPD band amplification frequency among genotypes for the three categories of bands classified by amplification strength revealed a measurable difference in the frequencies of RAPDs classified as faint (weakly amplifying) compared to RAPD bands classified as bold (strongly amplifying) indicating a possible scoring error due to the underscoring of faint bands. Correlation analysis showed that RAPD bands amplified by the same primer are not more closely correlated then RAPD bands amplified by different primers but are more highly correlated then expected by chance. Pairwise comparisons of RAPD bands indicate that the distribution of RAPD amplification among genotypes will be a useful criterion for establishing RAPD band identity. For the average pairwise comparison of genotypes, 50% of primers tested and 15.8% of all scored RAPDs detected polymorphism. Based on RAPD data Nei's average gene diversity at a locus was 0.158 based on all scorable RAPD bands and 0.388 if only polymorphic RAPD loci were considered. RAPD-derived 1 relationships among genotypes are reported for the ten genotypes included in this study. The data presented here demonstrate that many informative, polymorphic RAPDs can be found among snap bean cultivars. These RAPDs may be useful for the unique identification of bean varieties, the organization of bean germplasm, and applications of molecular markers to bean breeding.     

Detection of DNA polymorphisms within the genusCattleya (Orchidaceae)

We have adapted methodology necessary for the detection of molecular polymorphisms in the orchid genusCattleya, namely, randomly amplified polymorphic DNA (RAPD). We report a high level of molecular variability among species; each of eight species examined exhibited a unique DNA fingerprint with nine out of ten arbitrary primers used in single-primer RAPD reactions. Among progeny of an intraspecificCattleya cross, 55 percent of major amplification products were found to segregate. Segregation of these markers facilitated the preliminary identification of several linkage intervals. The identification and mapping of DNA polymorphisms by the RAPD technique will facilitate the use of these taxa for the identification of species-specific and genus-specific traits, allow for the measurement of recombination and introgression in hybrid populations, and enable geneticists to address concordance (or lack thereof) in the processes of speciation, morphological evolution, and molecular change in a large and highly advanced plant family.     

Development of reliable PCR-based markers linked to downy mildew resistance genes in lettuce

Summary Sequence characterized amplified regions (SCARs) were derived from eight random amplified polymorphic DNA (RAPD) markers linked to disease resistance genes in lettuce. SCARs are PCR-based markers that represent single, genetically defined loci that are identified by PCR amplification of genomic DNA with pairs of specific oligonucleotide primers; they may contain high-copy, dispersed genomic sequences within the amplified region. Amplified RAPD products were cloned and sequenced. The sequence was used to design 24-mer oligonucleotide primers for each end. All pairs of SCAR primers resulted in the amplification of single major bands the same size as the RAPD fragment cloned. Polymorphism was either retained as the presence or absence of amplification of the band or appeared as length polymorphisms that converted dominant RAPD loci into codominant SCAR markers. This study provided information on the molecular basis of RAPD markers. The amplified fragment contained no obvious repeated sequences beyond the primer sequence. Five out of eight pairs of SCAR primers amplified an alternate allele from both parents of the mapping population; therefore, the original RAPD polymorphism was likely due to mismatch at the primer sites.     

Genetic variation detected with RAPD markers among upland and lowland rice cultivars (Oryza sativa L.)

Genetic variation of nine upland and four lowland rice cultivars (Oryza sativa L.) was investigated at the DNA level using the randomly amplified polymorphic DNA (RAPD) method via the polymerase chain reaction (PCR). Forty-two random primers were used to amplify DNA segments and 260 PCR products were obtained. The results of agarosegel electrophoretic analysis of these PCR products indicated that 208 (80%) were polymorphic. All 42 primers used in this experiment were amplified and typically generated one-to-four major bands. Only two primers showed no polymorphisms. In general, a higher level of polymorphism was found between japonica and indica subspecies while fewer polymorphisms were found between upland and lowland cultivars within the indica subspecies. A dendrogram that shows the genetic distances of 13 rice cultivars was constructed based on their DNA polymorphisms. Classification of rice cultivars based on the results from the RAPD analysis was identical to the previous classification based on isozyme analysis. This study demonstrated that RAPD analysis is a useful tool in determining the genetic relationships among rice cultivars.     

Random amplified polymorphic DNA (RAPD) identification of genetic variation in three species ofPorphyra (Bangiales,Rhodophyta)

The random amplified polymorphic DNA (RAPD) technique was used to characterize three species ofPorphyra from the western North Atlantic and adjacent Gulf of Mexico. Twenty 10-mer primers were screened for DNA amplification usingPorphyra template DNA. Nine of these oligonucleotide primers, all (G+C)-rich, were positive or band-producing, but yielded poor or variable band resolution. Subsequent use of the universal 20-mer M 13 primer resulted in both clear band resolution with a minimum of secondary bands and a high degree of reproducibility. Amplification products for DNA from six regional isolates ofPorphyra carolinensis Coll et Cox,P. leucosticta Thuret in Le Jolis andP. rosengurttii Coll et Cox were compared to each other and toBangia atropurpurea (Roth) C. Agardh. Results provide evidence of both genetically hetero- and homogeneous populations. Use of the RAPD method with the M 13 primer yields amplification products which can be used to fingerprint specific genotypes. This procedure could be used to discriminate between hetero- and homokaryotic fusion products from previously characterized donor strains.     

Random amplified polymorphic DNA (RAPD) markers in hop, Humulus lupulus: level of genetic variability and segregation in F1 progeny

The level of genetic variation in 24 hop genotypes was studied using the recently developed technique for producing random amplified polymorphic DNAs (RAPDs). Of the 60 primers screened, eight produced polymorphic RAPD bands, 38 produced bands that were monomorphic for all genotypes and 19 did not produce any amplification product. It appeared that the level of polymorphism among the genotypes was generally low. Three of the primers, A11, A17 and C9, were used to determine the stability and segregation of RAPD markers in five families with a total of 182 F₁ progeny. The segregation ratios of these markers in the f₁ progeny suggested that they were inherited in a Mendelian manner. RAPD markers were stable and may be useful for the construction of linkage maps in hop.     

一种新的分子标记方法－随机微卫星扩增多态DNA (RMAPD)

随机微卫星扩增多态DNA（RMAPD）是利用随机引物和微卫星的上游或下游引物一起作为该扩增的引物,在Taq DNA聚合酶、MgCl2、dNTPs和模板DNA等共同作用下进行PCR扩增的一种新型分子标记方法。其核心是RMAPD引物的有效性问题。通过对西农萨能奶山羊群体RMAPD电泳检测、数据统计分析及验证实验等证明RMAPD的引物是有效的。通过与微卫星和RAPD标记比较,发现RMAPD标记在扩增引物、扩增程序和重复性等方面区别于微卫星和RAPD标记;它是RAPD标记的一种广义的延伸,但又不完全等同于RAPD标记。因此,确定RMAPD是一种新的分子标记方法。该方法也具有DNA标记的特点,在群体遗传结构和亲缘关系分析以及标记辅助选择等遗传育种领域具有广阔的应用前景。     

Detection of DNA polymorphism among pea cultivars using RAPD technique

An influence of some Random Amplified Polymorphic DNA (RAPD) reaction factors on resulting banding pattern and the ability of RAPD technique to detect DNA polymorphism among six economically important pea cultivars was tested. Relatively high level of DNA polymorphism among peas was observed, using polyacrylamide/urea gels and silver staining. Altogether 13 arbitrarily designed primers produced 313 amplification products. In addition 59 polymorphisms were found. These polymorphisms can serve as potential genetic markers. RAPD data were processed using cluster analysis and plotted as dendrogram. Each tested cultivar was clearly distinguished from the others. Moreover,Pisum sativum andP. sativum subsp.arvense cultivars were separated into 2 different clusters, according to their systematic relationships.     

RAPD双引物在构建红麻连锁图谱中的应用研究

以阿联红麻（Alian Kenaf）与福红992（Fuhong992）杂交产生的F2代作图群体为研究材料,分别应用RAPD单引物和双引物进行多态性条带扩增,并进行扩增效果的比较研究,以期为作图群体构建红麻遗传连锁图谱奠定基础。结果表明,RAPD双引物比单引物扩增出更多的多态性条带,提高了引物的利用率和多态性条带的扩增效率。     

A preliminary study in the use of RAPD markers in detecting genetic differences in hatching patterns of Chirocephalus diaphanus Prévost, 1803 (Crustacea: Anostraca)

Randomly amplified polymorphic DNA (RAPD) was used to detect intra-clutch genetic differences of the anostracan Chirocephalus diaphanus Prévost, 1803. Thirty primers were tested on 130 nauplii from three different clutches. Two primers produced five repeatable and well-defined amplification products, that were used as genotype markers. Nauplii hatched after three successive dehydration and rehydration cycles. Consistent genetic differentiation was observed among nauplii from the same clutch. Significant association between presence or absence of three polymorphic amplification products and hatching after different stimuli was observed. These results suggest that RAPD markers might be related to the difference in nauplii hatching and provide reasonable support to the hypothesis that the source of the observed variation in hatching phenology are genetic as well as epigenetic.     

Detection of DNA polymorphism among pea cultivars using RAPD technique

An influence of some Random Amplified Polymorphic DNA (RAPD) reaction factors on resulting banding pattern and the ability of RAPD technique to detect DNA polymorphism among six economically important pea cultivars was tested. Relatively high level of DNA polymorphism among peas was observed, using polyacrylamide/urea gels and silver staining. Altogether 13 arbitrarily designed primers produced 313 amplification products. In addition 59 polymorphisms were found. These polymorphisms can serve as potential genetic markers. RAPD data were processed using cluster analysis and plotted as dendrogram. Each tested cultivar was clearly distinguished from the others. Moreover,Pisum sativum andP. sativum subsp.arvense cultivars were separated into 2 different clusters, according to their systematic relationships.     

Error Rates and Polymorphism Frequencies for Three RAPD Protocols

Three amplification protocols were analyzed for error rate and generation of polymorphisms during RAPD analysis. Using a set of 240 primers, the protocols detected similar frequencies of polymorphisms in two inbred sugar beet lines. The error rate was investigated by including a 1:1 mixture of DNA from the two lines in all analyses. Similar error rates, approximately 18%, were detected by the three protocols. Thus, altered amplification conditions did not substantially affect the error rate during RAPD analysis. For each of the three possible pairs of protocols, a positive correlation was obtained for primer and number of polymorphisms. Thus, a set of highly polymorphic RAPD primers can be used effectively, without prior screening, to detect polymorphisms for each protocol.     

Restriction Endonuclease Digestion of Amplification Products Generated by RAPD Technique in a Population of Glycine soja

n a population of Glycine soja L., the polymorphic loci could be hardly detected by RAPD markers, using several primers. These non-polymorphic amplification products were cleaved by some restriction endonuclease, such as Msp Ⅰ , Hinf Ⅰ , Taq Ⅰ , EcoR Ⅰ , Sal Ⅰ , Dra Ⅰ and Hae Ⅲ. After cleaving, the digested amplification products were detected on polyacrylamide gel electrophoresis with silver staining. It was found that: 1 ) some restriction endonucleases could not, and some others could effectively digest the random amplication products of the DNAs of G. soja; 2) some endonucleases could produce polymorphic DNA fragments after digestion of the non-poly-morphic products, but others could not even after digestion; 3) non-polymorphic amplification products amplified by some primers could produce polymorphic DNA fragments after digestion, while those by other primers could not. It could be concluded that the restriction endonuclease digestion of amplification products could increase significantly detectability of polymorphic DNA by RAPDs technique.     

Identification of a RAPD marker linked to progressive rod-cone degeneration in dogs

Random amplified polymorphic DNA (RAPD) analysis has been used widely in plant and fungi for identification of markers linked to genetic traits and mapping, but its use is limited to identification of intra- and inter-species difference in domestic mammals. We report here identification of a RAPD-derived marker linked to progressive rod-cone degeneration (prcd), an inherited autosomal recessive retinal disease of dogs. A total of 400 standard 10-mer primers were used for amplification by use of DNA samples from normal (+/+) and affected (prcd/prcd) dogs. A single primer was identified which amplified a 1.5-kb DNA fragment only from normal dogs. PCR with longer primers designed from the sequence-characterized amplified region of the 1.5-kb DNA fragment identified a co-dominant multi-allelic polymorphism in the prcd-informative pedigree. Three recombinants were identified among 34 informative offsprings, yielding a LOD score of 5.568 at θ= 0.091. This marker was mapped to two canine–rodent hybrid cell lines in which two genes (canine homologues of human breast cancer 1 susceptibility gene, and cGMP phosphodiesterase γ-subunit gene), and three anonymous microsatellites have been identified. This is the first reported identification of a RAPD-derived marker with multiple alleles linked to a mammalian disease locus. Received: 20 February 1998 / Accepted: 24 April 1998     

Optimization of RAPD‐PCR conditions in cattle

Abstract

Random Amplified Polymorphic DNA polymerase chain reaction (RAPD‐PCR) is a fast and easy way of identifying DNA polymorphisms generated from several regions of the genome. This could expedite the process of identifying informative polymorphic markers that may be linked to important genes controlling economic traits. In cattle, failure to obtain consistent amplification patterns in RAPD‐PCR has been a cause for concern. This has been attributed to the fact that decamer primers that are used in RAPD‐PCR reactions are likely to amplify regions of DNA where the primer‐template base pairing has some degree of mismatch and that these mismatches fail to repeat from reaction to reaction. This paper describes the use of tricine buffer along with changes in reaction components and thermal cycling conditions that has yielded consistent and reproducible RAPD‐PCR amplifications using single primers and double primer combinations on bovine DNA.