Monitoring of the subtraction process in solid-phase representational difference analysis: characterization of a candidate drug.

In this study, we have applied and evaluated a modified cDNA representational difference analysis (RDA) protocol based on magnetic bead technology to study the molecular effects of a candidate drug (N,N'-diacetyl-L-cystine, DiNAC) in a model for atherosclerosis. Alterations in a gene expression profile induced by DiNAC were investigated in a human monocytic cell line (THP-1) differentiated into macrophage-like cells by lipopolysaccharide and further exposed to DiNAC. Three rounds of subtraction have been performed and the difference products from the second and third rounds have been characterized in detail by analysis of over 1000 gene sequences. Two protocols for analysis of the subtraction products have been evaluated, a shotgun approach and size selection of both distinct fragments and band-patterned smear. We demonstrate that in order to obtain a representative view of the most abundant gene fragments, the shotgun procedure is preferred. The obtained sequences were analyzed against the UniGene and Expressed Gene Anatomy Database (EGAD) databases and the results were visualized and analyzed with the ExProView software enabling rapid pair-wise comparison and identification of individual genes or functional groups of genes with altered expression levels. The identified differentially expressed gene sequences were comprised of both genes with known involvement in atherosclerosis or cholesterol biosynthesis and genes previously not implicated in these processes. The applicability of a solid-phase shotgun RDA protocol, combined with virtual chip monitoring, results in new starting points for characterization of novel candidate drugs.     

Isolation of YAC insert sequences by representational difference analysis.

We present a method for the isolation of YAC insert sequences by representational difference analysis (RDA). To achieve maximal representation of the sequences, the amplicons were generated from a Mbol digestion product. RDA was performed using a 970 kb insert YAC clone. After two rounds of re-association and selective amplification 92% of the difference product represented sequences derived from the YAC insert. Twenty insert-specific sequence-tagged sites were readily defined. The difference product was also successfully used to isolate microsatellite markers, to identify clones from a human PAC library and as a chromosome painting probe in fluorescence in situ hybridization.     

Mapping of porcine genetic markers generated by representational difference analysis

Representational difference analysis (RDA) was performed using pig genomic DNA from a Landrace non-selected control population and a Landrace population selected for increased loin muscle area (LMA) for five generations. Pigs used for the analysis differed phenotypically for various carcass traits and were divergent in genotype at the skeletal muscle ryanodine receptor 1 locus. Two RDA experiments were performed using BamHI and BglII. Fourteen BamHI and 37 BglII difference products were cloned and sequenced. Oligonucleotide primers were designed to amplify RDA difference products and sequence-tagged sites (STS) were developed for 16 RDA fragments (two BamHI and 14 BglII). These 16 STS were mapped using the INRA-Minnesota porcine Radiation Hybrid panel. Polymorphisms identified in nine of the STS were used to place these markers on the PiGMaP genetic linkage map. Sequence-tagged sites were localized to 11 different chromosomes including three markers on chromosome 11 and four markers on chromosome 14. Development of RDA markers increases the resolution of the pig genome maps and markers located within putative quantitative trait locus (QTL) regions can be used to refine QTL positions.     

Targeting of marker loci to chicken chromosome 16 by representational difference analysis

Representational difference analysis (RDA) was initially used to identify differences between two inbred lines of chickens, line N and line 15I, on which the Compton mapping reference population is based. RDA was subsequently used to identify marker loci targeted specifically to chicken chromosome 16. Chromosome 16 contains the major histocompatibility complex (MHC), nucleolar organiser region (NOR) and Rfp-Y complex. To generate markers specific for this chromosome a bird was selected from the Compton mapping reference population which had inherited N line alleles for the MHC, NOR and Rfp-Y regions on this chromosome. DNA from this bird was compared with pooled DNA from 16 of its siblings, all of which had inherited line 15I alleles for the MHC, NOR and Rfp-Y regions. Initially amplicons were derived from Bam HI digested samples, RDA products were cloned after the first round of hybridisation and 113 clones were investigated: 45 of these identified Bam HI polymorphisms in this population. Of the 45 polymorphic clones, 17 have been mapped in the reference population so far, and these have identified seven new loci on chromosome 16. Interestingly a group of 16 other loci were linked on chromosome 4. The same birds were also compared by RDA following digestion with Taq I. Again large numbers of clones were generated of which 65 were investigated. Of these 17 clones were polymorphic and of five clones mapped so far three lie on chromosome 16. Two of the loci mapped to chromosome 16 have been used to identify yeast artificial chromosome (YAC) clones (GenBank accession numbers: AF057302, AF057303, AF057304, AF063218, AF06347, AF06348, AF06349, AF06350, AF063#51, AF06353, AF06354, AF06355, AF06356).     

用RDA技术寻找肝再生相关基因的初步研究

利用表达性差异显示分析 (RDA)技术 ,研究大鼠 2 /3肝部分切除后 1h肝组织中基因的选择性表达 ,建立了大鼠 2 /3肝部分切除术后 1h再生肝组织选择性表达基因EST库。该库约含 3× 10 4 个独立克隆 ,其中 95 %以上的克隆含有插入片段 ,长度约 2 0 0～ 70 0bp不等 ,对随机挑出的 5 2个克隆的序列分析表明其中大多数基因与肝再生调控相关 (38/5 2 )。 10株未报道序列经RNA杂交证实 ,其中 6株与肝再生相关。     

Identifying differences in mRNA expression by representational difference analysis of cDNA.

Detection of differentially regulated genes has been severely hampered by technical limitations. In an effort to overcome these problems, the PCR-coupled subtractive process of representational difference analysis (RDA) [Lisitsyn, N. et al. (1993) Science 259, 946-951] has been adapted for use with cDNA. In a model system, RAG-1 and RAG-2, the genes responsible for activating V(D)J recombination, were identified in a genomic transfectant by cDNA RDA in a small fraction of the time taken by conventional means. The system was also modified to eliminate expected difference products to facilitate the identification of novel genes. Additional alterations to the conditions allowed isolation of differentially expressed fragments. Several caffeine up-regulated clones were obtained from the pre-B cell line 1-8, including IGF-1B, and a predicted homologue of the natural killer cell antigen, NKR-P1. The approach was found to be fast, extremely sensitive, reproducible, and predominantly lacked false positives. cDNA RDA has the capacity and adaptability to be applied to a wide range of biological problems, including the study of single gene disorders, characterization of mutant and complemented cell types, developmental or post-event expression time courses, and examination of pathogen-host interactions.     

Targeted mapping of rye chromatin in wheat by representational difference analysis.

A targeted mapping strategy using representational difference analysis (RDA) was employed to isolate new restriction fragment length polymorphism probes for the long arm of chromosome 6 in rye (6RL), which carries a gene for resistance to Hessian fly larvae. Fragments from the 6RL arm were specifically isolated using a 'Chinese Spring' (CS) wheat - rye ditelosomic addition line (CSDT6RL) as tester, and CS and (or) CS4R as the driver for the genomic subtraction. Three RDA experiments were performed using BamHI amplicons, two of which were successful in producing low-copy clones. All low-copy clones were confirmed to have originated from 6RL, indicating substantial enrichment for target sequences. Two mapping populations, both of which are derived from a cross between two similar wheat-rye translocation lines, were used to map five RDA probes as well as five wheat probes. One of the populations was prescreened for recombinants by C-banding analysis. Fifteen loci, including seven new RDA markers, were placed on a map of the distal half of 6RL. The Hessian fly resistance gene was localized by mapping and C-banding analysis to approximately the terminal 1% of the arm. The utility of RDA as a method of targeted mapping in cereals and prospects for map-based cloning of the resistance gene are discussed.     

用表达性差异显示分析技术分离人胎肝组织选择性表达基因

目的：建立4月龄人胎肝组织选择性表达基因EST库,为研究胚胎肝组织特异表达基因提供有力的工具。方法：采用表达性差异显示分析（representational difference analysis,RDA) 技术建立4月龄人胎肝组织选择性表达基因EST库,并测定部分克隆核苷酸序列,以竞争PCR检测代表性基因的差异表达。结果与结论：以珠蛋白家族基因为标志,所建差减cDNA文库中α－珠蛋白家族基因的表达频率较未差减cDNA文库增高7倍,同时该文库也含有多种与肝生长密切相关的基因,表明RDA技术确是研究差异表达基因的有效手段,所建EST库富集胎肝特异表达基因。部分克隆序列分析获得2种未报道序列,其中一株含有丝／苏氨酸激酶结构域,表明可望从此库中分离具有重要未知功能的新基因。     

Identification of Brachyspira hyodysenteriae-specific DNA fragments using representational difference analysis

Two novel Brachyspira hyodysenteriae-specific DNA fragments, designated as Bh100 and Bh400, were identified using representational difference analysis. To isolate the fragments the combined DNA of the Brachyspira pilosicoli, Brachyspira intermedia, Brachyspira murdochii and Brachyspira innocens reference strains was subtracted from the genome of B. hyodysenteriae strain B204. Both fragments were present in a single copy and mapped to different positions on the genome of B. hyodysenteriae B78(T). Larger fragments encompassing the continuous open reading frames (ORF) of Bh100 and Bh400 were cloned and analysed. Whereas the ORF of 2130 bp encompassing Bh100 did not show homology to any known bacterial protein, Bh400 was part of a putative operon with significant homology to the phosphotransferase system of Bacillus subtilis.     

Maize DNA enrichment by representational difference analysis in a maize chromosome addition line of oat

 The recent recovery of maize (Zea mays L.) single-chromosome addition lines of oat (Avena sativa L.) from oat x maize crosses has provided novel source materials for the potential isolation of maize chromosome-specific sequences for use in genetic mapping and gene cloning. We report here the application of a technique, known as representational difference analysis (RDA), to selectively isolate maize sequences from a maize chromosome-3 addition line of oat. DNA fragments from the addition line and from the oat parent were prepared using BamHI digestion and primer ligation followed by PCR amplification. A subtractive hybridization technique using an excess of the oat parental DNA was employed to reduce the availability for amplification of DNA fragments from the addition lines that were in common with the ones from the oat parental line. After three rounds of hybridization and amplification, the resulting DNA fragments were cloned into a plasmid vector. A DNA library containing 400 clones was constructed by this method. In a test of 18 clones selected at random from this library, four (22%) detected maize-specific repetitive DNA sequences and nine (50%) showed strong hybridization to genomic DNA of maize but weak hybridization to genomic DNA of oat. Among these latter nine clones, three detected low-copy DNA sequences and two of them detected DNA sequences specific to chromosome 3 of maize, the chromosome retained in the source maize addition line of oat. The other eight out of the 13 clones that had strong hybridization to maize DNA detected repetitive DNA sequences or high-copy number sequences present on most or all maize chromosomes. We estimate that the maize DNA sequences were enriched from about 1.8% to over 72% of the total DNA by this procedure. Most of the isolated DNA fragments detected multiple or repeated DNA sequences in maize, indicating that the major part of the maize genome consists of repetitive DNA sequences that do not cross-hybridize to oat genomic sequences. Received: 18 November 1997 / Accepted: 12 March 1998     

Labile DNA sequences in flax identified by combined sample representational difference analysis (csRDA)

Flax (Linum usitatissimum) has a genome in which changes have been associated with environmental factors. The inbred flax variety, Stormont Cirrus (Pl), served as the parent, and several lines (termed genotrophs) were derived from this parent. The phenotypes of the genotrophs were stable in a number of different growth environments, unlike the original Pl line in which changes associated with environmental factors continued to occur. These genotrophs differed from the original line in a number of characteristics, but the only known phenotypic characteristic that is shared by all the genotrophs and different from the parental, Pl, line is the lack of changes associated with the original environmental factors. However, some of these genotrophs have changed in both phenotype and nuclear DNA subsequent to their original growth and differentiation from Pl. Representational difference analysis (RDA) has been used to identify differences between Pl and all the genotrophs in an attempt to identify the loci controlling these aspects of plasticity. Subtractions between Pl DNA as a tester (target) and one of the genotrophs (individual RDA) or a mixture of different types of genotroph (L6, S6, C2, and LH) DNAs as a driver were done (combined sample RDA; csRDA). In addition, contrary RDA, where of the genotroph DNA was used as a tester and Pl DNA as a driver, was also executed. Three difference clones (163-4-2, 123-5-2, and 163-13), from 74 primary clones obtained after three rounds of subtractions with Pl DNA as tester were further characterized. In addition, 2 difference products (213-r1 and 213-r9) were characterized from contrary RDA. The clones 163-4-2 and 163-13 from the csRDA showed polymorphisms between Pl and all the genotrophs when PCR was done with primers derived from sequences of the clones, but only the clone 163-13 polymorphism was confirmed by Southern blot analysis. Four of 5 clones (163-4-2, 123-5-2, 163-13 and 213-r9) that have been characterized appear to be associated with structural changes in the DNA. From the contrary csRDA, it was observed that no clones could be recovered from subtractions between a mixture of genotrophs as a tester and Pl as a driver, and several possible explanations have been proposed.     

Identification of sulI allele of dihydropteroate synthase by representational difference analysis in Haemophilus parasuis serovar 2

AIMS: Identification of genes differentially present in Haemophilus parasuis serovar 2 by representational difference analysis (RDA). METHODS AND RESULTS: Bacterial genomic DNA was extracted, cleaved with Sau3AI and ligated to oligonucleotide adapter pair. The optimal tester (H. parasuis serovar 2)/driver ratio (H. parasuis serovars 1, 3 and 5) for the hybridization was established and the mixture was hybridized, and amplified by PCR. The products were cloned and transformed into Escherichia coli TOP10 cells and checked for specificity by Southern blotting analysis. The RDA subtractive technique yielded six bands ranging from 1500 to 200 bp, which were cloned into pCR II-TOPO vector and 40 clones were analysed. A fragment of 369 bp was specific for H. parasuis serovar 2, and showed 99% homology to sulI gene encoding for dihydropteroate synthase (dhps). The dhps gene conferring sulfonamide resistance was detected in H. parasuis serovar 2 but was absent in serovars 1, 3, 5 and in most of the Actinobacillus pleuropneumoniae serotypes (except serotype 7). CONCLUSION: sulI allele of dihydropteroate synthase has been identified in H. parasuis serovar 2 by RDA technique. SIGNIFICANCE AND IMPACT OF THE STUDY: The RDA technique seems to be an useful method for the identification of genes that are differentially present in H. parasuis, a respiratory pathogen of veterinary interest.     

Generation of polymorphic markers tightly linked to the thymus enlargement loci by phenotype-directed representational difference analysis

To obtain genetic markers linked to a specific genetic locus, genomic subtraction with a DNA pool of backcross or F₂ intercross animals with a specific genotype at the locus is known to be effective. To determine whether the pooling strategy is also effective for isolation of genetic markers linked to a quantitative phenotype that can potentially be controlled by multiple genetic loci, we tested the ability of representational difference analysis (RDA) to isolate genetic markers linked to the thymus enlargement observed in the BUF/Mna (BUF) rat. This is known to be controlled by single major and minor genes, Ten1 and Ten2, on Chromosomes (Chrs) 1 and 13, respectively, both of which have dose effects on the normal WKY/Ncj (WKY) allele. DNA from an inbred WKY rat was used as the tester, and the driver was prepared from a DNA pool of 12 (WKY × BUF)F₁× BUF backcross rats with high thymus ratios (thymus weight/body weight), expected to have dominance of the BUF allele in the responsible loci. By two RDA series with the restriction enzymes BglII and BamHI, respectively, 28 polymorphic markers were isolated, and 8 of them were shown to be linked to Ten1, and one to Ten2. One of the 8 markers linked to Ten1 demonstrated no recombination in 18 rats with high thymus ratios. RDA with a DNA pool based on a quantitative phenotype (phenotype-directed RDA) can thus be considered an efficient approach for direct isolation of polymorphic markers linked to a quantitative trait. Received: 15 April 1997 / Accepted: 8 May 1998     

代表性差异分析比较两株来自不同地区的猪源Lactobacillus菌株

[目的]对分离自猪肠道的乳酸杆菌S1菌株进行鉴定,并比较该菌株与同种的001T菌株的基因差异.[方法]对S1菌株进行16S rRNA基因序列分析和种特异PCR检测,并且对S1菌株和Lactobacillus sobrius 001T进行代表性差异分析(Representational difference analysis,RDA).[结果]16S rRNA基因序列分析表明,与S1菌株最相似的已知菌为L.sobrius.变性梯度凝胶电泳分析显示,仔猪空、回肠细菌图谱中有一与S1菌株有相同迁移位置的优势条带,克隆、测序鉴定表明,与该条带相匹配的16S rRNA基因克隆(Clone S)的最相似已知菌也为L.sobrius.16S rRNA基因系统进化分析表明,S1菌株与Clone S和L.sobrius 16S rRNA基因序列同源性分别为99.8%和99.6%.L.sobrius特异性引物也可以扩增S1株菌的16S rRNA基因的特定片段.因此S1菌株可被确定为Lsobrius.RDA对菌株S1和同种的猪源L.sobrius 001T菌株的基因差异进行分析,未发现这两株菌的基因组差异.[结论]猪肠道乳杆酸菌S1菌株属于L.sobrius,其与猪源L sobrius 001T菌株为相似菌株.     

Identification of imprinted loci by methylation-sensitive representational difference analysis: application to mouse distal chromosome 2

Imprinted genes are distinguished by different patterns of methylation on their parental alleles, a property by which imprinted loci could be identified systematically. Here, representational difference analysis (RDA) is used to clone HpaII fragments with methylation differences on the maternal and paternal copies of distal chromosome (Chr) 2 in the mouse. Uniparental inheritance for this region causes imprinting phenotypes whose molecular basis is only partially understood. RDA led to the recovery of multiple differentially methylated HpaII fragments at two major sites of imprinted methylation: paternal-specific methylation at the Nesp locus and maternal-specific methylation at the Gnasxl locus. Nesp and Gnasxl represent oppositely imprinted promoters of the Gnas gene, which encodes the G-protein subunit, Gsalpha. The organization of the Nesp-Gnasxl-Gnas region was determined: Nesp and Gnasxl were found to be 15 kb apart, and Gnasxl was found to be 30 kb upstream of Gnas. Sites of imprinted methylation were also detected at the loci for neuronatin on Chr 2 and for M-cadherin on Chr 8. RDA was highly effective at identifying imprinted methylation, and its potential applications to imprinting studies are discussed.