Isolation of pathogen-induced Chinese cabbage genes by subtractive hybridization employing selective adaptor ligation

We have developed a subtractive cloning method in which target sequences are effectively enriched by selective adaptor ligation and PCR after hybridization. In this method both tester and driver DNAs are digested with RsaI, ligated with the linker DNA containing a KpnI recognition site, and amplified by PCR. The tester DNA samples are divided into two aliquots, each digested with either RsaI or KpnI. The two DNA samples are then combined and hybridized with an excess of the driver DNA retaining the linker. After hybridization, the DNA mixture is ligated to a new adaptor compatible only with double-stranded tester/tester DNAs. Therefore, only the tester/tester is selectively amplified in subsequent PCR. This also leads to complete elimination of the tester DNA hybridized with driver DNA from the tester DNA population. Although our protocol employs enzymatic treatments, the efficiency of the enzymatic treatments does not affect the subtraction efficiency. This new subtractive enrichment method was applied to isolate Chinese cabbage defense-related genes induced by Pseudomonas syringae pv. tomato (Pst), which elicits a hypersensitive response in Chinese cabbage. After two or three rounds of subtractive hybridization, the sequences of enriched DNAs were determined and examined by BLAST analysis. Northern blot hybridization showed that 12 of the 19 genes analyzed were strongly induced by Pst treatment. Among the 12 Pst-induced genes five represent pathogenesis-related genes encoding PR1a, two chitinases, a thaumatin-like protein, and a PR4 protein. Other Pst-induced genes include two cytochrome P450 genes responsible for glucosinolate biosynthesis, a disease resistance gene homolog, and several genes encoding proteins with unknown functions.     

Differential cDNA cloning by enzymatic degrading subtraction (EDS).

We describe a new method, called enzymatic degrading subtraction (EDS), for the construction of subtractive libraries from PCR amplified cDNA. The novel features of this method are that i) the tester DNA is blocked by thionucleotide incorporation; ii) the rate of hybridization is accelerated by phenol-emulsion reassociation; and iii) the driver cDNA and hybrid molecules are enzymatically removed by digestion with exonucleases III and VII rather than by physical partitioning. We demonstrate the utility of EDS by constructing a subtractive library enriched for cDNAs expressed in adult but not in embryonic rat brains.     

应用代表性差异分析法筛选人癌候选抑癌基因

运用cDNA代表性差异分析法(cDNA representational difference analysis,cDNA RDA),以正常人鼻咽上皮细胞及鼻咽癌HNE1细胞作为比较的样品来源,分离了四个在鼻咽癌中缺失的cDNA片段.以此四个片段作探针,分别进行DNA杂交、RNA杂交,结果显示,这些差异性的cDNA序列确实来自正常人鼻咽上皮且只在其中表达和/或在鼻咽癌HNE1中表达降低,并在鼻咽癌病人中存在不同程度的缺失.序列分析结果表明这些差异性表达的基因为具有相当抑癌基因功能的已知基因和可能与鼻咽癌相关的抑癌基因的新基因.从而说明cDNA RDA是一种高效、敏感、假阳性低的克隆抑癌基因的有效方法.     

抑制差减杂交法分离玉米幼苗淹水诱导表达基因

以淹水处理（submergence-treated,ST)的玉米（Zea maysL.)幼苗根部cDNA为目标群体,未处理（untreated,UT)的玉米幼苗cDNA为对照群体,进行抑制差减杂交。用经过UT差减的STcDNA构建了一个含有大约2000个独立克隆的差减文库。对随机挑取的408个克隆进行差异筛选。获得了184个在ST中特异表达或表达增强的候选克隆。对其中155个cDNA克隆测序并去除重复克隆后,共得到95个差异表达的cDNA片段。GenBank中BLAST查询结果表明;6个克隆为已知的玉米核苷酸序列;68个克隆与已知基因或EST序列部分区域的同源性为60%-90%;21个克隆在GenBank中无法查到对应的同源序列。可能代表了新基因。或者由于序列位于变异丰富的3′端而无法查到与其他物种基因的同源性。     

Prokaryotic Suppression Subtractive Hybridization PCR cDNA Subtraction, a Targeted Method To Identify Differentially Expressed Genes

Molecular biology tools can be used to monitor and optimize biological treatment systems, but the application of nucleic acid-based tools has been hindered by the lack of available sequences for environmentally relevant biodegradation genes. The objective of our work was to extend an existing molecular method for eukaryotes to prokaryotes, allowing us to rapidly identify differentially expressed genes for subsequent sequencing. Suppression subtractive hybridization (SSH) PCR cDNA subtraction is a technique that can be used to identify genes that are expressed under specific conditions (e.g., growth on a given pollutant). While excellent methods for eukaryotic SSH PCR cDNA subtraction are available, to our knowledge, no methods previously existed for prokaryotes. This work describes our methodology for prokaryotic SSH PCR cDNA subtraction, which we validated using a model system: Pseudomonas putida mt-2 degrading toluene. cDNA from P. putida mt-2 grown on toluene (model pollutant) or acetate (control substrate) was subjected to our prokaryotic SSH PCR cDNA subtraction protocol to generate subtraction clone libraries. Over 90% of the sequenced clones contained gene fragments encoding toluene-related enzymes, and 20 distinct toluene-related genes from three key operons were sequenced. Based on these results, prokaryotic SSH PCR cDNA subtraction shows promise as a targeted method for gene identification.     

Isolation and Identification of Submergence-induced Genes in Maize Seedlings by Suppression Subtractive Hybridization

To investigate the expression profile of maize genes induced by submergence, a subtracted cDNA library of maize seedling roots was constructed using suppression subtractive hybridization (SSH). The cDNA of maize seedling roots treated with submergence (ST) was used as tester and what from untreated roots (UT) as driver. Products of the secondary PCR from the forward subtraction were cloned into T/A vector and transferred into Escherichia coli strain JM10B by electroporation. Four hundred and eight randomly chosen transformants carrying cDNA fragments were screened with PCR-Select Deferential Screening Kit. One hundred and eighty-four cDNA clones were identified as submergence specifically induced or highly expressed. After sequencing and removing redundant cDNAs, we got 95 submergence-induced cDNA clones. Of the 95 cDNA clones, 68 contain the regions with 60%-90% identity to their homolog in GenBank, 21 are expected to be novel genes, only 6 correspond to the published maize sequences. Key words: maize; expression profile; suppression subtractive hybridization (SSH); submergence     

The Isolation of differentially expressed mRNA sequences by selective amplification via biotin and restriction-mediated enrichment

Molecular analysis of development frequently implies the isolation and characterization of genes with specific spatial and temporal expression patterns. Several methods have been developed to identify such DNA sequences. The most comprehensive technique involves the genomewide probing of DNA sequence microarrays with mRNA sequences. However, at present this technology is limited to the few organisms for which the entire genome has been sequenced. Here, we describe a subtractive hybridization technique, called selective amplification via biotin and restriction-mediated enrichment (SABRE), which allows the selective amplification of cDNA fragments representing differentially expressed mRNA species. The method involves the competitive hybridization of an excess of driver cDNA fragments (D) to a trace of tester cDNA fragments (T), and the subsequent purification of tester homohybrids (in which both strands are contributed by the tester cDNA). After competitive hybridization, cDNA fragments that are more abundant in the tester than in the driver are enriched in the tester homohybrids. However, as the fraction of tester homohybrids is very small [T(2)/(D + T)(2)], their purification requires highly efficient procedures. In SABRE, the isolation of tester homohybrids is afforded by a combination of three successive steps: removal of biotinylated terminal sequences from most of the heterohybrids by S1 nuclease digestion, capture of biotinylated hybrids with streptavidin-coated paramagnetic beads, and specific release of homohybrids from the beads by restriction nuclease digestion. If several rounds of SABRE selection are performed in series, even relatively rare differentially expressed mRNA sequences may result in the production of predominant cDNA fragments in the final tester homohybrid population.     

A simulation of subtractive hybridization.

Various strategies employed in genomic DNA cloning by subtractive hybridization have been examined by computer simulations, with the comparison between the predictions and the published results. The result shows that the efficiency of target sequence enrichment and the sensitivity to experimental conditions depend strongly on the enrichment strategy employed. The strategy selecting only tester/tester after hybridization can be very efficient to enrich targets. For successful target enrichment, however, the strategy requires a highly efficient subtraction method and proper hybridization conditions. The strategy also requires that the selected DNA be amplified by polymerase chain reaction (PCR) after each or each alternate subtraction. By contrast, the strategy selecting tester/tester plus single-stranded tester is less sensitive to various experimental factors, compared with the strategy selecting only tester/tester. However, it is not as efficient. With this strategy, the tester DNA selected may or may not be amplified by PCR before the next round. In the case of the strategy selecting single-stranded tester, the target DNA can be successfully enriched only when the selected DNA is directly used without PCR amplification in the next round. The strong features of existing methods can be combined to develop a protocol that is more efficient and more reliable.     

鼻咽癌上皮细胞株HNE1差异表达基因的分离与鉴定

为了分离鼻咽癌差异表达基因 ,应用抑制性扣除杂交技术 ,在正向抑制性扣除杂交中 ,以鼻咽癌上皮细胞株HNE1cDNA作为检测子 ,以人胚鼻咽上皮细胞cDNA作为驱赶子 ;在反向抑制性扣除杂交中 ,以人胚鼻咽上皮细胞cDNA作为检测子 ,以鼻咽癌上皮细胞株HNE1cDNA作为驱赶子 ,分别通过抑制性扣除杂交 ,构建了鼻咽癌上皮细胞株HNE1表达下调和表达上调的两个扣除cDNA文库 .从鼻咽癌相关的扣除cDNA文库中随机挑取 1 2 0 0个克隆 ,采用菌落PCR扩增其插入cDNA片段 ,自动点膜制备成cDNA微阵列膜 ,分别用鼻咽癌上皮细胞株HNE1、人胚鼻咽上皮mRNA经逆转录标记cDNA探针 ,分别与cDNA微阵列膜杂交 ,通过杂交信号的自动扫描分析 ,对杂交信号存在 5倍差异的克隆进行测序 ,获得了 1 0个鼻咽癌差异表达基因的cDNA片段 ,其中 3个为新基因序列 ,其GenBank登录号为 :AF5 1 0 1 88、AF5 1 0 1 89和AF5 1 0 1 90 ,7个代表已知基因序列 .采用RT PCR证实S1 0 0A8,CK1 9和RBP1基因在人胚鼻咽上皮中高表达而在鼻咽癌细胞株HNE1中低表达 .这些结果显示上述基因可能是鼻咽癌发生的重要因素     

消减杂交技术结合限制性显示技术制备K562细胞特异基因探针

建立一种简便、快速、特异的制备基因芯片探针的方法.以K562细胞和正常人淋巴细胞作为消减对象,利用自行建立的消减方法进行消减杂交,结合限制性显示技术,分组扩增差异cDNA,回收K562细胞特异基因片段,制作基因芯片探针.结果显示,分离到400个K562特异的基因,片段大小均一,适于制作cDNA芯片.消减杂交技术结合限制性显示技术制备基因芯片探针,具有快速、简便、特异的特点,降低了芯片制作成本,可加速芯片的推广应用.     

A method for generating subtractive cDNA libraries retaining clones containing repetitive elements.

Here we describe a two-stepped photobiotin-based procedure to enrich a target (canine retinal) cDNA library for tissue specific clones without removing those containing repetitive ( SINE ) elements, despite the presence of these elements in the driver population. In a first hybridization excess SINE elements were hybridized to a driver (canine cerebellar) cDNA. In a second hybridization target cDNA was added to this reaction. The resulting cDNA library was enriched for retinal specific clones, but contained the same ratio of clones with SINE elements found in the unsubtracted library.     

Hybridization monitor: a method for identifying differences between complex genomes

We have developed a method to identify and amplify differential fragments between two complex genomes. This technique, named hybridization-monitored genome differential analysis (HMDA), incorporates a monitor system into a PCR-based solid subtraction hybridization that tracks the entire hybridization process. This is achieved by monitoring the subtraction progress using PCR analysis of the conserved sequence of 18S rDNA in the tester sample after each round of subtraction. Homologous fragments can then be eliminated when bound to the driver DNA immobilized on a solid membrane. The hybridization continues until the conserved DNA sequence of 18S rDNA can no longer be detected, and most of the unbound DNA fragments left in the liquid were mainly the tester-specific fragments, thus greatly decreasing the complexity of DNA template of PCR amplification, increasing the amplification efficiency of differences accordingly, and ensuring high positive efficiency and coverage across the tester genome. We have applied the technique in a comparison between the genomes of Saccharomyces cerevisiae and Schizosaccharomyces pombe, which are two completely sequenced organisms. Results indicated that 95% of the subtracted clones have been confirmed to be different to the driver analyzed using the BLASTN homology alignment. With this technique, 240-fold enrichment of differences is obtained, and the coverage of the difference is up to 79%. These results indicate that HMDA can efficiently identify sequences that differ between two complex genomes.     

Identification of Genes Preferentially Expressed in Goat Hair Follicle Anagen-Catagen Transition Using Suppression Subtractive Hybridization

Suppressive subtraction hybridization (SSH) was used to identify differentially expressed genes in goat (Capra hircus) hair follicle anagen-catagen transition. The cDNA fragments, derived from SSH positive subtractive library (tester: anagen-catagen transition, driver: later anagen), were cloned into pEGM-T vector. Two hundred cDNA fragments screened from this library were subjected to identify forty-five unregulated isolates. Sequence analysis revealed that these fragments represented twenty-three genes. Blasting analysis with database in GenBank showed that twenty genes were previously clearly annotated, two were homologous to un-annotated expressed sequence tag (ESTs), and one might be novel. To identify characters of gene expression, seven genes in later anagen and anagen-catagen transition skin tissues were chosen for quantitative real-time PCR. Results indicated that expression of these seven genes varied much, reaching threefold among them, furthering indicating that expression of those genes was up-regulation in the anagen-catagen transition. We characterized expression levels of this potential novel gene and the goat ectodysplasin A during differential stages of hair cycle. These profiles suggested that these two genes might play a role in the goat secondary hair follicle cycle.     

Identification of genes preferentially expressed in goat hair follicle anagen-catagen transition using suppression subtractive hybridization

Suppressive subtraction hybridization (SSH) was used to identify differentially expressed genes in goat (Capra hircus) hair follicle anagen-catagen transition. The cDNA fragments, derived from SSH positive subtractive library (tester: anagen-catagen transition, driver: later anagen), were cloned into pEGM-T vector. Two hundred cDNA fragments screened from this library were subjected to identify forty-five unregulated isolates. Sequence analysis revealed that these fragments represented twenty-three genes. Blasting analysis with database in GenBank showed that twenty genes were previously clearly annotated, two were homologous to un-annotated expressed sequence tag (ESTs), and one might be novel. To identify characters of gene expression, seven genes in later anagen and anagen-catagen transition skin tissues were chosen for quantitative real-time PCR. Results indicated that expression of these seven genes varied much, reaching threefold among them, furthering indicating that expression of those genes was up-regulation in the anagen-catagen transition. We characterized expression levels of this potential novel gene and the goat ectodysplasin A during differential stages of hair cycle. These profiles suggested that these two genes might play a role in the goat secondary hair follicle cycle.     

Combination of PCR subtraction and cDNA microarray for differential gene expression profiling.

PCR subtraction hybridization has been used effectively to enrich and single out differentially expressed genes. However identification of these genes by means of cloning and sequencing individual cDNAs is a tedious and lengthy process. In this report, an attempt has been made to combine the use of PCR select cDNA subtraction hybridization and cDNA microarrays to identify differentially expressed genes using a nonradioactive chemiluminescent detection method. mRNA from human prolactin (hPRL) or human prolactin antagonist (hPRL-G129R) treated and non-treated breast cancer cells was isolated, and cDNAs were synthesized and used for the PCR subtraction to enrich the differentially expressed genes in the treated cells. The PCR-amplified and subtracted cDNA pools were purified and labeled using the digoxigenin method. Labeled cDNAs were hybridized to a human apoptosis cDNA microarray membrane and identified by chemiluminescence. The results suggest that the strategy of combining all three methods will allow for a more efficient, nonradioactive way of identifying differentially expressed genes in target cells.     

Direct cloning of cell differential expression genes with full-length by a new strategy based on the multiple rounds of 'long distance' polymerase chain reaction and magnetic beads mediated subtraction.

The paper described a new cDNA subtractive cloning strategy. This strategy was based on the 'cap-finder' method, 'long distance' polymerase chain reaction (PCR), streptavidin magnetic beads mediated subtraction, and spin column chromatography. When PCR products were resolved on agarose gel after three rounds of subtraction, the 'single gene difference' group displayed a predominantly enriched band, but the 'multiple gene difference' group did not display any apparent difference. Of 200 clones inserted with 0.7-2 kb fragments from the 'multiple gene difference' group, 50% were identified to be new sequences and 35% were known. Of 100 new sequences, 35% contained coding regions and 75% were confirmed by dot-blotting to be differentially expressed by genes of the target cell. The results suggested that this strategy might be very efficient for full-length cloning of differentially expressed genes of the cell.     

Construction of the seed-coat cDNA microarray and screening of differentially expressed genes in barley

Proanthocyanidins are dimeric or polymeric conden-sation products of the flavonoids, including catechin,epicatechin or gallocatechin with leucocyanidin, leuco-pelargonidin or leucodelphinidin [1]. They are prominentcolorless compounds, and are found widely existed inthe bark of trees, leaves, fruits, flowers and seed coats.They have many natural functions, such as antioxidantproperties [2] and insect resistance [3]. In forage, theycan bind and precipitate dietary proteins, thus protectthe anim…