A Novel mRNA Level Subtraction Method for Quick Identification of Target-Orientated Uniquely Expressed Genes Between Peanut Immature Pod and Leaf

Subtraction technique has been broadly applied for target gene discovery. However, most current protocols apply relative differential subtraction and result in great amount clone mixtures of unique and differentially expressed genes. This makes it more difficult to identify unique or target-orientated expressed genes. In this study, we developed a novel method for subtraction at mRNA level by integrating magnetic particle technology into driver preparation and tester–driver hybridization to facilitate uniquely expressed gene discovery between peanut immature pod and leaf through a single round subtraction. The resulting target clones were further validated through polymerase chain reaction screening using peanut immature pod and leaf cDNA libraries as templates. This study has resulted in identifying several genes expressed uniquely in immature peanut pod. These target genes can be used for future peanut functional genome and genetic engineering research.     

An improved method for subtractive cloning of differentially expressed genes in higher plants by protective exonuclease digestion and discriminating PCR amplification

An improved method for subtractive cloning with enhanced efficiency was developed by modifying the enzymatic degrading subtraction. The thionucleotide-modified tester cDNA fragments under control of one linker-primer were hybridized with excess driver cDNA fragments flanked by the other distinct linker-primer. After selective digestion of incompletely protected tester/driver and of unprotected driver/driver molecules with exonuclease III and VII, the protected tester/tester reassociates due to thionucleotides were exclusively amplified by PCR with the tester-cDNA-specific primer. The subtractively enriched target cDNA fragments, showing distinct bands in an agarose gel, were inserted into pUC19, and random colonies with inserts were screened by Northern hybridization to tester and driver RNA. Four distinct clones were confirmed to be up-regulated by the withdrawal of potassium from the nutrient solution of seedling barley growing hydroponically. The original protocol generated only smeared amplicons due to non-selective PCR amplification of the hybridized cDNA mixture including remains of undigested driver cDNA.Abbreviations EDS Enzymatic degrading subtraction - SET Subtractively enriched target     

DSN Depletion is a Simple Method to Remove Selected Transcripts from cDNA Populations

A novel DSN-depletion method allows elimination of selected sequences from full-length-enriched cDNA libraries. Depleted cDNA can be applied for subsequent EST sequencing, expression cloning, and functional screening approaches. The method employs specific features of the kamchatka crab duplex-specific nuclease (DSN). This thermostable enzyme is specific for double-stranded (ds) DNA, and is thus used for selective degradation of ds DNA in complex nucleic acids. DSN depletion is performed prior to library cloning, and includes the following steps: target cDNA is mixed with excess driver DNA (representing fragments of the genes to be eliminated), denatured, and allowed to hybridize. During hybridization, driver molecules form hybrids with the target sequences, leading to their removal from the ss DNA fraction. Next, the ds DNA fraction is hydrolyzed by DSN, and the ss fraction is amplified using long-distance PCR. DSN depletion has been tested in model experiments. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

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 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.     

An in situ hybridization screen for the rapid isolation of differentially expressed genes

To rapidly isolate genes specifically expressed during medaka development we generated a cDNA library enriched for genes expressed in the head region of the developing embryo. Clones were spotted on filters automatically and preselected for abundantly expressed genes by hybridizing them with a probe derived from RNA of undifferentiated totipotent cells. Of the nonhybridizing clones 153 were chosen randomly and further analyzed by whole-mount in situ hybridization. There were 67 selected clones differentially expressed in the developing embryos, and 48 of these were expressed in the developing head. Differentially expressed genes were either of novel type or showed homology to known genes containing DNA binding motifs or to putative housekeeping genes. Received: 1 December 1998 / Accepted: 17 May 1999     

Selective enrichment of cDNAs from salt-stress-induced genes in the wheatgrass, Lophopyrum elongatum, by the formamide-phenol emulsion reassociation technique

We present a novel technique for the enrichment of cDNA libraries to enhance the abundance of clones of differentially expressed genes. The technique is relatively simple, requires moderate quantities of poly(A) + RNA and results in preferential enrichment of clones derived from mRNAs that were of low abundance in their original population. This method was used to isolate cDNA clones of salt-stress-induced genes in the roots of Lophopyrum elongatum, a highly salt-tolerant wheatgrass. An excess of sonicated plasmid DNA from a cDNA library from nonstressed roots was hybridized in a formamide-phenol emulsion with inserts from a cDNA library of stressed roots. Clones that were more abundant in, or were unique to, the library of the stressed roots were recovered as double-stranded fragments by virtue of reconstituted restriction-enzyme-digested ends by ligating them to a plasmid vector. The resulting enriched library was screened by differential colony hybridization and clones of eleven different genes that were more strongly expressed in stressed roots than in controls were selected.     

Generation of full-length cDNA libraries enriched for differentially expressed genes for functional genomics

Here, we describe the application of a RecA-based cloning technology to generate full-length cDNA libraries enriched for genes that are differentially expressed between tumor and normal tissue samples. First, we show that the RecA-based method can be used to enrich cDNA libraries for several target genes in a single reaction. Then, we demonstrate that this method can be extended to enrich a cDNA library for many full-length cDNA clones using fragments derived from a subtracted cDNA population. The results of these studies show that this RecA-mediated cloning technology can be used to convert subtracted cDNAs or a mixture of several cDNA fragments corresponding to differentially expressed genes into a full-length library in a single reaction. This procedure yields a population of expression-ready clones that can be used for further high-throughput functional screening.     

用抑制差减杂交法分离和克隆梭梭幼苗受渗透胁迫诱导相关基因的cDNA片段

以Hoagland溶液培养的梭梭幼苗(H)为对照群体,甘露醇处理的梭梭幼苗(M)为目标群体,进行抑制差减杂交.用经过H cDNA差减的M cDNA构建了一个含有大约400个独立克隆的差减文库;采用差减前的H cDNA和M cDNA以及正向/反向差减杂交后的cDNA为模板标记探针,对随机挑取的100个重组质粒进行差示筛选,获得了21个阳性候选克隆.从这些阳性候选克隆中随机挑取了8个进行Northern blot分析,证实其中3个候选克隆代表了在M中特异表达或表达增强的基因,序列分析和同源性比较表明它们与逆境胁迫有关;而另外5个候选克隆无Northem杂交信号,推测它们为低丰度转录本.     

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.     

血管紧张素Ⅱ诱导心肌成纤维细胞表达上调基因的分离和鉴定

为了对成年大鼠心肌成纤维细胞（cardiac fibroblasts,CF）受血管紧张素Ⅱ（angiotensin Ⅱ,AngⅡ）刺激后上调基因表达谱进行筛选及分析,以受AngⅡ刺激CF为实验方,未刺激CF为驱动方,进行抑制消减杂交（suppression subtractive hybridization,SSH）,建立消减cDNA文库。经斑点杂交筛选文库后将表达变化显著的部分阳性克隆测序及同源性分析,共获得19个上调表达的基因,分别与细胞外基质、细胞周期、胞内信号转导、细胞骨架及细胞代谢等功能相关,并克隆到7个新的基因表达序列标签（expressed sequence tags,EST）。我们的数据证实了SSH可以有效地克隆成年大鼠CF受AngⅡ刺激后上调表达基因,对这些基因的研究将有助于阐明心肌重塑的分子机制。     

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.     

利用抑制性差减杂交技术筛选草原龙胆花器官发育特性基因

目的:探讨草原龙胆花发育的分子机制,为进一步阐述花器官同源异型、属于MADS-box基因家族的一系列基因在调节开花植物花瓣和雄蕊的发育中的作用奠定基础。方法:以草原龙胆不同发育时期的花器官(萼片、花瓣、雄蕊、雌蕊)原基的cDNA作为试验方(tester),以茎叶组织的cDNA作为驱动方(driver),利用抑制性消减杂交技术构建了一个富集花器官发育特性基因的抑制性差减cDNA文库。对抑制性差减cDNA文库进行筛选、测序及Blast同源性比较。结果:获得了与花器官发育相关的特异性基因。结论:构建了抑制性差减cDNA文库,为克隆草原龙胆花器官发育特异性基因全长序列奠定了基础。