Construction and screening of cDNA libraries-Experimentation of methods for identification of newly expressed genes under external environmental stress conditions
Construction and screening of cDNA libraries-Experimentation of methods for identification of newly expressed genes under external environmental stress conditions
Materials Many organisms are excellent models for disease studies or for exploring the molecular adaptive mechanisms that enable cells and organisms to cope with and survive different stimuli. The construction of cDNA libraries and subsequent screening of target genes can lead researchers to discover new genes that have important roles in regulating and responding to certain external specific environmental stresses that may not be expressed or present in other systems. Identifying the readable frames of these new genes and further analyzing the functions of the proteins they encode can open up entirely new areas of research and allow for more scientifically designed next steps.
By Martin, this experiment is from "Environmental Genomics Experiment Guide".
Operation method
Construction and screening of cDNA libraries -Experimentation of methods for identification of newly expressed genes under external environmental stress conditions Move I. Materials All chemical reagents were of molecular biology grade purity. Plastic and glass products used, including bottles and pipette tips were autoclaved. Gloves are required for any handling involving nucleic acids. (1) RNase-free water. Add I mL of diethyl pyrocarbonate (DEPC) (Sigma-Aldrich) to I L of water (0.1%, V/V), stir overnight (>12 h), and autoclave. This inactivates the RNase present in the water, and the treated water is used to prepare the solutions and dissolve the RNA samples in this section. (2) TRIzo reagent (Invitrogen). (3) Aerosol (Fisher Scientific). (4) Isopropyl alcohol (Fisher Scientific). (5) 70 % ethanol with 30 mL of DEPC-treated water to 70 mL of anhydrous ethanol. (6) Oligo (dT) cellulose (New England BioLabs, NEB). Dried Oligo (dT) cellulose was mixed with 0 -I mol/L NaOH to make a slurry and filled into a sterile column or I mL of sterilized cotton or glass-wire plugged syringe. Equilibrate the column with Sampling Buffer before spiking. (7) Sampling buffer: lm ol/L NaCl, 2 mmol/L phosphate buffer, pH 7.2. (8) Middle wash buffer: sample buffer + 0.3 mol,+LNaCl. (9) elution buffer: 10 mmol/L Tris--HCl, pH7.2~7.4, I mmol/LEDTA (10) 3 mol/L sodium acetate, pH 5.2. (11) Ethanol. (1) NZY plate (24 cmX24 cm), LB-ambient penicillin broth, XLl-Blue strain, NZY agar, NZY top agar (see items 19 and 20 in 2). (2) TSM buffer (see item 16 in 2). (3) Chloroform (Fisher Scientific). (4) Dimethyl satoxide (DMSO; Sigma-Aldrich). (1) NZY plate (24 cmX24 cm, see items 19 and 20 in 2) (2) Hybond-14 0.45/1111 pore size nylon membrane (GE Healthcare). (3) 20XSSC: 3 mol/L NaCl, 0. 3 mol/L sodium citrate (I L formulation: 175 g NaCl, 88 g sodium citrate); diluted with distilled water. (4) Denaturation buffer: I.5 mol/L NaCl, 0. 5 mol/L NaOH. (5) Neutralization buffer: I. 5 mol/L NaCl, 0. 5 mol/L Tris-HCl, pH 8.0. (6) Rinse buffer: 0.2 mol/L Tris-HCl, p H 8. 0, 2XSSC. (7) Whatman filter paper or chromatography paper (Fisher Scientific). (8) dNTPs (1 0 mmol/L each of dATP, dTTP, and dGTP). (9) Immobilized Oligo (dT) primers: 5' - dT (15) A/G/C-3, commercially available (Invitrogen; New England Biolabs). (10) Nasin (20 U/μL, Promega) (11) Dithiothreitol (DTT) (Sigma-Aldrich), which was prepared as a ○- I m ol/L stock solution with sterile water. (12) A M V reverse transcriptase (10 U/μL) and 10X reverse transcription buffer (Promega). (13) [ α-32P ] dCTP (3000 Ci/mol; GE Healthcare). (14) RNaseA (60 mg/mL, Sigma-Aldrich)0 (15) Quick spin column (TE; Sephadex 025, Fine) for radiolabeled DNA purification (Roche). (16) IX T wEl buffer: 10 mmol/L Tris-HCl, pH 8.0, I mmol/L EDTA. (17) Hybridization buffer, modified Church's buffer: 0.25 mol/L Na2HPO4, 0.25 mol/L NaH2 PO4 (pH 7. 5), lmmol/LED TA, 7 % sodium dodecyl sulfate (SDS; W/V ); or commercially available; Ultrahybe ( Ambion). (18) Membrane washing buffer: 0. 1XSSC, 0 -1 % SDS (W/ V). (19) Membrane rinsing buffer: 0.1 X SSC. (20) X-ray film (Koda). (21) TSM buffer: (see item 16 in 2). (22) Chloroform (Fisher Scientific). (23) XLl-Blue medium. (24) NZY supernatant agar (see Items 19 and 20 in 2). (1) XLl-Blue strain. (2) 10 mmol/L MgSO4. (3) ExAssist helper thumbs up the bacteriophage. (4) Uni-ZAP X R phage storage solution. (5) LB- Ampicillin Broth (see item 18 in 2). (6) SOLR cells. (7) L B Aminobenzylpenicillin Agar Plate: 15 g agar powder was added to L B broth (I L) and autoclaved. Cool to below 50°C and spread the plate, add ampicillin (lOOpg/mL) and spread the plate with proper thickness. (1) LB-aminobenzylpenicillin broth (see item 18 in 2. 2). (2) Pre-lysis buffer: 50 mmol/L glucose, 2 5 mmol, LTris-HC1, p H 8. 0, lOmmol/LEDTA (3) RNase A (see item 14 in 4). (4) Alkaline lysis buffer: 0.2 mol/L NaOH, 1% S D S , which should be freshly prepared before use. (5) Neutralization buffer: 5 m olZL potassium acetate, 30% acetic acid, 50 mm 〇 r L glucose, 25 mmol/L Tris-HCl, pH 8.0, 10 mmol/L EDTA0, 0.2 mol/L NaOH, 1% S D S , the solution should be freshly prepared before use. (6) Isopropyl alcohol (FisherScientific) 7.70% ethanol (see item 5 of 2. 1). (1) Restriction endonucleases: E co R I and Xho I (N ew EnglandBiolabs); can be adjusted according to the junction. (2) IOX restriction endonuclease buffer; use the buffer that comes with the restriction enzymes. (3) DNA Sampling Buffer: 0. 25% (W/V ) xylene cyanide, 0. 25% (W/V ) bromophenol blue, 50% glycerol. (4) 1% TACE Agar Gel and 50X TACE Buffer (see items 11 and 12 in 2.2). (5) DNA molecular quality standard (Invitrogen), depending on the size of the expressed clone fragment (from 100 bp to several kilobytes). (6) Pipette tips with cartridges (Im L ). (7) Sterilized cotton or glass wool. (1) 10X MOPS buffer: 200 mmol/L MOPS, 50 mmol/L acetate, 10 mmol/L EDT A , pH 7.0. (2) I. 25% formaldehyde denaturing gel: dissolve 3.75 g of agarose in 217 m L of double-distilled water, add EB to a final concentration of Iμg / m L, and place the solution in a 60°C incubator. In a separate sterilized bottle, add 30 mL of IOX MOPS buffer and 53 mL of formaldehyde (37%, W) and place the solution in a 60°C incubator. When both solutions have equilibrated to 60°C, mix them, swirl gently to blend, being careful not to create air bubbles, and pour into a larger gelatin plate. (3) RNA sample lysis buffer: IXMOPS buffer, 2.2 mol/L formaldehyde, 50 % formamide (V/V). (4) 6X RNA Sampling Buffer: IXMOPS buffer, 50% formamide (V/V), 40% glycerol (V/V), add a few drops of blue bromate and xylene cyanide as tracer dye. (5) HybondO.45 pm pore size nylon membrane (GE Healthcare). (6) 20XSSC (see item 3 in 4), diluted with distilled water if necessary to the desired concentration. (7) Whatman filter paper or chromatography paper (Fisher Scientific). (8) Paper towels. (9) Sequencing adhesive plates. (10) Press weights. (11) Glass or plastic pipette (5 or IOmL), used to dislodge air bubbles in the membrane transfer device. (12) Plastic film. (13) Fixative for Northern blotting: 0 -05 mol/L NaOH. (1) Hybridization solution: Ultrahybe Hybridization Buffer or modified Church's buffer (see item 17 in 4). (2) Radiolabeled probe (see 2. 8). (3) Northern hybridization wash: 0.1XSSC, 0.1% SDS in distilled water. (4) X-ray film. (5) Northern blotting eluent: Boil double-distilled water containing 0.5% SDS, place the blotting film in, and detect the radiation signal with a Geiger counter until it falls below the background level. Commercially available products designed for specific experiments (high or low copies of genes, etc.) have been developed to detect and characterize differentially expressed genes. Despite rapid technological advances, the isolation of mRNA from tissues/organs/organisms of interest to construct cDNA libraries is still the standard method for identifying new genes and proteins. There are many well-established reagents and products available for constructing a library; this chapter describes a common standard method for constructing libraries, screening positive clones and analyzing them. These experimental methods use the Uni-Zap-cDNA Synthesis Kit (Stmtagene) (5), but can be modified for use with other vectors. Some generalized phage cloning vectors include plTriplEX (Clontech), pSPORTl (Invitrgen), and ISCREEN-1 (Novagen), but are not limited to these. After library construction, differential expression screening was used to identify gene clones that were induced or repressed under the conditions tested. Here we illustrate specific experimental steps using the identification of a novel gene, expressed in hepatopancreatic tissues of sea snails and induced under hypoxic conditions, as an example. This up-regulation of expression was confirmed by Northern blotting. After the sequence determination of the imprinted-2 clone, see 3. 11 for further sequence analysis. (1) There are many kits available for total RNA and mRNA isolation (Ambion, Roche, Qiagen, Invitrogen, Novagen, etc.). These kits provide high purity and quality RNA, but are relatively expensive. Here we describe the traditional conventional RN A extraction method. (2) Add Im L TRIz0I homogenate per 100 mg of tissue and add 0.2 m L' m L chloroform. Invert and mix for 15 s and leave at room temperature for 2~3 min. 4: ° C, 12 000 g■ centrifuge for 15 min. (3) Transfer the upper aqueous phase to a new Eppendorf tube and add an equal volume of isopropanol to precipitate the RNA. leave at room temperature for 10 min. (4) Centrifuge at 4°C for 10 min at maximum speed, remove supernatant, wash with 250 pL of 70% ethanol, and centrifuge at maximum speed for 5 min. Aspirate off ethanol, air-dry the RNA for 10 min at room temperature, and dissolve in an appropriate amount of DEPC-treated water (assuming that the amount of RNA obtained from 10 mg of tissue is IOfXg). Store at 4°C (within one week) or at 20°C (long-term storage). (5) Determine the concentration and purity of RN A by measuring the 260 nm and 280 mn absorbance values with a UV spectrophotometer. A260/A 280 of 1.6 to 2.0 is an acceptable range (see Note 1). (6) Purify poly (A )+ InRNA using a cellulose column incorporating Oligo (dT). total RNA is heated to 65°C, mixed 1 : 1 with Sampling Buffer (V/V), and loaded onto a cellulose column with Olig0 (dT). (7) Rinse the column with one column bed volume of Sampling Buffer and collect the eluate in a sterile Eppendorf tube. The eluate was re-sampled, collected, and repeated twice. (8) Rinse the column with one column bed volume of Sample Buffer and Wash Buffer, respectively, and finally elute with 1.5 times the column bed volume of eluent. As a final step, poly(A)+ InRNA is eluted by adding 0.1 times the volume of 3 mOl/L sodium acetate (p H 5-2), 2-5 times the volume of anhydrous ethanol, and leaving to settle overnight at 20°C. The procedure can be stopped here. The procedure can be stopped here. (9) The next day, centrifuge at 13,000 g for 45 min at 4°C. Dispose of the supernatant and wash with 70% polyester ethanol (250 fxL) and centrifuge at the same speed for 10 min. The resulting precipitate is mRNA, which is air-dried and dissolved in DEPC-treated water (see Note 2). If the mRNA is not to be used immediately for experiments, store the samples at 180°C. The samples should not be used for experimental purposes. Clones with differential expression should be sequenced in both directions using standard methods (either in the laboratory or at a DNA/genome sequencing facility). Subsequent sequence analysis can be performed with commercially available software and a host of other online analysis tools. Listed below are some excellent bioinformatics software and application tools for performing cDNA and amino acid sequence analysis. (1) National Center for Biotechnology Information (NCBI) http: //www.ncbi.nlm.nih.gov/ 1. Basic Local Alignment Search Tool (BLAST): http:/ /blast, ncbi. nlm. nih.gov/Blast BLAST first gives the residues represented by the four letters in a sequence, and then the fragments formed by the expansion of these letters. In the program used, Wastx is used to translate all the readable frames of the query nucleotide sequence into a protein sequence and then compare it with the data in the protein database. tblastx is used to translate the query nucleotide sequence and compare it with the translation results of the nucleotide sequence database. blastp is to compare the query amino acid sequence with the protein database. (2) Gene translation and protein sequence identification The identification of new gene functions is a challenge for many large-scale genome projects. While mRNA sequences contain a lot of information, proteins are usually the functional performers. To predict the function of a particular gene, the gene sequence is often translated into a predicted protein sequence to analyze homology and conserved regions with known functional proteins. In many cases, a cDNA clone usually represents a known homologue. The genes or proteins represented by these clones can often be matched to existing functional models E because these genes are likely to have been identified in other systems, organs, tissues (under various types of stress and environmental conditions) with known roles and functions. However, if the target clone does not have any known homologs, further analysis and characterization is required. Some of the software used to analyze new genes or proteins are listed below: PredictProtein (Protein Prediction): http: //www.embl-heidelberg.de/predictprotein<, predictprotein. html The translated target protein sequences are searched with the PredictProtein server, and the result is a database of similar sequences and protein structure predictions. Protein Sequence Analysis (PSA). http:// bmerc-www.bu.edu/psa/request.htmPSA predicts the secondary and quaternary structures of proteins based on amino acid sequences. SOSUI: http : //sosui.proteome.bio.tuat.ac.jp/sosui_ submit,html This tool software predicts the secondary structure of membrane proteins from the physicochemical properties (e.g., hydrophobicity and charge) of the incoming amino acid sequence. PROSITE: http: //www.expasy.ch/prosite For more product details, please visit Aladdin Scientific website.![1. cDNA文库构建的克隆载体。现已有许多载体,各有其特别的用途,研究者应 根据其特性挑选恰当的载体。一些使用较广泛的 cDNA文库构建载体包括: Uni-ZAPXR (Stratagene)、 plTriplEx2 (Clontech)、 pSPORTl (Invitrogen)、 130^££1^-1(1^〇¥&8611/]\46]:〇 10。本章将以1711卜2八?父1^克隆载体为例。 2. 1/xg经过柱纯化的mRNA。 3 . 含 多 聚 ( dT) 区 域 的 寡 聚 核 苷 酸 连 接 物 - 引 物 ( linkerprimer) [例 如 5'- NNNNNNNNCTCGAGdT (15) -3’] 。 4. 核糖核酸酶抑制剂( RNasin, 2 0 U//iL ; Pr〇 mega)。 5. AMV反 转 录 酶 (10 U" L) 和 IOX反转录缓冲液( Promega)。 6 . 核 苷 酸 ( dATP、 dTTP、 dGTP 各 l 〇 mmol/L)。 7. 5-甲基胞嘧啶类似物(dCTP~J_5_mmol._~9_L~B。 8. RNase H (5 U '/ uL; New England Biolabs)。](http://img.dxycdn.com/trademd/upload/userfiles/image/2016/07/A1468315305397eqttctaq8bpng_small.jpg)
3 Amplification of CDNA libraries ![2. 8 标记探针的合成 1. 无〇 10 ^ 的 41^113: ; (〇1 八丁?、 £ 1丁丁?、 £ ^ 丁?各 5 111111〇1/乙)。 2• 随 机 引 物 ( 1〇〇 mmol/L dN6; New England Biolabs)。 3. IOX 随机引物缓冲液: 0.5 mol/L Tris-HCl, pH 7. 6, 20 mmol/L D T T, 50 mmol,L MgCl2,〇. 4 mol/L KC1。 4. DNA 聚合酶 I Klenow 片 段 ( 5 U/|nL; New England Biolabs)。 5. [cr32P] dCTP (3000 Ci/mol; GE Healthcare)。 6. 快 速 离 心 柱 ( TE; S印hadex 0 2 5 , Fine),用 于 放 射 性 标 记 的 D N A 纯化 (Roche)。](http://img.dxycdn.com/trademd/upload/userfiles/image/2016/07/B1468315324523aq69ps9453png_small.jpg)
9 Northern imprint ![3.2 cDNA文库的合成 1•在无RNase的 Eppendorf管中,加入mRNA (5 pg, < 3 0 pL) , 寡聚核苷酸连 接物-引 物 (3 pg) 及 RNasin (5 pL)。第一 链 cDNA合成以mRNA为模板,加 人 dNTPs (3 ML)、 5_甲基-dCTP (3 ; xL)、 IOX反转录酶缓冲液(5 , ),补水 至 45 fxL。轻轻混匀,于室温使引物和模板复性10 min。 2 . 加入反转录酶至反应管中(5 / JL, 50 U) 使最终体积为50 juL。轻轻混勻,稍 加离心收集反应液于离心管底部,然后在42°C放 置 I h (见注释3)。 3•于同一管中进行cDNA第二链的合成( 第一链的互补链)。在第一链反应液中加 人以下成分: dNTPs (6 pL)、 10X D N A 聚合酶I 缓 冲 液 (2 0 ^ ) 、 [a-32P] dCTP (I pL)、 RNase H (I fiL, 5 U )、 DNA 聚合酶 I (1〇 yL , 100 U),用 蒸馏水补加至终体积2〇〇 / xL,在 16°C孵 育 2 h。 4.将双链cDNA反应管置于冰上,加 人 22. 5 ^LdNTPs (A. C /C/T ) , DNA 聚 合 酶 (2. 5 yL) 合成平头末端,在 72°C反 应 30 min。 5•加人等体积的苯酸-氯仿( I : 1 V/V , pH 7. 4 ) , 振荡混勻,在台式离心机上室 温以最大速度离心1〇 min。转移水相至新离心管,加入等体积氯仿。振荡混匀](http://img.dxycdn.com/trademd/upload/userfiles/image/2016/07/B1468315361095k5ryp25gvrpng_small.jpg)

3 Titer assay and cDNA library amplification 
4 Differential screening of cDNA libraries 
![6•取第二张膜,重复步骤3〜5 , 吸收时间延长至2 min。 7•将尼龙膜放置于两张滤纸中间,于干胶仪中80°C 烘烤。 8. 需合成两套探针来筛选。一套用对照mRNA为模板合成,另一套则以暴露于环 境压力中的mRNA为模板。 9. 用与第一链cDNA合成类似的操作方法合成探针, ( 见 3. 2,材料列于2. 2)。分 装 poly (A )+ mRNA (约 1 辟 )入 DEPC处 理 的 1.5 m L离心管, 65°C 加热 5 min0 10. 立即置于冰上,随后各管分别加人IOX反转录酶缓冲液(5 ^ ) 、 dNTPs (3 / iL 、无 dCTP)、 Oligo (dT) 引 物 (3 jug)、 RNasin (5 pL)。补水至 40 / xL, 轻弹混匀,稍加离心收集液体于离心管底部,在室温退火10 min,使引物结合 至 mRNA模板。 11. 加 5 juL 反转录酶和 5 juL [cr32P] dCTP (3000 Ci/mol) 至各管, 42°C孵育 I h 后 ,将离心管转移至16°C水浴。 12. 为降解RNA,需加人RNase A 5 ( ixL并 于 37°C孵 育 30 mm。经此处理后离心 管内只剩下cDNA,将其上样至快速离心柱, 400 g•离心3 min。洗 脱 液 ( 放射 标记的cDNA) 即可用作探针与尼龙膜杂交。 13. 结合有噬菌斑的膜放置于55°C 的旋转杂交管中在杂交液中预杂交30 min。 14•把放射标记的探针煮沸5 min (见注释8),立即置于冰上。将探针直接加入现 有的杂交液中( 见注释9 ) 至终浓度为l X 10scpm/mL。为便于比较,需加人 等同的放射标记量至匹配的印迹膜上( 对照和实验组) ,在 45°C 下滚动杂交过 夜 ( 〜16 h)。 15. 杂交后,用0.2父33(:, 0 . 1 % ( 灰 / ^)3〇 3溶 液 于 55。〇洗涤杂交膜10 111丨 11 ,再 重复该洗涤步骤3 次以降低放射背景。如果背景仍然很高( 用手持式盖革计数 器测量) ,可重复该洗涤步骤。 16. 将洗涤过的膜保持湿润,有放射活性的一面朝下,放置于塑料薄膜上,封口使 液体不至漏出。用薄膜再次包裹杂交膜。用纸巾抚平表面( 除去折皱和气泡) 。 将杂交印迹曝光于X 光 胶 片 ( 或成像憐屏)适当的时间,其时间取决于特异性 探针结合于杂交膜的cpm值。 17. 曝光X 光胶片,并分析放射自显影结果。图 I A 为第一次筛选的放射自显影结 果。每一点代表一个探针结合的噬菌斑。 18. 根据定位标记,回 到 N ZY平板上找出对应于差异表达克隆的噬菌斑并剪下。 用一灭菌的巴斯德管剪切下各个斑点的琼脂块,放置于加有500 ML TSM 缓冲 液 的 I.5 mL Eppendorf管中。如果不能分离出单个克隆( 特别在初次筛选 时) ,将推定的大致阳性“区 域 “切下。 19. 每管加入氯仿( 至 5 % , W/V ),振荡混匀30 s, 在室温放置30 min,使得噬 菌体从琼脂释放至缓冲液中。 20_将以上样品在4°C , 3OOOg 离 心 5 min, 转移上清至一新的离心管( 包含游离 的噬菌体) ,存放于4°C 。 21.测定每一转移噬菌斑的滴度( 试11/1111)(见 3.3)。](http://img.dxycdn.com/trademd/upload/userfiles/image/2016/07/A1468315837126kxfmh8c7nppng_small.jpg)
![22•按50〜100 pfu/平板的水平将 每 一 阳性克隆重新铺板于NZY平 板 (10 cm直径) 。 23.用一小的圆形尼龙膜重新做第二次噬菌斑筛选,方法与初次筛选相同( 从 第 3 步开始)。 用同样的方法重复差异筛选步骤( 从 第 8 步开始V。通过检查放射自 显影图谱,选择代表感兴趣基因( 具有差异表达)的阳性克隆。图 I B 为第二 次筛选的放射自显影图谱。图 I cDNA文库的表达差异筛选。 ( A) 初次差异筛选使用以海蜗牛( Lto0WmZii0- mz) 的肝胰腺组织的mRNA为 来 源 合 成 的 [32P ] d C T P 掺 入 的 cDNA。正常氧含量 组 :试验动物处于4°C正常氧含量环境。低压氧组:试验动物处于一个大气压的氮气 环境中,持续时间为l h 、 1 2 h、 2 4 h (将来源于各时间点的等量的mRNA混合) 。 (B) 第二次差异筛选,用相同的探针筛选假定的缺氧反应克隆。 ( C) 从噬菌体上切割 质粒载体,随后从细菌中对质粒进行纯化。可分离缺氧诱导的阳性克隆插人片段。第 一泳道为编码蜗牛缺氧响应蛋白2 (snail anoxia-responsive protein 2,似印-幻的质粒 克隆;各类非特异性的基因插人显示于随后几个泳道。阳性克隆需用Northern印迹确 证其差异表达,随后进一步的鉴定如图2 所示](http://img.dxycdn.com/trademd/upload/userfiles/image/2016/07/A1468315854511j3jj4htqnbpng_small.jpg)
5 Pick-up of in vivo clones

6 Small volume extraction of plasmids 
7 Isolation and extraction of insertion fragments 
8 Synthesis of labeled probes ![3 . 8 标记探针的合成 1■取1 2 鸿 D N A片段溶液,转 移 人 L 5 m L离心管,补 水 至 8 ML 。 94°C 变 性 3 min,稍加离心收集反应液于离心管底部,立即置于冰上。加人下列试剂: dNTPs (dATP、 dTTP、 dGTP,终浓度各 I mmol/L ) , I )uL 随 机 引 物 (1〇〇 mmol/L d (N)6; New England Biolabs), 2 /JL 10 X 随机引物缓冲液, 2.5 U DN A酶 I 的 Klenow 片 段 ( New England Biolabs), 2.5 yL [cr32P] dCTP (3000 Ci/mol; Amersham)。 2•轻轻混匀,于 37°C 加 热 45 min。将反应液放人快速离心柱中, 400 g 离 心 3 min。洗脱的放射标记探针用于Northern印迹。 3.9 Northern 印迹 1. 准 备 1.25%甲醛变性胶,将其浸没于IXM OPS缓冲液,预电泳15 min。 2. 分装适量的RNA (10〜2 0 ^ 8 ) 于做好标记的离心管中,加入等体积的R N A 样 品缓冲液。](http://img.dxycdn.com/trademd/upload/userfiles/image/2016/07/A1468316154148f4gwcqjjfrpng_small.jpg)
9 Northern imprint 
10 Northern blotting with probes 
![图 2 来 源 于 海 蜗 牛 的 新 基 因 的 鉴 定 。 ( A) 从定名为sarp-2 基因的克隆中分离到插入片段后( 见 图 1),暴露于低氧环境中各时间 点 的 基 因 表 达 用 Northern印迹法监测。 wrp- 2 的表达量用管 家 基 因 的 表 达 量 标 准 化 ,同时也用转膜前凝胶上rRNA的光 密度值作对照。 ( B) 对 插 人 的 基 因 测 序 显 示 有 550个核苷酸 序列,并包含有完整的可读框编码131个氨基酸的蛋白质。使 用 3.11 中所列出的分析工具,在 mRNA和推定的蛋白质序列上发现 多种常见的蛋白结构域,结果显示如图。 5 . 将膜用塑料薄膜包裹,曝 光 X 光 片 ( 或成像磷屏)适当的时间,显影。 6 . 用合适的成像分析软件进行放射自显影图像分析光密度[例如Imagequant (GE Healthcare) 或 QuantityQne (Bio~Rad)],图 2 为 Northern印 迹 结 果 ( 上半部分)。 7•如果需要,将印迹膜用煮沸的含0 . 5 % SDS的去离子水冲洗可除去探针。重复 该步骤直至放射活性达到或低于背景水平。用无菌水冲洗杂交的印迹膜以除去 残 留 的 SDS, 如果需要可以重新再用探针杂交。检测组成性表达、不受试验条 件影响的管家基因,用 来 标 准 化 差 异 表 达 的 目 的 基 因 的 表 达 量 。图 2 中的 Northern印迹膜洗脱后,再 用 探 针 杂 交 检 测 其 表 达 量 用 于 控 制 上 样 量 (中间部分)。](http://img.dxycdn.com/trademd/upload/userfiles/image/2016/07/A14683162727495mkdw6b5xgpng_small.jpg)

11 Cloning Analysis
As a first step, DNA sequences should be copied to NCBI's BLAST server to compare existing and annotated sequences. The similarity of identical gene sequences or expressed sequence tags can be determined by the E-value. The E-value indicates the likelihood that each pair of sequences is similar. When the E-value of -5 means that the sequence pair is not produced by error, the sequence pair is not similar.
The E value -5 means that the sequence comparison is not produced by error. New or unknown genes usually cannot be paired, but some conserved regions can be identified and provide very short sequence pairs.
2.ORF (readable frame) finder: http://ncbi.nlm. nih. gov/gorf/gorf.htmlORFfinder can identify the coding regions of all 6 readable frames in a nucleotide sequence. Selected reading frames can be directly transferred to BLAST for searching conserved regions or similar sequences (blastp).
