分子生物学-6
- 格式:ppt
- 大小:5.00 MB
- 文档页数:51


第五、六章分子生物学研究方法练习题1一、【单项选择题】1.一般的限制性核酸内切酶II作用的特点不包括A.在对称序列处切开DNAB.DNA两链的切点常不在同一位点C.酶切后产生的DNA片段多半具有粘性末端D. DNA两链的切点常在同一位点,E.酶辨认的碱基一般为4-6个4.下列关于建立cDNA文库的叙述哪项是错误的A.从特定组织或细胞中提取mRNAB.将特定细胞的DNA用限制性核酸内切酶切割后,克隆到噬菌体或质粒中,C.用逆转录酶合成mRNA的对应单股DNAD.用DNA聚合酶,以单股DNA为模板合成双链DNA5.限制性核酸内切酶的通常识别序列是A.粘性末端B.RNA聚合酶附着点C.回文对称序列,D.多聚腺苷酸E.甲基化的“帽”结构9.基因工程的操作程序可简单地概括为A.载体和目的基因的分离、提纯与鉴定B.分、切、连、转、筛,C.将重组体导入宿主细胞,筛选出含目的基因的菌株D.将载体和目的基因接合成重组体E.限制性核酸内切酶的应用11.常用质粒有以下特征A.是线性双链DNAB.插入片段的容量比λ噬菌体DNA大C.含有抗生素抗性基因,D.含有同一限制性核酸内切酶的多个切口E.不随细菌繁殖而进行自我复制14.表达人类蛋白质的最理想的细胞体系是A.大肠杆菌表达体系B.原核表达体系C.酵母表达体系D.昆虫E.哺乳类细胞表达体系,18.在分子生物学上“重组DNA技术”又称为A.酶工程B.蛋白质工程C.细胞工程D.发酵工程E.分子克隆技术22.基因组代表一个细胞或生物的A.部分遗传信息B.整套遗传信息,C.可转录基因D.非转录基因E.可表达基因25.在已知序列信息的情况下,获取目的基因的最方便方法是A.化学合成法B.基因组文库法C.cDNA文库法D.PCRE.差异显示法27.PCR主要的酶是A.DNA连接酶B.反转录酶C.末端转移酶D.碱性磷酸酶E. Taq DNA聚合酶28.重组DNA技术中实现目的基因与载体DNA拼接的酶A.DNA聚合酶B.RNA聚合酶C.DNA连接酶D.RNA连接酶E.限制性核酸内切酶30.最常用的筛选转化细菌是否含重组质粒的方法是A.营养互补筛选B.抗药性筛选,C.免疫化学筛选D.PCR筛选E.分子杂交筛选33.用于重组DNA的限制性核酸内切酶,识别核苷酸序列的A.正超螺旋结构B.负超螺旋结构C.α-螺旋结构D.回文结构,E.锌指结构58、基因治疗是指A.对有基因缺陷的细胞进行修复,从而使其恢复正常,达到治疗疾病的目的B.把健康的外源基因导入到有基因缺陷的细胞中,达到治疗疾病的目的C.运用人工诱变的方法,使有基因缺陷的细胞发生基因突变恢复正常D.运用基因工程技术,把有缺陷的基因切除,达到治疗疾病的目的93.PCR实验的特异性主要取决于A.DNA聚合酶的种类B.反应体系中模板DNA的量C.引物序列的结构和长度D.四种dNTP的浓度E.循环周期的次数94.基因剔除(knock out)的方法主要被用来研究A.基因的结构B.基因的功能C.基因的表达D.基因的调控E.基因的突变95.反义核酸作用主要是A.封闭DNA B.封闭RNAC.降解DNA D.降解DNA E.封闭核糖体的功能105. 酵母单杂交技术是分析【】的实验系统。
Chapter19Detection and Quantitative Analysis of Small RNAs by PCR Seungil Ro and Wei YanAbstractIncreasing lines of evidence indicate that small non-coding RNAs including miRNAs,piRNAs,rasiRNAs, 21U endo-siRNAs,and snoRNAs are involved in many critical biological processes.Functional studies of these small RNAs require a simple,sensitive,and reliable method for detecting and quantifying levels of small RNAs.Here,we describe such a method that has been widely used for the validation of cloned small RNAs and also for quantitative analyses of small RNAs in both tissues and cells.Key words:Small RNAs,miRNAs,piRNAs,expression,PCR.1.IntroductionThe past several years have witnessed the surprising discovery ofnumerous non-coding small RNAs species encoded by genomesof virtually all species(1–6),which include microRNAs(miR-NAs)(7–10),piwi-interacting RNAs(piRNAs)(11–14),repeat-associated siRNAs(rasiRNAs)(15–18),21U endo-siRNAs(19),and small nucleolar RNAs(snoRNAs)(20).These small RNAsare involved in all aspects of cellular functions through direct orindirect interactions with genomic DNAs,RNAs,and proteins.Functional studies on these small RNAs are just beginning,andsome preliminaryfindings have suggested that they are involvedin regulating genome stability,epigenetic marking,transcription,translation,and protein functions(5,21–23).An easy and sensi-tive method to detect and quantify levels of these small RNAs inorgans or cells during developmental courses,or under different M.Sioud(ed.),RNA Therapeutics,Methods in Molecular Biology629,DOI10.1007/978-1-60761-657-3_19,©Springer Science+Business Media,LLC2010295296Ro and Yanphysiological and pathophysiological conditions,is essential forfunctional studies.Quantitative analyses of small RNAs appear tobe challenging because of their small sizes[∼20nucleotides(nt)for miRNAs,∼30nt for piRNAs,and60–200nt for snoRNAs].Northern blot analysis has been the standard method for detec-tion and quantitative analyses of RNAs.But it requires a relativelylarge amount of starting material(10–20μg of total RNA or>5μg of small RNA fraction).It is also a labor-intensive pro-cedure involving the use of polyacrylamide gel electrophoresis,electrotransfer,radioisotope-labeled probes,and autoradiogra-phy.We have developed a simple and reliable PCR-based methodfor detection and quantification of all types of small non-codingRNAs.In this method,small RNA fractions are isolated and polyAtails are added to the3 ends by polyadenylation(Fig.19.1).Small RNA cDNAs(srcDNAs)are then generated by reverseFig.19.1.Overview of small RNA complementary DNA(srcDNA)library construction forPCR or qPCR analysis.Small RNAs are polyadenylated using a polyA polymerase.ThepolyA-tailed RNAs are reverse-transcribed using a primer miRTQ containing oligo dTsflanked by an adaptor sequence.RNAs are removed by RNase H from the srcDNA.ThesrcDNA is ready for PCR or qPCR to be carried out using a small RNA-specific primer(srSP)and a universal reverse primer,RTQ-UNIr.Quantitative Analysis of Small RNAs297transcription using a primer consisting of adaptor sequences atthe5 end and polyT at the3 end(miRTQ).Using the srcD-NAs,non-quantitative or quantitative PCR can then be per-formed using a small RNA-specific primer and the RTQ-UNIrprimer.This method has been utilized by investigators in numer-ous studies(18,24–38).Two recent technologies,454sequenc-ing and microarray(39,40)for high-throughput analyses of miR-NAs and other small RNAs,also need an independent method forvalidation.454sequencing,the next-generation sequencing tech-nology,allows virtually exhaustive sequencing of all small RNAspecies within a small RNA library.However,each of the clonednovel small RNAs needs to be validated by examining its expres-sion in organs or in cells.Microarray assays of miRNAs have beenavailable but only known or bioinformatically predicted miR-NAs are covered.Similar to mRNA microarray analyses,the up-or down-regulation of miRNA levels under different conditionsneeds to be further validated using conventional Northern blotanalyses or PCR-based methods like the one that we are describ-ing here.2.Materials2.1.Isolation of Small RNAs, Polyadenylation,and Purification 1.mirVana miRNA Isolation Kit(Ambion).2.Phosphate-buffered saline(PBS)buffer.3.Poly(A)polymerase.4.mirVana Probe and Marker Kit(Ambion).2.2.Reverse Transcription,PCR, and Quantitative PCR 1.Superscript III First-Strand Synthesis System for RT-PCR(Invitrogen).2.miRTQ primers(Table19.1).3.AmpliTaq Gold PCR Master Mix for PCR.4.SYBR Green PCR Master Mix for qPCR.5.A miRNA-specific primer(e.g.,let-7a)and RTQ-UNIr(Table19.1).6.Agarose and100bp DNA ladder.3.Methods3.1.Isolation of Small RNAs 1.Harvest tissue(≤250mg)or cells in a1.7-mL tube with500μL of cold PBS.T a b l e 19.1O l i g o n u c l e o t i d e s u s e dN a m eS e q u e n c e (5 –3 )N o t eU s a g em i R T QC G A A T T C T A G A G C T C G A G G C A G G C G A C A T G G C T G G C T A G T T A A G C T T G G T A C C G A G C T A G T C C T T T T T T T T T T T T T T T T T T T T T T T T T V N ∗R N a s e f r e e ,H P L CR e v e r s e t r a n s c r i p t i o nR T Q -U N I r C G A A T T C T A G A G C T C G A G G C A G GR e g u l a r d e s a l t i n gP C R /q P C Rl e t -7a T G A G G T A G T A G G T T G T A T A G R e g u l a r d e s a l t i n gP C R /q P C R∗V =A ,C ,o r G ;N =A ,C ,G ,o r TQuantitative Analysis of Small RNAs299 2.Centrifuge at∼5,000rpm for2min at room temperature(RT).3.Remove PBS as much as possible.For cells,remove PBScarefully without breaking the pellet,leave∼100μL of PBS,and resuspend cells by tapping gently.4.Add300–600μL of lysis/binding buffer(10volumes pertissue mass)on ice.When you start with frozen tissue or cells,immediately add lysis/binding buffer(10volumes per tissue mass)on ice.5.Cut tissue into small pieces using scissors and grind it usinga homogenizer.For cells,skip this step.6.Vortex for40s to mix.7.Add one-tenth volume of miRNA homogenate additive onice and mix well by vortexing.8.Leave the mixture on ice for10min.For tissue,mix it every2min.9.Add an equal volume(330–660μL)of acid-phenol:chloroform.Be sure to withdraw from the bottom phase(the upper phase is an aqueous buffer).10.Mix thoroughly by inverting the tubes several times.11.Centrifuge at10,000rpm for5min at RT.12.Recover the aqueous phase carefully without disrupting thelower phase and transfer it to a fresh tube.13.Measure the volume using a scale(1g=∼1mL)andnote it.14.Add one-third volume of100%ethanol at RT to the recov-ered aqueous phase.15.Mix thoroughly by inverting the tubes several times.16.Transfer up to700μL of the mixture into afilter cartridgewithin a collection bel thefilter as total RNA.When you have>700μL of the mixture,apply it in suc-cessive application to the samefilter.17.Centrifuge at10,000rpm for15s at RT.18.Collect thefiltrate(theflow-through).Save the cartridgefor total RNA isolation(go to Step24).19.Add two-third volume of100%ethanol at RT to theflow-through.20.Mix thoroughly by inverting the tubes several times.21.Transfer up to700μL of the mixture into a newfilterbel thefilter as small RNA.When you have >700μL of thefiltrate mixture,apply it in successive appli-cation to the samefilter.300Ro and Yan22.Centrifuge at10,000rpm for15s at RT.23.Discard theflow-through and repeat until all of thefiltratemixture is passed through thefilter.Reuse the collectiontube for the following washing steps.24.Apply700μL of miRNA wash solution1(working solu-tion mixed with ethanol)to thefilter.25.Centrifuge at10,000rpm for15s at RT.26.Discard theflow-through.27.Apply500μL of miRNA wash solution2/3(working solu-tion mixed with ethanol)to thefilter.28.Centrifuge at10,000rpm for15s at RT.29.Discard theflow-through and repeat Step27.30.Centrifuge at12,000rpm for1min at RT.31.Transfer thefilter cartridge to a new collection tube.32.Apply100μL of pre-heated(95◦C)elution solution orRNase-free water to the center of thefilter and close thecap.Aliquot a desired amount of elution solution intoa1.7-mL tube and heat it on a heat block at95◦C for∼15min.Open the cap carefully because it might splashdue to pressure buildup.33.Leave thefilter tube alone for1min at RT.34.Centrifuge at12,000rpm for1min at RT.35.Measure total RNA and small RNA concentrations usingNanoDrop or another spectrophotometer.36.Store it at–80◦C until used.3.2.Polyadenylation1.Set up a reaction mixture with a total volume of50μL in a0.5-mL tube containing0.1–2μg of small RNAs,10μL of5×E-PAP buffer,5μL of25mM MnCl2,5μL of10mMATP,1μL(2U)of Escherichia coli poly(A)polymerase I,and RNase-free water(up to50μL).When you have a lowconcentration of small RNAs,increase the total volume;5×E-PAP buffer,25mM MnCl2,and10mM ATP should beincreased accordingly.2.Mix well and spin the tube briefly.3.Incubate for1h at37◦C.3.3.Purification 1.Add an equal volume(50μL)of acid-phenol:chloroformto the polyadenylation reaction mixture.When you have>50μL of the mixture,increase acid-phenol:chloroformaccordingly.2.Mix thoroughly by tapping the tube.Quantitative Analysis of Small RNAs3013.Centrifuge at10,000rpm for5min at RT.4.Recover the aqueous phase carefully without disrupting thelower phase and transfer it to a fresh tube.5.Add12volumes(600μL)of binding/washing buffer tothe aqueous phase.When you have>50μL of the aqueous phase,increase binding/washing buffer accordingly.6.Transfer up to460μL of the mixture into a purificationcartridge within a collection tube.7.Centrifuge at10,000rpm for15s at RT.8.Discard thefiltrate(theflow-through)and repeat until allof the mixture is passed through the cartridge.Reuse the collection tube.9.Apply300μL of binding/washing buffer to the cartridge.10.Centrifuge at12,000rpm for1min at RT.11.Transfer the cartridge to a new collection tube.12.Apply25μL of pre-heated(95◦C)elution solution to thecenter of thefilter and close the cap.Aliquot a desired amount of elution solution into a1.7-mL tube and heat it on a heat block at95◦C for∼15min.Open the cap care-fully because it might be splash due to pressure buildup.13.Let thefilter tube stand for1min at RT.14.Centrifuge at12,000rpm for1min at RT.15.Repeat Steps12–14with a second aliquot of25μL ofpre-heated(95◦C)elution solution.16.Measure polyadenylated(tailed)RNA concentration usingNanoDrop or another spectrophotometer.17.Store it at–80◦C until used.After polyadenylation,RNAconcentration should increase up to5–10times of the start-ing concentration.3.4.Reverse Transcription 1.Mix2μg of tailed RNAs,1μL(1μg)of miRTQ,andRNase-free water(up to21μL)in a PCR tube.2.Incubate for10min at65◦C and for5min at4◦C.3.Add1μL of10mM dNTP mix,1μL of RNaseOUT,4μLof10×RT buffer,4μL of0.1M DTT,8μL of25mM MgCl2,and1μL of SuperScript III reverse transcriptase to the mixture.When you have a low concentration of lig-ated RNAs,increase the total volume;10×RT buffer,0.1M DTT,and25mM MgCl2should be increased accordingly.4.Mix well and spin the tube briefly.5.Incubate for60min at50◦C and for5min at85◦C toinactivate the reaction.302Ro and Yan6.Add1μL of RNase H to the mixture.7.Incubate for20min at37◦C.8.Add60μL of nuclease-free water.3.5.PCR and qPCR 1.Set up a reaction mixture with a total volume of25μL ina PCR tube containing1μL of small RNA cDNAs(srcD-NAs),1μL(5pmol of a miRNA-specific primer(srSP),1μL(5pmol)of RTQ-UNIr,12.5μL of AmpliTaq GoldPCR Master Mix,and9.5μL of nuclease-free water.ForqPCR,use SYBR Green PCR Master Mix instead of Ampli-Taq Gold PCR Master Mix.2.Mix well and spin the tube briefly.3.Start PCR or qPCR with the conditions:95◦C for10minand then40cycles at95◦C for15s,at48◦C for30s and at60◦C for1min.4.Adjust annealing Tm according to the Tm of your primer5.Run2μL of the PCR or qPCR products along with a100bpDNA ladder on a2%agarose gel.∼PCR products should be∼120–200bp depending on the small RNA species(e.g.,∼120–130bp for miRNAs and piRNAs).4.Notes1.This PCR method can be used for quantitative PCR(qPCR)or semi-quantitative PCR(semi-qPCR)on small RNAs suchas miRNAs,piRNAs,snoRNAs,small interfering RNAs(siRNAs),transfer RNAs(tRNAs),and ribosomal RNAs(rRNAs)(18,24–38).2.Design miRNA-specific primers to contain only the“coresequence”since our cloning method uses two degeneratenucleotides(VN)at the3 end to make small RNA cDNAs(srcDNAs)(see let-7a,Table19.1).3.For qPCR analysis,two miRNAs and a piRNA were quan-titated using the SYBR Green PCR Master Mix(41).Cyclethreshold(Ct)is the cycle number at which thefluorescencesignal reaches the threshold level above the background.ACt value for each miRNA tested was automatically calculatedby setting the threshold level to be0.1–0.3with auto base-line.All Ct values depend on the abundance of target miR-NAs.For example,average Ct values for let-7isoforms rangefrom17to20when25ng of each srcDNA sample from themultiple tissues was used(see(41).Quantitative Analysis of Small RNAs3034.This method amplifies over a broad dynamic range up to10orders of magnitude and has excellent sensitivity capable ofdetecting as little as0.001ng of the srcDNA in qPCR assays.5.For qPCR,each small RNA-specific primer should be testedalong with a known control primer(e.g.,let-7a)for PCRefficiency.Good efficiencies range from90%to110%calcu-lated from slopes between–3.1and–3.6.6.On an agarose gel,mature miRNAs and precursor miRNAs(pre-miRNAs)can be differentiated by their size.PCR prod-ucts containing miRNAs will be∼120bp long in size whileproducts containing pre-miRNAs will be∼170bp long.However,our PCR method preferentially amplifies maturemiRNAs(see Results and Discussion in(41)).We testedour PCR method to quantify over100miRNAs,but neverdetected pre-miRNAs(18,29–31,38). AcknowledgmentsThe authors would like to thank Jonathan Cho for reading andediting the text.This work was supported by grants from theNational Institute of Health(HD048855and HD050281)toW.Y.References1.Ambros,V.(2004)The functions of animalmicroRNAs.Nature,431,350–355.2.Bartel,D.P.(2004)MicroRNAs:genomics,biogenesis,mechanism,and function.Cell, 116,281–297.3.Chang,T.C.and Mendell,J.T.(2007)Theroles of microRNAs in vertebrate physiol-ogy and human disease.Annu Rev Genomics Hum Genet.4.Kim,V.N.(2005)MicroRNA biogenesis:coordinated cropping and dicing.Nat Rev Mol Cell Biol,6,376–385.5.Kim,V.N.(2006)Small RNAs just gotbigger:Piwi-interacting RNAs(piRNAs) in mammalian testes.Genes Dev,20, 1993–1997.6.Kotaja,N.,Bhattacharyya,S.N.,Jaskiewicz,L.,Kimmins,S.,Parvinen,M.,Filipowicz, W.,and Sassone-Corsi,P.(2006)The chro-matoid body of male germ cells:similarity with processing bodies and presence of Dicer and microRNA pathway components.Proc Natl Acad Sci U S A,103,2647–2652.7.Aravin,A.A.,Lagos-Quintana,M.,Yalcin,A.,Zavolan,M.,Marks,D.,Snyder,B.,Gaaster-land,T.,Meyer,J.,and Tuschl,T.(2003) The small RNA profile during Drosophilamelanogaster development.Dev Cell,5, 337–350.8.Lee,R.C.and Ambros,V.(2001)An exten-sive class of small RNAs in Caenorhabditis ele-gans.Science,294,862–864.u,N.C.,Lim,L.P.,Weinstein, E.G.,and Bartel,D.P.(2001)An abundant class of tiny RNAs with probable regulatory roles in Caenorhabditis elegans.Science,294, 858–862.gos-Quintana,M.,Rauhut,R.,Lendeckel,W.,and Tuschl,T.(2001)Identification of novel genes coding for small expressed RNAs.Science,294,853–858.u,N.C.,Seto,A.G.,Kim,J.,Kuramochi-Miyagawa,S.,Nakano,T.,Bartel,D.P.,and Kingston,R.E.(2006)Characterization of the piRNA complex from rat testes.Science, 313,363–367.12.Grivna,S.T.,Beyret,E.,Wang,Z.,and Lin,H.(2006)A novel class of small RNAs inmouse spermatogenic cells.Genes Dev,20, 1709–1714.13.Girard, A.,Sachidanandam,R.,Hannon,G.J.,and Carmell,M.A.(2006)A germline-specific class of small RNAs binds mammalian Piwi proteins.Nature,442,199–202.304Ro and Yan14.Aravin,A.,Gaidatzis,D.,Pfeffer,S.,Lagos-Quintana,M.,Landgraf,P.,Iovino,N., Morris,P.,Brownstein,M.J.,Kuramochi-Miyagawa,S.,Nakano,T.,Chien,M.,Russo, J.J.,Ju,J.,Sheridan,R.,Sander,C.,Zavolan, M.,and Tuschl,T.(2006)A novel class of small RNAs bind to MILI protein in mouse testes.Nature,442,203–207.15.Watanabe,T.,Takeda, A.,Tsukiyama,T.,Mise,K.,Okuno,T.,Sasaki,H.,Minami, N.,and Imai,H.(2006)Identification and characterization of two novel classes of small RNAs in the mouse germline: retrotransposon-derived siRNAs in oocytes and germline small RNAs in testes.Genes Dev,20,1732–1743.16.Vagin,V.V.,Sigova,A.,Li,C.,Seitz,H.,Gvozdev,V.,and Zamore,P.D.(2006)A distinct small RNA pathway silences selfish genetic elements in the germline.Science, 313,320–324.17.Saito,K.,Nishida,K.M.,Mori,T.,Kawa-mura,Y.,Miyoshi,K.,Nagami,T.,Siomi,H.,and Siomi,M.C.(2006)Specific asso-ciation of Piwi with rasiRNAs derived from retrotransposon and heterochromatic regions in the Drosophila genome.Genes Dev,20, 2214–2222.18.Ro,S.,Song,R.,Park, C.,Zheng,H.,Sanders,K.M.,and Yan,W.(2007)Cloning and expression profiling of small RNAs expressed in the mouse ovary.RNA,13, 2366–2380.19.Ruby,J.G.,Jan,C.,Player,C.,Axtell,M.J.,Lee,W.,Nusbaum,C.,Ge,H.,and Bartel,D.P.(2006)Large-scale sequencing reveals21U-RNAs and additional microRNAs and endogenous siRNAs in C.elegans.Cell,127, 1193–1207.20.Terns,M.P.and Terns,R.M.(2002)Small nucleolar RNAs:versatile trans-acting molecules of ancient evolutionary origin.Gene Expr,10,17–39.21.Ouellet,D.L.,Perron,M.P.,Gobeil,L.A.,Plante,P.,and Provost,P.(2006)MicroR-NAs in gene regulation:when the smallest governs it all.J Biomed Biotechnol,2006, 69616.22.Maatouk,D.and Harfe,B.(2006)MicroR-NAs in development.ScientificWorldJournal, 6,1828–1840.23.Kim,V.N.and Nam,J.W.(2006)Genomics of microRNA.Trends Genet,22, 165–173.24.Bohnsack,M.T.,Kos,M.,and Tollervey,D.(2008)Quantitative analysis of snoRNAassociation with pre-ribosomes and release of snR30by Rok1helicase.EMBO Rep,9, 1230–1236.25.Hertel,J.,de Jong, D.,Marz,M.,Rose,D.,Tafer,H.,Tanzer, A.,Schierwater,B.,and Stadler,P.F.(2009)Non-codingRNA annotation of the genome of Tri-choplax adhaerens.Nucleic Acids Res,37, 1602–1615.26.Kim,M.,Patel,B.,Schroeder,K.E.,Raza,A.,and Dejong,J.(2008)Organization andtranscriptional output of a novel mRNA-like piRNA gene(mpiR)located on mouse chro-mosome10.RNA,14,1005–1011.27.Mishima,T.,Takizawa,T.,Luo,S.S.,Ishibashi,O.,Kawahigashi,Y.,Mizuguchi, Y.,Ishikawa,T.,Mori,M.,Kanda,T., and Goto,T.(2008)MicroRNA(miRNA) cloning analysis reveals sex differences in miRNA expression profiles between adult mouse testis and ovary.Reproduction,136, 811–822.28.Papaioannou,M.D.,Pitetti,J.L.,Ro,S.,Park, C.,Aubry, F.,Schaad,O.,Vejnar,C.E.,Kuhne, F.,Descombes,P.,Zdob-nov, E.M.,McManus,M.T.,Guillou, F., Harfe,B.D.,Yan,W.,Jegou,B.,and Nef, S.(2009)Sertoli cell Dicer is essential for spermatogenesis in mice.Dev Biol,326, 250–259.29.Ro,S.,Park,C.,Sanders,K.M.,McCarrey,J.R.,and Yan,W.(2007)Cloning and expres-sion profiling of testis-expressed microRNAs.Dev Biol,311,592–602.30.Ro,S.,Park,C.,Song,R.,Nguyen,D.,Jin,J.,Sanders,K.M.,McCarrey,J.R.,and Yan, W.(2007)Cloning and expression profiling of testis-expressed piRNA-like RNAs.RNA, 13,1693–1702.31.Ro,S.,Park,C.,Young,D.,Sanders,K.M.,and Yan,W.(2007)Tissue-dependent paired expression of miRNAs.Nucleic Acids Res, 35,5944–5953.32.Siebolts,U.,Varnholt,H.,Drebber,U.,Dienes,H.P.,Wickenhauser,C.,and Oden-thal,M.(2009)Tissues from routine pathol-ogy archives are suitable for microRNA anal-yses by quantitative PCR.J Clin Pathol,62, 84–88.33.Smits,G.,Mungall,A.J.,Griffiths-Jones,S.,Smith,P.,Beury,D.,Matthews,L.,Rogers, J.,Pask, A.J.,Shaw,G.,VandeBerg,J.L., McCarrey,J.R.,Renfree,M.B.,Reik,W.,and Dunham,I.(2008)Conservation of the H19 noncoding RNA and H19-IGF2imprint-ing mechanism in therians.Nat Genet,40, 971–976.34.Song,R.,Ro,S.,Michaels,J.D.,Park,C.,McCarrey,J.R.,and Yan,W.(2009)Many X-linked microRNAs escape meiotic sex chromosome inactivation.Nat Genet,41, 488–493.Quantitative Analysis of Small RNAs30535.Wang,W.X.,Wilfred,B.R.,Baldwin,D.A.,Isett,R.B.,Ren,N.,Stromberg, A.,and Nelson,P.T.(2008)Focus on RNA iso-lation:obtaining RNA for microRNA (miRNA)expression profiling analyses of neural tissue.Biochim Biophys Acta,1779, 749–757.36.Wu,F.,Zikusoka,M.,Trindade,A.,Das-sopoulos,T.,Harris,M.L.,Bayless,T.M., Brant,S.R.,Chakravarti,S.,and Kwon, J.H.(2008)MicroRNAs are differen-tially expressed in ulcerative colitis and alter expression of macrophage inflam-matory peptide-2alpha.Gastroenterology, 135(1624–1635),e24.37.Wu,H.,Neilson,J.R.,Kumar,P.,Manocha,M.,Shankar,P.,Sharp,P.A.,and Manjunath, N.(2007)miRNA profiling of naive,effec-tor and memory CD8T cells.PLoS ONE,2, e1020.38.Yan,W.,Morozumi,K.,Zhang,J.,Ro,S.,Park, C.,and Yanagimachi,R.(2008) Birth of mice after intracytoplasmic injec-tion of single purified sperm nuclei and detection of messenger RNAs and microR-NAs in the sperm nuclei.Biol Reprod,78, 896–902.39.Guryev,V.and Cuppen,E.(2009)Next-generation sequencing approaches in genetic rodent model systems to study func-tional effects of human genetic variation.FEBS Lett.40.Li,W.and Ruan,K.(2009)MicroRNAdetection by microarray.Anal Bioanal Chem.41.Ro,S.,Park,C.,Jin,JL.,Sanders,KM.,andYan,W.(2006)A PCR-based method for detection and quantification of small RNAs.Biochem and Biophys Res Commun,351, 756–763.。