Amplification of cDNA ends based on template-switching effect and step-out PCR

A new method for amplifying cDNA ends is described which requires only first-strand cDNA synthesis and a single PCR to generate a correct product with very low or no background. The method can be successfully applied to total RNA as well as poly A+ RNA. The same first-strand cDNA can be used to amplify flanking sequences of any cDNA species present in the sample.     

Rapid amplification of 5' complementary DNA ends (5' RACE)

This method is used to extend partial cDNA clones by amplifying the 5' sequences of the corresponding mRNAs 1-3. The technique requires knowledge of only a small region of sequence within the partial cDNA clone. During PCR, the thermostable DNA polymerase is directed to the appropriate target RNA by a single primer derived from the region of known sequence; the second primer required for PCR is complementary to a general feature of the target-in the case of 5' RACE, to a homopolymeric tail added (via terminal transferase) to the 3' termini of cDNAs transcribed from a preparation of mRNA. This synthetic tail provides a primer-binding site upstream of the unknown 5' sequence of the target mRNA. The products of the amplification reaction are cloned into a plasmid vector for sequencing and subsequent manipulation.     

3' end cDNA amplification using classic RACE

Having knowledge of the entire 3' sequence of a cDNA is often important because the non-coding terminal region can contain signals that regulate the stability or subcellular localization of the mRNA. Also, some messages use alternative genomic sites for cleavage and polyadenylation that can alter the above properties, or change the encoded protein. Full-length cDNAs can be obtained from complex mixtures of cellular mRNA using rapid amplification of cDNA ends (RACE) PCR as long as part of the mRNA sequence is known; adding non-specific tags to the ends of the cDNA allows the regions between the known parts of the sequence and the ends to be amplified. In 3' RACE, the poly(A) tail functions as a non-specific tag at the 3' end of the mRNA. cDNA ends can be obtained in 1-3 days using this protocol.     

cDNA末端快速扩增试剂盒研发进展

DNA扩增的方法有许多种,其中cDNA末端快速扩增（rapid amplification of cDNA ends,RACE）因其操作简单、成功率相对较高、重复性好,被广泛应用于真核生物基因全长的克隆与分析。本文比较了市售的RACE试剂盒所采用的模板制备策略及改进的扩增方法。     

RecA-mediated multistrand formation for cloning PCR products into vectors: simplified process for 5'-rapid amplification of cDNA ends

I have developed a novel rapid amplification of cDNA ends (RACE) technology that uses multistranded DNA formation mediated by the RecA protein. Multistranded DNA can readily be formed at the terminus of double-stranded DNA by a complementary single-stranded DNA in the presence of RecA and exonuclease I. The possibility of applying this finding to the direct cloning of a 5'-RACE product onto a cDNA fragment, which does not require the use of restriction endonucleases, was explored. The results show that the terminal multistranded structure formed by the RecA-mediated reaction can be applied to RACE systems. Modifications to the RACE protocol to improve the effectiveness of the technique are also suggested.     

Rapid amplification and cloning of Tn5 flanking fragments by inverse PCR

A simple approach is described to efficiently amplify DNA sequences flanking transposon Tn5 insertions. The method involves: (i) digestion with a restriction enzyme that cuts within Tn5; (ii) self-ligation under conditions favouring the production of monomeric circles; (iii) four parallel PCR reactions using primers designed to amplify left or right flanking sequences, and to distinguish target amplicons from non-specific products. This reveals the number of Tn5 insertions and the size of flanking genomic restriction fragments, without Southern blot analysis. The amplified product contains restriction sites that facilitate cohesive-end cloning. This rapid method is demonstrated using Tn5 and Tn5-Mob tagged DNA sequences involved in albicidin biosynthesis in Xanthomonas albilineans. It is generally applicable for efficient recovery of DNA sequences flanking transposon Tn5 derivatives in insertional mutagenesis studies.     

Integrons found in different locations have identical 5' ends but variable 3' ends.

The positions of the outer boundaries of the 5'- and 3'-conserved segment sequences of integrons found at several different locations have been determined. The position of the 5' end of the 5'-conserved segment is the same for six independently located integrons, In1 (R46), In2 (Tn21), In3 (R388), In4 (Tn1696), In5 (pSCH884), and In0 (pVS1). However, the extent of the 3'-conserved segment differs in each integron. The sequences of In2 and In0 diverge first from the conserved sequence, and their divergence point corresponds to the 3'-conserved segment endpoint defined previously (H.W. Stokes and R.M. Hall, Mol. Microbiol. 3:1669-1683, 1989), which now represents the endpoint of a 359-base deletion in In0 and In2. The sequence identity in In3, In1, In4, and In5 extends beyond this point, but each sequence diverges from the conserved sequence at a different point within a short region. Insertions of IS6100 were identified adjacent to the end of the conserved region in In1 and 123 bases beyond the divergence point of In4. These 123 bases are identical to the sequence found at the mer end of the 11.2-kb insertion in Tn21 but are inverted. In5 and In0 are bounded by the same 25-base inverted repeat that bounds the 11.2-kb insert in Tn21, and this insert now corresponds to In2. However, while In0, In2, and In5 have features characteristic of transposable elements, differences in the structures of these three integrons and the absence of evidence of mobility currently preclude the identification of all of the sequences associated with a functional transposon of this type.     

基于模板切换的mRNA5'末端全长扩增方法

本文介绍一种称为CapFinder的技术,可用于克隆基因mRNA序列的5'末端非翻译区全长。该技术是利用某些反转录酶在反转录达到mRNA的5'末端帽结构时表现出很高的加尾活性(主要添加dC)这一特点,在反转录体系中加入一种带GGG的寡核苷酸序列,当反转录反应到达mRNA模板的5'末端帽结构时,切换到以该寡核酸为模板继续进行反转录反应,即可合成完整的cDNA一链,且在其3'末端还带有一段额外的寡核苷酸序列。用GGG寡核苷酸序列为上游引物和基因特异性的下游引物进行PCR即可扩增得到mRNA5'末端非翻译区的全长。利用该技术克隆了棉铃虫幼虫中肠Bt毒素受体E-钙粘素基因的5'末端非翻译区序列。     

Simultaneous PCR amplification of two barley 5S rDNA sequence types in the same PCR reaction

Many researchers are currently using PCR technology to amplify individual members of multigene families, including 5S rDNA, for sequencing and related purposes. When members of the family differ in length, analyses would be facilitated if different units could be simultaneously and efficiently amplified. In the present paper we describe conditions that can be used to amplify simultaneously both the “long” and “short” 5S rDNA repeats found in barley (Hordeum vulgare L.).