In-cell PCR from mRNA: amplifying and linking the rearranged immunoglobulin heavy and light chain V-genes within single cells.

We describe a process for the identification of mRNAs within single cells, as demonstrated with the immunoglobulin (Ig) variable region (V) genes of two mouse hybridoma cell lines and the bcr-abl fusion gene of the human K562 myeloid leukaemia line. The cells were fixed and permeabilised, the mRNA reverse transcribed to cDNA and the cDNA amplified by the polymerase chain reaction (PCR). After using fluorescent PCR primers, the amplified DNA could be detected within the cells as demonstrated by confocal fluorescence microscopy and flow cytometry. Furthermore the amplified Ig VH and VL DNA could be assembled within the same cell using suitable PCR primers. We detected no cross-contamination of amplified DNA between cells: the DNA isolated from mixtures of two hybridoma cell lines (B1-8 and NQ10/12.5) treated to in-cell PCR and assembly, was shown by cloning to correspond to the combinations of VH and VL genes of the parent hybridomas. We forsee diverse applications of in-cell assembly by PCR, especially for the analysis of the combinations of chains of rearranged Ig or T cell receptor (TCR) V-genes in a population of cells, and the construction of human antibodies from the V-genes of immune B-lymphocytes.     

Expression sequence tag-specific full-length cDNA cloning: actin cDNAs

Current strategies for cDNA cloning are based on construction of cDNA libraries and colony screening. The process of obtaining a full-length cDNA clone can be highly time and labor intensive. Using the human actin gene as a model target cDNA, we have developed an RNA-capture method for rapid cloning of full-length cDNAs. The approach involves the capture of mRNA with expressed sequence tag (EST)-derived, biotin labeled antisense "capture" primers and streptavidin-coated magnetic beads. Full-length cDNA is then synthesized from purified EST-specific mRNA and cloned directly into plasmid vectors. The results of using beta-actin-based capture primers on cytoplasmic RNA were the isolation of both beta- and gamma-actin cDNA clones. Of the 16 actin-specific cDNA clones analyzed, 15 (93%) were full-length. This approach for cloning full-length cDNAs from available ESTs or partial cDNA sequences will facilitate a more rapid and efficient characterization of gene structure and function.     

甲型H1N1流感病毒血凝素单克隆抗体轻链和重链可变区基因的巢式PCR扩增及序列分析

目的：采用巢式PCR对甲型H1N1流感病毒血凝素单克隆抗体的轻链和重链基因进行扩增,对获得的基因进行序列分析,并找出克隆鼠Igκ轻链和重链可变区基因的通用方法。方法：设计22对扩增鼠Igκ轻链可变区和重链可变区基因的引物,对6株鼠抗人甲型H1N1流感病毒血凝素单克隆抗体的轻链和重链可变区基因进行克隆并测序,与NCBI公布的鼠免疫球蛋白序列比对分析。结果：巢式PCR方法可以有效避免单克隆抗体克隆过程的假基因,并且得到的单克隆抗体的氨基酸序列均符合鼠免疫球蛋白可变区特征。结论：建立了克隆鼠免疫球蛋白轻链和重链可变区基因的通用方法,为后期克隆鼠源性单克隆抗体的可变区基因提供了基础,并为研究甲型H1N1流感病毒血凝素与抗体的结合位点提供了实验数据。     

用基因组DNA剪接技术克隆SIgA相关基因

目的：克隆分泌型IgA（SIgA）相关基因--J链基因(IgJ)、多聚免疫球蛋白受体基因（pIgR）和IgA重链恒定区基因（IGHA）,为进一步构建SIgA真核表达质粒奠定基础。方法：采用本室建立的"基因组DNA剪接"技术,根据已发表的IgJ、pIgR和IGHA的核苷酸序列,通过计算机软件分别设计各个基因片段外显子的优化引物,从人外周血基因组DNA中直接扩增各基因的外显子序列;然后人工设计融合相邻外显子的融合引物,采用重叠PCR技术,把各基因片段的外显子串联起来形成全长编码序列,完成基因组DNA的体外剪接。扩增的PCR产物纯化后克隆到pGEM-T Easy Vector中,通过DNA测序对阳性克隆进行分析鉴定。结果：PCR扩增的IgJ、pIgR和IGHA基因与预期大小一致;测序结果表明本实验获得的上述基因与GenBank中的目标基因序列完全一致。结论：本文通过基因组DNA剪接技术成功克隆人类SIgA三个相关基因,提示此技术是合成多外显子cDNA的有效手段。     

抗人Clq单克隆抗体轻链可变区基因的克隆及序列测定

 抗人Ｃｌｑ单克隆抗体轻链可变区基因的克隆及序列测定陈克敏,朱锡华（第三军医大学免疫学教研室,重庆６３００３８）目前国内外对基因工程抗体的研究较多,但尚未见补体基因工程的研究报道．一般的方法是经ＲＮＡ反转录合成ｃＤＮＡ,再以ＰＣＲ扩增,克隆Ｉｇ可变区基...     

RT-PCR检测HUTP14A mRNA时排除假基因HUTP14C干扰的方法

人类U3蛋白14C基因(HUTP14C)是人类U3蛋白14A基因(HUTP14A)的假基因。两者转录本序列同源性高达95%。常规RT-qPCR技术在检测HUTP14A mRNA丰度时,HUTP14C的存在会影响检测结果。本研究旨在建立检测HUTP14A mRNA时排除HUTP14C干扰的RT PCR方法。本研究设计出能分别从多种肿瘤细胞DNA和RNA中特异性扩增HUTP14A和HUTP14C的引物,避免假基因HUTP14C对其同源基因HUTP14A检测的干扰。在检测细胞系HUTP14A mRNA时,通过DNaseⅠ消除RNA中污染的HUTP14C DNA,用靶向HUTP14C 3′-UTR的siRNA沉默HUTP14C mRNA后,再用RT PCR检测HUTP14A mRNA丰度,使结果更加准确。在18对肝癌及癌旁组织中,利用特异性引物进行RT PCR检测,HUTP14A和HUTP14C mRNA的表达略高于癌旁组织。本研究提示,针对有假基因存在的功能基因,对其mRNA丰度进行检测时,在提取细胞或组织总RNA后,用DNaseⅠ处理,再用RNA直接进行PCR扩增,排除DNA污染后,再进行RT-PCR或RT-qPCR扩增。大多假基因具有较长的3′-UTR区,在该区域设计siRNA特异性沉默假基因的mRNA后,用RT-qPCR检测功能基因的mRNA丰度,可以排除假基因mRNA的影响。在病理组织中检测功能基因的mRNA丰度时,可以根据假基因和其功能基因的序列差异设计出特异扩增功能基因的引物,从假基因的3′-UTR区设计特异扩增假基因的引物,通过RT-qPCR技术分别检测二者的mRNA。     

cDNA cloning by amplification of circularized first strand cDNAs reveals non-IRE-regulated iron-responsive mRNAs

Currently, the rapid amplification of cDNA ends (RACE) is the most common method for PCR cloning of cDNA. Because RACE uses a gene specific primer and one adaptor primer that is shared by all cDNAs may result in numerous nonspecific products that can hinder the cloning process. Here we report a new method that uses circularized first strand cDNA from mRNA and two gene specific primers to amplify both the 5' and 3' cDNA ends in one reaction. A cDNA band of correct size can be obtained on the first pass in this approach. If the correct size is not obtained on the first pass, amplification of cDNA ends can be repeated until the correct size of the cDNA is obtained. We tested this new method on eight mRNAs that we have previously shown to respond to cellular iron levels. We obtained sequences for six mRNAs that were 43 bp to 1324 bp longer than that reported in GenBank and obtained the same length sequence for the other two mRNAs. RNA folding program shows no iron responsive elements (IRE) on these mRNA. In conclusion, our cloning approach offers a more efficient method for cloning full-length cDNA and it may be used to replace the existing method of 5' end cDNA extension. The data enabled us to exclude the possibility that the expression of these iron responsive genes are regulated by IREs.     

Gene conversion of immunoglobulin variable regions in mutagenesis cassettes by replacement PCR mutagenesis.

A technique, Replacement PCR Mutagenesis, was developed to replace one immunoglobulin variable region (V) in a M13 phage cassette with a different, homologous V. This allows the use of the same mutagenesis and subsequent expression vectors for many V regions or V segments. The method combines PCR of V fragments and in vitro mutagenesis. Primers homologous to 3' and 5' ends of both V regions initiate PCR synthesis of the V DNA fragment (donor) that will replace the V region (recipient) in M13. Donor V PCR DNA may originate from mRNA, cloned V genes or genomic templates. The donor V PCR DNA is denatured and annealed to the M13 cassette containing the recipient V to be supplanted. The second strand is synthesized, transfected into bacteria and mutant plaques selected by hybridization. Since restriction sites in primers are not required, altered primer-encoded amino acids are avoided. Further, the PCR donor piece can be of any length if it shares homology with the recipient gene. This allows construction and expression of complete gene replacements and chimeras. This method is also applicable to V "humanization" and studying sets of homologous genes containing polymorphic or evolutionary disparities. The potential uses of the technique are discussed.     

A simple method for obtaining cell-specific cDNA from small numbers of growing root-hair cells in Arabidopsis thaliana

A simple and rapid method for cloning specific cDNAs from mRNA populations derived solely from small numbers of root-hair cells is described here. To identify genes expressed during the earliest visible stage of root-hair cell development, cell contents were aspirated from small numbers of Arabidopsis root-hair cells at or just before this stage. This material was used to make reusable solid-phase oligo-dT-primed cDNA libraries. To demonstrate that the libraries contained high quality longer cDNAs, a fragment located 2.7 kb from the 3' end of the cDNA of the single copy root-hair expressed gene RHD3 was cloned using a nested PCR strategy. This technique was also used to obtain novel gene expression information by cloning the full-length 0.85 kb cDNA of the Rop2 GTPase from this library. This approach offers a means of cloning larger cDNAs directly from small numbers of growing root-hair cells and, potentially, other epidermal cell types.     

Succession of microbial communities during hot composting as detected by PCR-single-strand-conformation polymorphism-based genetic profiles of small-subunit rRNA genes

A cultivation-independent technique for genetic profiling of PCR-amplified small-subunit rRNA genes (SSU rDNA) was chosen to characterize the diversity and succession of microbial communities during composting of an organic agricultural substrate. PCR amplifications were performed with DNA directly extracted from compost samples and with primers targeting either (i) the V4-V5 region of eubacterial 16S rRNA genes, (ii) the V3 region in the 16S rRNA genes of actinomycetes, or (iii) the V8-V9 region of fungal 18S rRNA genes. Homologous PCR products were converted to single-stranded DNA molecules by exonuclease digestion and were subsequently electrophoretically separated by their single-strand-conformation polymorphism (SSCP). Genetic profiles obtained by this technique showed a succession and increasing diversity of microbial populations with all primers. A total of 19 single products were isolated from the profiles by PCR reamplification and cloning. DNA sequencing of these molecular isolates showed similarities in the range of 92.3 to 100% to known gram-positive bacteria with a low or high G+C DNA content and to the SSU rDNA of gamma-Proteobacteria. The amplified 18S rRNA gene sequences were related to the respective gene regions of Candida krusei and Candida tropicalis. Specific molecular isolates could be attributed to different composting stages. The diversity of cultivated bacteria isolated from samples taken at the end of the composting process was low. A total of 290 isolates were related to only 6 different species. Two or three of these species were also detectable in the SSCP community profiles. Our study indicates that community SSCP profiles can be highly useful for the monitoring of bacterial diversity and community successions in a biotechnologically relevant process.     

Quikgene: a gene synthesis method integrated with ligation-free cloning

Gene synthesis is a convenient tool that is widely used to make genes for a variety of purposes. All current protocols essentially take inside-out approaches to assemble complete genes using DNA oligonucleotides or intermediate fragments. Here we present an efficient method that integrates gene synthesis and cloning into one step. Our method, which is evolved from QuikChange mutagenesis, can modify, extend, or even de novo synthesize relatively large genes. The genes are inserted directly into vectors without ligations or subcloning. We de novo synthesized a 600-bp gene through multiple steps of polymerase chain reaction (PCR) directly into a bacterial expression vector. This outside-in gene synthesis method is called Quikgene. Furthermore, we have defined an overlap region of a minimum of nine nucleotides in insertion primers that is sufficient enough to circularize PCR products for efficient transformation, allowing one to significantly reduce the lengths of primers. Taken together, our protocol greatly extends the current length limit for QuikChange insertion. More importantly, it combines gene synthesis and cloning into one step. It has potential applications for high-throughput structural genomics.     

Amplification and analysis of cDNA generated from a single cell by 5'-RACE: application to isolation of antibody heavy and light chain variable gene sequences from single B cells

The technique of 5'-rapid amplification of cDNA ends (5'-RACE) is widely used to amplify unknown sequences at the 5' end of a messenger RNA (mRNA). However, conventional 5'-RACE is inappropriate for producing cDNAs from a single cell due to the small quantity of mRNA present in one cell. In this study, we report an improved 5'-RACE method that is suitable for generating cDNA from a single cell. In this method, the first-strand cDNA was directly synthesized from a single cell, and both the tailing reaction and second-strand cDNA synthesis were performed in the same tube without purifying the cDNA sample. Using this method, we were able to amplify the cDNA of the immunoglobulin (Ig) variable region gene from more than 50% of single B cells. The amplified cDNA fragment contained a full-length Ig variable region including a 5'-untranslated region, a leader sequence, and an initiation codon. This method may thus be applicable for a comprehensive analysis of the Ig variable genes of the lymphocyte repertoire in humans and animals, thereby contributing to the development of antibody-based therapeutics for infectious diseases.     

从噬菌体抗体库中淘选血纤维蛋白特异的单链抗体

为构建小鼠噬菌体抗体库 ,以获得对人血纤维蛋白特异的抗体 ,由小鼠脾脏提取 m RNA,经反转录 PCR扩增出抗体重链、轻链可变区基因片段 ,将二者和一段编码十五肽 (Gly4 Ser) 3的 DNA接头借助重组 PCR组装成为单链抗体 (single- chain antibody,Sc Ab)基因 .将单链抗体基因插入噬菌体展示载体 p CANTAB- 5E,通过电击法转化大肠杆菌 TG1细胞 ,用辅助噬菌体 M1 3K0 7超感染 ,构建了库容量在 1 0 8以上的噬菌体单链抗体库 .利用亲和选择方法 (淘选 ) ,从噬菌体抗体库中选得血纤维蛋白特异的单链抗体 .模拟抗体成熟过程 ,用 DNA改组 (DNA shuffling)技术使抗体基因重新组合 ,构建新的改组抗体库 ,并从中选择到提高了亲和力的噬菌体单链抗体 .抗体基因在大肠杆菌中表达 ,表达蛋白经 Sephadex G- 75柱层析分离 ,得到初步纯化的单链抗体蛋白 .     

Rapid verification of lambda-cDNA clones using mixed-base oligonucleotide as screening probe and sequencing primer

A rapid procedure has been developed for the isolation and verification of cDNA clones isolated from a cDNA library based on lambda vectors. Using information of the partial amino acid sequence of a protein, synthetic mixed-base oligonucleotides are first employed as a screening probe using the plaque hybridization procedure. The cDNA inserts of the clones obtained are then directly amplified by polymerase chain reaction (PCR) using primers flanking the cloning site of the vector. Besides being used for cloning into a plasmid vector, the amplified DNA's are also subjected to nucleotide sequence analysis using the same mixed-base oligonucleotides as sequencing primers. This approach allows sequencing through the region of the known amino acid sequence for direct verification of the authenticity of the clones obtained. This procedure has successfully been used for cloning and partial characterization of the gene coding for a platelet aggregation inhibitor.     

用一个简单快速的RT-PCR技术筛选白细胞介素-6作用相关基因

为了研究白细胞介素-6(IL-6)作用相关基因以及一些可能受IL-6调控的基因,利用一个简单快速的以PCR为基础的方案,检测了IL-6处理和未处理的Sko007细胞中基因表达的差异,克隆并鉴定了差异表达基因的cDNA片段.首先用6-mer寡核苷酸引物进行反转录从而最大限度地将mRNA编码区序列生成cDNA;然后用2或3个较长的随机引物进行PCR扩增,并以不同引物组合重复PCR增扩;扩增产物在2%琼脂糖凝胶上电泳分离,回收差异片段并直接用于克隆、测序及进一步分析.在此研究中,获得了3个表达序列标签(EST),其中一个为新的基因片段,反向RNA杂交有力证实了它们与IL-6作用的相关性.进一步的生物信息学分析表明,新基因片段STRF17在多种组织中表达.     

Primer design for the cloning of immunoglobulin heavy-chain leader-variable regions from mouse hybridoma cells using the PCR

To facilitate the rapid cloning and sequencing of rearranged murine heavy-chain variable regions, we have designed a set of universal primers using conserved sequences of leader (signal peptide), framework one and constant regions of the immunoglobulin heavy-chain genes. RNA was extracted from the mouse hybridoma cells secreting monoclonal antibodies: IOR-T3 (anti-CD3), C6 (anti-P1 of N. meningitidis B385), IOR-T1 (anti-CD6), CB-CEA.1 (anti-carcinoembryonic antigen), CB-Fib.1 (anti-human fibrin) and CB-Hep.2 (anti-hepatitis B surface antigen). First-strand cDNA was synthesized and amplified using PCR. The primers successfully amplified correct size fragments from cDNA prepared from all hybridomas. These methods will facilitate the cloning and sequencing of mouse immunoglobulin variable regions.     

Algorithms and software for support of gene identification experiments

MOTIVATION: Gene annotation is the final goal of gene prediction algorithms. However, these algorithms frequently make mistakes and therefore the use of gene predictions for sequence annotation is hardly possible. As a result, biologists are forced to conduct time-consuming gene identification experiments by designing appropriate PCR primers to test cDNA libraries or applying RT-PCR, exon trapping/amplification, or other techniques. This process frequently amounts to 'guessing' PCR primers on top of unreliable gene predictions and frequently leads to wasting of experimental efforts. RESULTS: The present paper proposes a simple and reliable algorithm for experimental gene identification which bypasses the unreliable gene prediction step. Studies of the performance of the algorithm on a sample of human genes indicate that an experimental protocol based on the algorithm's predictions achieves an accurate gene identification with relatively few PCR primers. Predictions of PCR primers may be used for exon amplification in preliminary mutation analysis during an attempt to identify a gene responsible for a disease. We propose a simple approach to find a short region from a genomic sequence that with high probability overlaps with some exon of the gene. The algorithm is enhanced to find one or more segments that are probably contained in the translated region of the gene and can be used as PCR primers to select appropriate clones in cDNA libraries by selective amplification. The algorithm is further extended to locate a set of PCR primers that uniformly cover all translated regions and can be used for RT-PCR and further sequencing of (unknown) mRNA.      

Cloning and sequencing of immunoglobulin variable-region genes using degenerate oligodeoxyribonucleotides and polymerase chain reaction

A procedure is described for using the polymerase chain reaction (PCR) to amplify and clone the cDNA from mouse immunoglobulin (Ig) variable (V) regions. This method uses a set of universal 5'-oligodeoxyribonucleotide primers that are degenerate and allow for the amplification of Ig V-region sequences from gamma and mu heavy chains and from kappa light chains. Selective first-strand cDNA synthesis is performed using Ig constant region primers and then a PCR is achieved by using the appropriate universal 5'-primer. The universal Ig heavy-chain primer was used to amplify the V-region cDNA from gamma and mu isotypes and the universal light-chain primer was used to amplify three separate kappa light V-region sequences. This procedure was used to obtain Ig V-region gene sequences from hybridomas secreting IgG1/kappa, IgG2b/kappa and IgM/kappa isotypes.