应用RD-PCR技术制备基因芯片靶基因片段

应用RD－PCR技术分离SH－SY5Y细胞的基因片段。从正常培养的SH－SY5Y细胞中提取总RNA,经oligo(dT）纤维素柱纯化分离出mRNA,然后以oligo(dT18)为锚定引物反转录生成单链cDNA,再以此为模板合成DNA的第二条链;将双链DNA经Sau3AI酶切之后,接上接头,经通用引物和选择性引物进行扩增;然后与载体pMD18-T相连,克隆鉴定、筛选、测序。所分离的cDNA片段经过扩增后用于制备基因芯片的靶基因,杂交检测的结果表明,此种方法所分离的基因片段可以用于基因芯片的靶基因片段,所制备的芯片将为进一步研究神经细胞基因表达提供了条件。     

A modified overlap extension PCR method to create chimeric genes in the absence of restriction enzymes

A modified overlap extension technique for the creation of chimeric genes is described: the method consists in three PCR steps. The first step is a conventional PCR reaction, in which oligonucleotide primers are partially complementary at their 5' ends to the adjacent fragments that are fused to create the chimer. The second PCR step consists in the fusion of the PCR fragments generated in the first step using the complementary extremities of the primers. The third step corresponds to the PCR amplification of the fusion product. The final PCR product is a chimeric gene built up with the different amplified PCR fragments. The technique is illustrated by the construction of a chimeric 5- hydroxytryptamine (5-HT, serotonin)1B/D receptor by combining one part of the human 5-HT1B (h5-HT1B) and two parts of the h5-HT1D receptor gene. The chimeric gene expressed in Cos-7 cells yielded similar binding properties as the wild type h5-HT1D receptor. © Rapid Science Ltd. 1998     

Creating random mutagenesis libraries using megaprimer PCR of whole plasmid

The conventional method for cloning a DNA fragment is to insert it into a vector and ligate it. Although this method is commonly used, it is labor intensive because the ratio and concentrations of the DNA insert and the vector need optimizing. Even then, the resultant library is often plagued with unwanted plasmids that have no inserts or multiple inserts. These species have to be eradicated to avoid tedious screening, especially when producing a mutant gene library. To overcome these problems, we modified the QuikChange protocol so that each plasmid carries a single insert. Although the QuikChange was originally developed for site-directed mutagenesis using complementary mutagenic oligonucleotide primers in whole plasmid PCR, we found that the protocol also worked for megaprimers consisting of hundreds of nucleotides. Based on this discovery, we used insert fragments, which we wanted to clone, as the primers in the QuikChange reaction. The resultant libraries were virtually free from species with no inserts or multiple inserts. The present method, which we designated MEGAWHOP (megaprimer PCR of whole plasmid), is thus ideal for creating random mutagenesis megalibraries.     

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.     

A site-directed mutagenesis method particularly useful for creating otherwise difficult-to-make mutants and alanine scanning

Site-directed mutagenesis has become routine in molecular biology. However, many mutants can still be very difficult to create. Complicated chimerical mutations, tandem repeats, inverted sequences, GC-rich regions, and/or heavy secondary structures can cause inefficient or incorrect binding of the mutagenic primer to the target sequence and affect the subsequent amplification. In theory, these problems can be avoided by introducing the mutations into the target sequence using mutagenic fragments and so removing the need for primer-template annealing. The cassette mutagenesis uses the mutagenic fragment in its protocol; however, in most cases it needs to perform two rounds of mutagenic primer-based mutagenesis to introduce suitable restriction enzyme sites into templates and is not suitable for routine mutagenesis. Here we describe a highly efficient method in which the template except the region to be mutated is amplified by polymerase chain reaction (PCR) and the type IIs restriction enzyme-digested PCR product is directly ligated with the mutagenic fragment. Our method requires no assistance of mutagenic primers. We have used this method to create various types of difficult-to-make mutants with mutagenic frequencies of nearly 100%. Our protocol has many advantages over the prevalent QuikChange method and is a valuable tool for studies on gene structure and function.     

Efficient One-Step Fusion PCR Based on Dual-Asymmetric Primers and Two-Step Annealing

Gene splicing by fusion PCR is a versatile and widely used methodology, especially in synthetic biology. We here describe a rapid method for splicing two fragments by one-round fusion PCR with a dual-asymmetric primers and two-step annealing (ODT) method. During the process, the asymmetric intermediate fragments were generated in the early stage. Thereafter, they were hybridized in the subsequent cycles to serve as template for the target full-length product. The process parameters such as primer ratio, elongation temperature and cycle numbers were optimized. In addition, the fusion products produced with this method were successfully applied in seamless genome editing. The fusion of two fragments by this method takes less than 0.5 day. The method is expected to facilitate various kinds of complex genetic engineering projects with enhanced efficiency.     

Rapid and efficient site-directed mutagenesis by single-tube 'megaprimer' PCR method.

We describe a rapid and efficient megaprimer PCR procedure for site-directed mutagenesis that does not require any intermediate purification of DNA between the two rounds of PCR. This protocol is based on the design of forward and reverse flanking primers with significantly different melting temperatures ( T m). A megaprimer is synthesized in the first PCR reaction using a mutagenic primer, the low T m flanking primer and a low annealing temperature. The second PCR reaction is performed in the same tube as the first PCR and utilizes the high T m flanking primer, the megaprimer product of the first PCR and a high annealing temperature, which prevents priming by the low T m primer from the first PCR reaction. We have used this protocol with two different plasmids to produce cDNAs encoding seven distinct mutated proteins. We have observed an average mutagenesis efficiency of 82% in these experiments.     

Analysis of microbial communities using culture-dependent and culture-independent approaches in an anaerobic/aerobic SBR reactor

Comparative analysis of microbial communities in a sequencing batch reactor which performed enhanced biological phosphorus removal (EBPR) was carried out using a cultivation-based technique and 16S rRNA gene clone libraries. A standard PCR protocol and a modified PCR protocol with low PCR cycle was applied to the two clone libraries of the 16S rRNA gene sequences obtained from EBPR sludge, respectively, and the resulting 424 clones were analyzed using restriction fragment length polymorphisms (RFLPs) on 16S rRNA gene inserts. Comparison of two clone libraries showed that the modified PCR protocol decreased the incidence of distinct fragment patterns from about 63% (137 of 217) in the standard PCR method to about 34% (70 of 207) under the modified protocol, suggesting that just a low level of PCR cycling (5 cycles after 15 cycles) can significantly reduce the formation of chimeric DNA in the final PCR products. Phylogenetic analysis of 81 groups with distinct RFLP patterns that were obtained using the modified PCR method revealed that the clones were affiliated with at least 11 phyla or classes of the domain Bacteria. However, the analyses of 327 colonies, which were grouped into just 41 distinct types by RFLP analysis, showed that they could be classified into five major bacterial lineages: alpha, beta, gamma- Proteobacteria, Actinobacteria, and the phylum Bacteroidetes, which indicated that the microbial community yielded from the cultivation-based method was still much simpler than that yielded from the PCR-based molecular method. In this study, the discrepancy observed between the communities obtained from PCR-based and cultivation-based methods seems to result from low culturabilities of bacteria or PCR bias even though modified culture and PCR methods were used. Therefore, continuous development of PCR protocol and cultivation techniques is needed to reduce this discrepancy.     

Gene splicing and mutagenesis by PCR-driven overlap extension

Extension of overlapping gene segments by PCR is a simple, versatile technique for site-directed mutagenesis and gene splicing. Initial PCRs generate overlapping gene segments that are then used as template DNA for another PCR to create a full-length product. Internal primers generate overlapping, complementary 3' ends on the intermediate segments and introduce nucleotide substitutions, insertions or deletions for site-directed mutagenesis, or for gene splicing, encode the nucleotides found at the junction of adjoining gene segments. Overlapping strands of these intermediate products hybridize at this 3' region in a subsequent PCR and are extended to generate the full-length product amplified by flanking primers that can include restriction enzyme sites for inserting the product into an expression vector for cloning purposes. The highly efficient generation of mutant or chimeric genes by this method can easily be accomplished with standard laboratory reagents in approximately 1 week.     

Improved PCR-based gene synthesis method and its application to the Citrobacter freundii phytase gene codon modification

Gene synthesis technologies provide a powerful tool for increasing protein expression through codon optimization and gene modification. Here we describe an improved PCR-based gene synthesis technology, which is accurate, simple and cheap. The improved PCR-based gene synthesis (IPS) method consists of two steps. The first one is the synthesis of 300-400 bp fragments by PCR reaction with Pfu DNA polymerase from 60-mer and 30-mer oligonucleotides with a 15 bp overlap. The second one is assembling of fragments from the first step into the full-length gene by PCR reaction. Using this approach, we have successfully synthesized a modified phytase gene with 1256 bp in length with optimal codons for expression in Pichia pastoris. P. pastoris strain that expressed the modified phytase gene (phyA-mod) showed a 50% increase in phytase activity level. In addition, we propose an inexpensive method for error correction, based on overlap-extension PCR (OE-PCR).     

In vitro 'sexual' evolution through the PCR-based staggered extension process (StEP)

This protocol describes a directed evolution method for in vitro mutagenesis and recombination of polynucleotide sequences. The staggered extension process (StEP) is essentially a modified PCR that uses highly abbreviated annealing and extension steps to generate staggered DNA fragments and promote crossover events along the full length of the template sequence(s). The resulting library of chimeric polynucleotide sequence(s) is subjected to subsequent high-throughput functional analysis. The recombination efficiency of the StEP method is comparable to that of the most widely used in vitro DNA recombination method, DNA shuffling. However, the StEP method does not require DNA fragmentation and can be carried out in a single tube. This protocol can be completed in 4-6 h.     

应用限制性显示技术制备HCV cDNA诊断基因芯片的初步研究

制备丙型肝炎病毒 (HCV)检测芯片并进行验证、初步检测质量评价。采用限制性显示 (Restrictiondisplay ,RD)技术制备芯片探针 ,从载体pCV_J4L6S中切出HCV全长cDNA ,Sau3AⅠ酶消化 ,所得的限制性片段进行RD_PCR扩增 ,经聚丙烯酰胺电泳 (PAGE)结合银染法进行分离。切胶回收后作 3次PCR ,得到较纯净的HCVcDNA限制性片段。扩增后的产物克隆至pMD18_T载体进行快速鉴定。将筛选出的限制性片段打印在氨基修饰的玻片上制备成检测芯片进行杂交验证分析 ,对芯片检测进行优化、初步的质量评估。运用RD技术 ,得到 2 4个 2 0 0～ 80 0bp、大小均一的基因片段 ,序列分析表明 ,均属于HCV特异基因 ,可以作为诊断芯片探针 ;杂交、测序结果显示 ,芯片检测的敏感性、特异性、准确度、重复性、线性等指标均佳。利用RD技术制备基因芯片探针是一种快速、简便的实用方法 ;制备的诊断芯片可以用于检测HCVRNA ,具有敏感、检测结果较为可靠的优点。     

Splicing together different regions of a gene by modified polymerase chain reaction-based site-directed mutagenesis

A modified polymerase chain reaction (PCR)-based site-directed mutagenesis method used to splice together different regions of a gene by deleting hundreds of nucleotides of undesired sequences is described. This method was inspired by a PCR-based site-directed mutagenesis method developed by Stratagene (La Jolla, CA, USA); the procedure and primer design were modified to enable the method to generate deletions several hundreds of nucleotides in length with an efficiency of 80-100%, and to delete two DNA fragments simultaneously in a single PCR. This method should be useful for deletion of large DNA fragments from a gene.     

Template-blocking PCR: An advanced PCR technique for genome walking

This article describes the development of an improved method for the isolation of genomic fragments adjacent to a known DNA sequence based on a cassette ligation-mediated polymerase chain reaction (PCR) technique. To reduce the nonspecific amplification of PCR-based genome walking, the 3′ ends of the restriction enzyme-digested genomic DNA fragments were blocked with dideoxynucleoside triphosphate (ddNTP) and ligated with properly designed cassettes. The modified genomic DNA fragments flanked with cassettes were used as a template for the amplification of a target gene with a gene-specific primer (GSP) and a cassette primer (CP). The ddNTP blocking of the genomic DNA ends significantly reduced the nonspecific amplification and resulted in a simple and rapid walking along the genome. The efficiency of the template-blocking PCR method was confirmed by a carefully designed control experiment. The method was successfully applied for the cloning of the PGK1 promoter from Pichia ciferrii and two novel cellulase genes from Penicillium sp.     

Rapid PCR amplification of chimeric products and its direct application to in vitro testing of recombinant DNA construction strategies

This article describes a simple and rapid method for efficient production of chimeric products by polymerase chain reaction (PCR). This protocol is amenable to site-directed mutagenesis strategies and can be done without the time-consuming gel purification step. The PCR products generated can also be directly used for direct gene transfer into plant cells without further subcloning to test construction strategies. An erratum to this article is available at .     

A rapid and efficient PCR-based mutagenesis method applicable to cell physiology study

PCR-based mutagenesis is a cornerstone of molecular biology and protein engineering studies. Herein we describe a rapid and highly efficient mutagenesis method using type IIs restriction enzymes. A template gene is amplified into two separate PCR fragments using two pairs of anchor and mutagenic primers. Mutated sequences are located near the recognition site of a type IIs restriction enzyme. After digestion of two fragments with a type IIs enzyme, exposed cohesive ends that are complementary to each other are then ligated together to generate a mutated gene. We applied this method to introduce multiple site-directed mutations in EGFP and Bcl-2 family genes and observed perfect mutagenesis efficiency at the desired sites. This efficient and cost-effective mutagenesis method can be applied to a wide variety of structural and functional studies in cell physiology. Type IIs restriction enzyme; enhanced green fluorescent protein; Bcl-2     

邻近多位点基因突变的组合大引物PCR策略(英文)

报道了一种新的组合多位点突变策略,通过单管中三阶段聚合酶链式反应(PCR)得以实现。在第一阶段,PCR扩增出多位点突变大引物,然后在第二阶段延伸大引物,在第三阶段获得全长突变基因序列。基于退火温度与热循环参数的组合大引物反应的优化,三个阶段中退火温度差异小(低于10°C),成功扩增出多位点突变基因序列和比邻突变序列。是一种简单、高效的多位点突变方法。     

Mutational analysis by a combined application of the multiple restriction fragment-single strand conformation polymorphism and the direct linear amplification DNA sequencing protocols.

We describe here an improved procedure for polymerase chain reaction (PCR)-based single strand conformation polymorphism (SSCP) for rapid mutational detection. To circumvent the restriction of having to analyze relatively short PCR fragments, restriction endonucleases were used to cleave a longer PCR product and the mixture of fragments was analyzed directly in SSCP gel electrophoresis. This multiple restriction fragment (MRF)-SSCP protocol was demonstrated by the detection of a 4-bp deletion in codons 41-42 and a point mutation in the IVS-2 sequence of the human beta-globin gene. The MRF-SSCP or the standard SSCP protocol was then combined with the linear amplification DNA sequencing (LADS) procedure for direct analysis of the PCR products without further purification for an exact characterization of the mutations detected. In the LADS analysis, homo- or heterozygosity of a mutation was easily distinguished by the appearance of a single- or double-lane band in the sequencing gel. The choice of isotope used and different labeling methods were compared and were found, in some cases, to produce SSCP patterns of different complexities. The combined MRF-SSCP/LADS protocol permits rapid mutational analysis of a large number of clinical samples using only very small amounts of materials and can easily be adopted for nonisotopic clinical applications.