蚕豆叶绿体DNA BamH I克隆库的构建及含16S-25S rRNA基因克隆的分析

蚕豆叶绿体DNA(ct—DNA)经BamH I酶切产生26个片段,最大的为14．00kb,最小的为0．42kb。本文以pBR322为载体,E．Coli HB101为受体菌,采用标准分子克隆法构建了蚕豆ct—DNA BamH I克隆库,并从库中分离得到含叶绿体rRNA基因的克隆。32P标记的E．Coil 16S、23S rRNA能和蚕豆ct—DNA BamH I第6(B₆,5．65kb)和第9(B₉,4．70kb)个片段杂交,含有这二个片段的克隆分别命名为pVFB32和pVFBl6。利用几种限制性内切酶酶切和Southern印迹法构建了pVFBl6的物理图谱。pVFBl6电镜下观察到有一变性环(A—T丰富区),经Hind I酶切,电镜观察定位此A—T丰富区位于16S和23S rRNA基因的间隔顺序内,推测该环可能与DNA复制有关。     

一种简单有效的克隆未知旁侧DNA片段的方法

操作含长插入片段的DNA克隆时 ,经常需要进行亚克隆和测序实验。通常的方法首先是得到插入片段的限制性内切酶谱 ,然后选择合适的内切酶消化DNA ,分离靶片段 ,将其连接入质粒载体中进行下一步操作。但这种方法工作量大 ,步骤繁琐。在此 ,介绍一种不需要做限制性内切酶谱分析 ,而根据靶片段的旁侧序列直接进行亚克隆实验的方法。首先 ,选择合适的限制性内切酶消化含长插入片段的DNA克隆 ,其中一种酶切在已知的旁侧序列上 ,另一为随机选择 ;然后酶切混合物与线性化的质粒载体连接 ,转化细菌得到一“亚克隆库” ;将其中的克隆挑选入 96孔板培养后 ,按行或列混合菌液得到相应的“pool” ;最后 ,用PCR方法筛选获得含靶DNA片段的阳性克隆 ,其中所用的引物一个与已知的旁侧DNA序列配对 ,另一个与质粒载体上序列配对 ,PCR扩增已知的旁侧DNA片段以鉴定阳性克隆。多次独立实验表明该方法简单有效 ,可广泛用于亚克隆和DNA步移实验     

表达人溶菌酶基因牛乳腺特异表达载体的构建

利用高保真PCR法,分别扩增了牛乳腺酪蛋白基因的1.8kb和1.1kb的5'和3'调控 序列,克隆入TA载体.经测序鉴定后,利用DNA重组技术依次亚克隆入改造过的真核表达载体 pcDNA3(切除CMV启动子),并插入人溶菌酶基因(hLYZ)的cDNA, 构建成牛乳腺特异表达 载体.获得的重组载体经限制性内切酶酶切鉴定、PCR验证等表明,成功克隆了酪蛋白基因5 '和3'的调控区,并成功构建了表达人溶菌酶基因的牛乳腺特异表达载体.     

鹅源新城疫病毒ZJI株基因组cDNA克隆的序列修饰

将鹅源新城疫病毒ZJI株全基因组cDNA克隆通过酶切切下包含T7启动子区域和转录载体的片段,将其自身环化后获得约6．5kb的质粒。设计引物,利用基因定点突变技术,在此质粒上T7启动子与NDV Leader序列之间突变插入额外的3个G碱基,将此突变最终引入到原基因组cDNA克隆中。应用RT—PCR技术从尿囊液中扩增NDV基因组F／HN基因区域部分片段,利用限制性内切酶BsmBI将扩增片段连接,最终将原cDNA克隆中相应片段替换下。测序结果表明,原基因组cDNA克隆中特定位置碱基插入突变成功,F／HN基因区域碱基突变均得以纠正。以上cDNA克隆的修饰与替换为该毒株的反向遗传研究打下了基础。     

利用PCR对PVX外壳蛋白基因进行同义密码子修饰

利用聚合酶链式反应 (PolymeraseChainReaction ,PCR)与限制性内切酶相结合的方法 ,设计 4条含有限制性酶切位点和相应突变的引物。以马铃薯X病毒 (PotatoVirusX ,PVX)外壳蛋白cp基因为模板 ,扩增出相应的片段 ,相应酶切后通过三片段连接构建到克隆载体pBlueKS( / - )上。随机挑选重组子测序表明 ,利用三片段拼接成功地在PVX外壳蛋白基因的不同部位产生了突变。实验结果说明利用三片段接可以大大提高筛选得到突变子的效率 ,从而节省人力、物力和时间。     

口虾蛄肠道细菌种群多样性的分子分析

目的探讨口虾蛄肠道细菌种群的多样性。方法通过不依赖于分离培养的分子生物学分析方法,以直接提取虾蛄肠道细菌的总DNA为模板经过PCR扩增16S DNA,然后经与T载体连接建立质粒文库。用限制性内切酶(BsuRⅠ和Hin6Ⅰ)对阳性克隆的PCR扩增产物进行限制性酶切片段长度多态性(RFLP)分析,选取有代表性的克隆进行测序。结果16S DNA序列通过CLUSTALX进行多序列比对及NCBI数据库中的BLAST分析后发现口虾蛄肠道细菌主要分成4类:未培养细菌,未培养支原体科细菌,未培养δ变形菌和马特斯支原体。结论口虾蛄肠道细菌种类较为简单,且多为未培养的细菌。     

鹅源新城疫病毒ZJI株基因组cDNA克隆的序列修饰*

将鹅源新城疫病毒ZJI株全基因组cDNA克隆通过酶切切下包含T7启动子区域和转录载体的片段,将其自身环化后获得约6.5kb的质粒。设计引物,利用基因定点突变技术,在此质粒上T7启动子与NDV Leader序列之间突变插入额外的3个G碱基,将此突变最终引入到原基因组cDNA克隆中。应用RT-PCR技术从尿囊液中扩增NDV基因组F/HN基因区域部分片段,利用限制性内切酶BsmB I将扩增片段连接,最终将原cDNA克隆中相应片段替换下。测序结果表明,原基因组cDNA克隆中特定位置碱基     

牛β-酪蛋白基因的克隆及乳腺特异性表达载体的构建

利用PCR技术分3段克隆了长约9．7kb的牛β-酪蛋白基因,分别克隆在pGEM-T easy Vector的T位点。经NCBI Blastn分析,与牛β-酪蛋白基因相应区段的同源性为98％。这3段序列包含完整的5’侧翼序列、前8个外显子及第8个内含子的部分序列。以此构建了两个乳腺特异性表达载体：利用第1段和第2段共有的酶切位点将两段融合,作为5’调控区（6．8kb）,第3段和实验室已有的600bp的加尾信号通过重组PCR拼接作为3’调控区（3．4kb）构建了一乳腺特异性表达载体;以第一段作为5’调控区,实验室已有的600bp加尾信号作为3’为调控区构建了另一乳腺特异性表达载体。可以应用于进一步乳腺生物反应器的研制。     

一种新的DNA分子克隆方法

DNA分子克隆是基本的分子生物学实验技术,传统的分子克隆方法大多需经过酶切链接过程,但在某些情况下,没有合适的酶切位点往往会成为阻碍克隆进行的障碍.本文描述了一种新的分子克隆方法,称为不依赖酶切和链接的分子克隆（RLIC）.利用RLIC,将3种不同大小的DNA片段克隆到3种不同载体,证明了这种方法的有效性和可靠性.由于该方法不受限制性酶切序列限制,省去了酶切连接步骤,因此具有很大的灵活性和简便性,在分子生物学研究方面有广泛应用前景.     

Efficient molecular cloning of environmental DNA from geothermal sediments

An efficient and simple method for constructing an environmental library using mechanically sheared DNA obtained directly from geothermal sediments is presented. The method is based on blunt-end modification of DNA fragments followed by 3-adenylation using Vent DNA polymerase and Taq DNA polymerase, respectively. The prepared DNA fragments are then ligated into a TA cloning vector and used in the transformation of Escherichia coli. This method has been successfully applied to the cloning of ORFs derived from uncultivated prokaryotes present in geothermal sediment.     

Direct cloning of a long restriction fragment aided with a jumping clone.

Long-range physical mapping with rare-cutting restriction enzymes (rare cutters) is an important step for structural analysis of complex genomes. Combination of two types of DNA clones bearing the rare-cutter sites, linking clones and jumping clones (Fig. 1a), facilitates the physical mapping [Poustka et al., Nature 325 (1987) 353-355]. A step followed by the physical mapping is the cloning of the large (rare-cutter-generated) restriction fragment of interest. For facilitating this step, we devised a method to directly clone a long restriction fragment without constructing the whole genomic DNA library using the jumping clone as starting material. The short DNA segments of a jumping clone, which are derived from the 5' and 3' terminal regions of the large restriction fragment, are inserted into the yeast artificial chromosome plasmid (pYAC) vector, and then converted into single strands with T7 gene 6-encoded 5'----3' exonuclease. The total genomic DNA digested with the restriction enzyme is also treated with the exonuclease to convert the terminal regions of the restriction fragments into single strands. In the resulting products, only the fragment corresponding to the jumping clone can form hybrids with the just-mentioned, single-stranded DNAs, which are connected to the pYAC, and only this fragment is cloned in yeast. We describe the protocol of this method with Escherichia coli DNA as a model experiment. Judging from the cloning efficiency, this method could be applied to cloning single-copy regions of the human genome, provided a jumping clone is available. The instability of inserts in the pYAC vector is also discussed.     

Ligation-independent cloning of PCR products (LIC-PCR).

A new procedure has been developed for the efficient cloning of complex PCR mixtures, resulting in libraries exclusively consisting of recombinant clones. Recombinants are generated between PCR products and a PCR-amplified plasmid vector. The procedure does not require the use of restriction enzymes, T4 DNA ligase or alkaline phosphatase. The 5'-ends of the primers used to generate the cloneable PCR fragments contain an additional 12 nucleotide (nt) sequence lacking dCMP. As a result, the amplification products include 12-nt sequences lacking dGMP at their 3'-ends. The 3'-terminal sequence can be removed by the action of the (3'----5') exonuclease activity of T4 DNA polymerase in the presence of dGTP, leading to fragments with 5'-extending single-stranded (ss) tails of a defined sequence and length. Similarly, the entire plasmid vector is amplified with primers homologous to sequences in the multiple cloning site. The vector oligos have additional 12-nt tails complementary to the tails used for fragment amplification, permitting the creation of ss-ends with T4 DNA polymerase in the presence of dCTP. Circularization can occur between vector molecules and PCR fragments as mediated by the 12-nt cohesive ends, but not in mixtures lacking insert fragments. The resulting circular recombinant molecules do not require in vitro ligation for efficient bacterial transformation. We have applied the procedure for the cloning of inter-ALU fragments from hybrid cell-lines and human cosmid clones.     

Universal TA cloning

TA cloning is one of the simplest and most efficient methods for the cloning of PCR products. The procedure exploits the terminal transferase activity of certain thermophilic DNA polymerases, including Thermus aquaticus (Taq) polymerase. Taq polymerase has non-template dependent activity which preferentially adds a single adenosine to the 3'-ends of a double stranded DNA molecule, and thus most of the molecules PCR amplified by Taq polymerase possess single 3'-A overhangs. The use of a linearized "T-vector" which has single 3'-T overhangs on both ends allows direct, high-efficiency cloning of PCR products, facilitated by complementarity between the PCR product 3'-A overhangs and vector 3'-T overhangs. The TA cloning method can be easily modified so that the same T-vector can be used to clone any double-stranded DNA fragment, including PCR products amplified by any DNA polymerase, as well as all blunt- and sticky-ended DNA species. This technique is especially useful when compatible restriction sites are not available for the subcloning of DNA fragments from one vector to another. Directional cloning is made possible by appropriate hemi-phosphorylation of both the T-vectors and the inserts. With a single T-vector at hand, any DNA fragment can be cloned without compromising the cloning efficiency. The universal TA cloning method is thus both convenient and labor-saving.     

Sequential cloning by a vector walking along the chromosome.

A procedure was devised for sequential cloning of chromosomal DNA by cyclical integration and excision of a plasmid vector so that slightly overlapping chromosomal segments are successively cloned. The method depends on circular integration of the vector into the chromosome of a host nonpermissive for its replication, and on excision and reduction of a recombinant plasmid by use of an appropriately designed set of restriction enzyme sites in the vector. A vector suitable for cloning in Escherichia coli was constructed by combining a segment of pBR322 with a gene encoding chloramphenicol resistance expressible in many species. Sequential cloning was demonstrated in Streptococcus pneumoniae by extending a previously cloned segment of the region of the chromosome encoding maltosaccharide utilization by 8 kb in three cycles of cloning. Accuracy of the method was confirmed by hybridization of cloned DNA with chromosomal restriction fragments. It is pointed out that the similarity of the requisite genetic processes in bacteria and yeasts should allow use of the method for sequential cloning of yeast chromosomal DNA and of human or other mammalian DNA in artificial chromosomes of yeast.     

Rapid generation of subclones for DNA sequencing using the reverse cloning procedure

A fast and reliable procedure for generating subclones necessary for sequencing long stretches of DNA has been developed. The reverse cloning procedure involves cloning a fragment of DNA into a single-stranded plasmid or phage vector containing a polycloning region; synthesizing variable lengths of double-stranded DNA using a "Universal Primer"; isolating the double-stranded DNA; and force cloning the double-stranded DNA fragments into a complementary vector with the polycloning region in the reverse orientation. The resulting clones can be sequenced, using the same Universal Primer and T7 DNA polymerase, to provide overlapping DNA sequences. The reverse cloning procedure can be used to construct deletion mutations.     

Universal CG cloning of polymerase chain reaction products

Single-insert cloning of DNA fragments without restriction enzymes has traditionally been achieved using TA cloning, with annealing of a polymerase chain reaction (PCR) fragment containing a single overhanging 3′ A to a plasmid vector containing a 3′ T. In this article, we show that the analogous “CG cloning” is faster and far more efficient, using AhdI to generate a C-vector. For an afternoon ligation, CG cloning achieved double the cloning efficiency and more than 4-fold the number of transformants compared with TA cloning. However, blunt-end ligation was markedly more efficient than both. CG cloning could prove to be extremely useful for single-copy high-throughput cloning.     

Quick and clean cloning: a ligation-independent cloning strategy for selective cloning of specific PCR products from non-specific mixes

We have developed an efficient strategy for cloning of PCR products that contain an unknown region flanked by a known sequence. As with ligation-independent cloning, the strategy is based on homology between sequences present in both the vector and the insert. However, in contrast to ligation-independent cloning, the cloning vector has homology with only one of the two primers used for amplification of the insert. The other side of the linearized cloning vector has homology with a sequence present in the insert, but nested and non-overlapping with the gene-specific primer used for amplification. Since only specific products contain this sequence, but none of the non-specific products, only specific products can be cloned. Cloning is performed using a one-step reaction that only requires incubation for 10 minutes at room temperature in the presence of T4 DNA polymerase to generate single-stranded extensions at the ends of the vector and insert. The reaction mix is then directly transformed into E. coli where the annealed vector-insert complex is repaired and ligated. We have tested this method, which we call quick and clean cloning (QC cloning), for cloning of the variable regions of immunoglobulins expressed in non-Hodgkin lymphoma tumor samples. This method can also be applied to identify the flanking sequence of DNA elements such as T-DNA or transposon insertions, or be used for cloning of any PCR product with high specificity.     

LoxP-directed cloning: use of Cre recombinase as a universal restriction enzyme.

We have developed a novel way to use the Cre/loxP system for in vitro manipulation of DNA and a technique to clone DNA into circular episomes. The method is fast, reliable, and allowsflexible cloning of DNA fragments into episomes containing a loxP site. We show that a loxP site can serve as a universal target site to clone a DNA fragment digested with any restriction enzyme(s). This technique abolishes the need for compatible restriction sites in cloning vectors and targets by generating custom-designed 5' 3', or blunt ends in the desired orientation and reading frame in the vector Therefore, this method eliminates the limitations encountered when DNA fragments are cloned into vectors with a confined number of cloning sites. The 34-bp loxP sequence assures uniqueness, even when large episomes are manipulated. We present three examples, including the manipulation of a bacterial artificial chromosome. Because DNA manipulation takes place at a loxP site, we refer to this technique as loxP-directed cloning.     

A vector for purification-free cloning of polymerase chain reaction products

Conventional cloning requires the purification of restriction-enzyme-digested vectors prior to the ligation reaction. The purification often involves the separation of restriction fragments via electrophoresis, the cutting out of a piece of gel, and the gel extraction of the linearized vector. In addition to the loss of significant amounts of DNA, reduced cloning efficiency, time, and cost, these steps are also mutagenic to DNA and hazardous to humans. We developed a purification-free cloning vector pGT3 with a bright green fluorescent protein indicator that is suitable for TA cloning of polymerase chain reaction (PCR) products. PCR products were cloned into pGT3 efficiently without the gel purification steps.