Rapid and reliable universal cloning of influenza A virus genes by target-primed plasmid amplification

Reverse genetics has become pivotal in influenza virus research relying on rapid generation of tailored recombinant influenza viruses. They are rescued from transfected plasmids encoding the eight influenza virus gene segments, which have been cloned using restriction endonucleases and DNA ligation. However, suitable restriction cleavage sites often are not available. Here, we describe a cloning method universal for any influenza A virus strain which is independent of restriction sites. It is based on target-primed plasmid amplification in which the insert provides two megaprimers and contains termini homologous to plasmid regions adjacent to the insertion site. For improved efficiency, a cloning vector was designed containing the negative selection marker ccdB flanked by the highly conserved influenza A virus gene termini. Using this method, we generated complete sets of functional gene segments from seven influenza A strains and three haemagglutinin genes from different serotypes amounting to 59 cloned influenza genes. These results demonstrate that this approach allows rapid and reliable cloning of any segment from any influenza A strain without any information about restriction sites. In case the PCR amplicon ends are homologous to the plasmid annealing sites only, this method is suitable for cloning of any insert with conserved termini.     

A system for shotgun DNA sequencing.

A multipurpose cloning site has been introduced into the gene for beta-galactosidase (beta-D-galactosidegalactohydrolase, EC 3.21.23) on the single-stranded DNA phage M13mp2 (Gronenborn, B. and Messing, J., (1978) Nature 272, 375-377) with the use of synthetic DNA. The site contributes 14 additional codons and does not affect the ability of the lac gene product to undergo intracistronic complementation. Two restriction endonuclease cleavage sites in the viral gene II were removed by single base-pair mutations. Using the new phage M13mp7, DNA fragments generated by cleavage with a variety of different restriction endonucleases can be cloned directly. The nucleotide sequences of the cloned DNAs can be determined rapidly by DNA synthesis using chain terminators and a synthetic oligonucleotide primer complementary to 15 bases preceeding the new array of restriction sites.     

Kilo-sequencing: an ordered strategy for rapid DNA sequence data acquisition

A strategy for rapid DNA sequence acquisition in an ordered, nonrandom manner, while retaining all of the conveniences of the dideoxy method with M13 transducing phage DNA template, is described. Target DNA 3 to 14 kb in size can be stably carried by our M13 vectors. Suitable targets are stretches of DNA which lack an enzyme recognition site which is unique on our cloning vectors and adjacent to the sequencing primer; current sites that are so useful when lacking are Pst, Xba, HindIII, BglII, EcoRI. By an in vitro procedure, we cut RF DNA once randomly and once specifically, to create thousands of deletions which start at the unique restriction site adjacent to the dideoxy sequencing primer and extend various distances across the target DNA. Phage carrying a desired size of deletions, whose DNA as template will give rise to DNA sequence data in a desired location along the target DNA, may be purified by electrophoresis alive on agarose gels. Phage running in the same location on the agarose gel thus conveniently give rise to nucleotide sequence data from the same kilobase of target DNA.     

Conversion of bacteriophage fd into an efficient single-stranded DNA vector system

Summary Single-stranded DNA vectors were constructed in vitro by insertion of various DNA fragments into the Intergenic Region of the single-stranded DNA phage fd. These inserts introduce into the phage genome unique cleavage sites for restriction nucleases which are suited for sticky joining in cloning experiments. Since these sites are usually located within genes coding for antibiotic resistance, inactivation of a resistance gene by insertion can be used as a marker for the successful cloning of a DNA fragment. Resistance genes also allow to select for recombinant DNA phages and to minimize the loss of DNA inserts which otherwise becomes significant above an insert size of about one kb. Cloning of several DNA fragments is described and strand separation of double-stranded DNA fragments by means of cloning into fd DNA is given as an example for application of single-stranded DNA vectors.Abbreviations Ap ampicillin - Cm chloramphenicol - Km kanamycin - Sm streptomycin - kb, kbp a unit length equivalent to 1000 bases, respectively 1000 base pairs - wt wild type     

Generation in vitro of deletions in the broad host range plasmid RK2 using phage Mu insertions and a restriction endonuclease

Several non-lethal deletions of the broad host range plasmid RK2 (molecular weight of 37.6 . 10(6) have been produced in vitro. The method employed relied on the single HindIII restriction nuclease site in RK2 and the ability of phage Mu to insert and thereby add new HindIII restriction sites at various positions in the plasmid. The deleted plasmids have in each case lost kanamycin (Km) resistance, and in two cases are defective in self-transmissibility. The method used to reduce the size of the RK2 plasmid also results in the cloning of each of the two ends of the Mu phage DNA on the plasmid derivatives.     

Construction and characterization of new coliphage M13 cloning vectors

New single-stranded DNA cloning vectors have been constructed by the insertion of additional DNA fragments into a HaeII restriction site in the bacteriophage M13 duplex replicative form (RF). These inserts into the M13 genome bring a single restriction sites useful for cloning, including PstI, XorII, EcoRI, SstI, XhoI, KpnI, and PvuII. Drug-resistance genes cloned into M13 include the beta-lactamase (bla) gene and the chloramphenicol acetyl transferase (cat) gene. These vectors provide a convenient means of easily obtaining the separated strands of a cloned duplex DNA fragment by cloning the fragment in each of the two possible orientations. Standard cloning techniques commonly applied to double-stranded DNAs can be utilized to insert foreign DNAs into the duplex RF DNAs of these vectors. Cells transformed by chimeric DNAs extrude filamentous phage particles carrying a circular single-stranded copy of the chimeric viral strand. Because M13-infected cells continue to grow and divide, cells can be transformed to yield either plaques or drug-resistant colonies. Specific inserts are readily detected by plaque hybridization techniques using an appropriate probe. Chimeric viral single strands from virus particles in the supernatant of small volumes of infected cultures can be rapidly and sensitively analyzed by agarose gel electrophoresis to determine the size of an insert.     

A versatile primer for DNA sequencing in the M13mp2 cloning system

A primer for DNA sequencing by the chain-termination method in the M13mp2 cloning system was constructed and amplified. The primer was isolated as an EcoRI/AluI restriction fragment. After conversion of the AluI end into an EcoRI end the fragment was cloned in pBR325 from which it can be recovered by cleavage with EcoRI. The primer hybridizes to the single-stranded DNA of the mature M13mp2 phage next to the site of insertion thereby directing DNA synthesis along the inserted DNA.     

Rapid generation of nested deletions by differential restriction digestion

A method was devised for generating nested deletions in DNA that exploits the difference in frequency of restriction sites recognized by compatible restriction endonucleases. A cloning vector was constructed that contains no common blunt-end or RsaI restriction sites and two 8-bp blunt-end restriction sites flanking a commodious multiple cloning site. DNA fragments are cloned into the multiple cloning site using blue-white selection, and nested deletions are generated by digesting the resulting plasmid with either SwaI or PmeI and partially digesting the insert DNA with RsaI. The DNAs are ligated and transformed, producing afamily of plasmids with different-sized deletions. The DNA sequence of these inserts can be rapidly determined, and the overlapping sequences can be assembled in silico to produce a large DNA contig. Nested deletions generated in this manner can also be used for the structure-function analysis of proteins.     

Targeted gene walking polymerase chain reaction.

We describe a modification of a polymerase chain reaction method called 'targeted gene walking' that can be used for the amplification of unknown DNA sequences adjacent to a short stretch of known sequence by using the combination of a single, targeted sequence specific PCR primer with a second, nonspecific 'walking' primer. This technique can replace conventional cloning and screening methods with a single step PCR protocol to greatly expedite the isolation of sequences either upstream or downstream from a known sequence. A number of potential applications are discussed, including its utility as an alternative to cloning and screening for new genes or cDNAs, as a method for searching for polymorphic sites, restriction endonuclease or regulatory regions, and its adaptation to rapidly sequence DNA of lengthy unknown regions that are contiguous to known genes.     

High efficiency vectors for cosmid microcloning and genomic analysis

We describe the construction and use of cosmid vectors designed for microcloning, gene isolation and genomic mapping starting from submicrogram amounts of eukaryotic DNA. These vectors contain (1) multiple cos sites to allow for simple and efficient cloning using non size-selected DNA; (2) bacteriophage T3 and T7 promoter sequences flanking the cloning site to allow for the synthesis of end-specific probes for chromosome walking; (3) a selectable gene for immediate gene transfer of cosmid DNA into mammalian cells; (4) recognition sequences for specific oligodeoxyribonucleotides to allow rapid restriction mapping; (5) unique NotI, SacII or SfiI sites flanking the cloning site to allow for removal of the cloned DNA insert from the vector. These cosmid vectors allow the construction of high quality genomic libraries in situations where the quantity of purified DNA is extremely limited, such as when using DNA prepared from purified mammalian chromosomes isolated by fluorescence-activated cell sorting.     

Functional cloning vectors for use in directional cDNA cloning using cohesive ends produced with T4 DNA polymerase.

This paper describes the construction of 'Prime' cloning vectors, which include phage lambda and plasmid vectors useful for functional cloning in oocytes, yeast, and mammalian cells, and their use in a 'Prime' cloning system. The system takes advantage of the very active and precise 3' exonuclease activity of T4 DNA polymerase to produce single-stranded (ss) ends (cut-back) of vector and insert DNA. This results in the highly efficient directional cloning of cDNA and PCR-amplified DNA. The system obviates the need to digest insert DNA with a restriction endonuclease to unveil cloning sites, and thus eliminates the chance of internal digestion of the insert DNA. The cloning of PCR-amplified DNA, which is sometimes difficult, is made routine with this system. The 'Prime' sequence is included in vector cloning sites and cDNA and PCR primers. The 'Prime' sequence was chosen so that the ss sticky ends are nonpalindromic and will hybridize only to the appropriate partners. This makes cloning with the 'Prime' system very efficient, because neither the vector nor insert DNA is lost to unproductive self-hybridization.     

Rapid isolation of cosmid insert DNA by triple-helix-mediated affinity capture

A simple and rapid method for the isolation of cosmid insert DNA was developed based on triple-helix-mediated affinity capture (TAC). A modified cosmid was constructed from the SuperCos 1 cosmid vector by flanking the cloning site with two homopurine-homopyrimidine triple-helix-forming sequences. The cosmid DNA is digested with NotI restriction enzyme to release the insert DNA. The NotI-digested cosmid DNA is then combined with a biotinylated homopyrimidine oligonucleotide in an acidic buffer solution to form a triple-helix complex. The triple-helix complex is captured with streptavidin-coated magnetic beads. Insert DNA is eluted by adding a pH 9 buffered solution to the captured complex, The purified insert DNA is recovered with a yield of up to 95% and a purity of at least 95%. The isolated insert DNA was directly digested with CviJI restriction endonuclease to generate random fragments for shotgun sequencing.     

The pIC plasmid and phage vectors with versatile cloning sites for recombinant selection by insertional inactivation

The versatility of insertional inactivation of β-galactosidase activity for subcloning and sequencing has been enhanced by combining a chemically synthesized oligonucleotide which specifies nine 6-bp-cutter restriction sites including BglII, XhoI, NruI, ClaI, SacI and EcoRV in various configurations with existing polylinkers to create a set of highly versatile cloning sites. These improved polylinkers have been inserted into plasmids (the pICs) for routine cloning of double-stranded DNA, and into chimeric phage/plasmids (the pICEMs) for biological production of single stranded DNA. The most versatile Polylinker specifies 17 restriction sites in the β-galactosidase α-complementing gene fragment. One of the new polylinkers was inserted into M 13 DNA to produce a vector (M13mIC7) with nine cloning sites.     

霍乱弧菌分型噬菌体VP3基因组序列的测定与分析

测定和分析霍乱弧菌分型噬菌体VP3基因组序列,并为ElTor型霍乱弧菌两类菌株的分型方法原理提供研究基础。鸟枪法构建VP3噬菌体全基因组随机文库;测序拼接成最小重叠群,引物步移法填补缝隙序列,拼接后获得VP3全基因组序列。PCR随机扩增噬菌体DNA片段并酶切鉴定;预测可能存在的开放读码框(ORF);对VP3和相关噬菌体的DNA聚合酶基因作进化树分析,协助判定VP3的分类;对预测的部分启动子区利用报道基因进行活性分析。VP3全基因组为环状双链DNA,长度39504bp;酶切鉴定结果与序列一致。确定了49个ORF,注释了27个ORF的编码产物,其中有20个基因产物与T7样噬菌体同源,包括RNA聚合酶(RNAP)、参与DNA复制的蛋白、衣壳蛋白、尾管及尾丝蛋白、DNA包装蛋白等。DNA聚合酶(DNAP)进化树分析表明VP3与T7样噬菌体有同源性。将预测的10个启动子序列克隆到lacZ融合质粒pRS1274上,经检测均具有启动子活性。测定和分析VP3的基因组序列,基因组结构与进化树分析提示VP3属于T7噬菌体家族。     

PCR method for generating multiple mutations at adjacent sites

Procedures to introduce point mutations, restriction sites and insert or delete DNA fragments are very important tools to study protein function. We describe here two-step PCR-based method for generating single or multiple mutations, insertions and delections in a small region of the sequence. In the first step, a unique restriction site is introduced near the part of DNA sequence to be changed, without changing the amino acid sequence. For this step, one of the methods already described can be used. In the second step, mutations are introduced using mutagenic primers containing the unique restriction site from the first step at the 5′ end, paired with a universal primer crossing another unique restriction site present originally in the sequence. The method is very simple, economic and rapid. In comparison with the traditionalin vitro mutagenesis methods, one can generate large numbers of mutated plasmids in hours.     

RF cloning: a restriction-free method for inserting target genes into plasmids

Restriction-free (RF) cloning provides a simple, universal method to precisely insert a DNA fragment into any desired location within a circular plasmid, independent of restriction sites, ligation, or alterations in either the vector or the gene of interest. The technique uses a PCR fragment encoding a gene of interest as a pair of primers in a linear amplification reaction around a circular plasmid. In contrast to QuickChange site-directed mutagenesis, which introduces single mutations or small insertions/deletions, RF cloning inserts complete genes without the introduction of unwanted extra residues. The absence of any alterations to the protein as well as the simplicity of both the primer design and the procedure itself makes it suitable for high-throughput expression and ideal for structural genomics.     

Restriction of lambda trp bacteriophages by Escherichia coli K

trp-transducing derivatives of phage λ have been used to study Escherichia coli K specific restriction in vivo. The expression of the trp genes from unmodified phages during infection of a rec⁺, restricting host is eliminated by restriction. In a K-restricting recB,C host, where degradation of restricted phage DNA is prevented, expression of the trp genes is little affected by the presence of a single unmodified, K-restriction recognition site, even when that site is within the trpE gene. RI restriction, in contrast to K restriction, prevents trp gene expression in a recB,C host when the restriction target is between the trp genes and the relevant promoter. The presence of two K-restriction recognition sites in a λtrp phage can have a marked effect on trp gene expression. This effect can be interpreted as the result of preferential breakage between the two restriction recognition sites. We conclude that K restriction does not break susceptible DNA at, or even preferentially near, a restriction recognition sequence.