Expression vectors for enzyme restriction- and ligation-independent cloning for producing recombinant His-fusion proteins

In this work we have constructed two novel expression vectors, designated as pURI2 and pURI3, which enable parallel cloning of a given target gene for producing recombinant His-fusion proteins. The vectors were created using the well-known pT7-7 and pIN-III-A3 plasmids as their template. The same DNA fragment containing the His-tag, enterokinase cleavage site, and a NotI unique site, as well as keeping the HindIII unique restriction site, was introduced in both vectors. These vectors have been designed to avoid the enzyme restriction and ligation steps during the cloning. The unique NotI site was introduced to facilitate the selection of the adequate recombinant plasmid. Parallel cloning of the same polymerase chain reaction fragment can be carried out since both vectors shared the same leader sequence. The described strategy avoids tedious cloning efforts into different expression vectors and represents a highly efficient means of cloning. To validate our vectors, we have cloned one target gene in both vectors and used expression and purification techniques to obtain the recombinant target protein. We herein show that both vectors function effectively in all the required experimental steps-cloning, expression, purification, and cleavage.     

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.     

Method for cloning restriction fragments containing the termini of BAC inserts

We have developed a method to isolate the termini of BAC clones. The method is based on the two unique NotI sites located approximately 300 bp on either side of the EcoRI cloning site of the BAC vector pECS-BAC4. Our strategy includes the following steps: (i) generation of Southern blots with BAC clones digested with NotI and a second restriction enzyme; (ii) identification of the termini attached to the NotI/EcoRI fragment of the BAC vector via hybridization with a probe derived from sequences located between one NotI site (left or right arm) and the cloning site; (iii) ligation of the doubly digested BAC clone (NotI and the selected second restriction enzyme) with an equally doubly digested cloning plasmid vector; and (iv) confirmation of the clone as a terminus. This strategy has allowed us to begin the construction of a contig near a common bean gene that controls resistance to a group of potyviruses.     

A high-resolution, fluorescence-based, semiautomated method for DNA fingerprinting

We describe a fluorescence-based method for the automated analysis of DNA fragments on polyacrylamide gels. A single-stranded oligonucleotide primer (18-mer) with a fluorochrome covalently bound to its 5'-end is annealed to a synthetic oligonucleotide to create a double-stranded oligonucleotide linker with a 5'-overhang complementary to a restriction enzyme site. Cosmid or plasmid DNA is digested with the appropriate restriction enzyme and then ligated to the fluorochrome-labeled linker. The labeled restriction fragments are loaded on a denaturing polyacrylamide gel in a commercially available DNA sequencer. As the restriction fragments migrate through the gel, they intersect a laser beam which excites the fluorochrome-labeled fragment. Fluorescence emission data are captured on a computer in real time and analyzed after the completion of electrophoresis. Fragment length is nearly linearly related to migration time. This method offers very near single-base resolution up to 400 bases and the ability to quantitate fragment size up to 2000 bases. The fluorochrome-labeling chemistry relies on straightforward enzymatic reactions and can be performed in a single reaction tube. Because four different fluorochromes can be used, each of 16 lanes on the gel can be used to analyze four different digest reactions, one in each color. One of the fluorochromes can be used to label size standards in each lane, eliminating interlane variability and allowing more precise estimates of fragment size. We apply the method to the analysis of overlapping cosmids.     

Direct cloning of specific genomic DNA sequences in plasmid libraries following fragment enrichment.

We describe a simple method to directly clone any DNA fragment for which a flanking restriction enzyme map is known. Genomic DNA is digested with multiple enzymes cutting outside the fragment to be cloned, selected by electroelution from an agarose gel, and cloned directly into a plasmid vector. It is only necessary to screen 10-1000 colonies and recombinant DNA is ready for immediate molecular analysis without further subcloning. The use of this technique is demonstrated for the cloning of a sequence from within the human alpha-globin complex that was previously shown to be "unclonable" in bacteriophage and cosmid vectors and which is a multiallelic general genetic marker, as well as both beta-globin alleles from an individual with beta-thalassaemia.     

A simple procedure for parallel sequence analysis of both strands of 5'-labeled DNA

Ligation of a 5'-labeled DNA restriction fragment results in a circular DNA molecule carrying the two 32Ps at the reformed restriction site. Double digestions of the circular DNA with the original enzyme and a second restriction enzyme cleavage near the labeled site allows direct chemical sequencing of one 5'-labeled DNA strand. Similar double digestions, using an isoschizomer that cleaves differently at the 32P-labeled site, allows direct sequencing of the now 3'-labeled complementary DNA strand. It is possible to directly sequence both strands of cloned DNA inserts by using the above protocol and a multiple cloning site vector that provides the necessary restriction sites. The simultaneous and parallel visualization of both DNA strands eliminates sequence ambiguities. In addition, the labeled circular molecules are particularly useful for single-hit DNA cleavage studies and DNA footprint analysis. As an example, we show here an analysis of the micrococcal nuclease-induced breaks on the two strands of the somatic 5S RNA gene of Xenopus borealis, which suggests that the enzyme may recognize and cleave small AT-containing palindromes along the DNA helix.     

Purification of BsuE methyltransferase and its application in genome mapping.

We have used a combination of BsuE methyltransferase (M-BsuE) and NotI restriction enzyme to cut genomic DNA at a subset of NotI sites. The usefulness of this system is shown in a re-examination of the restriction map of the human MHC. Combinations of methylases and restriction enzymes can be used to generate cuts at different frequencies in genomic DNA, such that they generate ends complementary to NotI ends, and can be used in conjunction with NotI linking clones in chromosome jumping experiments. These enzyme combinations have the potential to produce cutting sites in genomic DNA spaced at intervals favorable for extensive mapping, fragment enrichment, and cloning efforts.     

Vectors containing infrequently cleaved restriction sites for use in BAL 31 nuclease-assisted and end-label-mediated analysis of cloned DNA fragments

Cloning vectors derived from plasmids pUC8 and pUC18 and phage M13mp10 were constructed so as to have multiple cloning sites (MCS) flanked by the recognition/cleavage sites for the Sfi I and Not I restriction nucleases. Cleavage of vectors containing cloned DNA fragments with either of the infrequently cleaving Sfi I or Not I endonucleases will usually yield linear DNAs cleaved only at the corresponding site in the MCS, so that the cloned insert can be degraded unidirectionally by the duplex exonuclease activity of the BAL 31 nucleases until an amount equal to the length of the vector has been degraded. The ends of the above constructs resulting from cleavage with Not I or Sfi I can readily be labeled, with labeling at only the terminus of the cloned DNA available for the Sfi I site. The BAL 31 nuclease-mediated procedures enhance a previous technique for mapping of restriction enzyme fragments, allow for localization of sequences in cloned segments for which a probe is available, and improve a method for sequencing cloned inserts through the production of sets of nested unidirectional deletions from either end of the parent cloned fragment. The advantages of end-label-mediated restriction site mapping using the above vectors over existing such procedures are also demonstrated.     

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.     

A protocol for the construction of microsatellite enriched genomic library

An improved protocol for constructing microsatellite-enriched libraries was developed. The procedure depends on digesting genomic DNA with a restriction enzyme that generates blunt-ends, and on ligating linkers that, when dimerized, create a restriction site for a different blunt-end producing restriction enzyme. Efficient ligation of linkers to the genomic DNA fragments is achieved by including restriction enzymes in the ligation reaction that eliminate unwanted ligation products. After ligation, the reaction mixture is subjected to subtractive hybridization without purification. DNA fragments containing microsatellites are captured by biotin-labeled oligonucleotide repeats and recovered using streptavidin-coated beads. The recovered fragments are amplified by PCR using the linker sequence as primer, and cloned directly into a plasmid vector. The linker has the sequence GTTT on the 5′ end, which promotes efficient adenylation of the 3′ ends of the PCR products. Consequently, the amplified fragments could be cloned into vectors without purification. This procedure enables efficient enrichment and cloning of microsatellite sequences, resulting in a library with a low level of redundancy.     

Branch capture reactions: effect of recipient structure.

Branch capture reactions (BCR) contain two DNA species: (i) a recipient restriction fragment terminating in an overhang and (ii) a displacer-linker duplex terminating in a displacer tail complementary to the overhang as well as contiguous nucleotides within the recipient duplex. Branched complexes containing both species are captured by ligation of the linker to the recipient overhang. Specificity depends upon branch migration and is increased by substitution of bromodeoxycytidine for deoxycytidine in the displacer. BCR rates and specificities were determined for recipient overhangs that were (i) 5' and 3', (ii) 3 and 4 nucleotides long, and (iii) 0-100% G+C. Model systems permitted independent determination of G+C and branching effects on ligation rates and verification of rapid equilibrium between the branched complex and its component species. With all 4-base overhangs, recipient duplexes permitting extensive branch migration became saturated with displacer-linker duplexes. With increasing G+C, increasing ligation at competing sites led to decreased BCR specificity. BCR may be used to label a DNA fragment prior to electrophoresis, mark a fragment for affinity chromatography, or introduce a new overhang sequence compatible with a restriction endonuclease site in a cloning vector. A protocol was confirmed for mapping restriction sites in cloned DNA.     

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.     

Nonrandom DNA sequencing of exonuclease III-deleted complementary DNA

The nonrandom DNA sequence analysis procedure of Poncz et al. [Proc. Natl. Acad. Sci. USA 79, 4298-4302 (1982)] was extensively modified to permit the determination of complementary DNA (cDNA) sequences containing G-C homopolymer regions. The recombinant cDNA plasmid was cleaved at a unique restriction enzyme site close to the cDNA and treated with Exonuclease III under controlled conditions to generate a set of overlapping fragments having deletions 50-1500 bases in length at the free 3' termini. After removal of single-stranded DNA regions by Bal31 and DNA polymerase I large fragment, the unique restriction enzyme site was recreated by blunt end ligation of synthetic oligonucleotides to the deleted DNA fragments and restriction enzyme digestion. The cDNA fragment was excised from the cloning vector using a second different restriction enzyme having a unique site that flanks the cDNA fragment and subsequently force-cloned into either M13 mp10 or mp11. This method should also be particularly useful for the sequencing of other types of DNA molecules with lengths 1500 bp or smaller.     

Directional cloning of cDNA using a selectable SfiI cassette

To increase the efficiency of directionally cloning cDNA, we have constructed a pair of vectors and devised a cDNA cloning strategy that improves upon previously published methods. The vectors, pLIB: AZ and pLIB: ZA, have two unique (distinct religation specificities; GGCCN/NNNNGGCC) SfiI sites (SfiI.A and SfiI.B) flanking a stuffer fragment which contains the tetracycline-resistance element. These vectors permit the directional cloning of cDNA in both sense (pLIB: AZ) and antisense (pLIB: ZA) orientations relative to the promoter for phage T3 RNA polymerase. cDNA that was synthesized using a primer with a 5' sequence of a SfiI.B site followed by an oligo(dT)16 3' tail was then ligated to an adaptor with the sequence of a SfiI.A site produced directional molecules that could be cloned into the pLIB vectors. Complex libraries with 10(7) members were produced from as few as 6 x 10(5) cells. The SfiI sites and stuffer can be subcloned as a cassette to permit directional cloning in other vectors, as there are several restriction enzyme sites flanking this region to the 5' and 3'.     

The genome of Haemophilus influenzae Rd has a unique NotI site

Previous analysis of physical maps of Haemophilus influenzae, which is circular and 1.9 Mb in length [Lee and Smith, J. Bacteriol. 170 (1988) 4402-4405; Kauc et al., J. Bacteriol. 171 (1989) 2474-2479], did not detect any NotI (GCGGCCGC) restriction sites. A transposon, Tn916, was constructed to contain a NotI linker cloned into its NciI site and introduced into the H. influenzae chromosome. NotI digestion of chromosomes containing a Tn916-associated NotI site followed by separation of fragments by field-inversion gel electrophoresis revealed the presence of two fragments obtained by two NotI cuts, one in Tn916 and the other, a unique, 'natural' NotI site in the original chromosomal DNA. The examination of other Haemophilus strains demonstrated the presence of one or more NotI sites in all of those tested.     

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.