Direct cloning of cDNA inserts from lambda gt11 phage DNA into a plasmid vector by a novel and simple method

Bacteriophage lambda gt11 has been used quite extensively for producing cDNA libraries. The cDNA inserts are usually subcloned into a plasmid vector for large scale production and analysis. However, isolating the recombinant DNA of interest from the phage clones can be a tedious task. Since the E. coli strain Y1088 used for lambda gt11 phage infection carries a pBR322-derived plasmid endogenously, we reasoned that this endogenous plasmid could be used directly for cloning the cDNA phage insert. In this report, we describe a method in which cDNA inserts from lambda gt11 phage were cloned directly into the pBR322 plasmid vector, bypassing the time-consuming procedures of preparing plasmid DNA as a subcloning vector. This method is likely to be extended to the cloning of DNA inserts derived from other phage lambda vectors when bacteria containing endogenous pBR322 are used as host cells.     

Yeast artificial chromosomes: an alternative approach to the molecular analysis of mouse developmental mutations

Mammalian genetics now allows a molecular study of genomic regions previously analysed by genetic and embryological techniques. To simplify such an analysis, we have established a number of libraries of mouse DNA in Yeast Artificial Chromosome (YAC) vectors, constructed either by partial digestion with EcoRI, or by complete digestion with enzymes which cut rarely in the mammalian genome. In this paper we report the construction of complete digest libraries prepared from mouse genomic DNA using the rare cutter enzymes NotI and BssHII, and the detection of gene loci from the H-2 complex, the t-complex, and other loci from the mouse genome. Due to their large insert size, YAC clones simplify the cloning of extended regions of the mouse genome surrounding known developmental mutations and should, after introduction into the germ line, offer a high probability of correct expression of the genes contained within the cloned region. We hope that this will allow the use of YAC clones to scan regions of interest such as the t-complex for specific genes by testing DNA introduced into transgenic mice for the ability to complement mutations localised to this region.     

Vegetative expression of the delta-endotoxin genes of Bacillus thuringiensis subsp. kurstaki in Bacillus subtilis.

Bacillus thuringiensis subsp. kurstaki total DNA was digested with BglII and cloned into the BamHI site of plasmid pUC9 in Escherichia coli. A recombinant plasmid, pHBHE, expressed a protein of 135,000 daltons that was toxic to caterpillars. A HincII-SmaI double digest of pHBHE was then ligated to BglII-cut plasmid pBD64 and introduced into Bacillus subtilis by transformation. The transformants were identified by colony hybridization and confirmed by Southern blot hybridization. A 135,000-dalton protein which bound to an antibody specific for the crystal protein of B. thuringiensis was detected from the B. subtilis clones containing the toxin gene insert in either orientation. A toxin gene insert cloned into a PvuII site distal from the two drug resistance genes of the pBD64 vector also expressed a 135,000-dalton protein. These results suggest that the toxin gene is transcribed from its own promoter. Western blotting of proteins expressed at various stages of growth revealed that the crystal protein expression in B. subtilis begins early in the vegetative phase, while in B. thuringiensis it is concomitant with the onset of sporulation. The cloned genes when transferred to a nonsporulating strain of B. subtilis also expressed a 135,000-dalton protein. These results suggest that toxin gene expression in B. subtilis is independent of sporulation. Another toxin gene encoding a 130,000- to 135,000-dalton protein was cloned in E. coli from a library of B. thuringiensis genes established in lambda 1059. This gene was then subcloned in B. subtilis. The cell extracts from both clones were toxic to caterpillars. Electron microscope studies revealed the presence of an irregular crystal inclusion in E. coli and a well-formed bipyramidal crystal in B. subtilis clones similar to the crystals found in B. thuringiensis.     

The leftward promoter of bacteriophage lambda. Isolation on a small restriction fragment and deletion of adjacent regions

As part of our investigations on the relationship between DNA structure and gene regulation, a 352-base pair Hae III fragment was cloned containing the leftward operator-promoter (PL) region of bacteriophage lambda. This was accomplished without the aid of a phenotypic assay for the cloned fragment. A Hae III digest of a segment of the lambda genome was first fractionated by RPC-5 column chromatography. The partially purified PL fragment was then ligated into the Eco RI site of the pBR322 plasmid vector and cloned into the recBC+ Escherichia coli host C600(R-M-) using a technique that converts the Hae III ends of the fragment into Eco RI sites. Similar cloning attempts into a recBC- host (C600-SF8) were unsuccessful. The cloned fragment has the PL promoter oriented toward the tetracycline resistance genes of the vector, and is isolated from the plasmid (pRW601) by digestion with Eco RI followed by sucrose gradient sedimentation. The fragment was identified as PL by restriction mapping, repressor binding, sequencing, and promoter location. The now complete sequence of this fragment, part of which was known previously, reveals a large A/T-rich region immediately adjacent to the PL promoter. We have generated deletions in this region in order to study the influence of this sequence on promoter function.     

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.     

Direct Cloning of Yeast Genes from an Ordered Set of Lambda Clones in Saccharomyces Cerevisiae by Recombination in Vivo

We describe a technique that facilitates the isolation of yeast genes that are difficult to clone. This technique utilizes a plasmid vector that rescues lambda clones as yeast centromere plasmids. The source of these lambda clones is a set of clones whose location in the yeast genome has been determined by L. Riles et al. in 1993. The Esherichia coli-yeast shuttle plasmid carries URA3, ARS4 and CEN6, and contains DNA fragments from the lambda vector that flank the cloned yeast insert. When yeast is cotransformed with linearized plasmid and lambda clone DNA, Ura(+) transformants are obtained by a recombination event between the lambda clone and the plasmid vector that generates an autonomously replicating plasmid containing the cloned yeast DNA sequences. Genes whose genetic map positions are known can easily be identified and recovered in this plasmid by testing only those lambda clones that map to the relevant region of the yeast genome for their ability to complement the mutant phenotype. This technique facilitates the isolation of yeast genes that resist cloning either because (1) they are underrepresented in yeast genomic libraries amplified in E. coli, (2) they provide phenotypes that are too marginal to allow selection of the gene by genetic complementation or (3) they provide phenotypes that are laborious to score. We demonstrate the utility of this technique by isolating three genes, GAL83, SSN2 and MAK7, each of which presents one of these problems for cloning.     

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.     

Molecular cloning of unintegrated and a portion of integrated moloney murine leukemia viral DNA in bacteriophage lambda.

A covalently closed circular form of unintegrated viral DNA obtained from NIH 3T3 cells freshly infected with Moloney murine leukemia virus (M-MLV) and a port of the endogenous M-MLV from the BALB/Mo mouse strain have been cloned in bacteriophage lambda. The unintegrated viral DNA was cleaved with restriction endonuclease HindIII and inserted into the single HindIII site of lambda phage Charon 21A. Similarly high-molecular-weight DNA from BALB/Mo mice ws cleaved sequentially with restriction endonucleases EcoRI and HindIII and separated on the basis of size, and one of the two fractions which reacted with an M-MLV-specific complementary DNA was inserted into the HindIII site of Charon 21A. Recombinant clones containing M-MLV-reacting DNA were analyzed by restriction endonuclease mapping, heteroduplexing, and infectivity assays. The restriction endonuclease map of the insert derived from unintegrated viral DNA, lambda x MLV-1, was comparable to published maps. Electron microscope analysis of the hybrid formed between lambda x MLV-1 DNA and 35S genomic M-MLV RNA showed a duplex structure. The molecularly cloned lambda x MLV-1 DNA contained only one copy of the long terminal repeat and was not infectious even after end-to-end ligation of the insert DNA. The insert DNA derived from endogenous M-MLV, lambda x MLVint-1, contained a DNA stretch measuring 5.4 kilobase pairs in length, corresponding to the 5' part of the genomic viral RNA, and cellular mouse DNA sequences measuring 3.5 kilobase pairs in length. The viral part of the insert showed the typical restriction pattern of M-MLV DNA except that a single restriction site, PvuII, in the 5' long terminal repeat was missing. Reconstructed genomes containing the 5' half derived from the integrated viral DNA and the 3' half derived from the unintegrated viral DNA were able to induce XC plaques after transfection in uninfected mouse fibroblasts.     

Efficient construction of cDNA libraries in plasmid expression vectors using an adaptor strategy.

We describe a method for the construction of large DNA fragment libraries in plasmid vectors, in which complementary, single-stranded extensions are ligated onto both vector and insert DNA using un-phosphorylated adaptor oligonucleotides. Special consideration has been taken of the requirements of expression screening as follows: cDNA synthesis using random oligonucleotide primers is described which maximises the probability of obtaining open reading frame fragments from large mRNA molecules, the adaptors use codons found in high abundance E. coli proteins to minimise problems of premature termination when using strong promoters, and the sequence encoded by the adaptors, when cloned into the bacterial expression vector pEX1, promotes a surface location for the foreign antigenic determinant where it is accessible to antibodies used for screening.     

A Modular, Positive Selection Bacterial Artificial Chromosome Vector with Multiple Cloning Sites

To construct large-insert libraries for the sequencing, mapping, and functional studies of complex genomes, we have constructed a new modular bacterial artificial chromosome (BAC) vector, pBACe3.6 (GenBank Accession No. U80929). This vector contains multiple cloning sites located within the sacB gene, allowing positive selection for recombinant clones on sucrose-containing medium. A recognition site for the PI-SceI nuclease has also been included, which permits linearization of recombinant DNA irrespective of the characteristics of the insert sequences. An attTn7 sequence present in pBACe3.6 permits retrofitting of BAC clones by Tn7-mediated insertion of desirable sequence elements into the vector portion. The ability to retrofit BAC clones will be useful for functional analysis of genes carried on the cloned inserts. The pBACe3.6 vector has been used for the construction of many genomic libraries currently serving as resources for large-scale mapping and sequencing.     

Phasmids as effective and simple tools for construction and analysis of gene libraries

Phasmid lambda pMYF131, a hybrid of phage lambda vectors and plasmid pUC19, was constructed. The phasmid and its derivatives were shown to be efficient vectors for construction and analysis of gene libraries in Escherichia coli cells. The lambda pMYF131 DNA molecule contains all the genes and regions essential for phage lytic development. The plasmid cannot be packaged either in the monomeric or the oligomeric form due to its specific length. Elongation of the DNA molecule by ligation with fragments of foreign DNA can make it packageable and this is easily detected by plaque formation. Hence, the procedures used to construct genomic libraries can be simplified by selection of only recombinant DNA molecules just at the time and on the basis of their packaging in vitro. The output of recombinant clones per vector molecule was several times higher for vector lambda pMYF131, compared to phage vector lambda L47.1AB, and attained 3 x 10(6) clones per micrograms DNA. Vector and recombinant phasmids can be obtained in large quantities in plasmid form. lambda pMYF131 contains nine unique restriction sites which allow the cloning of DNA fragments with blunt ends and of fragments with various types of cohesive ends, obtained by digestion with 14 prototype restriction enzymes. The maximal size of the cloned DNA fragments is approx. 20 kb for lambda pMYF131. Phasmid vectors were used to construct libraries of bovine, pig and quail genomes, and genomic libraries of 17 species of bacteria. Application of suitable methods allowed the identification 13 individual genes within these libraries.     

Bacteriophage lambda display of complex cDNA libraries: a new approach to functional genomics

We describe the construction and characterization of two lambda surface displayed cDNA expression libraries derived from human brain and mouse embryo. cDNA inserts were obtained by tagged random-priming elongation of commercially available cDNA libraries and cloned into a novel lambda vector at the 3' end of the D capsid protein gene, which produced highly complex repertoires (1x10(8) and 2x10(7) phage). These libraries were affinity selected with a monoclonal antibody against the neural specific factor GAP-43 and with polyclonal antibodies that recognize the EMX1 and EMX2 homeoproteins. In both cases rapid identification of specific clones was achieved, which demonstrates the great potential of the lambda display system for generating affinity selectable cDNA libraries from complex genomes.     

Large-insert BAC/YAC libraries for selective re-isolation of genomic regions by homologous recombination in yeast.

We constructed representative large-insert bacterial artificial chromosome (BAC) libraries of two human pathogens (Trypanosoma brucei and Giardia lamblia) using a new hybrid vector, pTARBAC1, containing a yeast artificial chromosome (YAC) cassette (a yeast selectable marker and a centromere). The cassette allows transferring of BACs into yeast for their further modification. Furthermore, the new hybrid vector provides the opportunity to re-isolate each DNA insert without construction of a new library of random clones. Digestion of a BAC DNA by an endonuclease that has no recognition site in the vector, but which deletes most of the internal insert sequence and leaves the unique flanking sequences, converts a BAC into a TAR vector, thus allowing direct gene isolation. Cotransformation of a TAR vector and genomic DNA into yeast spheroplasts, and subsequent recombination between the TAR vector's flanking ends and a specific genomic fragment, allows rescue of the fragment as a circular YAC/BAC molecule. Here we prove a new cloning strategy by re-isolation of randomly chosen genomic fragments of different size from T. brucei cloned in BACs. We conclude that genomic regions of unicellular eukaryotes can be easily re-isolated using this technique, which provides an opportunity to study evolution of these genomes and the role of genome instability in pathogenicity.     

A binary vector for transferring genomic libraries to plants.

The transformation of mutant plants with a complete recombinant library derived from wild-type DNA followed by assay of transformed plants for complementation of the mutant phenotype is a promising method for the isolation of plant genes. The small genome of Arabidopsis thaliana is a good candidate for attempting this so-called shotgun transformation. We present the properties of an A. thaliana genomic library cloned in a binary vector, pC22. This vector, designed to introduce genomic libraries into plants, contains the oriV of the Ri plasmid pRiHR1 by which it replicates perfectly stably in Agrobacterium. Upon transfer of the library from E. coli to A. tumefaciens large differences in transfer efficiencies of individual recombinant clones were observed. There is a direct relation between transfer efficiency and stability of the recombinant clones both in E. coli and A. tumefaciens. The stability is independent of the insert size, but seems to be related to the nature of the insert DNA. The feasibility of shotgun transformation and problems of statistical sampling are discussed.     

PCR preparation of DNA inserts from lambda and plasmid vectors for RFLP mapping

A simplified method is described for preparing insert DNA for labelling reactions to be used in Southern hybridization. This method works with sequences cloned into both plasmid and lambda phage, and eliminates many of the steps leading to the labelling reaction. Small quantities of hostE. coli or lambda phage carrying a probe sequence are lysed and amplified via the polymerase chain reaction using standard sequencing primers. Unincorporated nucleotides are removed by ethanol precipitation or gel purification and insert DNA is ready for radio-labelling. This method reduces the time and expense associated with conventional insert preparation, and greatly simplifies the use of sequences cloned into lambda phage.     

Use of a recombination-deficient phage lambda system to construct wheat genomic libraries

The poor cloning efficiency of wheat (Triticum aestivum cv. Yamhill) DNA in conventional cloning vectors has previously prevented the preparation of complete genomic libraries. We show here that while wheat DNA does not clone efficiently using the vector Ch4A, it can be cloned efficiently using Ch32. Ch32 clones are red- gam+ and therefore can be propagated on recombination-deficient hosts. These results suggest that instability of wheat sequences in conventional lambda vector systems has frustrated previous attempts to prepare libraries.     

p lambda Zd39: a new type of cDNA expression vector for low background, high efficiency directional cloning.

We have developed a new type of bacteriophage lambda vector which provides a strong biological selection against non-recombinants that is independent of the sequences immediately surrounding the cloning site. This system, which we call 'selective substitution', is ideally suited for cDNA expression vectors where it is necessary to flank the cDNA insert with sequence elements (promoters etc.) required to produce a biologically active mRNA in vivo. Selective substitution is a general method, which may be applied to many types of vectors. In this report, we have specifically applied selective substitution to the construction of a new mammalian retrovirus expression vector. The level of background obtained with this vector (that is, the number of plaques obtained when the vector is ligated in the absence of insert DNA) is 0.02% when compared to ligation with restriction fragments and 0.1% to 0.4% when compared to ligation with newly synthesized cDNA. These features have allowed us to easily and efficiently generate several large cDNA libraries using total and size selected cDNA.     

A selective λ phage cloning vector with automatic excision of the insert in a plasmid

A bacteriophage λ cloning vehicle has been constructed for the generation of cDNA libraries. The vector has the following properties. (1) It has a unique BamHI site engineered into the λ gam gene. Segments of DNA can be cloned into this site and clones with an insert can be selected by their ability to grow on an Escherichia coli host lysogenic for phage P2 (Spi⁻ phenotype). (2) When the recombinant phage infects a Cre-producing E. coli strain, a site-specific recombination event results in the excision of a plasmid replicon with the cloned insert. (3) Single-stranded DNAs can be recovered by growing helper M13 phages on bacteria harboring such plasmids. The vector, λMGU2, has been used to construct a nematode (Caenorhabditis elegans) cDNA library.