Phage lambda cDNA cloning vectors for subtractive hybridization, fusion-protein synthesis and Cre-loxP automatic plasmid subcloning

We describe the construction and use of two classes of cDNA cloning vectors. The first class comprises the lambda EXLX(+) and lambda EXLX(-) vectors that can be used for the expression in Escherichia coli of proteins encoded by cDNA inserts. This is achieved by the fusion of cDNA open reading frames to the T7 gene 10 promoter and protein-coding sequences. The second class, the lambda SHLX vectors, allows the generation of large amounts of single-stranded DNA or synthetic cRNA that can be used in subtractive hybridization procedures. Both classes of vectors are designed to allow directional cDNA cloning with non-enzymatic protection of internal restriction sites. In addition, they are designed to facilitate conversion from phage lambda to plasmid clones using a genetic method based on the bacteriophage P1 site-specific recombination system; we refer to this as automatic Cre-loxP plasmid subcloning. The phage lambda arms, lambda LOX, used in the construction of these vectors have unique restriction sites positioned between the two loxP sites. Insertion of a specialized plasmid between these sites will convert it into a phage lambda cDNA cloning vector with automatic plasmid subcloning capability.     

Balanced-size and long-size cloning of full-length, cap-trapped cDNAs into vectors of the novel lambda-FLC family allows enhanced gene discovery rate and functional analysis.

We have developed a new class of cloning vectors: lambda-full-length cDNA (lambda-FLC) cloning vectors. These vectors can be bulk-excised for preparing full-length cDNA libraries in which a high proportion of the plasmids carry large inserts that can be transferred into other (for example, functional) vectors. Unlike other cloning vectors, lambda-FLC vectors accommodate a broad range of sizes of eukaryotic cDNA inserts because they contain "size balancers." Further, the main protocol we use for direct bulk excision of plasmids is mediated by a Cre-lox system and is apparently free of size bias. The average size of the inserts from excised plasmid cDNA libraries was 2.9 kb for standard and 6.9 kb for size-selected cDNA. The average insert size of the full-length cDNA libraries was correlated to the rate of new gene discovery, suggesting that effectively cloning rarely expressed mRNAs requires vectors that can accommodate large inserts from a variety of sources. Part of the vectors are also suitable for bulk transfer of inserts into various functional vectors.     

Plasmid pU29, a vehicle for mutagenesis of the photosynthetic puf operon in Rhodopseudomonas capsulata

Plasmid pU21, which carries the reaction center and light-harvesting genes (puf operon) of Rhodopseudomonas capsulata, has been redesigned by site-specific mutagenesis. Five restriction sites have been removed and three unique restriction sites have been introduced into this 11,589-bp pBR322 derivative. The modifications divide the puf structural genes into four regions separated by five unique and nonmutagenic restriction sites. These four fragments have been subcloned into the M13-mp series of vectors to facilitate oligonucleotide-mediated site-specific mutagenesis experiments on the photosynthetic apparatus structural genes. The inserts can then be returned from the M13 replicative form to the redesigned pU21 derivative. The modified plasmid, pU29, greatly facilitates in vitro mutagenesis experiments since previously described techniques and screening procedures are more efficient with M13 derivatives carrying smaller inserts. Additionally, tandem homologous sequences (the reaction center L and M subunits) within the puf operon are now separated on different phage vectors, eliminating problems encountered in the targeting of mutagenic oligonucleotides to only one of the two homologous sites.     

New yeast-Escherichia coli shuttle vectors constructed with in vitro mutagenized yeast genes lacking six-base pair restriction sites

We describe the production of new alleles of the LEU2, URA3 and TRP1 genes of Saccharomyces cerevisiae by in vitro mutagenesis. Each new allele, which lacks restriction enzyme recognition sequences found in the pUC19 multicloning site, was used to construct a unique series of yeast-Escherichia coli shuttle vectors derived from the plasmid pUC19. For each gene a 2 mu vector (YEplac), an ARS1 CEN4 vector (YCplac) and an integrative vector (YIplac) was constructed. The features of these vectors include (i) small size; (ii) unique recognition site for each restriction enzyme found in the pUC19 multicloning site; (iii) screening for plasmids containing inserts by color assay; (iv) high plasmid yield; (v) efficient transformation of S. cerevisiae. These vectors should allow greater flexibility with regard to DNA restriction fragment manipulation and subcloning.     

A quantitative analysis of shotgun cloning in Bacillus subtilis protoplasts

Summary We used the Escherichia coli-Bacillus subtilis shuttle vector pHP13, which carries the replication functions of the cryptic B. subtilis plasmid pTA1060, to study the effects of BsuM restriction, plasmid size and DNA concentration on the efficiency of shotgun cloning of heterologous E. coli DNA in B. subtilis protoplasts. In a restriction-deficient strain, clones were obtained with low frequency (19% of the transformants contained a recombinant plasmid) and large inserts (>6 kb) were relatively rare (12% of the clones contained inserts in the range of 6–9 kb). The efficiency of shotgun cloning was severely reduced in restricting protoplasts: the class of large inserts (>6 kb) was under-represented in the clone bank (4% of the clones contained inserts in the range of 6–6.1 kb). Furthermore, BsuM restriction caused structural instability of some recombinant plasmids. Transformation of protoplasts with individual recombinant plasmids showed that plasmid size and transforming activity were negatively correlated. The size effect was most extreme with cut and religated plasmid DNA. The yield of clones was independent of the DNA concentration during transformation. It is therefore unlikely that clones were not detected because of simultaneous uptake of more than one plasmid. It is concluded that shotgun cloning in B. subtilis protoplasts is inferior to that in competent cells.     

Rapid and efficient subcloning of DNA without dephosphorylation or gel electrophoresis

Conventional subcloning into plasmid vectors often involves dephosphorylation, gel electrophoresis, DNA extraction, and purification to isolate the target insert and the cleaved plasmid. This is not only time-consuming but very often problematic. We have developed strategies that can circumvent these steps by mixing digested donor and recipient plasmids together for ligation. These strategies capitalizes on: (1) the ability to enhance the ligation efficiency of desired DNA fragments into the target vector by the generation and removal of small (<50 bp) fragments from nontarget DNA using peripheral restriction sites and spin column technology and (2) the elimination of undesired ligation products after ligation by using the Lac Z gene, differences in antibiotic resistance among plasmid vectors, and unique restriction sites situated in nontarget DNA fragments.     

A plasmid cloning system utilizing replication and packaging functions of the filamentous bacteriophage fd

DNA cloning vectors were developed which utilize the replication origin (ori) of bacteriophage fd for their propagation. These vectors depend on the expression of viral gene 2 that was inserted into phage lambda, which in turn was integrated into the host genome. The constitutive expression of gene 2 in the host cells is sufficient for the propagation of at least 100 pfd plasmids per cell. In addition to the fd ori, the pfd vectors carry various antibiotic-resistance genes and unique restriction sites. Some of these vectors have no homologies to commonly used pBR plasmids or to lambda DNA. The nucleotide sequence of the vectors can be deduced from published sequences. Large DNA inserts can be stably propagated in pfd vectors; these are more stable than similar DNA fragments cloned in intact genomes of filamentous bacteriophage. Inclusion of phage sequences required for efficient phage packaging and infection with a helper phage resulted in formation of phage particles containing single-stranded plasmid genomes. Growth at 42 degrees C without selective pressure results in loss of pfd plasmids.     

Efficient integration of artificial transposons into plasmid targets in vitro: a useful tool for DNA mapping, sequencing and genetic analysis.

We have developed efficient methods for creating artificial transposons and inserting these transposons into plasmid targets in vitro, primarily for the purpose of DNA mapping and sequencing. A novel plasmid has been engineered to convert virtually any DNA sequence, or combination of sequences, into an artificial transposon; hence, custom transposons containing any desired feature can be easily designed and constructed. Such transposons are then efficiently inserted into plasmid targets, in vitro, using the integrase activity present in yeast Ty1 virus-like particles. A single in vitro integration reaction, which resembles a simple restriction digestion in the complexity of the reaction, gives rise to thousands of recoverable insertion events within DNA target molecules; this frequency approaches one insertion per phosphodiester bond in typical plasmids. Importantly, transposon insertions are recovered from all regions of DNA inserts carried on plasmid targets, indicating that integration is a random or nearly-random process. Because of its versatility, this technology offers a generalized method of generating recombinant DNA molecules of a desired structure. We have adapted this system for DNA sequencing by developing a customized artificial transposon to insert new primer binding sites into internal regions of DNA inserts carried on cloning vectors. Transposon insertions have been generated throughout several different yeast and human DNA inserts carried on plasmids, allowing the efficient recovery of sequence information from these inserts. Our results demonstrate the overall utility of this method for both small and large-scale DNA sequencing, as well as general DNA restructuring, and indicate that it could be adapted for use with a number of additional applications including functional genetic analysis.     

Versatile Escherichia coli-Bacillus shuttle vectors derived from runaway replication plasmids related to CloDF13

Summary Versatile cloning vectors were constructed employing a runaway replication mutant of the bacteriocinogenic plasmid CloDF13. These vectors can, under conditions where protein synthesis is not inhibited, be amplified in Escherichia coli to high levels by elevating the temperature and are therefore useful for the production of large quantities of DNA and protein. Since the constructed shuttle vectors, which harbour at least six unique restriction endonucleases sites, replicate in E. coli, Enterobacter cloacae, Staphylococcus aureus and a variety of Bacilli, they are applicable for the genetic engineering of both gramnegative and gram-positive bacteria.     

Construction and characterization of three yeast-Escherichia coli shuttle vectors designed for rapid subcloning of yeast genes on small DNA fragments

We have constructed three new subcloning plasmid vectors, pRC1, pRC2, and pRC3, derived from pKC7, which allow the rapid, single-step subcloning of yeast genes. Subcloning with these vectors utilizes a partial digestion with Sau3A to generate a quasi-random set of DNA fragments from the original plasmid. All three vectors contain a kanamycin resistance gene. Therefore, if the original cloned yeast DNA fragment is present in a vector that does not specify kanamycin resistance, the subclone pool can be propagated in Escherichia coli in the presence of kanamycin to select against parent plasmids that escaped restriction by Sau3A. Selection by complementation in yeast yields a collection of plasmids with smaller yeast DNA inserts containing the gene of interest. In the vectors pRC2 and pRC3, constructed from pRC1, the unique BamHI site is located within an intact tetracycline resistance gene, thus making it possible to screen bacterial transformants for those containing recombinant plasmid molecules. Vectors pRC2 and pRC3 also contain the yeast 2 micrometers DNA replication origin, and thus are more stable than plasmids carrying only the TRP1-associated replicator (ars1).     

Bacteriophage lambda-E. coli K12 vector-host system for gene cloning and expression under lactose promoter control. II. DNA fragment insertion at the vicinity of the lac UV5 promoter.

Summary Recombinant plasmids containing the entire 16S RNA gene from the rrn B cistron of E. coli inserted in Col E1 and pBR322 plasmid vectors have been constructed. These plasmids have been mapped using several restriction endonucleases as well as by DNA-RNA hybridization. These maps reveal previously undetected restriction sites in the rrn B cistron and in Col E1 plasmid DNA.     

Transfer of P1 inserts into a yeast-bacteria shuttle vector by co-transformation mediated homologous recombination.

Manipulation of genomic inserts cloned into the bacteriophage P1 vector is hindered by the large size of the inserts. We have used co-transformation mediated recombination between the yeast-bacteria shuttle vector, pClasper, and various P1 clones to transfer the entire insert from the P1 into pClasper. This results in the insert being stably maintained in yeast, facilitating mutagenesis by homologous recombination. The recombinant plasmid can subsequently be transferred to and stably maintained in bacteria for efficient plasmid preparation. This method can also be applied to inserts from P1 artificial chromosome or bacterial artificial chromosome vectors.     

One-Step Preparation of a TA-cloning Vector from a Specially Designed Parent Plasmid Containing a Dual <Emphasis Type="Italic">lacZ</Emphasis> Gene System

A high-yield method was developed for producing a TA-cloning vector suitable for blue/white colony selection from a unique parent plasmid containing a dual lacZ gene system through a one-step restriction enzyme digestion, which creates a single-base 3′-overhang. The dual lacZ gene system was realized by inserting an inner lacZ gene between two single-base 3′-overhangs, creating restriction enzyme sites within the reading-frame-adjusted outer lacZ gene sequence in the parent plasmid. The proposed method overcomes problems, such as the inefficient digestion frequently observed when generating a TA-cloning vector and the difficulty of purifying TA-cloning vectors from the digestion mixture, while maintaining the applicability of blue/white colony selection. Moreover, the use of TA-cloning vector prepared by the proposed method can provide the distinguish tool of transformants carrying the cloning product from those carrying contaminating parent plasmids, recircularized plasmids derived from incompletely digested parent plasmid fragments, or intra-molecularly ligated TA-cloning vectors derived from T-overhangs missing TA-cloning vectors (instability of the T-overhangs is another important consideration when designing TA-cloning vectors) by making all colonies except those carrying the cloning product appear blue during blue/white colony selection.     

Shuttle vectors containing a multiple cloning site and a lacZ alpha gene for conjugal transfer of DNA from Escherichia coli to gram-positive bacteria

The mobilizable shuttle cloning vectors, pAT18 and pAT19, are composed of: (i) the replication origins of pUC and of the broad-host-range enterococcal plasmid pAM beta 1; (ii) an erythromycin-resistance-encoding gene expressed in Gram- and Gram+ bacteria; (iii) the transfer origin of the IncP plasmid RK2; and (iv) the multiple cloning site and the lacZ alpha reporter gene of pUC18 (pAT18) and pUC19 (pAT19). These 6.6-kb plasmids contain ten unique cloning sites that allow screening of derivatives containing DNA inserts by alpha-complementation in Escherichia coli carrying the lacZ delta M15 deletion, and can be efficiently mobilized by self-transferable IncP plasmids co-resident in the E. coli donors. Plasmids pAT18, pAT19 and recombinant derivatives have been successfully transferred by conjugation from E. coli to Bacillus subtilis, Bacillus thuringiensis, Listeria monocytogenes, Enterococcus faecalis, Lactococcus lactis, and Staphylococcus aureus at frequencies ranging from 10(-6) to 10(-9). The presence of a restriction system in the recipient dramatically affects (by three orders of magnitude) the efficiency of conjugal transfer of these vectors from E. coli to Gram+ bacteria.     

Positive-selection and ligation-independent cloning vectors for large scale <Emphasis Type="Italic">in Planta</Emphasis> expression for plant functional genomics

Transient expression is an easy, rapid and powerful technique for producing proteins of interest in plants. Recombinational cloning is highly efficient but has disadvantages, including complicated, time consuming cloning procedures and expensive enzymes for large-scale gene cloning. To overcome these limitations, we developed new ligationindependent cloning (LIC) vectors derived from binary vectors including tobacco mosaic virus (pJL-TRBO), potato virus X (pGR106) and the pBI121 vector-based pMBP1. LIC vectors were modified to enable directional cloning of PCR products without restriction enzyme digestion or ligation reactions. In addition, the ccdB gene, which encodes a potent cell-killing protein, was introduced between the two LIC adapter sites in the pJL-LIC, pGR-LIC, and pMBP-LIC vectors for the efficient selection of recombinant clones. This new vector does not require restriction enzymes, alkaline phosphatase, or DNA ligase for cloning. To clone, the three LIC vectors are digested with SnaBI and treated with T4 DNA polymerase, which includes 3′ to 5′ exonuclease activity in the presence of only one dNTP (dGTP for the inserts and dCTP for the vector). To make recombinants, the vector plasmid and the insert PCR fragment were annealed at room temperature for 20 min prior to transformation into the host. Bacterial transformation was accomplished with 100% efficiency. To validate the new LIC vector systems, we were used to coexpressed the Phytophthora AVR and potato resistance (R) genes in N. benthamiana by infiltration of Agrobacterium. Coexpressed AVR and R genes in N. benthamiana induced the typical hypersensitive cell death resulting from in vivo interaction of the two proteins. These LIC vectors could be efficiently used for high-throughput cloning and laboratory-scale in planta expression. These vectors could provide a powerful tool for high-throughput transient expression assays for functional genomic studies in plants.     

Molecular cloning of the genome of human spumaretrovirus

DNA of human spumaretrovirus (HSRV) was cloned from both cDNA and from viral DNA into phage lambda and bacterial plasmid vectors. The recombinant plasmids harboring viral DNA were characterized by Southern blot hybridization and restriction mapping. Physical maps were constructed from cDNA and found to be colinear with the restriction maps obtained from viral DNA. The recombinant clones isolated contained viral DNA inserts which range in size from 2.2 kb to 15.4 kb. The recombinant clones allowed to construct a physical map of the complete HSRV provirus of 12.2 kb.     

UV inducible UV protection and mutation functions on the I group plasmid TP110

Summary The UV protection and mutation properties of the I group plasmid TP110 have been investigated. It is demonstrated that the genes responsible for these effects are able to complement the deficiency in umuC36 mutants of E. coli, as are the similar genes carried by the B group plasmid R16. Mu-lac inserts into TP110 have been isolated which abolish the UV protection and mutation functions. Restriction mapping of these inserts locates them within a single region of the genome. A comparison of the restriction sites of this region with the muc region of pKM101 reveals very little similarity. Expression of -galactosidase in those Mu-lac inserts in which the lacZ gene is fused to the promoter for the protection and mutation functions is inducible by DNA damaging agents, and induction in mutant strains suggests that these genes are under the direct control of the lexA repressor.     

Non-oncogenic plant vectors for use in the agrobacterium binary system

Summary Agrobacterium strains harbouring the T-region and the virulence-region of the Ti plasmid on separate replicons still display efficient T-DNA transfer to plants. Based on this binary vector strategy we have constructed T-region derived gene vectors for the introduction of foreign DNA into plants. The vectors constructed can replicate in E. coli, thus the genetic manipulations with them can be performed with E. coli as a host. They can be transferred to Agrobacterium as a cointegrate with the wide host range plasmid R772. Their T-regions are transferred to plant cells from Agrobacterium strains conferring virulence functions.The plasmid pRAL 3940 reported here is 11.5 kb large, contains a marker to identify transformed plant cells and unique restriction sites for direct cloning of passenger DNA, flanked by the left- and right-hand border fragments of the T-region (including the 25 bp border repeats). The plasmid is free of onc-genes. Therefore, is does not confer tumorigenic traits on the transformed plant cells and mature, fertile plants can thus be regenerated from them.     

几种新型植物基因表达载体的构建方法

利用基因工程技术手段研究基因功能过程中,构建基因表达载体处于转基因植物的主导地位,采用合适的构建方法会使实验效果事半功倍。植物基因表达载体的构建方法除了传统构建法、Gateway技术、三段T-DNA法、一步克隆法等,还有近年来出现的几种新型的载体构建方法:基于竞争性连接原理快速构建小片段基因表达载体;MicroRNA前体PCR置换法适用于构建小分子RNA表达载体;重组融合PCR法特别适用于插入片段中含有较多限制性酶切位点的载体构建;利用In-Fusion试剂盒可以将任何目的片段插入一个线性化载体的某个区域;构建多片段复杂载体可采用不依赖序列和连接的克隆方法(Sequence and ligation-independent cloning,SLIC)法;Gibson等温拼接法;Golden Gate拼接法。本文将在总结分析前人工作的基础上,结合自己工作的体会和经验分析这7种新方法的特点,期望通过这几种新的方法给植物基因工程表达载体的构建提供新的思路。