Plasmids related to the broad host range vector, pRK290, useful for gene cloning and for monitoring gene expression

Derivatives of plasmid pRK290 that are useful for cloning and for analyzing gene expression in a wide variety of Gram-negative bacteria are described. A smaller broad host range plasmid derived from RK2, with properties similar to that of pRK290, is also described.     

Construction of shuttle cloning vectors for Bacteroides fragilis and use in assaying foreign tetracycline resistance gene expression

Shuttle vectors capable of replication in both Escherichia coli and Bacteroides fragilis have been developed. Conjugal transfer of these plasmids from E. coli to B. fragilis is facilitated by inclusion of the origin of transfer of the IncP plasmid RK2. The vectors pDK1 and pDK2 provide unique sites for cloning selectable markers in Bacteroides. pOA10 is a cosmid vector containing the replication region of pCP1 necessary for maintenance in Bacteroides. pDK3, pDK4.1, and pDK4.2 contain the Bacteroides clindamycin resistance gene allowing selection and maintenance in B. fragilis of plasmids containing inserted DNA fragments. pDK3 was used to test the expression in B. fragilis of five foreign tetracycline resistance (TcR) genes. The tetA, -B, and -C markers from facultative gram-negative bacteria, as well as a TcR determinant from Clostridium perfringens, did not express TcR in B. fragilis. The tetM gene, originally described in streptococci, encoded a small but reproducible increase of TcR in Bacteroides. These studies demonstrate the utility of shuttle vectors for introducing cloned genes into Bacteroides and underscore the differences in gene expression in these anaerobes.     

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.     

Screening costramid libraries for chromosomal genes: an alternative interspecific hybridization method

Abstract Broad host-range RK2-based cosmid vectors ('costramids') are increasingly used in molecular genetic studies of Gram-negative soil bacteria such as Rhizobium spp. we describe a simple modification of existing methods, whereby a genomic library constructed in a stringently replicated vector can be screened for genes which are undetectable by colony hybridization due to background cross-hybridization. This method allows the use of 'heterologous' probes (interspecies hybridization) to isolate several presumptive genes of interest from a gene bank of Rhizobium sp. NGR234 made in the costramid pRK7813. These are a gene with homology to the citrate synthase gene ( gltA ) or Escherichia coli , the gene encoding δ-aminol evulinic acid synthase ( hemA ), and a gene or genes regulating dicarboxylate transport.     

Construction of Plasmid Vectors for Screening Replicons from Gram-Positive Bacteria and Their Use as Shuttle Cloning Vectors

Plasmids play a central role in engineering recombinant bacteria because they are the primary vehicles used to manipulate targeted sequences. In some cases, bacteria of interest are poorly provided with suitable tools for these molecular or genetic manipulations. In this context, we constructed from two shuttle cloning vectors, pUCB2871 and pUCB2872, the basic vectors pUCB30 and pUCB31, which could represent suitable tools to isolate replicons from Gram-positive bacteria. These plasmid vectors are characterized by the following after-features: (a) the pUC origin of replication is unable to replicate in Gram-positive bacteria; (b) an erythromycin-resistance encoding gene that is functional in both Gram-negative and -positive bacteria; (c) the pUC19 multiple cloning site (MCS) within the lacZα reporter gene; and (4) an additional multiple cloning site (MCS). Cloning replicons from Gram-positive bacteria in this additional MCS would allow the derivative vectors to function directly as shuttle cloning vectors.     

Novel plasmid vectors for gene cloning in Pseudomonas.

Novel host-vector systems have been developed for gene cloning in the metabolically versatile bacterial genus Pseudomonas. We found that a new Pseudomonas strain, Pseudomonas flavida IF-4, isolated from soil, carried two small cryptic plasmids, named pNI10 and pNI20. They were multi-copy, but not self-transmissible, and the genome size was 3.7 kb for pNI10 and 2.9 kb for pNI20. Several types of cloning vectors containing a kanamycin or streptomycin resistance (Kmr or Smr) gene were constructed from pNI10 and pNI20. These plasmid vectors were efficiently transformed into several strains of Pseudomonas at a frequency up to 4 x 10(5) transformants per 1 microgram plasmid DNA by the usual competent cell method. The vectors derived from pNI10 replicated not only in Pseudomonas but also in some other Gram-negative enteric bacteria such as Escherichia coli, Enterobacter aerogenes, and Proteus mirabilis.     

Improved broad-host-range plasmids for DNA cloning in gram-negative bacteria

Improved broad-host-range plasmid vectors were constructed based on existing plasmids RSF1010 and RK404. The new plasmids pDSK509, pDSK519, and pRK415, have several additional cloning sites and improved antibiotic-resistance genes which facilitate subcloning and mobilization into various Gram-negative bacteria. Several new polylinker sites were added to the Escherichia coli plasmids pUC118 and pUC119, resulting in the new plasmids, pUC128 and pUC129. These plasmids facilitate the transfer of cloned DNA fragments to the broad-host-range vectors. Finally, the broad-host-range cosmid cloning vector pLAFR3 was improved by the addition of a double cos casette to generate the new plasmid, pLAFR5. This latter cosmid simplifies vector preparation and has permitted the rapid cloning of genomic DNA fragments generated with Sau3A. The resulting clones may be introduced into other Gram-negative bacteria by conjugation.     

A mini binary vector series for plant transformation

A streamlined mini binary vector was constructed that is less than 1/2 the size of the pBIN19 backbone (3.5 kb). This was accomplished by eliminating over 5 kb of non-T-DNA sequences from the pBIN19 vector. The vector still retains all the essential elements required for a binary vector. These include a RK2 replication origin, the nptIII gene conferring kanamycin resistance in bacteria, both the right and left T-DNA borders, and a multiple cloning site (MCS) in between the T-DNA borders to facilitate cloning. Due to the reduced size, more unique restriction sites are available in the MCS, thus allowing more versatile cloning. Since the traF region was not included, it is not possible to mobilize this binary vector into Agrobacterium by triparental mating. This problem can be easily resolved by direct transformation. The mini binary vector has been demonstrated to successfully transform Arabidopsis plants. Based on this mini binary vector, a series of binary vectors were constructed for plant transformation.     

Broad-host-range properties of plasmid RK2: importance of overlapping genes encoding the plasmid replication initiation protein TrfA.

The trfA gene, encoding the essential replication initiation protein of the broad-host-range plasmid RK2, possesses an in-frame overlapping arrangement. This results in the production of TrfA proteins of 33 and 44 kDa, respectively. Utilizing deletion and site-specific mutagenesis to alter the trfA operon, we compared the replication of an RK2-origin plasmid in several distantly related gram-negative bacteria when supported by both TrfA-44 and TrfA-33, TrfA-33 alone, or TrfA-44/98L (a mutant form of the TrfA-44 protein) alone. TrfA-44/98L is identical to wild-type TrfA-44 with the exception of a single conservative amino acid alteration from methionine to leucine at codon 98; this alteration removes the translational start codon for the TrfA-33 protein. Copy number and stability were virtually identical for plasmids containing both TrfA-44 and TrfA-33 proteins or TrfA-44/98L alone in Pseudomonas aeruginosa and Agrobacterium tumefaciens, two unrelated bacteria in which TrfA-33 is poorly functional. This, along with recent in vitro studies comparing TrfA-44, TrfA-33, and TrfA-44/98L, suggests that the functional activity of TrfA-44 is not significantly affected by the 98L mutation. Analysis of minimal RK2 derivatives in certain gram-negative bacterial hosts suggests a role of the overlapping arrangement of trfA in facilitating the broad host range of RK2. RK2 derivatives encoding TrfA-44/98L alone demonstrated decreased copy number and stability in Escherichia coli and Azotobacter vinelandii when compared with derivatives specifying both TrfA-44 and TrfA-33. A strategy employing the trfA-44/98L mutant gene and in vivo homologous recombination was used to eliminate the internal translational start codon of trfA in the intact RK2 plasmid. The mutant intact RK2 plasmid produced only TrfA-44/98L. A small reduction in copy number and beta-lactamase expression resulted in E. coli, suggesting that overlapping trfA genes also enhance the efficiency of replication of the intact RK2 plasmid.     

ColD-derived cloning vectors that autoamplify in the stationary phase of bacterial growth

The construction of cloning vectors based on the replicon of plasmid ColD-CA23 is reported. These vectors, like ColD itself, autoamplify when cultures of host bacteria enter the stationary phase of growth, thereby resulting in a substantial increase in the expression of cloned genes as a consequence of the increase in gene dosage. The principal advantage of these vectors is that, unlike the situation pertaining to other expression vectors, the increase in expression of genes cloned in ColD vectors does not require any experimental intervention (i.e., occurs naturally), and takes place at high cell densities. The vectors show high stability in Escherichia coli strains and are compatible with ColE1-type cloning vectors.     

Simple cloning strategy using GFPuv gene as positive/negative indicator

Because construction of expression vectors is the first requisite in the functional analysis of genes, development of simple cloning systems is a major requirement during the postgenomic era. In the current study, we developed cloning vectors for gain- or loss-of-function studies by using the GFPuv gene as a positive/negative indicator of cloning. These vectors allow us to easily detect correct clones and obtain expression vectors from a simple procedure by means of the combined use of the GFPuv gene and a type IIS restriction enzyme.     

Constructs and methods for high-throughput gene silencing in plants

Gene silencing can be achieved by transformation of plants with constructs that express self-complementary (termed hairpin) RNA containing sequences homologous to the target genes. The DNA sequences encoding the self-complementary regions of hairpin (hp) RNA constructs form an inverted repeat. The inverted repeat can be stabilized in bacteria through separation of the self-complementary regions by a "spacer" region. When the spacer sequence encodes an intron, the efficiency of gene silencing is very high. There are at least three ways in which hpRNA constructs can be made. The construct may be generated from standard binary plant transformation vectors in which the hairpin-encoding region is generated de novo for each gene. Alternatively, generic gene-silencing vectors such as the pHANNIBAL and the pHELLSGATE series can be used. They simply require the insertion of PCR products, derived from the target gene, into the vectors by conventional cloning or by using the Gateway directed recombination system. In this article, we describe and evaluate the advantages of these vectors and then provide the protocols for their efficient use.     

Specific-purpose plasmid cloning vectors. II. Broad host range, high copy number, RSF1010-derived vectors, and a host-vector system for gene cloning in Pseudomonas

Host-vector systems have been developed for gene cloning in the metabolically versatile bacterial genus Pseudomonas. They comprise restriction-negative host strains of Pseudomonas aeruginosa and P. putida and new cloning vectors derived from the high-copy-number, broad-host-range plasmid RSF1010, which are stably maintained in a wide range of Gram-negative bacteria. These plasmids contain EcoRI, SstI, HindIII, XmaI, XhoI, SalI, BamHI, and ClaI insertion sites. All cloning sites, except for BamHI and ClaI, are located within antibiotic-resistance genes' insertional inactivation of these genes during hybrid plasmid formation provides a readily scored phenotypic change for the rapid identification of bacterial clones carrying such hybrids. One of the new vector plasmids is a cosmid that may be used for the selective cloning of large DNA fragments by in vitro lambda packaging. An analogous series of vectors that are defective in their plasmid-mobilization function, and that exhibit a degree of biological containment comparable to that of current Escherichia coli vector plasmids, are also described.     

Mutagenesis and gene cloning in Schizosaccharomyces pombe using nonhomologous plasmid integration and rescue

Genes are commonly cloned in yeasts and bacteria by plasmid complementation, where the introduction of the gene of interest into a host strain carrying a recessive mutation in that gene suppresses the host's mutant phenotype. However, a lack of low copy cloning vectors in the fission yeast Schizosaccharomyces pombe can complicate this approach especially when overexpression of one gene may suppress a defect in another gene or when overexpression of the desired gene is detrimental, if not lethal, to the cell. We describe here a method of identifying mutations in S. pombe that allows for the rapid and direct cloning of the defective gene. This involves the nonhomologous integration of a marked plasmid into the yeast genome and its subsequent rescue into Escherichia coli, so that DNA at the site of insertion is incorporated into the recovered plasmid. As two of three insertions obtained in this study occurred outside of the affected gene's open reading frame, this method should be applicable to cloning both essential genes and nonessential genes.     

Genome organization of the plasmid of IncQ/P4 group and its vector derivatives

The genome organization and functioning of IncQ/P4 plasmids are reviewed. Based on these plasmids, cloning vectors have been constructed for broad host range of gram-negative bacteria. Together with one- and two-replicon vectors for cloning via insertion inactivation of markers, specialized plasmid vectors are described: cosmids, promoter-probe vectors, vectors for direct selection of recombinant molecules. Examples of using broad host range vectors for gene cloning and expression in non-enteric gram-negative bacteria are presented.     

Parallel gene cloning and protein production in multiple expression systems

To quickly find an optimal expression system for recombinant protein production, a set of vectors with the same restriction sites were constructed for parallel cloning of a target gene and recombinant protein production in prokaryotic and eukaryotic expression systems, simultaneously. These vectors include nucleotide sequences encoding protein tags and protease recognition sites for tag removal, followed by the cloning sites 5′‐EcoRI/3′‐XhoI identical in these vectors for ligating with the sticky‐end PCR product of a target gene. Our vectors allow parallel gene cloning and protein production in multiple expression systems with minimal cloning effort. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Construction and characterization of Streptococcus suis-Escherichia coli shuttle cloning vectors

pSSU1, a native plasmid of Streptococcus suis DAT1, was used to construct pSET-series shuttle vectors. In addition to the replication function of pSSU1, these vectors contain the multiple cloning sites and lacZ' gene from pUC19, which means that X-gal screening can be used to select recombinants in Escherichia coli. pSET1, pSET2, and pSET3 carry cat, spc, and both of these genes, respectively, as selectable markers. These vectors could be introduced into S. suis, E. coli, Salmonella typhimurium, S. pneumoniae, and S. equi ssp. equi by electrotransformation. The recA gene was cloned from S. suis and sequenced, and this information was used in the construction of a recA mutant of S. suis. Transformation frequencies and/or plasmid stability of all pSET vectors tested were decreased in both S. suis and E. coli recA mutants compared with the parental strains. These results suggested that functional RecA protein improved the maintenance of pSET vectors in both S. suis and E. coli. Moreover, cloning of the functional S. suis recA gene into pSET2 and complementation analysis of the recA mutant were successful in S. suis but not in E. coli. These results showed that pSET vectors are useful tools for cloning and analyzing S. suis genes in S. suis strains directly.