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.     

Construction and Properties of Cloning Vectors Based on a 7.2-kb Rhizobium meliloti Cryptic Plasmid

Cloning vectors (pFD1001, pFD1192, pFD1194, and pFD1212) were constructed by extension of the host range of a 7.2-kb Rhizobium meliloti cryptic plasmid (pRm1132f) with the ColE1-based plasmids, pBR322, pACYC177, pACYC 184, pSUP301, or pHC179; mobilization was facilitated by introduction of the ori T region from pRK2, a broad-host-range plasmid. The vector plasmids transferred readily into a wide range of gram-negative bacteria and had relatively low copy number in R. meliloti; two constructs, pFD1001 and pFD1212, were completely stable in R. meliloti isolated from nodules of alfalfa (Medicago sativa). A representative of the vector constructs (pFD1001) could be maintained in R. meliloti in the presence of the broad-host-range shuttle plasmid pRK290. These two vector plasmids could be introduced into R. meliloti, either simultaneously or singly when pRK290 was the resident plasmid; however, entry of pRK290 was blocked when pFD1001 was the resident plasmid. The cloning vectors constructed in this study should prove to be useful for the genetic manipulation of Rhizobium.     

Gene targeting in gram-negative bacteria by use of a mobile group II intron ("Targetron") expressed from a broad-host-range vector

Mobile group II introns ("targetrons") can be programmed for insertion into virtually any desired DNA target with high frequency and specificity. Here, we show that targetrons expressed via an m-toluic acid-inducible promoter from a broad-host-range vector containing an RK2 minireplicon can be used for efficient gene targeting in a variety of gram-negative bacteria, including Escherichia coli, Pseudomonas aeruginosa, and Agrobacterium tumefaciens. Targetrons expressed from donor plasmids introduced by electroporation or conjugation yielded targeted disruptions at frequencies of 1 to 58% of screened colonies in the E. coli lacZ, P. aeruginosa pqsA and pqsH, and A. tumefaciens aopB and chvI genes. The development of this broad-host-range system for targetron expression should facilitate gene targeting in many bacteria.     

Mapping and cloning of the par-region of broad-host-range plasmid RP4

Various deletion mutants of the identical broad-host-range plasmids RP4 and RK2, obtained after conjugative transfer of these plasmids from Escherichia coli to Alcaligenes eutrophus H16, were tested with respect to their segregation behaviour. Although the parent plasmids and some of the deletion mutants were completely stable in both A. eutrophus and E. coli, other derivatives were lost under non-selective conditions. The analysis of these deletion mutants allowed the identification and mapping of a region encoding a partitioning system (par) between the tra2 region and the kanamycin resistance gene of RP4 (RK2). This area corresponds to the PstI-C restriction fragment of RP4 (RK2). Cloning of this fragment into several unstable vector plasmids including pBR322 and pACYC177 resulted in all cases in an increase of segregational stability. By insertion of the par-region into an unstable broad-host-range mobilizable plasmid and transfer to a series of gram-negative bacteria, it could be shown that the cloned par-region of RP4 is functional in a broad-host-range.     

Construction of broad-host-range cosmid cloning vectors: identification of genes necessary for growth of Methylobacterium organophilum on methanol.

Four new cloning vectors have been constructed from the broad-host-range cloning vector pRK290. These vectors, pLA2901, pLA2905, pLA2910, and pLA2917, confer resistance to kanamycin and tetracycline. The latter two are cosmid derivatives of pLA2901. The new vectors can be mobilized into, and are stably maintained in, a variety of gram-negative bacteria. A Sau3A genomic bank of Methylobacterium organophilum strain xx DNA has been constructed in pLA2917, and complementation analysis, with a variety of mutants unable to grow on methanol, revealed at least five separate regions necessary for growth on methanol. Complementation analysis and Tn5 mutagenesis data suggest that at least three genes are responsible for expression of active methanol dehydrogenase.     

Comparative biology of IncQ and IncQ-like plasmids.

Plasmids belonging to Escherichia coli incompatibility group Q are relatively small (approximately 5 to 15 kb) and able to replicate in a remarkably broad range of bacterial hosts. These include gram-positive bacteria such as Brevibacterium and Mycobacterium and gram-negative bacteria such as Agrobacterium, Desulfovibrio, and cyanobacteria. These plasmids are mobilized by several self-transmissible plasmids into an even more diverse range of organisms including yeasts, plants, and animal cells. IncQ plasmids are thus highly promiscuous. Recently, several IncQ-like plasmids have been isolated from bacteria found in environments as diverse as piggery manure and highly acidic commercial mineral biooxidation plants. These IncQ-like plasmids belong to different incompatibility groups but have similar broad-host-range replicons and mobilization properties to the IncQ plasmids. This review covers the ecology, classification, and evolution of IncQ and IncQ-like plasmids.     

Vector for regulated expression of cloned genes in a wide range of gram-negative bacteria.

A pKT231-based broad-host-range plasmid vector was constructed which enabled regulation of expression of cloned genes in a wide range of gram-negative bacteria. This vector, pNM185, contained upstream of its EcoRI, SstI, and SstII cloning sites the positively activated pm twin promoters of the TOL plasmid and xylS, the gene of the positive regulator of these promoters. Expression of cloned genes was induced with micromolar quantities of benzoate or m-toluate, the inexpensive coinducers of the pm promoters. Expression of a test gene, xylE, which specifies catechol 2,3-dioxygenase, cloned in this vector was tested in representative strains of a variety of gram-negative bacteria. Regulated expression of xylE was observed in most strains examined, and induced levels of enzyme representing up to 5% of total cellular protein and ratios of induced:noninduced levels of enzyme up to a factor of 600 were observed. The level of xylE gene expression in different bacteria tended to be correlated with their phylogenetic distance from Pseudomonas putida.     

Identification of putative methanol dehydrogenase (moxF) structural genes in methylotrophs and cloning of moxF genes from Methylococcus capsulatus bath and Methylomonas albus BG8.

An open-reading-frame fragment of a Methylobacterium sp. strain AM1 gene (moxF) encoding a portion of the methanol dehydrogenase structural protein has been used as a hybridization probe to detect similar sequences in a variety of methylotrophic bacteria. This hybridization was used to isolate clones containing putative moxF genes from two obligate methanotrophic bacteria, Methylococcus capsulatus Bath and Methylomonas albus BG8. The identity of these genes was confirmed in two ways. A T7 expression vector was used to produce methanol dehydrogenase protein in Escherichia coli from the cloned genes, and in each case the protein was identified by immunoblotting with antiserum against the Methylomonas albus methanol dehydrogenase. In addition, a moxF mutant of Methylobacterium strain AM1 was complemented to a methanol-positive phenotype that partially restored methanol dehydrogenase activity, using broad-host-range plasmids containing the moxF genes from each methanotroph. The partial complementation of a moxF mutant in a facultative serine pathway methanol utilizer by moxF genes from type I and type X obligate methane utilizers suggests broad functional conservation of the methanol oxidation system among gram-negative methylotrophs.     

Extension of the host range of Escherichia coli vectors by incorporation of RSF1010 replication and mobilization functions.

The broad-host-range vectors pSUP104, pSUP106, pSUP204, pSUP304, and pSUP404 are based on conventional Escherichia coli vectors (such as pBR325 and pACYC184) which have been modified to include the mobilization and broad-host-range replication functions of the IncQ plasmid RSF1010. These vector plasmids now can be maintained in a wide range of bacterial genera including Rhizobium, Agrobacterium, and Pseudomonas. They are efficiently mobilized by RP4 and thus are of particular interest for bacteria refractory to transformation. They offer the selection markers and cloning sites characteristic of the basic E. coli vectors. Therefore, they can be applied and adapted to a variety of cloning strategies. However, the cloning of very large fragments (e.g., in cosmid hybrids of pSUP106) was found to affect the stability of the recombinant molecules in a Rec+ background. This instability was not observed with smaller inserts of about 5 kilobases.     

Cloning and localization of the replication and mobilization regions in the D-plasmid of Pseudomonas putida pBS286 (IncP-9) with a broad host range

Rep-mob loci of naphthalene degradative plasmid pBS286 (IncP-9) have been cloned on the Escherichia coli vectors pUC19 and pUBR322. These loci confer to recombinant plasmids pBS952 and pBS953 the ability for effective mobilization by RP4 (IncP-1) and F plasmid, as well as constant maintenance in various gram-negative bacteria. Localization of cloned sequences in the restriction fragments of conservative part of the pBS286 genome was established. The data obtained correlate with the analysis of plasmids pBS950 and pBS951 which are spontaneous mini-derivatives of pBS286 and pBS292 (delta NPL1::Tn1/Tra+ Nah-) plasmids formed during transformation of E. coli HB101 cells. Plasmids pBS952 and pBS953 retain the incompatibility properties of parental IncP-9 replicon. These recombinant derivatives can be used for construction of bhr vectors with required properties and compatible with bhr vectors constructed on the basis of plasmids from the IncP-1 and IncP-4 groups.     

Gene Targeting in Gram-Negative Bacteria by Use of a Mobile Group II Intron (“Targetron”) Expressed from a Broad-Host-Range Vector

Mobile group II introns (“targetrons”) can be programmed for insertion into virtually any desired DNA target with high frequency and specificity. Here, we show that targetrons expressed via an m-toluic acid-inducible promoter from a broad-host-range vector containing an RK2 minireplicon can be used for efficient gene targeting in a variety of gram-negative bacteria, including Escherichia coli, Pseudomonas aeruginosa, and Agrobacterium tumefaciens. Targetrons expressed from donor plasmids introduced by electroporation or conjugation yielded targeted disruptions at frequencies of 1 to 58% of screened colonies in the E. coli lacZ, P. aeruginosa pqsA and pqsH, and A. tumefaciens aopB and chvI genes. The development of this broad-host-range system for targetron expression should facilitate gene targeting in many bacteria.     

Construction of broad-host-range plasmid vectors for easy visible selection and analysis of promoters.

We have constructed a series of broad-host-range plasmids which use "visual screens" to detect promoter activity. These plasmids contain the pMB1 and pRO1600 origins of replication and are capable of replicating in a wide range of gram-negative bacteria. The genes encoding beta-galactosidase and alkaline phosphatase from Escherichia coli and bacterial luciferase from Vibrio harveyi supply the promoterless indicator genes. The constructs were tested in E. coli and Pseudomonas aeruginosa.     

A broad-host-range plasmid for isolating mobile genetic elements in gram-negative bacteria

Plasmid pGBG1 was constructed to isolate mobile genetic elements in a wide variety of gram-negative bacteria. The mutation target, carried on a broad-host-range vector, allows positive selection for tetracycline resistance. In tests using several gram-negative bacteria we could detect transposition events of either insertion sequences or transposons. A new insertion sequence (IS) element was identified in Ralstonia eutropha.     

A broad-host-range cloning vector transposable to various replicons

A system is described for the stable insertion of cloned DNA sequences into the chromosomes of Gram-negative bacteria. Two broad-host-range plasmids form the basis of the system: one (the "carrier") contains a transposable DNA sequence into which foreign DNA can be cloned; the second (the "helper") provides transposition functions in trans. Both plasmids can be readily transferred between Gram-negative bacteria by conjugation. Instability of the carrier allows enrichment for the products of transposition to the chromosome of the new host, following which the insertion can be stabilised by elimination of the helper. The system was successfully tested in Escherichia coli, Methylophilus methylotrophus and Pseudomonas aeruginosa, and the insertions were stable in each case (less than 0.02% loss per generation).     

Characterization, cloning, curing, and distribution in lactic acid bacteria of pLP1, a plasmid from Lactobacillus plantarum CCM 1904 and its use in shuttle vector construction

A small 2.1-kb plasmid called pLP1 was extracted from Lactobacillus plantarum CCM 1904 (ATCC 8014) and cloned into the Escherichia coli pUC19 plasmid. As determined by DNA-DNA Southern hybridization with a pLP1-radioactively labeled probe, other lactic acid bacteria such as L. curvatus, L. sake, Carnobacterium, and Leuconostoc mesenteroides harbor pLP1-related plasmids. Shuttle vectors based on the pLP1 replicon were constructed by inserting the erythromycin-resistance gene from pVA891 into the various pUC19-pLP1 constructions. pLP1-based shuttle vector transformation efficiencies (TE) by electroporation were compared to TE of a broad-host-range plasmid pGK12 in different lactobacilli strains. Expression of the pUC19-pLP1 plasmids in Escherichia coli maxicells showed that pLP1 encodes for a 37,000 MW protein which can act in trans allowing the replication of plasmids in which this protein is truncated. The pLP1-based shuttle vectors producing this protein replicate in lactobacilli and also in Bacillus subtilis. A pLP1-free strain was obtained by incompatibility with a pLP1-based shuttle vector introduced in L. plantarum CCM 1904 by electroporation. The absence of pLP1 has no incidence on the strain phenotype suggesting that pLP1 is not essential for the strain in our laboratory conditions.     

Differential regulation of lambda pL and pR promoters by a cI repressor in a broad-host-range thermoregulated plasmid marker system.

Plasmid systems with unique markers were constructed to assess the fate of recombinant DNA and genetically manipulated bacteria in soil and freshwater model environments. On such constructs the marker gene, xylE (for catechol 2,3-dioxygenase), is expressed from the lambda promoter pL or pR, each of which is controlled by the temperature-sensitive lambda repressor c1857. Combinations of these elements were cloned into the broad-host-range plasmid pKT230 to form pLV1010 (pL-xylE), pLV1011 (pL-xylE-c1857), and pLV1013 (pR-xylE-c1857). The recombinant plasmids were introduced into different gram-negative bacteria. The thermoregulated system of pLV1013 functioned well in a range of species, with xylE induction being readily achieved by elevation of the temperature from 28 to 37 degrees C. There was a difference in the induction of catechol 2,3-dioxygenase activity, depending on whether xylE was expressed from pL (pLV1011) or pR (pLV1013). Our observations on testing the different systems in a number of hosts suggest that genes carried by the DNA of genetically engineered microorganisms may not be expressed in a predictable manner following transfer from the release host to other species.     

Differential regulation of lambda pL and pR promoters by a cI repressor in a broad-host-range thermoregulated plasmid marker system

Plasmid systems with unique markers were constructed to assess the fate of recombinant DNA and genetically manipulated bacteria in soil and freshwater model environments. On such constructs the marker gene, xylE (for catechol 2,3-dioxygenase), is expressed from the lambda promoter pL or pR, each of which is controlled by the temperature-sensitive lambda repressor c1857. Combinations of these elements were cloned into the broad-host-range plasmid pKT230 to form pLV1010 (pL-xylE), pLV1011 (pL-xylE-c1857), and pLV1013 (pR-xylE-c1857). The recombinant plasmids were introduced into different gram-negative bacteria. The thermoregulated system of pLV1013 functioned well in a range of species, with xylE induction being readily achieved by elevation of the temperature from 28 to 37 degrees C. There was a difference in the induction of catechol 2,3-dioxygenase activity, depending on whether xylE was expressed from pL (pLV1011) or pR (pLV1013). Our observations on testing the different systems in a number of hosts suggest that genes carried by the DNA of genetically engineered microorganisms may not be expressed in a predictable manner following transfer from the release host to other species.     

Development of techniques for the genetic manipulation of the gliding bacterium Cytophaga johnsonae.

Cytophaga johnsonae displays many features that make it an excellent model of bacterial gliding motility. Unfortunately, genetic analyses of C. johnsonae, or any related gliding bacteria, were not possible because of a complete lack of selectable markers, cloning vectors, transposons, and convenient methods of gene transfer. As a first step toward a molecular analysis of gliding motility of C. johnsonae, we developed these genetic techniques and tools. Common broad-host-range plasmids and transposons did not function in C. johnsonae. We identified one Bacteroides transposon, Tn4351, that could be introduced into C. johnsonae on plasmid R751 by conjugation from Escherichia coli. Tn4351 inserted in the C. johnsonae genome and conferred erythromycin resistance. Tn-4351 insertions resulted in auxotrophic mutations and motility mutations. We constructed novel plasmids and cosmids for genetic analyses of C. johnsonae. These cloning vectors are derived from a small cryptic plasmid (pCP1) that we identified in the fish pathogen Cytophaga psychrophila D12. These plasmids contain the ermF (erythromycin resistance) gene from Tn4351 and a variety of features that facilitate propagation and selection in E. coli and conjugative transfer from E. coli to C. johnsonae.     

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.