Shuttle plasmids for Escherichia coli and Clostridium perfringens.

Small plasmids which replicate in both Escherichia coli and Clostridium perfringens were made by recombining E. coli plasmid pBR322 with three different small (less than 4 kilobases) plasmids native to C. perfringens. Subsequently, two homologous, though distinct, tetracycline resistance determinants (tet) from other C. perfringens plasmids were cloned into them. Both tet systems made E. coli resistant to at least 5 micrograms of tetracycline per ml when resident on the shuttle plasmids. The shuttle vectors have been used to transform L-phase variants and autoplasts of C. perfringens. In the latter case, the intact transforming plasmid could be isolated from walled cells after cell wall regeneration. Reciprocal transformation experiments in which plasmid DNAs derived from E. coli or C. perfringens were used suggest that restriction barriers exist between these two organisms. The plasmids contain restriction enzyme recognition sites in locations which are useful for cloning experiments.     

Development and use of cloning systems for Bacteroides fragilis: cloning of a plasmid-encoded clindamycin resistance determinant.

Chimeric plasmids able to replicate in Bacteroides fragilis or in B. fragilis and Escherichia coli were constructed and used as molecular cloning vectors. The 2.7-kilobase pair (kb) cryptic Bacteroides plasmid pBI143 and the E. coli cloning vector pUC19 were the two replicons used for these constructions. Selection of the plasmid vectors in B. fragilis was made possible by ligation to a restriction fragment bearing the clindamycin resistance (Ccr) determinant from a Bacteroides R plasmid, pBF4;Ccr was not expressed in E. coli. The chimeric plasmids ranged from 5.3 to 7.3 kb in size and contained at least 10 unique restriction enzyme recognition sites suitable for cloning. Transformation of B. fragilis with the chimeric plasmids was dependent upon the source of the DNA; generally 10(5) transformants micrograms-1 of DNA were recovered when plasmid purified from B. fragilis was used. When the source of DNA was E. coli, there was a 1,000-fold decrease in the number of transformants obtained. Two of the shuttle plasmids not containing the pBF4 Ccr determinant were used in an analysis of the transposon-like structure encoding Ccr in the R plasmid pBI136. This gene encoding Ccr was located on a 0.85-kb EcoRI-HaeII fragment and cloned nonselectively in E. coli. Recombinants containing the gene inserted in both orientations at the unique ClaI site within the pBI143 portion of the shuttle plasmids could transform B. fragilis to clindamycin resistance. These results together with previous structural data show that the gene encoding Ccr lies directly adjacent to one of the repeated sequences of the pBI136 transposon-like structure.     

Shuttle cloning vectors for the cyanobacterium Anacystis nidulans.

Hybrid plasmids capable of acting as shuttle cloning vectors in Escherichia coli and the cyanobacterium Anacystis nidulans R2 were constructed by in vitro ligation. DNA from the small endogenous plasmid of A. nidulans was combined with two E. coli vectors, pBR325 and pDPL13, to create vectors containing either two selectable antibiotic resistance markers or a single marker linked to a flexible multisite polylinker. Nonessential DNA was deleted from the polylinker containing plasmid pPLAN B2 to produce a small shuttle vector carrying part of the polylinker (pCB4). The two polylinker-containing shuttle vectors, pPLAN B2 and pCB4, transform both E. coli and A. nidulans efficiently and provide seven and five unique restriction enzyme sites, respectively, for the insertion of a variety of DNA fragments. The hybrid plasmid derived from pBR325 (pECAN1) also transforms both E. coli and A. nidulans, although at a lower frequency, and contains two unique restriction enzyme sites.     

Novel streptococcal-integration shuttle vectors for gene cloning and inactivation.

Seven new streptococcal integration shuttle vectors have been constructed which contain different antibiotic-resistance-encoding genes capable of expression in both Streptococcus sp. and Escherichia coli. These plasmids can replicate in E. coli, but not in streptococci because of the absence of a streptococcal origin of replication. The size, antibiotic resistance, and number of unique restriction sites available for cloning for each plasmid are as follows: pSF141 (7.6 kb, CmR and KmR, 7 sites), pSF143 (5.7 kb, TcR, 6 sites), pSF148 (7.3 kb, CmR and SpR, 7 sites), pDL285 (3.4 kb, KmR, 3 sites), pDL286 (3.1 kb, SpR, 4 sites), pSF151 (3.5 kb, KmR, 10 sites), pSF152 (3.2 kb, SpR, 9 sites). If these plasmids carry a fragment of streptococcal DNA they can specifically integrate into the chromosome via Campbell-like, homologous recombination. Therefore, they should be useful for gene inactivation, cloning, chromosomal walking, or linkage analysis in streptococci. The availability of these integration plasmids resistant to different antibiotics, along with the previously described plasmid, pVA891 (ErR), should also allow the construction of mutants possessing multiple insertionally inactivated genes useful for a variety of genetic studies.     

Construction of a chimeric shuttle plasmid via a heterodimer system: secretion of an scFv protein from Bacillus brevis cells capable of inhibiting hemagglutination

Passive immunization is an attractive therapy for preventing oral diseases including dental caries and periodontal disease. For this purpose, we attempted to produce a single chain variable fragment, scFv, which inhibited hemagglutination using the Bacillus brevis protein-producing system. To accomplish this, a novel strategy, a heterodimer system, was used for the construction of a chimeric shuttle plasmid. Initially, a set of new plasmids, kanamycin-resistant donor and erythromycin-resistant general cloning plasmids, were constructed. p15A ori was a common replication origin in these plasmids, while the pUB110 rep and minus origin (MO) were cloned into the donor plasmid. Next, the secretion domain of the B. subtilis alpha-amylase gene and the G2-4 gene, coding for the scFv protein, were cloned into the general cloning plasmid and fused by PCR. Both the donor plasmid and the general cloning plasmid containing the fused gene were digested with NotI and them ligated, a dimeric plasmid being constructed. The key restriction sites, AscI, are arranged such that the pUB110 rep-MO moiety was switched from the donor to the general cloning plasmid following AscI digestion. The chimeric shuttle plasmid was readily constructed by simple re-circularization and a B. brevis transformant producing the scFv protein in the culture fluid was isolated.     

Development of the vector-host system in Corynebacterium. Cloning and expression of homoserine dehydrogenase and homoserine kinase genes in Corynebacterium cells

Novel cloning vectors for glutamic acid producing bacteria have been constructed. The cryptic plasmid pBO1 (4.4 kb) from Brevibacterium sp. recombined with the plasmid pACYC184 (4.0 kb) from Escherichia coli was used to produce composite plasmid named pKA1. The plasmid could propagate and express the Cm-r phenotype in E. coli and coryneform glutamic acid producing bacteria Br. flavum, C. glutamicum, Br. lactofermentum. The pKA1 plasmid and its variants deleted within non-essential plasmid regions with unique restriction sites HindIII, SalGI, SphI were used in cloning experiments. The genes coding for threonine biosynthesis of C. glutamicum and Br. flavum were subcloned into shuttle vectors in C. glutamicum cells. Recombinant plasmids were introduced into protoplasts by polyethylenglycol-mediated transformation of plasmid DNAs. It was shown that the presence of plasmids containing the Br. flavum thrA2 gene in C. glutamicum (thrB) caused 10-fold increase in homoserine dehydrogenase activity, as compared to that of wild type strain, and in homoserine production.     

A host-vector system for gene cloning in the cyanobacterium Anacystis nidulans R2

We describe the construction of a series of vectors suitable for gene cloning in the Cyanobacterium Anacystis nidulans R2. From the indigenous plasmid pUH24, derivatives were constructed with streptomycin as the selective marker; one of these plasmids was used to construct pUC303, a shuttle vector capable of replication in A. nidulans R2 as well as in Escherichia coli K12. It has two markers, streptomycin and chloramphenicol resistance, and three unique restriction sites. Instability of recombinant plasmids was overcome by using a derivative of A. nidulans R2 cured of the indigenous plasmid pUH24. This strain, R2-SPc, can be transformed stably and at high frequency by the plasmids described in this paper. The combination of the cured strain R2-SPc and the new plasmid pUC303 serves as a suitable host-vector system for gene cloning in cyanobacteria.     

Useful modifications of the Escherichia coli expression plasmid pJL6

Several useful modifications of the Escherichia coli expression plasmid pJL6 have been constructed. These include the introduction of a wide variety of restriction sites by the cloning of oligonucleotide linker DNA or of a short DNA fragment containing many sites. These plasmids can allow the expression of genes adjacent to one of the restriction sites provided. Another plasmid, pJLA16, allows the cloning of blunt-ended DNA adjacent to the fragment of phage gene, thus allowing fusions of this gene fragment with target gene DNA. This facilitates the expression of genes on blunt-ended DNA fragments that are either directly the product of restriction enzyme digestion or fragments that are resected with Bal-31 nuclease.     

Rapid generation of nested deletions by differential restriction digestion

A method was devised for generating nested deletions in DNA that exploits the difference in frequency of restriction sites recognized by compatible restriction endonucleases. A cloning vector was constructed that contains no common blunt-end or RsaI restriction sites and two 8-bp blunt-end restriction sites flanking a commodious multiple cloning site. DNA fragments are cloned into the multiple cloning site using blue-white selection, and nested deletions are generated by digesting the resulting plasmid with either SwaI or PmeI and partially digesting the insert DNA with RsaI. The DNAs are ligated and transformed, producing afamily of plasmids with different-sized deletions. The DNA sequence of these inserts can be rapidly determined, and the overlapping sequences can be assembled in silico to produce a large DNA contig. Nested deletions generated in this manner can also be used for the structure-function analysis of proteins.     

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.     

New yeast/E. coli/Drosophila triple shuttle vectors for efficient generation of Drosophila P element transformation constructs

We have generated a set of novel triple shuttle vectors that facilitate the construction of Drosophila-P-element transformations vectors. These YED-vectors allow the insertion of any kind of sequence at any chosen position due to the presence of a yeast casette which ensures replication and allows for homologous recombination in Saccharomyces cerevisiae. As a proof of principle we generated several reporter constructs and tested them in transgenic flies for expression and correct subcellular localization. YED-vectors can be used for many purposes including promoter analysis or the expression of tagged or truncated proteins. Thus, time-consuming conventional restriction site based multi-step cloning procedures can be circumvented by using the new YED-vectors. The new set of triple shuttle vectors will be highly beneficial for the rapid construction of complex Drosophila transformation plasmids.     

Construction ofClostridium butyricum hybrid plasmids and transfer toBacillus subtilis

Summary Small plasmids were isolated from type strains ofClostridium butyricum. Strain NCIB 7423 carries one plasmid (pCBU1) of 6.4 kb, whereas strain NCTC 7423 carries two unrelated plasmids of 6.3 kb (pCBU2) and 8.4 kb (pCBU3). Cleavage sites for 18 restriction endonucleases have been mapped on these plasmids and detailed physical maps are presented. For the purpose of developing vector plasmids for gene cloning in saccharolytic clostridia these crypticC. butyricum plasmids were joined to a selectable marker that will likely be expressed in clostridia. This was achieved by cloning the clostridial plasmids into theE. coli vector pBR322 carrying the chloramphenicol acetyltransferase (CAT) gene from theStaphylococcus aureus plasmid pC194. The recombinant plasmids were tested for their ability to confer chloramphenicol resistance toBacillus subtilis. Hybrid plasmids (pHL105, pHL1051) derived from pCBU2 were identified, which are capable of replication and expression of theS. aureus drug resistance marker in bothE. coli andB. subtilis. No structural instability was detected upon retransformation of pHL105 fromB. subtilis intoE. coli. The recombinant plasmids might thus be useful as shuttle vectors for the gene transfer betweenE. coli and a wide range of bacilli and clostridia.     

Cryptic plasmids isolated from Campylobacter strains represent multiple, novel incompatibility groups

Three small, cryptic plasmids from the multi-drug-resistant (MDR) Campylobacter coli strain RM2228 and one small, cryptic plasmid from the MDR Campylobacter jejuni strain RM1170 were sequenced and characterized. pCC2228-1 has some similarity to Firmicutes RepL family plasmids that replicate via a rolling-circle mechanism. pCC2228-2 is a theta-replicating, iteron-containing plasmid (ICP) that is a member of the same incompatibility (Inc) group as previously described Campylobacter shuttle vectors. The other two ICPs, pCC2228-3 and pCJ1170, represent a second novel Inc group. Comparison of the four plasmids described in this study with other characterized plasmids from C. jejuni, C. coli, C. lari, and C. hyointestinalis suggests that cryptic plasmids in Campylobacter may be classified into as many as nine Inc groups. The plasmids characterized in this study have several unique features suitable for the construction of novel Campylobacter shuttle vectors, e.g., small size, absence of many common multiple-cloning site restriction sites, and Inc groups not represented by current Campylobacter shuttle plasmids. Thus, these plasmids may be used to construct a new generation of Campylobacter shuttle vectors that would permit transformation of environmental Campylobacter isolates with an existing repertoire of native plasmids.     

New shuttle vectors for Bacillus subtilis and Escherichia coli which allow rapid detection of inserted fragments

Two new shuttle vectors have been constructed by fusing the Escherichia coli plasmid pUC9 with the Staphylococcus aureus plasmids pU110 and pC194. The resulting hybrids replicate in both E. coli and Bacillus subtilis and contain seven restriction sites within a part of the lacZ gene. Insertion of foreign DNA into those sites can be easily detected in E. coli and hybrid plasmids can subsequently be transformed into B. subtilis.     

STRU-Cloning: A Fast,Inexpensive and Efficient Cloning Procedure Applicable to Both Small Scale and Structural Genomics Size Cloning

We have developed a Single-Tube Restriction-based Ultrafiltration (STRU) cloning procedure that updates traditional ligation-dependent cloning to challenge the newer, faster and more efficient ligation-free techniques and could make it the method of choice. STRU-cloning employs centrifugal filter units with membrane of suitable cut off to remove small unwanted DNA fragments created during restriction of plasmids or PCR products. Heat inactivation, of restriction enzymes, followed by DNA ligation is then performed on the filtrate. By removing the agarose gel electrophoresis DNA purification step from the traditional protocol, which is time consuming and is known to be the cause of ligation problems, STRU-cloning becomes fast, very efficient, inexpensive and offers the highest degree of cloning flexibility by using restriction sites and can be performed in a single tube. This novel agarose gel-free cloning procedure provides benefits for both small and large scale cloning projects. Unlike traditional cloning it can be easily implemented as a fully automated process at very low costs.     

Analysis of the dibenzothiophene metabolic pathway in a newly isolated Rhodococcus spp.

We previously described the construction and characterization of Escherichia coli–Francisella tularensis shuttle vectors, derived from the cryptic Francisella plasmid pFNL10, for the genetic manipulation of F. tularensis ssp. tularensis . We now report further characterization of the biology of these shuttle vectors and the development of a new generation of Francisella plasmids. We show that the addition of ORF3 from pFNL10 can convert an unstable shuttle vector into a stable one, and that this is likely due to increased plasmid copy number. We also describe various improvements to the earlier generations of shuttle vectors, such as the addition of a multiple cloning site containing a novel RsrII restriction endonuclease site for directional insertion of Francisella genes, and the inclusion of the F. tularensis blaB promoter for heterologous gene expression.     

Construction and characterization of a new shuttle vector, pLES2, capable of functioning in Escherichia coli and Neisseria gonorrhoeae

In vitro recombination techniques were used to construct a bifunctional shuttle vector capable of functioning in Neisseria gonorrhoeae and Escherichia coli. This 6-kb plasmid contains a selectable phenotype, beta-lactamase production, which functions in both organisms. It also contains the lac region from pUC9 that allows for the direct selection of hybrid plasmids in the appropriate E. coli hosts by disruption of beta-galactosidase alpha complementation. The lac region contains several unique restriction sites useful for cloning: EcoRI, SmaI, BamHI and SalI.     

Cloning vectors, derived from a naturally occurring plasmid of Pseudomonas savastanoi, specifically tailored for genetic manipulations in Pseudomonas

A minimal replicon of 1.8 kb isolated from a 10-kb plasmid of Pseudomonas savastanoi, pPS10, has been used to obtain a collection of small vectors specific for Pseudomonas (P. savastanoi, P. aeruginosa and P.putida). In addition, shuttle vectors that can be established both in Pseudomonas and Escherichia coli have been constructed by adding a pMB9 replicon. The vectors permit cloning of DNA fragments generated by a variety of restriction enzymes using different antibiotic resistance markers for selection and offer the possibility to screen recombinants by insertional inactivation. This cloning system can be used to establish recombinant plasmids in Pseudomonas either at low or high copy number. pPS10 derivatives are compatible with other Pseudomonas vectors derived from broad-host-range replicons of the incompatibility groups P1, P4/Q and W. Introduction and expression of the iaaMH operon in a P. savastanoi mutant deficient in the production of indoleacetic acid has been achieved using one of these vectors.     

The pIC plasmid and phage vectors with versatile cloning sites for recombinant selection by insertional inactivation

The versatility of insertional inactivation of β-galactosidase activity for subcloning and sequencing has been enhanced by combining a chemically synthesized oligonucleotide which specifies nine 6-bp-cutter restriction sites including BglII, XhoI, NruI, ClaI, SacI and EcoRV in various configurations with existing polylinkers to create a set of highly versatile cloning sites. These improved polylinkers have been inserted into plasmids (the pICs) for routine cloning of double-stranded DNA, and into chimeric phage/plasmids (the pICEMs) for biological production of single stranded DNA. The most versatile Polylinker specifies 17 restriction sites in the β-galactosidase α-complementing gene fragment. One of the new polylinkers was inserted into M 13 DNA to produce a vector (M13mIC7) with nine cloning sites.