A site-specific recE4-independent intramolecular recombination between Bacillus subtilis and Staphylococcus aureus DNAs in hybrid plasmids

A composite plasmid pLS253 was constructed from pLS103 [carrying the Bacillus subtilis leucine genes on B. subtilis (natto) plasmid pLS28] and pHV14 [a recombinant plasmid composed of pBR322 and the staphylococcal R-plasmid pC194] employing BamHI endonuclease, T4 DNA ligase, and B. subtilis transformation. All the Leu+ Cmr transformants tested harbored not only pLS253 but also two smaller plasmids designated as pLS251 and pLS252. pLS253 DNA, when purified on an agarose gel, retained both Leu+ and Cmr transforming activities; however, in all the Leu+ Cmr transformants, the two smaller plasmids reappeared. pLS251 and pLS252 exhibited Leu+- or Cm4-transforming activity, respectively, and must have been derived from the pLS253 parent by an intramolecular recombination event, since the sum of the pLS251 and pLS252 DNAs represent the entire pLS253 genome. The recombination occurred between specific sites on the B. subtilis (natto) and Staphylococcus aureus plasmids. When the composite plasmid, pLS254, was constructed by BamHI cleavage of pLS251 and pLS252 followed by ligation, Leu+ Cmr transformants segregated two smaller plasmids which were indistinguishable from the original plasmids pLS103 and pHV14, respectively. They must have been derived from pLS254 through a reversal of the original recombination event. No intermolecular recombination between pLS251 and pLS252 DNA was detected. The recombination process was independent of recE function of the host cells, and its mechanism is discussed.     

Construction of plasmid vectors for gene cloning in Escherichia coli and Bacillus subtilis

The construction and some properties of new hybrid plasmids which are able to replicate in both Escherichia coli and Bacillus subtilis are presented. A 5.5 Md hybrid plasmid pJP9 was constructed from pBR322 (Tc, Ap) and pUB110 (Nm) plasmids. pIM1 (7.0 Md) and pIM3 (7.7 Md) plasmids are its different erythromycin resistant derivatives. Tetracycline, ampicillin, neomycin and possibly erythromycin resistance genes are expressed in E. coli while neomycin and erythromycin resistance genes are expressed in B. subtilis. Insertional inactivation of only one gene is possible using the pJP9 plasmid as a vector in B. subtilis. However, insertional inactivation of at least two different genes can be achieved and monitored in E. coli and B. subtilis transformants in cloning experiments with PIM1 and pIM3 plasmids. Insertional inactivation of antibiotic resistance genes present in pJP9 plasmid was achieved by cloning of Streptococcus sanguis DNA fragments generated by appropriate restriction endonucleases. The pJP9 plasmid and its derivatives were found to be stable in both hosts cells.     

Construction of a recombinant plasmid composed of B. subtilis leucine genes and a B. subtilis (natto) plasmid: its use as cloning vehicle in B. subtilis 168.

Summary Recombinant plasmids composed of Bacillus subtilis 168 leucine genes and a B. subtilis (natto) plasmid have been constructed in a recombination deficient (recE4) mutant of Bacillus subtilis 168. The process involved EcoRI fragmentation and ligation of a B. subtilis (natto) plasmid and a composite plasmid RSF2124-B · leu in which B. subtilis 168 leucine genes are linked to the R-factor RSF2124. A constructed plasmid (pLS102) was found to be composed of an EcoRI fragment derived from the vector plasmid and two tandemly repeated EcoRI fragments carrying the leucine genes. A derivative plasmid (pLS101 or pLS103) consisting of one molecule each of the EcoRI fragments was obtained by in vivo intramolecular recombination between the repeated leucine gene fragments in pLS102. pLS103 was cleaved once with BamNI, SmaI and HpaI. Insertion of foreign DNA (Escherichia coli plasmid pBR322) into the BamNI site inactivated leuA but not the leuC function which thus can serve as selective marker if the plasmid is used as vector in molecular cloning. The penicillin resistance carried in pBR322 was not functionally expressed in B. subtilis cells. By partial digestion of pLS103 with HindIII followed by ligation with T4-induced ligase, pLS107 was obtained which contained only one EcoRI site. However, insertion of exogenous DNA (pBR322) into this EcoRI site inactivated both leuA and leuC functions.     

Experimental basis for a stable plasmid, pLS30, to shuttle between Bacillus subtilis species by conjugational transfer

The use of Bacillus subtilis 168 as the initial host for molecular cloning and subsequent delivery of the engineered DNA to other Bacillus hosts appears attractive, and would lead to an efficient DNA manipulation system. However, methods of delivery to other Bacillus species are limited due to their inability to develop natural competence. An alternative, unexplored conjugational transfer method drew our attention and a B. subtilis native plasmid, pLS30, isolated from B. subtilis (natto) strain IAM1168 was characterized for this aim. The nucleotide sequence (6,610 bp) contained the mob gene and its recognition sequence, oriT, that features pLS30 as a mobile plasmid between Bacillus species on conjugational transfer. Plasmid pLS3001, a chimera with a pBR322-based plasmid prepared in Escherichia coli to confer an antibiotic resistance marker, showed apparent mobilizing activity in the pLS20-mediated conjugational transfer system recently established. The rep gene and associated palT1-like sequence common to all other pLS plasmids previously sequenced indicated that pLS30 is a typical rolling circle replicating (RCR) type plasmid. Due to the significant stability of pLS30 in IAM1168, application of a mobile plasmid would allow quick propagation to Bacillus species.     

Bacillus licheniformis as an object for the propagaton of heterologous genetic material from bacilli

Bacillus licheniformis was transformed with plasmids pUB110 and pJJ10 (pUB110 - pBR322) isolated from Bac. subtilis and Escherichia coli, respectively. It was revealed that the structure and genetic properties of the plasmids did not change during the transformation process. pJJ101 (pJJ10-rib) DNA isolated from E. coli and containing helper pJJ10 plasmid was used, as a recipient. It was shown that pJJ101 rib markers were "rescued" by the resident plasmid during transformation of Bac. licheniformis (pJJ10). Plasmid pLP1 containing ribB, ribD, Kmr genes and the pUB110 replicator, was isolated from the transformants. pLP1 plasmid might be considered as a detected derivative of the parental pJJ101 plasmid. The deletion is presented by 3,9 MD segment that contains the pBR322 replicator. pLP1 DNA is capable of transforming plasmidless strains of Bac. licheniformis and Bac. subtilis.     

Recombination-dependent recircularization of linearized pBR322 plasmid DNA following transformation of Escherichia coli

Summary Monomeric pBR322 DNA that had been linearized at its unique SalI site transformed wild-type Escherichia coli with 10² to 10³ times less efficiency than CCC plasmid DNA. Dose-response experiments indicated that a single linear plasmid molecule was sufficient to produce a transformant. Transformation with linearized pBR322 DNA was reduced 10 to 40 fold in recA ^–, recBC ^– or recF ^– backgrounds. In contrast, transformation with CCC DNA was unaffected by the rec status of the host. Transformation with linear pBR322 DNA was increased 3-fold in a DNA ligase-overproducing (lop11) mutant and decreased to a similar degree by transient inactivation of ligase in a ligts7 mutant.A proportion (ranging from about 9% in the wild-type to 42% in a recBC, lop11 mutant) of the transformants obtained with SalI-linearized pBR322 monomeric DNA contained deleted plasmids. Deletion rates were generally higher in rec ^– strains. Dephosphorylation of the termini on linear DNA or the creation of blunt-ended pBR322 molecules (by end-filling the SalI 5 protrusions or by cleavage with PvuII) decreased the transformation frequencywhilst increasing the deletion rate.Linear pBR322 dimeric DNA gave transformation frequencies in recA ⁺ and recA ^– strains that were reduced only 3 to 7 fold respectively relative to frequencies obtained with dimeric CCC DNA. Furthermore, in contrast to transformation with linear monomeric DNA, deletions were not observed.We propose that the majority of transformants arise, not by simple intracellular reannealing and ligation of the two cohesive SelI-termini of a linear molecule, but by intramolecular recombination. Deleted plasmids could be generated therefore during recyclization caused by recombination between short directly repeated sequences within a pBR322 monomer. We suggest that perfectly recircularized monomeric pBR322 molecules, which are found in the majority of transformants, arise primarily by intramolecular recombinational resolution of head-to-tail linear pBR322 dimers. Such linear oligomeric forms are created during preparation of linearized plasmid DNA by annealing of the SalI cohesive termini and constitute a variable proportion of the total molecules present.     

Mechanism of intramolecular recyclization and deletion formation following transformation of Escherichia coli with linearized plasmid DNA.

The deletion end-points of a number of type I (less than monomeric) plasmid deletants obtained by transforming recA+ or recA- E. coli with linear pBR322 DNA were determined by DNA sequencing. In both monodirectional and bidirectional deletions the recyclization point was normally characterized by recombination between directly repeated sequences of between 4 and 10 bp present on each arm of the linearized pBR322 molecule. Frequently, short tracts of uninterrupted homology involved in recombinational recircularization were embedded in regions of relative non-homology. A model predicting the probability of matching sequences in either end of a linear plasmid molecule is presented. It is proposed that exonucleolytic processing of the exposed termini of linear plasmid molecules generates substrates for subsequent recombinational recyclization and deletion. The activity of host recombination and repair functions in recircularizing linear DNA molecules explains the generation of many of the aberrant recombinant DNA constructs obtained during gene cloning procedures.     

Interference of plasmid pCM194 with lysogeny of bacteriophage SP02 in Bacillus subtilis.

Three observations indicated that the 2-megadalton chloramphenicol resistance plasmid pCM194 interferes with SP02 lysogeny of Bacillus subtilis. SP02 plaques formed on B. subtilis(pCM194) appeared almost clear, whereas plaques produced on plasmid-free or pUB110-containing cells contained large turbid centers. The number of phages spontaneously liberated by B. subtilis(SP02) was increased 10-fold or more when pCM194 was also present in the lysogens. Lastly, growth of B. subtilis(SP02, pCM194) for approximately 20 to 25 generations resulted in essentially complete loss of the prophage. This interference was not observed with pUB110 or pE194, and the pCM194 interference was not directed against B. subtilis temperate phage phi 105, which is unrelated to SP02. Lytic replication of SP02 appeared to be unaffected by pCM194. pCM194 interference with SP02 lysogeny was demonstrable in recombination-proficient strains and a recE mutant of B. subtilis. SP02 prophage which were noninducible due to the phage ind mutation were resistant to pCM194 interference. pCM194 interference was lost when the entire pCM194 molecule was joined at its unique HpaII site or at one of the two MboI sites to pUB110 or pUB110 derivatives. pBR322 joined to pCM194 at the same MboI site or at the HindIII site produced chimeras that retained the ability to interfere with SP02 lysogeny. A three-part plasmid constructed by joining pBR322 to pCM194 (at HindIII sites) and to pE194 (at PstI sites) was compatible with the SP02 prophage and showed a temperature-sensitive replication phenotype characteristic of the pE194 replicon. One explanation for the interference involves competition for a host component between an SP02 genome attempting to establish lysogeny and plasmids whose replication is directed by the pCM194 replicon.     

Characteristics of expression of the tetracycline resistance gene from the plasmid pBR322 in Bacillus subtilis cells

The expression of Tc resistance gene derived from plasmid pBR322 has been studied in Bacillus subtilis cells where this alien gene is not usually expressed. Fragments of Bacillus subtilis chromosome were inserted into the Tc resistance gene promoter region of the hybrid plasmid pGG20 and the expression of this gene was registered. Plasmid pGG20 confers a constitutive mode of Tc resistance in Escherichia coli cells. In contrast, the inducibility of Tc resistance gene expression in Bacillus subtilis cells has been reported. Optimal concentration for the highest inducibility of Tc resistance by the antibiotic has been determined.     

Conjugational transfer system to shuttle giant DNA cloned by Bacillus subtilis genome (BGM) vector

The Bacillus subtilis GenoMe (BGM) vector was designed as a versatile vector for the cloning of giant DNA segments. Cloned DNA in the BGM can be retrieved to a plasmid using our Bacillus recombinational transfer (BReT) method that takes advantage of competent cell transformation. However, delivery of the plasmid to a different B. subtilis strain by the normal transformation method is hampered by DNA size-related inefficiency. Therefore, we designed a novel method, conjugational plasmid-mediated DNA retrieval and transfer (CReT) from the BGM vector, and investigated conjugational transmission to traverse DNA between cells to circumvent the transformation-induced size limitation. pLS20, a 65-kb plasmid capable of conjugational transfer between B. subtilis strains, was modified to retrieve DNA cloned in the BGM vector by homologous recombination during normal culture. As the plasmid copy number was estimated to be 3, the retrieval plasmid was selected using increased numbers of marker genes derived from the retrieved DNA. We applied this method to retrieve Synechocystis genome segments up to 90 kb in length. We observed retrieved plasmid transfers between B. subtilis strains by conjugation in the absence of structural alterations in the DNA fragment. Our observations extend DNA transfer protocols over previously exploited size ranges.     

Recombinant DNA molecules comprising bovine papilloma virus type 1 DNA linked to plasmid DNA are maintained in a plasmidial state both in rodent fibroblasts and in bacterial cells.

Transformed cells obtained after transfecting FR3T3 rat fibroblasts with DNA of bovine papilloma virus type 1 ( BPV1 ) maintained only free copies of the viral genome. Transfection with BPV1 DNA inserted in a bacterial plasmid (pBR322 or pML2 ) did not produce transformants at a detectable rate, unless the viral sequences had been first excised from the plasmid. In contrast, transfer of the same plasmids by polyethylene glycol-induced fusion of bacterial protoplasts with FR3T3 rat or C127 mouse cells led to significant transformation frequencies. A total of eight cell lines were studied, three rat and five mouse transformants, obtained with various BPV1 - pML2 recombinants. In all cell lines, both BPV1 and plasmid sequences were maintained as non-integrated molecules, predominantly as oligomeric forms of the transforming DNA. In the three rat transformants and in two of the mouse lines, parts of the non-transforming viral region and some bacterial sequences were deleted. In the remaining three mouse lines, the monomeric repeat was a non-rearranged plasmid molecule which could be re-established as a plasmid in Escherichia coli after cleavage with "one-cut" restriction endonucleases and circularization of the molecule.     

Construction of a vector for cloning promoters in Bacillus subtilis

A versatile vector for cloning DNA fragments containing promoter activity in Bacillus subtilis was derived from plasmids pBR322, pUB110 and pC194. Selection is based on chloramphenicol resistance which is dependent upon the introduction of DNA fragments allowing expression of a chloramphenicol acetyl transferase gene. The plasmid contains a second selectable marker, neomycin resistance, and contains functional origins of replication for both B. subtilis and Escherichia coli.     

Artificial insertion of peptides between signal peptide and mature protein: effect on secretion and processing of hybrid thermostable alpha-amylases in Bacillus subtilis and Escherichia coli cells

To study the effect of inserted peptides on the secretion and processing of exported proteins in Bacillus subtilis and Escherichia coli, pBR322-derived DNA fragments coding for small peptides were inserted between the DNA coding for the 31 amino acid B. subtilis alpha-amylase signal peptide and that coding for the mature part of the extracellular thermostable alpha-amylase of B. stearothermophilus. Most of the inserted peptides (21 to 65 amino acids) decreased the production of the enzyme in B. subtilis and E. coli, the effect of each peptide being similar in the two strains. In contrast, with one peptide (a 21 amino acid sequence encoded by the extra DNA in pTUBE638), the production of alpha-amylase was enhanced more than 1.7-fold in B. subtilis in comparison with that of the parent strain. The molecular masses of the thermostable alpha-amylases in the periplasm of the E. coli transformants varied for each peptide insert, whereas those in the culture supernatants of the B. subtilis transformants had molecular masses similar to that of the mature enzyme. Based on the NH2-terminal amino acid sequence of the hybrid protein from pTUBE638, it was shown that in E. coli, the NH2-terminally extended thermostable alpha-amylase was translocated and remained in the periplasm after the 31 amino acid signal sequence was removed. In the case of B. subtilis, after the removal of a 34-amino acid signal sequence, the hybrid protein was secreted and processed to the mature form.     

Comparative study of the symbiotic plasmid DNA in free living bacteria and bacteroids of Rhizobium leguminosarum

Plasmids pIM13, pT127 and pBC16 delta 1, introduced by transformation into Clostridium acetobutylicum N1-4081, were shown to replicate in, and to confer antibiotic resistance upon this new host. Recombinant plasmids were constructed by inserting erythromycin-resistant plasmid pIM13 into the unique ClaI site of pBR322 or by ligating a tetracycline-resistant determinant of plasmid pT127 to HindIII-linearized pIM13. The hybrid plasmids replicated and expressed erythromycin resistance in C. acetobutylicum strain N1-4081 and in Escherichia coli or Bacillus subtilis, indicating that they might be useful as shuttle vectors for transferring genes between these strains. The efficiency and stability of different replicons in C. acetobutylicum were compared.     

The role of DNA-gyrase from Bacillus subtilis during intermolecular irregular recombination]

The location of oxolinis acid-induced gyrase cleavage sites on pBR322 and pUB110 plasmid DNA in Bacillus subtilis cells has been studied and established. The treated Bacillus subtilis protoplasts were used in the study. Coordinates of the gyrase cleavage sites were compared to the location of the illegitimate recombination sites precisely mapped on the plasmid genomes. The obtained data indicate involvement of the DNA gyrase in formation of a fraction of recombinants in Bacillus subtilis.     

Nucleotide sequence and functional map of pC194, a plasmid that specifies inducible chloramphenicol resistance.

The nucleotide sequence of pC194, a small plasmid from Staphylococcus aureus which is capable of replication in Bacillus subtilis, has been determined. The genetic determinant of chloramphenicol (CAM) resistance, which includes the chloramphenicol acetyl transferase (CAT) structural gene, the putative promoter and controlling element of this determinant, have been mapped functionally by subcloning a 1,035-nucleotide fragment which specifies the resistance phenotype using plasmid pBR322 as vector. Expression of CAM resistance is autogenously regulated since the 1,035-nucleotide fragment containing the CAT gene sequence and its promoter cloned into pBR322 expresses resistance inducibly in the Escherichia coli host. A presumed controlling element of CAT expression consists of a 37-nucleotide inverted complementary repeat sequence that is located between the -10 and ribosome-loading sequences of the CAT structural gene. Whereas the composite plasmid containing the minimal CAT determinant cloned in pBR322 could not replicate in B. subtilis, ability to replicate in B. subtilis was seen if the fragment cloned included an extension consisting of an additional 300 nucleotides beyond the 5' end of the single pC194 MspI site associated with replication. This 5' extension contained a 120-nucleotide inverted complementary repeat sequence similar to that found in pE194 TaqI fragment B which contains replication sequences of that plasmid. pC194 was found to contain four opening reading frames theoretically capable of coding for proteins with maximum molecular masses, as follows: A, 27,800 daltons; B, 26,200 daltons; C, 15,000 daltons; and D, 9,600 daltons. Interruption or deletion of either frame A or D does not entail loss of ability to replicate or to express CAM resistance, whereas frame B contains the CAT structural gene and frame C contains sequences associated with plasmid replication.     

Targeted isolation of a designated region of the Bacillus subtilis genome by recombinational transfer

A method for positional cloning of the Bacillus subtilis genome was developed. The method requires a set of two small DNA fragments that flank the region to be copied. A 38-kb segment that carries genes ppsABCDE encoding five enzymes for antibiotic plipastatin synthesis and another genome locus as large as 100 kb including one essential gene were examined for positional cloning. The positional cloning vector for ppsABCDE was constructed using a B. subtilis low-copy-number plasmid that faithfully copied the precise length of the 38-kb DNA in vivo via the recombinational transfer system of this bacterium. Structure of the copied DNA was confirmed by restriction enzyme analyses. Furthermore, the unaltered structure of the 38-kb DNA was demonstrated by complementation of a ppsABCDE deletion mutant.     

Decreased DNA damage by acid and increased repair of acid-damaged DNA in acid-habituated Escherichia coli

A study of the conjugal transfer of ColV,I-K94 tn10 from acid-treated donors suggested that acid-habituated recipients repair acid-damaged plasmid DNA better than those that are not habituated. The presence of an increased repair activity for acid-damaged DNA in habituated cells was confirmed by isolating pBR322 from acid-treated organisms; habituated cells produced more transformants when transformed by it than did non-habituated ones. Additionally, agarose gel electrophoretic studies of pBR322 DNA isolated from acid-damaged cells and tests of its transforming activity both indicated that plasmid DNA in habituated cells is less damaged by extreme acidity than is that in non-habituated organisms.     

Isolation of an autonomously replicating DNA fragment from the region of defective bacteriophage PBSX of Bacillus subtilis

We have isolated a 5.4-kilobase fragment of Bacillus subtilis DNA that confers the ability to replicate upon a nonreplicative plasmid. The B. subtilis 168 EcoRI fragment was ligated into the chimeric plasmid pCs540, which contains a chloramphenicol resistance determinant from the Staphylococcus aureus plasmid pC194 and an HpaII fragment from the Escherichia coli plasmid, pSC101. A recE B. subtilis derivative, strain BD224, is capable of maintaining this DNA as an autonomously replicating plasmid. In rec+ recipients, chloramphenicol-resistant transformants do not contain free plasmid. The plasmid is integrated as demonstrated by alterations in the pattern of chromosomal restriction enzyme fragments to which the plasmid hybridizes. The site of plasmid integration was mapped by PBS1-mediated transduction to the metC-PBSX region. A strain was a deletion in the region of defective bacteriophage PBSX differs in the hybridization profile obtained by probing EcoRI digests with this cloned fragment. This same deletion mutant, though proficient in normal recombinational pathways, permits autonomous replication of the plasmid apparently owing to the lack of an homologous chromosomal region with which to recombine. We believe that, like E. coli. B. subtilis contains at least one DNA fragment capable of autonomous replication when liberated from its normally integrated chromosomal site and that this cloned DNA fragment comes from the region of defective bacteriophage PBSX.