Construction of a novel gene bank of Bacillus subtilis using a low copy number vector in Escherichia coli

Low copy number vector plasmid pCT571 was constructed to clone Bacillus subtilis genomic fragments in Escherichia coli. pCT571 confers KmR, TcR and CmR in E. coli and CmR in B. subtilis. It has unique restriction sites within the KmR and TcR markers to allow screening for recombinant plasmids by insertional inactivation of these genes. It contains the pSC101 replicon and replicates normally at six to eight copies per chromosome equivalent in E. coli. It also contains oriVRK2, which when supplied with the product of the trfA gene of RK2 in trans, allows pCT571 to replicate at 35-40 copies per chromosome equivalent. A B. subtilis gene bank was created by cloning partially Sau3A-digested and size-fractionated fragments of B. subtilis chromosomal DNA into the BamHI site of pCT571. DNA from 1097 KmR TcS transformants was extracted and analysed electrophoretically as supercoiled DNA and after digesting with EcoRI or EcoRI and SalI. Approximately 1000 hybrid plasmids were found with reasonably sized B. subtilis fragments. The mean size of the inserts in pCT571 is 8 kb, ranging from 4 to 20 kb in different plasmids. The gene bank covers most of the B. subtilis chromosome, as demonstrated by the results of screening the gene bank for selectable nutritional markers in E. coli and B. subtilis. Hybrid plasmids which complement E. coli mutants for arg, his, lys, met, pdx, pyr and thr markers were identified from the gene bank. In B. subtilis the presence of argC, cysA, dal, hisA, ilvA, leuA, lys, metB, metC, phe, purA, purB, thr and trpC was established by transformation experiments. The effects of copy number on cloning and long-term maintenance in the bacterial strains were also investigated. At high copy number some hybrid plasmids cannot be maintained at all, while others show an increased rate of structural deletions and rearrangements.     

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.     

Investigation of the instability of plasmids directing the expression of Met-prochymosin in Escherichia coli

The causes of the instability of a multicopy plasmid, pCT70, which directs the expression of calf prochymosin in Escherichia coli, were investigated. Plasmid pAT153 and its derivative, pCT54, were stable for more than 90 generations in continuous culture with glucose limitation. The multicopy plasmid pCT66, which expressed very low levels of prochymosin due to poor translational efficiency, and low copy number plasmids which efficiently expressed the prochymosin gene, were also stable. These results indicated that high level translation of the recombinant gene was the cause of the instability of pCT70. The maximum specific growth rate of E. coli(pCT70) was reduced by 30% compared with E. coli(pCT66). To fulfil the requirements of a production system, a dual origin plasmid with controllable copy number was developed. Both this plasmid (pMG165) and a derivative which contained the prochymosin gene (pMG168) were stable when maintained at low copy number. When the copy number of plasmid pMG168 was increased by putting replication under the control of the lambda PR promoter and the cI857 temperature sensitive repressor, expression of prochymosin was achieved. This strategy enables large-scale production of prochymosin without the need for antibiotic selection or other methods of preventing plasmid loss.     

Comparison of the nucleotide sequences of the vegetative replication origins of broad host range IncP plasmids R751 and RK2 reveals conserved features of probable functional importance.

An 864 bp EcoRI fragment carrying oriVR751, the vegetative replication origin of broad host range IncP plasmid R751, was cloned and sequenced. Only the trfA gene of the IncP plasmid RK2 was required in trans for the function of oriVR751. The sequence of oriVR751 showed 65% overall homology to that of oriVRK2 determined previously. Highly conserved regions of probable functional importance were apparent, including two sets of direct repeats postulated to be interaction sites for the trfA protein(s), a putative dnaA protein binding site and a downstream inverted repeat of unknown function.     

Replication of mini RK2 plasmid in extracts of Escherichia coli requires plasmid-encoded protein TrfA and host-encoded proteins DnaA, B, G DNA gyrase and DNA polymerase III

Soluble extracts of Escherichia coli capable of carrying out replication of the mini-RK2 derivative pCT461 have been prepared from cells carrying this plasmid or from plasmid-free bacteria. The latter are dependent upon exogenously added plasmid-encoded replication protein (TrfA) and require additional DnaA protein for optimum activity. This dependence upon DnaA was confirmed by the failure of DnaA-deficient cell extracts to support replication of pCT461 in the absence of added DnaA protein. Replication is unidirectional and begins at or near oriV, the vegetative replication origin of RK2. DNase I protection studies with purified TrfA indicate that this protein acts by binding to short (17 base-pairs) directly repeated DNA sequences present in oriV. The in vitro replication is resistant to rifampicin but can be abolished by antibodies against DnaG protein (E. coli primase) or DnaB protein (helicase) and by DNA gyrase inhibitors. Inhibition by arabinosyl-CTP suggests that DNA polymerase III is responsible for elongation of nascent DNA strands. These results are discussed in relation to the mechanism of RK2 replication and in the context of the host range of the plasmid.     

Plasmid pGA1 from Corynebacterium glutamicum codes for a gene product that positively influences plasmid copy number.

The complete nucleotide sequence (4,826 bp) of the cryptic plasmid pGA1 from Corynebacterium glutamicum was determined. DNA sequence analysis revealed four putative coding regions (open reading frame A [ORFA], ORFA2, ORFB, and ORFC). ORFC was identified as a rep gene coding for an initiator of plasmid replication (Rep) according to the high level of homology of its deduced amino acid sequence with the Rep proteins of plasmids pSR1 (from C. glutamicum) and pNG2 (from Corynebacterium diphtheriae). This function was confirmed by deletion mapping of the minimal replicon of pGA1 (1.7 kb) which contains only ORFC. Deletion derivatives of pGA1 devoid of ORFA exhibited significant decreases in the copy number in C. glutamicum cells and displayed segregational instability. Introduction of ORFA in trans into the cells harboring these deletion plasmids dramatically increased their copy number and segregational stability. The ORFA gene product thus positively influences plasmid copy number. This is the first report on such activity associated with a nonintegrating bacterial plasmid. The related plasmids pGA1, pSR1, and pNG2 lacking significant homology with any other plasmid seem to be representatives of a new group of plasmids replicating in the rolling-circle mode.     

Mutations in the trfA replication gene of the broad-host-range plasmid RK2 result in elevated plasmid copy numbers.

Mutated forms of trfA, the replication protein gene of plasmid RK2, that support a minimal RK2 origin plasmid in Escherichia coli at copy numbers up to 23-fold higher than normal have been isolated. Six such high-copy-number (copy-up) mutations were mapped and sequenced. In each case, a single base transition led to an amino acid substitution in the TrfA protein primary sequence. The six mutations affected different residues of the protein and were located within a 69-base-pair region encoding 24 amino acids. Dominance tests showed that each of the mutants can be suppressed by wild-type trfA in trans, but suppression is highly dependent on the amount of wild-type protein produced. Excess mutant TrfA protein provided in trans significantly increased the copy number of RK2 and other self-replicating derivatives of RK2 that contain a wild-type trfA gene. These observations suggest that the mutations affect a regulatory activity of the TrfA replication protein that is a key factor in the control of initiation of RK2 replication.     

The sequence encoding the 43-kilodalton trfA protein is required for efficient replication or maintenance of minimal RK2 replicons in Pseudomonas aeruginosa

The trfA gene of the broad-host-range plasmid RK2 encodes two proteins of 43- and 32-kDa by initiating translation at either of two in-phase AUG codons in a single open reading frame. At least one of these proteins is essential for replication of RK2 derivatives. In order to study the role of the 43-kDa protein, Bal31 deletions into the 5' end of the trfA gene were constructed and incorporated into minimal RK2 replicons. When examined in Escherichia coli, replication and maintenance properties of plasmids encoding only the 32-kDa protein were indistinguishable from those of plasmids encoding both the 43- and the 32-kDa proteins. In four other gram-negative hosts deletion of sequences encoding only the 43-kDa protein did not have a substantial effect on plasmid establishment or stable maintenance. However, in Pseudomonas aeruginosa, deletion of 43-kDa coding sequences greatly reduced the efficiency of plasmid maintenance, suggesting a host-specific role for the 43-kDa TrfA protein in RK2 replication.     

Anin vivo cointegrate of two plasmids from incompatibility group X

Formation of a recombinant plasmid designated pNH603 was observed when two plasmids from incompatibility group X, the multicopy plasmid pNH602 (a higher-copy-number deletion derivative of R6K) and the oligocopy plasmid R485, coexisted in a single Escherichia coli cell. According to its size and its restriction endonuclease cleavage pattern, plasmid pNH603 is a true cointegrate of pNH602 and R485. An insertion-sequence-like element coming from plasmid R485 is supposed to mediate the fusion of both replicons. The pNH603 copy number (1-2 per chromosome) indicates that the mechanism of replication of the low-copy-number plasmid is dominant in this cointegrate. No dissociation of pNH603 to parental plasmids was observed even in E. coli K-12 recA+ cells. On the other hand, deletion derivatives of four size classes originate from pNH603 in both recA+ and recA hosts. A miniplasmid designated pNH604, a representative of the most frequent 7 Mg/mol size class, was found, in a low number of copies per host chromosome.     

Plasmid pTB913 derivatives are segregationally stable in Bacillus subtilis at elevated temperatures.

We studied the effects of temperature on the segregational stability of derivatives of the rolling-circle-type plasmid pTB913 in Bacillus subtilis. This 4.5-kb plasmid is a deletion derivative of pTB19, which was originally isolated from a thermophilic Bacillus. pTB913 derivatives carrying large inserts or lacking the minus origin for complementary strand synthesis were segregationally unstable at 37 degrees C. In contrast, at 47 degrees C all pTB913 derivatives tested were stably maintained in B. subtilis. The increased stability at 47 degrees C was attributed, at least partly, to increased copy numbers at this temperature. Although considerable amounts of single-stranded and high-molecular-weight plasmid DNA were formed at 47 degrees C, these products did not reduce plasmid stability at this temperature. The increased stability and increased copy number of pTB913 at elevated temperatures extend the use of this plasmid as a cloning vector in B. subtilis and other bacilli.     

Spontaneous deletions of the chromosome-mobilizing plasmid R68.45 in Pseudomonas aeruginosa PAO

In Pseudomonas aeruginosa strain PAO the chromosome-mobilizing IncP-1 plasmid R68.45 was unstable whereas the parent plasmid R68 was stable. The instability of R68.45 was observed in rec+ and rec strains within about 100 generations after conjugal transfer of the plasmid and, to a lesser extent, in established R68.45 donor strains. Two phenotypically distinct classes of R68.45 derivatives were obtained: (i) CbR (carbenicillin-resistant), TcR (tetracycline-resistant), KmR (kanamycin-resistant), Tra+ (transfer proficient), Cma- (chromosome-mobilizing ability), lacking the duplicated IS21 copy typical of R68.45 and indistinguishable from R68 by restriction enzyme analysis; (ii) CbR TcR KmS Tra- Cma-, due to deletion of one IS21 copy, the adjacent KmR gene, and a variable part of the Tra-1 region including, in most cases, the origin of transfer (oriT). Both types of deletion derivatives were stable. R68.45 derivatives lacking the Tra-2 region were not recovered spontaneously, but could be constructed in vitro and were stable in strain PAO. Deletion formation of type ii as well as Cma did not depend on homologous recombination and can be ascribed to functions of the duplicated IS21. Chromosome mobilization does not appear to require obligatory transfer of the entire R68.45 plasmid. Four ClaI restriction sites were mapped on R68 extracted from P. aeruginosa. One of these sites was cryptic, presumably because of methylation, when the plasmid was prepared from Escherichia coli (dam+).     

Synthesis of hybrid bacterial plasmids containing highly repeated satellite DNA.

Hybrid plasmid molecules containing tandemly repeated Drosophila satellite DNA were constructed using a modification of the (dA)-(dT) homopolymer procedure of Lobban and Kaiser (1973). Recombinant plasmids recovered after transformation of recA bacteria contained 10% of the amount of satellite DNA present in the transforming molecules. The cloned plasmids were not homogenous in size. Recombinant plasmids isolated from a single colony contained populations of circular molecules which varied both in the length of the satellite region and in the poly(dA)-(dt) regions linking satellite and vector. While subcloning reduced the heterogeneity of these plasmid populations, continued cell growth caused further variations in the size of the repeated regions. Two different simple sequence satellites of Drosophila melanogaster (1.672 and 1.705 g/cm3) were unstable in both recA and recBC hosts and in both pSC101 and pCR1 vectors. We propose that this recA-independent instability of tandemly repeated sequences is due to unequal intramolecular recombination events in replicating DNA molecules, a mechanism analogous to sister chromatid exchange in eucaryotes.     

Loss of RecA function affects the ability of Escherichia coli to maintain recombinant plasmids containing a Ter site.

In the Escherichia coli chromosome, DNA replication forks arrested by a Tus-Ter complex or by DNA damage are reinitiated through pathways that involve RecA and numerous other recombination functions. To examine the role of recombination in the processing of replication forks arrested by a Tus-Ter complex, the requirements for recombination-associated gene products were assessed in cells carrying Ter plasmids, i.e., plasmids that contain a Ter site oriented to block DNA replication. Of the E. coli recombination functions tested, only loss of recA conferred an observable phenotype on cells containing a Ter plasmid, which was inefficient transformation and reduced ability to maintain a Ter plasmid when Tus was expressed. Given the current understanding of replication reinitiation, the simplest explanation for the restriction of Ter plasmid maintenance was a reduced ability to restart plasmid replication in a recA tus(+) background. However, we were unable to detect a difference in the efficiency of replication arrest by Tus in recA-proficient and recA-deficient cells, which suggests that the inability to restart arrested replication forks is not the cause of the restriction on growth, but is due to an additional function provided by RecA. Other explanations for restriction of Ter plasmid maintenance were examined, including plasmid multimerization, plasmid rearrangements, and copy number differences. The most likely cause of the restriction on Ter plasmid maintenance was a reduced copy number in recA cells that was detected when the copy number was measured in relation to an external control. Possibly, loss of RecA function leads to improper processing of replication forks arrested at a Ter site, leading to the generation of degradation-prone substrates.     

Genetic instability of an artificial palindrom DNA sequence

A short DNA palindrom, produced by head to head ligation of a 29 bp DNA fragment, was inserted into a 27,000 bp plasmid DNA element composed of two functional replicons (R6K, ColE1). Several plasmid types containing a single copy of this palindrom in different locations of insertion on the R6K sequence were obtained. The palindrom was engineered to possess a unique EcoRI recognition sequence at its axis of symmetry. The presence of this restriction site allowed to monitor the genetic stability of the artificial palindrom at their different insertion loci. Out of 5 different insertion locations, one (in pAS807) was found to lead to a significant destabilization of the palindrom. This insertion site lies within the replication control region of R6K. We have shown that the inserted palindrom in pAS8O7 does not affect the functionality of the R6K replication origins. Excission of the palindrom sequences from pAS8O7 was not accompanied by loss of the adjacent R6K DNA sequences. Different deletion derivatives of pAS807 were generated in-vitro in order to determine the driving unit of DNA sequences around the palindrom that are involved in its excision. The results imply that large DNA structure(s) around the palindrom are involved in its excission. Complete deletion of R6K sequences from either the left or the right side of the palindrom resulted in new configurations which stabilized the palindrom. A configuration of R6K DNA sequences exceeding 270 bp long sequence from both sides of the palindrom are necessary for the transition from a palindrom stable to palindrom unstable state. In addition evidence is presented to show that the excision process of palindrom sequences requires a functional polymerase I but not the gene product of recA.     

Novel system for recognizing and eliminating foreign DNA in Pseudomonas putida.

Derivatives of pQSR49 (R1162::Tn1) containing cloned fragments of Escherichia coli chromosomal DNA are stable in E. coli but unstable in Pseudomonas putida. Similar derivatives containing P. putida chromosomal DNA are stable in both species. Instability is a consequence of plasmid loss during growth and is not due to death or inhibition of growth of plasmid-containing cells. Average copy numbers per cell of the unstable hybrid plasmids are similar to that of pQSR49, indicating that instability is not the result of reduced replication of plasmid DNA. A plasmid unrelated to pQSR49, RK2, becomes unstable in the presence of the unstable hybrids but only when it also contains foreign DNA. The data suggest an inducible mechanism in P. putida active in the elimination of plasmid-borne foreign DNA from the cell.     

Cloning and DNA sequence of a mycoplasmal recA gene.

Mycoplasmas are wall-less prokaryotes phylogenetically related to gram-positive bacteria. In order to investigate DNA recombination in these organisms, we have cloned the recA gene from the mycoplasma Acholeplasma laidlawii. DNA sequence data indicate extensive homology between the A. laidlawii recA gene and recA genes from other bacteria, particularly Bacillus subtilis. The recA sequences from three A. laidlawii strains (strains JA1, K2, and 8195) were compared, and surprisingly, the gene from A. laidlawii 8195 was found to contain a nonsense mutation that results in truncation of 36 amino acids from the carboxyl terminus of the RecA protein. By using sensitivity to UV irradiation as a measure of DNA repair, strain 8195 had an apparent RecA- phenotype. When carried on a multicopy plasmid, the wild-type A. laidlawii recA gene was detrimental to growth of Escherichia coli, perhaps because of improper regulation of the RecA protein.