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.     

Molecular aspects of genetic instability of an artificial 68 bp perfect palindrome in Escherichia coli

Summary An artificial 68 bp perfect palindrome carried on a plasmid (pAS807) is genetically unstable. An increase in the population of cells harbouring palindrome-deleted pAS807 derivatives (pAS807-) is observed as the number of cell generations increases. The calculated frequency of palindrome excision events per cell generation and per plasmid replication round in Escherichia coli is 0.95x10^-4. Sequence analysis of eight independent isolates of palindrome-deleted molecules, reveals two symmetrical deletion types (three of type I and five of type II). The two types of pAS807- molecules retain 19 bp of the original sequence of the 68 bp palindrome but differ in the content of the central 3 bp. The generation of the two deletion types is best explained by formation of intermediate cruciform structures. Following the fate of the palindrome in various bacterial mutants, we find that the excision events depend on functional polA1, polA(ex1), lig, texA343(recC343) and texA344(recB344) gene products. However, recB21 recC22 mutations do not affect palindrome excision.     

The nucleotide sequence of a DNA fragment from the replication origin of the antibiotic resistance factor R1drd19

Summary The recombinant plasmid pRK101 contains a DNA fragment which carries the complete replication origin of the antibiotic resistance factor R1drd-19 inserted into the vector plasmid pBR322. In a spontaneously arising mutant of this plasmid (pRK 103) a deletion of about 215 base pairs (bp) has been detected by heteroduplex analysis and mapping with restriction endonucleases. Essential parts of the replication origin must be located in the deleted sequence. The deletion mutant pRK103, in contrast to its parent plasmid pRK101 is not replicated under the control of the R1 replicon, even when the R1 factor or copy mutants of it are present within the same cell. These latter plasmids can complement a plasmid-specific protein not coded by pRK101 but essential for R1-directed replication. The nucleotide sequence of a 252 bp HpaII fragment covering about 170–200 bp of the deletion was determined. This piece of DNA is rich in G and C and contains a series of small palindromes, symmetrically arranged repeated sequences and short selfcomplementary structures which may be of significance for the initiation of the DNA replication. The possibility that the sequenced DNA fragment comprises a major part of the replication origin of R1drd-19 is discussed.     

Site-specific deletion at the replication origin of the antibiotic resistance factor R1

Summary The recombinant plasmid pRK101 carrying the complete replication origin of the antibiotic resistance factor R1 suffers frequently a deletion of 218 base pairs, removing parts or all of the origin sequence. This deletion seems to occur always when the Pst-E fragment carrying the replication origin is inserted into the cloning vector pBR322 in an orientation where the direction of R1 replication is the same as that of the vector plasmid and frequently when it is inserted in the opposite direction. DNA sequence analysis around the junction site generated by the deletion in three independently isolated deletion mutants reveals that the deletion occurs at a specific site, namely the end of a 22 bp sequence which is repeated almost identically at the other end of a segment of 197 bp. During the deletion one repeat unit is removed whereas the other is retained. The DNA sequence included by the two repeats contains high symmetric structures, i.e. inverted repeats, direct repeats and palindromes which may represent regulatory sites of the origin.     

Genetic control of plasmid R6K conjugativity

The regions determining conjugation ability of plasmid R6K were localized by means of deletion mutants obtained in vitro and in vivo and Tra- mutants induced by integration of transposons Tn5, Tn7 and Tn9 into different DNA sites of the conjugative deletion mutant pAS3. At least 13 genes were found to be involved in the genetic control of R6K conjugativity, on the basis of genetic, restriction and heteroduplex studies. They were mapped within the two DNA regions having the total molecular weight of about 10-11 md. A transposon-like structure with a replication function has been located between them.     

Mobilization of the pACYC184 plasmid by hybrid pAS8-121 delta plasmids in Escherichia coli cells

The plasmid pACYC184 is shown to be mobilized for conjugal transfer in Escherichia coli cells by the deleted (Tn7-TcR) derivatives of the hybrid conjugative plasmid pAS8-121 (RP4-Co1E1). Both the mobilized and mobilizing plasmids are autonomously inherited by the recipient cells when the mobilizing plasmid carries single copy of IS8 (the plasmid pAS8-121 delta 16). Cointegrates pAS8-121 delta 16D:: ::pACYC184 are found in the recipient cells with pACYC184 being inserted between two repeats of IS8 if the derivate plasmid pAS8-121 delta 16D having the duplication of IS8 is used to mobilize pACYC184 for conjugal transfer. The insertion of pACYC184 between IS8 repeats in the plasmid pAS8-121 delta 16D eliminates the plasmid ability to be inserted with high frequency into the chromosome of the phototrophic bacterium R. sphaeroides 2R. The cointegrate pAS8-121 delta 16D:: pACYC184 is stable but can be resolved during the transformation deriving the plasmid pACYC184:: IS8. The latter may be used as a probe for isolation and analysis of IS8 DNA sequences and for constructing the vectors on the basis of pACYC184.     

Plasmid R6K DNA replication. II. Direct nucleotide sequence repeats are required for an active gamma-origin

Insertions of the transposable element Tn5 were obtained at a number of sites within the γ origin region of plasmid R6K. A contiguous region of DNA, 240 base-pairs in length, was identified as the functional γ origin of replication on the basis that Tn5 insertions within this region inactivated the origin. This region contains seven, tandemly arranged, 22 base-pair direct repeats. Spontaneous deletion of a Tn5 sequence that is inserted in one of the repeats was accompanied generally by the loss of nucleotide sequences equivalent to one or more of the repeat sequences. Deletion mutants of the γ origin that lack one or two repeats are still functional but a plasmid containing such a mutant origin is not maintained stably. Deletions of nucleotide sequences equivalent to four or more of the direct repeats result in the inactivation of the R6K γ origin.     

Mapping of RP4 plasmid using deletion mutants of pAS8 hybrid (RP4-ColE1)

Summary We used the hybrid plasmid pAS8 in order to conduct the genetic analysis of RP4 plasmid. The presence of two replicons in the hybrid plasmid permitted to expand the spectrum of deletion mutants of RP4 isolated, which are capable to autonomous replication. The shortening of the hybrid plasmid was achieved by P22 transduction, by induction of deletion mutants using mitomycin C, as well as by selection of Tra^- mutants on the basis of resistance of cells to P-specific phages. These techniques have lead to isolation of clones possessing different combinations of plasmid resistance determinants.Comparison of phenotypic characteristics of deletion plasmids pAS9, pAS10, pAS11, pAS12 and pAS10-2 permitted to propose the map for pAS8 plasmid with the following sequence of markers: trakan-ColE1-amp-tet...Heteroduplex analysis of deletion mutants of pAS8 permitted to construct a physical map and to elaborate in greater detail the functional map of RP4 plasmid. The correlation between the ability of mutants to replicate in polA (TS) strain at nonpermissive conditions and the length of the deleted segment permitted to map rep genes of RP4 on a region with coordinates 9.8–17.3 kb. A relationship between the manifestation of incompatibility of mutants with Inc P-1 plasmids and the length of deletions points out that inc genes are located on DNA region with coordinates 2.1–9.8 kb. The analysis of replication of deletion mutants and the manifestation of incompatibility just as of the data about the size of appropriate deletions permitted to make the conclusion about the functional and genetic independence of the replication control and incompatibility control in RP4 plasmid.     

Sequence analysis of the family of penicillinase-producing plasmids of Neisseria gonorrhoeae

The exact nature of the sequence differences between the medically important family of gonococcal penicillinase-producing plasmids has been ascertained. The entire DNA sequence of the Asia-type plasmid, pJD4, demonstrated that it is 7426 bp and contains two direct repeats (DR30) that are implicated in the formation of deletion variant plasmids, such as the Africa-type plasmid. We have identified putative DnaA and IHF binding sites, various open reading frames that are thought to specify functional proteins, and some important DNA sequences involved with conjugative transfer of gonococcal beta-lactamase plasmids. The deletion in the Africa-type plasmid is 1827 bp and one of the DR30 repeats is also missing. The deletion in the Rio-type plasmid and several Toronto-type plasmids was determined to be 2273 bp and the sequence spanning the deletion was identical irrespective of geographic or temporal origin. The &Ncirc;imes-type plasmid is an Africa-type plasmid and also contains an IS5 insertion sequence. Since IS5 has not been identified in gonococcal isolates, we suggest that this sequence may have been inserted after the original gonococcal plasmid was transformed into Escherichia coli. The New Zealand plasmid is an Asia-type plasmid that contains an endogenous tandem duplication of 1883 bp and the direct DR2 is implicated in this duplication. The nature of the defined truncation of Tn2 present in the various plasmids is also discussed.     

Control of plasmid incompatibility: characteristics of the bireplicon hybrid pAS8 and its deletion mutants]

The phenomenon of incompatibility has been investigated using deletion mutants of hybrid bireplicon plasmid pAS8. The hybrid pAS8 displays incompatibility specific for both components of its structure. In contrast to P-specificity of pAS8, functions of ColE1-specificity are not effectively expressed. Expression of ColE1-specificity in pAS8 plasmid and its derivatives is characterized by different directions and this is due to the presence or absence of genes of RP4 replication machinery in the plasmid DNA. Mutant plasmids show different efficiency of P-specificity depending on the extension of deletion in the region of essential genes of the RP4 component. Some of the mutants, in spite of the loss of replication genes, including origin of vegetative replication, are incompatible with the representatives of the Inc P group in both directions of testing. Different character and the level of expression of ColE1- and P-specificity in the pAS8 hybrid and its deletion derivatives are not associated with change in the number of plasmid DNA copies, for all of them are subjects to stringent control of replication. The data suggest the existence of incompatibility functions control mechanism which does not seem to include replication genes. Possible ways of realization of the inc genes functions are discussed.     

DNA segments of the IncX plasmid R485 determining replication and incompatibility with plasmid R6K

The expression of incompatibility properties between the IncX plasmids R6K and R485 of Escherichia coli was examined. For small autonomously replicating derivatives of both plasmid elements, the requirements for incompatibility expression include a functional R485 replicon and an active R6K beta-origin region. Functional R6K alpha and gamma origins are not directly involved in incompatibility expression between R6K and R485. A trans-acting replication system was constructed for plasmid R485. It consists of a 3.2-(kb) DNA fragment of R485 that specifies a product(s) in trans which supports replication from an R485 origin plasmid. A minimal R485 origin region of 591 bp was derived utilizing this trans-acting replication system and the nucleotide sequence of this origin region determined. The most striking feature of the sequence is the presence of six tandem 22-bp nucleotide sequence direct repeats.     

New replication mutant pnh602 and its relationship to plasmid pAS3, another deletion derivative of plasmid R6K

A stable deletion derivative pNH602 was obtained when the recently described higher-copy-number point mutant pNH601 of plasmid R6K was introduced to a minicells-producing strain of Escherichia coli. The size of plasmid pNH602 is 18.8 Mg/mol as determined by electron microscopy. The 7.2 Mg/mol fragment of R6K genome missing in pNH602 carries the Smr-determinant and the region finO and, according to the results of restriction analysis, it includes one EcoRI site. With its radioisotopically determined 33 copies of pNH602 per E. coli K-12 chromosome (npc), representing a 23% increase of the point mutant pNH601 and 150% enhancement of R6K npc, plasmid pNH602 differs from another closely related R6K deletion derivative pAS3 of the same size which exhibits only 20 npc. Both pNH602 and pAS3 plasmids are conjugative.     

Stability of an inverted repeat in a human fibrosarcoma cell.

Deletions and rearrangements of DNA sequences within the genome of human cells result in mutations associated with human disease. We have developed a selection system involving a neo gene containing a DNA sequence inserted into the NcoI site that can be used to quantitatively assay deletion of this sequence from the chromosome. The spontaneous deletion from the neo gene of a 122 bp inverted repeat occurred at a rate of 2.1 x 10(-8) to <3.1 x 10(-9) revertants/cell/generation in three different cell lines. Deletion of the 122 bp inverted repeat occurred between 6 bp flanking direct repeats. Spontaneous deletion of a 122 bp non-palindromic DNA sequence flanked by direct repeats was not observed, indicating a rate of deletion of <3.1 x 10(-9) revertants/cell/generation. This result demonstrates that a 122 bp inverted repeat can exhibit a low level of instability in some locations in the chromosome of a human cell line.     

Broad-host-range IncP-4 plasmid R1162: effects of deletions and insertions on plasmid maintenance and host range

R1162 is an 8.7-kilobase (kb) broad-host-range replicon encoding resistance to streptomycin and sulfa drugs. In vitro deletion of 1.8-kb DNA between coordinates 3.0 and 5.3 kb did not affect plasmid maintenance, but a Tn1 insertion at coordinate 6.3 kb led to a recessive defect in plasmid maintenance. The only cis-acting region necessary for plasmid replication appears to lie between the Tn1 insertion at coordinate 6.3 kb and a second Tn1 insertion at coordinate 6.5 kb. All R1162 sequences between position 6.5 kb and the EcoRI site at coordinate 8.7/0 kb were dispensible for replication in Escherichia coli and Pseudomonas putida. Plasmids carrying insertions in a variety of restriction sites in an R1162::Tn1 derivative were unstable in P. putida but stable in E. coli. Tn5 insertions in R1162 showed a hot spot at coordinate 7.5 kb. A Tn5 insertion at coordinate 8.2 kb appeared to mark the 3' end of the streptomycin phosphotransferase coding sequence. All R1162::Tn5 derivatives showed specific instability in Pseudomonas strains but not in E. coli. The instability could be relieved by internal deletions of Tn5 sequences. In the haloaromatic-degrading Pseudomonas sp. strain B13, introduction of an unstable R1162::Tn5 plasmid led to loss of ability to utilize m-chlorobenzoate as a growth substrate. Our results showed that alteration of plasmid sequence organization in nonessential regions can result in restriction of plasmid host range.     

The replication initiator protein of plasmid R6K tagged with beta-galactosidase shows sequence-specific DNA-binding

We have tagged the replication initiator protein of the plasmid R6K near the C-terminal end by fusion, in the correct reading frame, with the 89 amino acid long N-terminal alpha-donor polypeptide of beta-galactosidase of E. coli. This fusion was carried out with recombinant DNA methods. The protein chimera thus generated retained the activities of both initiation of DNA replication in vivo at the replication origin gamma of R6K and hydrolysis of beta-galactopyranoside when complemented in vivo with the alpha-acceptor polypeptide coded by the lac Z gene containing the M15 deletion. Using the simple and convenient assay for detecting beta-galactosidase, we have partially purified the tagged replication initiator, and have demonstrated that the protein binds to specific DNA sequences of the R6K chromosome. The protein bound to DNA sequences located at two places in the 5' untranslated leader region of the initiator protein cistron.     

Identification of the DNA sequence from the E. coli terminus region that halts replication forks

The terminus region of the E. coli chromosome contains two loci, T1 and T2, that inhibit the progress of replication forks and require the trans-acting factor tus. We have identified a 23 bp terminator signal at T1 and T2 that is within 100 bp of the sites of replication arrest. When an oligodeoxyribonucleotide containing the terminator signal was inserted into a plasmid, replication was halted only in a tus+ strain and when the terminator signal was oriented properly. We also found this terminator sequence in the terminus region of the plasmid R6K and in the origin region of RepFIIA class plasmids. In addition, we found striking similarities between the E. coli terminator signal and the terminator sequence of B. subtilis.     

In vitro and in vivo analysis of transcription within the replication region of plasmid pIP501

Summary The tobacco (Nicotiana tabacum) nuclear genome contains long tracts of DNA (i.e. in excess of 18 kb) with high sequence homology to the tobacco plastid genome. Five lambda clones containing these nuclear DNA sequences encompass more than one-third of the tobacco plastid genome. The absolute size of these five integrants is unknown but potentially includes uninterrupted sequences that are as large as the plastid genome itself. An additional sequence was cloned consisting of both nuclear and plastid-derived DNA sequences. The nuclear component of the clone is part of a family of repeats, which are present in about 400 locations in the nuclear genome. The homologous sequences present in chromosomal DNA were very similar to those of the corresponding sequences in the plastid genome. However significant sequence divergence, including base substitutions, insertions and deletions of up to 41 bp, was observed between these nuclear sequences and the plastid genome. Associated with the larger deletions were sequence motifs suggesting that processes such as DNA replication slippage and excision of hairpin loops may have been involved in deletion formation.     

Gene conversion associated with site-specific recombination in yeast plasmid pSR1.

A circular DNA plasmid, pSR1, isolated from Zygosaccharomyces rouxii has a pair of inverted repeats consisting of completely homologous 959-base pair (bp) sequences. Intramolecular recombination occurs frequently at the inverted repeats in cells of Saccharomyces cerevisiae, as well as in Z. rouxii, and is catalyzed by a protein encoded by the R gene of its own genome. The recombination is, however, independent of the RAD52 gene of the host genome. A site for initiation of the intramolecular recombination in the S. cerevisiae host was delimited into, at most, a 58-bp region in the inverted repeats by using mutant plasmids created by linker insertion. The 58-bp region contains a pair with 14-bp dyad symmetry separated by a 3-bp spacer sequence. The recombination initiated at this site was accompanied by a high frequency of gene conversion (3 to 50% of the plasmid clones examined). Heterogeneity created by the linker insertion or by a deletion (at most 153 bp so far tested) at any place on the inverted repeats was converted to a homologous combination by the gene conversion, even in the rad52-1 mutant host. A mechanism implying branch migration coupled with DNA replication is discussed.     

Amplification and excision of integrated polyoma DNA sequences require a functional origin of replication

Cells transformed by Polyoma virus (Py) can undergo a high rate of excision or amplification of integrated viral DNA sequences, and these phenomena require the presence of homology (i.e., repeats) within the viral insertion as well as a functional viral large T antigen (T-Ag). To determine whether the main role of large T-Ag in excision and amplification was replicative or recombination-promoting, we studied transformed rat cell lines containing tandem insertions of a ts-a Py molecule (encoding a thermolabile large T-Ag) with a deletion of the origin of viral DNA replication. Culturing of these cells at the temperature permissive for large T-Ag function did not result in any detectable excision or amplification of integrated Py sequences. We then introduced into origin-defective lines a recombinant plasmid containing the viral origin of replication and the gene coding for resistance to the antibiotic G418. All G418-resistant clones analyzed readily amplified the integrated plasmid molecules when grown under conditions permissive for large T-Ag function, showing that these cells produced viral large T-Ag capable of promoting amplification in trans of DNA sequences containing the Py origin. These observations strongly suggest that Polyoma large T antigen promotes excision or amplification of viral DNA by initiating replication at the integrated origin, providing a favorable substrate for subsequent recombination.