Deletions in Plasmid Pbr322: Replication Slippage Involving Leading and Lagging Strands

We test here whether a class of deletions likely to result from errors during DNA replication arise preferentially during synthesis of either the leading or the lagging DNA strand. Deletions were obtained by reversion of particular insertion mutant alleles of the pBR322 amp gene. The alleles contain insertions of palindromic DNAs bracketed by 9-bp direct repeats of amp sequence; in addition, bp 2 to 5 in one arm of the palindrome form a direct repeat with 4 bp of adjoining amp sequence. Prior work had shown that reversion to Ampr results from deletions with endpoints in the 8- or 4-bp repeat, and that the 4-bp repeats are used preferentially because one of them is in the palindrome. To test the role of leading and lagging strand synthesis in deletion formation, we reversed the direction of replication of the amp gene by inverting the pBR322 replication origin, and also constructed new mutant alleles with a 4-bp repeat starting counterclockwise rather than clockwise of the insertion. In both cases the 4-bp repeats were used preferentially as deletion endpoints. A model is presented in which deletions arise during elongation of the strand that copies the palindrome before the adjoining 4-bp repeat, and in which preferential use of the 4-bp repeats independent of the overall direction of replication implies that deletions arise during syntheses of both leading and lagging strands.     

Detection of template strand switching during initiation and termination of DNA replication of porcine circovirus

Nucleotide substitution mutagenesis was conducted to investigate the importance of the inverted repeats (palindrome) at the origin of DNA replication (Ori) of porcine circovirus type 1 (PCV1). Viral genomes with engineered mutations on either arm or both arms of the palindrome were not impaired in protein synthesis and yielded infectious progeny viruses with restored or new palindromes. Thus, a flanking palindrome at the Ori was not essential for initiation of DNA replication, but one was generated inevitably at termination. Among the 26 viruses recovered, 16 showed evidence of template strand switching, from minus-strand genome DNA to palindromic strand DNA, during biosynthesis of the Ori. Here I propose a novel rolling-circle "melting-pot" model for PCV1 DNA replication. In this model, the replicator Rep protein complex binds, destabilizes, and nicks the Ori sequence to initiate leading-strand DNA synthesis. All four strands of the destabilized inverted repeats exist in a "melted" configuration, and the minus-strand viral genome and a palindromic strand are available as templates, simultaneously, during initiation or termination of DNA replication. Inherent in this model is a "gene correction" or "terminal repeat correction" mechanism that can restore mutilated inverted-repeat sequences to a palindrome at the Ori of circular DNAs or at the termini of circularized linear DNAs. Potentially, the melted state of the inverted repeats increases the rate of noncomplementary or illegitimate nucleotide incorporation into the palindrome. Thus, this melting-pot model provides insight into the mechanisms of DNA replication, gene correction, and illegitimate recombination at the Ori of PCV1, and it may be applicable to the replication of other circular DNA molecules.     

Rapid, stabilizing palindrome rearrangements in somatic cells by the center-break mechanism

DNA palindromes are associated with rearrangement in a variety of organisms. A unique opportunity to examine the impact of a long palindrome in mammals is afforded by the Line 78 strain of mice. Previously it was found that the transgene in Line 78 is likely to be palindromic and that the symmetry of the transgene was responsible for a high level of germ line instability. Here we prove that Line 78 mice harbor a true 15.4-kb palindrome, and through the establishment of cell lines from Line 78 mice we have shown that the palindrome rearranges at the impressive rate of about 0.5% per population doubling. The rearrangements observed to arise from rapid palindrome modification are consistent with a center-break mechanism where double-strand breaks, created through hairpin nicking of an extruded cruciform, are imprecisely rejoined, thus introducing deletions at the palindrome center. Significantly, palindrome rearrangements in somatic tissue culture cells almost completely mirrored the structures generated in vivo in the mouse germ line. The close correspondence between germ line and somatic events indicates the possibility that center-break modification of palindromes is an important mechanism for preventing mutation in both contexts. Permanent cell lines carrying a verified palindrome provide an essential tool for future mechanistic analyses into the consequences of palindromy in the mammalian genome.     

Modulation of an ultraviolet mutational hotspot in a shuttle vector Xeroderma cells.

Ultraviolet mutagenesis of the shuttle vector plasmid pZ189 in Xeroderma Pigmentosum cells yields a mutational pattern marked by hotspots at photoproduct sites on both strands of the supF marker gene. In order to test the influence of strand orientation on the appearance of hotspots the mutagenesis study was repeated on a vector with the supF gene in the inverted orientation. We recovered a pattern the same as that in the earlier work and conclude that the nature of the DNA polymerase involved in the replication of specific strands is not a primary determinant of hotspot occurrence in this system. One of the hotspots lies in an 8 base palindrome while the corresponding site on the other strand was not a hotspot. These results were obtained with calcium phosphate transfection of the UV treated vector. When DEAE dextran was used as a transfection agent both sites in the palindrome were hotspots. In a mixing experiment the calcium phosphate pattern was recovered. Our data suggest that the sequence determinants of mutational probability at these two sites lie outside the 8 bases of the palindrome and that mutagenesis at one, but not the other, site is sensitive to perturbation of cellular calcium levels.     

Characterization of the binding specificity of two anticruciform DNA monoclonal antibodies

Two monoclonal antibodies (2D3 and 4B4) have been raised against a stable cruciform DNA structure containing the 27-base pair palindrome of the SV40 origin of replication on one strand and an unrelated 26-base pair palindrome on the complementary strand (pRGM 21 x pRGM 29) and have been shown to recognize conformational determinants specific to cruciform DNA structures (Frappier, L., Price, G.B., Martin, R. G., and Zannis-Hadjopoulos, M. (1987) J. Mol. Biol. 193, 751-758). To define the region(s) of the cruciform that is recognized by these antibodies, we examined the ability of 2D3 and 4B4 to protect the single-stranded tips of the loops or the four-way junctions at the base of the stem of stable cruciform molecules against cleavage by mung bean nuclease or T7 endonuclease 3, respectively. Both antibodies were found to protect two of the four elbow-like structures at the base of the cruciform from T7 endonuclease 3 cleavage, but not the tips of the cruciform arms from mung bean nuclease cleavage. Also, predigestion of the cruciform with mung bean nuclease did not affect the binding of either antibody. In addition, 2D3 bound to a cruciform and a T-shaped structure involving the palindromic sequence at the cloning site of pUC7, which is completely unrelated in sequence to the palindrome of pRGM 21 x pRGM 29, and protected the base of these stem-loop structures against cleavage by T4 endonuclease VII. These results indicate that 2D3 and 4B4 bind at or near the base of the cruciform molecules and that, at least for 2D3, binding is independent of DNA sequence.     

Turn-on of Inactive Genes by Promoter Recruitment in ESCHERICHIA COLI: Inverted Repeats Resulting in Artificial Divergent Operons

We have characterized two rearrangements consisting of inverted repeats of the argE gene. The promoters (p) of argE and of argCBH face each other over an internal operator. The rearrangements were obtained as reactivations of argE in a strain harboring an argEp deletion on a lambda darg prophage. In both cases the repeat included argE and argCBHp on either side of a unique sequence; the result is a divergent operon in which each copy of argCBHp reads into the adjacent argE repeat. In one case, the pair of repeats adjoins the silent parental gene, forming a triplication (comes from leads to comes from). The other rearrangement consists of a single argE palindrome, but the whole prophage is rearranged into an inverted repeat, analogous to certain lambda dv's. Both structures could be explained by breakage of a replication fork passing argE and by inaccurate rejoining of strands. The lambda dv-like rearrangement would result from breakage at both replication forks of a phage or prophage replicating during transient release of immunity. The triplication would imply breaking of a chromosomal replication fork, formation of a cyclic intermediate by recombination between the daughter duplex molecules and reinsertion into the parental argE gene. Formation of a triplication by replication errors involving appropriate strand switchings and branch migrations can not be excluded however.     

Species-specific Typing of DNA Based on Palindrome Frequency Patterns

DNA in its natural, double-stranded form may contain palindromes, sequences which read the same from either side because they are identical to their reverse complement on the sister strand. Short palindromes are underrepresented in all kinds of genomes. The frequency distribution of short palindromes exhibits more than twice the inter-species variance of non-palindromic sequences, which renders palindromes optimally suited for the typing of DNA. Here, we show that based on palindrome frequency, DNA sequences can be discriminated to the level of species of origin. By plotting the ratios of actual occurrence to expectancy, we generate palindrome frequency patterns that allow to cluster different sequences of the same genome and to assign plasmids, and in some cases even viruses to their respective host genomes. This finding will be of use in the growing field of metagenomics.     

A method to find palindromes in nucleic acid sequences

Various types of sequences in the human genome are known to play important roles in different aspects of genomic functioning. Among these sequences, palindromic nucleic acid sequences are one such type that have been studied in detail and found to influence a wide variety of genomic characteristics. For a nucleotide sequence to be considered as a palindrome, its complementary strand must read the same in the opposite direction. For example, both the strands i.e the strand going from 5'' to 3'' and its complementary strand from 3'' to 5'' must be complementary. A typical nucleotide palindromic sequence would be TATA (5'' to 3'') and its complimentary sequence from 3'' to 5'' would be ATAT. Thus, a new method has been developed using dynamic programming to fetch the palindromic nucleic acid sequences. The new method uses less memory and thereby it increases the overall speed and efficiency. The proposed method has been tested using the bacterial (3891 KB bases) and human chromosomal sequences (Chr-18: 74366 kb and Chr-Y: 25554 kb) and the computation time for finding the palindromic sequences is in milli seconds.     

Local DNA Sequence Control of Deletion Formation in Escherichia coli Plasmid Pbr322

The specificity of deletion formation was studied using tests involving reversion of palindromic insertion mutations. Insertions of a Tn5-related transposon at 13 sites in the ampicillin-resistance (amp) gene of plasmid pBR322 were shortened to a nested set of perfect palindromes, 22, 32 and 90 bp long. We monitored frequencies of reversion to Ampr, which is the result of deletion of the palindrome plus one copy of the flanking 9 bp direct repeats (which had been formed by transposition). Revertant frequencies were found to depend on the location and the sequence of the palindromic insert. Changing a 45-kb interrupted palindrome to a 22-bp perfect palindrome stimulated deletion formation by factors of from fourfold to 545-fold among the 13 sites, while elongation of the perfect palindrome from 22 to 90 bp stimulated deletion formation by factors of from eight- to 18,000-fold. We conclude that deletion formation is strongly affected by subtle features of DNA sequence or conformation, both inside and outside the deleted segment, and that these effects may reflect specific interactions of DNA processing proteins with template DNAs.     

Long DNA palindromes,cruciform structures,genetic instability and secondary structure repair

Long DNA palindromes pose a threat to genome stability. This instability is primarily mediated by slippage on the lagging strand of the replication fork between short directly repeated sequences close to the ends of the palindrome. The role of the palindrome is likely to be the juxtaposition of the directly repeated sequences by intrastrand base-pairing. This intra-strand base-pairing, if present on both strands, results in a cruciform structure. In bacteria, cruciform structures have proved difficult to detect in vivo, suggesting that if they form, they are either not replicated or are destroyed. SbcCD, a recently discovered exonuclease of Escherichia coli, is responsible for preventing the replication of long palindromes. These observations lead to the proposal that cells may have evolved a post-replicative mechanism for the elimination and/or repair of large DNA secondary structures.     

眼镜王蛇线粒体基因组全序列分析

参照近缘物种线粒体基因序列共设计和合成了8对引物, 结合Ex Taq-PCR、TA克隆和步移测序技术, 文章首次获得眼镜王蛇线粒体基因组全序列(GenBank登录号: EU_921899)。该基因组全长17 267 bp, 共编码13个蛋白、2个rRNA、23个tRNA-- 其中tRNA-Ile基因发生了复制, 属于一种新的蛇类物种线粒体基因排列模式, 另外还含有2个非编码的富含AT的控制区。除了8个tRNA基因和1个蛋白基因由L链编码外, 其余均由H链编码, 其中H链编码基因的A和T含量接近, 而L链上A的含量则明显高于T。基于21种蛇合并的“12S＋16S”rRNA基因序列的系统发育分析表明, 眼镜王蛇属与眼镜蛇属亲缘关系较近, 两者与环蛇属共同构成一个单系群。作为国内外眼镜王蛇线粒体基因组全序列的首次报道, 上述结果对于蛇类物种分子系统发育和进化研究具有重要意义。     

Effects of palindrome size and sequence on genetic stability in the bacteriophage phi X174 genome

By inserting palindromes of varying length and sequence into a non-essential region of the bacteriophage phi X174 genome we have investigated the effect of palindrome size and sequence on their genetic stability. Multimers of increasing size of the EcoRI linker CCGAATTCGG (E), the BamHI linker CCGGATCCGG (B) or mixtures of both (E, B) were inserted into the PvuII site of a previously constructed bacteriophage strain phi X174 J-F ins6. The largest inserts that could be maintained in the genome without significant loss of genetic stability were 2B, 4E, and 4(E, B), respectively. Polymers exceeding this size could be inserted but resulted in rapid and precise deletion from the phage genome, whereby nB was more unstable than nE, and nE was more unstable than n(E, B). Analysis of the resulting deletion mutants provided evidence for two different types of deletions. The more frequent deletion arose from either type palindrome and removed nucleotides in blocks of ten base-pairs (one linker unit), but only from the palindromic sequence, and always left at least an 18 base-pair long palindrome (one linker plus 8 neighboring base-pairs) behind. The less frequently occurring deletions arose only from nB type palindromes, removing the complete palindromic sequence plus adjacent nucleotides. At least the first type of deletion occurred in the absence of recA activity. Our results show a correlation between the sequence, as well as size, and the genetic stability of palindromes, i.e. sequences that could decrease the stability of a cruciform increased their genetic stability. This supports the theory that palindrome deletion occurs via extrusion of the palindrome into a cruciform or cruciform-like structure.     

Mutations predetermined by the primary structure of DNA

This study is concerned with an experimental verification of hypotheses postulating the involvement of self-complementary nucleotide sequences in the formation of deletions and insertions. It was suggested that deletions can arise in the regions of self-complementary nucleotide sequences, which allows the formation of the hairpin structures in a single-stranded DNA, arising during excision repair. These hairpin structures can be eliminated by nucleases or during DNA replication. Insertions can arise as a result of homologous recombination, when a migrating DNA strand contains a self-complementary sequence which forms hairpin structure. Model experiments were carried out with the pBR322 plasmid. A plasmid DNA with premutational damage in the palindrome-containing region was constructed by in vitro dimethylsulfate modification of one strand of EcoRI-BamHI restriction fragment. The plasmid was used for transformation of Escherichia coli. Restriction mapping and nucleotide analysis of the mutant DNAs demonstrated that they all contained deletions. The end points of the deletions coincide with the palindrome. To model homologous recombination, a plasmid with D-loop was constructed. A single-stranded DNA fragment containing palindrome forming a hairpin structure was introduced into the plasmid DNA and covalently fixed in the complex. When E. coli cells were transfected with this DNA, plasmid mutants containing insertions predetermined by palindromic structure arose. The evolutionary role of mutations predetermined by primary DNA structure is discussed.     

Palindrome regeneration by template strand-switching mechanism at the origin of DNA replication of porcine circovirus via the rolling-circle melting-pot replication model

Palindromic sequences (inverted repeats) flanking the origin of DNA replication with the potential of forming single-stranded stem-loop cruciform structures have been reported to be essential for replication of the circular genomes of many prokaryotic and eukaryotic systems. In this study, mutant genomes of porcine circovirus with deletions in the origin-flanking palindrome and incapable of forming any cruciform structures invariably yielded progeny viruses containing longer and more stable palindromes. These results suggest that origin-flanking palindromes are essential for termination but not for initiation of DNA replication. Detection of template strand switching in the middle of an inverted repeat strand among the progeny viruses demonstrated that both the minus genome and a corresponding palindromic strand served as templates simultaneously during DNA biosynthesis and supports the recently proposed rolling-circle "melting-pot" replication model. The genome configuration presented by this model, a four-stranded tertiary structure, provides insights into the mechanisms of DNA replication, inverted repeat correction (or conversion), and illegitimate recombination of any circular DNA molecule with an origin-flanking palindrome.     

NMR structure of the mature dimer initiation complex of HIV-1 genomic RNA

The two identical genomic RNA strands inside each HIV-1 viral particle are linked through homodimerization of an RNA stem-loop, termed SL1, near their 5' ends. SL1 first dimerizes through a palindromic sequence in its loop, forming a transient kissing-loop complex which then refolds to a mature, linear duplex. We previously reported the NMR structure of a 23-base truncate of SLI in kissing-dimer form, and here report the high-resolution structure of its linear isoform. This structure comprises three short duplex regions--derived from the central palindrome and two stem regions of each strand, respectively--separated by two bulges that each encompass three unpaired adenines flanking the palindromes. The stacking pattern of these adenines differs from that seen in the kissing-loop complex, and leads to greater colinear base stacking overall. Moreover, the mechanical distortion of the palindrome helix is reduced, and base pairs ruptured during formation of the kissing-loop complex are re-established, so that all potential Watson-Crick pairs are intact. These features together likely account for the greater thermodynamic stability of the mature dimer as compared to its kissing-loop precursor.     

A perfect palindrome in the Escherichia coli chromosome forms DNA hairpins on both leading- and lagging-strands

DNA palindromes are hotspots for DNA double strand breaks, inverted duplications and intra-chromosomal translocations in a wide spectrum of organisms from bacteria to humans. These reactions are mediated by DNA secondary structures such as hairpins and cruciforms. In order to further investigate the pathways of formation and cleavage of these structures, we have compared the processing of a 460 base pair (bp) perfect palindrome in the Escherichia coli chromosome with the same construct interrupted by a 20 bp spacer to form a 480 bp interrupted palindrome. We show here that the perfect palindrome can form hairpin DNA structures on the templates of the leading- and lagging-strands in a replication-dependent reaction. In the presence of the hairpin endonuclease SbcCD, both copies of the replicated chromosome containing the perfect palindrome are cleaved, resulting in the formation of an unrepairable DNA double-strand break and cell death. This contrasts with the interrupted palindrome, which forms a hairpin on the lagging-strand template that is processed to form breaks, which can be repaired by homologous recombination.