Effect of magnesium on cruciform extrusion in supercoiled DNA.

Recently, it was reported that Mg2+greatly facilitates cruciform extrusion in the short palindromes of supercoiled DNA, thereby allowing the formation of cruciform structures in vivo. Because of the potential biological importance of this phenomenon, we undertook a broader study of the effect of Mg2+on a cruciform extrusion in supercoiled DNA. The method of two-dimensional gel electrophoresis was used to detect the cruciform extrusion both in the absence and in the presence of these ions. Our results show that Mg2+shifts the cruciform extrusion in the d(CCC(AT)16GGG) palindrome to a higher, rather than to a lower level of supercoiling. In order to study possible sequence-specific properties of the short palindromes for which the unusual cruciform extrusion in the presence Mg2+was reported, we constructed a plasmid with a longer palindromic region. This region bears the same sequences in the hairpin loops and four-arm junction as the short palindrome, except that the short stems of the hairpins are extended. The extension allowed us to overcome the limitation of our experimental approach which cannot be used for very short palindromes. Our results show that Mg2+also shifts the cruciform extrusion in this palindrome to a higher level of supercoiling. These data suggest that cruciform extrusion in the short palindromes at low supercoiling is highly improbable. We performed a thermodynamic analysis of the effect of Mg2+on cruciform extrusion. The treatment accounted for the effect of Mg2+on both free energy of supercoiling and the free energy of cruciform structure per se. Our analysis showed that although the level of supercoiling required for the cruciform extrusion is not reduced by Mg2+, the ions reduce the free energy of the cruciform structure.     

The Effects of Nucleotide Sequence Changes on DNA Secondary Structure Formation in Escherichia Coli Are Consistent with Cruciform Extrusion in Vivo

The construction in bacteriophage λ of a set of long DNA palindromes with paired changes in the central sequence is described. Identical palindrome centers were previously used by others to test the S-type model for cruciform extrusion in vitro. Long DNA palindromes prevent the propagation of carrier phage λ on a wild-type host, and the sbcC mutation is sufficient to almost fully alleviate this inviability. The plaque areas produced by the palindrome containing phages were compared on an Escherichia coli sbcC lawn. Central sequence changes had a greater effect upon the plaque area than peripheral changes, implying that the residual palindrome-mediated inviability in E. coli sbcC is center-dependent and could be due to the formation of a cruciform structure. The results argue strongly that intrastrand pairing within palindromes is critical in determining their effects in vivo. In addition, the same data suggests that DNA loops in vivo may sometimes contain two bases only.     

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.     

Extrusion of an imperfect palindrome to a cruciform in superhelical DNA: complete determination of energetics using a statistical mechanical model

We present a detailed study of the extrusion of an imperfect palindrome, derived from the terminal regions of vaccinia virus DNA and contained in a superhelical plasmid, into a cruciform containing bulged bases. We monitor the course of extrusion by two-dimensional gel electrophoresis experiments as a function of temperature and linking number. We find that extrusion pauses at partially extruded states as negative superhelicity increases. To understand the course of extrusion with changes in linking number, DeltaLk, we present a rigorous semiempirical statistical mechanical analysis that includes complete coupling between DeltaLk, cruciform extrusion, formation of extrahelical bases, and temperature-dependent denaturation. The imperfections in the palindrome are sequentially incorporated into the cruciform arms as hairpin loops, single unpaired bases, and complex local regions containing several unpaired bases. We analyze the results to determine the free energies, enthalpies and entropies of formation of all local structures involved in extrusion. We find that, for each unpaired structure, the DeltaG, DeltaH and DeltaS of formation are all approximately proportional to the number of unpaired bases contained therein. This surprising result holds regardless of the arrangement or composition of unpaired bases within a particular structure. Imperfections have major effects on the overall energetics of cruciform extrusion and on the course of this transition. In particular, the extent of the DeltaLk change necessary to extrude an imperfect palindrome is considerably greater than that required for extrusion of the underlying perfect palindrome. Our analysis also suggests that, at higher temperatures, significant denaturation at the base of an imperfect cruciform can successfully compete with extension of the cruciform arms.     

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.     

Formation of large palindromic DNA by homologous recombination of short inverted repeat sequences in Saccharomyces cerevisiae

Large DNA palindromes form sporadically in many eukaryotic and prokaryotic genomes and are often associated with amplified genes. The presence of a short inverted repeat sequence near a DNA double-strand break has been implicated in the formation of large palindromes in a variety of organisms. Previously we have established that in Saccharomyces cerevisiae a linear DNA palindrome is efficiently formed from a single-copy circular plasmid when a DNA double-strand break is introduced next to a short inverted repeat sequence. In this study we address whether the linear palindromes form by an intermolecular reaction (that is, a reaction between two identical fragments in a head-to-head arrangement) or by an unusual intramolecular reaction, as it apparently does in other examples of palindrome formation. Our evidence supports a model in which palindromes are primarily formed by an intermolecular reaction involving homologous recombination of short inverted repeat sequences. We have also extended our investigation into the requirement for DNA double-strand break repair genes in palindrome formation. We have found that a deletion of the RAD52 gene significantly reduces palindrome formation by intermolecular recombination and that deletions of two other genes in the RAD52-epistasis group (RAD51 and MRE11) have little or no effect on palindrome formation. In addition, palindrome formation is dramatically reduced by a deletion of the nucleotide excision repair gene RAD1.     

Mus81-dependent double-strand DNA breaks at in vivo-generated cruciform structures in S. cerevisiae

Long DNA palindromes are implicated in chromosomal rearrangement, but their roles in the underlying molecular events remain a matter of conjecture. One notion is that palindromes induce DNA breaks after assuming a cruciform structure, the four-way DNA junction providing a target for cleavage by Holliday junction (HJ)-specific enzymes. Though compelling, few components of the "cruciform resolution" proposal are established. Here we address fundamental properties and genetic dependencies of palindromic DNA metabolism in eukaryotes. Plasmid-borne palindromes introduced into S. cerevisiae are site-specifically broken in vivo, and the breaks exhibit unique hallmarks of an HJ resolvase mechanism. In vivo resolution requires Mus81, for which the bacterial HJ resolvase RusA will substitute. These results provide confirmation of cruciform extrusion and resolution in the context of eukaryotic chromatin. Related observations are that, unchecked by a nuclease function provided by Mre11, episomal palindromes launch a self-perpetuating breakage-fusion-bridge-independent copy number increase termed "escape."     

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.     

An intramolecular recombination mechanism for the formation of the rRNA gene palindrome of Tetrahymena thermophila.

Large palindromic DNAs are found in a wide variety of eukaryotic cells. In Tetrahymena thermophila, a large palindrome is formed from a single rRNA gene (rDNA) during nuclear differentiation. We present evidence that a key step in the formation of the rDNA palindrome of T. thermophila involves homologous intramolecular recombination. Heteroduplex micronuclear rDNA molecules were constructed in vitro and microinjected into developing macronuclei, where they formed palindromes. Analysis of the resulting palindromes indicated that both strands of the microinjected rDNA are used to form the same palindrome. This study, together with a previous study (L. F. Yasuda and M.-C. Yao, Cell 67:505-516, 1991), is the first to define a molecular pathway of palindrome formation. The process is initiated by chromosome breakage at sites flanking the micronuclear rDNA. An intramolecular recombination reaction, guided by a pair of short inverted repeats located at the 5' end of the excised rDNA, covalently joins the two strands of micronuclear rDNA in a giant hairpin molecule. Bidirectional DNA replication converts the giant hairpin molecule to a palindrome. We suggest that the general features of this pathway are applicable to palindrome formation in other cell types.     

Palindrome resolution and recombination in the mammalian germ line.

Genetic instability is promoted by unusual sequence arrangements and DNA structures. Hairpin DNA structures can form from palindromes and from triplet repeats, and they are also intermediates in V(D)J recombination. We have measured the genetic stability of a large palindrome which has the potential to form a one-stranded hairpin or a two-stranded cruciform structure and have analyzed recombinants at the molecular level. A palindrome of 15.3 kb introduced as a transgene was found to be transmitted at a normal Mendelian ratio in mice, in striking contrast to the profound instability of large palindromes in prokaryotic systems. In a significant number of progeny mice, however, the palindromic transgene is rearranged; between 15 and 56% of progeny contain rearrangements. Rearrangements within the palindromic repeat occur both by illegitimate and homologous, reciprocal recombination. Gene conversion within the transgene locus, as quantitated by a novel sperm fluorescence assay, is also elevated. Illegitimate events often take the form of an asymmetric deletion that eliminates the central symmetry of the palindrome. Such asymmetric transgene deletions, including those that maintain one complete half of the palindromic repeat, are stabilized so that they cannot undergo further illegitimate rearrangements, and they also exhibit reduced levels of gene conversion. By contrast, transgene rearrangements that maintain the central symmetry continue to be unstable. Based on the observed events, we propose that one mechanism promoting the instability of the palindrome may involve breaks generated at the hairpin structure by a hairpin-nicking activity, as previously detected in somatic cells. Because mammalian cells are capable of efficiently repairing chromosome breaks through nonhomologous processes, the resealing of such breaks introduces a stabilizing asymmetry at the center of the palindrome. We propose that the ability of mammalian cells to eliminate the perfect symmetry in a palindromic sequence may be an important DNA repair pathway, with implications regarding the metabolism of palindromic repeats, the mutability of quasipalindromic triplet repeats, and the early steps in gene amplification events.     

Myc oncogene-induced genomic instability: DNA palindromes in bursal lymphomagenesis

Genetic instability plays a key role in the formation of naturally occurring cancer. The formation of long DNA palindromes is a rate-limiting step in gene amplification, a common form of tumor-associated genetic instability. Genome-wide analysis of palindrome formation (GAPF) has detected both extensive palindrome formation and gene amplification, beginning early in tumorigenesis, in an experimental Myc-induced model tumor system in the chicken bursa of Fabricius. We determined that GAPF-detected palindromes are abundant and distributed nonrandomly throughout the genome of bursal lymphoma cells, frequently at preexisting short inverted repeats. By combining GAPF with chromatin immunoprecipitation (ChIP), we found a significant association between occupancy of gene-proximal Myc binding sites and the formation of palindromes. Numbers of palindromic loci correlate with increases in both levels of Myc over-expression and ChIP-detected occupancy of Myc binding sites in bursal cells. However, clonal analysis of chick DF-1 fibroblasts suggests that palindrome formation is a stochastic process occurring in individual cells at a small number of loci relative to much larger numbers of susceptible loci in the cell population and that the induction of palindromes is not involved in Myc-induced acute fibroblast transformation. GAPF-detected palindromes at the highly oncogenic bic/miR-155 locus in all of our preneoplastic and neoplastic bursal samples, but not in DNA from normal and other transformed cell types. This finding indicates very strong selection during bursal lymphomagenesis. Therefore, in addition to providing a platform for gene copy number change, palindromes may alter microRNA genes in a fashion that can contribute to cancer development.     

Size-dependent palindrome-induced intrachromosomal recombination in yeast

Palindromic and quasi-palindromic sequences are important DNA motifs found in various cis-acting genetic elements, but are also known to provoke different types of genetic alterations. The instability of such motifs is clearly size-related and depends on their potential to adopt secondary structures known as hairpins and cruciforms. Here we studied the influence of palindrome size on recombination between two directly repeated copies of the yeast CYC1 gene leading to the loss of the intervening sequence (“pop-out” recombination). We show that palindromes inserted either within one copy or between the two copies of the CYC1 gene become recombinogenic only when they attain a certain critical size and we estimate this critical size to be about 70 bp. With the longest palindrome used in this study (150 bp) we observed a more than 20-fold increase in the pop-out recombination. In the sae2/com1 mutant the palindrome-stimulated recombination was completely abolished. Suppression of palindrome recombinogenicity may be crucial for the maintenance of genetic stability in organisms containing a significant number of large palindromes in their genomes, like humans.     

A 160-bp palindrome is a Rad50.Rad32-dependent mitotic recombination hotspot in Schizosaccharomyces pombe

Palindromic sequences can form hairpin and cruciform structures that pose a threat to genome integrity. We found that a 160-bp palindrome (an inverted repeat of 80 bp) conferred a mitotic recombination hotspot relative to a control nonpalindromic sequence when inserted into the ade6 gene of Schizosaccharomyces pombe. The hotspot activity of the palindrome, but not the basal level of recombination, was abolished by a rad50 deletion, by a rad50S "separation of function" mutation, or by a rad32-D25A mutation in the nuclease domain of the Rad32 protein, an Mre11 homolog. We propose that upon extrusion of the palindrome the Rad50.Rad32 nuclease complex recognizes and cleaves the secondary structure thus formed and generates a recombinogenic break in the DNA.     

Compositional Bias is a Major Determinant of the Distribution Pattern and Abundance of Palindromes in Drosophila melanogaster

Palindromic sequences are important DNA motifs related to gene regulation, DNA replication and recombination, and thus, investigating the evolutionary forces shaping the distribution pattern and abundance of palindromes in the genome is substantially important. In this article, we analyzed the abundance of palindromes in the genome, and then explored the possible effects of several genomic factors on the palindrome distribution and abundance in Drosophila melanogaster. Our results show that the palindrome abundance in D. melanogaster deviates from random expectation and the uneven distribution of palindromes across the genome is associated with local GC content, recombination rate, and coding exon density. Our data suggest that base composition is the major determinant of the distribution pattern and abundance of palindromes and the correlation between palindrome density and recombination is a side-product of the effect of compositional bias on the palindrome abundance.     

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.     

回文序列诱导突变的机制及人类相关疾病

在原核和真核生物基因组中, 含有回文序列的区域高度可变且稳定性差, 主要原因是回文序列能形成发卡或十字形二级结构, 然后通过滑动错配、单链复性以及非同源末端连接(Non-homologous end joining, NHEJ)等机制导致缺失突变或染色体易位的发生。在人类基因组中, 回文序列较普遍存在于基因表达调控的重要作用元件中, 它诱导的缺失和易位突变还与男性不育、地中海贫血等多种疾病的发生、发展密切相关。文章综合近几年国内外相关文献, 初步阐释回文序列诱导突变的类型和可能机制, 及其与人类疾病的关系, 为进一步探讨回文序列在基因表达调控、基因突变及人类疾病中的作用及功能等相关研究提供参考。     

A novel recombination pathway initiated by the Mre11/Rad50/Nbs1 complex eliminates palindromes during meiosis in Schizosaccharomyces pombe

DNA palindromes are rare in humans but are associated with meiosis-specific translocations. The conserved Mre11/Rad50/Nbs1 (MRN) complex is likely directly involved in processing palindromes through the homologous recombination pathway of DNA repair. Using the fission yeast Schizosaccharomyces pombe as a model system, we show that a 160-bp palindrome (M-pal) is a meiotic recombination hotspot and is preferentially eliminated by gene conversion. Importantly, this hotspot depends on the MRN complex for full activity and reveals a new pathway for generating meiotic DNA double-strand breaks (DSBs), separately from the Rec12 (ortholog of Spo11) pathway. We show that MRN-dependent DSBs are formed at or near the M-pal in vivo, and in contrast to the Rec12-dependent breaks, they appear early, during premeiotic replication. Analysis of mrn mutants indicates that the early DSBs are generated by the MRN nuclease activity, demonstrating the previously hypothesized MRN-dependent breakage of hairpins during replication. Our studies provide a genetic and physical basis for frequent translocations between palindromes in human meiosis and identify a conserved meiotic process that constantly selects against palindromes in eukaryotic genomes.     

Short inverted repeats at a free end signal large palindromic DNA formation in Tetrahymena

Large palindromic DNAs are formed in many cell types, but their molecular mechanism is unknown. During nuclear differentiation in Tetrahymena, the ribosomal RNA genes (rDNA) are converted from a single integrated copy to an extrachromosomal head-to-head palindrome. Using in vitro mutagenesis and Tetrahymena transformation, we show that two properties of the rDNA are necessary and sufficient for palindrome formation. The first is a pair of 42 bp inverted repeats found at the rDNA's 5' end. Its inverted symmetry, but not specific sequence, is important. The second is a free end next to the repeats. It is normally created by chromosome breakage in vivo, but can also be provided by restriction endonuclease cutting before transformation. We also demonstrate that the ability to form palindromes is not restricted to developing nuclei, but is present in vegetative cells as well. This process may represent a general mechanism for palindrome formation in eukaryotes.     

Palindromes and genomic stress fractures: bracing and repairing the damage

DNA palindromes are a source of instability in eukaryotic genomes but remain under-investigated because they are difficult to study. Nonetheless, progress in the last year or so has begun to form a coherent picture of how DNA palindromes cause damage in eukaryotes and how this damage is opposed by cellular mechanisms. In yeast, the features of double strand DNA interruptions that appear at palindromic sites in vivo suggest that a resolvase-type activity creates the fractures by attacking a palindrome after it extrudes into a cruciform structure. Induction of DNA breaks in this fashion could be deterred through a Center-Break palindrome revision process as investigated in detail in mice. The MRX/MRN likely plays a pivotal role in prevention of palindrome-induced genome damage in eukaryotes.     

Palindromic sequences are associated with sites of DNA breakage during gene conversion.

Gene conversion is a recombinatorial mechanism which transfers genetic information from a donor into a recipient gene. A case of gene conversion between immunoglobulin VH region genes was analysed and palindromic sequences were found to be located near to the left recombinatorial breakpoint, which also is flanked by a direct repeat sequence. We performed a computer search for palindromes and direct repeats in the published sequences of eucaryotic genes which had been involved in gene conversion. In these sequences, the palindrome with the best or second best quality is located near to a breakpoint of recombination. A correlation of recombination breakpoints with direct repeats was not observed. This suggests that gene conversion is promoted by palindromic sequences.