Identification of nuclear proteins that specifically interact with adeno-associated virus type 2 inverted terminal repeat hairpin DNA.

A palindromic hairpin duplex containing the inverted terminal repeat sequence of adeno-associated virus type 2 (AAV) DNA was used as a substrate in gel retardation assays to detect putative proteins that specifically interact with the AAV hairpin DNA structures. Nuclear proteins were detected in extracts prepared from human KB cells coinfected with AAV and adenovirus type 2 that interacted with the hairpin duplex but not in nuclear extracts prepared from uninfected, AAV-infected, or adenovirus type 2-infected KB cells. The binding was specific for the hairpin duplex, since no binding occurred with a double-stranded DNA duplex with the identical nucleotide sequence. Furthermore, in competition experiments, the binding could be reduced with increasing concentrations of the hairpin duplex but not with the double-stranded duplex DNA with the identical nucleotide sequence. S1 nuclease assays revealed that the binding was sensitive to digestion with the enzyme, whereas the protein-bound hairpin duplex was resistant to digestion with S1 nuclease. The nucleotide sequence involved in the protein binding was localized within the inverted terminal repeat of the AAV genome by methylation interference assays. These nuclear proteins may be likely candidates for the pivotal enzyme nickase required for replication or resolution (or both) of single-stranded palindromic hairpin termini of the AAV genome.     

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.     

Resolution of linear minichromosomes with hairpin ends from circular plasmids containing vaccinia virus concatemer junctions

The junctions, separating unit-length genomes in intracellular concatemeric forms of vaccinia virus DNA, are duplex copies of the hairpin loops that form the ends of mature DNA molecules present in infectious virus particles. Circular E. coli plasmids with palindromic junction fragments were replicated in vaccinia virus-infected cells and resolved into linear minichromosomes with vector DNA in the center and vaccinia virus DNA hairpins at the two ends. Resolution did not occur when the concatemer joint was less than 250 bp or when plasmids were transfected into uninfected cells, indicating requirements for a specific DNA structure and viral trans-acting factors. These studies indicate that concatemers can serve as replicative intermediates and account for the generation of flip-flop sequence variation of the hairpins at the ends of the mature vaccinia virus genome.     

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.     

Efficient resolution of replicated poxvirus telomeres to native hairpin structures requires two inverted symmetrical copies of a core target DNA sequence.

The terminal hairpin sequences of the linear double-stranded DNA genome of the leporipoxvirus Shope fibroma virus (SFV) has been cloned in Saccharomyces cerevisiae and in recombination-deficient Escherichia coli as a palindromic insert within circular plasmid vectors. This sequence configuration is equivalent to the inverted repeat structure detected as a telomeric replicative intermediate during poxvirus replication in vivo. Previously, it has been shown that when circular plasmids containing this palindromic insert were transfected into SFV-infected cells, efficient replication and resolution generated linear minichromosomes with bona fide viral hairpin termini (A. M. DeLange, M. Reddy, D. Scraba, C. Upton, and G. McFadden, J. Virol. 59:249-259, 1986). To localize the minimal target DNA sequence required for efficient resolution, a series of staggered unidirectional deletions were constructed at both ends of the inverted repeat. Analyses of the resolution efficiencies of the various clones indicate that up to 240 base pairs (bp) centered at the symmetry axis were required for maximal resolution to minichromosomes. To investigate the role of the AT-rich central axis sequences, which in SFV include 8 nonpalindromic bp, a unique AflII site at the symmetry axis was exploited. Bidirectional deletions extending from this AflII site and insertions of synthetic oligonucleotides into one of the deletion derivatives were constructed and tested in vivo. The efficiency with which these plasmids resolved to linear minichromosomes with hairpin termini has enabled us to define the minimal target DNA sequence as two inverted copies of an identical DNA sequence between 58 and 76 bp in length. The nonpalindromic nucleotides, which, after resolution, constitute the extrahelical residues characteristic of native poxviral telomeres, were not required for resolution. The close resemblance of the SFV core target sequence to the analogous region from the orthopoxvirus vaccinia virus is consistent with a conserved mechanism for poxviral telomere resolution.     

Repair by recombination of DNA containing a palindromic sequence

We report here that homologous recombination functions are required for the viability of Escherichia coli cells maintaining a 240 bp chromosomal inverted repeat (palindromic) sequence. Wild-type cells can successfully replicate this palindrome but recA , recB or recC mutants carrying the palindrome are unviable. The dependence on homologous recombination for cell viability is overcome in sbcC mutants. Directly repeated copies of the DNA containing the palindrome are rapidly resolved to single copies in wild-type cells but not in sbcC mutants. Our results suggest that double-strand breaks introduced at the palindromic DNA sequence by the SbcCD nuclease are repaired by homologous recombination. The repair is conservative and the palindrome is retained in the repaired chromosome. We conclude that SbcCD can attack secondary structures but that repair conserves the DNA sequence with the potential to fold.     

Mutational analysis of the resolution sequence of vaccinia virus DNA: essential sequence consists of two separate AT-rich regions highly conserved among poxviruses.

In replicative forms of vaccinia virus DNA, the unit genomes are connected by palindromic junction fragments that are resolved into mature viral genomes with hairpin termini. Bacterial plasmids containing the junction fragment for vaccinia virus or Shope fibroma virus were converted into linear minichromosomes of vector sequence flanked by poxvirus hairpin loops after transfection into infected cells. Analysis of a series of symmetrical deletion mutations demonstrated that in vaccinia virus the presence of the DNA sequence ATTTAGTGTCTAGAAAAAAA on both sides of the apical segment of the concatemer junction is crucial for resolution. To determine the precise architecture of the resolution site, a series of site-directed mutations within this tract of nucleotides were made and the relative contribution of each nucleotide to the efficaciousness of resolution was determined. The nucleotide sequence necessary for the resolution of the vaccinia virus concatemer junction, (A/T)TTT(A/G)N7-9AAAAAAA, is highly conserved among poxviruses and found proximal to the hairpin loop in the genomes of members of the Leporipoxvirus, Avipoxvirus, and Capripoxvirus genera.     

Hairpin structures in synthetic oligodeoxynucleotides: sequence effects on the duplex-to-hairpin transition

We have synthesized and examined a number of fully and partly self-complementary palindromic oligodeoxynucleotides for their ability to assume in solution a unimolecular hairpin structure. The main results obtained by a combined optical and electrophoresis investigation show that: (i) DNA folding needs not be driven by mismatched base pairings over the dyad; fully self-complementary palindromic duplexes, comprising regular (CG)n DNA fragments, possess a considerable intrinsic propensity to make intramolecular base pairings; (ii) The duplex-hairpin interconversion is, in general, a slow process independent of the length and base composition of the palindrome; (iii) The palindromic sequences energetically least favored to form hairpin structures consist of C:G base pairs around the dyad axis and of T:A blocks in the arms of the inverted repeat; (IV) The base composition of the stem strongly influences the hairpin thermal stability. For instance, the substitution of one C:G with one A:T base pair in the stem helix of d(CG)7 diminishes the stability of the hairpin by 9 degrees C. It is found that the stability of the stem helix, in hairpins of defined sequence and with the same loop length, decreases in the order alternating-CG greater than homo-CG greater than AC(GT) greater than alternating-AT, i.e. as in polynucleotides. The thermodynamic parameters for the hairpin-coil transition are reported.     

The promiscuity of heterospecific lox sites increases dramatically in the presence of palindromic DNA

Heterospecific lox sites are mutated lox sites that in the presence of Cre recombinase recombine with themselves but not or much less with wildtype loxP. We here show that in Escherichia coli both lox511 and lox2272 sites become highly promiscuous with respect to loxP when in the presence of Cre one of the recombination partners is present in a larger stretch of an inverted repeat of non-lox DNA. In such a palindromic DNA configuration, also the occurrence of other DNA repeat-mediated recombination events is somewhat increased in the presence of Cre. The results indicate that in recombinase mediated cassette exchange or other double lox applications based on the exclusivity of heterospecific lox sites, or in research combining Cre-lox approaches with hairpin RNA for gene silencing, the presence of duplicated DNA around lox sites has to be taken into account. It is proposed that the presence of palindromic non-lox DNA interferes with the homology search of the Cre enzyme prior to the actual recombination event.     

The role of palindromic and non-palindromic sequences in arresting DNA synthesis in vitro and in vivo

The nature of specific DNA sequences that arrest synthesis by mammalian DNA polymerase alpha in vitro was analyzed using circular, single-stranded M13 or phi X174 virion DNA templates annealed to a unique, terminally labeled, DNA primer. This method rigorously defined both the starting nucleotide position and the direction of synthesis, as well as making the amount of radioactivity proportional to the number rather than the length of nascent DNA chains. The precise nucleotide locations of arrest sites were determined over templates with complementary sequences by cloning unique DNA restriction fragments into M13 DNA and isolating virions containing either the Watson or Crick strand. Results were correlated with the locations of palindromic (self-complementary) sequences, repeated sequences, and repeated sequences with mirror-image orientation. Two classes of DNA synthesis arrest sites were identified, distinct in structure but equivalent in activity. Class I sites consisted of palindromic sequences that formed a stable hairpin structure in solution and arrested DNA polymerase on both complementary templates. The polymerase stopped precisely at the base of the duplex DNA stem, regardless of the direction from which the enzyme approached. Class II sites consisted of non-palindromic sequences that could not be explained by either secondary structure or sequence symmetry elements, and whose complementary sequence was not an arrest site. Size limits, orientation and some sequence specificity for arrest sites were suggested by the data. Arrest sites were also observed in vivo by mapping the locations of 3'-end-labeled nascent simian virus 40 DNA strands throughout the genome. Arrest sites closest to the region where termination of replication occurs were most pronounced, and the locations of 80% of the most prominent sites appeared to be recognized by alpha-polymerase on the same template in vitro. However, class I sites were not identified in vivo, suggesting that palindromic sequences do not form hairpin structures at replication forks.     

Genes for 7S RNAs can replace the gene for 4.5S RNA in growth of Escherichia coli.

4.5S RNAs of eubacteria and 7S RNAs of archaebacteria and eukaryotes exist in a hairpin conformation. The apex of this hairpin displays structural and sequence similarities among both 4.5S and 7S RNAs. Furthermore, a hyphenated sequence of 16 nucleotides is conserved in all eubacterial 4.5S RNAs examined. In this article I report that 7S RNAs that contain this 16-nucleotide sequence are able to replace 4.5S RNAs and permit growth of Escherichia coli.     

Nucleotide sequence required for resolution of the concatemer junction of vaccinia virus DNA.

The mature form of the vaccinia virus genome consists of a linear, 185,000-base-pair (bp) DNA molecule with a 10,000-bp inverted terminal repetition and incompletely base-paired 104-nucleotide hairpin loops connecting the two strands at each end. In concatemeric forms of intracellular vaccinia virus DNA, the inverted terminal repetitions of adjacent genomes form an imperfect palindrome. The apex of this palindrome corresponds in sequence to the double-stranded form of the hairpin loop. Circular plasmids containing palindromic concatemer junction fragments of 250 bp or longer are converted into linear minichromosomes with hairpin ends when they are transfected into vaccinia virus-infected cells, providing a model system with which to study the resolution process. To distinguish between sequence-specific and structural requirements for resolution, plasmids with symmetrical insertions, deletions, and oligonucleotide-directed mutations within the concatemer junction were constructed. A sequence (ATTTAGTGTCTAGAAAAAAA) located on both sides of the apex segment was found to be critical for resolution. Resolution was more efficient when additional nucleotides, TGTG, followed the run of A residues. Both the location and sequence of the proposed resolution signal are highly conserved among poxviruses.     

Analysis of the kinetic hairpin transfer model for parvoviral DNA replication

All linear DNA molecules face special problems in replicating their 5' ends, as DNA polymerases add nucleotides only to pre-existing strands with free 3'-OH groups. Parvoviruses, a group of small animal viruses with a linear single-stranded DNA genome, cope with this problem by having palindromic terminal sequences that can fold back on themselves to form hairpin structures essential in priming DNA replication. The 3' terminal sequence that initiates replication becomes reversed in orientation during the process, and if the palindrome is imperfect, two different, reverse-complementary terminal sequences are generated. The relative abundances of the terminal sequence orientations at each end of the DNA molecules can be measured and give information about the replication process. From such clues, we developed a "kinetic hairpin transfer model" based on differential rates of hairpin formation and inversion processes depending on the conformations of the 3' termini. Numerical studies showed that this simple idea can account for the diverse pattern of DNA distributions observed in the family Parvoviridae. In this paper, we simplify the model to a set of coupled linear first-order ordinary differential equations in order to delineate its essential properties by Perron-Frobenius theory. Secondly, we examine our assumption of linear kinetics by modeling enzyme catalysis of the component steps of the hairpin transfer process. We show that the rate-determining step of the process is the binding of initiation complex to the self-priming hairpin structures. Furthermore, we find that if the replication machinery is saturated by DNA substrate late in an infection, the differential equations become non-linear but the steady-state DNA distribution is still given by the solution of our original linear equations.     

A 140-Bp-Long Palindromic Sequence Induces Double-Strand Breaks during Meiosis in the Yeast Saccharomyces Cerevisiae

Palindromic sequences have the potential to form hairpin or cruciform structures, which are putative substrates for several nucleases and mismatch repair enzymes. A genetic method was developed to detect such structures in vivo in the yeast Saccharomyces cerevisiae. Using this method we previously showed that short hairpin structures are poorly repaired by the mismatch repair system in S. cerevisiae. We show here that mismatches, when present in the stem of the hairpin structure, are not processed by the repair machinery, suggesting that they are treated differently than those in the interstrand base-paired duplex DNA. A 140-bp-long palindromic sequence, on the contrary, acts as a meiotic recombination hotspot by generating a site for a double-strand break, an initiator of meiotic recombination. We suggest that long palindromic sequences undergo cruciform extrusion more readily than short ones. This cruciform structure then acts as a substrate for structure-specific nucleases resulting in the formation of a double-strand break during meiosis in yeast. In addition, we show that residual repair of the short hairpin structure occurs in an MSH2-independent pathway.     

An Enzyme-Catalyzed Multistep DNA Refolding Mechanism in Hairpin Telomere Formation

Hairpin telomeres of bacterial linear chromosomes are generated by a DNA cutting–rejoining enzyme protelomerase. Protelomerase resolves a concatenated dimer of chromosomes as the last step of chromosome replication, converting a palindromic DNA sequence at the junctions between chromosomes into covalently closed hairpins. The mechanism by which protelomerase transforms a duplex DNA substrate into the hairpin telomeres remains largely unknown. We report here a series of crystal structures of the protelomerase TelA bound to DNA that represent distinct stages along the reaction pathway. The structures suggest that TelA converts a linear duplex substrate into hairpin turns via a transient strand-refolding intermediate that involves DNA-base flipping and wobble base-pairs. The extremely compact di-nucleotide hairpin structure of the product is fully stabilized by TelA prior to strand ligation, which drives the reaction to completion. The enzyme-catalyzed, multistep strand refolding is a novel mechanism in DNA rearrangement reactions.     

Elongation of palindromic repetitive DNA by DNA polymerase from hyperthermophilic archaea: a mechanism of DNA elongation and diversification

DNA polymerase from hyperthermophilic bacteria can elongate tandem repetitive oligoDNA with a complete or incomplete palindromic sequence under isothermal conditions by "hairpin elongation". However, the product of the reaction has not yet been sufficiently characterized. Here, I demonstrate that when palindromic repetitive oligoDNA, e.g., (5'AGATATCT3')(6), was added as a "seed" to the DNA synthesis reaction catalyzed by DNA polymerase from the archaea Thermococcus litoralis (Vent polymerase) at 74 degrees C, the product was (5'AGATATCT3')(n). The product itself was palindromic and repetitive, and its motif (unit) sequence was exactly the same as that of the seed oligoDNA. On the other hand, when a pseudopalindrome, which contains a palindrome-breaking nucleotide (underlined), was present in seed oligoDNA, e.g., (5'GATTC3')(6), the product was (5'GATATC3')(n), which had a different motif sequence from that of the seed oligoDNA. When a pseudopalindrome (5'AGATATCA3')(6) was added to the reaction, the products were 5'TATCA . (AGATATCA)(3) . AGATATCT . (TGATATCT)(5) . TGATA3', etc. When 5'AGATATCA . (AGATATCT3')(5) was added, products were 5'TATCT . (AGATATCT)(2).TGATATCT . AGATATCT . AGATATCA . AGATATCT . AGA3', etc., demonstrating the generation of many "mutations" in the product DNA. I conclude that a tandem repetitive sequence is faithfully elongated (amplified) by hyperthermophilic DNA polymerase if it is completely palindromic, but is elongated with many errors if it is incompletely palindromic (pseudopalindromic) or mixed with a pseudopalindrome. The results suggest a protein-catalyzed elongation/diversification mechanism of short repetitive DNAs on the early earth.