Formation of base triplets by non-Watson-Crick bonds mediates homologous recognition in RecA recombination filaments

Intrastrand triplex DNA repeats in bacteria: a source of genomic instability

Repetitive nucleic acid sequences are often prone to form secondary structures distinct from B-DNA. Prominent examples of such structures are DNA triplexes. We observed that certain intrastrand triplex motifs are highly conserved and abundant in prokaryotic genomes. A systematic search of 5246 different prokaryotic plasmids and genomes for intrastrand triplex motifs was conducted and the results summarized in the ITxF database available online at http://bioinformatics.uni-konstanz.de/utils/ITxF/. Next we investigated biophysical and biochemical properties of a particular G/C-rich triplex motif (TM) that occurs in many copies in more than 260 bacterial genomes by CD and nuclear magnetic resonance spectroscopy as well as in vivo footprinting techniques. A characterization of putative properties and functions of these unusually frequent nucleic acid motifs demonstrated that the occurrence of the TM is associated with a high degree of genomic instability. TM-containing genomic loci are significantly more rearranged among closely related Escherichia coli strains compared to control sites. In addition, we found very high frequencies of TM motifs in certain Enterobacteria and Cyanobacteria that were previously described as genetically highly diverse. In conclusion we link intrastrand triplex motifs with the induction of genomic instability. We speculate that the observed instability might be an adaptive feature of these genomes that creates variation for natural selection to act upon.

High fidelity of RecA-catalyzed recombination: a watchdog of genetic diversity

Homologous recombination plays a key role in generating genetic diversity, while maintaining protein functionality. The mechanisms by which RecA enables a single-stranded segment of DNA to recognize a homologous tract within a whole genome are poorly understood. The scale by which homology recognition takes place is of a few tens of base pairs, after which the quest for homology is over. To study the mechanism of homology recognition, RecA-promoted homologous recombination between short DNA oligomers with different degrees of heterology was studied in vitro, using fluorescence resonant energy transfer. RecA can detect single mismatches at the initial stages of recombination, and the efficiency of recombination is strongly dependent on the location and distribution of mismatches. Mismatches near the 5′ end of the incoming strand have a minute effect, whereas mismatches near the 3′ end hinder strand exchange dramatically. There is a characteristic DNA length above which the sensitivity to heterology decreases sharply. Experiments with competitor sequences with varying degrees of homology yield information about the process of homology search and synapse lifetime. The exquisite sensitivity to mismatches and the directionality in the exchange process support a mechanism for homology recognition that can be modeled as a kinetic proofreading cascade.

A RecA-mediated exon profiling method

We have developed a RecA-mediated simple, rapid and scalable method for identifying novel alternatively spliced full-length cDNA candidates. This method is based on the principle that RecA proteins allow to carry radioisotope-labeled probe DNAs to their homologous sequences, resulting in forming triplexes. The resulting complex is easily detected by mobility difference on electrophoresis. We applied this exon profiling method to four selected mouse genes as a feasibility study. To design probes for detection, the information on known exonic regions was extracted from public database, RefSeq. Concerning the potentially transcribed novel exonic regions, RNA mapping experiment using Affymetrix tiling array was performed. As a result, we were able to identify alternative splice variants of Thioredoxin domain containing 5, Interleukin1β, Interleukin 1 family 6 and glutamine-rich hypothetical protein. In addition, full-length sequencing demonstrated that our method could profile exon structures with >90% accuracy. This reliable method can allow us to screen novel splice variants from a huge number of cDNA clone set effectively.

Non-B DNA structure-induced genetic instability

Repetitive DNA sequences are abundant in eukaryotic genomes, and many of these sequences have the potential to adopt non-B DNA conformations. Genes harboring non-B DNA structure-forming sequences increase the risk of genetic instability and thus are associated with human diseases. In this review, we discuss putative mechanisms responsible for genetic instability events occurring at these non-B DNA structures, with a focus on hairpins, left-handed Z-DNA, and intramolecular triplexes or H-DNA. Slippage and misalignment are the most common events leading to DNA structure-induced mutagenesis. However, a number of other mechanisms of genetic instability have been proposed based on the finding that these structures not only induce expansions and deletions, but can also induce DNA strand breaks and rearrangements. The available data implicate a variety of proteins, such as mismatch repair proteins, nucleotide excision repair proteins, topoisomerases, and structure specific-nucleases in the processing of these mutagenic DNA structures. The potential mechanisms of genetic instability induced by these structures and their contribution to human diseases are discussed.

Interarm interaction of DNA cruciform forming at a short inverted repeat sequence

A novel interarm interaction of DNA cruciform forming at inverted repeat sequence was characterized using an S1 nuclease digestion, permanganate oxidation, and microscopic imaging. An inverted repeat consisting of 17 bp complementary sequences was isolated from the bluegill sunfish Lepomis macrochirus (Perciformes) and subcloned into the pUC19 plasmid, after which the supercoiled recombinant plasmid was subjected to enzymatic and chemical modification. In high salt conditions (200 mM NaCl, or 100-200 mM KCl), S1 nuclease cut supercoiled DNA at the center of palindromic symmetry, suggesting the formation of DNA cruciform. On the other hand, S1 nuclease in the presence of 150 mM NaCl or less cleaved mainly the 3'-half of the repeat, thereby forming an unusual structure in which the 3'-half of the inverted repeat, but not the 5'-half, was retained as an unpaired strand. Permanganate oxidation profiles also supported the presence of single-stranded part in the 3'-half of the inverted repeat in addition to the center of the symmetry. Both electron microscopy and atomic force microscopy have detected a thick protrusion on the supercoiled DNA harboring the inverted repeat. We hypothesize that the cruciform hairpins at conditions favoring triplex formation adopt a parallel side-by-side orientation of the arms allowing the interaction between them supposedly stabilized by hydrogen bonding of base triads.

In vitro selection of DNA aptamers against the HIV-1 TAR RNA hairpin

In vitro selection was performed to identify DNA aptamers against the TAR RNA stem-loop structure of HIV-1. A counterselection step allowed the elimination of kissing complex-forming aptamers previously selected (Boiziau et al. J. Biol. Chem. 1999; 274:12730). This led to the emergence of oligonucleotides, most of which contained two consensus sequences, one targeted to the stem 3'-strand (5'-CCCTAGTTA) and the other complementary to the TAR apical loop (5'-CTCCC). The best aptamer could be shortened to a 19-mer oligonucleotide, characterized by a dissociation constant of 50 nM. A 16-mer oligonucleotide complementary to the TAR stem 3'-strand could also be derived from the identified aptamers, with an equal affinity (Kd = 50 nM). Experiments performed to elucidate the interaction between TAR and the aptamers (UV melting measures, enzymatic and chemical footprints) demonstrated that the TAR stem 5'-strand was not simply displaced as a result of the complex formation but unexpectedly remained associated on contact with the antisense oligonucleotide. We suggest that a multistranded structure could be formed.

DNA exhibits multi-stranded binding recognition on glass microarrays

In the course of exploring the hybridization properties of glass DNA microarrays, multi-stranded DNA structures were observed that could not be accounted for by classical Watson-Crick base pairing. Non-denatured double-stranded DNA array elements were shown to hybridize to single-stranded (ss)DNA probes. Similarly, ssDNA array elements were shown to bind duplex DNA probes. This led to a series of experiments demonstrating the formation of multi-stranded DNA structures on the surface of microarrays. These structures were observed with a number of heterogeneous sequences, including both purine and pyrimidine bases, with shared sequence identity between the ssDNA and one of the duplex strands. Furthermore, we observed a strong binding preference near the ends of duplexes containing a 3'-homologous strand. We suggest that such binding interactions on cationic solid surfaces could serve as a model for a number of biological processes mediated through multi-stranded DNA.

Evidence for a DNA triplex in a recombination-like motif: I. Recognition of Watson-Crick base pairs by natural bases in a high-stability triplex

Data are presented on a triplex type with two parallel homologous strands for which triplex formation is almost as strong as duplex formation at least for some sequences and even at pH 7 and 0.2 M NaCl. The evidence mainly rests upon comparing thermodynamic properties of similar systems. A paperclip oligonucleotide d(A12C4T12C4A12) with two linkers C4 obviously can form a triplex with parallel back-folded adenine strand regions, because the single melting transition of this complex splits in two transitions by introducing mismatches only in the third strand region. Respectively, a hairpin duplex d(A12C4T12) and a single strand d(A12) form a triplex as a 1:1 complex in which the second adenine strand is parallel oriented to the homologous one in the Watson-Crick paired duplex. In this system the melting temperature T(m) of the triplex is practically the same as that of the duplex d(A12)-d(T12), at least within a complex concentration range of 0.2-4.0 microM. The melting behaviour of complexes between triplex stabilizing ligand BePI and the system hairpin duplex plus single strand supports the triplex model. Non-denaturing gel electrophoresis suggests the existence of a triplex for a system in which five of the twelve A-T*A base triads are substituted by C-G*C base triads. The recognition between any substituted Watson-Crick base pair (X-Y) in the hairpin duplex d(A4XA7C4T7YT4) and the correspondingly replaced base (Z) in the third strand d(A4ZA7) is mutually selective. All triplexes with matching base substitutions (Z = X) have nearly the same stability (T(m) values from 29 to 33.5 degrees C), whereas triplexes with non-matching substitutions (Z not equal X) show a clearly reduced stability (T(m) values from 15 to 22 degrees C) at 2microM equimolar oligonucleotide concentration. Most nucleic acid triple helices hitherto known are limited to homopurine-homopyrimidine sequences in the target duplex. A stable triplex formation is demonstrated for inhomogeneous sequences tolerating at least 50% pyrimidine content in the homologous strands. On the basis of the surprisingly similar thermodynamic parameters for duplex and triplex, and of the fact that this triplex type seems to be more stable than many other natural DNA triplexes known, and on the basis of semiempirical and molecule mechanical calculations, we postulate bridging interactions of the third strand with the two other strands in the triplex according to the recombination motif. This triplex, denoted by us 'recombination-like form', tolerates heterogeneous base sequences.

Correction of chromosomal point mutations in human cells with bifunctional oligonucleotides

A sequence-specific genomic delivery system for the correction of chromosomal mutations was designed by incorporating two different binding domains into a single-stranded oligonucleotide. A repair domain (RD) contained the native sequence of the target region. A third strand-forming domain (TFD) was designed to form a triplex by Hoogsteen interactions. The design was based upon the premise that the RD will rapidly form a heteroduplex that is anchored synergistically by the TFD. Deoxyoligonucleotides were designed to form triplexes in the human adenosine deaminase (ADA) and p53 genes adjacent to known point mutations. Transfection of ADA-deficient human lymphocytes corrected the mutant sequence in 1-2% of cells. Neither the RD or TFD individually corrected the mutation. Transfection of p53 mutant human glioblastoma cells corrected the mutation and induced apoptosis in 7.5% of cells.

Investigation of the secondary DNA-binding site of the bacterial recombinase RecA

The L2 loop is a DNA-binding site of RecA protein, a recombinase from Eschericha coli. Two DNA-binding sites have been functionally defined in this protein. To determine whether the L2 loop of RecA protein is part of the primary or secondary binding site, we have constructed proteins with site-specific mutations in the loop and investigated their biological, biochemical, and DNA binding properties. The mutation E207Q inhibits DNA repair and homologous recombination in vivo and prevents DNA strand exchange in vitro (Larminat, F., Cazaux, C., Germanier, M., and Defais, M. (1992) J. Bacteriol. 174, 6264-6269; Cazaux, C., Larminat, F., Villani, G., Johnson, N. P., Schnarr, M., and Defais, M. (1994) J. Biol. Chem. 269, 8246-8254). We have found that mutant protein RecAE207Q lacked one of the two single stranded DNA-binding sites of wild type RecA. The remaining site was functional, and biochemical activities of the mutant protein were the same as wild type RecA with ssDNA in the primary binding site. The second mutation, E207K, reduced but did not eliminate DNA repair, SOS induction, and homologous recombination in vivo. In the presence of ATP, mutant protein RecAE207K catalyzed DNA strand exchange in vitro at a slower rate than wild type protein, and ssDNA binding at site I was competitively inhibited. These results show that the L2 loop is or is part of the functional secondary DNA-binding site of RecA protein.

Dissociation kinetics of RecA protein-three-stranded DNA complexes reveals a low fidelity of RecA-assisted recognition of homology

We determined that the incorporation of one mismatch into RecA mediated synaptic complexes between oligonucleotide single-stranded DNAs and target duplex DNAs destabilizes the complex by 0.8 to 1.9 kcal/mol. This finding supports our previous result, that RecA binding per se can significantly decrease the loss in free energy associated with mismatch incorporation even in the absence of ATP hydrolysis. We show that the specificity is mostly driven by the dissociation process. We found that the relative destabilization induced by different mismatches depends on their position. Thus, while there is a good correlation between the ranking order of mismatches at the 5' end of synaptic complexes and mismatches in heteroduplexes (D-loops), there is no correlation between the ranking order for mismatches at the 3' end and mismatches in various DNA structures. This difference between the 5' and 3' ends of synaptic complexes agrees well with the established 5' to 3' polarity of the strand exchange promoted by RecA protein. The lack of a correlation between mismatches at the 3' end of synaptic complexes and mismatches in D-loops suggests the intermediate is probably not a canonical protein-free D-loop.

A role for CH...O interactions in protein-DNA recognition

The concept of CH...O hydrogen bonds has recently gained much interest, with a number of reports indicating the significance of these non-classical hydrogen bonds in stabilizing nucleic acid and protein structures. Here, we analyze the CH...O interactions in the protein-DNA interface, based on 43 crystal structures of protein-DNA complexes. Surprisingly, we find that the number of close intermolecular CH...O contacts involving the thymine methyl group and position C5 of cytosine is comparable to the number of protein-DNA hydrogen bonds involving nitrogen and oxygen atoms as donors and acceptors. A comprehensive analysis of the geometries of these close contacts shows that they are similar to other CH...O interactions found in proteins and small molecules, as well as to classical NH...O hydrogen bonds. Thus, we suggest that C5 of cytosine and C5-Met of thymine form relatively weak CH...O hydrogen bonds with Asp, Asn, Glu, Gln, Ser, and Thr, contributing to the specificity of recognition. Including these interactions, in addition to the classical protein-DNA hydrogen bonds, enables the extraction of simple structural principles for amino acid-base recognition consistent with electrostatic considerations.

The function of the secondary DNA-binding site of RecA protein during DNA strand exchange

RecA protein features two distinct DNA-binding sites. During DNA strand exchange, the primary site binds to single-stranded DNA (ssDNA), forming the helical RecA nucleoprotein filament. The weaker secondary site binds double-stranded DNA (dsDNA) during the homology search process. Here we demonstrate that this site has a second important function. It binds the ssDNA strand that is displaced from homologous duplex DNA during DNA strand exchange, stabilizing the initial heteroduplex DNA product. Although the high affinity of the secondary site for ssDNA is essential for DNA strand exchange, it renders DNA strand exchange sensitive to an excess of ssDNA which competes with dsDNA for binding. We further demonstrate that single-stranded DNA-binding protein can sequester ssDNA, preventing its binding to the secondary site and thereby assisting at two levels: it averts the inhibition caused by an excess of ssDNA and prevents the reversal of DNA strand exchange by removing the displaced strand from the secondary site.

Parallel and antiparallel A*A-T intramolecular triple helices

Intramolecular triple helices have been obtained by folding back twice oligonucleotides formed by decamers bound by non-nucleotide linkers: dA10-linker-dA10-linker-dT10 and dA10-linker-dT10-linker-dA10. We have thus prepared two triple helices with forced third strand orientation, respectively antiparallel (apA*A-T) and parallel (pA*A-T) with respect to the adenosine strand of the Watson-Crick duplex. The existence of the triple helices has been shown by FTIR, UV and fluorescence spectroscopies. Similar melting temperatures have been obtained in very different oligomer concentration conditions (micromolar solutions for thermal denaturation classically followed by UV spectroscopy, milimolar solutions in the case of melting monitored by FTIR spectroscopy) showing that the triple helices are intramolecular. The stability of the parallel triplex is found to be slightly lower than that of the antiparallel (deltaT(m) = 6 degrees C). The sugar conformations determined by FTIR are different for both triplexes. Only South-type sugars are found in the antiparallel triplex whereas both South- and North-type sugars are detected in the parallel triplex. In this case, thymidine sugars have a South-type geometry, and the adenosine strand of the Watson-Crick duplex has North-type sugars. For the antiparallel triplex the experimental results and molecular modeling data are consistent with a reverse-Hoogsteen like third-strand base pairing and South-type sugar conformation. An energetically optimized model of the parallel A*A-T triple helix with a non-uniform distribution of sugar conformations is discussed.

The specificity of the secondary DNA binding site of RecA protein defines its role in DNA strand exchange

The RecA protein-single-stranded DNA (ssDNA) filament can bind a second DNA molecule. Binding of ssDNA to this secondary site shows specificity, in that polypyrimidinic DNA binds to the RecA protein-ssDNA filament with higher affinity than polypurinic sequences. The affinity of ssDNA, which is identical in sequence to that bound in the primary site, is not always greater than that of nonhomologous DNA. Moreover, this specificity of DNA binding does not depend on the sequence of the DNA bound to the RecA protein primary site. We conclude that the specificity reflects an intrinsic property of the secondary site of RecA protein rather than an interaction between DNa molecules within nucleoprotein filament--i.e., self-recognition. The secondary DNA binding site displays a higher affinity for ssDNA than for double-stranded DNA, and the binding of ssDNA to the secondary site strongly inhibits DNA strand exchange. We suggest that the secondary binding site has a dual role in DNA strand exchange. During the homology search, it binds double-stranded DNA weakly; upon finding local homology, this site binds, with higher affinity, the ssDNA strand that is displaced during DNA strand exchange. These characteristics facilitate homologous pairing, promote stabilization of the newly formed heteroduplex DNA, and contribute to the directionality of DNA strand exchange.

Parallel and antiparallel (G.GC)2 triple helix fragments in a crystal structure

Nucleic acid triplexes are formed by sequence-specific interactions between single-stranded polynucleotides and the double helix. These triplexes are implicated in genetic recombination in vivo and have application to areas that include genome analysis and antigene therapy. Despite the importance of the triple helix, only limited high-resolution structural information is available. The x-ray crystal structure of the oligonucleotide d(GGCCAATTGG) is described; it was designed to contain the d(G middle dotGC)2 fragment and thus provide the basic repeat unit of a DNA triple helix. Parameters derived from this crystal structure have made it possible to construct models of both parallel and antiparallel triple helices.

Solution structure of an antiparallel purine motif triplex containing a T.CG pyrimidine base triple

BACKGROUND

Triplex formation is an approach of potential use in regulating and mapping of gene sequences. However, such applications have been limited to homogeneous sequences consisting of stretches of purines or pyrimidines. Understanding how heterogeneous duplexes are recognized by a third strand oligonucleotide at the atomic resolution level is an essential step toward broadening the application of triplex formation into biochemical and biomedical areas.

RESULTS

The solution structure of an antiparallel triplex (RRY6) containing a site of inversion (i.e. a T within a homopurine stretch, forming a T.CG base triple) has been determined using NMR-restrained computations in the presence of explicit water. The results reveal that within the RRY6 triplex the conformation of the duplex is mostly B-like and that of the third strand exhibits significant variations in interbase separations and backbone torsion angles. A major displacement of the inversion site T sugar in a 5'-direction, accompanied by the tilt of the T base in T.CG, was observed. The T.CG base triple contains a single hydrogen bond between T O4 and the exposed C amino proton and is stabilized by a number of interstrand and sequential van der Waal contacts. The structural comparisons of RRY6 with two related triplexes indicate localized perturbation at the non-classical base triple site. Various triplexes contain sugars in the C2'-endo family and the global features of their duplexes are similar.

CONCLUSIONS

This study provides valuable information concerning the molecular basis of the specific recognition of a Watson-Crick base paired C residue at the inversion sites in the antiparallel triplex and should lead to general rules for designing triplexes containing heterogeneous sequences.

Conformations of three-stranded DNA structures formed in presence and in absence of the RecA protein

Using FTIR and UV spectroscopies, we have studied the structures of three-stranded DNA complexes (TSC) having two identical strands, containing all four bases, in parallel orientation. In the first system, an intermolecular TSC is formed by the addition of the third strand (ssDNA) previously coated with RecA protein to an hairpin duplex (dsDNA), in presence of ATP gamma S. In the second one, the formation of an intramolecular triplex is forced by folding back twice on itself an oligonucleotide. The sequences of the three strands are the same in both systems. The formation of the RecA-TSC, which accommodates all four bases, is evidenced by gel retardation assay, and by its biphasic melting profile observed by UV spectroscopy. Using FTIR spectroscopy, N-type sugars are detected in this structure. This shows that in the RecA-TSC studied in presence of the protein, the nucleic acid part adopts an extended form, in agreement with the model proposed by Zhurkin et al. (1,2) and electron microscopy observations (3-6). In contrast, the RecA-free intramolecular triplex in a non extended form has S-type sugars.

Tandem sequence duplications functionally complement deletions in the D1 protein of photosystem II

Obligate photoheterotrophic mutants of the cyanobacterium Synechocystis sp. PCC 6803 that carry deletions of conserved residues in the plastoquinone-binding niche of the D1 protein were used to select for spontaneous mutations that restore photoautotrophic growth. Spontaneous pseudorevertants emerged from two deletion mutants, delta YNIV246-9 and delta NN266-7, when the cultures were maintained long after the carbon source (glucose) had been depleted from the medium and cells had reached stationary phase. Most pseudorevertants were found to contain tandem duplications of 6-45-base pair DNA sequences located close to the domain carrying the deletion; none of them restored the wild-type sequence. Three pseudorevertants isolated from the delta YNIV246-9 mutant contained a duplication (7-15 codons) of the DNA sequence immediately downstream of the deletion; the protein region encoded by this DNA may include part of the putative de helix, an important constituent of the plastoquinone-binding niche. Three pseudorevertants isolated from the delta NN266-7 mutant contained duplications corresponding to 2-8 amino acid residues adjacent to the site of the deletion. In all six pseudorevertants carrying duplications, the length of the D1 protein in the modified regions was restored to at least the length present in wild type, suggesting that a minimal length of these protein domains may be required for functional integrity. In another photoautotrophic strain isolated from delta NN266-7, no secondary mutations could be identified in the gene coding for the D1 protein; such mutations apparently reside on another protein subunit of the photosystem II complex. Photosystem II function in the pseudorevertants was altered as compared with wild type in terms of growth and oxygen evolution rates, photosystem II concentration, the semiquinone equilibrium at the acceptor side, and thermostability. A mechanism leading to tandem sequence duplication may involve DNA damage followed by DNA synthesis, strand displacement, and ligation.

Genetics of genetics in Drosophila: P elements serving the study of homologous recombination, gene conversion and targeting

P-element induced double strand break repair in Drosophila can be used for studying the mechanisms of homologous recombination in higher eucaryotes as well as for targeting and converting genes in their original chromosomal environment. So far studies on the molecular mechanisms of recombination were mainly possible in fungi. Even though gene targeting through homologous recombination is becoming a routine instrument in the mouse the underlying molecular events are by no means clear. The genetics of Drosophila provides a powerful tool to study the basics of gene targeting and gene conversion events in higher eucaryotes.

A model for repair of radiation-induced DNA double-strand breaks in the extreme radiophile Deinococcus radiodurans

The bacterium Deinococcus (formerly Micrococcus) radiodurans and other members of the eubacterial family Deinococaceae are extremely resistant to ionizing radiation and many other agents that damage DNA. Stationary phase D. radiodurans exposed to 1.0-1.5 Mrad gamma-irradiation sustains > 120 DNA double-strand breaks (dsbs) per chromosome; these dsbs are mended over a period of hours with 100% survival and virtually no mutagenesis. This contrasts with nearly all other organisms in which just a few ionizing radiation induced-dsbs per chromosome are lethal. In this article we present an hypothesis that resistance of D. radiodurans to ionizing radiation and its ability to mend radiation-induced dsbs are due to a special form of redundancy wherein chromosomes exist in pairs, linked to each other by thousands of four-stranded (Holliday) junctions. Thus, a dsb is not a lethal event because the identical undamaged duplex is nearby, providing an accurate repair template. As addressed in this article, much of what is known about D. radiodurans suggests that it is particularly suited for this proposed novel form of DNA repair.

RecA protein mediates homologous recognition via non-Watson-Crick bonds in base triplets

E. coli RecA protein, the prototype of a class, forms a helical nucleoprotein filament on single-stranded DNA that recognizes homology in duplex DNA, and initiates the exchange of strands in homologous recombination. The discovery of this reaction some years ago posed a quandary on how a third strand recognizes homology in duplex DNA, whose Watson-Crick bonds face inward in a hydrophobic core of stacked bases. Recent studies have shown that RecA protein promotes homologous recognition via non-Watson-Crick bonds in base triplets. The intermediates in the RecA reaction differ distinctly from triplex DNA that forms non-enzymically. The biological significance of the novel set of DNA interactions by which RecA protein effects homologous recognition is indicated by the importance of this protein in recombination, and the widespread distribution of homologous proteins in prokaryotes and eukaryotes.

RAP1 stimulates single- to double-strand association of yeast telomeric DNA: implications for telomere-telomere interactions

Repressor Activator Protein 1 (RAP1) of Saccharomyces cerevisiae is an abundant nuclear protein implicated in telomere length maintenance, transactivation, and in the establishment of silent chromatin domains. The RAP1 binding site 5' of the yeast HIS4 gene is also a region of hyperrecombination in meiosis. We report here that as RAP1 binds its recognition consensus, it appears to untwist double-stranded DNA, which we detect as the introduction of a negative supercoil in circularization assays. Coincident with the RAP1-dependent untwisting, we observe stimulation of the association of a single-stranded yeast telomeric sequence with its homologous double-stranded sequence in a supercoiled plasmid. This unusual distortion of the DNA double helix by RAP1 may contribute to the RAP1-dependent enhancement of recombination rates and promote non-duplex strand interactions at telomeres.