Radioprobing of a RecA-three-stranded DNA complex with iodine 125: evidence for recognition of homology in the major groove of the target duplex

Modeling the Homologous Recombination Process: Methods, Successes and Challenges

Homologous recombination (HR) is a fundamental process common to all species. HR aims to faithfully repair DNA double strand breaks. HR involves the formation of nucleoprotein filaments on DNA single strands (ssDNA) resected from the break. The nucleoprotein filaments search for homologous regions in the genome and promote strand exchange with the ssDNA homologous region in an unbroken copy of the genome. HR has been the object of intensive studies for decades. Because multi-scale dynamics is a fundamental aspect of this process, studying HR is highly challenging, both experimentally and using computational approaches. Nevertheless, knowledge has built up over the years and has recently progressed at an accelerated pace, borne by increasingly focused investigations using new techniques such as single molecule approaches. Linking this knowledge to the atomic structure of the nucleoprotein filament systems and the succession of unstable, transient intermediate steps that takes place during the HR process remains a challenge; modeling retains a very strong role in bridging the gap between structures that are stable enough to be observed and in exploring transition paths between these structures. However, working on ever-changing long filament systems submitted to kinetic processes is full of pitfalls. This review presents the modeling tools that are used in such studies, their possibilities and limitations, and reviews the advances in the knowledge of the HR process that have been obtained through modeling. Notably, we will emphasize how cooperative behavior in the HR nucleoprotein filament enables modeling to produce reliable information.

Characteristic variation of α-fetoprotein DNA nanometer-range irradiated by iodine-125

To obtain the characteristic variation of structure and functional groups of α-fetoprotein (AFP) DNA irradiated by iodine-125((125)I), the AFP antisense oligonucleotide labeled with various radioactivity dose (125)I was mixed with the AFP DNA in a simulated polymerase chain reaction temperature condition. After the mixtures were irradiated by the (125)I from 2 to 72 hours, the mutation of the biogenic conformation and functional groups of the irradiated DNA were investigated using laser Raman spectroscopy. The shifted peak and the decreased intensity of the characteristic Raman spectra were found, which demonstrated that the structure of the phosphodiester linkage was broke, the pyridine and purine bases in DNA emerged and damaged. The model of gene conformation changed from form B to form C spectrum after the nanometer-range irradiation with (125)I from 2 to 24 hours. The damage of local pyridine and purine bases gradually increased along with the accumulation of irradiation, and the bases and ribosome were finally dissociated and stacked.

Radioprobing the conformation of DNA in a p53-DNA complex

PURPOSE

The frequency of DNA strand breaks produced by the decay of Auger electron-emitting radionuclides is inversely proportional to the distance of DNA nucleotides from the decay site; and thus is very sensitive to changes in the local conformation of the DNA. Analysis of the frequency of DNA breaks, or radioprobing, gives valuable information about the local DNA structure. More than 10 years ago, we demonstrated the feasibility of radioprobing using a DNA-repressor complex with a known structure. Herein, we used radioprobing to study the conformation of DNA in complex with the tumor suppressor protein 53 (p53). Several structures of p53-DNA complexes have been solved by X-ray crystallography. These structures, obtained with the p53 DNA binding domain, a truncated form, laid the groundwork for understanding p53-DNA interactions and their relation to p53 functions. However, whether all observed stereochemical details are relevant to the native p53-DNA complex remains unclear. A common theme of the crystallographic structures is the lack of significant bending in the central part of the DNA response element. In contrast, gel electrophoresis and electron microscopy data showed strong DNA bending and overtwisting upon binding to the native p53 tetramer.

METHODS

To analyze DNA in complex with p53, we incorporated (125)I-dCTP in two different positions of synthetic duplexes containing the consensus p53-binding site.

RESULTS

The most significant changes in the break frequency distributions were detected close to the center of the binding site, which is consistent with an increase in DNA twisting in this region and local DNA bending and sliding.

CONCLUSIONS

Our data confirm the main results of the studies made in solution and lay a foundation for systematic examination of interactions between DNA and native p53 using (125)I radioprobing.

Assessing DNA structures with 125I radioprobing

Iodine-125 radioprobing is based on incorporation of radioiodine into a defined position in a nucleic acid molecule. Decay of (125)I results in the emission of multiple, low-energy Auger electrons that, along with positively charged residual daughter nuclide, produce DNA strand breaks. The probability of such strand breaks at a given nucleotide is in inverse proportion to the distance from the (125)I atom to the sugar of that nucleotide. Therefore, conclusions can be drawn about the conformation or folding of a DNA or RNA molecule based on the distribution of (125)I decay-induced strand breaks. Here we describe in detail the application (125)I radioprobing for studying the conformation of quadruplex structures, and discuss the advantages and limitations of the method.

Reversibility, equilibration, and fidelity of strand exchange reaction between short oligonucleotides promoted by RecA protein from escherichia coli and human Rad51 and Dmc1 proteins

We demonstrate the reversibility of RecA-promoted strand exchange reaction between short oligonucleotides in the presence of adenosine 5'-O-(thiotriphosphate). The reverse reaction proceeds without the dissociation of RecA from DNA. The reaction reaches equilibrium and its yield depends on the homology between the reaction substrates. We estimate the tolerance of the RecA-promoted strand exchange to individual base substitutions for a comprehensive set of possible base combinations in a selected position along oligonucleotide substrates for strand exchange and find, in agreement with previously reported estimations, that this tolerance is higher than in the case of free DNA. It is demonstrated that the short oligonucleotide-based approach can be applied to the human recombinases Rad51 and Dmc1 when strand exchange is performed in the presence of calcium ions and ATP. Remarkably, despite the commonly held belief that the eukaryotic recombinases have an inherently lower strand exchange activity, in our system their efficiencies in strand exchange are comparable with that of RecA. Under our experimental conditions, the human recombinases exhibit a significantly higher tolerance to interruptions of homology due to point base substitutions than RecA. Finding conditions where a chemical reaction is reversible and reaches equilibrium is critically important for its thermodynamically correct description. We believe that the experimental system described here will substantially facilitate further studies on different aspects of the mechanisms of homologous recombination.

Heteropolymeric triplex-based genomic assay to detect pathogens or single-nucleotide polymorphisms in human genomic samples

Human genomic samples are complex and are considered difficult to assay directly without denaturation or PCR amplification. We report the use of a base-specific heteropolymeric triplex, formed by native duplex genomic target and an oligonucleotide third strand probe, to assay for low copy pathogen genomes present in a sample also containing human genomic duplex DNA, or to assay human genomic duplex DNA for Single Nucleotide Polymorphisms (SNP), without PCR amplification. Wild-type and mutant probes are used to identify triplexes containing FVL G1691A, MTHFR C677T and CFTR mutations. The specific triplex structure forms rapidly at room temperature in solution and may be detected without a separation step. YOYO-1, a fluorescent bis-intercalator, promotes and signals the formation of the specific triplex. Genomic duplexes may be assayed homogeneously with single base pair resolution. The specific triple-stranded structures of the assay may approximate homologous recombination intermediates, which various models suggest may form in either the major or minor groove of the duplex. The bases of the stable duplex target are rendered specifically reactive to the bases of the probe because of the activity of intercalated YOYO-1, which is known to decondense duplex locally 1.3 fold. This may approximate the local decondensation effected by recombination proteins such as RecA in vivo. Our assay, while involving triplex formation, is sui generis, as it is not homopurine sequence-dependent, as are “canonical triplexes”. Rather, the base pair-specific heteropolymeric triplex of the assay is conformation-dependent. The highly sensitive diagnostic assay we present allows for the direct detection of base sequence in genomic duplex samples, including those containing human genomic duplex DNA, thereby bypassing the inherent problems and cost associated with conventional PCR based diagnostic assays.

RecA-DNA filament topology: the overlooked alternative of an unconventional syn-syn duplex intermediate

The helical filaments of RecA protein mediate strand exchange for homologous recombination, but the paths of the interacting DNAs have yet to be determined. Although this interaction is commonly limited to three strands, it is reasoned here that the intrinsic symmetry relationships of quadruplex topology are superior in explaining a range of observations. In particular, this topology suggests the potential of post-exchange base pairing in the unorthodox configuration of syn-syn glycosidic bonds between the nucleotide bases and the pentose rings in the sugar-phosphate backbone, which would transiently be stabilized by the external scaffolding of the RecA protein filament.

Direct evaluation of a kinetic model for RecA-mediated DNA-strand exchange: the importance of nucleic acid dynamics and entropy during homologous genetic recombination

The Escherichia coli RecA protein is the prototype of a class of proteins that play central roles in genomic repair and recombination in all organisms. The unresolved mechanistic strategy by which RecA aligns a single strand of DNA with a duplex DNA and mediates a DNA strand switch is central to understanding homologous recombination. We explored the mechanism of RecA-mediated DNA-strand exchange using oligonucleotide substrates with the intrinsic fluorophore 6-methylisoxanthopterin. Pre-steady-state spectrofluorometric analysis elucidated the earliest transient intermediates formed during recombination and delineated the mechanistic strategy by which RecA facilitates this process. The structural features of the first detectable intermediate and the energetic characteristics of its formation were consistent with interactions between a few bases of the single-stranded DNA and the minor groove of a locally melted or stretched duplex DNA. Further analysis revealed RecA to be an unusual enzyme in that entropic rather than enthalpic contributions dominate its catalytic function, and no unambiguously active role for the protein was detected in the earliest molecular events of recombination. The data best support the conclusion that the mechanistic strategy of RecA likely relies on intrinsic DNA dynamics.

Recombination R-triplex: H-bonds contribution to stability as revealed with minor base substitutions for adenine

Several cellular processes involve alignment of three nucleic acids strands, in which the third strand (DNA or RNA) is identical and in a parallel orientation to one of the DNA duplex strands. Earlier, using 2-aminopurine as a fluorescent reporter base, we demonstrated that a self-folding oligonucleotide forms a recombination-like structure consistent with the R-triplex. Here, we extended this approach, placing the reporter 2-aminopurine either in the 5'- or 3'-strand. We obtained direct evidence that the 3'-strand forms a stable duplex with the complementary central strand, while the 5'-strand participates in non-Watson-Crick interactions. Substituting 2,6-diaminopurine or 7-deazaadenine for adenine, we tested and confirmed the proposed hydrogen bonding scheme of the A*(T.A) R-type triplet. The adenine substitutions expected to provide additional H-bonds led to triplex structures with increased stability, whereas the substitutions consistent with a decrease in the number of H-bonds destabilized the triplex. The triplex formation enthalpies and free energies exhibited linear dependences on the number of H-bonds predicted from the A*(T.A) triplet scheme. The enthalpy of the 10 nt long intramolecular triplex of -100 kJ x mol(-1) demonstrates that the R-triplex is relatively unstable and thus an ideal candidate for a transient intermediate in homologous recombination, t-loop formation at the mammalian telomere ends, and short RNA invasion into a duplex. On the other hand, the impact of a single H-bond, 18 kJ x mol(-1), is high compared with the overall triplex formation enthalpy. The observed energy advantage of a 'correct' base in the third strand opposite the Watson-Crick base pair may be a powerful mechanism for securing selectivity of recognition between the single strand and the duplex.

Construction and evaluation of a kinetic scheme for RecA-mediated DNA strand exchange

The Escherichia coli RecA protein is the prototype of a class of proteins playing a central role in genomic repair and recombination in all organisms. The unresolved mechanistic strategy by which RecA aligns a single strand of DNA with a duplex DNA and mediates a DNA strand switch is central to understanding its recombinational activities. Toward a molecular-level understanding of RecA-mediated DNA strand exchange, we explored its mechanism using oligonucleotide substrates and the intrinsic fluorescence of 6-methylisoxanthopterin (6MI). Steady- and presteady-state spectrofluorometric data demonstrate that the reaction proceeds via a sequential four-step mechanism comprising a rapid, bimolecular association step followed by three slower unimolecular steps. Previous authors have proposed multistep mechanisms involving two or three steps. Careful analysis of the differences among the experimental systems revealed a previously undiscovered intermediate (N1) whose formation may be crucial in the kinetic discrimination of homologous and heterologous sequences. This observation has important implications for probing the fastest events in DNA strand exchange using 6MI to further elucidate the molecular mechanisms of recombination and recombinational repair.

The potential for gene-targeted radiation therapy of cancers

Targeted cancer therapy is the mantra now chanted by oncologists of all types. Everyone hopes that the rapid expansion in the knowledge of cancer cell genetics, signaling, regulatory factors and other changes that underlie malignant transformation and metastasis will lead to innovative approaches for the treatment of cancers. To date, successful targeted therapies have been derived from pharmaceutical chemistry - designing chemical compounds intended to disrupt a crucial pathway for malignant cells to survive, grow and metastasize. Radiotherapy also has a goal of more-selective targeting of therapeutic radiation effects to only tumor cells. In this review, we describe our efforts to create a form of gene-targeted radiation therapy by using the unique radiation effects of radionuclides that decay by the Auger process attached to oligonucleotide carrier-molecules that are capable of forming triplex DNA structures with target sequences in the genome of the human cancer cell.

Exchange of DNA base pairs that coincides with recognition of homology promoted by E. coli RecA protein

The unresolved mechanism by which a single strand of DNA recognizes homology in duplex DNA is central to understanding genetic recombination and repair of double-strand breaks. Using stopped-flow fluorescence we monitored strand exchange catalyzed by E. coli RecA protein, measuring simultaneously the rate of exchange of A:T base pairs and the rates of formation and dissociation of the three-stranded intermediates called synaptic complexes. The rate of exchange of A:T base pairs was indistinguishable from the rate of formation of synaptic complexes, whereas the rate of displacement of a single strand from complexes was five to ten times slower. This physical evidence shows that a subset of bases exchanges at a rate that is fast enough to account for recognition of homology. Together, several studies suggest that a mechanism governed by the dynamic structure of DNA and catalyzed by diverse enzymes underlies both recognition of homology and initiation of strand exchange.

Intramolecular quadruplex conformation of human telomeric DNA assessed with 125I-radioprobing

A repeated non-coding DNA sequence d(TTAGGG)n is present in the telomeric ends of all human chromosomes. These repeats can adopt multiple inter and intramolecular non-B-DNA conformations that may play an important role in biological processes. Two intramolecular structures of the telomeric oligonucleotide dAGGG(TTAGGG)3, antiparallel and parallel, have been solved by NMR and X-ray crystallography. In both structures, the telomeric sequence adopts an intramolecular quadruplex structure that is stabilized by G-4 quartets, but the ways in which the sequence folds into the quadruplex are different. The folds of the human telomeric DNA were described as an anti-parallel basket-type and a parallel propeller-type. We applied 125I-radioprobing to determine the conformation of the telomeric quadruplex in solution, in the presence of either Na+ or K+ ions. The probability of DNA breaks caused by decay of 125I is inversely related to the distance between the radionuclide and the sugar unit of the DNA backbone; hence, the conformation of the DNA backbone can be deduced from the distribution of breaks. The probability of breaks measured in the presence of Na+ and K+ were compared with the distances in basket-type and propeller-type quadruplexes obtained from the NMR and crystal structures. Our radioprobing data demonstrate that the antiparallel conformation was present in solution in the presence of both K+ and Na+. The preferable conformation in the Na+-containing solution was the basket-type antiparallel quadruplex whereas the presence of K+ favored the chair-type antiparallel quadruplex. Thus, we believe that the two antiparallel and the parallel conformations may coexist in solution, and that their relative proportion is determined by the type and concentration of ions.

Formation of an intramolecular triple-stranded DNA structure monitored by fluorescence of 2-aminopurine or 6-methylisoxanthopterin

The parallel (recombination) 'R-triplex' can accommodate any nucleotide sequence with the two identical DNA strands in parallel orientation. We have studied oligonucleotides able to fold back into such a recombination-like structure. We show that the fluorescent base analogs 2-aminopurine (2AP) and 6-methylisoxanthopterin (6MI) can be used as structural probes for monitoring the integrity of the triple-stranded conformation and for deriving the thermodynamic characteristics of these structures. A single adenine or guanine base in the third strand of the triplex-forming and the control oligonucleotides, as well as in the double-stranded (ds) and single-stranded (ss) reference molecules, was substituted with 2AP or 6MI. The 2AP*(T.A) and 6MI*(C.G) triplets were monitored by their fluorescence emission and the thermal denaturation curves were analyzed with a quasi-two-state model. The fluorescence of 2AP introduced into an oligonucleotide sequence unable to form a triplex served as a negative control. We observed a remarkable similarity between the thermodynamic parameters derived from melting of the secondary structures monitored through absorption of all bases at 260 nm or from fluorescence of the single base analog. The similarity suggests that fluorescence of the 2AP and 6MI base analogs may be used to monitor the structural disposition of the third strand. We consider the data in the light of alternative 'branch migration' and 'strand exchange' structures and discuss why these are less likely than the R-type triplex.

The synaptic complex of RecA protein participates in hybridization and inverse strand exchange reactions

RecA protein catalyzes strand exchange between homologous single-stranded and double-stranded DNAs. In the presence of ATPgammaS, the post-strand exchange synaptic complex is a stable end product that can be studied. Here we ask whether such complexes can hybridize to or exchange with DNA, 2'-OMe RNA, PNA, or LNA oligonucleotides. Using a gel mobility shift assay, we show that the displaced strand of a 45 bp synaptic complex can hybridize to complementary oligonucleotides with different backbones to form a four-stranded (double D-loop) joint that survives removal of the RecA protein. This hybridization reaction, which confirms the single-stranded character of the displaced strand in a synaptic complex, might initiate recombination-dependent DNA replication if it occurs in vivo. We also show that either strand of the heteroduplex in a 30 bp synaptic complex can be replaced with a homologous DNA oligonucleotide in a strand exchange reaction that is mediated by the RecA filament. Consistent with the important role that deoxyribose plays in strand exchange, oligonucleotides with non-DNA backbones did not participate in this reaction. The hybridization and strand exchange reactions reported here demonstrate that short synaptic complexes are dynamic structures even in the presence of ATPgammaS.

The bacterial RecA protein and the recombinational DNA repair of stalled replication forks

The primary function of bacterial recombination systems is the nonmutagenic repair of stalled or collapsed replication forks. The RecA protein plays a central role in these repair pathways, and its biochemistry must be considered in this context. RecA protein promotes DNA strand exchange, a reaction that contributes to fork regression and DNA end invasion steps. RecA protein activities, especially formation and disassembly of its filaments, affect many additional steps. So far, Escherichia coli RecA appears to be unique among its nearly ubiquitous family of homologous proteins in that it possesses a motorlike activity that can couple the branch movement in DNA strand exchange to ATP hydrolysis. RecA is also a multifunctional protein, serving in different biochemical roles for recombinational processes, SOS induction, and mutagenic lesion bypass. New biochemical and structural information highlights both the similarities and distinctions between RecA and its homologs. Increasingly, those differences can be rationalized in terms of biological function.

Site-specific strand breaks in RNA produced by (125)I radiodecay

Decay of (125)I produces a shower of low energy electrons (Auger electrons) that cause strand breaks in DNA in a distance-dependent manner with 90% of the breaks located within 10 bp from the decay site. We studied strand breaks in RNA molecules produced by decay of (125)I incorporated into complementary DNA oligonucleotides forming RNA/DNA duplexes with the target RNA. The frequencies and distribution of the breaks were unaffected by the presence of the free radical scavenger dimethyl sulfoxide (DMSO) or by freezing of the samples. Therefore, as was the case with DNA, most of the breaks in RNA were direct rather than caused by diffusible free radicals produced in water. The distribution of break frequencies at individual bases in RNA molecules is narrower, with a maximum shifted to the 3'-end with respect to the distribution of breaks in DNA molecules of the same sequence. This correlates with the distances from the radioiodine to the sugars of the corresponding bases in A-form (RNA/DNA duplex) and B-form (DNA/DNA duplex) DNA. Interestingly, when (125)I was located close to the end of the antisense DNA oligonucleotide, we observed breaks in RNA beyond the RNA/DNA duplex region. This was not the case for a control DNA/DNA hybrid of the same sequence. We assume that for the RNA there is an interaction between the RNA/DNA duplex region and the single-stranded RNA tail, and we propose a model for such an interaction. This report demonstrates that (125)I radioprobing of RNA could be a powerful method to study both local conformation and global folding of RNA molecules.

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.

Elucidating a key intermediate in homologous DNA strand exchange: structural characterization of the RecA-triple-stranded DNA complex using fluorescence resonance energy transfer

The RecA protein of Escherichia coli plays essential roles in homologous recombination and restarting stalled DNA replication forks. In vitro, the protein mediates DNA strand exchange between single-stranded (ssDNA) and homologous double-stranded DNA (dsDNA) molecules that serves as a model system for the in vivo processes. To date, no high-resolution structure of the key intermediate, comprised of three DNA strands simultaneously bound to a RecA filament (RecA-tsDNA complex), has been reported. We present a systematic characterization of the helical geometries of the three DNA strands of the RecA-tsDNA complex using fluorescence resonance energy transfer (FRET) under physiologically relevant solution conditions. FRET donor and acceptor dyes were used to label different DNA strands, and the interfluorophore distances were inferred from energy transfer efficiencies measured as a function of the base-pair separation between the two dyes. The energy transfer efficiencies were first measured on a control RecA-dsDNA complex, and the calculated helical parameters (h approximately 5 A, Omega(h) approximately 20 degrees ) were consistent with structural conclusions derived from electron microscopy (EM) and other classic biochemical methods. Measurements of the helical parameters for the RecA-tsDNA complex revealed that all three DNA strands adopt extended and unwound conformations similar to those of RecA-bound dsDNA. The structural data are consistent with the hypothesis that this complex is a late, post-strand-exchange intermediate with the outgoing strand shifted by about three base-pairs with respect to its registry with the incoming and complementary strands. Furthermore, the bases of the incoming and complementary strands are displaced away from the helix axis toward the minor groove of the heteroduplex, and the bases of the outgoing strand lie in the major groove of the heteroduplex. We present a model for the strand exchange intermediate in which homologous contacts preceding strand exchange arise in the minor groove of the substrate dsDNA.

The stretched DNA geometry of recombination and repair nucleoprotein filaments

The RecA protein of Escherichia coli plays essential roles in homologous recombination and restarting stalled DNA replication forks. In vitro, the protein mediates DNA strand exchange between single-stranded (ssDNA) and homologous double-stranded DNA (dsDNA) molecules that serves as a model system for the in vivo processes. To date, no high-resolution structure of the key intermediate, comprised of three DNA strands simultaneously bound to a RecA filament (RecA x tsDNA complex), has been elucidated by classical methods. Here we review the systematic characterization of the helical geometries of the three DNA strands of the RecA x tsDNA complex using fluorescence resonance energy transfer (FRET) under physiologically relevant solution conditions. Measurements of the helical parameters for the RecA x tsDNA complex are consistent with the hypothesis that this complex is a late, poststrand-exchange intermediate with the outgoing strand shifted by about three base pairs with respect to its registry with the incoming and complementary strands. All three strands in the RecA x tsDNA complex adopt extended and unwound conformations similar to those of RecA-bound ssDNA and dsDNA.

Peptide nucleic acid (PNA) facilitates multistranded hybrid formation between linear double-stranded DNA targets and RecA protein-coated complementary single-stranded DNA probes

RecA protein-coated single-stranded DNA probes, known as RecA nucleoprotein filaments, bind specifically to homologous DNA sequences within double-stranded DNA targets, forming multistranded probe-target DNA hybrids. This DNA hybridization reaction can be used for sequence-specific gene capture, gene modification, and gene regulation. Thus, factors that enhance the efficiency of the hybridization reaction are of significant practical importance. We show here that the hybridization of a peptide nucleic acid (PNA) within or adjacent to the probe-target homology region significantly enhances the yield of hybrid DNA formed in the reaction between linear double-stranded DNA targets and RecA protein-coated complementary single-stranded (css)DNA probes. The possible mechanisms and the advantages of using RecA nucleoprotein filaments in combination with PNA for genomic DNA cloning and mutagenesis are presented.

Homologous genetic recombination as an intrinsic dynamic property of a DNA structure induced by RecA/Rad51-family proteins: a possible advantage of DNA over RNA as genomic material

Heteroduplex joints are general intermediates of homologous genetic recombination in DNA genomes. A heteroduplex joint is formed between a single-stranded region (or tail), derived from a cleaved parental double-stranded DNA, and homologous regions in another parental double-stranded DNA, in a reaction mediated by the RecA/Rad51-family of proteins. In this reaction, a RecA/Rad51-family protein first forms a filamentous complex with the single-stranded DNA, and then interacts with the double-stranded DNA in a search for homology. Studies of the three-dimensional structures of single-stranded DNA bound either to Escherichia coli RecA or Saccharomyces cerevisiae Rad51 have revealed a novel extended DNA structure. This structure contains a hydrophobic interaction between the 2' methylene moiety of each deoxyribose and the aromatic ring of the following base, which allows bases to rotate horizontally through the interconversion of sugar puckers. This base rotation explains the mechanism of the homology search and base-pair switch between double-stranded and single-stranded DNA during the formation of heteroduplex joints. The pivotal role of the 2' methylene-base interaction in the heteroduplex joint formation is supported by comparing the recombination of RNA genomes with that of DNA genomes. Some simple organisms with DNA genomes induce homologous recombination when they encounter conditions that are unfavorable for their survival. The extended DNA structure confers a dynamic property on the otherwise chemically and genetically stable double-stranded DNA, enabling gene segment rearrangements without disturbing the coding frame (i.e., protein-segment shuffling). These properties may give an extensive evolutionary advantage to DNA.

RecA-mediated strand exchange traverses substitutional heterologies more easily than deletions or insertions

RecA protein in bacteria and its eukaryotic homolog Rad51 protein are responsible for initiation of strand exchange between homologous DNA molecules. This process is crucial for homologous recombination, the repair of certain types of DNA damage and for the reinitiation of DNA replication on collapsed replication forks. We show here, using two different types of in vitro assays, that in the absence of ATP hydrolysis RecA-mediated strand exchange traverses small substitutional heterologies between the interacting DNAs, whereas small deletions or insertions block the ongoing strand exchange. We discuss evolutionary implications of RecA selectivity against insertions and deletions and propose a molecular mechanism by which RecA can exert this selectivity.

Modeling DNA deformations

Recent developments have been made in modeling double-helical DNA at four levels of three-dimensional structure: the all-atom level, whereby an oligonucleotide duplex is surrounded by a shroud of solvent molecules; the base-pair level, with explicit backbone atoms; the mesoscopic level, that is, a few hundred base pairs, with the local duplex conformation described by knowledge-based harmonic energy functions; and the scale of several thousand nucleotides, with the duplex described as an ideal elastic rod. Predictions of the sequence-dependent bending and twisting of the double helix, as well as solvent- and force-induced B-->A and over-stretching conformational transitions, are compared with experimental data. These subtle conformational changes are critical to the functioning of the double helix, including its packaging in the close confines of the cell, the mutual fit of DNA and protein in nucleoprotein complexes, and the effective recognition of base pairs in recombination and transcription.