Dna Strand Exchange

Twenty years of t-loops: A case study for the importance of collaboration in molecular biology

Collaborative studies open doors to breakthroughs otherwise unattainable by any one laboratory alone. Here we describe the initial collaboration between the Griffith and de Lange laboratories that led to thinking about the telomere as a DNA template for homologous recombination, the proposal of telomere looping, and the first electron micrographs of t-loops. This was followed by collaborations that revealed t-loops across eukaryotic phyla. The Griffith and Tomáška/Nosek collaboration revealed circular telomeric DNA (t-circles) derived from the linear mitochondrial chromosomes of nonconventional yeast, which spurred discovery of t-circles in ALT-positive human cells. Collaborative work between the Griffith and McEachern labs demonstrated t-loops and t-circles in a series of yeast species. The de Lange and Zhuang laboratories then applied super-resolution light microscopy to demonstrate a genetic role for TRF2 in loop formation. Recent work from the Griffith laboratory linked telomere transcription with t-loop formation, providing a new model of the t-loop junction. A recent collaboration between the Cesare and Gaus laboratories utilized super-resolution light microscopy to provide details about t-loops as protective elements, followed by the Boulton and Cesare laboratories showing how cell cycle regulation of TRF2 and RTEL enables t-loop opening and reformation to promote telomere replication. Twenty years after the discovery of t-loops, we reflect on the collective history of their research as a case study in collaborative molecular biology.

Recombinase polymerase amplification: Emergence as a critical molecular technology for rapid, low-resource diagnostics

Isothermal molecular diagnostics are bridging the technology gap between traditional diagnostics and polymerase chain reaction-based methods. These new techniques enable timely and accurate testing, especially in settings where there is a lack of infrastructure to support polymerase chain reaction facilities. Despite this, there is a significant lack of uptake of these technologies in developing countries where they are highly needed. Among these novel isothermal technologies, recombinase polymerase amplification (RPA) holds particular potential for use in developing countries. This rapid nucleic acid amplification approach is fast, highly sensitive and specific, and amenable to countries with a high burden of infectious diseases. Implementation of RPA technology in developing countries is critically required to assess limitations and potentials of the diagnosis of infectious disease, and may help identify impediments that prevent adoption of new molecular technologies in low resource- and low skill settings. This review focuses on approaching diagnosis of infectious disease with RPA.

Double-strand break repair in bacteriophage T4: recombination effects of 3'-5' exonuclease mutations

The role of 3'-5' exonucleases in double-strand break (DSB)-promoted recombination was studied in crosses of bacteriophage T4, in which DSBs were induced site specifically within the rIIB gene by SegC endonuclease in the DNA of only one of the parents. Frequency of rII+ recombinants was measured in two-factor crosses of the type i x ets1, where ets1 designates an insertion in the rIIB gene carrying the cleavage site for SegC and i's are rIIB or rIIA point mutations located at various distances (12-2040 bp) from the ets1 site. The frequency/distance relationship was obtained in crosses of the wild-type phage and dexA1 (deficiency in deoxyribonuclease A), D219A (deficiency in the proofreading exonuclease of DNA polymerase), and tsL42 (antimutator allele of DNA polymerase) mutants. In all the mutants, recombinant frequency in crosses with the i-markers located at 12 and 33 bp from ets1 was significantly enhanced, implying better preservation of 3'-terminal sequences at the ends of the broken DNA. The effects of dexA1 and D219A were additive, suggesting an independent action of the corresponding nucleases in the DSB repair pathway. The recombination enhancement in the dexA1 mutant was limited to short distances (<100 bp from ets1), whereas in the D219A mutant a significant enhancement was seen at all the tested distances. From the character of the frequency/distance relationship, it is inferred that the synthesis-dependent strand-annealing pathway may operate in the D219A mutant. The recombination-enhancing effect of the tsL42 mutation could be explained by the hypothesis that the antimutator 43Exo removes a shorter stretch of paired nucleotides than the wild-type enzyme does during hydrolysis of the unpaired terminus in the D-loop intermediate. The role of the proofreading exonuclease in the formation of a robust replicative fork is discussed.

Telomere looping in P. sativum (common garden pea)

Telomeres vary greatly in size among plants and, in most higher plants, consist of a long array of 5'-TTTAGGG-3'/3'-AAATCCC-5' (TTTAGGG) repeats. Recently, telomeric DNA in human, mouse, oxytricha, and trypanosome chromosomes have been found arranged into loops (t-loops), proposed to sequester the telomere from unwanted repair events and prevent activation of DNA damage checkpoints. We have asked whether t-loops exist in the higher order plant Pisum sativum (garden pea). DNA was isolated from the shoots and root tips of germinating seeds. Analysis of the telomeric restriction fragments showed that DNA hybridizing to a (TTTAGGG)n probe migrated as a smear centering around 25 kb, and direct sequencing verified the repeat to be (TTTAGGG)n. Total DNA in isolated nuclei was photo-cross-linked, and the telomeric restriction fragments were purified by gel filtration. Electron microscopic (EM) analysis revealed DNA molecules arranged as t-loops with a size distribution consistent with that seen by gel electrophoresis. Some molecules had loops as large as 75 kb. These results show that the arrangement of telomeric DNA into loops occurs in higher plants.

Interaction of tyrosine 65 of RecA protein with the first and second DNA strands

We investigated the structure of the active RecA-DNA complex by analyzing the environment of tyrosine residue 65, which is on the DNA-binding surface of the protein. We prepared a modified RecA protein in which the tyrosine residue was replaced by tryptophan, a natural fluorescent reporter, and measured the change in its fluorescence upon binding of DNA and cofactor. The fluorescence of the inserted tryptophan 65 (Trp65) was centered at 345 nm, indicating a partly exposed residue. Binding cofactor, adenosine 5'-O-3-thiotriphosphate (ATPgammaS), alone at a low salt concentration did not change the fluorescence of Trp65, confirming that the residue is not close to the nucleotide. In contrast, the binding of single-stranded DNA quenched the fluorescence of Trp65 in both the presence and absence of ATPgammaS. Trp65 fluorescence was also quenched upon binding a second DNA strand. The fluorescence change depended upon the presence and absence of ATPgammaS, reflecting the difference in the DNA binding. These results indicate that residue 65 is close to both the first and second DNA strands. The degree of quenching depended upon the base composition of DNA, suggesting that the residue 65 interacts with the DNA bases. Binding of DNA with ATPgammaS as well as binding of ATPgammaS alone at high salt concentration shifted the fluorescence emission peak from 345 to 330 nm, indicating a change from a polar to a non-polar environment. Therefore, the environment change around residue 65 would also be linked to a change in conformation and thus the activation of the protein.

Structural and functional comparative study of the complexes formed by viral ø29, Nf and GA-1 SSB proteins with DNA

Single-stranded DNA-binding proteins have in common their crucial roles in DNA metabolism, although they exhibit significant differences in their single-stranded DNA binding properties. To evaluate the correlation between the structure of different nucleoprotein complexes and their function, we have carried out a comparative study of the complexes that the single-stranded DNA-binding proteins of three related bacteriophages, ø29, Nf and GA-1, form with single-stranded DNA. Under the experimental conditions used, ø29 and Nf single-stranded DNA-binding proteins are stable monomers in solution, while GA-1 single-stranded DNA-binding protein presents a hexameric state, as determined in glycerol gradients. The thermodynamic parameters derived from quenching measurements of the intrinsic protein fluorescence upon single-stranded DNA binding revealed (i) that GA-1 single-stranded DNA-binding protein occludes a larger binding site (n=51 nt/oligomer) than ø29 and Nf SSBs (n=3.4 and 4.7 nt/monomer, respectively); and (ii) that it shows a higher global affinity for single-stranded DNA (GA-1 SSB, K(eff)=18.6 x 10(5) M(-1); o29 SSB, K(eff)=2.2 x 10(5) M(-1); Nf SSB, K(eff)=2.9 x 10(5) M(-1)). Altogether, these parameters justify the differences displayed by the GA-1 single-stranded DNA-binding protein and single-stranded DNA complex under the electron microscope, and the requirement of higher amounts of ø29 and Nf single-stranded DNA-binding proteins than of GA-1 SSB in gel mobility shift assays to produce a similar effect. The structural differences of the nucleoprotein complexes formed by the three single-stranded DNA-binding proteins with single-stranded DNA correlate with their different functional stimulatory effects in ø29 DNA amplification.

A phylogenomic study of DNA repair genes, proteins, and processes

The ability to recognize and repair abnormal DNA structures is common to all forms of life. Studies in a variety of species have identified an incredible diversity of DNA repair pathways. Documenting and characterizing the similarities and differences in repair between species has important value for understanding the origin and evolution of repair pathways as well as for improving our understanding of phenotypes affected by repair (e.g., mutation rates, lifespan, tumorigenesis, survival in extreme environments). Unfortunately, while repair processes have been studied in quite a few species, the ecological and evolutionary diversity of such studies has been limited. Complete genome sequences can provide potential sources of new information about repair in different species. In this paper, we present a global comparative analysis of DNA repair proteins and processes based upon the analysis of available complete genome sequences. We use a new form of analysis that combines genome sequence information and phylogenetic studies into a composite analysis we refer to as phylogenomics. We use this phylogenomic analysis to study the evolution of repair proteins and processes and to predict the repair phenotypes of those species for which we now know the complete genome sequence.

Quantitative analysis of the kinetics of end-dependent disassembly of RecA filaments from ssDNA

On linear single-stranded DNA, RecA filaments assemble and disassemble in the 5' to 3' direction. Monomers (or other units) associate at one end and dissociate from the other. ATP hydrolysis occurs throughout the filament. Dissociation can result when ATP is hydrolyzed by the monomer at the disassembly end. We have developed a comprehensive model for the end-dependent filament disassembly process. The model accounts not only for disassembly, but also for the limited reassembly that occurs as DNA is vacated by disassembling filaments. The overall process can be monitored quantitatively by following the resulting decline in DNA-dependent ATP hydrolysis. The rate of disassembly is highly pH dependent, being negligible at pH 6 and reaching a maximum at pH values above 7. 5. The rate of disassembly is not significantly affected by the concentration of free RecA protein within the experimental uncertainty. For filaments on single-stranded DNA, the monomer kcat for ATP hydrolysis is 30 min-1, and disassembly proceeds at a maximum rate of 60-70 monomers per minute per filament end. The latter rate is that predicted if the ATP hydrolytic cycles of adjacent monomers are not coupled in any way.

TRF1 promotes parallel pairing of telomeric tracts in vitro

Human telomeres consist of long arrays of TTAGGG repeats bound to the telomere-specific proteins, TRF1 and TRF2. Here we describe the structure of in vitro complexes formed between telomeric DNA and TRF1 as deduced by electron microscopy. Visualization of TRF1 bound to DNA containing six or 12 tandem TTAGGG repeats revealed a population of DNAs containing a spherical protein complex localized just to the repeats. Mass analysis of the protein complexes suggested binding of TRF1 dimers and tetramers to the TTAGGG repeats. The DNA was not significantly compacted or extended by protein binding. TRF1 formed filamentous structures on longer telomeric repeat arrays (>/=27 repeats) consistent with the presence of an array of bound TRF1 dimers. Unexpectedly, there was a strong propensity for two telomeric tracts to form paired synapses over the TRF1 covered segment. Up to 30% of the TRF1-bound DNAs could be found in a paired configuration with a strong bias for a parallel as contrasted to an antiparallel arrangement. TRF1-induced pairing was confirmed using a ligation assay which detected the formation of DNA multimers dependent on the presence of TRF1 and a 27mer repeat array in the DNA. These findings suggests that this protein may have an architectural role at telomeres. We discuss the possibility that TRF1-dependent changes in the conformation of telomeres are involved in the regulation of telomere length.

Roles of Tyr103 and Tyr264 in the regulation of RecA-DNA interactions by nucleotide cofactors

The DNA-binding mode of the RecA protein, in particular its dependence on nucleotide cofactor, has been investigated by monitoring the fluorescence and linear-dichroism signals of a tryptophan residue inserted in the RecA to replace tyrosine at position 103 or 264. These residues are important for cofactor and DNA binding, as evidenced from their fluorescence changes upon binding of cofactor and DNA [Morimatsu, K., Horii, T. & Takahashi, M. (1995) Eur. J. Biochem. 228, 779-785]. The substitution of these residues with tryptophan does not affect the structure or biological function of the complex and can therefore be exploited to gain structural information in terms of the orientation and environment of the inserted reporter chromophore. The fluorescence change upon formation of the ternary cofactor.RecA. DNA complex was much smaller than the sum of the changes induced by cofactor or DNA alone. This difference indicates that the cofactor and DNA interact with RecA via common components. The fluorescence change caused by DNA in the presence of cofactor was almost independent of the base composition of DNA, in contrast to the interaction in the absence of cofactor. Hence, the contact mode between the selected residues and DNA in the complex may depend significantly on the cofactor. Linear-dichroism measurements indicate that the cofactor does not markedly alter the organization of RecA filament. Linear dichroism shows that neither the aromatic moiety of residue 103 nor that of residue 264 is intercalated between the DNA bases. The textural changes reported for the helical pitch and contour length of RecA fiber upon interaction with cofactor and DNA may derive from a subtle change in orientation of the RecA subunits in the filament.

Isolation, characterization, and magnesium-induced self-association kinetics of discrete aggregates of RecA protein from Escherichia coli

Dynamic and static intensity light scattering techniques were employed to identify conditions allowing preparation of homogeneous solutions of distinct oligomeric states of RecA protein. These hydrodynamically distinguishable oligomer populations of RecA protein were obtained in homogeneous pure quantities sufficient for physical studies. Results indicate two fairly narrow distributions of RecA oligomers comprised on average of 42 +/- 3 and 18 +/- 1 RecA monomers. These structures, denoted RecA42 and RecA18, respectively, could be obtained reproducibly in milligram quantities and were stable for at least one week. This enabled reliable characterizations of their hydrodynamic properties by dynamic and total intensity light scattering. These measurements revealed RecA42 had an average translational diffusion coefficient, D20(L) = 8 +/- 2 x 10(-8) cm2/s, molecular weight, M(r) = 1.6 +/- 0.1 x 10(6), and radius of gyration, RG = 465 +/- 29 A. The smaller aggregate, RecA18, had D20(S) = 20.5 +/- 2.5 x 10(-8) cm2/s, M(r) = 7.0 +/- 0.4 x 10(5), and RG = 300 +/- 20 A. Heating RecA18 at 37 degrees C overnight resulted in conversion to a species with hydrodynamic properties indistinguishable from RecA42, called RecA18/42. Conversion of RecA42 to RecA18 occurred almost instantaneously by 50% dilution at 38 degrees C or very slowly with incubation at 4 degrees C for at least 39 days. Self-association reactions of the three starting oligomeric states (RecA18, RecA42, and RecA18/42) induced by MgCl2 were monitored at several temperatures by dynamic light scattering. Results of these experiments provided evaluations of kinetic activation parameters of the self-association reactions. The activation parameters found for each starting oligomeric state of the protein were significantly different, revealing the variable influence of MgCl2 on the activation barriers to RecA self-association. Highly aggregated equilibrium solutions that ultimately form in solutions of each starting oligomeric species, incubated in MgCl2 at 38 degrees C for four days, were characterized by total intensity light scattering. Interpretations of these data in terms of characteristic behavior of random polymers suggests the surface morphologies of these highly associated equilibrium states formed from RecA42 and RecA18/42 are similar but contrast with that of RecA18. Calculated values of the translational diffusion coefficient D0 were obtained for oligomeric structures modeled as helical arrays of connected monomer spheres. Best agreement with experimentally determined diffusion coefficients required that constituent monomer spheres of RecA42 have radii 33-40% larger than the monomer spheres of RecA18. Results suggest the hydrodynamically distinct oligomeric forms of RecA may reside in conformational states with different surface exposure of hydrophobic residues, which results in substantial differences in local solvation/hydration.

DNA strand exchange mediated by a RAD51-ssDNA nucleoprotein filament with polarity opposite to that of RecA

Yeast RAD51 gene functions in genetic recombination and DNA double-strand break repair. In vitro, in the presence of ATP and replication protein A, RAD51 protein pairs single-stranded DNA (ssDNA) with homologous double-stranded DNA (dsDNA) and catalyzes strand exchange between the synapsed DNA partners. Electron microscopic analyses show that RAD51 forms helical filaments on both ssDNA and dsDNA, in which the DNA is highly extended. However, results presented here indicate that only the RAD51-ssDNA nucleoprotein filament is functionally relevant. Strand exchange is arrested when heterology is encountered in the duplex partner, and analysis of the configuration of the terminal joint thus formed reveals that pairing and strand exchange initiate at the 5' end of the complementary strand in the linear duplex, a reaction polarity opposite to that of the bacterial prototype RecA.

Properties of RecA-oligonucleotide complexes

The interaction of RecA protein with short single-stranded oligonucleotides is characterised by flow linear dichroism (LD), isoelectric focusing (IEF) and electron microscopy (EM). From LD and EM it is evident that RecA forms long filaments with at least some 50 oligonucleotides in a 'train formation'. The tendency to form trains is substantially lower when an amino group is attached to the 5' end of the oligonucleotide, suggesting that the modification impairs protein-protein interactions at the interface between two oligomers. From LD it is also evident that no bridging occurs between RecA-oligonucleotide complexes containing more than one oligomer strand per RecA filament. This property make them manageable in polyacrylamide gels, hence allowing characterisation by IEF. RecA was found acidic with a pI of 5.0. The pI was not dependent on the presence of bound cofactor (ATP gamma S) and oligonucleotides suggesting that protonation of the protein readily occurs to compensate for the negative charges provided by bound cofactor and DNA.

Biochemistry of homologous recombination in Escherichia coli

Homologous recombination is a fundamental biological process. Biochemical understanding of this process is most advanced for Escherichia coli. At least 25 gene products are involved in promoting genetic exchange. At present, this includes the RecA, RecBCD (exonuclease V), RecE (exonuclease VIII), RecF, RecG, RecJ, RecN, RecOR, RecQ, RecT, RuvAB, RuvC, SbcCD, and SSB proteins, as well as DNA polymerase I, DNA gyrase, DNA topoisomerase I, DNA ligase, and DNA helicases. The activities displayed by these enzymes include homologous DNA pairing and strand exchange, helicase, branch migration, Holliday junction binding and cleavage, nuclease, ATPase, topoisomerase, DNA binding, ATP binding, polymerase, and ligase, and, collectively, they define biochemical events that are essential for efficient recombination. In addition to these needed proteins, a cis-acting recombination hot spot known as Chi (chi: 5'-GCTGGTGG-3') plays a crucial regulatory function. The biochemical steps that comprise homologous recombination can be formally divided into four parts: (i) processing of DNA molecules into suitable recombination substrates, (ii) homologous pairing of the DNA partners and the exchange of DNA strands, (iii) extension of the nascent DNA heteroduplex; and (iv) resolution of the resulting crossover structure. This review focuses on the biochemical mechanisms underlying these steps, with particular emphases on the activities of the proteins involved and on the integration of these activities into likely biochemical pathways for recombination.

Why does RecA protein hydrolyse ATP?

RecA is a DNA-dependent ATPase involved in DNA-strand repair. Most of the ATP hydrolysis that occurs in a RecA nucleoprotein filament is implicitly considered to be irrelevant in many current models for RecA-mediated DNA-strand exchange. However, preventing RecA from hydrolysing ATP alters its behavior, suggesting that ATP hydrolysis by RecA is more than incidental. This review explores recent results detailing the effects and rates of ATP hydrolysis by RecA, and models are proposed that permit us to account quantitatively for ATP consumption by this protein.

The search for the right partner: homologous pairing and DNA strand exchange proteins in eukaryotes

Finding the right partner is a central problem in homologous recombination. Common to all models for general recombination is a homologous pairing and DNA strand exchange step. In prokaryotes this process has mainly been studied with the RecA protein of Escherichia coli. Two approaches have been used to find homologous pairing and DNA strand exchange proteins in eukaryotes. A biochemical approach has resulted in numerous proteins from various organisms. Almost all of these proteins are biochemically fundamentally different from RecA. The in vivo role of these proteins is largely not understood. A molecular-genetical approach has identified structural homologs to the E. coli RecA protein in the yeast Saccharomyces cerevisiae and subsequently in other organisms including other fungi, mammals, birds, and plants. The biochemistry of the eukaryotic RecA homologs is largely unsolved. For the fungal RecA homologs (S. cerevisiae RAD51, RAD55, RAD57, DMC1; Schizosaccharomyces pombe rad51; Neurospora crassa mei3) a role in homologous recombination and recombinational repair is evident. Besides recombination, homologous pairing proteins might be involved in other cellular processes like chromosome pairing or gene inactivation.

Accessibility to modification of histidine residues of RecA protein upon DNA and cofactor binding

The potential role of histidine residues of RecA protein in binding DNA has been investigated by monitoring their accessibility to diethylpyrocarbonate. In the absence of both DNA and cofactor, only one of two histidine residues is modified by the reagent, indicating that the other residue is buried. However, both histidine residues become accessible after addition of cofactor analog adenosine 5'-O-(3-thiotriphosphate) (ATP[S]) indicating a change in the organization of the RecA filament and/or a change in the conformation of protein. The diethylpyrocarbonate-modified RecA is found to be able to polymerize just as the unmodified protein. The binding of double-stranded DNA, in the presence of ATP[S], reduces the reactivity of both histidine residues to diethylpyrocarbonate. The binding of single-stranded DNA (with ATP[S]) has a similar, though smaller, protective effect. However, no significant dissociation of either of the complexes as a result of the modification was observed and a RecA molecule which had been modified in the absence of DNA could still bind DNA. A protection of the histidine residues is also effected by high salt concentration which promotes, just as DNA binding, ATPase and coprotease activity in RecA. The protection of histidine residues to diethylpyrocarbonate upon DNA binding probably relates to a conformational change of RecA and may not be any direct effect of shielding by the DNA. Nonetheless, the domains including the histidine residues could be centers of allosteric effects and are concluded to be close to the DNA binding site.

Early stages in RecA protein-catalyzed pairing. Analysis of coaggregate formation and non-homologous DNA contacts

RecA protein will catalyze the in vitro pairing of homologous DNA molecules. To further explore the events involved in the search for homology, we have applied a nitrocellulose filter binding assay to follow pairing, and a sedimentation assay to follow the generation of aggregates (termed coaggregates) formed between RecA-complexed single-stranded (ss) DNA and double stranded (ds) DNA. Electron microscopy (EM) was used to visualize the structures involved. RecA protein promoted the pairing of circular M13 ssDNA and linear M13mp7 dsDNA efficiently in the absence of coaggregates. Indeed, pairing of homologous ss- and dsDNAs involved coaggregate formation only if the dsDNA was circular. For DNAs containing only a few hundred base-pairs of homology, for example pUC7 dsDNA and M13mp7 ssDNA, pairing and joint formation was observed if the dsDNA was superhelical but not if it was topologically relaxed or linear with the homology internal to an end of the dsDNA. The effect of non-covalently attached heterologous dsDNA on the RecA-promoted joining of M13 ssDNA and linear M13mp7 dsDNA (with non-M13 sequences at both ends) was found to depend on the topology and concentration of the heterologous DNA. A tenfold excess of superhelical pBR322 DNA strongly inhibited pairing. However, addition of relaxed or linear pBR322 DNA to the pairing reaction had little effect. As seen by EM, superhelical pBR322 DNA inhibited joint formation by excluding the homologous dsDNA form the coaggregates. EM also revealed heterologous DNA interactions presumably involved in the search for homology. Here the use of EM has provided a direct visualization of the form and architecture of coaggregates revealing a dense interweaving of presynaptic filaments and dsDNA.

Coordination and internal exchange of two DNA molecules in a RecA filament in the presence of hydrolysing ATP. Information on ATP-RecA-DNA structure from linear dichroism spectroscopy

Solution structure of complexes between DNA and recombinase RecA from Escherchia coli, in the presence of the physiological cofactor ATP, is probed by flow linear dichroism (LD) spectroscopy. A problem of ADP accumulation which promotes dissociation of DNA-RecA is circumvented by using an ATP-regenerating system. The LD features indicate that the local structure of the complex is very similar to that found in the presence of the non-hydrolysable analog of ATP, adenosine-5'-O-[gamma-thio]triphosphate (ATP[gamma S]); the DNA bases are oriented with their planes preferentially perpendicular to the long axis of the filament, while the indole chromophores of the two tryptophan residues of RecA are rather parallel to this reference direction. A much smaller overall amplitude of the LD spectrum, compared to ATP[gamma S], is interpreted as a result of fast dissociation of RecA due to hydrolysis of ATP, producing transiently naked DNA regions which act like flexible joints, diminishing the macroscopic orientation of the RecA filaments. However, the ATP hydrolysis is not found to prevent simultaneous accommodation of two non-complementary DNA molecules in the RecA complex, as judged from the LD behaviour upon successive addition of two different polynucleotides or modified DNA strands. A notable difference from corresponding complexes formed with ATP[gamma S] is that, in the presence of ATP hydrolysis, the order in which the two DNA molecules have been added is insignificant as judged from virtually identical resulting structures; this observation indicates that exchange of DNA occurs between the two DNA accommodation sites within the RecA filament.

Structure of RecA-DNA complexes studied by combination of linear dichroism and small-angle neutron scattering measurements on flow-oriented samples

By combining anisotropy of small-angle neutron scattering (SANS) and optical anisotropy (linear dichroism, l.d.) on flow-oriented RecA-DNA complexes, the average DNA-base orientation has been determined in RecA complexes with double-stranded (ds) as well as single-stranded (ss) DNA. From the anisotropy of the two-dimensional SANS intensity representation, the second moment orientation function S is obtained. Knowledge of S is crucial for the interpretation of l.d. spectra in terms of orientation of the DNA bases and the aromatic amino acid residues. The DNA-base planes are essentially perpendicular to the fibre axis of the complex between RecA and dsDNA in the presence of cofactor ATP gamma S. A somewhat tilted base geometry is found for the RecA-ATP gamma S complexes with single-stranded poly(dT) and poly(d epsilon A). This behaviour contrasts the RecA-ssDNA complex formed without cofactor which displays a poor orientation of the bases. Well-ordered bases in the ssDNA-RecA complex is possibly reflecting the role of RecA in preparing a nucleotide strand for base-pairing in the search-for-homology process. While the central SANS intensity is essentially independent of the pitch of the helical complex, a secondary intensity maximum, which becomes focused upon flow orientation, is found to be a sensitive measure of the pitch. The pitch values for the complexes compare well with cryo-electron microscopy results but are slightly larger than those seen for uranyl-stained samples.

Structure of DNA-RecA complexes studied by residue differential linear dichroism and fluorescence spectroscopy for a genetically engineered RecA protein

The structure of complexes of RecA with double-stranded and single-stranded DNA was studied by linear dichroism spectroscopy, fluorescence quenching and fluorescence anisotropy measurements. One of the two tryptophan residues (Trp291) of RecA was replaced by genetic engineering for an ultraviolet light-transparent threonine. This modified RecA protein shows, within experimental errors, the same DNA-binding kinetics and stoichiometry as the wild-type protein and no significant variation with respect to in vivo repair function was observed between cells with the two protein forms. By comparing the dichroic and fluorescence properties of the wild-type versus the modified protein, when bound to DNA, information about orientation and environment of the Trp291 chromophore in the complex could be obtained. The indole chromophore of Trp291Z was found to be oriented with its pseudo-long axis tilted 61 degrees and the aromatic plane is tilted 27 degrees relative to the fibre axis. Trp291 shows low mobility within the protein and therefore the deduced orientation may be used as a "handle" on the protein at the construction of three-dimensional models of RecA-DNA complexes. Comparison with the orientation for this residue in the crystal structure of the RecA homopolymer fibre indicates no measurable reorientation of the C-terminal subdomain of RecA upon DNA binding. Whereas the accuracy of the orientation determination of tryptophan, in absolute terms, is rather poor, changes of its orientation can be detected with high precision. Thus, similar Trp291 orientations are obtained in the complexes with single-stranded and double-stranded DNA, indicating similar structures of the protein fibres. The fluorescence quenching results indicate that the protein region of Trp291 is not involved in the binding of DNA.

Effect of nucleotide cofactor structure on recA protein-promoted DNA pairing. 1. Three-strand exchange reaction

The structurally related nucleoside triphosphates, adenosine triphosphate (ATP), purine riboside triphosphate (PTP), inosine triphosphate (ITP), and guanosine triphosphate (GTP), are all hydrolyzed by the recA protein with the same turnover number (17.5 min-1). The S0.5 values for these nucleotides increase progressively in the order ATP (45 microM), PTP (100 microM), ITP (300 microM), and GTP (750 microM). PTP, ITP, and GTP are each competitive inhibitors of recA protein-catalyzed ssDNA-dependent ATP hydrolysis, indicating that these nucleotides all compete for the same catalytic site on the recA protein. Despite these similarities, ATP and PTP function as cofactors for the recA protein-promoted three-strand exchange reaction, whereas ITP and GTP are inactive as cofactors. The strand exchange activity of the various nucleotides correlates directly with their ability to support the isomerization of the recA protein to a strand exchange-active conformational state. The mechanistic deficiency of ITP and GTP appears to arise as a consequence of the hydrolysis of these nucleotides to the corresponding nucleoside diphosphates, IDP and GDP. We speculate the nucleoside triphosphates with S0.5 values greater than 100 microM will be intrinsically unable to sustain the strand exchange-active conformational state of the recA protein during ongoing NTP hydrolysis and will therefore be inactive as cofactors for the strand exchange reaction.

RecA protein-promoted homologous pairing and strand exchange between intact and partially single-stranded duplex DNA

In the pairing reaction between circular gapped and fully duplex DNA, RecA protein first polymerizes on the gapped DNA to form a nucleoprotein filament. Conditions that removed the formation of secondary structure in the gapped DNA, such as addition of Escherichia coli single-stranded DNA binding protein or preincubation in 1 mM-MgCl2, optimized the binding of RecA protein and increased the formation of joint molecules. The gapped duplex formed stable joints with fully duplex DNA that had a 5' or 3' terminus complementary to the single-stranded region of the gapped molecule. However, the joints formed had distinct properties and structures depending on whether the complementary terminus was at the 5' or 3' end. Pairing between gapped DNA and fully duplex linear DNA with a 3' complementary terminus resulted in strand displacement, symmetric strand exchange and formation of complete strand exchange products. By contrast, pairing between gapped and fully duplex DNA with a 5' complementary terminus produced a joint that was restricted to the gapped region; there was no strand displacement or symmetric strand exchange. The joint formed in the latter reaction was likely a three-stranded intermediate rather than a heteroduplex with the classical Watson-Crick structure. We conclude that, as in the three-strand reaction, the process of strand exchange in the four-strand reaction is polar and progresses in a 5' to 3' direction with respect to the initiating strand. The present study provides further evidence that in both three-strand and four-strand systems the pairing and strand exchange reactions share a common mechanism.

RecA-mediated annealing of single-stranded DNA and its relation to the mechanism of homologous recombination

We demonstrate that RecA protein can mediate annealing of complementary DNA strands in vitro by at least two different mechanisms. The first annealing mechanism predominates under conditions where RecA protein causes coaggregation of single-stranded DNA (ssDNA) molecules and where RecA-free ssDNA stretches are present on both reaction partners. Under these conditions annealing can take place between locally concentrated protein-free complementary sequences. Other DNA aggregating agents like histone H1 or ethanol stimulate annealing by the same mechanism. The second mechanism of RecA-mediated annealing of complementary DNA strands is best manifested when preformed saturated RecA-ssDNA complexes interact with protein-free ssDNA. In this case, annealing can occur between the ssDNA strand resident in the complex and the ssDNA strand that interacts with the preformed RecA-ssDNA complex. Here, the action of RecA protein reflects its specific recombination promoting mechanism. This mechanism enables DNA molecules resident in the presynaptic RecA-DNA complexes to be exposed for hydrogen bond formation with DNA molecules contacting the presynaptic RecA-DNA filament.

Use of ion exchange chromatography for the study of RecA-DNA interaction

In vitro binding of RecA protein to double-stranded DNA (dsDNA) was studied using ion-exchange liquid chromatography. The method allowed quantification of both free DNA and free protein. The results unambiguously showed a binding stoichiometry of 3 base pairs per RecA monomer. The binding exhibited cooperativity, and the stoichiometry suggested that RecA does not form complexes with two molecules of dsDNA. More than 90% of RecA molecules in the sample were active for DNA binding.

Co-ordination of multiple DNA molecules in RecA fiber evidenced by linear dichroism spectroscopy

Polarized light spectroscopy has been used to study the interaction of RecA protein with DNA. Several different DNA complexes have been identified and characterized with respect to stoichiometries, base orientation and nuclease accessibility. By using spectroscopically distinguishable DNAs, we determined the number of DNA molecules co-ordinated by the RecA fiber in each of these complexes, and established their base pairing abilities. Based on these observations, we discuss the molecular mechanism of the RecA-mediated strand exchange reaction.

On the polymerization state of recA in the absence of DNA

We present an electron microscopy study on the polymerization state of recA in the absence of DNA. In solution recA exists as monomers, small complexes not clearly longer than wide (approximately 9-18 nm), and filaments (diameter approximately 11 nm and variable lengths). We have attempted to quantify the relative amounts of these species by length measurements of the particles on electron micrographs. The percentages of each of these types was found to depend on recA concentration, temperature and presence in the incubation mixture of Mg2+, ATP gamma S, salt or D2O. These additives do not have an absolute effect on polymerization but rather shift the polymerization equilibrium of recA (which depends on recA concentration) up or down the concentration scale.

Dynamic light scattering investigations of RecA self-assembly and interactions with single strand DNA

Dynamic light scattering (DLS) measurements were performed on self-assembled solutions of RecA as a function of assembly time under strand exchange ionic strength conditions (10 mM MgCl2, 65 mM NaCl, 10 mM Tris-HCl, pH = 7.5, 1 mM DTT, 3-4 microM RecA) in the absence of ATP. These measurements yield distributions of the translational diffusion coefficients of the changing populations of assembling protein species. Interpretations of results of DLS measurements are made in terms of model hydrodynamic calculations that indicate, under the solution conditions employed, the smallest fundamental quaternary subunit of RecA is a hexamer in a toroidal or lock-washer configuration. Interactions of M13mp19 circular single strand DNA (ssDNA) with RecA assembled to different stages were also investigated. Additions of ssDNA to self-assembled solutions of RecA acts to dissociate the associated structures into hexamer subunits. However, the effect of ssDNA on assembled RecA is highly dependent on the RecA self-assembly state. The longer the assembly time, the less reversible the self-assembled structures of RecA become. Binding isotherms of titrated mixtures of ssDNA with RecA self-assembled to various stages were also determined. Evaluated dissociation constants of RecA/ssDNA complexes were found to increase with increases of the associated state of RecA. These results strongly suggest that, under the solvent conditions employed, the active ssDNA binding form of RecA is a hexamer.

Biochemical and biological function of Escherichia coli RecA protein: behavior of mutant RecA proteins

The recA protein of E coli participates in several diverse biological processes and promotes a variety of complex in vitro reactions. A careful comparison of the phenotypic behavior of E coli recA mutations to the biochemical properties of the corresponding mutant proteins reveals a close parallel both between recombination phenotype and DNA strand exchange and renaturation activities, and between inducible phenomena and repressor cleavage activity. The biochemical alterations manifest by the mutant recA proteins are reflected in the strength of their interaction with ssDNA. The defective mutant recA proteins fail to properly assume the high-affinity DNA-binding state that is characteristic of the wild-type protein and, consequently, form less stable complexes with DNA. The mutant proteins displaying an 'enhanced' activity bind ssDNA with approximately the same affinity as the wild-type protein but, due to altered protein-protein interactions, they associate more rapidly with ssDNA. These changes proportionately affect the ability of recA protein to compete with SSB protein, to interact with dsDNA, and, perhaps, to bind repressor proteins. In turn, the DNA strand exchange, DNA renaturation, and repressor cleavage activities mirror these modifications.

RecA protein self-assembly. II. Analytical equilibrium ultracentrifugation studies of the entropy-driven self-association of RecA

We have investigated the self-association of RecA protein from Escherichia coli by equilibrium ultracentrifugation. Monomeric RecA (Mr = 37,842) was observed in reversible equilibrium with trimers, hexamers and dodecamers in the presence of 1.5 M-KCl, 5 mM-Hepes, 1 mM-EDTA, 2 mM-ATP (pH 7.0) at 1 degrees C. The equilibrium was strongly temperature-dependent, with polymerization being favored as the temperature was raised from 1 degrees C 21 degrees C, and was reversible with respect to temperature. The values of both the standard enthalpy and entropy of self-association were positive, indicating that it is an entropy-driven process under these conditions. In the absence of KCl, in 50 mM-citrate, 5 mM-ATP, 5% (v/v) glycerol (pH 6.0) at 4 degrees C, only small amounts of RecA monomer could be detected, while in 10 mM-Tris-acetate, 10% glycerol (pH 7.5) at 4 degrees C, the smallest species present in significant concentration appeared to be the trimer. The majority of the species observed had molecular weights between 228,000 and 456,000, suggesting dominant stoichiometries of six to 12 monomers per oligomer. At pH 6.0, in the absence of ATP, much larger oligomers containing at least 24 monomers also appeared to be present. The data are consistent with an equilibrium mixture of monomers, trimers, hexamers, dodecamers, 24-mers and higher oligomers, with the distribution of oligomers being dependent on solution conditions. Thermodynamic analysis indicates that these oligomeric species are in reversible equilibrium with each other. It is not certain whether trimers assemble directly into hexamers, or whether disassembly into monomers is a prerequisite for the formation of higher oligomers. The possible role of higher-order RecA oligomers in the formation of RecA nucleoprotein filaments is discussed.

The single-stranded DNA-binding protein of Escherichia coli

The single-stranded DNA-binding protein (SSB) of Escherichia coli is involved in all aspects of DNA metabolism: replication, repair, and recombination. In solution, the protein exists as a homotetramer of 18,843-kilodalton subunits. As it binds tightly and cooperatively to single-stranded DNA, it has become a prototypic model protein for studying protein-nucleic acid interactions. The sequences of the gene and protein are known, and the functional domains of subunit interaction, DNA binding, and protein-protein interactions have been probed by structure-function analyses of various mutations. The ssb gene has three promoters, one of which is inducible because it lies only two nucleotides from the LexA-binding site of the adjacent uvrA gene. Induction of the SOS response, however, does not lead to significant increases in SSB levels. The binding protein has several functions in DNA replication, including enhancement of helix destabilization by DNA helicases, prevention of reannealing of the single strands and protection from nuclease digestion, organization and stabilization of replication origins, primosome assembly, priming specificity, enhancement of replication fidelity, enhancement of polymerase processivity, and promotion of polymerase binding to the template. E. coli SSB is required for methyl-directed mismatch repair, induction of the SOS response, and recombinational repair. During recombination, SSB interacts with the RecBCD enzyme to find Chi sites, promotes binding of RecA protein, and promotes strand uptake.

Structure of a RecA-DNA complex from linear dichroism and small-angle neutron-scattering in flow-oriented solution

Small-angle neutron-scattering (SANS) and ultraviolet linear dichroism (l.d.) were measured on identical samples of a RecA-double-stranded (ds) DNA complex, including cofactor adenosine 5'-O-thiotriphosphate, which were aligned by flow in two equivalent Couette devices made of niobium and silica, transparent to neutrons and to ultraviolet light, respectively. The SANS anisotropy indicates a modest orientation of the RecA-dsDNA fiber with the helix axis parallel to the flow field. By correlation with the corresponding l.d. of the DNA at the same orientation conditions, it is inferred that the DNA bases have a local orientation that is approximately perpendicular to the helix axis. By comparison with the worse orientation in single-stranded DNA-RecA, this conclusion suggests that the dsDNA in its complex with RecA is not strand separated, and may be accommodated as an essentially unperturbed, straight double helix running along the RecA polymer fiber. The SANS anisotropy is also found to support the assignment of a subsidiary intensity maximum as originating from the pitch of a helical fiber.

Three-stranded paranemic joints: architecture, topological constraints and movement

The RecA and SSB proteins will catalyze the joining of two DNA molecules containing homologous sequences but lacking homologous ends in a reaction termed paranemic joining. The absence of homologous ends can be achieved by (1) pairing two circular DNAs or (2) using linear DNA(s) with ends lacking homology to the pairing partner. Here we have used electron microscopy (EM) to examine such pairings. Circular M13 single-stranded (ss) DNA enveloped by RecA protein into a presynaptic filament was paired with linear M13mp7 double-stranded (ds) DNA containing non-M13 sequences at its ends. Joint complexes were frequently seen in which the dsDNA was joined with the presynaptic filament over several kilobase (10(3) bases) lengths of the dsDNA. In this region, the presynaptic filament appeared disorganized as contrasted to the customary helical structure of the filament containing only a single strand of DNA. The same ultrastructure, but with greater detail, was observed when the samples were prepared for EM without fixation using a new method of fast-freezing and freeze-drying. EM immunogold staining demonstrated the presence of SSB protein in the disorganized region containing all three strands, but not in the regular helically arranged region. Psoralen photo-crosslinking of the DNA in the joint complexes revealed that the three DNA strands were in close proximity only over a single short (200 to 300 base-pairs) region. The joining of nicked circular M13 dsDNA and presynaptic filaments containing circular M13 ssDNA resulted in the intertwining of the dsDNA about the circular presynaptic filament. The joints produced in this case were short, as was the single region of psoralen photo-crosslinking of the three DNA strands. A model of how these long three-stranded joints form is presented involving the movement of a short "true" paranemic joint along the presynaptic filament.