Coli Single-stranded DNA Binding Protein Research Articles

Single-stranded DNA binding protein hitches a ride with the Escherichia coli YoaA-χ helicase.

The Escherichia coli XPD/Rad3-like helicase, YoaA, and DNA polymerase III subunit, χ, are involved in E. coli DNA damage tolerance and repair. YoaA and χ promote tolerance to the DNA chain-terminator, 3□-azidothymidine (AZT), and together form the functional helicase complex, YoaA-χ. How YoaA-χ contributes to DNA damage tolerance is not well understood. E. coli single-stranded DNA binding protein (SSB) accumulates at stalled replication forks, and the SSB-χ interaction is required to promote AZT tolerance via an unknown mechanism. YoaA-χ and SSB interactions were investigated in vitro to better understand this DNA damage tolerance mechanism, and we discovered YoaA-χ and SSB have a functional interaction. SSB confers a substrate-specific effect on the helicase activity of YoaA-χ, barely affecting YoaA-χ on an overhang DNA substrate but inhibiting YoaA-χ on forked DNA. A paralog helicase, DinG, unwinds SSB-bound DNA in a similar manner to YoaA-χ on the substrates tested. Through use of ensemble experiments, we believe SSB binds behind YoaA-χ relative to the DNA ds/ss junction and show via single-molecule assays that SSB translocates along ssDNA with YoaA-χ. This is, to our knowledge, the first demonstration of a mechanoenzyme pulling SSB along ssDNA.

E. coli Single-Stranded DNA Binding (SSB) Protein Undergoes Dynamic Liquid-Liquid Phase Separation Controlled via Protein-Protein and Protein-DNA Interactions

A number of eukaryotic proteins have recently been shown to form phase-separated liquid condensates (membrane-less organelles) playing key roles in normal cell physiology and stress tolerance as bioreactors, biomolecular filters, stress sensors or molecular reservoirs. However, it is still debated whether liquid-liquid phase separation (LLPS) is a fundamental process in bacteria as it is in eukaryotes. Here we report the striking observation that the E. coli SSB protein, a ubiquitous central player of practically all DNA metabolic processes, forms phase-separated condensates under physiological conditions. LLPS is generally driven by multivalent weak protein-protein or protein-nucleic acid interactions, mediated mostly by intrinsically disordered protein regions. We found that LLPS by the homotetrameric SSB protein is mediated via multifaceted inter-tetramer interactions involving all protein regions including the conserved ssDNA-binding domain, the intrinsically disordered linker (IDL) and the C-terminal peptide (CTP, a highly conserved protein-protein interaction motif binding to a variety of DNA metabolic proteins). SSB, ssDNA and SSB-interacting partners are highly concentrated within the phase-separated droplets, whereas LLPS is overall regulated by the stoichiometry of SSB and ssDNA. Our bioinformatics analysis indicates that the LLPS-forming propensity of the SSB IDL is broadly conserved across all major phylogenetic groups of Eubacteria. Together with recently observed dynamic spot-like subcellular localization patterns of SSB, our results suggest that bacterial cells store an abundant pool of SSB and SSB-interacting proteins in phase-separated condensates via a conserved mechanism. The discovered features enable rapid mobilization of SSB to ssDNA regions exposed upon DNA damage or metabolic processes to serve efficient repair, replication and recombination.

Assembly and Binding of E. coli RecOR Proteins to SSB C-Terminal Tails

The E. coli single-stranded DNA binding (SSB) protein interacts with at least 17 different proteins, known as SSB-interacting proteins (SIPs), during DNA replication, repair, and recombination. The E. coli RecO protein is a recombination mediator protein functioning in complex with RecF and RecR proteins in the RecF pathway of homologous recombination. RecO has been shown to interact with the last 9 amino acids of the intrinsically disordered C-terminal tails of SSB (SSB-Ct). Although structures of RecOR complexes from organisms, such as D. Radiodurans and T. Tencongensis, have been determined, they differ in stoichiometry. Furthermore, structures of the E. coli RecOR complex are not yet available. We therefore investigated the assembly states of RecO and RecR, and RecOR complexes using analytical ultracentrifugation. We find that E. coli RecO is a stable monomer. Although E. coli RecR had previously been reported to form a dimer, we find that it is in a pH-dependent dimer-tetramer equilibrium. We also find that only the RecR tetramer and not the dimer binds RecO and that the SSB-C-terminal peptide destabilizes the RecOR4 complex (supported by NIH GM030498 to TML).

Escherichia coli AlkB and single-stranded DNA binding protein SSB interaction explored by Molecular Dynamics Simulation

Repair of alkylation damage in DNA is essential for maintaining genome integrity. Escherichia Coli (E.coli) DNA repair enzyme AlkB removes methyl adducts including 1-methyladenine and 3-methylcytosine present in DNA by oxidative demethylation from single-stranded DNA (ssDNA). E. coli single-stranded DNA binding protein (SSB) selectively binds ssDNA in a sequence-independent manner. We have recently shown that AlkB can repair methyl adduct present in SSB-coated ssDNA. In this study, we aimed to elucidate details of AlkB-mediated DNA repair of SSB-bound DNA substrate. Therefore, we generated a structural model of AlkB-SSB-ssDNA and using Molecular Dynamics simulation analysis we show that flexibility of SSB-bound DNA allows AlkB to bind in multiple ways. Our docking analysis of AlkB-SSB-ssDNA structure revealed that the Cyt109 base is present in the hydrophobic cavity of AlkB active site pocket. The characterization of AlkB-SSB interaction pattern would likely to help in understanding the mode of alkylated DNA adduct recognition by AlkB.

Allosteric Effect of E. coli SSB C-Terminal Tails on RecOR Binding to DNA

The E. coli single-stranded DNA binding (SSB) protein interacts with at least 15 different proteins, known as SSB-interacting proteins (SIP), during DNA replication, repair, and recombination. However, the specificity by which SSB differentiates and recruits each SIP for different roles is not understood. The E. coli RecO protein is a recombination mediator protein (RMP) involved in the RecF pathway of homologous recombination. RecO forms complexes with RecF and RecR, and is thought to interact with the last 9 amino acids of the intrinsically disordered C-terminal tails of SSB (SSB-Ct). We are examining the interaction of SSB with RecOR by monitoring the change in intrinsic Trp fluorescence of RecO. We observe an allosteric effect of the SSB-Ct on DNA binding by RecOR, such that the SSB-Ct peptide enhances RecOR binding to ssDNA. Whereas structures of RecOR complexes from other organisms, such as D. Radiodurans and T. Tengcongensis, have been determined, they differ in stoichiometry. Furthermore, structures of the E. coli RecOR complex are not available. We therefore are investigating the functional oligomeric state of RecO and RecR, and the stoichiometry of the RecOR complex using analytical ultracentrifugation and isothermal titration calorimetry. E. coli RecR had previously been reported to form a dimer, but we find that it is in a dimer-tetramer equilibrium and the RecR tetramer appears to be the form that binds RecO (supported by NIH GM030498 to TML).

SSB binds to the RecG and PriA helicases invivo in the absence of DNA.

The E. coli single-stranded DNA-binding protein (SSB) binds to the fork DNA helicases RecG and PriA in vitro. Typically for binding to occur, 1.3 m ammonium sulfate must be present, bringing into question the validity of these results as these are nonphysiological conditions. To determine whether SSB can bind to these helicases, we examined binding in vivo. First, using fluorescence microscopy, we show that SSB localizes PriA and RecG to the vicinity of the inner membrane in the absence of DNA damage. Localization requires that SSB be in excess over the DNA helicases and the SSB C-terminus and both PriA and RecG be present. Second, using the purification of tagged complexes, our results show that SSB binds to PriA and RecG in vivo, in the absence of DNA. We propose that this may be the 'storage form' of RecG and PriA. We further propose that when forks stall, RecG and PriA are targeted to the fork by SSB, which, by virtue of its high affinity for single-stranded DNA, allows these helicases to outcompete other proteins. This ensures their actions in the early stages of the rescue of stalled replication forks.

The Integron Integrase Efficiently Prevents the Melting Effect of Escherichia coli Single-Stranded DNA-Binding Protein on Folded attC Sites

Integrons play a major role in the dissemination of antibiotic resistance genes among bacteria. Rearrangement of gene cassettes occurs by recombination between attI and attC sites, catalyzed by the integron integrase. Integron recombination uses an unconventional mechanism involving a folded single-stranded attC site. This site could be a target for several host factors and more precisely for proteins able to bind single-stranded DNA. One of these, Escherichia coli single-stranded DNA-binding protein (SSB), regulates many DNA processes. We studied the influence of this protein on integron recombination. Our results show the ability of SSB to strongly bind folded attC sites and to destabilize them. This effect was observed only in the absence of the integrase. Indeed, we provided evidence that the integrase is able to counterbalance the observed effect of SSB on attC site folding. We showed that IntI1 possesses an intrinsic property to capture attC sites at the moment of their extrusion, stabilizing them and recombining them efficiently. The stability of DNA secondary structures in the chromosome must be restrained to avoid genetic instability (mutations or deletions) and/or toxicity (replication arrest). SSB, which hampers attC site folding in the absence of the integrase, likely plays an important role in maintaining the integrity and thus the recombinogenic functionality of the integron attC sites. We also tested the RecA host factor and excluded any role of this protein in integron recombination.

The effect of single-stranded DNA binding proteins on template/primer-independent DNA synthesis in the presence of nicking endonuclease Nt.BspD6I

In the presence of the Nt.BspD6I nicking endonuclease DNA polymerase Bst stimulates intensive template/primer-independent DNA synthesis. Template/primer-independent DNA synthesis could be the reason for appearing nonspecific DNA products in many DNA amplification reactions particularly in the reactions with using nicking endonucleases. Search of the modes for inhibition template/primer-independent DNA synthesis becomes an urgent task because of broadening the DNA amplification methods with using nicking endonucleases. We report here that the E. coli single-stranded DNA binding protein has no effect on the template/primer-independent DNA synthesis. In the absence of the nicking endonuclease the single-stranded DNA binding protein encoded by bacteriophage T4 gene 32 completely inhibits template/primer-independent DNA synthesis. This protein does not inhibit synthesis of specific DNA product in the presence of nicking endonuclease but remarkably decreases the amount of nonspecific products.

Single-Stranded DNA Binding Proteins Unwind the Newly Synthesized Double-Stranded DNA of Model Miniforks

Single-stranded DNA binding (SSB) proteins are essential proteins of DNA metabolism. We characterized the binding of the bacteriophage T4 SSB, Escherichia coli SSB, human replication protein A (hRPA), and human hSSB1 proteins onto model miniforks and double-stranded-single-stranded (ds-ss) junctions exposing 3' or 5' ssDNA overhangs. T4 SSB proteins, E. coli SSB proteins, and hRPA have a different binding preference for the ss tail exposed on model miniforks and ds-ss junctions. The T4 SSB protein preferentially binds substrates with 5' ss tails, whereas the E. coli SSB protein and hRPA show a preference for substrates with 3' ss overhangs. When interacting with ds-ss junctions or miniforks, the T4 SSB protein, E. coli SSB protein, and hRPA can destabilize not only the ds part of a ds-ss junction but also the daughter ds arm of a minifork. The T4 SSB protein displays these unwinding activities in a polar manner. Taken together, our results position the SSB protein as a potential key player in the reversal of a stalled replication fork and in gap repair-mediated repetitive sequence expansion.

Molecular interactions of Escherichia coli ExoIX and identification of its associated 3'-5' exonuclease activity

The flap endonucleases (FENs) participate in a wide range of processes involving the structure-specific cleavage of branched nucleic acids. They are also able to hydrolyse DNA and RNA substrates from the 5′-end, liberating mono-, di- and polynucleotides terminating with a 5′ phosphate. Exonuclease IX is a paralogue of the small fragment of Escherichia coli DNA polymerase I, a FEN with which it shares 66% similarity. Here we show that both glutathione-S-transferase-tagged and native recombinant ExoIX are able to interact with the E. coli single-stranded DNA binding protein, SSB. Immobilized ExoIX was able to recover SSB from E. coli lysates both in the presence and absence of DNA. In vitro cross-linking studies carried out in the absence of DNA showed that the SSB tetramer appears to bind up to two molecules of ExoIX. Furthermore, we found that a 3′–5′ exodeoxyribonuclease activity previously associated with ExoIX can be separated from it by extensive liquid chromatography. The associated 3′–5′ exodeoxyribonuclease activity was excised from a 2D gel and identified as exonuclease III using matrix-assisted laser-desorption ionization mass spectrometry.

Herpes Simplex Virus Type 1 Single-Strand DNA Binding Protein ICP8 Enhances the Nuclease Activity of the UL12 Alkaline Nuclease by Increasing Its Processivity

UL12 is a 5'- to 3'-exonuclease encoded by herpes simplex virus type 1 (HSV-1) which degrades single- and double-stranded DNA. UL12 and the single-strand DNA binding protein ICP8 mediate a strand exchange reaction. We found that ICP8 inhibited UL12 digestion of single-stranded DNA but stimulated digestion of double-stranded DNA threefold. The stimulatory effect of ICP8 was independent of a strand exchange reaction; furthermore, the effect was specific to ICP8, as it could not be reproduced by Escherichia coli single-stranded DNA binding protein. The effect of ICP8 on the rate of UL12 double-stranded DNA digestion is attributable to an increase in processivity in the presence of ICP8.

Thermochemistry of Protein−DNA Interaction Studied with Temperature-Controlled Nonequilibrium Capillary Electrophoresis of Equilibrium Mixtures

We introduce temperature-controlled nonequilibrium capillary electrophoresis of equilibrium mixtures (NECEEM) and demonstrate its use to study thermochemistry of protein-DNA interactions. Being a homogeneous kinetic method, temperature-controlled NECEEM uniquely allows finding temperature dependencies of equilibrium and kinetic parameters of complex formation without the immobilization of the interacting molecules on the surface of a solid substrate. In this work, we applied temperature-controlled NECEEM to study the thermochemistry of two protein-DNA pairs: (i) Taq DNA polymerase with its DNA aptamer and (ii) E. coli single-stranded DNA binding protein with a 20-base-long single-stranded DNA. We determined temperature dependencies of three parameters: the equilibrium binding constant (Kb), the rate constant of complex dissociation (k(off)), and the rate constant of complex formation (k(on)). The Kb(T) functions for both protein-DNA pairs had phase-transition-like points suggesting temperature-dependent conformational changes in structures of the interacting macromolecules. Temperature dependencies of k(on) and k(off) provided insights into how the conformational changes affected two opposite processes: binding and dissociation. Finally, thermodynamic parameters, DeltaH and DeltaS, for complex formation were found for different conformations. With its unique features and potential applicability to other macromolecular interactions, temperature-controlled NECEEM establishes a valuable addition to the arsenal of analytical methods used to study dynamic molecular complexes.

Effects of single-stranded DNA binding proteins on primer extension by telomerase

We present a biochemical analysis of the effects of three single-stranded DNA binding proteins on extension of oligonucleotide primers by the Tetrahymena telomerase. One of them, a human protein designated translin, which was shown to specifically bind the G-rich Tetrahymena and human telomeric repeats, slightly stimulated the primer extension reactions at molar ratios of translin/primer of <1:2. At higher molar ratios, it inhibited the reactions by up to 80%. The inhibition was caused by binding of translin to the primers, rather than by a direct interaction of this protein with telomerase. A second protein, the general human single-stranded DNA binding protein Replication Protein A (RPA), similarly affected the primer extension by telomerase, even though its mode of binding to DNA differs from that of translin. A third protein, the E. coli single-stranded DNA binding protein (SSB), whose binding to DNA is highly cooperative, caused more substantial stimulation and inhibition at the lower and the higher molar ratios of SSB/primer, respectively. Both telomere-specific and general single-stranded DNA binding proteins are found in living cells in telomeric complexes. Based on our data, we propose that these proteins may exert either stimulatory or inhibitory effects on intracellular telomerases, depending on their local concentrations.

Non-equilibrium capillary electrophoresis of equilibrium mixtures--appreciation of kinetics in capillary electrophoresis.

We describe a new electrophoretic method (patent pending), Non-Equilibrium Capillary Electrophoresis of Equilibrium Mixtures (NECEEM), and demonstrate its application to the study of protein-DNA interactions. A single NECEEM experiment allows for the determination of equilibrium and kinetic parameters of protein-DNA complex formation. The equilibrium mixture is prepared by mixing protein and DNA; it contains three components: free protein, free DNA, and the protein-DNA complex. A small plug of such a mixture is injected onto a capillary and the three components are separated under non-equilibrium conditions using a run buffer that does not contain the components of the equilibrium mixture. The protein-DNA complex decays during the NECEEM separation; the resulting electropherograms contain characteristic peaks and exponential curves. A simple analysis of a single electropherogram reveals two parameters: the equilibrium dissociation constant of the protein-DNA complex and the monomolecular rate constant of complex decay. The bimolecular rate constant of complex formation can then be calculated as the ratio of the two experimentally-determined constants. NECEEM was applied to find the equilibrium and kinetic parameters of interaction between an E. coli single-stranded DNA binding protein and a fluorescently-labeled oligonucleotide. The constants determined by NECEEM are in good agreement with those obtained by other methods. The new method is simple, fast, and accurate. It can be equally applied to other non-covalent molecular complexes.

Parvovirus initiator protein NS1 and RPA coordinate replication fork progression in a reconstituted DNA replication system.

We show here that the DNA helicase activity of the parvoviral initiator protein NS1 is highly directional, binding to the single strand at a recessed 5' end and displacing the other strand while progressing in a 3'-to-5' direction on the bound strand. NS1 and a cellular site-specific DNA binding factor, PIF, also known as glucocorticoid modulating element binding protein, bind to the left-end minimal replication origin of minute virus of mice, forming a ternary complex. In this complex, NS1 is activated to nick one DNA strand, becoming covalently attached to the 5' end of the nick in the process and providing a 3' OH for priming DNA synthesis. In this situation, the helicase activity of NS1 did not displace the nicked strand, but the origin duplex was distorted by the NS1-PIF complex, as assayed by its sensitivity to KMnO(4) oxidation, and a stretch of about 14 nucleotides on both strands of the nicked origin underwent limited unwinding. Addition of Escherichia coli single-stranded DNA binding protein (SSB) did not lead to further unwinding. However, addition of recombinant human single-stranded DNA binding protein (RPA) to the initiation reaction catalyzed extensive unwinding of the nicked origin, suggesting that RPA may be required to form a functional replication fork. Accordingly, the unwinding mediated by NS1 and RPA promoted processive leading-strand synthesis catalyzed by recombinant human DNA polymerase delta, PCNA, and RFC, using the minimal left-end origin cloned in a plasmid as a template. The requirement for RPA, rather than SSB, in the unwinding reaction indicated that specific NS1-RPA protein interactions were formed. NS1 was tested by enzyme-linked immunosorbent assay for binding to two- or three-subunit RPA complexes expressed from recombinant baculoviruses. NS1 efficiently bound each of the baculovirus-expressed complexes, indicating that the small subunit of RPA is not involved in specific NS1 binding. No NS1 interactions were observed with E. coli SSB or other proteins included as controls.

Purification and Characterization of the Single-Stranded DNA Binding Protein from Streptococcus pneumoniae

The Escherichia coli single-stranded DNA binding (SSB) protein is a non-sequence-specific DNA binding protein that functions as an accessory factor for the RecA protein-promoted three-strand exchange reaction. An open reading frame encoding a protein similar in size and sequence to the E. coli SSB protein has been identified in the Streptococcus pneumoniae genome. The open reading frame has been cloned, an overexpression system has been developed, and the protein has been purified to greater than 99% homogeneity. The purified protein binds to ssDNA in a manner similar to that of the E. coli SSB protein. The protein also stimulates the S. pneumoniae RecA protein and E. coli RecA protein-promoted strand exchange reactions to an extent similar to that observed with the E. coli SSB protein. These results indicate that the protein is the S. pneumoniae analog of the E. coli SSB protein. The availability of highly-purified S. pneumoniae SSB protein will facilitate the study of the molecular mechanisms of RecA protein-mediated transformational recombination in S. pneumoniae.

Sequence and DNA structural determinants of N4 virion RNA polymerase-promoter recognition.

Coliphage N4-coded, virion-encapsidated RNA polymerase (vRNAP) is able to bind to and transcribe promoter-containing double-stranded DNAs when the template is supercoiled and Escherichia coli single-stranded DNA-binding protein (Eco SSB) is present. We report that vRNAP-promoter recognition and activity on these templates require specific sequences and a hairpin structure on the template strand. Hairpin extrusion, induced by Mg(II) and physiological superhelical density, is essential to provide the correct DNA structure for polymerase recognition, as mutant promoters that do not form hairpins show reduced in vitro activity. Therefore, a supercoil-induced DNA structural transition regulates N4 vRNAP transcription. Eco SSB activates transcription at physiological superhelical densities by stabilizing the template-strand hairpin. Specific sequences at the promoters are conserved to provide proper contacts for vRNAP, to support hairpin extrusion, or both. We propose a model for in vivo utilization of the vRNAP promoters, and discuss the roles of DNA supercoiling and Eco SSB in promoter activation.

In vitro and in vivo function of the C-terminus of Escherichia coli single-stranded DNA binding protein.

We constructed several deletion mutants of Escherichia coli single-stranded DNA binding protein (EcoSSB) lacking different parts of the C-terminal region. This region of EcoSSB is composed of two parts: a glycine and proline-rich sequence of approximately 60 amino acids followed by an acidic region of the last 10 amino acids which is highly conserved among the bacterial SSB proteins. The single-stranded DNA binding protein of human mitochondria (HsmtSSB) lacks a region homologous to the C-terminal third of EcoSSB. Therefore, we also investigated a chimeric protein consisting of the complete sequence of the human mitochondrial single-stranded DNA binding protein (HsmtSSB) and the C-terminal third of EcoSSB. Fluorescence titrations and DNA-melting curves showed that the C-terminal third of EcoSSB is not essential for DNA-binding in vitro. The affinity for single-stranded DNA and RNA is even increased by the removal of the last 10 amino acids. Consequently, the nucleic acid binding affinity of HsmtSSB is reduced by the addition of the C-terminus of EcoSSB. All mutant proteins lacking the last 10 amino acids are unable to substitute wild-type EcoSSB in vivo. Thus, while the nucleic acid binding properties do not depend on an intact C-terminus, this region is essential for in vivo function. Although the DNA binding properties of HsmtSSB and EcoSSB are quite similar, HsmtSSB does not function in E.coli. This failure cannot be overcome by fusing the C-terminal third of EcoSSB to HsmtSSB. Thus differences in the N-terminal parts of both proteins must be responsible for this incompatibility. None of the mutants was defective in tetramerization. However, mixed tetramers could only be formed by proteins containing the same N-terminal part. This reflects structural differences between the N-terminal parts of HsmtSSB and EcoSSB. These results indicate that the region of the last 10 amino acids, which is highly conserved among bacterial SSB proteins, is involved in essential protein-protein interactions in the E.coli cell.

Protein-Protein Interactions between the Escherichia coli Single-Stranded DNA-Binding Protein and Exonuclease I

It was demonstrated previously that a deoxyribophosphodiesterase (dRpase) activity is associated with the DNA repair enzyme exonuclease I, and that this activity is stimulated by the addition of the E. coli single-stranded DNA-binding protein (Ssb). This activity catalyzes the release of deoxyribose-phosphate groups at apurinic/apyrimidinic (AP) sites in the DNA that have been cleared by the action of an AP endonuclease. We have now used the yeast two-hybrid system to demonstrate that a protein-protein interaction occurs between exonuclease I and Ssb. When the E. coli ssb gene was fused in frame to the DNA-activating domain of the GAL4 transcriptional activator and the exonuclease I gene was fused in frame to the DNA-binding domain, a functional GAL4 transcriptional activator was produced as determined by growth of yeast on selective medium and the measurement of beta-galactosidase activity. We have also demonstrated that Ssb can stimulate the dRpase activity of exonuclease I using double-stranded bacteriophage M13 DNA containing several strand interruptions at incised AP sites. These results suggest that Ssb may be required for efficient base-excision repair in bacteria.

The effects on strand exchange of 5′ versus 3′ ends of single-stranded DNA in RecA nucleoprotein filaments

Since the ends of DNA chains are thought to be important in homologous recombination, the way in which RecA protein and similar recombination enzymes process ends is important. We analyzed the effects of ends both on the formation of joints, and the progression of strand exchange. When the only homologous end was provided by a single strand, there was no significant difference between the formation of joints at a 5′ end or a 3′ end; but in agreement with the report of Konforti &, Davis, Escherichia coli single-stranded DNA binding protein (SSB) selectively inhibited the activity of 5′ ends. Complete strand exchange, assessed by study of linear single-stranded and double-stranded substrates, took place only in the 5′ to 3′ direction relative to DNA in the nucleoprotein filament. These observations pose a paradox: in the presence of SSB, of which there are about 800 tetramers per cell, the formation of homologous joints by RecA protein is favored at a 3′ end, from which, however, authentic strand exchange appears not to occur. Since observations reported here and elsewhere show that joints have different properties when formed at a 5′ versus a 3′ end, we suggest that they may be processed differently in vivo.