Interaction of dimeric intercalating dyes with single-stranded DNA.

The unsymmetrical cyanine dye thiazole orange homodimer (TOTO) binds to single-stranded DNA (ssDNA, M13mp18 ssDNA) to form a fluorescent complex that is stable under the standard conditions of electrophoresis. The stability of this complex is indistinguishable from that of the corresponding complex of TOTO with double-stranded DNA (dsDNA). To examine if TOTO exhibits any binding preference for dsDNA or ssDNA, transfer of TOTO from pre-labeled complexes to excess unlabeled DNA was assayed by gel electrophoresis. Transfer of TOTO from M13 ssDNA to unlabeled dsDNA proceeds to the same extent as that from M13 dsDNA to unlabeled dsDNA. A substantial amount of the dye is retained by both the M13 ssDNA and M13 dsDNA even when the competing dsDNA is present at a 600-fold weight excess; for both dsDNA and ssDNA, the pre-labeled complex retains approximately one TOTO per 30 bp (dsDNA) or bases (ssDNA). Rapid transfer of dye from both dsDNA and ssDNA complexes is seen at Na+ concentrations > 50 mM. Interestingly, at higher Na+ or Mg2+ concentrations, the M13 ssDNA-TOTO complex appears to be more stable to intrinsic dissociation (dissociation in the absence of competing DNA) than the complex between TOTO and M13 dsDNA. Similar results were obtained with the structurally unrelated dye ethidium homodimer. The dsDNA- and ssDNA-TOTO complexes were further examined by absorption, fluorescence and circular dichroism spectroscopy. The surprising conclusion is that polycationic dyes, such as TOTO and EthD, capable of bis-intercalation, interact with dsDNA and ssDNA with very similar high affinity.     

Kinetics and thermodynamics of salt-dependent T7 gene 2.5 protein binding to single- and double-stranded DNA

Bacteriophage T7 gene 2.5 protein (gp2.5) is a single-stranded DNA (ssDNA)-binding protein that has essential roles in DNA replication, recombination and repair. However, it differs from other ssDNA-binding proteins by its weaker binding to ssDNA and lack of cooperative ssDNA binding. By studying the rate-dependent DNA melting force in the presence of gp2.5 and its deletion mutant lacking 26 C-terminal residues, we probe the kinetics and thermodynamics of gp2.5 binding to ssDNA and double-stranded DNA (dsDNA). These force measurements allow us to determine the binding rate of both proteins to ssDNA, as well as their equilibrium association constants to dsDNA. The salt dependence of dsDNA binding parallels that of ssDNA binding. We attribute the four orders of magnitude salt-independent differences between ssDNA and dsDNA binding to nonelectrostatic interactions involved only in ssDNA binding, in contrast to T4 gene 32 protein, which achieves preferential ssDNA binding primarily through cooperative interactions. The results support a model in which dimerization interactions must be broken for DNA binding, and gp2.5 monomers search dsDNA by 1D diffusion to bind ssDNA. We also quantitatively compare the salt-dependent ssDNA- and dsDNA-binding properties of the T4 and T7 ssDNA-binding proteins for the first time.     

Effect of the Streptococcus pneumoniae MmsA protein on the RecA protein-promoted three-strand exchange reaction. Implications for the mechanism of transformational recombination

Streptococcus pneumoniae is a naturally transformable bacterium that is able to incorporate DNA from its environment into its own chromosome. This process, known as transformational recombination, is dependent in part on the mmsA gene, which encodes a protein having a sequence that is 40% identical to that of the Escherichia coli RecG protein, a junction-specific DNA helicase believed to be involved in the branch migration of recombinational intermediates. We have developed an expression system for the MmsA protein and have purified the MmsA protein to more than 99% homogeneity. The MmsA protein has DNA-dependent ATP hydrolysis and DNA junction-helicase activities that are similar to those of the E. coli RecG protein. The effect of the MmsA protein on the S. pneumoniae RecA protein-promoted three-strand exchange reaction was also investigated. In the standard direction (circular single-stranded (ss) DNA + linear double-stranded (ds) DNA --> linear ssDNA + nicked circular dsDNA), the MmsA protein appears to promote the branch migration of partially exchanged intermediates in a direction opposite of the RecA protein, resulting in a nearly complete inhibition of the overall strand exchange reaction. In the reverse direction (linear ssDNA + nicked circular dsDNA --> circular ssDNA + linear dsDNA), however, the MmsA protein appears to facilitate the conversion of partially exchanged intermediates into fully exchanged products, leading to a pronounced stimulation of the overall reaction. These results are discussed in terms of the molecular mechanism of transformational recombination.     

Salt dependent binding of T4 gene 32 protein to single and double-stranded DNA: single molecule force spectroscopy measurements

Bacteriophage T4 gene 32 protein (gp32) is a well-studied representative of the large family of single-stranded DNA (ssDNA) binding proteins, which are essential for DNA replication, recombination and repair. Surprisingly, gp32 has not previously been observed to melt natural dsDNA. At the same time, *I, a truncated version of gp32 lacking its C-terminal domain (CTD), was shown to decrease the melting temperature of natural DNA by about 50 deg. C. This profound difference in the duplex destabilizing ability of gp32 and *I is especially puzzling given that the previously measured binding of both proteins to ssDNA was similar. Here, we resolve this apparent contradiction by studying the effect of gp32 and *I on the thermodynamics and kinetics of duplex DNA melting. We use a previously developed single molecule technique for measuring the non-cooperative association constants (K(ds)) to double-stranded DNA to determine K(ds) as a function of salt concentration for gp32 and *I. We then develop a new single molecule method for measuring K(ss), the association constant of these proteins to ssDNA. Comparing our measured binding constants to ssDNA for gp32 and *I we see that while they are very similar in high salt, they strongly diverge at [Na+] < 0.2 M. These results suggest that intact protein must undergo a conformational rearrangement involving the CTD that is in pre-equilibrium to its non-cooperative binding to both dsDNA and ssDNA. This lowers the effective concentration of protein available for binding, which in turn lowers the rate at which it can destabilize dsDNA. For the first time, we quantify the free energy of this CTD unfolding, and show it to be strongly salt dependent and associated with sodium counter-ion condensation on the CTD.     

Electron microscopic visualization of the RecA protein-mediated pairing and branch migration phases of DNA strand exchange

The RecA protein of Escherichia coli will drive the pairing and exchange of strands between homologous DNA molecules in a reaction stimulated by single-stranded binding protein. Here, reactions utilizing three homologous DNA pairs which can undergo both paranemic and plectonemic joining were examined by electron microscopy: supertwisted double-stranded (ds) DNA and linear single-stranded (ss) DNA, linear dsDNA and circular ssDNA, and linear dsDNA and colinear ssDNA. Several major observations were: (i) with RecA protein bound to the DNA, plectonemic joints were ultrastructurally indistinguishable from paranemic joints; (ii) complexes which appeared to be joined both paranemically and plectonemically were present in these reactions in roughly equal numbers; and (iii) in complexes undergoing strand exchange, both DNA partners were often enveloped within a RecA protein filament consisting of hundreds of RecA protein monomers and several kilobases of DNA. These observations suggest that, following RecA protein-ssDNA filament formation, strand exchange proceeds by a pathway that can be divided structurally into three phases: pairing, envelopment/exchange, and release of the products.     

Model for helicase translocating along single-stranded DNA and unwinding double-stranded DNA

A model is proposed for non-hexameric helicases translocating along single-stranded (ss) DNA and unwinding double-stranded (ds) DNA. The translocation of a monomeric helicase along ssDNA in weakly-ssDNA-bound state is driven by the Stokes force that is resulted from the conformational change following the transition of the nucleotide state. The unwinding of dsDNA is resulted mainly from the bending of ssDNA induced by the strong binding force of helicase with dsDNA. The interaction force between ssDNA and helicases in weakly-ssDNA-bound state determines whether monomeric helicases such as PcrA can unwind dsDNA or dimeric helicases such as Rep are required to unwind dsDNA.     

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.     

Tethering telomeric double- and single-stranded DNA-binding proteins inhibits telomere elongation

Mammalian telomeres are composed of G-rich repetitive double-stranded (ds) DNA with a 3' single-stranded (ss) overhang and associated proteins that together maintain chromosome end stability. Complete replication of telomeric DNA requires de novo elongation of the ssDNA by the enzyme telomerase, with telomeric proteins playing a key role in regulating telomerase-mediated telomere replication. In regards to the protein component of mammalian telomeres, TRF1 and TRF2 bind to the dsDNA of telomeres, whereas POT1 binds to the ssDNA portion. These three proteins are linked through either direct interactions or by the proteins TIN2 and TPP1. To determine the biological consequence of connecting telomeric dsDNA to ssDNA through a multiprotein assembly, we compared the effect of expressing TRF1 and POT1 in trans versus in cis in the form of a fusion of these two proteins, on telomere length in telomerase-positive cells. When expressed in trans these two proteins induced extensive telomere elongation. Fusing TRF1 to POT1 abrogated this effect, inducing mild telomere shortening, and generated looped DNA structures, as assessed by electron microscopy, consistent with the protein forming a complex with dsDNA and ssDNA. We speculate that such a protein bridge between dsDNA and ssDNA may inhibit telomerase access, promoting telomere shortening.     

Hybridizing ability and nuclease resistance profile of backbone modified cationic phosphorothioate oligonucleotides

Various stereochemically pure cationic phosphorothioate oligonucleotides bearing aminoalkyl moieties were synthesized, and their duplex-forming ability against single-stranded DNA (ssDNA), single-stranded RNA (ssRNA) and triplex-forming ability against double-stranded DNA (dsDNA) were evaluated by UV melting experiments. The cationic Rp stereoisomers showed improved duplex-forming ability against ssDNA, triplex-forming ability against dsDNA and nuclease stability.     

Surfactant-DNA gel particles: formation and release characteristics

Aqueous mixtures of oppositely charged polyelectrolytes undergo associative phase separation, resulting in coacervation, gelation, or precipitation. This phenomenon has been exploited here to form DNA gel particles by interfacial diffusion. We report on the formation of DNA gel particles by mixing solutions of DNA (either single-stranded (ssDNA) or double-stranded (dsDNA)) with solutions of cationic surfactant cetyltrimetrylammonium bromide (CTAB). By using CTAB, the formation of DNA reservoir gel particles, without adding any kind of cross-linker or organic solvent, has been demonstrated. Particles have been characterized with respect to the degree of DNA entrapment, surface morphology, and secondary structure of DNA in the particles. The swelling/deswelling behavior and the DNA release have been investigated in response to salt additions. Analysis of the data has suggested a higher degree of interaction between ssDNA and the cationic surfactant, confirming the stronger amphiphilic character of the denatured DNA. Fluorescence microscopy studies have suggested that the formation of these particles is associated with a conservation of the secondary structure of DNA.     

Role of LrpC from Bacillus subtilis in DNA transactions during DNA repair and recombination

Bacillus subtilis LrpC is a sequence-independent DNA-binding and DNA-bending protein, which binds both single-stranded (ss) and double-stranded (ds) DNA and facilitates the formation of higher order protein–DNA complexes in vitro. LrpC binds at different sites within the same DNA molecule promoting intramolecular ligation. When bound to separate molecules, it promotes intermolecular ligation, and joint molecule formation between a circular ssDNA and a homologous ssDNA-tailed linear dsDNA. LrpC binding showed a higher affinity for 4-way (Holliday) junctions in their open conformation, when compared with curved dsDNA. Consistent with these biochemical activities, an lrpC null mutant strain rendered cells sensitive to DNA damaging agents such as methyl methanesulfonate and 4-nitroquinoline-1-oxide, and showed a segregation defect. These findings collectively suggest that LrpC may be involved in DNA transactions during DNA repair and recombination.     

SOS repair can be about as effective for single-stranded DNA as for double-stranded DNA and even more so.

As ordinarily measured, the SOS repair of damaged DNA by Weigle reactivation appears to be more effective for double-stranded (ds) than for single-stranded (ss) DNA bacteriophages. A complicating feature, which is usually not considered, is the possibility of DNA-protein cross-linking of ssDNA to the viral capsid, which would conceivably be an extraneous source of nonreactivable lesions. This idea is supported in studies of phage S13 by the observation that photoreactivation more than doubles when naked ssDNA is substituted for encapsidated ssDNA as the UV target. The same effect was observed for Weigle reactivation; there was little, if any, difference in the reactivation of ssDNA and dsDNA when naked DNA was irradiated. Moreover, in a uvrA mutant, ssDNA actually had the advantage; Weigle reactivation was then more than twice as effective for ssDNA as for dsDNA. It is also shown that when a suitable measure of Weigle mutagenesis is used, there is no convincing evidence that dsDNA is mutagenized more effectively than ssDNA.     

Conformational transition of DNA induced by cationic lipid vesicle in acidic solution: spectroscopy investigation

The conformational transition of DNA induced by the interaction between DNA and a cationic lipid vesicle, didodecyldimethylammonium bromide (DDAB), had been investigated by circular dichroism (CD) and UV spectroscopy methods. We used singular value decomposition least squares method (SVDLS) to analyze the experimental CD spectra. Although pH value influenced the conformation of DNA in solution, the results showed that upon binding to double helical DNA, positively charged liposomes induced a conformational transition of DNA molecules from the native B-form to more compact conformations. At the same time, no obvious conformational changes occurred at single-strand DNA (ssDNA). While the cationic lipid vesicles and double-strand DNA (dsDNA) were mixed at a high molar ratio of DDAB vesicles to dsDNA, the conformation of dsDNA transformed from the B-form to the C-form resulting in an increase in duplex stability (DeltaT(m)=8+/-0.4 degrees C). An increasing in T(m) was also observed while the cationic lipid vesicles interacted with ssDNA.     

Characterization of strand exchange activity of yeast Rad51 protein.

The Saccharomyces cerevisiae RAD51 gene product takes part in genetic recombination and repair of DNA double strand breaks. Rad51, like Escherichia coli RecA, catalyzes strand exchange between homologous circular single-stranded DNA (ssDNA) and linear double-stranded DNA (dsDNA) in the presence of ATP and ssDNA-binding protein. The formation of joint molecules between circular ssDNA and linear dsDNA is initiated at either the 5' or the 3' overhanging end of the complementary strand; joint molecules are formed only if the length of the overhanging end is more than 1 nucleotide. Linear dsDNAs with recessed complementary or blunt ends are not utilized. The polarity of strand exchange depends upon which end is used to initiate the formation of joint molecules. Joint molecules formed via the 5' end are processed by branch migration in the 3'-to-5' direction with respect to ssDNA, and joint molecules formed with a 3' end are processed in the opposite direction.     

Substrate requirements for duplex DNA translocation by the eukaryal and archaeal minichromosome maintenance helicases

Replicative DNA helicases are ring-shaped hexamers that play an essential role in DNA synthesis by separating the two strands of chromosomal DNA to provide the single-stranded (ss) substrate for replicative polymerases. Biochemical and structural studies suggest that these helicases translocate along one strand of the duplex, which passes through and interacts with the central channel of these ring-shaped hexamers, and displace the complementary strand. A number of these helicases were shown to also encircle both strands simultaneously and then translocate along double-stranded (ds)DNA. In this report it is shown that the Schizosaccharomyces pombe Mcm4,6,7 complex and archaeal minichromosome maintenance (MCM) helicase from Methanothermobacter thermautotrophicus move along duplex DNA. These two helicases, however, differ in the substrate required to support dsDNA translocation. Although the S. pombe Mcm4,6,7 complex required a 3'-overhang ssDNA region to initiate its association with the duplex, the archaeal protein initiated its transit along dsDNA in the absence of a 3'-overhang region, as well. Furthermore, DNA substrates containing a streptavidin-biotin steric block inhibited the movement of the eukaryotic helicase along ss and dsDNAs but not of the archaeal enzyme. The M. thermautotrophicus MCM helicase, however, was shown to displace a streptavidin-biotin complex from ss, as well as dsDNAs. The possible roles of dsDNA translocation by the MCM proteins during the initiation and elongation phases of chromosomal replication are discussed.     

Energetics of the sequence-specific binding of single-stranded DNA by the F factor relaxase domain

Transfer of conjugative plasmids between bacteria requires the activity of relaxases or mobilization proteins. These proteins nick the plasmid in a site- and strand-specific manner prior to transfer of the cut strand from donor to recipient. TraI36, the relaxase domain of TraI from plasmid F factor, binds a single-stranded DNA (ssDNA) oligonucleotide containing an F factor sequence with high affinity and sequence specificity. To better understand the energetics of this interaction, we examined the temperature, salt, and pH dependence of TraI36 recognition. Binding is entropically driven below 25 degrees C and enthalpically driven at higher temperatures. van't Hoff analysis yields an estimated deltaC(P)(0) of binding (-3300 cal x mol(-1) x K(-1)) that is larger and more negative than that observed for most double-stranded DNA (dsDNA)-binding proteins. Based on analyses of circular dichroism data and the crystal structure of the unliganded protein, we attribute the deltaC(P)(0) to both burial of hydrophobic surface area and coupled folding and binding of the protein. The salt dependence of the binding indicates that several ssDNA phosphates are buried in the complex, and the pH dependence of the binding suggests that some of these ssDNA phosphates form ionic interactions with basic residues of the protein. Although data are available for relatively few sequence-specific ssDNA-binding proteins, sufficient differences exist between TraI36 and other proteins to indicate that, like dsDNA-binding proteins, ssDNA-binding proteins use different motifs and combinations of forces to achieve specific recognition.     

Segregation of viral double-stranded and single-stranded DNA molecules in nuclei of adenovirus infected cells as revealed by electron microscope in situ hybridization.

Formation of progeny viruses in the nuclei of HeLa cells infected with adenovirus type 5 was studied at the ultrastructural level by in situ hybridization techniques allowing specific detection of either viral double-stranded DNA (dsDNA) or single-stranded DNA (ssDNA). Prior to the initiation of replication of viral genomes, infective DNA molecules which entered the nucleus of the target cell were randomly distributed among host chromatin fibers including nucleolus-associated chromatin. They were double-stranded, that is, without single-strand breaks. Such association of viral DNA with host condensed chromatin also occurred in mitosis. The initiation of viral genome replication occurred simultaneously with the appearance in the nucleoplasm of small fibrillar regions containing intermingled viral dsDNA and ssDNA. Later, at the intermediate stage of nuclear transformation, viral dsDNA and ssDNA molecules were almost entirely separated into two contiguous substructures. At this stage, viruses were observed occasionally in the vicinity of viral ssDNA accumulation sites. Still later, an additional substructure developed in the centre of the nucleus which consisted of large quantities of viral dsDNA, traces of viral ssDNA and abundant viruses. Portions of viral ssDNA were attached to some viruses even at late stage of nuclear transformation, an association which strongly suggests the occurrence of encapsidation of at least some of the viral genomes while they are still engaged in replication.     

Three-strand exchange by the Escherichia coli RecA protein using ITP as a nucleotide cofactor: mechanistic parallels with the ATP-dependent reaction of the RecA protein from Streptococcus pneumoniae

The RecA protein from Escherichia coli promotes an ATP-dependent three-strand exchange reaction between a circular single-stranded DNA (ssDNA) and a homologous linear double-stranded (dsDNA). We have now found that under certain conditions, the RecA protein is also able to promote the three-strand exchange reaction using the structurally related nucleoside triphosphate, ITP, as the nucleotide cofactor. However, although both reactions are stimulated by single-stranded DNA-binding (SSB) protein, the ITP-dependent reaction differs from the ATP-dependent reaction in that it is observed only at low SSB protein concentrations, whereas the ATP-dependent reaction proceeds efficiently even at high SSB protein concentrations. Moreover, the circular ssDNA-dependent ITP hydrolysis activity of the RecA protein is strongly inhibited by SSB protein (suggesting that SSB protein displaces RecA protein from ssDNA when ITP is present), whereas the ATP hydrolysis activity is uninhibited even at high SSB protein concentrations (because RecA protein is resistant to displacement by SSB protein when ATP is present). These results suggest that SSB protein does not stimulate the ITP-dependent strand exchange reaction presynaptically (by facilitating the binding of RecA protein to the circular ssDNA substrate) but may act postsynaptically (by binding to the displaced strand that is generated when the circular ssDNA invades the linear dsDNA substrate). Interestingly, the mechanistic characteristics of the ITP-dependent strand exchange reaction of the E. coli RecA protein are similar to those of the ATP-dependent strand exchange reaction of the RecA protein from Streptococcus pneumoniae. These findings are discussed in terms of the relationship between the dynamic state of the RecA-ssDNA filament and the mechanism of the SSB protein-stimulated three-strand exchange reaction.     

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.