Specificity of binding of single-stranded DNA-binding protein to its target

Single-stranded DNA-binding proteins (SSBs) bind single-stranded DNA (ssDNA) and participate in all genetic processes involving ssDNA, such as replication, recombination, and repair. Here we applied atomic force microscopy to directly image SSB-DNA complexes under various conditions. We used the hybrid DNA construct methodology in which the ssDNA segment is conjugated to the DNA duplex. The duplex part of the construct plays the role of a marker, allowing unambiguous identification of specific and nonspecific SSB-DNA complexes. We designed hybrid DNA substrates with 5'- and 3'-ssDNA termini to clarify the role of ssDNA polarity on SSB loading. The hybrid substrates, in which two duplexes are connected with ssDNA, were the models for gapped DNA substrates. We demonstrated that Escherichia coli SSB binds to ssDNA ends and internal ssDNA regions with the same efficiency. However, the specific recognition by ssDNA requires the presence of Mg(2+) cations or a high ionic strength. In the absence of Mg(2+) cations and under low-salt conditions, the protein is capable of binding DNA duplexes. In addition, the number of interprotein interactions increases, resulting in the formation of clusters on double-stranded DNA. This finding suggests that the protein adopts different conformations depending on ionic strength, and specific recognition of ssDNA by SSB requires a high ionic strength or the presence of Mg(2+) cations.     

Preferential binding of Escherichia coli RecF protein to gapped DNA in the presence of adenosine (gamma-thio) triphosphate.

Escherichia coli RecF protein binds, but does not hydrolyze, ATP. To determine the role that ATP binding to RecF plays in RecF protein-mediated DNA binding, we have determined the interaction between RecF protein and single-stranded (ss)DNA, double-stranded (ds)DNA, and dsDNA containing ssDNA regions (gapped [g]DNA) either alone or in various combinations both in the presence and in the absence of adenosine (gamma-thio) triphosphate, gamma-S-ATP, a nonhydrolyzable ATP analog. Protein-DNA complexes were analyzed by electrophoresis on agarose gels and visualized by autoradiography. The type of protein-DNA complexes formed in the presence of gamma-S-ATP was different with each of the DNA substrates and from those formed in the absence of gamma-S-ATP. Competition experiments with various combinations of DNA substrates indicated that RecF protein preferentially bound gDNA in the presence of gamma-S-ATP, and the order of preference of binding was gDNA > dsDNA > ssDNA. Since gDNA has both ds- and ssDNA components, we suggest that the role for ATP in RecF protein-DNA interactions in vivo is to confer specificity of binding to dsDNA-ssDNA junctions, which is necessary for catalyzing DNA repair and recombination.     

Formation of heteroduplex DNA promoted by the combined activities of Escherichia coli recA and recBCD proteins

We have established an in vitro reaction in which heteroduplex DNA formation is dependent on the concerted actions of recA and recBCD proteins, the major components of the recBCD pathway of genetic recombination in vivo. We find that heteroduplex DNA formation requires three distinct enzymatic functions: first, the helicase activity of recBCD enzyme initiates heteroduplex DNA formation by unwinding the linear double-stranded DNA molecule to transiently form single-stranded DNA (ssDNA); second, recA protein traps this ssDNA before it reanneals; third, recA protein catalyzes the pairing of this ssDNA molecule with another homologous ssDNA molecule, followed by the renaturation of these molecules to form heteroduplex DNA. The first two functions should be important to all in vitro reactions involving recA and recBCD proteins, whereas the third will be specific to the DNA substrates used. The rate-limiting step of heteroduplex DNA formation is the trapping by recA protein of the ssDNA produced by recBCD enzyme. A model for this reaction is described.     

Differences in the enzymatic efficiency of human and bony fish AID are mediated by a single residue in the C terminus modulating single-stranded DNA binding

Activation-induced cytidine deaminase (AID) mediates antibody diversification by deaminating deoxycytidines to deoxyuridine within immunoglobulin genes. However, it also generates genome-wide DNA lesions, leading to transformation. Though the biochemical properties of AID have been described, its 3-dimensional structure has not been determined. Hence, to investigate the relationship between the primary structure and biochemical characteristics of AID, we compared the properties of human and bony fish AID, since these are most divergent in amino acid sequence. We show that AIDs of various species have different catalytic rates that are thermosensitive and optimal at native physiological temperatures. Zebrafish AID is severalfold more catalytically robust than human AID, while catfish AID is least active. This disparity is mediated by a single amino acid difference in the C terminus. Using functional assays supported by models of AID core and surface structure, we show that this residue modulates activity by affecting ssDNA binding. Furthermore, the cold-adapted catalytic rates of fish AID result from increased ssDNA binding affinity at lower temperatures. Our work suggests that AID may generate DNA damage with variable efficiencies in different organisms, identifies residues critical in regulating AID activity, and provides insights into the evolution of the APOBEC family of enzymes.     

Dynamic and selective DNA-binding activity of Smc5, a core component of the Smc5-Smc6 complex

Members of the structural maintenance of chromosome (SMC) family of proteins are essential regulators of genomic stability. In particular, the conserved Smc5-6 complex is required for efficient DNA repair, checkpoint signaling, and DNA replication in all eukaryotes. Despite these important functions, the actual nature of the DNA substrates recognized by the Smc5-6 complex in chromosomes is currently unknown. Furthermore, how the core SMC components of the Smc5-6 complex use their ATPase-driven mechanochemical activities to act on chromosomes is not understood. Here, we address these issues by purifying and defining the DNA-binding activity of Smc5. We show that Smc5 binds strongly and specifically to single-stranded DNA (ssDNA). Remarkably, this DNA-binding activity is independent of Smc6 and is observed with the monomeric form of Smc5. We further show that Smc5 ATPase activity is essential for its functions in vivo and that ATP regulates the association of Smc5 with its substrates in vitro. Finally, we demonstrate that Smc5 is able to bind efficiently to oligonucleotides consistent in size with ssDNA intermediates produced during DNA replication and repair. Collectively, our data on the DNA-binding activities of Smc5 provide a compelling molecular basis for the role of the Smc5-6 complex in the DNA damage response.     

Activation-induced cytosine deaminase (AID) is actively exported out of the nucleus but retained by the induction of DNA breaks

Activation-induced cytosine deaminase (AID) is a cytosine deaminase that is critical to immunoglobulin hypermutation, class switch recombination, and gene conversion. In the context of hypermutating B cells, AID deaminates cytosine in the DNA of immunoglobulin genes, leading to the accumulation of mutations in the variable regions. However, when AID is expressed ectopically, it is a generalized mutator of G:C base pairs. Therefore, we asked whether AID may be partially regulated by an active system of nuclear export. We found that removal of a highly conserved nuclear export signal in the C terminus of AID causes accumulation of AID in the nucleus. However, a putative nuclear localization signal in the N terminus does not appear to be functional. Finally, we found that agents that induce DNA breaks caused retention of AID in the nucleus, suggesting that DNA breaks or the repair patches initiated as a result are a substrate for AID binding.     

The efficiency of strand invasion by Escherichia coli RecA is dependent upon the length and polarity of ssDNA tails

RecA protein is essential for homologous recombination and the repair of DNA double-strand breaks in Escherichia coli. The protein binds DNA to form nucleoprotein filaments that promote joint molecule formation and strand exchange in vitro. RecA polymerises on ssDNA in the 5'-3' direction and catalyses strand exchange and branch migration with a 5'-3' polarity. It has been reported previously, using D-loop assays, in which ssDNA (containing a heterologous block at one end) invades supercoiled duplex DNA that 3'-homologous ends are reactive, whereas 5'-ends are inactive. This polarity bias was thought to be due to the polarity of RecA filament formation, which results in the 3'-ends being coated in RecA, whereas 5'-ends remain naked. Using a range of duplex substrates containing ssDNA tails of various lengths and polarities, we now demonstrate that when no heterologous block is imposed, 5'-ends are just as reactive as 3'-ends. Moreover, using short-tailed substrates, we find that 5'-ends form more stable D-loops than 3'-ends. This bias may be a consequence of the instability of short 3'-joints. With more physiological substrates containing long ssDNA tails, we find that RecA shows no intrinsic preference for 5' or 3'-ends and that both form D-loop complexes with high efficiency.     

Somatic hypermutation and class switch recombination in Msh6(-/-)Ung(-/-) double-knockout mice

Somatic hypermutation (SHM) and class switch recombination (CSR) are initiated by activation-induced cytosine deaminase (AID). The uracil, and potentially neighboring bases, are processed by error-prone base excision repair and mismatch repair. Deficiencies in Ung, Msh2, or Msh6 affect SHM and CSR. To determine whether Msh2/Msh6 complexes which recognize single-base mismatches and loops were the only mismatch-recognition complexes required for SHM and CSR, we analyzed these processes in Msh6(-/-)Ung(-/-) mice. SHM and CSR were affected in the same degree and fashion as in Msh2(-/-)Ung(-/-) mice; mutations were mostly C,G transitions and CSR was greatly reduced, making Msh2/Msh3 contributions unlikely. Inactivating Ung alone reduced mutations from A and T, suggesting that, depending on the DNA sequence, varying proportions of A,T mutations arise by error-prone long-patch base excision repair. Further, in Msh6(-/-)Ung(-/-) mice the 5' end and the 3' region of Ig genes was spared from mutations as in wild-type mice, confirming that AID does not act in these regions. Finally, because in the absence of both Ung and Msh6, transition mutations from C and G likely are "footprints" of AID, the data show that the activity of AID is restricted drastically in vivo compared with AID in cell-free assays.     

Surface Plasmon Resonance Studies of the Hybridization Behavior of DNA-Modified Gold Nanoparticles with Surface-Attached DNA Probes

Colloidal gold nanoparticles (AuNPs) have been extensively investigated as amplification tags to improve the sensitivity of surface plasmon resonance (SPR) biosensors. When using the so-called AuNP-enhanced SPR technique for DNA detection, the density of single-stranded DNA (ssDNA) on both the AuNPs and planar gold substrates is of crucial importance. Thus, in this work, we carried out a systematical study about the influence of surface ssDNA density onto the hybridization behavior of various DNA-modified AuNPs (DNA-AuNPs) with surface-attached DNA probes by using surface plasmon resonance spectroscopy. The lateral densities of the ssDNA on both the AuNPs and planar gold substrates were controlled by using different lengths of oligo-adenine sequence (OAS) as anchoring group. Besides SPR measurements, the amount of the captured DNA-AuNPs after the hybridization was further identified via atomic force microscope (AFM). SPR and AFM results clearly indicated that a higher ssDNA density on either the AuNPs or the gold substrates would give rise to better hybridization efficiency. Moreover, SPR data showed that the captured DNA-AuNPs could not be removed from SPR sensor surfaces using various dehybridization solutions regardless of surface ssDNA density. Consequently, it is apparent that the hybridization behavior of DNA-AuNPs was different from that of solution-phase ssDNA. Based on these data, we hypothesized that both multiple recognitions and limited accessibility might account for the hybridization of DNA-AuNPs with surface-attached ssDNA probes.

     

Molecular determinants of the DprA?RecA interaction for nucleation on ssDNA

Natural transformation is a major mechanism of horizontal gene transfer in bacteria that depends on DNA recombination. RecA is central to the homologous recombination pathway, catalyzing DNA strand invasion and homology search. DprA was shown to be a key binding partner of RecA acting as a specific mediator for its loading on the incoming exogenous ssDNA. Although the 3D structures of both RecA and DprA have been solved, the mechanisms underlying their cross-talk remained elusive. By combining molecular docking simulations and experimental validation, we identified a region on RecA, buried at its self-assembly interface and involving three basic residues that contact an acidic triad of DprA previously shown to be crucial for the interaction. At the core of these patches, ^DprAM238 and ^RecAF230 are involved in the interaction. The other DprA binding regions of RecA could involve the N-terminal α-helix and a DNA-binding region. Our data favor a model of DprA acting as a cap of the RecA filament, involving a DprA−RecA interplay at two levels: their own oligomeric states and their respective interaction with DNA. Our model forms the basis for a mechanistic explanation of how DprA can act as a mediator for the loading of RecA on ssDNA.     

The process of displacing the single-stranded DNA-binding protein from single-stranded DNA by RecO and RecR proteins

The regions of single-stranded (ss) DNA that result from DNA damage are immediately coated by the ssDNA-binding protein (SSB). RecF pathway proteins facilitate the displacement of SSB from ssDNA, allowing the RecA protein to form protein filaments on the ssDNA region, which facilitates the process of recombinational DNA repair. In this study, we examined the mechanism of SSB displacement from ssDNA using purified Thermus thermophilus RecF pathway proteins. To date, RecO and RecR are thought to act as the RecOR complex. However, our results indicate that RecO and RecR have distinct functions. We found that RecR binds both RecF and RecO, and that RecO binds RecR, SSB and ssDNA. The electron microscopic studies indicated that SSB is displaced from ssDNA by RecO. In addition, pull-down assays indicated that the displaced SSB still remains indirectly attached to ssDNA through its interaction with RecO in the RecO-ssDNA complex. In the presence of both SSB and RecO, the ssDNA-dependent ATPase activity of RecA was inhibited, but was restored by the addition of RecR. Interestingly, the interaction of RecR with RecO affected the ssDNA-binding properties of RecO. These results suggest a model of SSB displacement from the ssDNA by RecF pathway proteins.     

The nuclear DNA deaminase AID functions distributively whereas cytoplasmic APOBEC3G has a processive mode of action

AID deaminates cytosine in the context of single stranded DNA to generate uracil, essential for effective class-switch recombination, somatic hypermutation and gene conversion at the B cell immunoglobulin locus. As a nuclear DNA mutator, AID activity must be tightly controlled and regulated, but the genetic analysis of AID and other DNA deaminases has left unstudied a number of important biochemical details. We have asked fundamental questions regarding AID's substrate recognition and processing, i.e. whether AID acts distributively or processively. We demonstrate that in vitro, human AID exhibits turnover, a prerequisite for our analysis, and show that it exhibits a distributive mode of action. Using a variety of different assays, we established that human AID is alone unable to act processively on any of a number of DNA substrates, i.e. one AID molecule is unable to carry out multiple, sequential deamination events on the same substrate. This is in contrast to the cytoplasmically expressed anti-viral DNA deaminase APOBEC3G, which acts in a processive manner, possibly suggesting that evolutionary pressure has altered the ability of DNA deaminases to act in a processive or distributive manner, depending on the physiological need.