Characterization of the Mycobacterial AdnAB DNA Motor Provides Insights into the Evolution of Bacterial Motor-Nuclease Machines

Mycobacterial AdnAB exemplifies a family of heterodimeric motor-nucleases involved in processing DNA double strand breaks (DSBs). The AdnA and AdnB subunits are each composed of an N-terminal UvrD-like motor domain and a C-terminal RecB-like nuclease module. Here we conducted a biochemical characterization of the AdnAB motor, using a nuclease-inactivated heterodimer. AdnAB is a vigorous single strand DNA (ssDNA)-dependent ATPase (k_cat 415 s⁻¹), and the affinity of the motor for the ssDNA cofactor increases 140-fold as DNA length is extended from 12 to 44 nucleotides. Using a streptavidin displacement assay, we demonstrate that AdnAB is a 3′ → 5′ translocase on ssDNA. AdnAB binds stably to DSB ends. In the presence of ATP, the motor unwinds the DNA duplex without requiring an ssDNA loading strand. We integrate these findings into a model of DSB unwinding in which the “leading” AdnB and “lagging” AdnA motor domains track in tandem, 3′ to 5′, along the same DNA single strand. This contrasts with RecBCD, in which the RecB and RecD motors track in parallel along the two separated DNA single strands. The effects of 5′ and 3′ terminal obstacles on ssDNA cleavage by wild-type AdnAB suggest that the AdnA nuclease receives and processes the displaced 5′ strand, while the AdnB nuclease cleaves the displaced 3′ strand. We present evidence that the distinctive “molecular ruler” function of the ATP-dependent single strand DNase, whereby AdnAB measures the distance from the 5′-end to the sites of incision, reflects directional pumping of the ssDNA through the AdnAB motor into the AdnB nuclease. These and other findings suggest a scenario for the descent of the RecBCD- and AddAB-type DSB-processing machines from an ancestral AdnAB-like enzyme.     

Structure–activity relationships at a nucleobase-stacking tryptophan required for chemomechanical coupling in the DNA resecting motor-nuclease AdnAB

Mycobacterial AdnAB is a heterodimeric helicase-nuclease that initiates homologous recombination by resecting DNA double-strand breaks. The AdnB subunit hydrolyzes ATP to drive single-nucleotide steps of 3′-to-5′ translocation of AdnAB on the tracking DNA strand via a ratchet-like mechanism. Trp325 in AdnB motif III, which intercalates into the tracking strand and makes a π stack on a nucleobase 5′ of a flipped-out nucleoside, is the putative ratchet pawl without which ATP hydrolysis is mechanically futile. Here, we report that AdnAB mutants wherein Trp325 was replaced with phenylalanine, tyrosine, histidine, leucine, or alanine retained activity in ssDNA-dependent ATP hydrolysis but displayed a gradient of effects on DSB resection. The resection velocities of Phe325 and Tyr325 mutants were 90% and 85% of the wild-type AdnAB velocity. His325 slowed resection rate to 3% of wild-type and Leu325 and Ala325 abolished DNA resection. A cryo-EM structure of the DNA-bound Ala325 mutant revealed that the AdnB motif III peptide was disordered and the erstwhile flipped out tracking strand nucleobase reverted to a continuous base-stacked arrangement with its neighbors. We conclude that π stacking of Trp325 on a DNA nucleobase triggers and stabilizes the flipped-out conformation of the neighboring nucleoside that underlies formation of a ratchet pawl.     

Structural basis for DNA strand separation by a hexameric replicative helicase

Hexameric helicases are processive DNA unwinding machines but how they engage with a replication fork during unwinding is unknown. Using electron microscopy and single particle analysis we determined structures of the intact hexameric helicase E1 from papillomavirus and two complexes of E1 bound to a DNA replication fork end-labelled with protein tags. By labelling a DNA replication fork with streptavidin (dsDNA end) and Fab (5′ ssDNA) we located the positions of these labels on the helicase surface, showing that at least 10 bp of dsDNA enter the E1 helicase via a side tunnel. In the currently accepted ‘steric exclusion’ model for dsDNA unwinding, the active 3′ ssDNA strand is pulled through a central tunnel of the helicase motor domain as the dsDNA strands are wedged apart outside the protein assembly. Our structural observations together with nuclease footprinting assays indicate otherwise: strand separation is taking place inside E1 in a chamber above the helicase domain and the 5′ passive ssDNA strands exits the assembly through a separate tunnel opposite to the dsDNA entry point. Our data therefore suggest an alternative to the current general model for DNA unwinding by hexameric helicases.     

Dna2 Is Involved in CA Strand Resection and Nascent Lagging Strand Completion at Native Yeast Telomeres

Post-replicational telomere end processing involves both extension by telomerase and resection to produce 3′-GT-overhangs that extend beyond the complementary 5′-CA-rich strand. Resection must be carefully controlled to maintain telomere length. At short de novo telomeres generated artificially by HO endonuclease in the G₂ phase, we show that dna2-defective strains are impaired in both telomere elongation and sequential 5′-CA resection. At native telomeres in dna2 mutants, GT-overhangs do clearly elongate during late S phase but are shorter than in wild type, suggesting a role for Dna2 in 5′-CA resection but also indicating significant redundancy with other nucleases. Surprisingly, elimination of Mre11 nuclease or Exo1, which are complementary to Dna2 in resection of internal double strand breaks, does not lead to further shortening of GT-overhangs in dna2 mutants. A second step in end processing involves filling in of the CA-strand to maintain appropriate telomere length. We show that Dna2 is required for normal telomeric CA-strand fill-in. Yeast dna2 mutants, like mutants in DNA ligase 1 (cdc9), accumulate low molecular weight, nascent lagging strand DNA replication intermediates at telomeres. Based on this and other results, we propose that FEN1 is not sufficient and that either Dna2 or Exo1 is required to supplement FEN1 in maturing lagging strands at telomeres. Telomeres may be among the subset of genomic locations where Dna2 helicase/nuclease is essential for the two-nuclease pathway of primer processing on lagging strands.     

Identification of the Xenopus DNA2 protein as a major nuclease for the 5'->3' strand-specific processing of DNA ends

The first step of homology-dependent DNA double-strand break (DSB) repair is the 5′ strand-specific processing of DNA ends to generate 3′ single-strand tails. Despite extensive effort, the nuclease(s) that is directly responsible for the resection of 5′ strands in eukaryotic cells remains elusive. Using nucleoplasmic extracts (NPE) derived from the eggs of Xenopus laevis as the model system, we have found that DNA processing consists of at least two steps: an ATP-dependent unwinding of ends and an ATP-independent 5′→3′ degradation of single-strand tails. The unwinding step is catalyzed by DNA helicases, the major one of which is the Xenopus Werner syndrome protein (xWRN), a member of the RecQ helicase family. In this study, we report the purification and identification of the Xenopus DNA2 (xDNA2) as one of the nucleases responsible for the 5′→3′ degradation of single-strand tails. Immunodepletion of xDNA2 resulted in a significant reduction in end processing and homology-dependent DSB repair. These results provide strong evidence that xDNA2 is a major nuclease for the resection of DNA ends for homology-dependent DSB repair in eukaryotes.     

Replisome-mediated Translesion Synthesis and Leading Strand Template Lesion Skipping Are Competing Bypass Mechanisms

A number of different enzymatic pathways have evolved to ensure that DNA replication can proceed past template base damage. These pathways include lesion skipping by the replisome, replication fork regression followed by either correction of the damage and origin-independent replication restart or homologous recombination-mediated restart of replication downstream of the lesion, and bypass of the damage by a translesion synthesis DNA polymerase. We report here that of two translesion synthesis polymerases tested, only DNA polymerase IV, not DNA polymerase II, could engage productively with the Escherichia coli replisome to bypass leading strand template damage, despite the fact that both enzymes are shown to be interacting with the replicase. Inactivation of the 3′ → 5′ proofreading exonuclease of DNA polymerase II did not enable bypass. Bypass by DNA polymerase IV required its ability to interact with the β clamp and act as a translesion polymerase but did not require its “little finger” domain, a secondary region of interaction with the β clamp. Bypass by DNA polymerase IV came at the expense of the inherent leading strand lesion skipping activity of the replisome, indicating that they are competing reactions.     

Molecular and Functional Characterization of RecD,a Novel Member of the SF1 Family of Helicases,from Mycobacterium tuberculosis

The annotated whole-genome sequence of Mycobacterium tuberculosis revealed the presence of a putative recD gene; however, the biochemical characteristics of its encoded protein product (MtRecD) remain largely unknown. Here, we show that MtRecD exists in solution as a stable homodimer. Protein-DNA binding assays revealed that MtRecD binds efficiently to single-stranded DNA and linear duplexes containing 5′ overhangs relative to the 3′ overhangs but not to blunt-ended duplex. Furthermore, MtRecD bound more robustly to a variety of Y-shaped DNA structures having ≥18-nucleotide overhangs but not to a similar substrate containing 5-nucleotide overhangs. MtRecD formed more salt-tolerant complexes with Y-shaped structures compared with linear duplex having 3′ overhangs. The intrinsic ATPase activity of MtRecD was stimulated by single-stranded DNA. Site-specific mutagenesis of Lys-179 in motif I abolished the ATPase activity of MtRecD. Interestingly, although MtRecD-catalyzed unwinding showed a markedly higher preference for duplex substrates with 5′ overhangs, it could also catalyze significant unwinding of substrates containing 3′ overhangs. These results support the notion that MtRecD is a bipolar helicase with strong 5′ → 3′ and weak 3′ → 5′ unwinding activities. The extent of unwinding of Y-shaped DNA structures was ∼3-fold lower compared with duplexes with 5′ overhangs. Notably, direct interaction between MtRecD and its cognate RecA led to inhibition of DNA strand exchange promoted by RecA. Altogether, these studies provide the first detailed characterization of MtRecD and present important insights into the type of DNA structure the enzyme is likely to act upon during the processes of DNA repair or homologous recombination.     

DNA Unwinding by Ring-Shaped T4 Helicase gp41 Is Hindered by Tension on the Occluded Strand

The replicative helicase for bacteriophage T4 is gp41, which is a ring-shaped hexameric motor protein that achieves unwinding of dsDNA by translocating along one strand of ssDNA while forcing the opposite strand to the outside of the ring. While much study has been dedicated to the mechanism of binding and translocation along the ssDNA strand encircled by ring-shaped helicases, relatively little is known about the nature of the interaction with the opposite, ‘occluded’ strand. Here, we investigate the interplay between the bacteriophage T4 helicase gp41 and the ss/dsDNA fork by measuring, at the single-molecule level, DNA unwinding events on stretched DNA tethers in multiple geometries. We find that gp41 activity is significantly dependent on the geometry and tension of the occluded strand, suggesting an interaction between gp41 and the occluded strand that stimulates the helicase. However, the geometry dependence of gp41 activity is the opposite of that found previously for the E. coli hexameric helicase DnaB. Namely, tension applied between the occluded strand and dsDNA stem inhibits unwinding activity by gp41, while tension pulling apart the two ssDNA tails does not hinder its activity. This implies a distinct variation in helicase-occluded strand interactions among superfamily IV helicases, and we propose a speculative model for this interaction that is consistent with both the data presented here on gp41 and the data that had been previously reported for DnaB.     

The UvrD303 Hyper-helicase Exhibits Increased Processivity

DNA helicases use energy derived from nucleoside 5′-triphosphate hydrolysis to catalyze the separation of double-stranded DNA into single-stranded intermediates for replication, recombination, and repair. Escherichia coli helicase II (UvrD) functions in methyl-directed mismatch repair, nucleotide excision repair, and homologous recombination. A previously discovered 2-amino acid substitution of residues 403 and 404 (both Asp → Ala) in the 2B subdomain of UvrD (uvrD303) confers an antimutator and UV-sensitive phenotype on cells expressing this allele. The purified protein exhibits a “hyper-helicase” unwinding activity in vitro. Using rapid quench, pre-steady state kinetic experiments we show the increased helicase activity of UvrD303 is due to an increase in the processivity of the unwinding reaction. We suggest that this mutation in the 2B subdomain results in a weakened interaction with the 1B subdomain, allowing the helicase to adopt a more open conformation. This is consistent with the idea that the 2B subdomain may have an autoregulatory role. The UvrD303 mutation may enable the helicase to unwind DNA via a “strand displacement” mechanism, which is similar to the mechanism used to processively translocate along single-stranded DNA, and the increased unwinding processivity may contribute directly to the antimutator phenotype.     

A novel mode of nuclease action is revealed by the bacterial Mre11/Rad50 complex

The Mre11/Rad50 complex is a central player in various genome maintenance pathways. Here, we report a novel mode of nuclease action found for the Escherichia coli Mre11/Rad50 complex, SbcC₂/D₂ complex (SbcCD). SbcCD cuts off the top of a cruciform DNA by making incisions on both strands and continues cleaving the dsDNA stem at ∼10-bp intervals. Using linear-shaped DNA substrates, we observed that SbcCD cleaved dsDNA using this activity when the substrate was 110 bp long, but that on shorter substrates the cutting pattern was changed to that predicted for the activity of a 3′-5′ exonuclease. Our results suggest that SbcCD processes hairpin and linear dsDNA ends with this novel DNA end-dependent binary endonuclease activity in response to substrate length rather than using previously reported activities. We propose a model for this mode of nuclease action, which provides new insight into SbcCD activity at a dsDNA end.     

Kinetics of DNA Unwinding by the RecD2 Helicase from Deinococcus radiodurans

RecD2 from Deinococcus radiodurans is a superfamily 1 DNA helicase that is homologous to the Escherichia coli RecD protein but functions outside the context of RecBCD enzyme. We report here on the kinetics of DNA unwinding by RecD2 under single and multiple turnover conditions. There is little unwinding of 20-bp substrates by preformed RecD2-dsDNA complexes when excess ssDNA is present to trap enzyme molecules not bound to the substrate. A shorter 12-bp substrate is unwound rapidly under single turnover conditions. The 12-bp unwinding reaction could be simulated with a mechanism in which the DNA is unwound in two kinetic steps with rate constant of k_unw = 5.5 s⁻¹ and a dissociation step from partially unwound DNA of k_off = 1.9 s⁻¹. These results indicate a kinetic step size of about 3–4 bp, unwinding rate of about 15–20 bp/s, and low processivity (p = 0.74). The reaction time courses with 20-bp substrates, determined under multiple turnover conditions, could be simulated with a four-step mechanism and rate constant values very similar to those for the 12-bp substrate. The results indicate that the faster unwinding of a DNA substrate with a forked end versus only a 5′-terminal single-stranded extension can be accounted for by a difference in the rate of enzyme binding to the DNA substrates. Analysis of reactions done with different RecD2 concentrations indicates that the enzyme forms an inactive dimer or other oligomer at high enzyme concentrations. RecD2 oligomers can be detected by glutaraldehyde cross-linking but not by size exclusion chromatography.     

Manipulation of single polymerase-DNA complexes: A mechanical view of DNA unwinding during replication

Comment on: Morin JA, et al. Proc Natl Acad Sci USA 2012; 109:8115-20.DNA replication requires overcoming the energetic barrier associated with the base pair melting of its double helix and a fine-tuned coordination between the processes of DNA unwinding and DNA replication. One intriguing question that remains poorly understood is the exact mechanism of the coupling of these two reactions. In some organisms, these activities are coupled within the same protein, like in the case of the phage Phi29 DNA polymerase. This polymerase works as a hybrid polymerase-helicase, because it presents an amino acid insertion that together with other protein domains forms a narrow tunnel around the template strand. This topological restriction is similar to the one imposed by hexameric helicases at the fork junction and promotes the separation of the fork ahead.¹ The Phi29 DNA polymerase, therefore, constitutes a simple, good model system to understand the basic mechanistic principles of the coupling between DNA replication and unwinding activities: the polymerase may behave as a “passive” unwinding motor, if translocation of the protein traps transient unwinding fluctuations of the fork, or as an “active” motor, if the polymerase actively destabilizes the duplex DNA at the junction. Therefore, factors that affect the stability of the fork junction, as DNA sequence or mechanical destabilization of the fork, will have a stronger effect on the unwinding kinetics of a “passive” motor than on an “active” one.To determine the DNA unwinding mechanism of the Phi29 DNA polymerase, we used optical tweezers to measure at single molecule level the effect of DNA sequence and destabilizing forces on the fork on the rates of strand displacement (replication and unwinding are tightly coupled, Δx₁, Fig. 1A) and primer extension (replication of the displaced complementary strand without unwinding, Δx₂, Fig. 1A) of two polymerases: the wild-type Phi29 DNA polymerase and a strand displacement deficient variant, which bears a couple of mutations that may affect the stability of the tunnel required for unwinding.² We quantified the free energy of interaction between the polymerase and the DNA fork, ΔG_int, and the range of this interaction, M, through a theoretical analysis of the dependence of the replication, unwinding and pause kinetics on the DNA sequence and force.^3,4Open in a separate windowFigure 1. (A) Schematic representation of the experimental design (not to scale). A single DNA hairpin was attached to functionalized beads inside a fluidics chamber. One strand of the hairpin is attached through a dsDNA handle to a bead held in the optical trap (top), while the complementary strand is attached to a bead on top of a mobile micropipette (bottom). At a constant force, after flowing the nucleotides into the reaction chamber, the strand displacement and primer extension rates of the polymerase are detected as a change in distance between the beads, Δx₁ and Δx₂, respectively. (B) Representative replication activity of a single mutant polymerase molecule. Long pauses are observed only during the strand displacement reaction. (C) Mechanistic distinction between passive and active unwinding. The cartoon illustrates the degree of activeness in DNA unwinding of different replicative helicases⁶ and the Phi29 DNA polymerase.Our results show that while the primer extension rates of both polymerases are force- and sequence-independent their average unwinding rates are sensitive to these two variables, although with different intensity. As expected, the dsDNA fork presents a much stronger physical barrier to the mutant polymerase unwinding. Qualitative reasoning might suggest that the observed differences imply different “activeness” of the unwinding mechanism of each polymerase. However, the inclusion of the pause kinetics of each polymerase in our model revealed that they use the same active mechanism; they both destabilize the two nearest base pairs of the fork (M = 2) with an interaction energy ΔG_int = 2 k_BT per base pair. These results suggest that mutations affecting the stability of the tunnel required for unwinding do not decrease the “activeness” of the motor but instead increase the probability of the unwinding mechanism to fail upon encountering a closed fork junction, inducing the entrance of the mutant polymerase into a long-lived inactive pause state (Fig. 1B). These results bring out the importance to consider pause kinetics to accurately quantify the actual unwinding mechanism of the Phi29 DNA polymerase or any other nucleic acid unwinding motor in which pauses are relevant during its operation. The presence of pauses obscures the actual pause-free rates of the motor and can lead to misleading results when they are not properly accounted.Our data are consistent with a model in which the closed template tunnel that wraps around the template strand allows the Phi29 DNA polymerase to maintain a sharp bending of this strand (essential for template reading in all replicative polymerases) and a bending of the complementary strand, due to its steric exclusion, at a closed fork junction. Bending of the two strands would generate mechanical stress at the junction promoting its active destabilization. A less stable tunnel, as in the mutant polymerase, will not be able to keep the mechanical stress at a closed fork junction, in this case the fork pressure would induce loosening of the correct protein-DNA interactions favoring the entrance to a polymerization inactive state.Similar mechanisms for mechanical destabilization of the fork junction can be envisioned for other DNA replication systems in which a DNA polymerase and a helicase work in coordination. In these systems, the leading strand can be sharply bent by the steric exclusion induced by the helicase and by the functional binding of the polymerase generating effective mechanical stress at the fork junction to account for efficient unwinding during replication. These implications are further supported by recent single molecule studies using magnetic tweezers that describe a collaborative coupling of this nature between the activities of the bacteriophage T4 DNA polymerase and DNA helicase.⁵     

Euler buckling and nonlinear kinking of double-stranded DNA

The bending stiffness of double-stranded DNA (dsDNA) at high curvatures is fundamental to its biological activity, yet this regime has been difficult to probe experimentally, and literature results have not been consistent. We created a ‘molecular vise’ in which base-pairing interactions generated a compressive force on sub-persistence length segments of dsDNA. Short dsDNA strands (<41 base pairs) resisted this force and remained straight; longer strands became bent, a phenomenon called ‘Euler buckling’. We monitored the buckling transition via Förster Resonance Energy Transfer (FRET) between appended fluorophores. For low-to-moderate concentrations of monovalent salt (up to ∼150 mM), our results are in quantitative agreement with the worm-like chain (WLC) model of DNA elasticity, without the need to invoke any ‘kinked’ states. Greater concentrations of monovalent salts or 1 mM Mg²⁺ induced an apparent softening of the dsDNA, which was best accounted for by a kink in the region of highest curvature. We tested the effects of all single-nucleotide mismatches on the DNA bending. Remarkably, the propensity to kink correlated with the thermodynamic destabilization of the mismatched DNA relative the perfectly complementary strand, suggesting that the kinked state is locally melted. The molecular vise is exquisitely sensitive to the sequence-dependent linear and nonlinear elastic properties of dsDNA.     

Biochemical characterization of the DNA helicase activity of the escherichia coli RecQ helicase

We demonstrate that RecQ helicase from Escherichia coli is a catalytic helicase whose activity depends on the concentration of ATP, free magnesium ion, and single-stranded DNA-binding (SSB) protein. Helicase activity is cooperative in ATP concentration, with an apparent S(0.5) value for ATP of 200 microm and a Hill coefficient of 3.3 +/- 0.3. Therefore, RecQ helicase utilizes multiple, interacting ATP-binding sites to mediate double-stranded DNA (dsDNA) unwinding, implicating a multimer of at least three subunits as the active unwinding species. Unwinding activity is independent of dsDNA ends, indicating that RecQ helicase can unwind from both internal regions and ends of dsDNA. The K(M) for dsDNA is 0.5-0.9 microm base pairs; the k(cat) for DNA unwinding is 2.3-2.7 base pairs/s/monomer of RecQ helicase; and unexpectedly, helicase activity is optimal at a free magnesium ion concentration of 0.05 mm. Omitting Escherichia coli SSB protein lowers the rate and extent of dsDNA unwinding, suggesting that RecQ helicase associates with the single-stranded DNA (ssDNA) product. In agreement, the ssDNA-dependent ATPase activity is reduced in proportion to the SSB protein concentration; in its absence, ATPase activity saturates at six nucleotides/RecQ helicase monomer and yields a k(cat) of 24 s(-1). Thus, we conclude that SSB protein stimulates RecQ helicase-mediated unwinding by both trapping the separated ssDNA strands after unwinding and preventing the formation of non-productive enzyme-ssDNA complexes.     

Single-stranded-DNA-binding protein-dependent DNA unwinding of the yeast ARS1 region.

DNA unwinding of autonomously replicating sequence 1 (ARS1) from the yeast Saccharomyces cerevisiae was investigated. When a negatively supercoiled plasmid DNA containing ARS1 was digested with single-strand-specific mung bean nuclease, a discrete region in the vector DNA was preferentially digested. The regions containing the core consensus A domain and the 3'-flanking B domain of ARS1 were weakly digested. When the DNA was incubated with the multisubunit single-stranded DNA-binding protein (SSB, also called RPA [replication protein A]) from human and yeast cells prior to mung bean nuclease digestion, the cleavage in the A and B domains was greatly increased. Furthermore, a region corresponding to the 5'-flanking C domain of ARS1 was digested. These results indicate that three domains of ARS1, each of which is important for replication in yeast cells, closely correspond to the regions where the DNA duplex is easily unwound by torsional stress. SSB may stimulate the unwinding of the ARS1 region by its preferential binding to the destabilized three domains. Mung bean nuclease digestion of the substitution mutants with mutations of ARS1 (Y. Marahrens and B. Stillman, Science 255:817-823, 1992) revealed that the sequences in the B2 and A elements are responsible for the unwinding of the B domain and the region containing the A domain, respectively.     

Sequence Conversion by Single Strand Oligonucleotide Donors via Non-homologous End Joining in Mammalian Cells

Double strand breaks (DSBs) can be repaired by homology independent nonhomologous end joining (NHEJ) pathways involving proteins such as Ku70/80, DNAPKcs, Xrcc4/Ligase 4, and the Mre11/Rad50/Nbs1 (MRN) complex. DSBs can also be repaired by homology-dependent pathways (HDR), in which the MRN and CtIP nucleases produce single strand ends that engage homologous sequences either by strand invasion or strand annealing. The entry of ends into HDR pathways underlies protocols for genomic manipulation that combine site-specific DSBs with appropriate informational donors. Most strategies utilize long duplex donors that participate by strand invasion. Work in yeast indicates that single strand oligonucleotide (SSO) donors are also active, over considerable distance, via a single strand annealing pathway. We examined the activity of SSO donors in mammalian cells at DSBs induced either by a restriction nuclease or by a targeted interstrand cross-link. SSO donors were effective immediately adjacent to the break, but activity declined sharply beyond ∼100 nucleotides. Overexpression of the resection nuclease CtIP increased the frequency of SSO-mediated sequence modulation distal to the break site, but had no effect on the activity of an SSO donor adjacent to the break. Genetic and in vivo competition experiments showed that sequence conversion by SSOs in the immediate vicinity of the break was not by strand invasion or strand annealing pathways. Instead these donors competed for ends that would have otherwise entered NHEJ pathways.     

The MRX complex regulates Exo1 resection activity by altering DNA end structure

Homologous recombination is triggered by nucleolytic degradation (resection) of DNA double‐strand breaks (DSBs). DSB resection requires the Mre11‐Rad50‐Xrs2 (MRX) complex, which promotes the activity of Exo1 nuclease through a poorly understood mechanism. Here, we describe the Mre11‐R10T mutant variant that accelerates DSB resection compared to wild‐type Mre11 by potentiating Exo1‐mediated processing. This increased Exo1 resection activity leads to a decreased association of the Ku complex to DSBs and an enhanced DSB resection in G1, indicating that Exo1 has a direct function in preventing Ku association with DSBs. Molecular dynamics simulations show that rotation of the Mre11 capping domains is able to induce unwinding of double‐strand DNA (dsDNA). The R10T substitution causes altered orientation of the Mre11 capping domain that leads to persistent melting of the dsDNA end. We propose that MRX creates a specific DNA end structure that promotes Exo1 resection activity by facilitating the persistence of this nuclease on the DSB ends, uncovering a novel MRX function in DSB resection.     

Recognition of duplex RNA by the deaminase domain of the RNA editing enzyme ADAR2

Adenosine deaminases acting on RNA (ADARs) hydrolytically deaminate adenosines (A) in a wide variety of duplex RNAs and misregulation of editing is correlated with human disease. However, our understanding of reaction selectivity is limited. ADARs are modular enzymes with multiple double-stranded RNA binding domains (dsRBDs) and a catalytic domain. While dsRBD binding is understood, little is known about ADAR catalytic domain/RNA interactions. Here we use a recently discovered RNA substrate that is rapidly deaminated by the isolated human ADAR2 deaminase domain (hADAR2-D) to probe these interactions. We introduced the nucleoside analog 8-azanebularine (8-azaN) into this RNA (and derived constructs) to mechanistically trap the protein–RNA complex without catalytic turnover for EMSA and ribonuclease footprinting analyses. EMSA showed that hADAR2-D requires duplex RNA and is sensitive to 2′-deoxy substitution at nucleotides opposite the editing site, the local sequence and 8-azaN nucleotide positioning on the duplex. Ribonuclease V1 footprinting shows that hADAR2-D protects ∼23 nt on the edited strand around the editing site in an asymmetric fashion (∼18 nt on the 5′ side and ∼5 nt on the 3′ side). These studies provide a deeper understanding of the ADAR catalytic domain–RNA interaction and new tools for biophysical analysis of ADAR–RNA complexes.     

A Novel Bio-Sensor Based on DNA Strand Displacement

DNA strand displacement technology performs well in sensing and programming DNA segments. In this work, we construct DNA molecular systems based on DNA strand displacement performing computation of logic gates. Specifically, a class of so-called “DNA neurons” are achieved, in which a “smart” way inspired by biological neurons encoding information is developed to encode and deliver information using DNA molecules. The “DNA neuron” is bistable, that is, it can sense DNA molecules as input signals, and release “negative” or “positive” signals DNA molecules. We design intelligent DNA molecular systems that are constructed by cascading some particularly organized “DNA neurons”, which could perform logic computation, including AND, OR, XOR logic gates, automatically. Both simulation results using visual DSD (DNA strand displacement) software and experimental results are obtained, which shows that the proposed systems can detect DNA signals with high sensitivity and accretion; moreover, the systems can process input signals automatically with complex nonlinear logic. The method proposed in this work may provide a new way to construct a sensitive molecular signal detection system with neurons spiking behavior in vitro, and can be used to develop intelligent molecular processing systems in vivo.