Structural and torsional properties of the RAD51-dsDNA nucleoprotein filament

Human RAD51 is a key protein in the repair of DNA by homologous recombination. Its assembly onto DNA, which induces changes in DNA structure, results in the formation of a nucleoprotein filament that forms the basis of strand exchange. Here, we determine the structural and mechanical properties of RAD51-dsDNA filaments. Our measurements use two recently developed magnetic tweezers assays, freely orbiting magnetic tweezers and magnetic torque tweezers, designed to measure the twist and torque of individual molecules. By directly monitoring changes in DNA twist on RAD51 binding, we determine the unwinding angle per RAD51 monomer to be 45°, in quantitative agreement with that of its bacterial homolog, RecA. Measurements of the torque that is built up when RAD51-dsDNA filaments are twisted show that under conditions that suppress ATP hydrolysis the torsional persistence length of the RAD51-dsDNA filament exceeds that of its RecA counterpart by a factor of three. Examination of the filament’s torsional stiffness for different combinations of divalent ions and nucleotide cofactors reveals that the Ca²⁺ ion, apart from suppressing ATPase activity, plays a key role in increasing the torsional stiffness of the filament. These quantitative measurements of RAD51-imposed DNA distortions and accumulated mechanical stress suggest a finely tuned interplay between chemical and mechanical interactions within the RAD51 nucleoprotein filament.     

Torsional sensing of small-molecule binding using magnetic tweezers

DNA-binding small molecules are widespread in the cell and heavily used in biological applications. Here, we use magnetic tweezers, which control the force and torque applied to single DNAs, to study three small molecules: ethidium bromide (EtBr), a well-known intercalator; netropsin, a minor-groove binding anti-microbial drug; and topotecan, a clinically used anti-tumor drug. In the low-force limit in which biologically relevant torques can be accessed (<10 pN), we show that ethidium intercalation lengthens DNA ∼1.5-fold and decreases the persistence length, from which we extract binding constants. Using our control of supercoiling, we measure the decrease in DNA twist per intercalation to be 27.3 ± 1° and demonstrate that ethidium binding delays the accumulation of torsional stress in DNA, likely via direct reduction of the torsional modulus and torque-dependent binding. Furthermore, we observe that EtBr stabilizes the DNA duplex in regimes where bare DNA undergoes structural transitions. In contrast, minor groove binding by netropsin affects neither the contour nor persistence length significantly, yet increases the twist per base of DNA. Finally, we show that topotecan binding has consequences similar to those of EtBr, providing evidence for an intercalative binding mode. These insights into the torsional consequences of ligand binding can help elucidate the effects of small-molecule drugs in the cellular environment.     

Probing of unusual DNA structures in topologically constrained form V DNA: use of restriction enzymes as structural probe.

The ability of DNA sequences to adopt unusual structures under the superhelical torsional stress has been studied. Sequences that are forced to adopt unusual conformation in topologically constrained pBR322 form V DNA (Lk = 0) were mapped using restriction enzymes as probes. Restriction enzymes such as BamHI, PstI, AvaI and HindIII could not cleave their recognition sequences. The removal of topological constraint relieved this inhibition. The influence of neighbouring sequences on the ability of a given sequence to adopt unusual DNA structure, presumably left handed Z conformation, was studied through single hit analysis. Using multiple cut restriction enzymes such as NarI and FspI, it could be shown that under identical topological strain, the extent of structural alteration is greatly influenced by the neighbouring sequences. In the light of the variety of sequences and locations that could be mapped to adopt non-B conformation in pBR322 form V DNA, restriction enzymes appear as potential structural probes for natural DNA sequences.     

Electron transfer in DNA

Electrons migrate over long distances along the DNA in a multistep hopping process where the rate of each step depends strongly upon its length. The efficiency of this process is not only determined by the electron transfer rates but also by competing reactions with water, in which the charge carriers are trapped. Because electron transfer through DNA can occur under the conditions of oxidative stress, biological consequences are highly likely. In addition, it has been observed that some DNA-binding enzymes influence this charge transport. The question of whether DNA is a suitable material for nanolelectronic devices remains unanswered.     

Human topoisomerase IIalpha rapidly relaxes positively supercoiled DNA: implications for enzyme action ahead of replication forks

Movement of the DNA replication machinery through the double helix induces acute positive supercoiling ahead of the fork and precatenanes behind it. Because topoisomerase I and II create transient single- and double-stranded DNA breaks, respectively, it has been assumed that type I enzymes relax the positive supercoils that precede the replication fork. Conversely, type II enzymes primarily resolve the precatenanes and untangle catenated daughter chromosomes. However, studies on yeast and bacteria suggest that type II topoisomerases may also function ahead of the replication machinery. If this is the case, then positive DNA supercoils should be the preferred relaxation substrate for topoisomerase IIalpha, the enzyme isoform involved in replicative processes in humans. Results indicate that human topoisomerase IIalpha relaxes positively supercoiled plasmids >10-fold faster than negatively supercoiled molecules. In contrast, topoisomerase IIbeta, which is not required for DNA replication, displays no such preference. In addition to its high rates of relaxation, topoisomerase IIalpha maintains lower levels of DNA cleavage complexes with positively supercoiled molecules. These properties suggest that human topoisomerase IIalpha has the potential to alleviate torsional stress ahead of replication forks in an efficient and safe manner.     

Topoisomerase function during replication-independent chromatin assembly in yeast.

DNA topoisomerases I and II are the two major nuclear enzymes capable of relieving torsional strain in DNA. Of these enzymes, topoisomerase I plays the dominant role in relieving torsional strain during chromatin assembly in cell extracts from oocytes, eggs, and early embryos. We tested if the topoisomerases are used differentially during chromatin assembly in Saccharomyces cerevisiae by a combined biochemical and pharmacological approach. As measured by plasmid supercoiling, nucleosome deposition is severely impaired in assembly extracts from a yeast mutant with no topoisomerase I and a temperature-sensitive form of topoisomerase II (strain top1-top2). Expression of wild-type topoisomerase II in strain top1-top2 fully restored assembly-driven supercoiling, and assembly was equally efficient in extracts from strains expressing either topoisomerase I or II alone. Supercoiling in top1-top2 extract was rescued by adding back either purified topoisomerase I or II. Using the topoisomerase II poison VP-16, we show that topoisomerase II activity during chromatin assembly is the same in the presence and absence of topoisomerase I. We conclude that both topoisomerases I and II can provide the DNA relaxation activity required for efficient chromatin assembly in mitotically cycling yeast cells.     

Study of deformation and shape recovery of NiTi nanowires under torsion

The nanomechanical properties, deformation, and shape recovery mechanism of NiTi nanowires (NWs) under torsion are studied using molecular dynamics simulations. The effects of loading rate, aspect ratio of NWs, and NW shape are evaluated in terms of atomic trajectories, potential energy, torque required for deformation, stress, shear modulus, centro-symmetry parameter, and radial distribution function. Simulation results show that dislocation nucleation starts from the surface and then extends to the interior along the {110} close-packed plane. For a high loading rate, the occurrence of torsional buckling of a NW is faster, and the buckling gradually develops near the location of the applied external loading. The critical torsional angle and critical buckling angle increase with aspect ratio of the NWs. Square NWs have better mechanical strength than that of circular NWs due to the effect of shape. Shape recovery naturally occurs before buckling.     

Constitutively active Artemis nuclease recognizes structures containing single-stranded DNA configurations

The Artemis nuclease recognizes and endonucleolytically cleaves at single-stranded to double-stranded DNA (ss/dsDNA) boundaries. It is also a key enzyme in the non-homologous end joining (NHEJ) DNA double-strand break repair pathway. Previously, a truncated form, Artemis-413, was developed that is constitutively active both in vitro and in vivo. Here, we use this constitutively active form of Artemis to detect DNA structures with ss/dsDNA boundaries that arise under topological stress. Topoisomerases prevent abnormal levels of torsional stress through modulation of positive and negative supercoiling. We show that overexpression of Artemis-413 in yeast cells carrying genetic mutations that ablate topoisomerase activity have an increased frequency of DNA double-strand breaks (DSBs). Based on the biochemical activity of Artemis, this suggests an increase in ss/dsDNA-containing structures upon increased torsional stress, with DSBs arising due to Artemis cutting at these ss/dsDNA structures. Camptothecin targets topoisomerase IB (Top1), and cells treated with camptothecin show increased DSBs. We find that expression of Artemis-413 in camptothecin-treated cells leads to a reduction in DSBs, the opposite of what we find with topoisomerase genetic mutations. This contrast between outcomes not only confirms that topoisomerase mutation and topoisomerase poisoning have distinct effects on cells, but also demonstrates the usefulness of Artemis-413 to study changes in DNA structure.     

Collaborative effects of Photobacterium CuZn superoxide dismutase (SODs) and human AP endonuclease in DNA repair and SOD-deficient Escherichia coli under oxidative stress

The defenses against free radical damage include specialized repair enzymes that correct oxidative damage in DNA and detoxification systems such as superoxide dismutases (SODs). These defenses may be coordinated genetically as global responses. We hypothesized that the expression of SOD and DNA repair genes would inhibit DNA damage under oxidative stress. Therefore, protection of Escherichia coli mutants deficient in SOD and DNA repair genes (sod-, xth-, and nfo-) was demonstrated by transforming the mutant strain with a plasmid pYK9 that encoded Photobacterium leiognathi CuZnSOD and human AP endonuclease. The results show that survival rates were increased in sod+ xth- nfo+ cells compared with sod- xth- ape-, sod- xth- ape-, and sod+ xth- ape- cells under oxidative stress generated with 0.1 mM paraquat or 3 mM H2O2. The data suggest that, at the least, SOD and DNA repair enzymes may collaborate on protection and repair of damaged DNA. Additionally, both enzymes are required for protection against free radicals.     

Three deoxyribonucleic acid-dependent adenosine triphosphatases from Bacillus subtilis.

We have isolated from Bacillus subtilis three deoxyribonucleic acid (DNA)-dependent adenosine triphosphatases (ATPases) (gamma-phosphohydrolases). The enzymes were extensively purified, and their physicochemical and functional properties were determined. The three enzymes (ATPases I, II, and III) were shown to be different by several criteria. ATPases II and III showed an absolute requirement for single-stranded DNA as a cofactor, whereas ATPase I had some residual activity also with double-stranded DNA. They required Mg2+ and had a pH optimum of 6.5 to 7. Only adenosine 5'-triphosphate and deoxyadenosine 5'-triphosphate were hydrolyzed. The molecular weights of ATPases I, II, and III were 108,000, 115,000, and 148,000, respectively. Km values for adenosine 5'-triphosphate and DNA were also evaluated and shown to be different for each enzyme. All three enzymes formed physical complexes with single-stranded DNA. We present evidence that ATPases I and II might migrate along DNA during adenosine 5'-triphosphate hydrolysis. On the other hand, this effect was not observed with ATPase III, which exhibited the highest affinity for single-stranded DNA.     

Magnetic torque tweezers: measuring torsional stiffness in DNA and RecA-DNA filaments

We introduce magnetic torque tweezers, which enable direct single-molecule measurements of torque. Our measurements of the effective torsional stiffness C of dsDNA indicated a substantial force dependence, with C = approximately 40 nm at low forces up to C = approximately 100 nm at high forces. The initial torsional stiffness of RecA filaments was nearly twofold larger than that for dsDNA, yet at moderate torques further build-up of torsional strain was prevented.     

The response of the human periodontal ligament to torsional loading—I. Experimental methods

A test technique is described in which torsional loads are applied to human maxillary central incisors in vivo. The central axis of the incisor is located by a stereoscopic X-ray method and the tooth loading device is adjusted by means of a setting jig so that torque is applied about this central axis. The maximum torque which can be applied is ± 0·05 Nm and the maximum rotation of the tooth is ± 0·02 radian (± 1·2). A servo-control system allows one to apply any desired torque or deflection history. e.g. a creep or stress relaxation test or a cyclic load of any waveform.

Initial results obtained with this system are presented and show that the torque vs rotation response is initially linear but becomes highly nonlinear at higher torques. Creep tests and cyclic loading tests indicate that the periodontal ligament is viscoelastic in nature. Periods of cyclic loading separated by rest periods of 1–20 min show that the commonly observed decrease in tissue stiffness during the initial few load cycles is not a permanent effect in this in vivo test. Recovery to the initial stiffness takes place rapidly. e.g. 50 per cent recovery in 5 min at zero load.     

Physical characterisation of the plastid DNA in Neospora caninum

The physical characteristics of the plastid DNA in Neospora caninum were investigated using pulsed-field gel electrophoresis and TEM. In a comparison of contour-clamped homogenous electric field and field inversion gel electrophoresis, the latter proved the more successful technique for studying the plastid molecules. In most cases, restriction or modifying enzymes were required to enable the plastid DNA molecules to enter the gel from the well area. The unit length of the plastid of N. caninum is approximately 35 kb; however, there is evidence for the formation of oligomeric molecules, which may migrate as linear molecules in approximate multiples of the unit length. Four different plastid genes encoding the ssrRNA, lsrRNA, rpoC and tufA genes were identified by hybridisation studies of contour-clamped homogenous electric field and field inversion gel electrophoresis gels. Transmission EM was performed on isolated plastid DNA, and circular structures similar in size and appearance to those described in other apicomplexans were observed, with an approximate length of 19 microm. The data presented here conclusively show that the Nc-Liverpool canine strain of N. caninum possesses a plastid DNA, with physical characteristics similar to the plastids found in other apicomplexans.     

Electron transfer through DNA and peptides

Electrons can migrate through DNA and peptides over very long distances in a multistep hopping process. Stepping stones, which carry the charges for a short time, are the nucleotide bases of DNA or the aromatic side chains of amino acids in peptides. Chemical reactions of these charged intermediates lead to the formation but also to the repair of DNA lesions. In enzymes, long distance electron transfer can activate the binding pocket, and initiates the chemical transformation of the substrate.     

A network of enzymes involved in repair of oxidative DNA damage in Neisseria meningitidis

Although oxidative stress is a key aspect of innate immunity, little is known about how host‐restricted pathogens successfully repair DNA damage. Base excision repair is responsible for correcting nucleobases damaged by oxidative stress, and is essential for bloodstream infection caused by the human pathogen, Neisseria meningitidis. We have characterized meningococcal base excision repair enzymes involved in the recognition and removal of damaged nucleobases, and incision of the DNA backbone. We demonstrate that the bi‐functional glycosylase/lyases Nth and MutM share several overlapping activities and functional redundancy. However, MutM and other members of the GO system, which deal with 8‐oxoG, a common lesion of oxidative damage, are not required for survival of N. meningitidis under oxidative stress. Instead, the mismatch repair pathway provides back‐up for the GO system, while the lyase activity of Nth can substitute for the meningococcal AP endonuclease, NApe. Our genetic and biochemical evidence shows that DNA repair is achieved through a robust network of enzymes that provides a flexible system of DNA repair. This network is likely to reflect successful adaptation to the human nasopharynx, and might provide a paradigm for DNA repair in other prokaryotes.