Single molecule studies of homologous recombination

Single molecule methods offer an unprecedented opportunity to examine complex macromolecular reactions that are obfuscated by ensemble averaging. The application of single molecule techniques to study DNA processing enzymes has revealed new mechanistic details that are unobtainable from bulk biochemical studies. Homologous DNA recombination is a multi-step pathway that is facilitated by numerous enzymes that must precisely and rapidly manipulate diverse DNA substrates to repair potentially lethal breaks in the DNA duplex. In this review, we present an overview of single molecule assays that have been developed to study key aspects of homologous recombination and discuss the unique information gleaned from these experiments.     

Visualizing the Behavior of Human Rad51 at the Single-Molecule Level

The repair of double-stranded DNA breaks by homologous recombination is essential for maintaining genome integrity. Much of what we know about this DNA repair pathway in eukaryotes has been gleaned from genetics, in vivo experiments with GFP-tagged proteins and traditional biochemical experiments with purified proteins. However, many questions have remained inaccessible to these experimental approaches. Recent technological advances have made it possible to directly visualize the behaviors of individual DNA and protein molecules in vitro, and it is now becoming feasible to apply these technology-driven approaches to complex biochemical systems, such as those involved in the repair of damaged DNA. This report summarizes the use of total internal reflection fluorescence microscopy to probe fundamental aspects of protein-DNA interactions at the single-molecule level, and specific emphasis is placed on our efforts to develop new methods and techniques for studying DNA repair. Using these new approaches we are investigating the DNA-binding behavior of human Rad51 and we have recently demonstrated that this protein can slide on dsDNA via a one-dimensional random walk mechanism driven solely by thermal fluctuations of the surrounding solvent. Here, we highlight some possible implications of this recent finding, and we also briefly discuss the potential benefits of future single-molecule studies in the study of protein-DNA interactions and DNA repair.     

A toolbox for generating single‐stranded DNA in optical tweezers experiments

Essential genomic transactions such as DNA‐damage repair and DNA replication take place on single‐stranded DNA (ssDNA) or require specific single‐stranded/double‐stranded DNA (ssDNA/dsDNA) junctions (SDSJ). A significant challenge in single‐molecule studies of DNA–protein interactions using optical trapping is the design and generation of appropriate DNA templates. In contrast to dsDNA, only a limited toolbox is available for the generation of ssDNA constructs for optical tweezers experiments. Here, we present several kinds of DNA templates suitable for single‐molecule experiments requiring segments of ssDNA of several kilobases in length. These different biotinylated dsDNA templates can be tethered between optically trapped microspheres and can, by the subsequent use of force‐induced DNA melting, be converted into partial or complete ssDNA molecules. We systematically investigated the time scale and efficiency of force‐induced melting at different ionic strengths for DNA molecules of different sequences and lengths. Furthermore, we quantified the impact of microspheres of different sizes on the lifetime of ssDNA tethers in optical tweezers experiments. Together, these experiments provide deeper insights into the variables that impact the production of ssDNA for single molecules studies and represent a starting point for further optimization of DNA templates that permit the investigation of protein binding and kinetics on ssDNA. © 2013 Wiley Periodicals, Inc. Biopolymers 99:611–620, 2013.     

零模波导原理、制备及其在单分子荧光检测中的应用

单分子荧光检测作为一种能够表征分子个体性质及行为的分析方法,有助于揭示利用传统荧光检测方法无法得到的信息,在近年来受到人们的广泛关注。利用传统光学检测设备进行单分子荧光检测时,由于受到衍射极限的限制,同时为了保证在观测体积内只有单个荧光分子,仅能采用无限稀释溶液的方法实现单分子荧光检测。虽然这种方法可以满足单分子检测的要求,但是由于大部分酶分子正常工作时底物的生理浓度都非常高,底物浓度的大幅度降低会对酶分子的反应机制等方面造成影响。零模波导作为一种新型的单分子检测器件,通过纳米微孔结构突破了光学衍射极限的限制将观测体积降至仄升量级（10-21L）,使得在生理浓度范围内检测单分子荧光成为可能,在单分子荧光检测领域得到了广泛应用。因此,就零模波导的原理、制备工艺及其在单分子DNA测序、生物膜、生物大分子之间的相互作用及单分子反应动力学方面的具体应用进行综述。     

Quantifying clustered DNA damage induction and repair by gel electrophoresis, electronic imaging and number average length analysis

Assessing DNA damage induction, repair and consequences of such damages requires measurement of specific DNA lesions by methods that are independent of biological responses to such lesions. Lesions affecting one DNA strand (altered bases, abasic sites, single strand breaks (SSB)) as well as damages affecting both strands (clustered damages, double strand breaks) can be quantified by direct measurement of DNA using gel electrophoresis, gel imaging and number average length analysis. Damage frequencies as low as a few sites per gigabase pair (10(9)bp) can be quantified by this approach in about 50ng of non-radioactive DNA, and single molecule methods may allow such measurements in DNA from single cells. This review presents the theoretical basis, biochemical requirements and practical aspects of this approach, and shows examples of their applications in identification and quantitation of complex clustered damages.     

Single molecule studies of DNA mismatch repair

DNA mismatch repair, which involves is a widely conserved set of proteins, is essential to limit genetic drift in all organisms. The same system of proteins plays key roles in many cancer related cellular transactions in humans. Although the basic process has been reconstituted in vitro using purified components, many fundamental aspects of DNA mismatch repair remain hidden due in part to the complexity and transient nature of the interactions between the mismatch repair proteins and DNA substrates. Single molecule methods offer the capability to uncover these transient but complex interactions and allow novel insights into mechanisms that underlie DNA mismatch repair. In this review, we discuss applications of single molecule methodology including electron microscopy, atomic force microscopy, particle tracking, FRET, and optical trapping to studies of DNA mismatch repair. These studies have led to formulation of mechanistic models of how proteins identify single base mismatches in the vast background of matched DNA and signal for their repair.     

Biophysics of the DNA Molecule: A New Trend

Briefly discussed are experiments with single molecules, representing a novel trend in the biophysical study of DNA. The techniques of optical and magnetic tweezers whereby external force can be applied to individual DNA molecules were used to assess the structural transitions of the DNA double helix under such conditions. Discussed are the latest data on the dependence of the rate of complementary chain synthesis by DNA polymerase on the stretching of the template.     

High‐resolution,hybrid optical trapping methods,and their application to nucleic acid processing proteins

Optical tweezers have become a powerful tool to investigate nucleic‐acid processing proteins at the single‐molecule level. Recent advances in this technique have now enabled measurements resolving the smallest units of molecular motion, on the scale of a single base pair of DNA. In parallel, new instrumentation combining optical traps with other functionalities have been developed, incorporating mechanical manipulation along orthogonal directions or fluorescence imaging capabilities. Here, we review these technical advances, their capabilities, and limitations, focusing on benchmark studies of protein‐nucleic acid interactions they have enabled. We highlight recent work that combines several of these advances together and its application to nucleic‐acid processing enzymes. Finally, we discuss future prospects for these exciting developments. © 2016 Wiley Periodicals, Inc. Biopolymers 105: 704–714, 2016.     

Single molecule measurements and biological motors

Recent technological advances in lasers and optical detectors have enabled a variety of new, single molecule technologies to be developed. Using intense and highly collimated laser light sources in addition to super-sensitive cameras, the fluorescence of single fluorophores can now be imaged in aqueous solution. Also, laser optical tweezers have enabled the piconewton forces produced by pair of interacting biomolecules to be measured directly. However, for a researcher new to the field to begin to use such techniques in their own research might seem a daunting prospect. Most of the equipment that is in use is custom-built. However, most of the equipment is essence fairly simple and the aim of this article is to provide an entry point to the field for a newcomer. It focuses mainly on those practical aspects which are not particularly well covered in the literature, and aims to provide an overview of the field as a whole with references and web links to more detailed sources elsewhere. Indeed, the opportunity to publish an article such as this on the Internet affords many new opportunities (and more space!) for presenting scientific ideas and information. For example, we have illustrated the nature of optical trap data with an interactive Java simulation; provided links to relevant web sites and technical documents, and included a large number of colour figures and plots. Our group’s research focuses on molecular motors, and the bias of this article reflects this. It turns out that molecular motors have been a paradigm (or prototype) for single molecule research and the field has seen a rapid development in the techniques. It is hoped that the methods described here will be broadly applicable to other biological systems.This is an interactive contribution, which can be accessed at:     

Tools to study DNA repair: what's in the box?

Our understanding of the DNA repair mechanisms that preserve genome integrity has increased greatly in recent years. To follow the DNA repair process, researchers have developed sophisticated techniques including live cell imaging, local damage induction and refined biochemical assays. These techniques have helped to elucidate the 'orchestration' of DNA repair mechanisms (i.e. the order of factor assembly around the lesion, the identification of new functions of known factors and the discovery of novel key regulators involved in DNA repair). We will discuss the uses and the limitations of these methods and their applications in the study of DNA repair.     

The processing of double-stranded DNA breaks for recombinational repair by helicase–nuclease complexes

Double-stranded DNA breaks are prepared for recombinational repair by nucleolytic digestion to form single-stranded DNA overhangs that are substrates for RecA/Rad51-mediated strand exchange. This processing can be achieved through the activities of multiple helicases and nucleases. In bacteria, the function is mainly provided by a stable multi-protein complex of which there are two structural classes; AddAB- and RecBCD-type enzymes. These helicase–nucleases are of special interest with respect to DNA helicase mechanism because they are exceptionally powerful DNA translocation motors, and because they serve as model systems for both single molecule studies and for understanding how DNA helicases can be coupled to other protein machinery. This review discusses recent developments in our understanding of the AddAB and RecBCD complexes, focussing on their distinctive strategies for processing DNA ends. We also discuss the extent to which bacterial DNA end resection mechanisms may parallel those used in eukaryotic cells.     

Reprint of: gene susceptibility to oxidative damage: from single nucleotide polymorphisms to function

Oxidative damage to DNA can cause mutations, and mutations can lead to cancer. DNA repair of oxidative damage should therefore play a pivotal role in defending humans against cancer. This is exemplified by the increased risk of colorectal cancer of patients with germ-line mutations of the oxidative damage DNA glycosylase MUTYH. In contrast to germ-line mutations in DNA repair genes, which cause a strong deficiency in DNA repair activity in all cell types, the role of single nucleotide polymorphisms (SNPs) in sporadic cancer is unclear also because deficiencies in DNA repair, if any, are expected to be much milder. Further slowing down progress are the paucity of accurate and reproducible functional assays and poor epidemiological design of many studies. This review will focus on the most common and widely studied SNPs of oxidative DNA damage repair proteins trying to bridge the information available on biochemical and structural features of the repair proteins with the functional effects of these variants and their potential impact on the pathogenesis of disease.     

Gene susceptibility to oxidative damage: from single nucleotide polymorphisms to function

Oxidative damage to DNA can cause mutations, and mutations can lead to cancer. DNA repair of oxidative damage should therefore play a pivotal role in defending humans against cancer. This is exemplified by the increased risk of colorectal cancer of patients with germ-line mutations of the oxidative damage DNA glycosylase MUTYH. In contrast to germ-line mutations in DNA repair genes, which cause a strong deficiency in DNA repair activity in all cell types, the role of single nucleotide polymorphisms (SNPs) in sporadic cancer is unclear also because deficiencies in DNA repair, if any, are expected to be much milder. Further slowing down progress are the paucity of accurate and reproducible functional assays and poor epidemiological design of many studies. This review will focus on the most common and widely studied SNPs of oxidative DNA damage repair proteins trying to bridge the information available on biochemical and structural features of the repair proteins with the functional effects of these variants and their potential impact on the pathogenesis of disease.     

The role of the Fanconi anemia network in the response to DNA replication stress

Fanconi anemia is a genetically heterogeneous disorder associated with chromosome instability and a highly elevated risk for developing cancer. The mutated genes encode proteins involved in the cellular response to DNA replication stress. Fanconi anemia proteins are extensively connected with DNA caretaker proteins, and appear to function as a hub for the coordination of DNA repair with DNA replication and cell cycle progression. At a molecular level, however, the raison d’être of Fanconi anemia proteins still remains largely elusive. The thirteen Fanconi anemia proteins identified to date have not been embraced into a single and defined biological process. To help put the Fanconi anemia puzzle into perspective, we begin this review with a summary of the strategies employed by prokaryotes and eukaryotes to tolerate obstacles to the progression of replication forks. We then summarize what we know about Fanconi anemia with an emphasis on biochemical aspects, and discuss how the Fanconi anemia network, a late acquisition in evolution, may function to permit the faithful and complete duplication of our very large vertebrate chromosomes.     

DNA damage response and cancer therapeutics through the lens of the Fanconi Anemia DNA repair pathway

Fanconi Anemia (FA) is a rare, inherited genomic instability disorder, caused by mutations in genes involved in the repair of interstrand DNA crosslinks (ICLs). The FA signaling network contains a unique nuclear protein complex that mediates the monoubiquitylation of the FANCD2 and FANCI heterodimer, and coordinates activities of the downstream DNA repair pathway including nucleotide excision repair, translesion synthesis, and homologous recombination. FA proteins act at different steps of ICL repair in sensing, recognition and processing of DNA lesions. The multi-protein network is tightly regulated by complex mechanisms, such as ubiquitination, phosphorylation, and degradation signals that are critical for the maintenance of genome integrity and suppressing tumorigenesis. Here, we discuss recent advances in our understanding of how the FA proteins participate in ICL repair and regulation of the FA signaling network that assures the safeguard of the genome. We further discuss the potential application of designing small molecule inhibitors that inhibit the FA pathway and are synthetic lethal with DNA repair enzymes that can be used for cancer therapeutics.     

DNA mechanics as a tool to probe helicase and translocase activity

Helicases and translocases are proteins that use the energy derived from ATP hydrolysis to move along or pump nucleic acid substrates. Single molecule manipulation has proved to be a powerful tool to investigate the mechanochemistry of these motors. Here we first describe the basic mechanical properties of DNA unraveled by single molecule manipulation techniques. Then we demonstrate how the knowledge of these properties has been used to design single molecule assays to address the enzymatic mechanisms of different translocases. We report on four single molecule manipulation systems addressing the mechanism of different helicases using specifically designed DNA substrates: UvrD enzyme activity detection on a stretched nicked DNA molecule, HCV NS3 helicase unwinding of a RNA hairpin under tension, the observation of RecBCD helicase/nuclease forward and backward motion, and T7 gp4 helicase mediated opening of a synthetic DNA replication fork. We then discuss experiments on two dsDNA translocases: the RuvAB motor studied on its natural substrate, the Holliday junction, and the chromosome-segregation motor FtsK, showing its unusual coupling to DNA supercoiling.     

Nucleotide excision repair in chromatin: damage removal at the drop of a HAT

In an earlier review of our understanding of the mechanism of nucleotide excision repair (NER) we examined the process with respect to how it occurs in chromatin [1]. We described how much of our mechanistic understanding of NER was derived from biochemical studies that analysed the repair reaction in DNA substrates not representative of that which exists in the living cell. We pointed out that our efforts to understand how NER operates in chromatin had been hampered in part because of the well-known inhibition of NER that occurs when DNA is assembled into nucleosomes and used as the substrate to examine the repair reaction in vitro. Despite this technical bottleneck, we summarized the biochemical, genetic and cell-based studies which have provided insights into the molecular mechanism of NER in the cellular context. More recently, we revisited the topic of how UV induced DNA damage is repaired in chromatin. In this review we examined the commonly held view that depicts a struggle in which the DNA repair machinery battles to overcome the inhibitory effect of chromatin during the repair process. We suggested that in this interpretation of events, the DNA repair mechanisms might be described as 'tilting at windmills': fighting an imaginary foe [2]. We surmised that this scenario was overly simplistic, and we described an emerging picture in which the DNA repair process and chromatin remodeling were mechanistically linked and were in fact functioning cooperatively to organize the efficient removal of DNA damage from the genome. Here we discuss the latest findings, which contribute to the idea that DNA damage induced changes to chromatin represent an important way in which the DNA repair process is initiated and organized throughout the genome to promote the efficient removal of damage in response to UV radiation.     

RecG helicase promotes DNA double-strand break repair

Double-strand breaks pose a major threat to the genome and must be repaired accurately if structural and functional integrity are to be preserved. This is usually achieved via homologous recombination, which enables the ends of a broken DNA molecule to engage an intact duplex and prime synthesis of the DNA needed for repair. In Escherichia coli, repair relies on the RecBCD and RecA proteins, the combined ability of which to initiate recombination and form joint-molecule intermediates is well understood. To shed light on subsequent events, we exploited the I-SceI homing endonuclease of yeast to make breaks at I-SceI cleavage sites engineered into the chromosome. We show that survival depends on RecA and RecBCD, and that subsequent events can proceed via either of two pathways, one dependent on the RuvABC Holliday junction resolvase and the other on RecG helicase. Both pathways rely on PriA, presumably to facilitate DNA replication. We discuss the possibility that classical Holliday junctions may not be essential intermediates in repair and consider alternative pathways for RecG-dependent separation of joint molecules formed by RecA.