单分子动力学研究大肠杆菌单链结合蛋白与单链DNA的结合过程

大肠杆菌单链结合蛋白(E.coli SSB)具有与单链DNA(single-stranded DNA,ssDNA)结合的性质,起着保护ssDNA及引导相关蛋白质反应的重要作用,然而,它与ssDNA的结合过程及其细节尚未得到确定的研究结果.本文采用单分子磁镊对E.coli SSB/ssDNA复合体进行拉力测试,并采用单分子化学反应动力学方法对测试结果进行分析.研究发现:E.coli SSB在ssDNA上的结合过程分为两个不同的阶段,一个是在临界力下快速的结合缠绕阶段,一个是随着力的进一步减小逐步缠绕的阶段.从中得到了E.coli SSB与ssDNA的化学反应系数,并得到了相应的自由能参数.采用自由能校准的方法,得到了SSB与ssDNA结合的完整自由能曲线,从而揭示了E.coli SSB与ssDNA的结合特征.本文的分析方法也可以应用于相似的化学反应的研究中.     

Direct Observation Method of Individual Single-Stranded DNA Molecules Using Fluorescent Replication Protein A

Direct observation studies of single molecules have revealed molecular behaviors usually hidden in the ensemble and time-averaging of bulk experiments. Direct single DNA molecule analysis of DNA metabolism reactions such as DNA replication, repair, and recombination is necessary to fully understand these essential processes. Intercalation of fluorescent dyes such as YOYO-1 and SYTOX Orange has been the standard method for observing single molecules of double-stranded DNA (dsDNA), but effective fluorescent dyes for observing single molecules of single-stranded DNA (ssDNA) have not been found. To facilitate direct single-molecule observations of DNA metabolism reactions, it is necessary to establish methods for discriminating ssDNA and dsDNA. To observe ssDNA directly, we prepared a fusion protein consisting of the 70 kDa DNA-binding domain of replication protein A and enhanced yellow fluorescent protein (RPA-YFP). This fusion protein had ssDNA-binding activity. In our experiments, dsDNA was stained by SYTOX Orange and ssDNA by RPA-YFP, and we succeeded in staining ssDNA and dsDNA by using RPA-YFP and SYTOX Orange simultaneously.     

Ashkin-Teller Formalism for Elastic Response of DNA Molecule to External Force and Torque

We propose an Ashkin-Teller-like model for elastic response of DNA molecule to external force and torque. The base-stacking interaction is described in a simple and uniform way. We obtain the phase diagram of dsDNA, and in particular, the transition from 13 form to the S state induced by stretching and twisting. The elastic response of the ssDNA is presented also in a unified formalism. The close relation of dsDNA molecule structure with elastic response is shown clearly. The calculated folding angle of the dsDNA molecule is 59.2°.     

Pairing Mismatched ssDNA to dsDNA Studied with Reflectometric Interference Spectroscopy Sensor

The interaction between two single-stranded DNA(ssDNA)molecules as pairing to a double-stranded DNA(dsDNA)molecule is studied by the reflectometric interference spectroscopy(RIFS)technology.A nano-porous anode alumina membrane coated an Au layer is employed as the sensor substrate.The results indicate that when there are mismatched nucleotide bases,the effective optical thicknesses(OT_(eff))have obvious difference,and the changes of OT_(eff)are connected with the sensor layer thickness and the effective refractive index.It is also demonstrated that the RIFS technique can be used to precisely detect the ssDNA molecules with individual base mismatched as pairing to dsDNA.     

Insights into the Discrepancy between Single Molecule Experiments

Sharp bending as one of the mechanical properties of double-stranded DNA(dsDNA) on the nanoscale is essential for biological functions and processes. Force sensors with optical readout have been designed to measure the forces inside short, strained loops composed of both dsDNA and single-stranded DNA(ssDNA). Recent FRET singlemolecule experiments were carried out based on the same force sensor design, but provided totally contrary results. In the current work, Monte Carlo simulations were performed under three conditions to clarify the discrepancy between the two experiments. The criterion that the work done by the force exerted on dsDNA by ssDNA should be larger than the nearest-neighbor(NN) stacking interaction energy is used to identify the generation of the fork at the junction of dsDNA and ssDNA. When the contour length of dsDNA in the sensor is larger than its critical length, the fork begins to generate at the junction of dsDNA and ssDNA, even with a kink in dsDNA. The forces inferred from simulations under three conditions are consistent with the ones inferred from experiments, including extra large force and can be grouped into two different states, namely, fork states and kink states. The phase diagrams constructed in the phase space of the NN stacking interaction energy and excited energy indicate that the transition between the fork state and kink state is difficult to identify in the phase space with an ultra small or large number of forks, but it can be detected in the phase space with a medium number of forks and kinks.     

拉直的单个DNA分子的全内反射荧光实时成像研究

全内反射荧光(TIRF)成像技术利用穿透深度仅200 nm左右的隐失波来激发诱导荧光,探测灵敏度和图像信噪比大大提高,成为单分子研究的有力工具。分子梳技术利用DNA末端与固体表面的结合力和周围流体流动产生的侧向力将DNA分子拉伸并平铺在表面上。结合这两种技术,对分子梳拉直的单个DNA分子进行了清晰的实时荧光成像,发现TIRF成像条件下DNA分子与荧光探针YOYO-1组成的复合体可自然避免发生光敏断裂现象;实时监测了单个DNA-YOYO-1复合体的光漂白过程,通过对激发光照射时间与探测器曝光时间进行同步控制,可大幅降低光漂白程度,为拉直的单个DNA分子的长时间实时观察和成像研究优化了实验条件,为实时、可视化地研究其与蛋白质相互作用的动力学过程奠定了基础。     

The kinetics of force-dependent hybridization and strand-peeling of short DNA fragments

Deoxyribonucleic acid (DNA) carries the genetic information in all living organisms. It consists of two interwound single-stranded (ss) strands, forming a double-stranded (ds) DNA with a right-handed double-helical conformation. The two strands are held together by highly specific basepairing interactions and are further stabilized by stacking between adjacent basepairs. A transition from a dsDNA to two separated ssDNA is called melting and the reverse transition is called hybridization. Applying a tensile force to a dsDNA can result in a particular type of DNA melting, during which one ssDNA strand is peeled away from the other. In this work, we studied the kinetics of strand-peeling and hybridization of short DNA under tensile forces. Our results show that the force-dependent strand-peeling and hybridization can be described with a simple two-state model. Importantly, detailed analysis of the force-dependent transition rates revealed that the transition state consists of several basepairs dsDNA.     

Direct Observation of Fluorescently Labeled Single-stranded λDNA Molecules in a Micro-Flow Channel

We developed two labeling methods for the direct observation of single-stranded DNA (ssDNA), using a ssDNA binding protein and a ssDNA recognition peptide. The first approach involved protein fusion between the 70-kDa ssDNA-binding domain of replication protein A and enhanced yellow fluorescent protein (RPA-YFP). The second method used the ssDNA binding peptide of Escherichia coli RecA labeled with Atto488 (ssBP-488; Atto488-IRMKIGVMFGNPETTTGGNALKFY). The labeled ssλDNA molecules were visualized over time in micro-flow channels. We report substantially different dynamics between these two labeling methods. When ssλDNA molecules were labeled with RPA-YFP, terminally bound fusion proteins were sheared from the free ends of the ssλDNA molecules unless 25-mer oligonucleotides were annealed to the free ends. RPA-YFP-ssλDNA complexes were dissociated by the addition of 0.2 M NaCl, although complex reassembly was possible with injection of additional RPA-YFP. In contrast to the flexible dynamics of RPA-YFP-ssλDNA complexes, the ssBP-488-ssλDNA complexes behaved as rigid rods and were not dissociated even in 2 M NaCl.     

Interactions between CdSe/CdS quantum dots and DNA through spectroscopic and electrochemical methods

The interaction of CdSe/CdS quantum dots (QDs) with Herring sperm-DNA (hs-DNA) has been studied by UV-vis spectroscopy and electrochemical method. Cu(phen)₂^2+/1+ (phen = 1, 10-phenanthroline) was used as an indicator for electroactive dsDNA or ssDNA. The apparent association constant has been deduced (4.94 × 10³ M⁻¹ and 2.39 × 10² M⁻¹) from the absorption spectral changes of the dsDNA-QDs and ssDNA-QDs. The results of dissociation method suggest that Cu(phen)₂^2+/1+ is more easily dissociated from dsDNA or ssDNA modified gold electrode (dsDNA/Au or dsDNA/Au) in presence of QDs. The dissociation rate constant (k) of Cu(phen)₂^2+/1+ on dsDNA/Au is 4.48 times higher than that in absence of QDs, while k is 2.34 times higher than that in absence of QDs on ssDNA/Au in Tris buffer with low ionic strength (pH 7.0, 0.5 mM NaCl). The results illuminate that hs-DNA has high affinity for QDs due to electrostatic force, hydrogen bonds, and van der Waals interactions, and the binding force of QDs with dsDNA is stronger than ssDNA.     

用单分子技术研究Sso7d与DNA的相互作用

为了维持基因的稳定性,每种生物体都含有一套独特的染色质蛋白来保护脱氧核糖核酸(DNA)的结构,观察染色质蛋白对DNA结构的作用过程和结果,可以帮助人们了解这些蛋白的具体功能和作用机理.硫化叶菌是一种能在高温下存活的古细菌,Sso7d是硫化叶菌的一种染色质蛋白.深入地了解Sso7d和DNA链的相互作用,有助于解释硫化叶菌的DNA为何能在高温环境下保持活性,本文通过原子力显微镜(AFM)和磁镊两种单分子操作手段,研究了Sso7d与DNA的相互作用.AFM的实验结果给出了Sso7d与DNA的作用过程:结合Sso7d后,DNA首先发生弯折,然后出现loop结构,最终DNA会团聚为致密的核结构.利用磁镊装置测量了Sso7d的结合对打开DNA双链的影响,实验结果表明Sso7d的结合导致打开DNA双链的力的增大,经过数据分析,计算出Sso7d与DNA结合的结合能?G=3.1k_BT,平均每5.5个碱基对(bp)结合一个Sso7d,较高的结合密度和较大的结合能,两方面的作用结果,解释了Sso7d能够稳定DNA结构的原因.     

MALDI-MS detection of noncovalent interactions of single stranded DNA with Escherichia coli single-stranded DNA-binding protein

The Escherichia coli single-stranded DNA binding protein (SSB) selectively binds single-stranded (ss) DNA and participates in the process of DNA replication, recombination and repair. Different binding modes have previously been observed in SSB?ssDNA complexes, due to the four potential binding sites of SSB. Here, chemical cross-linking, combined with high-mass matrix-assisted laser desorption/ionization (MALDI) mass spectrometry (MS), is used to determine the stoichiometry of the SSB?ssDNA complex. SSB forms a stable homotetramer in solution, but only the monomeric species (m/z 19,100) can be detected with standard MALDI-MS. With chemical cross-linking, the quaternary structure of SSB is conserved, and the tetramer (m/z 79,500) was observed. We found that ssDNA also functions as a stabilizer to conserve the quaternary structure of SSB, as evidenced by the detection of a SSB?ssDNA complex at m/z 94,200 even in the absence of chemical cross-linking. The stability of the SSB?ssDNA complex with MALDI strongly depends on the length and strand of oligonucleotides and the stoichiometry of the SSB?ssDNA complex, which could be attributed to electrostatic interactions that are enhanced in the gas phase. The key factor affecting the stoichiometry of the SSB?ssDNA complex is how ssDNA binds to SSB, rather than the protein-to-DNA ratio. This further suggests that detection of the complex by MALDI is a result of specific binding, and not due to non-specific aggregation in the MALDI plume.     

The elastic theory of a single DNA molecule

We study the elastic responses of double-(ds) and single-stranded (ss) DNA at external force fields. A double-strand-polymer elastic model is constructed and solved by path integral methods and Monte Carlo simulations to understand the entropic elasticity, cooperative extensibility, and supercoiling property of dsDNA. The good agreement with experiments indicates that short-ranged base-pair stacking interaction is crucial for the stability and the high deformability of dsDNA. Hairpin-coil transition in ssDNA is studied with generating function method. A threshold force is needed to pull the ssDNA hairpin patterns, stabilized by base pairing and base-pair stacking, into random coils. This phase transition is predicted to be of first order for stacking potential higher than some critical level, in accordance with experimental observations.     

Spectroscopic study on the interaction of eugenol with salmon sperm DNA in vitro

Fluorescence spectra, absorption spectra, melting temperature, ionic strength effect, and viscosity experiments were described that characterize the interaction of eugenol with salmon sperm DNA in vitro. Eugenol was found to bind but weakly to DNA, with binding constants of 4.23×10³, 3.62×10³ and 2.47×10³ L mol^?1 at 18, 28 and 38 °C respectively. The Stern–Volmer plots at different temperatures suggested that the quenching type of fluorescence of eugenol by DNA was a static quenching. Both the relative viscosity and the melting temperature of DNA were increased by the addition of eugenol. The changes of ionic strength had no affect on the binding. In addition, the binding constant of eugenol with single stranded DNA (ssDNA) was larger than that of eugenol with double stranded DNA (dsDNA). These results revealed that the binding mode of eugenol to DNA was intercalative binding. The thermodynamic parameters ΔH, ΔG and ΔS were also obtained according to the Van't Hoff equations, which suggested that hydrogen bond or van der Waals force might play an important role in a binding of eugenol to DNA. Based on the theory of the Förster energy transference, the binding distance between DNA and eugenol was determined as 4.40 nm, indicating that the static fluorescence quenching of eugenol by DNA was also a non-radiation energy transfer process.     

Adsorption dynamics of double-stranded DNA on a graphene oxide surface with both large unoxidized and oxidized regions

The adsorption dynamics of double-stranded DNA (dsDNA) molecules on a graphene oxide (GO) surface are important for applications of DNA/GO functional structures in biosensors, biomedicine and materials science. In this work, molecular dynamics simulations were used to examine the adsorption of different length dsDNA molecules (from 4 bp to 24 bp) on the GO surface. The dsDNA molecules could be adsorbed on the GO surface through the terminal bases and stand on the GO surface. For short dsDNA (4 bp) molecules, the double-helix structure was partially or totally broken and the adsorption dynamics was affected by the structural fluctuation of short dsDNA and the distribution of the oxidized groups on the GO surface. For long dsDNA molecules (from 8 bp to 24 bp) adsorption is stable. By nonlinear fitting of the contact angle between the axis of the dsDNA molecule and the GO surface, we found that a dsDNA molecule adsorbed on a GO surface has the chance of orienting parallel to the GO surface if the length of the dsDNA molecule is longer than 54 bp. We attributed this behavior to the flexibility of dsDNA molecules. With increasing length, the flexibility of dsDNA molecules also increases, and this increasing flexibility gives an adsorbed dsDNA molecule more chance of reaching the GO surface with the free terminal. This work provides a whole picture of adsorption of dsDNA molecules on the GO surface and should be of benefit for the design of DNA/GO based biosensors.     

Bubbles in DNA by random force

We model single strand binding (SSB) proteins as agents exerting randomly oriented force on the bonds in DNA unzipping. The fluctuating force is found to unzip the double stranded DNA (dsDNA) via opening of bubbles along the chain.     

NEXAFS characterization of DNA components and molecular-orientation of surface-bound DNA oligomers

Single stranded DNA oligomers (ssDNA) immobilized onto solid surfaces forms the basis for several biotechnological applications such as DNA microarrays, affinity separations, and biosensors. The surface structure of the surface-bound oligomers is expected to significantly influence their biological activity and interactions with the environment. In this study near-edge X-ray absorption fine structure spectroscopy (NEXAFS) is used to characterize the components of DNA (nucleobases, nucleotides and nucleosides) and the orientation information of surface-bound ssDNA. The K-edges of carbon, nitrogen and oxygen have spectra with features that are characteristic of the different chemical species present in the nucleobases of DNA. The effect of addition of the DNA sugar and phosphate components on the NEXAFS K-edge spectra was also investigated. The polarization-dependent nitrogen K-edge NEXAFS data show significant changes for different orientations of surface bound ssDNA. These results establish NEXAFS as a powerful technique for chemical and structural characterization of surface-bound DNA oligomers.     

Monomer dynamics in double- and single-stranded DNA polymers

We present the first measurements of the kinetics of random motion of individual monomers within large polymer coils. We use double- and single-stranded DNA (dsDNA and ssDNA) as models of semiflexible and flexible polymers, respectively. Fluorescence fluctuations of DNA fragments labeled specifically at a single position reveal the time dependence of the DNA monomer's mean-square displacement . The monomer motions within dsDNA and ssDNA coils are characterized by two qualitatively different kinetic regimes: close to proportional to t(2/3) for ssDNA and proportional to sqrt[t] for dsDNA. While the kinetic behavior of ssDNA is consistent with the generally accepted Zimm theory of polymer dynamics, the kinetic behavior of dsDNA monomers is in good agreement with the Rouse model.     

Force-extension behavior of folding polymers

The elastic response of flexible polymers made of elements which can be either folded or unfolded, having different lengths in these two states, is discussed. These situations are common for biopolymers as a result of folding interactions intrinsic to the monomers, or as a result of binding of other smaller molecules along the polymer length. Using simple flexible-chain models, we show that even when the energy ε associated with maintaining the folded state is comparable to k _B T, the elastic response of such a chain can mimic usual polymer linear elasticity, but with a force scale enhanced above that expected from the flexibility of the chain backbone. We discuss recent experiments on single-stranded DNA, chromatin fiber and double-stranded DNA with proteins weakly absorbed along its length which show this effect. Effects of polymer semiflexiblity and torsional stiffness relevant to experiments on proteins binding to dsDNA are analyzed. We finally discuss the competition between electrostatic self-repulsion and folding interactions responsible for the complex elastic response of single-stranded DNA. Received 7 August 2002 and Received in final form 7 March 2003 / Published online: 15 April 2003 RID="a" ID="a"e-mail: jmarko@uic.edu     

Recoiling DNA molecule: simulation and experiment

Single molecule DNA experiments often generate data from force versus extension measurements involving the tethering of a microsphere to one end of a single DNA molecule while the other is attached to a substrate. We show that the persistence length of single DNA molecules can also be measured based on the recoil dynamics of these DNA-microsphere complexes if appropriate corrections are made to the friction coefficient of the microsphere in the vicinity of the substrate. Comparison between computer simulated recoil curves, generated from the corresponding Langevin equation, and experimental recoils are used to assure the validity of data analysis.