AFM for analysis of structure and dynamics of DNA and protein-DNA complexes

This paper describes protocols for studies of structure and dynamics of DNA and protein-DNA complexes with atomic force microscopy (AFM) utilizing the surface chemistry approach. The necessary specifics for the preparation of functionalized surfaces and AFM probes with the use of silanes and silatranes, including the protocols for synthesis of silatranes are provided. The methodology of studies of local and global conformations DNA with the major focus on the time-lapse imaging of DNA in aqueous solutions is illustrated by the study of dynamics of Holliday junctions including branch migration. The analysis of nucleosome dynamics is selected as an example to illustrate the application of the time-lapse AFM to studies of dynamics of protein-DNA complexes. The force spectroscopy is the modality of AFM with a great importance to various fields of biomedical studies. The AFM force spectroscopy approach for studies of specific protein-DNA complexes is illustrated by the data on analysis of dynamics of synaptic SfiI-DNA complexes. When necessary, additional specifics are added to the corresponding example.     

DNA structure and dynamics

This review primarily outlines the most recent atomic force microscopy (AFM) studies of DNA structure and dynamics. Sample preparation techniques allowing reliable and reproducible imaging of various DNA topologies are reviewed. Such important issues as imaging of supercoiled DNA conformations at different ionic conditions and detection of local alternative structures that are stabilized by negative DNA supercoiling are discussed in length in the article. The possibility of imaging DNA structural dynamics at different levels is another major focus of the article. Using time-lapse AFM imaging mode of nondried samples, such extensive DNA dynamic processes as transition of one local structure into another (H-DNA to B-form transition), the conformational transitions of DNA Holliday junctions and their branch migration were observed. Potential future applications of this single-molecule dynamics mode of AFM to analyses of various biochemical processes involving DNA are discussed.     

Probing tethered targets of a single biomolecular complex with atomic force microscopy

DNA origami shows tremendous promise as templates for the assembly of nano‐components and detection of molecular recognition events. So far, the method of choice for evaluating these structures has been atomic force microscopy (AFM), a powerful tool for imaging nanoscale objects. In most cases, tethered targets on DNA origami have proven to be highly effective samples for investigation. Still, while maximal assembly of the nanostructures might benefit from the greatest flexibility in the tether, AFM imaging requires a sufficient stability of the adsorbed components. The balance between the tether flexibility and sample stability is a major, poorly understood, concern in such studies. Here, we investigated the dependence of the tethering length on molecular capture events monitored by AFM. In our experiments, single biotin molecules were attached to DNA origami templates with various linker lengths of thymidine nucleotides, and their interaction with streptavidin was observed with AFM. Our results show that the streptavidin‐biotin complexes are easily detected with short tethered lengths, and that their morphological features clearly change with the tethering length. We identify the functionally useful tether lengths for these investigations, which are also expected to prove useful in the construction and further application of DNA origami in bio‐nanotechnology studies. Copyright © 2013 John Wiley & Sons, Ltd.     

High-resolution AFM imaging of single-stranded DNA-binding (SSB) protein--DNA complexes

DNA in living cells is generally processed via the generation and the protection of single-stranded DNA involving the binding of ssDNA-binding proteins (SSBs). The studies of SSB-binding mode transition and cooperativity are therefore critical to many cellular processes like DNA repair and replication. However, only a few atomic force microscopy (AFM) investigations of ssDNA nucleoprotein filaments have been conducted so far. The point is that adsorption of ssDN A-SSB complexes on mica, necessary for AFM imaging, is not an easy task. Here, we addressed this issue by using spermidine as a binding agent. This trivalent cation induces a stronger adsorption on mica than divalent cations, which are commonly used by AFM users but are ineffective in the adsorption of ssDNA-SSB complexes. At low spermidine concentration (<0.3 mM), we obtained AFM images of ssDNA-SSB complexes (E. coli SSB, gp32 and yRPA) on mica at both low and high ionic strengths. In addition, partially or fully saturated nucleoprotein filaments were studied at various monovalent salt concentrations thus allowing the observation of SSB-binding mode transition. In association with conventional biochemical techniques, this work should make it possible to study the dynamics of DNA processes involving DNA-SSB complexes as intermediates by AFM.     

Insight into the cooperative DNA binding of the O6-alkylguanine DNA alkyltransferase

The O⁶-alkylguanine DNA alkyltransferase (AGT) is a highly conserved protein responsible for direct repair of alkylated guanine and to a lesser degree thymine bases. While specific DNA lesion-bound complexes in crystal structures consist of monomeric AGT, several solution studies have suggested that cooperative DNA binding plays a role in the physiological activities of AGT. Cooperative AGT–DNA complexes have been described by theoretical models, which can be tested by atomic force microscopy (AFM). Direct access to structural features of AGT–DNA complexes at the single molecule level by AFM imaging revealed non-specifically bound, cooperative complexes with limited cluster length. Implications of cooperative binding in AGT–DNA interactions are discussed.     

Human topoisomerase II-DNA interaction study by using atomic force microscopy

Type II topoisomerases (Topo II) are unique enzymes that change the DNA topology by catalyzing the passage of two double-strands across each other by using the energy from ATP hydrolysis. In vitro, human Topo II relaxes positive supercoiled DNA around 10-fold faster than negative supercoiled DNA. By using atomic force microscopy (AFM) we found that human Topo II binds preferentially to DNA cross-overs. Around 50% of the DNA crossings, where Topo II was bound to, presented an angle in the range of 80-90°, suggesting a favored binding geometry in the chiral discrimination by Topo II. Our studies with AFM also helped us visualize the dynamics of the unknotting action of Topo II in knotted molecules.     

抗癌药物奥沙利铂与DNA分子相互作用的研究

奥沙利铂被称为第三代铂类药物,特别对胃肠道肿瘤具有较好的疗效.目前大多数的研究表明奥沙利铂的主要作用靶点是DNA分子,但它与DNA分子形成的关键结构和作用机制仍处在探索阶段.本研究运用紫外可见吸收光谱和原子力显微镜观察探索奥沙利铂与DNA在活体外的相互作用过程,从而揭示奥沙利铂产生抗癌作用的主要分子结构基础.首先使用紫外光谱研究了较高浓度奥沙利铂与DNA的作用过程.在此基础上,进一步采用原子力显微镜在高定向热解石墨表面观察了不同浓度奥沙利铂与质粒DNA在37℃条件下作用不同时间后的结构形貌变化,分析了奥沙利铂与DNA相互作用的过程.高分辨原子力显微观察结果表明奥沙利铂与DNA作用后可导致质粒DNA的结构发生显著的变化.随着作用时间的增加,DNA分子逐渐由伸展的链状变化为相互缠绕并带有许多结点的紧密结构,最终变化为更紧密的球状结构.本研究结果表明奥沙利铂可通过化学键合作用和静电作用使质粒DNA逐渐凝集为紧密的球状结构,这种结构可能对奥沙利铂的抗癌活性和毒性产生重要影响.     

Imaging of nucleic acids with atomic force microscopy

Atomic force microscopy (AFM) is a key tool of nanotechnology with great importance in applications to DNA nanotechnology and to the recently emerging field of RNA nanotechnology. Advances in the methodology of AFM now enable reliable and reproducible imaging of DNA of various structures, topologies, and DNA and RNA nanostructures. These advances are reviewed here with emphasis on methods utilizing modification of mica to prepare the surfaces enabling reliable and reproducible imaging of DNA and RNA nanostructures. Since the AFM technology for DNA is more mature, AFM imaging of DNA is introduced in this review to provide experience and background for the improvement of AFM imaging of RNA. Examples of imaging different structures of RNA and DNA are discussed and illustrated. Special attention is given to the potential use of AFM to image the dynamics of nucleic acids at the nanometer scale. As such, we review recent advances with the use of time-lapse AFM.     

Direct haplotyping of kilobase-size DNA using carbon nanotube probes

We have implemented a method for multiplexed detection of polymorphic sites and direct determination of haplotypes in 10-kilobase-size DNA fragments using single-walled carbon nanotube (SWNT) atomic force microscopy (AFM) probes. Labeled oligonucleotides are hybridized specifically to complementary target sequences in template DNA, and the positions of the tagged sequences are detected by direct SWNT tip imaging. We demonstrated this concept by detecting streptavidin and IRD800 labels at two different sequences in M13mp18. Our approach also permits haplotype determination from simple visual inspection of AFM images of individual DNA molecules, which we have done on UGT1A7, a gene under study as a cancer risk factor. The haplotypes of individuals heterozygous at two critical loci, which together influence cancer risk, can be easily and directly distinguished from AFM images. The application of this technique to haplotyping in population-based genetic disease studies and other genomic screening problems is discussed.     

Analysis of interaction between DNA and Deinococcus radiodurans PprA protein by atomic force microscopy

A DNA repair-promoting protein, PprA, was isolated from a radiation resistant bacterium, Deinococcus radiodurans [I. Narumi, K. Sato, S. Cui, T. Funayama, S. Kitayama, H. Watanabe, PprA: a novel protein from Deinococcus radiodurans that stimulates DNA ligation, Mol. Microbiol. 54 (2004) 278-285]. Despite several studies, however, the function of PprA is not still clear. We used atomic force microscopy (AFM) to elucidate the role of this protein in the DNA repair pathway. In the present study, interaction between the linear DNA and PprA protein was imaged and analyzed by AFM without any fixation or staining. Though both end-bound and internally bound PprA was observed, the affinity of the end-bound protein was greater considering the proportion of features of binding analyzed by AFM. In some conditions, looping forms of the DNA-PprA complex were observed. Gel filtration high performance liquid chromatography (HPLC) was also conducted to estimate the molecular weight of this protein. The result of the HPLC analysis suggested that PprA formed multimers in buffer solution without DNA.     

RecA-double stranded DNA complexes studied by atomic force microscopy.

RecA-double stranded (ds) DNA complexes have been studied by atomic force microscopy (AFM). When the complexes were prepared in the presence of ATP gamma S, fully covered RecA-dsDNA filaments were observed by AFM. When the concentration of RecA proteins was lower, various lengths of filaments were found. The variation of the observed structures may directly reflect the real distribution of the intermediate complexes in the reaction mixture, as the mixture was simply deposited on a mica surface for AFM observation without special fixation or staining. The use of a carbon nanotube (CNT) AFM tip enabled high resolution to reveal the periodicity of RecA-dsDNA filaments. Our observations demonstrated the potential of the AFM method for the structural studies of the RecA-dsDNA complexes, especially their intermediate states.     

Delocalization of vaccinia virus components observed by atomic force and fluorescence microscopy

Better understanding of viral genomes is emerging as an urgent need as these genomes evolve and pandemic fears surface and for better understanding of viral infection processes. To address this need, we report a method to visualize intact, viral DNA and its interaction with viral proteins with the use of the atomic force microscope (AFM) in conjunction with fluorescence microscopy. Through a series of multifaceted experiments, we were able to visualize time-dependent progressive stages of proteolytic digestion and disassembly of extracellular enveloped vaccinia virus particles. After a 1-h treatment, the viral particles were partially digested and the viral cores showed slight disassociation in the AFM as evidenced by height analysis of individual virions. Most of the components of the virions were still intact. Further verification with florescence microscopy with nucleophilic and lipophilic stains demonstrated that viral DNA was, indeed still, co-localized within the viral core. However, with prolonged treatment with proteinase K and sodium dodecylsulfate, the AFM revealed that the viral core completely collapsed onto the substrate and had delocalized from the enclosed DNA. This process was again verified using fluorescence microscopy, the viral DNA was observed to be completely released from the viral core, in globular condensed form. These studies suggest that AFM imaging and fluorescence microscopy verification with stains specific for different constituents of viral particles is a valuable method to study the structural and mechano elastic properties of virus morphology and interactions of viral nucleoproteins with its DNA core. These authors contributed equally to the work.     

Determination of protein-DNA binding constants and specificities from statistical analyses of single molecules: MutS-DNA interactions

Atomic force microscopy (AFM) is a powerful technique for examining the conformations of protein–DNA complexes and determining the stoichiometries and affinities of protein–protein complexes. We extend the capabilities of AFM to the determination of protein–DNA binding constants and specificities. The distribution of positions of the protein on the DNA fragments provides a direct measure of specificity and requires no knowledge of the absolute binding constants. The fractional occupancies of the protein at a given position in conjunction with the protein and DNA concentrations permit the determination of the absolute binding constants. We present the theoretical basis for this analysis and demonstrate its utility by characterizing the interaction of MutS with DNA fragments containing either no mismatch or a single mismatch. We show that MutS has significantly higher specificities for mismatches than was previously suggested from bulk studies and that the apparent low specificities are the result of high affinity binding to DNA ends. These results resolve the puzzle of the apparent low binding specificity of MutS with the expected high repair specificities. In conclusion, from a single set of AFM experiments, it is possible to determine the binding affinity, specificity and stoichiometry, as well as the conformational properties of the protein–DNA complexes.     

激光作用质粒DNA和小牛胸腺DNA的AFM研究

激光作用质粒ＤＮＡ和小牛胸腺ＤＮＡ产生损伤效应,导致ＤＮＡ结构变化,利用一种改进的试样制备过程和纳米显微镜--原子力显微镜（ＡＦＭ）能够获得可重现的激光作用质粒ＤＮＡ和小牛胸腺ＤＮＡ的ＡＦＭ图象,显示它们的特殊的表面结构。     

The measurement of exonuclease activities by atomic force microscopy

We have applied atomic force microscopy (AFM) to the measurement of BAL 31 nuclease activities. BAL 31 nuclease, a species of exonuclease, is used to remove unwanted sequences from the termini of DNA before cloning. For cutting out only the appropriate sequences, it is important to know the nuclease properties, such as digestion speed and the distribution of the lengths of the digested DNA. AFM was used to obtain accurate measurements on the lengths of DNA fragments before and after BAL 31 nuclease digestion. We analyzed 4 DNAs with known number of base pairs (288, 778, 1818, and 3162 base pairs) for correlating the contour length measured by AFM with the number of base pairs under the deposition conditions used. We used this calibration for analyzing DNA degradation by BAL 31 nuclease from the AFM measurement of contour lengths of digested DNAs. In addition, the distribution of digested DNA could be analyzed in more detail by AFM than by electrophoresis, because digested DNA were measured as a population by electrophoresis, but were measured individually by AFM. These results show that AFM will be a useful new technique for measuring nuclease activities. Received: 8 August 1997 / Accepted: 10 September 1997     

High-resolution AFM imaging of single-stranded DNA-binding (SSB) protein—DNA complexes

DNA in living cells is generally processed via the generation and the protection of single-stranded DNA involving the binding of ssDNA-binding proteins (SSBs). The studies of SSB-binding mode transition and cooperativity are therefore critical to many cellular processes like DNA repair and replication. However, only a few atomic force microscopy (AFM) investigations of ssDNA nucleoprotein filaments have been conducted so far. The point is that adsorption of ssDN A–SSB complexes on mica, necessary for AFM imaging, is not an easy task. Here, we addressed this issue by using spermidine as a binding agent. This trivalent cation induces a stronger adsorption on mica than divalent cations, which are commonly used by AFM users but are ineffective in the adsorption of ssDNA–SSB complexes. At low spermidine concentration (<0.3mM), we obtained AFM images of ssDNA–SSB complexes (E. coli SSB, gp32 and yRPA) on mica at both low and high ionic strengths. In addition, partially or fully saturated nucleoprotein filaments were studied at various monovalent salt concentrations thus allowing the observation of SSB-binding mode transition. In association with conventional biochemical techniques, this work should make it possible to study the dynamics of DNA processes involving DNA–SSB complexes as intermediates by AFM.     

Atomic force microscopy of long and short double-stranded, single-stranded and triple-stranded nucleic acids.

Atomic force microscopy (AFM, also called scanning force microscopy) is proving to be a useful technique for imaging DNA. Thus it is important to push the limits of AFM imaging in order to explore both what types of DNA can be reliably imaged and identified and also what substrates and methods of sample preparation are suitable. The following advances in AFM of DNA are presented here. (i) DNA molecules as short as 25 bases can be seen by AFM. The short single-stranded DNAs imaged here (25 and 50 bases long) appeared globular in the AFM, perhaps because they are all capable of intramolecular base pairing and because the DNAs were in a Mg(ll) buffer, which facilitates intramolecular cross-bridging. (ii) AFM images in air of short double-stranded DNA molecules, 100-200 bp, gave lengths consistent with A-DNA. (iii) AFM images of poly (A) show both short bent lumpy molecules with an apparent persistence length of 40 nm and long straight molecules with an apparent persistence length of 600 nm. For comparison, the apparent persistence length for double-stranded DNA from phX-174 under the same conditions was 80 nm. (iv) Structures believed to be triple- stranded DNA were seen in samples of poly(dA.poly(dT) and poly (dG).poly(dC). These structures were twice as high as double-stranded DNA and the same width. (v) Entire molecules of lambda DNA, approx. 16 micron long, were imaged clearly in overlapping scans. (vi) Plasmid DNA was imaged on oxidized silicon, although less clearly than on mica.     

Analysis of radiation damage of DNA by atomic force microscopy in comparison with agarose gel electrophoresis studies

DNA damage induced with ionizing radiation is considered one of the main causes of cell inactivation. Several methods including gel electrophoresis, pulsed-field gel electrophoresis, neutral filter elution method, neutral sedimentation and electron microscopy have been applied to analyze this type of DNA damage. A new method employing an atomic force microscope (AFM) for nanometer-level-structure analysis of DNA damage induced with gamma-irradiation is introduced in this report. Structural changes of plasmid DNA on a molecular size scale of about 3 kbp were visually analyzed by AFM after irradiation with 60Co gamma-rays at doses of 1.9, 5.6, and 8.3 kGy. Three forms of plasmid DNA, closed circular (intact DNA), open circular (DNA with a single strand break) and linear form (DNA with a double strand break) were visualized by dynamic force mode AFM after gamma-irradiation. The torsional feature of the plasmid DNA was visualized better with AFM than with a transmission electron microscope (TEM). All three forms of plasmid DNA were observed in the sample irradiated with gamma-rays at the dose of 1.9 kGy. Open circular and linear forms were observed in the samples irradiated with gamma-rays at doses of 5.6 and 8.3 kGy, though no closed circular form was observed. A shortening of the length of a linear form of DNA irradiated with 5.6 and 8.3 kGy gamma-rays was observed by AFM. Structural changes of DNA after gamma-irradiation were visualized by AFM at nanometer level resolution. In addition, shortening of the length of the linear form of DNA after radiation exposure was observed by AFM.     

Cisplatin induces loop structures and condensation of single DNA molecules

Structural properties of single λ DNA treated with anti-cancer drug cisplatin were studied with magnetic tweezers and AFM. Under the effect of low-concentration cisplatin, the DNA became more flexible, with the persistence length decreased significantly from ~52 to 15 nm. At a high drug concentration, a DNA condensation phenomenon was observed. Based on experimental results from both single-molecule and AFM studies, we propose a model to explain this kind of DNA condensation by cisplatin: first, di-adducts induce local distortions of DNA. Next, micro-loops of ~20 nm appear through distant crosslinks. Then, large aggregates are formed through further crosslinks. Finally, DNA is condensed into a compact globule. Experiments with Pt(dach)Cl₂ indicate that oxaliplatin may modify the DNA structures in the same way as cisplatin. The observed loop structure formation of DNA may be an important feature of the effect of platinum anti-cancer drugs that are analogous to cisplatin in structure.     

A simple and effective sample preparation method for atomic force microscopy visualization of individual DNA molecules in situ

A simple, controllable and effective sample preparation method was established for atomic force microscopy (AFM) imaging of individual DNA molecules in aqueous solution. Firstly, magnesium ion (Mg²⁺) at a concentration of 5.0–10.0 mM as a positively charged bridge was transferred onto mica to immobilize DNA molecules. Then Mg²⁺-modified mica was used to investigate DNA molecules in any buffer without magnesium ion by AFM. AFM images demonstrated that DNA molecules can be successfully observed in solution with good resolution, reproducibility, and stability. Further, this DNA sample preparation method makes AFM successful to investigate DNA molecular interaction in situ and DNA/chitosan complex in gene delivery.