Theoretical analysis of competitive conformational transitions in torsionally stressed DNA

This paper presents a theoretical analysis of the conformation of a torsionally deformed segment of DNA containing two sites susceptible to stress-induced transitions in secondary structure. A mechanical analysis of the ensuing competitive behavior is developed and applied to several phenomena of possible biological relevance. First, a molecular lesion which disrupts base pairing without strand breakage (such as a pyrimidine dimer) is shown to provide an effective nucleation site for further stress-induced denaturation. A competition is established between strand separation at this lesion site and at the A + T-richest portion of the molecule. The relative importance of these two forms of melting is shown to depend upon the A + T-content of the sites involved, segment length, local environmental conditions and the magnitude of the imposed torsional deformation. A possible alternative mode of behavior of a stressed segment of DNA involves transitions from B-form to Z-form. The second application of this theory analyzes the interplay between B → Z transitions and local denaturation in torsionally stressed DNA. Finally, local melting is shown to be energetically preferred over transitions to A-form under physiologically reasonable conditions in vitro, due primarily to the greater degree of unwinding involved in melting.The mechanical theory presented here makes several simplifying assumptions regarding the nature of the transitions and the sequences involved. First, the theory is developed explicitly for the competition between two sites of possible transition, with no further consideration given to conformational degeneracy or sequence effects. These sites are regarded as being uniform in composition. A multistate, heteropolymeric statistical mechanical transition theory is required to account rigorously for degeneracy and the influence of base sequence. A preliminary formulation of such a theory is used to analyze the denaturation of a segment containing a site of disrupted base pairing.     

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.     

Supercoiling-dependent sequence specificity of mammalian DNA methyltransferase.

Negative supercoiling of substrate DNA dramatically alters the in vitro sequence specificity of mammalian DNA methyltransferase (DNA MeTase). This result suggests that in vivo site selection by DNA MeTase could be regulated by conformational information in the form of alternative secondary structures induced in DNA by local supercoiling or by the binding of specific nuclear proteins. DNA in the left-handed Z-form is shown not to be a substrate for mammalian DNA MeTase. The sensitivity of DNA MeTase to DNA structure may also make it useful as a probe for sequences which undergo supercoiling-dependent structural transitions in vitro.     

Conformational transitions of DNA induced by changing water content of the sample: a theoretical study

A semi-phenomenological model with spatially distributed parameters is suggested to describe the processes of conformational transitions induced with change of water content of wet DNA samples. It allows describing conformational dynamics of DNA molecules with heterogeneous primary structures. It has been shown that the process of cooperative conformational transition can be simulated as propagating front of a new conformation. The evolution of a conformational perturbation of DNA molecule has been described. It can collapse for finite time or occupy the whole molecule depending on the water content of the sample.     

Visualization of the maturation transition in bacteriophage P22 by electron cryomicroscopy

Large-scale conformational transitions are involved in the life-cycle of many types of virus. The dsDNA phages, herpesviruses, and adenoviruses must undergo a maturation transition in the course of DNA packaging to convert a scaffolding-containing precursor capsid to the DNA-containing mature virion. This conformational transition converts the procapsid, which is smaller, rounder, and displays a distinctive skewing of the hexameric capsomeres, to the mature virion, which is larger and more angular, with regular hexons. We have used electron cryomicroscopy and image reconstruction to obtain 15 A structures of both bacteriophage P22 procapsids and mature phage. The maturation transition from the procapsid to the phage results in several changes in both the conformations of the individual coat protein subunits and the interactions between neighboring subunits. The most extensive conformational transformation among these is the outward movement of the trimer clusters present at all strict and local 3-fold axes on the procapsid inner surface. As the trimer tips are the sites of scaffolding binding, this helps to explain the role of scaffolding protein in regulating assembly and maturation. We also observe DNA within the capsid packed in a manner consistent with the spool model. These structures allow us to suggest how the binding interactions of scaffolding and DNA with the coat shell may act to control the packaging of the DNA into the expanding procapsids.     

Global Conformational Dynamics of a Y-Family DNA Polymerase during Catalysis

Replicative DNA polymerases are stalled by damaged DNA while the newly discovered Y-family DNA polymerases are recruited to rescue these stalled replication forks, thereby enhancing cell survival. The Y-family DNA polymerases, characterized by low fidelity and processivity, are able to bypass different classes of DNA lesions. A variety of kinetic and structural studies have established a minimal reaction pathway common to all DNA polymerases, although the conformational intermediates are not well defined. Furthermore, the identification of the rate-limiting step of nucleotide incorporation catalyzed by any DNA polymerase has been a matter of long debate. By monitoring time-dependent fluorescence resonance energy transfer (FRET) signal changes at multiple sites in each domain and DNA during catalysis, we present here a real-time picture of the global conformational transitions of a model Y-family enzyme: DNA polymerase IV (Dpo4) from Sulfolobus solfataricus. Our results provide evidence for a hypothetical DNA translocation event followed by a rapid protein conformational change prior to catalysis and a subsequent slow, post-chemistry protein conformational change. Surprisingly, the DNA translocation step was induced by the binding of a correct nucleotide. Moreover, we have determined the directions, rates, and activation energy barriers of the protein conformational transitions, which indicated that the four domains of Dpo4 moved in a synchronized manner. These results showed conclusively that a pre-chemistry conformational change associated with domain movements was too fast to be the rate-limiting step. Rather, the rearrangement of active site residues limited the rate of correct nucleotide incorporation. Collectively, the conformational dynamics of Dpo4 offer insights into how the inter-domain movements are related to enzymatic function and their concerted interactions with other proteins at the replication fork.     

Side-chain conformational changes upon Protein-Protein Association

Conformational changes upon protein-protein association are the key element of the binding mechanism. The study presents a systematic large-scale analysis of such conformational changes in the side chains. The results indicate that short and long side chains have different propensities for the conformational changes. Long side chains with three or more dihedral angles are often subject to large conformational transition. Shorter residues with one or two dihedral angles typically undergo local conformational changes not leading to a conformational transition. A relationship between the local readjustments and the equilibrium fluctuations of a side chain around its unbound conformation is suggested. Most of the side chains undergo larger changes in the dihedral angle most distant from the backbone. The frequencies of the core-to-surface interface transitions of six nonpolar residues and Tyr are larger than the frequencies of the opposite surface-to-core transitions. The binding increases both polar and nonpolar interface areas. However, the increase of the nonpolar area is larger for all considered classes of protein complexes, suggesting that the protein association perturbs the unbound interfaces to increase the hydrophobic contribution to the binding free energy. To test modeling approaches to side-chain flexibility in protein docking, conformational changes in the X-ray set were compared with those in the docking decoy sets. The results lead to a better understanding of the conformational changes in proteins and suggest directions for efficient conformational sampling in docking protocols.     

DNA models for A, B, C and D conformations related to fiber X-ray, infrared and NMR measurements

A conformational analysis of the A, B, C and D DNA forms was made in order to establish molecular models presenting a good agreement with experimental data obtained from fiber X-ray, infrared linear dichroism and 31P NMR. The proposed models have been refined and do present good stereochemistry and optimized H-bond distances between bases associated with the Watson-Crick pairing. The DNA conformations proposed are a left handed double helix for the C form and right handed helices for A, B and D. Relations to conformational transitions between these forms are discussed.     

Theoretical study of large conformational transitions in DNA: the B<-->A conformational change in water and ethanol/water

We explore here the possibility of determining theoretically the free energy change associated with large conformational transitions in DNA, like the solvent-induced BA conformational change. We find that a combination of targeted molecular dynamics (tMD) and the weighted histogram analysis method (WHAM) can be used to trace this transition in both water and ethanol/water mixture. The pathway of the transition in the A→B direction mirrors the B→A pathway, and is dominated by two processes that occur somewhat independently: local changes in sugar puckering and global rearrangements (particularly twist and roll) in the structure. The B→A transition is found to be a quasi-harmonic process, which follows closely the first spontaneous deformation mode of B-DNA, showing that a physiologically-relevant deformation is in coded in the flexibility pattern of DNA.     

Pre-steady-state kinetics shows differences in processing of various DNA lesions by Escherichia coli formamidopyrimidine-DNA glycosylase

Formamidopyrimidine-DNA-glycosylase (Fpg pro tein, MutM) catalyses excision of 8-oxoguanine (8-oxoG) and other oxidatively damaged purines from DNA in a glycosylase/apurinic/apyrimidinic-lyase reaction. We report pre-steady-state kinetic analysis of Fpg action on oligonucleotide duplexes containing 8-oxo-2′-deoxyguanosine, natural abasic site or tetrahydrofuran (an uncleavable abasic site analogue). Monitoring Fpg intrinsic tryptophan fluorescence in stopped-flow experiments reveals multiple conformational transitions in the protein molecule during the catalytic cycle. At least four and five conformational transitions occur in Fpg during the interaction with abasic and 8-oxoG-containing substrates, respectively, within 2 ms to 10 s time range. These transitions reflect the stages of enzyme binding to DNA and lesion recognition with the mutual adjustment of DNA and enzyme structures to achieve catalytically competent conformation. Unlike these well-defined binding steps, catalytic stages are not associated with discernible fluorescence events. Only a single conformational change is detected for the cleavable substrates at times exceeding 10 s. The data obtained provide evidence that several fast sequential conformational changes occur in Fpg after binding to its substrate, converting the protein into a catalytically active conformation.     

Predicting order of conformational changes during protein conformational transitions using an interpolated elastic network model

The decryption of sequence of structural events during protein conformational transitions is essential to a detailed understanding of molecular functions ofvarious biological nanomachines. Coarse‐grained models have proven useful by allowing highly efficient simulations of protein conformational dynamics. By combining two coarse‐grained elastic network models constructed based on the beginning and end conformations of a transition, we have developed an interpolated elastic network model to generate a transition pathway between the two protein conformations. For validation, we have predicted the order of local and global conformational changes during key ATP‐driven transitions in three important biological nanomachines (myosin, F₁ ATPase and chaperonin GroEL). We have found that the local conformational change associated with the closing of active site precedes the global conformational change leading to mechanical motions. Our finding is in good agreement with the distribution of intermediate experimental structures, and it supports the importance of local motions at active site to drive or gate various conformational transitions underlying the workings of a diverse range of biological nanomachines. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Experimental method for studying conformational transitions in DNA

An experimental method combining fiber X-ray and direct fiber dimension measurements is proposed for the study of DNA conformational transitions. Curves corresponding to the A-B and B-C transitions are obtained by using the proportionality which exists between the fiber length and the axial rise per nucleotide in the DNA helix. The A-B transition is shown to be cooperative while the B-C one is a progressive change of helical conformation.     

Molecular dynamics of structural transitions and intercalation in DNA

The large-scale flexibility of DNA and the intercalation of actinomycin D have been studied by computer simulation using molecular dynamics. The stretching and unwinding of B and Z forms of DNA and intercalation in B-DNA were examined through molecular dynamics simulations, and the energetics of transitions were calculated by the conformational energy minimization method. The principal results of this research are as follows: (1) A dynamic conformational pathway is presented for longitudinal stretching and unwinding of the double helix to open an intercalation site. (2) Large-scale transitions are possible in both B and Z forms of DNA through a conformationally allowed kinetic pathway. (3) The stretching and untwisting of a 5′(CG)3′ step is energetically more favorable than for a GC step in B-DNA. (4) The formation of an adjacent second cavity in B-DNA requires larger energy than the formation of the first cavity, affirming the neighbor-exclusion principle of intercalation. (5) Docking an intercalated actinomycin D in the stretched structure is shown to be geometrically and energetically feasible.     

DNA Models for A,B, C and D Conformations Related to Fiber X-ray,Infrared and NMR Measurements

Abstract

A conformational analysis of the A, B, C and D DNA forms was made in order to establish molecular models presenting a good agreement with experimental data obtained from fiber X-ray, infrared linear dichroism and ³¹P NMR. The proposed models have been refined and do present good stereochemistry and optimized H-bond distances between bases associated with the Watson-Crick pairing. The DNA conformations proposed are a left handed double helix for the C form and right handed helices for A, B and D. Relations to conformational transitions between these forms are discussed.