Enhanced structural transformations in DNA macromolecules exposed to weak thermalized neutron field

We examined now an ultraweak thermalized neutron field (UTNF) affects the structural transformation in DNA macromolecules at room temperature. IR-spectroscopy, electrophoresis, and filtration through nitrocellulose filter measurements revealed that UTNF irradiation with a fluence of F(n) - 1.0 - 3.7 x 10(7) n/cm2 (the absorbed dose as low as 10 - 50 microGy) can induce non negligible structural changes in DNA macromolecules in film as well as in an aqueous solution. These structural changes appear as a type of reversible conformational transition from the A-form to a disordered state, as well as through intermolecular cross-link formations and the generation of double-strand breaks.     

Direct visualization of asymmetric adenine-nucleotide-induced conformational changes in MutL alpha

MutL alpha, the heterodimeric eukaryotic MutL homolog, is required for DNA mismatch repair (MMR) in vivo. It has been suggested that conformational changes, modulated by adenine nucleotides, mediate the interactions of MutL alpha with other proteins in the MMR pathway, coordinating the recognition of DNA mismatches by MutS alpha and the activation of MutL alpha with the downstream events that lead to repair. Thus far, the only evidence for these conformational changes has come from X-ray crystallography of isolated domains, indirect biochemical analyses, and comparison to other members of the GHL ATPase family to which MutL alpha belongs. Using atomic force microscopy (AFM), coupled with biochemical techniques, we demonstrate that adenine nucleotides induce large asymmetric conformational changes in full-length yeast and human MutL alpha and that these changes are associated with significant increases in secondary structure. These data reveal an ATPase cycle in which sequential nucleotide binding, hydrolysis, and release modulate the conformational states of MutL alpha.     

Exploring the range of protein flexibility, from a structural proteomics perspective

Changes in protein conformation play a vital role in biochemical processes, from biopolymer synthesis to membrane transport. Initial systematizations of protein flexibility, in a database framework, concentrated on the movement of domains and linkers. Movements were described in terms of simple sliding and hinging mechanisms of individual secondary structural elements. Recently, the accelerated pace and sophistication of methods for structural characterization of proteins has allowed high-resolution studies of increasingly complex assemblies and conformational changes. New data emphasize a breadth of possible structural mechanisms, particularly the ability to drastically alter protein architecture and the native flexibility of many structures.     

Circular dichroism studies on chromatin models. Interactions between DNA and sequential polypeptides containing arginine

The sequential polypeptides (L-Arg-Xaa-Gly)n where Xaa represents amino acid residues Ala, Val and Leu, were employed as models of arginine-rich histones, in studying their interactions with nucleic acids. These polypeptide-DNA complexes were prepared using gradient dialysis and their conformational properties were investigated by circular dichroism spectroscopy. It was found that poly(L-Arg-L-Val-Gly) caused pronounced structural changes in the DNA molecule (conformational transition from B to the more compact and asymmetric C form) as a function of ionic strength and polypeptide: DNA ratio. In contrast the DNA interaction with poly (L-Arg-L-Ala-Gly) and poly (L-Arg-L-Leu-Gly) increased in the order of Ala----Leu, but with slight structural changes in the DNA secondary conformation. Thus, the importance of the composition, amino acid sequence and conformation of the polypeptides which bind to DNA was demonstrated. The significance of the hydrophobic forces besides the arginine-phosphate charge interaction, which modulate the nature of the polypeptide-DNA complexes and their condensation into higher-ordered tertiary structures, as found in chromatin, was also confirmed.     

Secondary conformational polymorphism of nucleic acids as a possible functional link between cellular parameters and DNA packaging processes

Circular dichroism and electron microscopy studies of various in vitro DNA packaging systems indicate that all the factors which induce and modulate the secondary conformation of DNA molecules are capable of eliciting nucleic acids condensation processes into tight, highly ordered tertiary structures as well as altering the extent of order and compactness within the resulting species. Specifically, such factors include the ionic strength, the presence of particular dehydrating agents and polyamines, as well as the pH values. It is proposed that slight alterations of these parameters induce the formation of short non-B-DNA segments that propagate as a perturbation along the B-DNA double helix. The structural fluctuations of the dsDNA molecules that result from the conformational discontinuities formed at the junction sites between the B motif and the conformationally altered segments alter the elastic response of the nucleic acids and facilitate cooperative condensation processes. Moreover, the type and frequency of the structurally modified clusters interspersed within the B conformation and determined by the environmental parameters are shown to provide a means for continuous regulation of the extent and mode of DNA packaging. The ionic strength and hydrophobic environment in the close vicinity of the DNA molecules are controlled and modulated in vivo by DNA-binding proteins such as histones and protamines; similarly, pH values and polyamine concentrations are constantly regulated in living systems. It is suggested, therefore, that the secondary structural polymorphism which characterizes the DNA molecules might display a regulatory role by acting as a functional link between cellular parameters and the extent, mode, and timing of nucleic acid packaging processes.     

Ligand-induced conformational and structural dynamics changes in Escherichia coli cyclic AMP receptor protein

Cyclic AMP receptor protein (CRP) regulates the expression of a large number of genes in E. coli. It is activated by cAMP binding, which leads to some yet undefined conformational changes. These changes do not involve significant redistribution of secondary structures. A potential mechanism of activation is a ligand-induced change in structural dynamics. Hence, the cAMP-mediated conformational and structural dynamics changes in the wild-type CRP were investigated using hydrogen-deuterium exchange and Fourier transform infrared spectroscopy. Upon cAMP binding, the two functional domains within the wild-type CRP undergo conformational and structural dynamics changes in two opposite directions. While the smaller DNA-binding domain becomes more flexible, the larger cAMP-binding domain shifts to a less dynamic conformation, evidenced by a faster and a slower amide H-D exchange, respectively. To a lesser extent, binding of cGMP, a nonfunctional analogue of cAMP, also stabilizes the cAMP-binding domain, but it fails to mimic the relaxation effect of cAMP on the DNA-binding domain. Despite changes in the conformation and structural dynamics, cAMP binding does not alter significantly the secondary structural composition of the wild-type CRP. The apparent difference between functional and nonfunctional analogues of cAMP is the ability of cAMP to effect an increase in the dynamic motions of the DNA binding domain.     

Analysis of the changes in the structure and hydration of the nucleosome core particle at moderate ionic strengths

In order to better understand the conformational changes induced in the nucleosome core particle by changes in the ionic strength of the media in the range from 0.1 to 0.6 M NaCl, we have conducted a very detailed structural analysis, combining circular dichroism, DNase I digestion, and sedimentation equilibrium. The results of such analysis indicate that the secondary structure of both DNA and histones exhibits small (approximately 5%) but noticeable changes as the salt increases within this range. In the case of DNA, the data are consistent with a trend toward a more relaxed secondary structure. The DNase I pattern of digestion is also altered by the salt and suggests a DNA relaxation around the flanking ends. From the hydrodynamic measurements, we also observe a significant change in the virial coefficients of the particle as the salt increases, which in turn are in very good agreement with the theoretically expected values. Furthermore, the preferential hydration parameter is also found to increase with the salt. We believe that the self-dependent conformational change of the nucleosome core particle is the result of the conjunction of all these subtle changes. Yet, from the present data, their exact relationship to the tertiary structure of the whole particle at the different ionic strengths cannot be exactly defined.     

The agonist paradox: agonists and antagonists of acetylcholine receptors and opioid receptors

In contrast to antagonists, agonists tend to induce considerable conformational changes in their receptors, resulting in opening of ion channels, either directly or via secondary messengers. These conformational transformations require great energy expenses. However, the experimentally determined free energies of complexation between agonists and receptors are often relatively smaller than those for the corresponding antagonists. To rationalize this so-called 'agonist paradox', which has not been clarified in the literature, we have developed an alternative model. Our model may help to discriminate between agonists and antagonists of the acetylcholine (ACh) and mu-opioid receptors. For this purpose, a series of ligands (1-18) have been analyzed both in structural terms and with respect to complexation geometry within the anionic binding sites of these two receptor types.     

Ethanol and acetonitrile induces conformational changes in porcine pepsin at alkaline denatured state

Pepsin, a member of the aspartate protease family, exists in a partially unfolded state at alkaline pH where the N-terminal domain of pepsin has a flexible structure while the C-terminal domain has a highly folded structure. In this work, the conformational stability of porcine pepsin in an alkaline denatured (A(D)) state against acetonitrile and ethanol solvents was studied using a combination of electronic circular dichroism (ECD) and fluorescence techniques. The ECD results demonstrate that both ethanol and acetonitrile induce secondary structural changes in pepsin at A(D) state. However, the minimum concentration required to induce significant secondary structural changes in pepsin varies for ethanol (>30%, v/v) and acetonitrile (>60%, v/v) solvents. At maximum concentration used (90%, v/v), both solvents induce predominantly β-sheet conformation. Unlike acetonitrile, ethanol induces significant amount of non-native α-helical conformations at the intermediate concentrations (50-80%). The tryptophan fluorescence results demonstrate that both acetonitrile and ethanol induce substantial changes in the tertiary structure of pepsin in the A(D) state above certain concentrations. The current results have important implications in understanding the effect of co-solvents on the conformation of proteins in the "denatured state".     

The thermodynamic parameters of the conformational transitions in Mycoplasma DNA

DNA preparations have been isolated from 10 strains of phytopathogenic mycoplasms and collection culture Achole plasma laidlawii PG-8. Thermodynamic parameters of denaturation changes in the secondary structure (transconformation) of DNA of these mycoplasms have been determined. It is shown that denaturation temperature is 82.3-83.1 degree C and enthalpy of conformational DNA transitions calculated per 1 g of dry substance is 56.2-61.9 J/g. Changes in the enthalpy (delta H) and entropy (delta S) calculated per 1 mol of nucleotide pairs varied in the range of 35.6-39.0 J/m.p. and 995-109.6 J degree m.p. respectively. No linear dependence of transconformational thermal adsorption on the temperature of DNA denaturation of the studied strains of mycoplasms are revealed, which is probably connected with structural peculiarities of DNA of these microorganisms.     

Solvent Microenvironments and Copper Binding Alters the Conformation and Toxicity of a Prion Fragment

The secondary structures of amyloidogenic proteins are largely influenced by various intra and extra cellular microenvironments and metal ions that govern cytotoxicity. The secondary structure of a prion fragment, PrP(111-126), was determined using circular dichroism (CD) spectroscopy in various microenvironments. The conformational preferences of the prion peptide fragment were examined by changing solvent conditions and pH, and by introducing external stress (sonication). These physical and chemical environments simulate various cellular components at the water-membrane interface, namely differing aqueous environments and metal chelating ions. The results show that PrP(111-126) adopts different conformations in assembled and non-assembled forms. Aging studies on the PrP(111-126) peptide fragment in aqueous buffer demonstrated a structural transition from random coil to a stable β-sheet structure. A similar, but significantly accelerated structural transition was observed upon sonication in aqueous environment. With increasing TFE concentrations, the helical content of PrP(111-126) increased persistently during the structural transition process from random coil. In aqueous SDS solution, PrP(111-126) exhibited β-sheet conformation with greater α-helical content. No significant conformational changes were observed under various pH conditions. Addition of Cu²⁺ ions inhibited the structural transition and fibril formation of the peptide in a cell free in vitro system. The fact that Cu²⁺ supplementation attenuates the fibrillar assemblies and cytotoxicity of PrP(111-126) was witnessed through structural morphology studies using AFM as well as cytotoxicity using MTT measurements. We observed negligible effects during both physical and chemical stimulation on conformation of the prion fragment in the presence of Cu²⁺ ions. The toxicity of PrP(111-126) to cultured astrocytes was reduced following the addition of Cu²⁺ ions, owing to binding affinity of copper towards histidine moiety present in the peptide.     

Cyclic assemblies formed by metal ions, pyrimidines and isogeometrical heterocycles: DNA binding properties and antitumour activity

In this contribution, we discuss the use of simple pyrimidine derivatives and geometrically related heterocycles in combination with protected metal ions to build cyclic polynuclear coordination assemblies. The resulting assemblies range from conformationally rigid triangles to corrugated octagons with positively charged cavities and surfaces that can interact with anionic species in a supramolecular fashion. Special attention has been focussed to the supramolecular interaction of these systems towards mononucleotides and DNA as a possible novel interaction of DNA binding metallo-drugs. The results show that these systems efficiently interact with both mononucleotides and ds-DNA. The molecular recognition of ds-DNA leads to significant conformational changes, however, this interaction gives only rise to moderate cytotoxic effects towards tumour cell lines.     

Probing the conformational switch of I-motif DNA using tunable resistive pulse sensing

I-motif DNA, which can fold and unfold reversibly in various environments, plays a significant role in DNA nanotechnology and biological functions. Thus, it is of fundamental importance to identify the different conformations of i-motif DNA. Here, we demonstrate that distinct structures of i-motif DNA conjugated to polystyrene spheres can be distinguished through tunable resistive pulse sensing technique. When dispersed in acidic buffer, i-motif DNA coating on polystyrene spheres would fold into quadruplex structure and subsequently induce an apparent increase in the translocation duration time upon passing through a nanopore due to the shielding effect of the surface charge of the nanospheres. However, if the DNA strands don't have conformational changes in acidic buffer, little shift can be observed in the translocation duration time of the DNA functionalized polystyrene spheres. A before-and-after assay was also performed to illustrate the fast speed of i-motif DNA folding using this technique. The successful implementation of tunable resistive pulse sensing to monitor the conformational transition of i-motif DNA provides a potential tool to detect the structural changes of DNA and an alternative approach to study the function of DNA structures.     

Dissecting the mechanism of Epac activation via hydrogen-deuterium exchange FT-IR and structural modeling

Exchange proteins directly activated by cAMP (Epac) make up a family of cAMP binding domain-containing proteins that play important roles in mediating the effects of cAMP through the activation of downstream small GTPases, Ras-proximate proteins. To delineate the mechanism of Epac activation, we probed the conformation and structural dynamics of Epac using amide hydrogen-deuterium (H-D) exchange coupled with Fourier transform infrared spectroscopy (FT-IR) and structural modeling. Our studies show that unlike that of cAMP-dependent protein kinase (PKA), the classic intracellular cAMP receptor, binding of cAMP to Epac does not induce significant changes in overall secondary structure and structural dynamics, as measured by FT-IR and the rate of H-D exchange, respectively. These results suggest that Epac activation does not involve significant changes in the amount of exposed surface areas as in the case of PKA activation, and conformational changes induced by cAMP in Epac are most likely confined to small local regions. Homology modeling and comparative structural analyses of the CBDs of Epac and PKA lead us to propose a model of Epac activation. On the basis of our model, Epac activation by cAMP employs the same underlying structural principal utilized by PKA, although the detailed structural and conformational changes associated with Epac and PKA activation are significantly different. In addition, we predict that during Epac activation the first beta-strand of the switchboard switches its conformation to a alpha-helix, which folds back to the beta-barrel core of the CBD and interacts directly with cAMP to form the base of the cAMP-binding pocket.     

DNA Architecture,Deformability, and Nucleosome Positioning

Abstract

The positioning of DNA on nucleosomes is critical to both the organization and expression of the genetic message. Here we focus on DNA conformational signals found in the growing library of known high-resolution core-particle structures and the ways in which these features may contribute to the positioning of nucleosomes on specific DNA sequences. We survey the chemical composition of the protein-DNA assemblies and extract features along the DNA superhelical pathway—the minor-groove width and the deformations of successive base pairs—determined with reasonable accuracy in the structures. We also examine the extent to which the various nucleosome core-particle structures accommodate the observed settings of the crystallized sequences and the known positioning of the high-affinity synthetic ‘601’ sequence on DNA. We ‘thread’ these sequences on the different structural templates and estimate the cost of each setting with knowledge-based potentials that reflect the conformational properties of the DNA base-pair steps in other high-resolution protein-bound complexes.     

A-form conformational motifs in ligand-bound DNA structures

Recognition and biochemical processing of DNA requires that proteins and other ligands are able to distinguish their DNA binding sites from other parts of the molecule. In addition to the direct recognition elements embedded in the linear sequence of bases (i.e. hydrogen bonding sites), these molecular agents seemingly sense and/or induce an "indirect" conformational response in the DNA base-pairs that facilitates close intermolecular fitting. As part of an effort to decipher this sequence-dependent structural code, we have analyzed the extent of B-->A conformational conversion at individual base-pair steps in protein and drug-bound DNA crystal complexes. We take advantage of a novel structural parameter, the position of the phosphorus atom in the dimer reference frame, as well as other documented measures of local helical structure, e.g. torsion angles, base-pair step parameters. Our analysis pinpoints ligand-induced conformational changes that are difficult to detect from the global perspective used in other studies of DNA structure. The collective data provide new structural details on the conformational pathway connecting A and B-form DNA and illustrate how both proteins and drugs take advantage of the intrinsic conformational mechanics of the double helix. Significantly, the base-pair steps which exhibit pure A-DNA conformations in the crystal complexes follow the scale of A-forming tendencies exhibited by synthetic oligonucleotides in solution and the known polymorphism of synthetic DNA fibers. Moreover, most crystallographic examples of complete B-to-A deformations occur in complexes of DNA with enzymes that perform cutting or sealing operations at the (O3'-P) phosphodiester linkage. The B-->A transformation selectively exposes sugar-phosphate atoms, such as the 3'-oxygen atom, ordinarily buried within the chain backbone for enzymatic attack. The forced remodeling of DNA to the A-form also provides a mechanism for smoothly bending the double helix, for controlling the widths of the major and minor grooves, and for accessing the minor groove edges of individual base-pairs.     

Conformational changes in DNA‐binding proteins: Relationships with precomplex features and contributions to specificity and stability

Both Proteins and DNA undergo conformational changes in order to form functional complexes and also to facilitate interactions with other molecules. These changes have direct implications for the stability and specificity of the complex, as well as the cooperativity of interactions between multiple entities. In this work, we have extensively analyzed conformational changes in DNA‐binding proteins by superimposing DNA‐bound and unbound pairs of protein structures in a curated database of 90 proteins. We manually examined each of these pairs, unified the authors' annotations, and summarized our observations by classifying conformational changes into six structural categories. We explored a relationship between conformational changes and functional classes, binding motifs, target specificity, biophysical features of unbound proteins, and stability of the complex. In addition, we have also investigated the degree to which the intrinsic flexibility can explain conformational changes in a subset of 52 proteins with high quality coordinate data. Our results indicate that conformational changes in DNA‐binding proteins contribute significantly to both the stability of the complex and the specificity of targets recognized by them. We also conclude that most conformational changes occur in proteins interacting with specific DNA targets, even though unbound protein structures may have sufficient information to interact with DNA in a nonspecific manner. Proteins 2014; 82:841–857. © 2013 Wiley Periodicals, Inc.     

DNA-induced conformational changes in bacteriophage 434 repressor

Although bacteriophage 434 repressor binds to its specific DNA sites only as a dimer, formation of the dimers in solution occurs at concentrations three orders of magnitude higher than those needed to bind the 434 operator DNA. Our results suggest that both specific and non-specific DNA induce conformational changes in repressor that lead to formation of repressor dimers. The repressor conformational changes induced by DNA occur at concentrations much lower than those needed for binding of repressor, suggesting that the alternative conformations of repressor persist even if the protein is not in direct contact with DNA. Hence, DNA acts in a "catalytic" fashion to induce a steady-state amount of an alternative repressor conformation that has an enhanced affinity for its specific binding site. These findings suggest that the repressor conformer induced by non-specific DNA is the form of the repressor that is optimized for searching for DNA binding sites along non-specific DNA. Upon finding a binding site, the repressor protein undergoes an additional conformational change that allows it to "lock-on" to its specific site.