19F electron nuclear double resonance (ENDOR) spectroscopy for distance measurements using trityl spin labels in DNA duplexes.

The combination of fluorine labeling and pulsed electron-nuclear double resonance (ENDOR) is emerging as a powerful technique for obtaining structural information about proteins and nucleic acids. In this work, we explored the capability of Mims 19F ENDOR experiments on reporting intermolecular distances in trityl- and 19F-labeled DNA duplexes at three electron paramagnetic resonance (EPR) frequencies (34, 94, and 263 GHz). For spin labeling, we used the hydrophobic Finland trityl radical and hydrophilic OX063 trityl radical. Fluorine labels were introduced into two positions of a DNA oligonucleotide. The results indicated that hyperfine splittings visible in the ENDOR spectra are consistent with the most populated interspin distances between 19F and the trityl radical predicted from molecular dynamic (MD) simulations. Moreover, for some cases, ENDOR spectral simulations based on MD results were able to reproduce the conformational distribution reflected in the experimental ENDOR line broadening. Additionally, MD simulations provided more detailed information about the melting of terminal base pairs of the oligonucleotides and about the configuration of the trityls relative to a DNA end.

Application of the weighted histogram method for calculating the thermodynamic parameters of the formation of oligodeoxyribonucleotide duplexes.

To date, many derivatives and analogs of nucleic acids (NAs) have been developed. Some of them have found uses in scientific research and biomedical applications. Their effective use is based on the data about their properties. Some of the most important physicochemical properties of oligonucleotides are thermodynamic parameters of the formation of their duplexes with DNA and RNA. These parameters can be calculated only for a few NA derivatives: locked NAs, bridged oligonucleotides, and peptide NAs. Existing predictive approaches are based on an analysis of experimental data and the consequent construction of predictive models. The ongoing pilot studies aimed at devising methods for predicting the properties of NAs by computational modeling techniques are based only on knowledge about the structure of oligonucleotides. In this work, we studied the applicability of the weighted histogram analysis method (WHAM) in combination with umbrella sampling to the calculation of thermodynamic parameters of DNA duplex formation (changes in enthalpy ΔH°, entropy ΔS°, and Gibbs free energy ΔG° 37). A procedure was designed involving WHAM for calculating the hybridization properties of oligodeoxyribonucleotides. Optimal parameters for modeling and calculation of thermodynamic parameters were determined. The feasibility of calculation of ΔH°, ΔS°, and ΔG° 37 was demonstrated using a representative sample of 21 oligonucleotides 4-16 nucleotides long with a GC content of 14-100 %. Error of the calculation of the thermodynamic parameters was 11.4, 12.9, and 11.8 % for ΔH°, ΔS°, and ΔG° 37, respectively, and the melting temperature was predicted with an average error of 5.5 °C. Such high accuracy of computations is comparable with the accuracy of the experimental approach and of other methods for calculating the energy of NA duplex formation. In this paper, the use of WHAM for computation of the energy of DNA duplex formation was systematically investigated for the first time. Our results show that a reliable calculation of the hybridization parameters of new NA derivatives is possible, including derivatives not yet synthesized. This work opens up new horizons for a rational design of constructs based on NAs for solving problems in biomedicine and biotechnology.

Application of W-band 19F electron nuclear double resonance (ENDOR) spectroscopy to distance measurement using a trityl spin probe and a fluorine label.

Recently, Marina Bennati and coworkers (M. Bennati et al., Angew. Chem., Int. Ed., 2020, 59, 373-379., M. Bennati et al., J. Magn. Reson., 2021, 333, 107091) proposed to use electron nuclear double resonance (ENDOR) spectroscopy in the W-band for a pair of labels, nitroxide and 19F, for measurements of short (0.5-1.0 nm) distances in biomolecules. In our paper, we investigated the suitability of high-field ENDOR spectroscopy in the W-band for pairs of triarylmethyl and fluorine labels using five newly synthesized model compounds. It is shown that the application of strong magnetic fields allows distinguishing nuclear frequencies of 19F and protons with sufficient resolution. On the one hand, in contrast to nitroxides, for triarylmethyl radicals, it is not necessary to obtain spectra in different orientations owing to low g-factor anisotropic and long electron spin relaxation times of triarylmethyls. On the other hand, the size of the triarylmethyl radical is substantially larger than that of nitroxide and comparable with measured distances. We theoretically analyzed the suitability of the dipole-dipole approach for triarylmethyl to be used in a 19F ENDOR experiment and determined limitations of this approach. Finally, for comparison, we performed paramagnetic relaxation enhancement (PRE) NMR on the same compounds. In addition, we applied this approach to study the process of a thiol exchange between molecules of triarylmethyl-labeled and 19F-labeled human serum albumin (HSA).

[Calculation of Energy for RNA/RNA and DNA/RNA Duplex Formation by Molecular Dynamics Simulation].

The development of approaches for predictive calculation of hybridization properties of various nucleic acid (NA) derivatives is the basis for the rational design of the NA-based constructs. Modern advances in computer modeling methods provide the feasibility of these calculations. We have analyzed the possibility of calculating the energy of DNA/RNA and RNA/RNA duplex formation using representative sets of complexes (65 and 75 complexes, respectively). We used the classical molecular dynamics (MD) method, the MMPBSA or MMGBSA approaches to calculate the enthalpy (ΔH°) component, and the quasi-harmonic approximation (Q-Harm) or the normal mode analysis (NMA) methods to calculate the entropy (ΔS°) contribution to the Gibbs energy (ΔG°37) of the NA complex formation. We have found that the MMGBSA method in the analysis of the MD trajectory of only the NA duplex and the empirical linear approximation allow calculation of the enthalpy of formation of the DNA, RNA, and hybrid duplexes of various lengths and GC content with an accuracy of 8.6%. Within each type of complex, the combination of rather efficient MMGBSA and Q-Harm approaches being applied to the trajectory of only the bimolecular complex makes it possible to calculate the ΔG°37 of the duplex formation with an error value of 10%. The high accuracy of predictive calculation for different types of natural complexes (DNA/RNA, DNA/RNA, and RNA/RNA) indicates the possibility of extending the considered approach to analogs and derivatives of nucleic acids, which gives a fundamental opportunity in the future to perform rational design of new types of NA-targeted sequence-specific compounds.

Recognition and removal of clustered DNA lesions via nucleotide excision repair.

Clustered damage of DNA consists of two or more lesions located within one or two turns of the DNA helix. Clusters consisting of lesions of various structures can arise under the influence of strong damaging factors, especially if the cells have a compromised repair status. In this work, we analyzed how the presence of an analog of the apurinic/apyrimidinic site - a non-nucleoside residue consisting of diethylene glycol phosphodiester (DEG) - affects the recognition and removal of a bulky lesion (a non-nucleoside site of the modified DNA strand containing a fluorescein residue, nFlu) from DNA by a mammalian nucleotide excision repair system. Here we demonstrated that the efficiency of nFlu removal decreases in the presence of DEG in the complementary strand and is completely suppressed when the DEG is located opposite the nFlu. By contrast, protein factor XPC-RAD23B, which initiates global genomic nucleotide excision repair, has higher affinity for DNA containing clustered damage as compared to DNA containing a single bulky lesion; the affinity of XPC strengthens as the positions of DEG and nFlu become closer. The changes in the double-stranded DNA's geometry caused by the presence of clustered damage were also assessed. The obtained experimental data together with the results of molecular dynamics simulations make it possible to get insight into the structural features of DNA containing clustered lesions that determine the efficiency of repair. Speaking more broadly, this study should help to understand the probable fate of bulky adduct-containing clusters of various topologies in the mammalian cell.

A QCM-based rupture event scanning technique as a simple and reliable approach to study the kinetics of DNA duplex dissociation.

Rupture Event Scanning (REVS) is applied for the first time within an approach based on dynamic force spectroscopy. Using model DNA duplexes containing 20 pairs of oligonucleotides including those containing single mismatches, we demonstrated the possibility of reliable determination of the kinetic parameters of dissociation of biomolecular complexes: barrier positions, the rate constants of dissociation, and the lifetime of complexes. Within this approach, mechanical dissociation of DNA duplexes occurs according to a mechanism similar to unzipping. It is shown that this process takes place by overcoming a single energy barrier. In the case where a mismatch is located at the farthest duplex end from the QCM surface, a substantial decrease in the position of the barrier between the bound and unbound states is observed. We suppose that this is due to the formation of an initiation complex containing 3-4 pairs of bases, and this is sufficient for starting duplex unzipping.

The Structural and Immunological Properties of Chimeric Proteins Containing HIV-1 MPER Sites.

The human immunodeficiency virus (HIV-1) poses a serious risk to global public health. The development of a safe and effective vaccine could stop the HIV/AIDS pandemic. Much of the research focused on HIV-1 prevention through vaccination is aimed at developing immunogens and immunization strategies to induce the formation of antibodies with neutralizing activity against a broad range of HIV-1 isolates (bNAbs). The objective of this study was to develop immunogens capable of targeting an immune response to MPER, one of the regions of bNAb binding in Env. Two immunogens carrying MPER fragments on their scaffolds (protein YkuJ Bacillus subtilis and artificial polypeptide TBI) were constructed. Circular dichroism spectroscopy was used to show that the secondary structure of the immunogens was consistent with their theoretical models. The antigenic structure of the MPER-TBI and YkuJ-MPER proteins was characterized using bNAbs that recognize HIV-1 MPER (2F5, 4E10, and 10E8). The rabbit model made it possible to show the immunogenicity of the constructed recombinant proteins. The resulting serum was found to be cross-reactive with immunogens carrying MPER. The constructs designed and characterized in this study can be used for targeting the humoral immune response to MPER, which is known to be one of the sites of HIV-1 vulnerability.

[Modified Oligonucleotides for Guiding RNA Cleavage Using Bacterial RNase P].

The ability of a series of novel modified external guide sequences (EGS oligonucleotides) to induce the hydrolysis of target RNA with bacterial ribonuclease P has been studied; the most efficient modification variants have been selected. We have found patterns of the oligonucleotide sugar-phosphate backbone modi-fications that enhance oligonucleotide stability in the biological environment and do not violate the ability to interact with the enzyme and induce the RNA hydrolysis. It has been shown that analogues of EGS oligonucleotides selectively modified at 2'-position (2'-O-methyl and 2'-fluoro) or at internucleotide phosphates (phosphoryl guanidines) can be used for the addressed cleavage of a model RNA target by bacterial RNase P. The ability of new phosphoryl guanidine analogues of oligodeoxyribonucleotides that are stable in biological media to induce the hydrolysis of target RNA with bacterial ribonuclease P has been shown for the first time. The modified EGS oligonucleotides with an optimal balance between functional activity and stability in biological media can be considered as potential antibacterial agents.

Global DNA dynamics of 8-oxoguanine repair by human OGG1 revealed by stopped-flow kinetics and molecular dynamics simulation.

The toxic action of different endogenous and exogenous agents leads to damage in genomic DNA. 8-Oxoguanine is one of the most often generated and highly mutagenic oxidative forms of damage in DNA. Normally, in human cells it is promptly removed by 8-oxoguanine-DNA-glycosylase hOGG1, the key DNA-repair enzyme. An association between the accumulation of oxidized guanine and an increased risk of harmful processes in organisms was already found. However, the detailed mechanism of damaged base recognition and removal is still unclear. To clarify the role of active site amino acids in the damaged base coordination and to reveal the elementary steps in the overall enzymatic process we investigated hOGG1 mutant forms with substituted amino acid residues in the enzyme base-binding pocket. Replacing the functional groups of the enzyme active site allowed us to change the rates of the individual steps of the enzymatic reaction. To gain further insight into the mechanism of hOGG1 catalysis a detailed pre-steady state kinetic study of this enzymatic process was carried out using the stopped-flow approach. The changes in the DNA structure after mixing with enzymes were followed by recording the FRET signal using Cy3/Cy5 labels in DNA substrates in the time range from milliseconds to hundreds of seconds. DNA duplexes containing non-damaged DNA, 8-oxoG, or an AP-site or its unreactive synthetic analogue were used as DNA-substrates. The kinetic parameters of DNA binding and damage processing were obtained for the mutant forms and for WT hOGG1. The analyses of fluorescence traces provided information about the DNA dynamics during damage recognition and removal. The kinetic study for the mutant forms revealed that all introduced substitutions reduced the efficiency of the hOGG1 activity; however, they played pivotal roles at certain elementary stages identified during the study. Taken together, our results gave the opportunity to restore the role of substituted amino acids and main "damaged base-amino acid" contacts, which provide an important link in the understanding the mechanism of the DNA repair process catalyzed by hOGG1.

Rational design and studies of excimer forming novel dual probes to target RNA.

In this paper, we report structure-based rational design and physico-chemical and biological studies of novel pyrene excimer forming dual probes for visualization of intracellular RNAs. Herein, the probes based on 2'-O-methyl RNA with linkers of different structure and length between pyrene moiety and ribose are studied with respect to their hybridization and spectral properties. We found optimal linkers that provide more intense excimer emission (at ∼480nm) of RNA-bound probes; particularly, the length of the linker arm of the 3'-component of dual probes plays a key role in formation of pyrene excimer. Calculated molecular dynamics trajectories and probability distributions of pyrene-pyrene dimer formation upon hybridization of the dual probes with RNA target are in agreement with the obtained fluorescence spectroscopy data for the corresponding duplexes. Our study demonstrates the excellent binding properties of new dual probes to structured RNA and their feasibility for the visualization of intracellular RNA targets.

[Synthesis and properties of methylene carboxamide mimetics of nucleic acids based on morpholine nucleosides].

Uracyl and adenine containing oligocarboxamide mimetics of nucleic acids based on morpholine nucleosides (MorGly) are synthesized using peptide chemistry methods. Conditions for an analysis of homogeneity of protonated at physiological pH oligomers using a capillary electrophoresis are proposed. Studies of thermostability of complementary complexes formed by MorGly oligomers revealed that melting temperature dramatically depends on heterocyclic base composition (uracyl or adenine). Cooperative interactions realized at junctions in tandem complexes give more contribution to the thermostability in the case of complexes formed by modified oligomers than native oligodeoxyriboadenilates. Adenine containing MorGly oligomers form more stable complexes with poly(U) than native oligodeoxyriboadenilate of the same length. Complexes formed by modified oligomers with polyribonucleotides are more stable in compare with polydeoxyribonucleotide.

[Considering the oligonucleotides secondary structures at thermodynamic and kinetic analysis of the DNA-duplexes formation].

The influence of secondary structures of DNA oligonucleotides on thermodynamics and kinetics at the formation of their bimolecular complexes (duplexes) has been studied. The models considering inherent secondary structures of duplex components and their influence on quantitative thermodynamic and kinetic characteristics of the duplexes have been developed. The values of thermodynamic impacts given by individual structural elements of the double helix have been shown to depend on hairpin structuring of the duplex components. The "concentration" method to consider oligonucleotides intramolecular structure with thermodynamic parameters of bimolecular duplex formation has been proposed. According to stop-flow measurements, the observed values of association and dissociation constants are influenced by the presence of inherent structures in duplex components. The influence observed is increased with the lowering of the sample temperature. The analysis of experimental data involving the developed models provides the possibility to determine "proper" kinetic constants for the helix-to-coil transition. The difference between observed and calculated rate constants can amount up to two or more orders of magnitude.

[Bent dsDNA with defined geometric characteristics in terms of complexes of bridged oligonucleotides].

An opportunity of designing nontypical double-stranded DNA structures containing nonnatural inserts in a regular nucleotide DNA sequence has been investigated. The looped nucleotide inserts on the basis of adenylates and thymidilates, and nonnucleotide inserts on the basis of phosphodiesters of diethyleneglycol, 1,10-decanediol, and 3-hydroxy-2-hudroxymethyltetrahydrofuran were introduced into the backbone of a 32-mer native DNA duplex. These inserts formed the internal loops in the modified double-stranded DNA fragments which were shown to lead to bending of the linear duplex structure by 16 to 83 degrees. The dependencies of the bend angle of dsDNA on the composition and the length of the looped regions were determined. It was established that the bend of the irregular region of dsDNA depended on the electrostatic interaction of the phosphate residues. The tension in the complex structure could be reduced by the introduction of additional nucleotide units opposite the loop, which led to some relaxation of the bent helix. The resulting parameters of the bend values were shown to be in a good agreement with the published data obtained by NMR spectroscopy. It was demonstrated that the variation of the nature or the length of the insert allowed one to regulate the level of the local perturbation of the duplex structure and, thereby, influence both the bend level of the double helix and the destabilization of the modified complex.

[Thermodynamic description of oligonucleotide self-association in DNA concatamer structures].

A scheme of the formation of concatamer structures consisting of two different oligonucleotides has been considered. It was shown that, in the general case, the dependence of the concentration of oligonucleotide components on temperature cannot be found in the analytic form. Therefore, it is impossible to find the thermodynamic parameters of the formation of concatamer complexes (deltaH0, deltaS0) and melting temperature by analyzing the profiles of thermal denaturation of oligonucleotide complexes. An algorithm of the numerical solution of implicit dependences has been developed. A number of approaches have been considered that simplify the analysis of thermal denaturation curves of concatamer complexes. It was shown that the analytical dependence of the efficiency of the concatamer formation on temperature can be described when duplex fragments have close stability and there is no cooperativity at the helix-helix interface. In this case, the dependence of melting temperature on thermodynamic parameters and oligonucleotide concentration has the same form as in the case of the duplex structure formed by a pair of noncomplementary oligonucleotides. The capacity of various model approaches to describe the experimental curves of thermal denaturation of concatamer structures has been evaluated. For the case of concatamer structures used as signal amplifiers in DNA hybridization analysis, a function was introduced that shows a relative contribution of a concatamer of a fixed length to the magnitude of signal amplification. The dependence of the maximum of this function on the concentration of oligonucleotides, the thermodynamic characteristics of their complexes, and temperature has been determined. It was shown by the gel shift assay that the function of the length distribution of concatamers qualitatively correlates with the experimental dependences.

Hybridization of the bridged oligonucleotides with DNA: thermodynamic and kinetic studies.

Hybridization properties of oligonucleotides containing non-nucleotide inserts designed on the basis of synthetic abasic sites, oligomethylene diols or oligoethylene glycols have been characterized. The influence of the inserts which generate extrahelical anucleotidic bulges on thermodynamics, kinetics of hybridization of bridged oligonucleotide with DNA has been studied by UV-melting and stopped-flow techniques. Circular dichroism spectrometry data show that anucleotidic bulges in the middle of the duplex does not alter the B-form helix conformation. Nevertheless, the insert induces destabilization of the duplex structure, caused mostly by the considerable enhancement of the dissociation rates. Free energy increments for the extrahelical anucleotidic bulges can be described in the nearest-neighbor approximation. The thermodynamic effect of the insert lengthening obeys a simple Jacobson-Stockmayer entropy extrapolation. Independently of the insert type, the free energy term is directly proportional to the logarithm of the number of bonds between the oligonucleotide fragments. The behavior of hydrophobic inserts formed by 10-hydroxydecyl-1-phospate units is an exception to the rule.

3'-modified oligo (2'-O-methylribonucleotides) as improved probes for hybridization with RNA.

A series of octa (2-O-methylribonucleotides) with an additional 3'-terminal deoxynucleoside (T, dC, dA or dG) linked by the 3'-3' (inverted) bond was synthesized. The exceptional stability of these oligomers to a 3'-exonuclease (SVP) and nucleases in culture medium containing 10% heat-inactivated fetal calf serum was demonstrated. It was shown that the addition of the 3'-dangling inverted deoxynucleoside increases substantially the thermal stability of the duplexes of oligo(2'-O-methylribonucleotides) with complementary RNA and DNA in the case of a relatively weak terminal AmU(T) pair and enhances the mismatch sensitivity.