Glake Hill

Theoretical determination of one-electron redox potentials for DNA bases, base pairs, and stacks.

Electron affinities, ionization potentials, and redox potentials for DNA bases, base pairs, and N-methylated derivatives are computed at the DFT/M06-2X/6-31++G(d,p) level of theory. Redox properties of a guanine-guanine stack model are explored as well. Reduction and oxidation potentials are in good agreement with the experimental ones. Electron affinities of base pairs were found to be negative. Methylation of canonical bases affects the ionization potentials the most. Base pair formation and base stacking lower ionization potentials by 0.3 eV. Pairing of guanine with the 5-methylcytosine does not seem to influence the redox properties of this base pair much.

IR-UV double resonance spectroscopy of xanthine.

We present resonant two-photon ionization (R2PI), UV-UV, and IR-UV double resonance spectra of xanthine seeded in a supersonic jet by laser desorption. We show that there is only one tautomer of xanthine which absorbs in the wavelength range of 36 700 to 37 700 cm(-1). The IR-UV double resonance spectrum shows three strong bands at 3444, 3485, and 3501 cm(-1), all of which we assign as N-H stretching vibrations. Comparison of the IR-UV double resonance spectrum with frequencies and intensities obtained from density functional theory (DFT) and second order Møller Plesset (MP2) calculations suggests that the observed xanthine is the diketo N(7)H tautomer.

Theoretical ab Initio study of the effects of methylation on structure and stability of G:C watson-crick base pair

Abstract Methylation of DNA occurs most readily at N(3), N(7), and O(6) of purine bases and N(3) and O(2) of pyrimidines. Methylated bases are continuously formed through endogenous and exogenous mechanisms. The results of a theoretical ab initio study on the methylation of G:C base pair components are reported. The geometries of the local minima were optimized without symmetry restrictions by the gradient procedure at DFT level of theory and were verified by energy second derivative calculations. The standard 6–31G(d) basis set was used. The single-point calculations have been performed at the MP2/6–31G(d,p), MP2/6–31++G(d,p), and MP2/6–311++G(2d,2p) levels of theory. The geometrical parameters, relative stability and counterpoise corrected interaction energies are reported. Also, using a variation-perturbation energy decomposition scheme we have found the vital contributions to the total interaction energy.

Guanine–aspartic acid interactions probed with IR–UV resonance spectroscopy

Double resonance spectroscopy of clusters of guanine with aspartic acid reveals geometries similar to patterns exhibited in DNA base pairs. In the spectral region of 32,800 cm(-1) to 35,500 cm(-1) we observe five isomers of guanine-aspartic acid clusters and assign their structures based on IR-UV hole-burning spectra and wave function theory calculations at the MP2/cc-pVDZ and MP2/cc-pVTZ levels. The calculations employed both harmonic and one-dimensional scan anharmonic approximations. Three of the isomers are similar, assigned to structures containing three hydrogen bonds and 9-enolguanine. We assign the fourth isomer to a structure containing a 9-keto tautomer of guanine and forming a triply bonded structure similar to a base pairing interaction. The fifth isomer dissociates with proton transfer upon excitation or ionization. This is the first set of experiments and high-level ab initio calculations of the isolated, microscopic interactions of an amino acid and a nucleobase, the building blocks of nucleic acids and proteins.

Conventional strain energies of azetidine and phosphetane: Can density functional theory yield reliable results?

The conventional strain energies for azetidine and phosphetane are determined within the isodesmic, homodesmotic, and hyperhomodesmotic models. Optimum equilibrium geometries, harmonic vibrational frequencies, and corresponding electronic energies and zero‐point vibrational energies are computed for all pertinent molecular systems using self‐consistent field theory, second‐order perturbation theory, and density functional theory and using the correlation consistent basis sets cc‐pVDZ, cc‐pVTZ, and cc‐pVQZ. Single point fourth‐order perturbation theory, CCSD, and CCSD(T) calculations using the cc‐pVTZ and the cc‐pVQZ basis sets are computed using the MP2/cc‐pVTZ and MP2/cc‐pVQZ optimized geometries, respectively, to ascertain the contribution of higher order correlation effects and to determine if the quadruple‐zeta valence basis set is needed when higher order correlation is included. In the density functional theory study, eight different functionals are used including B3LYP, wB97XD, and M06‐2X to determine if any functional can yield results similar to those obtained at the CCSD(T) level.

Theoretical Investigation on Monomer and Solvent Selection for Molecular Imprinting of Nitrocompounds

The aim of this work is to serve as a guideline for the initial selection of monomer and solvent for the synthesis of the nitrocompound-based molecularly imprinted polymers, MIPs. Reported data include evaluation of six systems with the ability to form noncovalently bonded monomer-template complexes. These systems are represented by the following aliphatic and aromatic molecules: acrolein, acrylonitrile, 2,6-bisacrylamide, 4-ethylenebenzoic acid, methyl methacrylate, and 2-vinylpyridine. Cave models for selected monomers are also presented and supported by binding energy analysis under various conditions. Solvent effects on monomer-template binding energy have been studied for four solvents: acetone, acetonitrile, chloroform, and methanol. Additionally, systems such as 2,4-dinitrotoluene (2,4-DNT), 2,6-dinitrotoluene (2,6-DNT), pentachlorophenol (PCP), and 3,6-dichloro-2-methoxybenzoic acid (Dicamba) have been used to study selectivity of acrolein-based MIP toward TNT detection. The density functional theory, DFT, method has been used for all structural, vibrational frequency, and solvent calculations.

Molecular Structure and Properties of Protonated and Methylated Derivatives of Cytosine

Abstract Ab initio techniques were used to determine the effects of protonation and methylation on cytosines molecular geometry, molecular affinities, relative stability, and structural rigidity. The geometries of local minima were fully optimized by the gradient procedure at DFT and MP2 levels of theory with the medium size 6–31G(d,p) basis set. The results of energetic analysis indicate that N(3)-methyl-cytosine and C(5)-methyl-cytosine are the most stable derivatives for monocationic and neutral species, respectively. The structural rigidity of each species was assessed by an analysis of normal out-of-plane frequencies, the amplitudes, and by the contribution of internal coordinates to the potential energy distributions. The obtained evidence suggests that methylation increases the overall structural flexibility of cytosine and that all molecules in this study populate a non-planar conformation 50% of the time.

Theoretical study of tautomeric and ionizing effects of guanine, cytosine, and their methyl derivatives

The study of pre-translational effects (ionization, tautomerization) and post-translational effects (methylation) of guanine and cytosine has only recently been the focus of some studies. These effects can potentially help regulate gene expression as well as potentially disrupt normal gene function. Because of this wide array of roles, greater insight into these effects in deoxyribonucleic acids (DNA) are paramount. There has been considerable research of each phenomenon (tautomerization, methylation and ionization) individually. In this work, we attempt to shed light upon the pre- and post-translational effects of guanine and cytosine by investigating the electron affinities (EAs) and ionization potentials (IPs) of the major and minor tautomers and their methyl derivatives. We performed all calculations using the density functional theory B3LYP functional accompanied with 6-311G (d,p), 6-311+G (d,p), and 6-311++G (df,pd) basis sets. Our results reveal that the cytosine tautomer has a higher EA and IP than the guanine tautomers. The higher EA suggest that an electron that attaches to the GC base pair would predominately attach to the cytosine instead of guanine. The higher IP would suggest that an electron that is removed from the GC base pair would be predominately removed from the guanine within the base pair. Understanding how tautomerization, ionization, and methylation differences change effects, discourages, or promotes one another is lacking. In this work, we begin the steps of integrating these effects with one another, to gain a greater understanding of molecular changes in DNA bases.

cis-Diamminodichloronickel and Its Interaction with Guanine and Guanine–Cytosine Base Pair

Comprehensive ab initio calculations are performed on cis-diamminodichloronickel (cisni) at the HF, DFT, and MP2 levels of theory. The results are compared to those obtained for cisplatin. The characteristics of the interactions of cisni with guanine (G) and guanine–cytosine (GC) base pair are also evaluated and compared to the interactions of cisplatin. Cisni causes similar geometric changes of the base as cis-platinum when complexed to guanine. The nickel, palladium and platinum complexes also show similar characteristics when complexed to GC base pair. However, this study predicts higher dissociation energy of the cisni chlorine ligands that indicate areas of differences between the title Ni and Pt and Pd complexes. Comparison of the G-cisni interaction energy to that of cisplatin and cispd indicate differences between the Ni and Pd complexes, but also reveals its closer similarities to cisplatin.

Simple STM Tip Functionalization for Rapid DNA Sequencing : An Ab Initio Green's Function Study

An ab initio nonequilibrium Greens function study of the electron-transport properties of the adenine, thymine, cytosine, and guanine DNA bases located between gold electrodes has been performed. One-electron transmission spectra were calculated for both gold and sulfur-modified gold electrodes, which are model conditions of scanning tunneling microscopy (STM) experiments with the different tips. It is shown that the nature of chemical bonding between molecules and metal electrodes plays the most significant role in the overall conductance of the systems. The distance between electrodes and the size of molecules are less important, at least when both sides of the molecule form chemical contact with the electrodes. On the basis of the obtained results, a simple two-pass DNA sequencing scheme is suggested.