Adrià Gil

Influence of the Side Chain in the Structure and Fragmentation of Amino Acids Radical Cations.

The conformational properties of ionized amino acids (Gly, Ala, Ser, Cys, Asp, Gln, Phe, Tyr, and His) have been theoretically analyzed using the hybrid B3LYP and the hybrid-meta MPWB1K functionals as well as with the post-Hartree Fock CCSD(T) level of theory. As a general trend, ionization is mainly localized at the -NH2 group, which becomes more planar and acidic, the intramolecular hydrogen bond in which -NH2 acts as proton donor being strengthened upon ionization. For this reason, the so-called conformer IV(+) becomes the most stable for nonaromatic amino acid radical cations. Aromatic amino acids do not follow this trend because ionization takes place mainly at the side chain. For these amino acids for which ionization of the side chain prevails over the -NH2 group, structures III(+) and II(+) become competitive. The Cα-X fragmentations of the ionized systems have also been studied. Among the different decompositions considered, the one that leads to the loss of COOH(•) is the most favorable one. Nevertheless, for aromatic amino acids fragmentations leading to R(•) or R(+) start being competitive. In fact, for His and Tyr, results indicate that the fragmentation leading to R(+) is the most favorable process.

Effects of ionization on N-glycylglycine peptide: Influence of intramolecular hydrogen bonds

The ionization effects on 28 conformations of N-glycylglycine are analyzed by means of the hybrid B3LYP and the hybrid meta-MPWB1K density functionals and by single-point calculations at the CCSD(T) level of theory. The most favorable process observed corresponds to the ionization of the only neutral conformation that presents a OH...NH2 intramolecular hydrogen bond, which leads to CO2 elimination after a spontaneous proton transfer from -COOH to NH2. The remaining neutral structures evolve to 20 different conformations of N-glycylglycine radical cation, which lie about 25-40 kcal/mol higher than the decarboxylated [NH3CH2CONHCH2]+*...[CO2] complex. Structural changes induced by ionization depend on the intramolecular hydrogen bonds of the initial conformation, since they determine the nature of the electron hole formed. In most cases, ionization takes place at the terminal -NH2 and -CO of the amide bond, which produces a strengthening of the peptide bond and the formation of new -NH2...OC(amide) and -NH2...OCOH hydrogen bonds. However, if -NH2 and -CO(amide) simultaneously act as proton acceptor in the neutral conformation, ionization is mainly localized at the carboxylic group, which produces a strengthening of the -COOH...OC(amide) bond. Both functionals lead to similar trends and compare well with CCSD(T) results except for a few cases for which B3LYP provides a too delocalized picture of the electron hole and consequently leads to artificial geometry reorganization.

How the intercalation of phenanthroline affects the structure, energetics, and bond properties of DNA base pairs: theoretical study applied to adenine-thymine and guanine-cytosine tetramers.

The effects of phenanthroline (phen) intercalation on the structure, energetics, and bonding of adenine-thymine and guanine-cytosine tetramers (A-T/T-A and G-C/C-G) were studied through density functional theory (DFT) using functionals that were recently improved to consider the effect of dispersion forces. Our results given by energy decomposition analysis show that the dispersion contribution, ΔEdisp, is the most important contribution to the interaction energy, ΔEint. However, it is not enough to compensate the Pauli repulsion term, ΔEPauli, and the roles of the orbital contribution, ΔEorb, and, in particular, the electrostatic contribution, ΔEelstat, become crucial for the stabilization of the structures in the intercalation process. On the other hand, for G-C/C-G systems, hydrogen-bonding (HB) interactions are more important than stacking (S) interactions, whereas for A-T/T-A systems, HB and S become competitive. Moreover, intercalation produces important changes not only in the hydrogen bonds of base pairs, because S and HB are deeply connected, but also in other characteristic geometric parameters of the base pairs.

Influence of ionization on the conformational preferences of peptide models. Ramachandran surfaces of N‐formyl‐glycine amide and N‐formyl‐alanine amide radical cations

Ramachandran maps of neutral and ionized HCO–Gly–NH2 and HCO–Ala–NH2 peptide models have been built at the B3LYP/6‐31++G(d,p) level of calculation. Direct optimizations using B3LYP and the recently developed MPWB1K functional have also been carried out, as well as single‐point calculations at the CCSD(T) level of theory with the 6‐311++G(2df,2p) basis set. Results indicate that for both peptide models ionization can cause drastic changes in the shape of the PES in such a way that highly disallowed regions in neutral PES become low‐energy regions in the radical cation surface. The structures localized in such regions,

Base‐Catalyzed Anti‐Markovnikov Hydroamination of Vinylarenes – Scope, Limitations and Computational Studies

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CH/π Interactions in DNA and Proteins. A Theoretical Study

and

Structure and fragmentation of glycine, alanine, serine and cysteine radical cations. A theoretical study

\varepsilon^{+\bullet}_{\rm D}

How the site of ionisation influences side-chain fragmentation in histidine radical cation

are highly stabilized due to the formation of 2‐centre‐3‐electron interactions between the two carbonyl oxygens. Inclusion of solvent effects by the conductor‐like polarizable continuum model (CPCM) shows that the solute‐solvent interaction energy plays an important role in determining the stability order.