DFT studies of conversion of methyl chloride and three substituted chloromethyl tetrahydrofuran derivatives during reaction with trimethylamine

Conformational preferences of guanine-containing threose nucleic acid building blocks in B3LYP studies

In this paper, detailed and systematic gas-phase B3LYP conformational studies of four monomers of threose nucleic acid (TNA) with guanine attached at the C1' atom and bearing different substituents (OH, OP(=O)OH2 and OCH3) in the C2' and C3' positions of the α-l-threofuranose moiety are presented. All exocyclic single-bond (χ, ε and γ) rotations, as well as the ν0-ν4 endocyclic torsion angles, were taken into consideration. Three (threoguanosines TG1-TG3) or two (TG4) energy minima were found for the rotation about the χ torsion angle. The syn orientation (the A rotamer family) is strongly privileged in geometries TG1 and TG2, whereas the anti orientation (the C rotamer family) and the syn orientation are observed to be in equilibrium (with populations of 56% and 44%, respectively) for TG3. In the case of TG4, the high-anti orientation (the B rotamer family) turned out to be by far the most favourable, with the contribution exceeding 90% in equilibrium. Such a preference can be attributed to the inability of H-bonding between sugar and nucleobase and possibly because of the steric strains. The low-energy conformers of TG1-TG4 occupy the northeastern (P ∼ 40°) and/or southern (P ∼ 210°) parts of the pseudorotational wheel, which fits the A- and B-type DNA helices quite well. Additionally, in the case of TG4, some relatively stable geometries have the furanoid ring in conformation lying on the northwestern part of the pseudorotational wheel (P ∼ 288°).

Threocytidines: Insight into the Conformational Preferences of Artificial Threose Nucleic Acid (TNA) Building Blocks in B3LYP Studies

A systematic DFT conformational studies of four building blocks of TNA with cytosine attached to the C1' atom of the α-L-threofuranose moiety are presented. Structures bearing 2'-OR and 3'-OR substituents, where R represents H, CH₃ and phosphate groups, were used in the studies using a B3LYP functional in the gas phase. The χ angle (C2-N1-C1'-O4'), the ν₀-ν₄ endocyclic torsion angles and the exocyclic torsion angles ε (X-O2'-C2'-C1') and γ (X-O3'-C3'-C2') geometry parameter variations were taken into consideration. Three energy minima, high-anti, anti and syn, were found for the rotation about the C1'-N1 bond. The high-anti orientation of the base with respect to the sugar moiety, turned out to be preferred, regardless of the substituents at the C2' and C3' positions. Other orientations are at least 1.65 kcal/mol higher in Gibbs free energy than the high-anti one. It has been shown that intramolecular H-bonds and the anomeric effect of phosphate groups strongly affect the conformational preferences of the studied compounds. Further, the structure of substituents attached to the sugar moiety influence the pucker of the furanoid ring. The furanoid ring in the global minima of the compound with two OH groups (TC1) in the 2' and 3' positions, and the compound having a 3'-phosphate group (TC2), adopt roughly the same conformation located at the southern range of the pseudorotation wheel, and thus are close to those found in the B type DNA helix. The low-energy high-anti rotamers of the geometry with the phosphate group attached to the sugar ring in the 2' position (TC3) and the geometry with two methoxyl groups (TC4) have their furanoid rings in conformations resembling those found in A DNA and RNA helices (the northern range of the pseudorotation wheel).

DFT studies of the formation of furanoid derivatives of ammonium chlorides

B3LYP/6-31+G** level computations were performed on the formation of ammonium salts during the reaction of (S)-1,4-anhydro-5-chloro-2,3,5-trideoxypentitol (1) (2S,5S)-2,5-anhydro-6-chloro-1,3,4,6-tetradeoxyhexitol (2) and methyl 5-chloro-2,3,5-trideoxy-β-D-pentofuranoside (3) with ammonia in order to describe the reaction pathway in detail. All the structures were fully optimized in the gas phase, in chloroform and water. In addition, the gas phase activation barrier heights were estimated at B3LYP/6-311++G**, MPWIK/6-31+G**, MPWIK/6-311++G** and MP2/6-311++G(2d,2p)//MPWIK/6-31+G** levels of theory. All the calculations in solvents were performed the using polarizable continuum model (PCM) and the B3LYP functional with the 6-31+G** basis set. A detailed description of all the stationary points is presented, and the conformational behavior of the five-membered ring is discussed in the gas phase and in the solvents. The conversion of the reactant complexes into ion pairs is accompanied by a strong energy decrease in the gas phase and in all the solvents. The overall process is strongly unfavorable in the gas phase, but takes place readily in high-polarity solvents.

The conformational behavior, geometry and energy parameters of Menshutkin-like reaction of O-isopropylidene-protected glycofuranoid mesylates in view of DFT calculations

The formation of pyridinium salts in the transformation of three O-isopropylidene-protected mesylates of furanoid sugar derivatives under pyridine action is considered at the B3LYP/6-31+G** computation level. All the structures were optimized in the gas phase, in chloroform and water. Activation barrier heights in the gas phase were also estimated at the B3LYP/6-311++G**, MPW1K/6-31+G** and MPW1K/6-311++G** levels. The conducted calculations, both in the gas phase (regardless of the computation level) and in solvents, revealed the barrier height increasing order as follows: 1>2>3 for the three reactions studied. The conformational behavior of the five-membered ring is discussed in the gas phase and in solvents. The fused dioxolane ring makes the furanoid ring less likely to undergo conformational changes. In the case of reaction 3, the furanoid ring shape does not change either in the gas phase or in solvents. All conformers are close to E0 or (0)E.