A Competition between Relative Stability and Binding Energy in Caffeine Phenyl-Glucose Aggregates: Implications in Biological Mechanisms.

Hydrogen bonds and stacking interactions are pivotal in biological mechanisms, although their proper characterisation within a molecular complex remains a difficult task. We used quantum mechanical calculations to characterise the complex between caffeine and phenyl-ß-D-glucopyranoside, in which several functional groups of the sugar derivative compete with each other to attract caffeine. Calculations at different levels of theory (M06-2X/6-311++G(d,p) and B3LYP-ED=GD3BJ/def2TZVP) agree to predict several structures similar in stability (relative energy) but with different affinity (binding energy). These computational results were experimentally verified by laser infrared spectroscopy, through which the caffeine·phenyl-ß-D-glucopyranoside complex was identified in an isolated environment, produced under supersonic expansion conditions. The experimental observations correlate with the computational results. Caffeine shows intermolecular interaction preferences that combine both hydrogen bonding and stacking interactions. This dual behaviour had already been observed with phenol, and now with phenyl-ß-D-glucopyranoside, it is confirmed and maximised. In fact, the size of the complex's counterparts affects the maximisation of the intermolecular bond strength because of the conformational adaptability given by the stacking interaction. Comparison with the binding of caffeine within the orthosteric site of the A2A adenosine receptor shows that the more strongly bound caffeine·phenyl-ß-D-glucopyranoside conformer mimics the interactions occurring within the receptor.

Conformational Behavior of d-Lyxose in Gas and Solution Phases by Rotational and NMR Spectroscopies.

Understanding the conformational preferences of carbohydrates is crucial to explain the interactions with their biological targets and to improve their use as therapeutic agents. We present experimental data resolving the conformational landscape of the monosaccharide d-lyxose, for which quantum mechanical (QM) calculations offer model-dependent results. This study compares the structural preferences in the gas phase, determined by rotational spectroscopy, with those in solution, resolved by nuclear magnetic resonance (NMR) and molecular dynamics (MD) simulations. In contrast to QM calculations, d-lyxose adopts only pyranose forms in the gas phase, with the α-anomer exhibiting both the 4C1 and 1C4 chairs (60:40). The predominantly populated ß-anomer shows the 4C1 form exclusively, as determined experimentally by isotopic substitution. In aqueous solution, the pyranose forms are also dominant. However, in contrast to the gas phase, the α-anomer as 1C4 chair is the most populated, and its solvation is more effective than for the ß derivative. Markedly, the main conformers found in the gas phase and solution are characterized by the lack of the stabilizing anomeric effect. From a mechanistic perspective, both rotational spectroscopy and solid-state nuclear magnetic resonance (NMR) corroborate that αâ€¯â†”â€¯ß or furanose ↔ pyranose interconversions are prevented in the gas phase. Combining microwave (MW) and NMR results provides a powerful method for unraveling the water role in the conformational preferences of challenging molecules, such as flexible monosaccharides.

Shapes, Dynamics, and Stability of ß-Ionone and Its Two Mutants Evidenced by High-Resolution Spectroscopy in the Gas Phase.

The conformational landscapes of ß-ionone and two mutants (α-ionone and ß-damascone) have been analyzed by means of state-of-the-art rotational spectroscopy and quantum-chemical calculations. The experiments performed at high resolution and sensitivity have provided a deep insight into their conformational spaces, assigning more than 8000 transitions corresponding to the rotational structures of 54 different species (3 isomers, 14 conformers, and 40 isotopologues). Methyl internal rotation dynamics were also observed and analyzed. The work proved the great flexibility of ß-ionone due to its flatter potential energy surface. This feature confers on ß-ionone a wider ability to interconvert between conformers with rather similar energies with respect to its mutants, allowing the retinal ligand to better adapt inside the binding pocket.