Characterization of Asx Turn Types and Their Connate Relationship with β-Turns.

Invited for the cover of this issue are David J. Aitken, Michel Mons, and co-workers at Université Paris-Saclay. The image depicts the investigation strategies used to document the intrinsic structures of an important secondary structure in proteins, the so-called Asx turn.

Characterization of Asx Turn Types and Their Connate Relationship with β-Turns.

Models of asparagine-containing dipeptides specifically designed to favor intrinsic folding into an Asx turn were characterized both theoretically, by using quantum chemistry, and experimentally, by using laser spectroscopy in the gas phase. Both approaches provided evidence for the spontaneous folding of both the Asn-Ala and Asn-Gly dipeptide models into the most stable Asx turn, a conformation stabilized by a C10 H-bond that was very similar to a type II' β-turn. In parallel, analysis of Asx turns implicating asparagine in crystallized protein structures in the Protein Data Bank revealed a sequence-dependent behavior.

N-H⋯X interactions stabilize intra-residue C5 hydrogen bonded conformations in heterocyclic α-amino acid derivatives.

Nature makes extensive and elaborate use of hydrogen bonding to assemble and stabilize biomolecular structures. The shapes of peptides and proteins rely significantly on N-H⋯O[double bond, length as m-dash]C interactions, which are the linchpins of turns, sheets and helices. The C5 H-bond, in which a single residue provides both donor and acceptor, is generally considered too weak to force the backbone to adopt extended structures.

Characterization and Photofragmentation Studies of the Benzimidazole Homodimer: Evidence for Excited-State Charge-Coupled Proton Transfer.

The spectroscopic characterization of the benzimidazole (BIM) homodimer was carried out in a molecular beam in the ground state as well as in the cationic state using the R2PI and RIDIR methods. Primarily, interest in the dimer was due to the observation of a proton-transferred BIM fragment at energies well below its thermodynamic threshold (i.e.

Exploration of the theobromine-water dimer: comparison with DNA microhydration.

Understanding the molecular basis of the appearance of life on Earth is an exciting research field. Many factors may have influenced the election of the molecules used by living beings and evolution may have modified those original compounds. In an attempt to understand the role played by intermolecular interactions in the election of CGAT as the alphabet of life, we present here a thorough experimental and computational study on the interaction of theobromine with water.

Revisiting the spectroscopy of xanthine derivatives: theobromine and theophylline.

We explore the influence of the relative position of the methyl substituent on the photophysics of theophylline and theobromine, two molecules that are structurally related to the DNA bases. Using a combination of spectroscopic techniques and quantum mechanical calculations, we show that moving the methyl group from N1 in theophylline to N7 in theobromine causes significant differences in their excited state properties, i.e.