Violeta Yeguas scite author profile

Peptide-cyclodextrin and protein-cyclodextrin host-guest complexes are becoming more and more important for industrial applications, in particular in the fields of pharmaceutical and food chemistry. They have already deserved many experimental investigations although the effect of complex formation in terms of peptide (or protein) structure is not well-known yet. Theoretical calculations represent a unique tool to analyze such effects, and with this aim we have carried out in the present investigation molecular dynamics simulations and combined quantum mechanics-molecular mechanics calculations. We have studied complexes formed between the model Ace-Phe-Nme peptide and the β-cyclodextrin (β-CD) macromolecule, and our analysis focuses on the following points: (1) how is the peptide structure modified in going from bulk water to CD environment (backbone torsion angles), (2) which are the main peptide-CD interactions, in particular in terms of hydrogen bonds, (3) which relative peptide-CD orientation is preferred and which are the structural and energetic differences between them, and (4) how the electronic properties of the peptide changes under complex formation. Overall, our calculations show that in the most stable configuration, the backbone chain lies in the narrow rim of the CD. Strong hydrogen bonds form between the H atoms of the peptidic NH groups and oxygen atoms of the secondary OH groups in the CD. These and other (weaker) hydrogen bonds formed by the carbonyl groups reduce considerably the flexibility of the peptide structure, compared to bulk water, and produce a marked increase of the local dipole moment by favoring configurations in which the two C═O bonds point toward the same direction. This effect might have important consequences in terms of the peptide secondary structure, although this hypothesis needs to be tested using larger peptide models.

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Taste for Chiral Guests: Investigating the Stereoselective Binding of Peptides to β-Cyclodextrins

Altarsha

Yeguas

Ingrosso

et al. 2013

J. Phys. Chem. B

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Obtaining compounds of diastereomeric purity is extremely important in the field of biological and pharmaceutical industry, where amino acids and peptides are widely employed. In this work, we theoretically investigate the possibility of chiral separation of peptides by β-cyclodextrins (β-CDs), providing a description of the associated interaction mechanisms by means of molecular dynamics (MD) simulations. The formation of host/guest complexes by including a model peptide in the macrocycle cavity is analyzed and discussed. We consider the terminally blocked phenylalanine dipeptide (Ace-Phe-Nme), in the L- and D-configurations, to be involved in the host/guest recognition process. The CD-peptide free energies of binding for the two enantiomers are evaluated through a combined approach that assumes: (1) extracting a set of independent molecular structures from the MD simulation, (2) evaluating the interaction energies for the host/guest complexes by hybrid quantum mechanics/molecular mechanics (QM/MM) calculations carried out on each structure, for which we also compute, (3) the solvation energies through the Poisson-Boltzmann surface area method. We find that chiral discrimination by the CD macrocycle is of the order of 1 kcal/mol, which is comparable to experimental data for similar systems. According to our results, the Ace-(D)Phe-Nme isomer leads to a more stable complex with a β-CD compared to the Ace-(L)Phe-Nme isomer. Nevertheless, we show that the chiral selectivity of β-CDs may strongly depend on the secondary structure of larger peptides. Although the free energy differences are relatively small, the predicted selectivities can be rationalized in terms of host/guest hydrogen bonds and hydration effects. Indeed, the two enantiomers display different interaction modes with the cyclodextrin macrocavity and different mobility within the cavity. This finding suggests a new interpretation for the interactions that play a key role in chiral recognition, which may be exploited to design more efficient and selective chiral separations of peptides.

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The Importance of a Conformational Equilibrium on the Reactivity of Molybdenum and Rhenium Hydroxo−Carbonyl Complexes toward Phenyl Acetate: A Theoretical Investigation

2007

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4 )], respectively, was investigated by using the B3LYP density functional theory methodology in conjunction with the PCM-UAHF model to take into account solvent effects. For both complexes, the most favorable reaction mechanism is concerted and takes place, for the first time in the metal-promoted ester hydrolysis, through the addition of the complex O-H bond to the ester single C-O bond. The larger reactivity of the Mo complex experimentally found is explained in terms of the interaction detected in the rate-determining TS between one of the lone pairs of the oxygen atom bearing the phenyl group and the two π-antibonding C-N of the bidentate ligand. Due to the existence of a conformational equilibrium for the Mo complex, its reaction with phenyl acetate can evolve through a rate-determining TS 2.4 kcal mol -1 lower in relative energy than that found for the Re case, thus explaining the ratio between both periods of experimental reaction time.

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Violeta Yeguas

Peptide Binding to β-Cyclodextrins: Structure, Dynamics, Energetics, and Electronic Effects

Taste for Chiral Guests: Investigating the Stereoselective Binding of Peptides to β-Cyclodextrins

The Importance of a Conformational Equilibrium on the Reactivity of Molybdenum and Rhenium Hydroxo−Carbonyl Complexes toward Phenyl Acetate: A Theoretical Investigation

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