Computational Investigation of Conformational Properties of Short Azapeptides: Insights from DFT Study and NBO Analysis

Computational Investigation of Conformational Properties of Short Azapeptides: Insights from DFT Study and NBO Analysis

Azapeptides have gained much attention due to their ability to enhance the stability and bioavailability of peptide drugs. Their structural preferences, essential to understanding their function and potential application in the peptide drug design, remain largely unknown. In this work, we systematic...

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Bibliographic Details
Published in:Molecules (Basel, Switzerland) Switzerland), 2023-07, Vol.28 (14), p.5454
Main Authors: El Khabchi, Mouna, Mcharfi, Mohammed, Benzakour, Mohammed, Fitri, Asmae, Benjelloun, Adil Touimi, Song, Jong-Won, Lee, Kang-Bong, Lee, Ho-Jin
Format: Article
Language:eng
Subjects:
Acids
Amides
Analysis
Asx turn
azapeptides
cis-trans amide bond
conformational preferences
Energy
hydrogen bonds
Investigations
Ions
Isomerization
Peptides
Peptides - chemistry
Protein Conformation
Water - chemistry
β-turn
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Summary:Azapeptides have gained much attention due to their ability to enhance the stability and bioavailability of peptide drugs. Their structural preferences, essential to understanding their function and potential application in the peptide drug design, remain largely unknown. In this work, we systematically investigated the conformational preferences of three azaamino acid residues in tripeptide models, Ac-azaXaa-Pro-NHMe [Xaa = Asn ( ), Asp ( ), Ala ( )], using the popular DFT functionals, B3LYP and B3LYP-D3. A solvation model density (SMD) was used to mimic the solvation effect on the conformational behaviors of azapeptides in water. During the calculation, we considered the impact of the amide bond in the azapeptide models on the conformational preferences of models - . We analyzed the effect of the HB between the side-chain main chain and main-chain main-chain on the conformational behaviors of azapeptides - . We found that the predicted lowest energy conformation for the three models differs depending on the calculation methods. In the gas phase, B3LYP functional indicates that the conformers and of azapeptides and correspond to the type I of β-turn, the lowest energy conformation with all- amide bonds. Considering the dispersion correction, B3LYP-D3 functional predicts the conformers and of azapeptide and , which contain the amide bond preceding the Pro residue, as the lowest energy conformation in the gas phase. The results imply that azaAsx and Pro residues may involve - isomerization in the gas phase. In water, the predicted lowest energy conformer of azapeptides and differs from the gas phase results and depends on the calculational method. For azapeptide , regardless of calculation methods and phases, (β-I turn) is predicted as the lowest energy conformer. The results imply that the effect of the side chain that can form HBs on the conformational preferences of azapeptides and may not be negligible. We compared the theoretical results of azaXaa-Pro models with those of Pro-azaXaa models, showing that incorporating azaamino acid residue in peptides at different positions can significantly impact the folding patterns and stability of azapeptides.
ISSN:1420-3049
1420-3049