Structure and IR Spectrum of Phenylalanyl–Glycyl–Glycine Tripetide in the Gas‐Phase: IR/UV Experiments, Ab Initio Quantum Chemical Calculations, and Molecular Dynamic Simulations

Rooney, David; Valdés, Haydee; Vondrášek, Jiřı́; Hobza, Pavel; Abu-Riziq, Ali; Crews, Bridgit; Vries, Mattanjah S. de

doi:10.1002/chem.200500465

Cited by 172 publications

(151 citation statements)

References 51 publications

(57 reference statements)

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“…However, due to their computational cost, their applicability has been restricted to smaller systems such as amino acids, and di-and tripeptides. 5,6 Tetrapeptides are the smallest model systems that are able to mimic the typical hydrogen-bond pattern in a-helices. They are therefore of particular biological interest, and QM treatments of them have been reported since the late 1990s.…”

mentioning

confidence: 99%

Accurate quantum chemical energies for tetrapeptide conformations: why MP2 data with an insufficient basis set should be handled with caution

Goerigk

Karton

Martin

et al. 2013

Phys. Chem. Chem. Phys.

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Understanding the structure-function relationship in polypeptides and proteins is a crucial step in the elucidation of biochemical processes. In this regard, constantly improving hardware architectures and program codes have allowed the in silico treatment of proteins to become an important partner in related investigations. Due to the immense size of proteins, their computational study has generally been carried out with molecular mechanics (MM) force-field methods, such as CHARMM or GROMOS. 1 At the other extreme, high-level quantum mechanical (QM) methods, such as coupled-cluster with perturbative triples 2 [CCSD(T)] or composite methods like Gn 3 or Wn, 4 provide results with much higher accuracy. However, due to their computational cost, their applicability has been restricted to smaller systems such as amino acids, and di-and tripeptides. 5,6 Tetrapeptides are the smallest model systems that are able to mimic the typical hydrogen-bond pattern in a-helices. They are therefore of particular biological interest, and QM treatments of them have been reported since the late 1990s. 7 The highest levels of theory used in such studies were often conventional or local second-order Møller-Plesset perturbation theory (MP2) with a triple-z basis set. These levels are still popular in recent similar investigations. 8 Of particular relevance to the present work is the extensive study of 100 tetrapeptides by Jiang et al., 9 who evaluated the performance of a large number of QM and MM methods based on MP2/cc-pVTZ reference values.In the present article, we will demonstrate where potential problems of the MP2 approach combined with finite basis sets might lie when applied to conformers of polypeptides. For this purpose, we selected two systems from the study by Jiang et al. 9 that have the sequence ACE-ALA-X-ALA-NME. ALA is alanine, X is either glycine (GLY) or serine (SER), and ACE and NME stand for acetyl and methylamide groups, respectively (see Fig. 1a). For each peptide, five conformers have been examined, whose backbone dihedral angles (see ESI †) have been fixed such that they resemble those typically found in parallel (b) and antiparallel (b a ) b-sheets, in right-handed (a R ) and left-handed (a L ) a-helices, and in the common polyproline-II (PP-II) helix. We note that while the two a-helical conformers are stabilised by hydrogen bonds, the backbones of the other three conformers are not (see for example Fig. 1).

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mentioning

confidence: 99%

Accurate quantum chemical energies for tetrapeptide conformations: why MP2 data with an insufficient basis set should be handled with caution

Goerigk

Karton

Martin

et al. 2013

Phys. Chem. Chem. Phys.

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“…We have also covered the phenomena of halogen bonding 3 . Aside from noncovalent complexes, we have studied conformers of small peptides [4][5][6] at the same level of theory. This list is not final; we are working on more systematic high-level studies.…”

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confidence: 99%

Quantum Chemical Benchmark Energy and Geometry Database for Molecular Clusters and Complex Molecular Systems (www.begdb.com): A Users Manual and Examples

Řezáč

Jurečka

Riley

et al. 2008

Collect. Czech. Chem. Commun.

156

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The coupled cluster method covering single and double electron excitations iteratively and triple electron excitations non-iteratively (CCSD(T)) provides highly accurate energies, geometries and various properties for molecular clusters and complex molecular systems. In our laboratory, we consistently use the CCSD(T) method extrapolated to complete basis set limit (CBS) and during the past several years we have collected data for several hundreds of molecular complexes and complex molecular systems (mostly peptides). These calculations are, however, time consuming and for systems with more than about 50 atoms are still impractical. This is due to the fact that the method scales as N 7 where N is the number of basis functions. To attain similar accuracy for extended systems requires the use of new techniques,

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“…Also, B3LYP/6-31+G(d) and MP2/6-31+G(d) calculations predicted markedly different structures for the tyrosilglycine (YG) dipeptide [21]. The same conformational behaviour discrepancy between these two methods was observed for a number of other molecules containing an aromatic ring in addition to a flexible side chain, WG [17][18][19] and WGG [18,19]. Further investigation suggested that the very different structures obtained by B3LYP and MP2 are likely caused by dispersion (a true physical effect, underestimated by B3LYP) as well as large basis set superposition errors (BSSE, an artificial attraction) in the MP2 calculations [22].…”

Section: Introductionmentioning

confidence: 90%

“…One of the most important reasons for this inaccuracy might be the fact that they work with effective average charges (over all existing structures), which may be far from the charges that properly describe each individual structure. It has recently been proven that the scan of the PES of FGG [17] and GFA [46] by using the AMBER empirical force field fails mainly due to a large variety of atomic charges for individual conformers. These calculations have demonstrated that introducing an average charge brings some uncertainty that results in incorrect structural predictions when an empirical potential is used.…”

Section: Conformational Study Of Ygg In Solutionmentioning

confidence: 99%

“…There are four aromatic amino acids found in proteins, namely, phenylalanine (F), tyrosine (Y), tryptophan (W), and histidine (H). The structure of these amino acids and of some aromatic small peptides such as phenylalanylglycyl-glycine (FGG), tryptophyl-glycine (WG) and tryptophyl-glycyl-glycine (WGG), have already been reported by means of molecular dynamic simulations combined with high-level correlated ab initio quantum chemical calculations [17][18][19]. The structure of the tyrosyl-glycyl-glycine (YGG) peptide has recently been investigated using a combination of different strategies that employ a hierarchy of electronic structure theory [20].…”

Section: Introductionmentioning

confidence: 99%

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Structure of isolated tyrosyl-glycyl-glycine tripeptide. A comparative conformational study with peptides containing an aromatic ring

et al. 2010

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The potential energy surface (PES) of tyrosyl-glycyl-glycine (YGG) tripeptide in solution was explored using EDMC (Electrostatically Driven Monte Carlo) and in the gas-phase by means of ab initio quantum chemical calculations. The theoretical computational analysis revealed that this tripeptide possesses a significant molecular flexibility. A C 7 backbone conformation was the most energetically preferred for the central Gly residue, using both methodologies. Some new stable conformers that have not been previously reported were identified in the gas phase as well. This study points out the interplay of backbone and side-chain contributions in determining the relative stabilities of energy minima. In addition, the peptide backbone of YGG was compared with other small peptides containing aromatic side-chains (Phe-Gly-Gly and Trp-Gly-Gly). The comparison with experimental X-ray results was also satisfactory.

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Structure and IR Spectrum of Phenylalanyl–Glycyl–Glycine Tripetide in the Gas‐Phase: IR/UV Experiments, Ab Initio Quantum Chemical Calculations, and Molecular Dynamic Simulations

Cited by 172 publications

References 51 publications

Accurate quantum chemical energies for tetrapeptide conformations: why MP2 data with an insufficient basis set should be handled with caution

Accurate quantum chemical energies for tetrapeptide conformations: why MP2 data with an insufficient basis set should be handled with caution

Quantum Chemical Benchmark Energy and Geometry Database for Molecular Clusters and Complex Molecular Systems (www.begdb.com): A Users Manual and Examples

Structure of isolated tyrosyl-glycyl-glycine tripeptide. A comparative conformational study with peptides containing an aromatic ring

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