Understanding the Role of Stereoelectronic Effects in Determining Collagen Stability. 2. A Quantum Mechanical/Molecular Mechanical Study of (Proline-Proline-Glycine)<i><sub>n</sub></i> Polypeptides

Improta, Roberto; Mele, Franca; Crescenzi, Orlando; Benzi, Caterina; Barone, Vincenzo

doi:10.1021/ja020187p

Cited by 67 publications

(63 citation statements)

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“…Vitagliano et al (27) predicted steric hindrance by modeling, if the proline in the Xaa position of -(Pro-Pro-Gly) n -triple helix is replaced by 4(S)Hyp. Quantum mechanical studies also come to this conclusion (25). However, this steric hindrance might be minimized by peptides with 4(S)Flp, which is smaller than 4(S)Hyp (17).…”

Section: Ac-(gly-4(r)hyp-4(r)hyp) 10 -Nh 2 Forms a Stable Collagen Trmentioning

confidence: 92%

“…Raines and his colleagues (1,24) pointed out the importance of the inductive and stereoelectronic effects of the hydroxyl group of 4(R)Hyp. The importance of the pyrrolidine ring puckering of imino acids was shown with quantum and molecular mechanical analysis (25,26) and was supported by the "propensity-based" stabilization of proline in the Xaa position and 4(R)Hyp in the Yaa position and the destabilization of 4(R)Hyp in the Xaa position (27,28).…”

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confidence: 94%

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Hydroxylation-induced Stabilization of the Collagen Triple Helix

Mizuno

Hayashi

Peyton

et al. 2004

Journal of Biological Chemistry

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The collagen triple helix is one of the most abundant protein motifs in animals. The structural motif of collagen is the triple helix formed by the repeated sequence of -Gly-Xaa-Yaa-. Previous reports showed that H-(Pro-4(R)Hyp-Gly) 10 -OH (where '4(R)Hyp' is (2S,4R)-4-hydroxyproline) forms a trimeric structure, whereas H-(4(R)Hyp-Pro-Gly) 10 -OH does not form a triple helix. Compared with H-(Pro-Pro-Gly) 10 -OH, the melting temperature of H-(Pro-4(R)Hyp-Gly) 10 -OH is higher, suggesting that 4(R)Hyp in the Yaa position has a stabilizing effect. The inability of triple helix formation of H-(4(R)Hyp-Pro-Gly) 10 -OH has been explained by a stereoelectronic effect, but the details are unknown. In this study, we synthesized a peptide that contains 4(R)Hyp in both the Xaa and the Yaa positions, that is, Ac-(Gly-4(R)Hyp-4(R)Hyp) 10 -NH 2 and compared it to Ac-(GlyPro-4(R)Hyp) 10 -NH 2 , and Ac-(Gly-4(R)Hyp-Pro) 10 -NH 2 . Ac-(Gly-4(R)Hyp-4(R)Hyp) 10 -NH 2 showed a polyproline II-like circular dichroic spectrum in water. The thermal transition temperatures measured by circular dichroism and differential scanning calorimetry were slightly higher than the values measured for Ac-(Gly-Pro-4(R)Hyp) 10 -NH 2 under the same conditions. For Ac-(Gly-4(R)Hyp-4(R)Hyp) 10 -NH 2 , the calorimetric and the van't Hoff transition enthalpy ⌬H were significantly smaller than that of Ac-(Gly-Pro-4(R)Hyp) 10 -NH 2 . We postulate that the denatured states of the two peptides are significantly different, with Ac-(Gly-4(R)Hyp-4(R)Hyp) 10 -NH 2 forming a more polyproline II-like structure instead of a random coil. Two-dimensional nuclear Overhauser effect spectroscopy suggests that the triple helical structure of Ac-(Gly-4(R)Hyp-4(R)Hyp) 10 -NH 2 is more flexible than that of Ac-(Gly-Pro-4(R)Hyp) 10 -NH 2 . This is confirmed by the kinetics of amide 1 H exchange with solvent deuterium of Ac-(Gly-4(R)Hyp-4(R)Hyp) 10 -NH 2 , which is faster than that of Ac-(Gly-Pro-4(R)Hyp) 10 -NH 2 . The higher transition temperature of Ac-(Gly-4(R)Hyp-4(R)Hyp) 10 -NH 2 , can be explained by the higher trans/cis ratio of the Gly-4(R)Hyp peptide bonds than that of the Gly-Pro bonds, and this ratio compensates for the weaker interchain hydrogen bonds.The collagen triple helix is one of the most abundant protein motifs in animals. Each of the three polypeptide chains forms a polyproline-II like structure, and these structures twist around each other to form a right-handed superhelix (1, 2). To form this structure, a sequence with Gly in every third position is required. The general sequence is -Gly-Xaa-Yaa-, and the Xaa and Yaa positions contain a high content of proline and hydroxyproline. Twenty-seven types of collagens and more than fifteen proteins that form a triple helix, but are not named collagens such as collectins, ficolins, and scavenger receptors (3-5), occur in humans. In vertebrates, most of the proline residues in the Yaa position of the -Gly-Xaa-Yaa-repeated sequence are post-translationally modified to 4(R)Hyp 1 by prolyl 4-hydroxylase (EC 1.14.1...

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Section: Ac-(gly-4(r)hyp-4(r)hyp) 10 -Nh 2 Forms a Stable Collagen Trmentioning

confidence: 92%

mentioning

confidence: 94%

Hydroxylation-induced Stabilization of the Collagen Triple Helix

Mizuno

Hayashi

Peyton

et al. 2004

Journal of Biological Chemistry

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“…In addition, quantum mechanical ab initio calculations have elucidated the specific roles of stereoelectronic effects, ring pucker, cis/trans stabilization, and / dihedral angles in Pro and 4(R)Hyp residues and the effect of these parameters in the stability of the collagen triple helix (17)(18)(19)(20). These studies * This work was supported by a grant from Shriners Hospital for Children and, in part, by a Burroughs Wellcome Career Development Award 992863 (to M. A. S.).…”

Section: -Oh and H-(4(r)hyp-4(r)hyp-gly)mentioning

confidence: 99%

The Crystal Structure of a Collagen-like Polypeptide with 3(S)-Hydroxyproline Residues in the Xaa Position Forms a Standard 7/2 Collagen Triple Helix

Schumacher

Mizuno

Bächinger

2006

Journal of Biological Chemistry

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“…Current computational efforts on collagen molecules focus mostly on their structures and mechanical properties under various assumptions and approximations [22][23][24][25][26][27][28][29][30][31][32][33][34][35][36][37][38][39], and less on the electronic structure at the level of amino acids. Nevertheless, a classical description in biomolecular simulations has contributed tremendously in this area because they can be applied to much larger systems [36][37][38][39][40].…”

Section: Introductionmentioning

confidence: 99%

Computational Study of a Heterostructural Model of Type I Collagen and Implementation of an Amino Acid Potential Method Applicable to Large Proteins

et al. 2014

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Collagen molecules are the primary structural proteins of many biological systems. Much progress has been made in the study of the structure and function of collagen, but fundamental understanding of its electronic structures at the atomic level is still lacking. We present the results of electronic structure and bonding calculations of a specific model of type I collagen using the density functional theory-based method. Information on density of states (DOS), partial DOS, effective charges, bond order values, and intra-and inter-molecular H-bonding are obtained and discussed. We further devised an amino-acid-based potential method (AAPM) to circumvent the full self-consistent field (SCF) calculation that can be applied to large proteins. The AAPM is validated by comparing the results with the full SCF calculation of the whole type I collagen model with three strands. The calculated effective charges on each atom in the model retained at least 95% accuracy. This technique provides a viable and efficient way to study the electronic structure of large complex biomaterials at the ab initio level.

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Understanding the Role of Stereoelectronic Effects in Determining Collagen Stability. 2. A Quantum Mechanical/Molecular Mechanical Study of (Proline-Proline-Glycine)_n Polypeptides

Cited by 67 publications

References 50 publications

Hydroxylation-induced Stabilization of the Collagen Triple Helix

Hydroxylation-induced Stabilization of the Collagen Triple Helix

The Crystal Structure of a Collagen-like Polypeptide with 3(S)-Hydroxyproline Residues in the Xaa Position Forms a Standard 7/2 Collagen Triple Helix

Computational Study of a Heterostructural Model of Type I Collagen and Implementation of an Amino Acid Potential Method Applicable to Large Proteins

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Understanding the Role of Stereoelectronic Effects in Determining Collagen Stability. 2. A Quantum Mechanical/Molecular Mechanical Study of (Proline-Proline-Glycine)n Polypeptides

Cited by 67 publications

References 50 publications

Hydroxylation-induced Stabilization of the Collagen Triple Helix

Hydroxylation-induced Stabilization of the Collagen Triple Helix

The Crystal Structure of a Collagen-like Polypeptide with 3(S)-Hydroxyproline Residues in the Xaa Position Forms a Standard 7/2 Collagen Triple Helix

Computational Study of a Heterostructural Model of Type I Collagen and Implementation of an Amino Acid Potential Method Applicable to Large Proteins

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Understanding the Role of Stereoelectronic Effects in Determining Collagen Stability. 2. A Quantum Mechanical/Molecular Mechanical Study of (Proline-Proline-Glycine)_n Polypeptides