Folding of a Helix at Room Temperature Is Critically Aided by Electrostatic Polarization of Intraprotein Hydrogen Bonds

Duan, Li L.; Ye, Mei; Zhang, Dawei; Zhang, Qing G.; Zhang, John Z. H.

doi:10.1021/ja102735g

Cited by 89 publications

(113 citation statements)

References 58 publications

Supporting

Mentioning

107

Contrasting

Order By: Relevance

“…And this charge fitting scheme is termed the AHBC scheme. 35 The AHBC has been successfully applied to folding simulation of a short peptide, and we showed that electrostatic polarization along the hydrogen bond can accelerate the formation of α-helix and increased the population of native structure during equilibrium. The detailed simulation condition can be found in the supplementary material.…”

mentioning

confidence: 94%

Communication: The electrostatic polarization is essential to differentiate the helical propensity in polyalanine mutants

Wei

Tung

Yip

et al. 2011

The Journal of Chemical Physics

Self Cite

View full text Add to dashboard Cite

The folding processes of three polyalanine peptides with composition of Ac-(AAXAA)2-GY-NH2 (where X is chosen to be Q, K, and D) are studied by molecular dynamics simulation in solvent of 40% trifluoroethanol using both polarized and unpolarized force fields. The simulations reveal the critical role of polarization effect for quantitative description of helix formation. When polarized force field is used, peptides with distinctive helical propensity are correctly differentiated and the calculated helical contents are in close agreement with experimental measurement, indicating that consideration of polarization effect can correctly predict the effect of sequence variation on helix formation.

show abstract

mentioning

confidence: 94%

Communication: The electrostatic polarization is essential to differentiate the helical propensity in polyalanine mutants

Wei

Tung

Yip

et al. 2011

The Journal of Chemical Physics

Self Cite

View full text Add to dashboard Cite

show abstract

“…Under some conditions, such as high temperature, extremes of pH or mechanical forces, protein will unfold into random coil that loses biochemical function (Selkoe 2003). Since folding and unfolding are essential to life, literatures on the study of these processes are very rich (Gao and Truhlar 2002;Gao et al 2006;Freddolino et al 2010;Yang et al 2010;Alhambra et al 2000;Duan et al 2010;Shank et al 2010). And it has been greatly advanced in recent years by the development of fast time-resolved techniques.…”

Section: Introductionmentioning

confidence: 99%

Molecular dynamics simulation exploration of unfolding and refolding of a ten-amino acid miniprotein

Zhao

Cheng

2011

Amino Acids

View full text Add to dashboard Cite

Steered molecular dynamics simulations are performed to explore the unfolding and refolding processes of CLN025, a 10-residue beta-hairpin. In unfolding process, when CLN025 is pulled along the termini, the forceextension curve goes back and forth between negative and positive values not long after the beginning of simulation. That is so different from what happens in other peptides, where force is positive most of the time. The abnormal phenomenon indicates that electrostatic interaction between the charged termini plays an important role in the stability of the beta-hairpin. In the refolding process, the collapse to beta-hairpin-like conformations is very fast, within only 3.6 ns, which is driven by hydrophobic interactions at the termini, as the hydrophobic cluster involves aromatic rings of Tyr1, Tyr2, Trp9, and Tyr10. Our simulations improve the understanding on the structure and function of this type of miniprotein and will be helpful to further investigate the unfolding and refolding of more complex proteins.

show abstract

“…Polarized atomic charges are obtained by periodic restrained fitting to electrostatic potential calculated at quantum mechanical level in continuum solvent [25]. As in our previous work [25], charge update is based on the main chain hydrogen bond variation to save the computational expense. In this regard, this charge scheme is termed AHBC.…”

Section: Adaptive Hydrogen Bond-specific Chargementioning

confidence: 99%

“…Among various linear scaling quantum mechanical methods, the molecular fractionation with conjugate caps (MFCC) proposed in Zhang's group has been proved to be quite efficient for the electronic structure calculation for protein [15][16][17]. Recently, based on the MFCC method, a new charge scheme for protein termed the adaptive hydrogen bond-specific charge (AHBC) has been developed [25,26]. AHBC is obtained by periodic restrained fitting to the electrostatic potential (RESP) calculated usually at density functional theory (DFT) level in continuum solvent.…”

Section: Introductionmentioning

confidence: 99%

“…Thus AHBC is consistent with the AMBER force fields, and it can cooperate well with other AMBER force field parameters, like bond, angle and dihedral terms. Its applicability and advantage over traditional AMBER force field have been shown in several studies, including pK a prediction [26], structural stability [27,28], NMR coupling [29,30], protein/ligand binding [31] and peptide folding [25].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Folding of EK peptide and its dependence on salt concentration and pH: A computational study

Zhang

Duan

et al. 2011

Sci. China Chem.

Self Cite

View full text Add to dashboard Cite

In this study, we apply both pairwise AMBER03 force field and the recently developed polarized force field to study the folding process of EK peptide under various ion strength and pH conditions. The polarized force field is based on our newly proposed adaptive hydrogen bond-specific charge (AHBC) scheme. These two force fields differ only by the atomic charges. Solvent effect is described with generalized Born models (IGB5 in AMBER 10 package). The result shows that although when applying AMBER03 charge, the helical structure is preferred, its dependence on salt concentration and pH is qualitatively wrong. While using AHBC the peptide finds its native structure within 10 ns, and then fluctuates around this folded state. Under high salt concentration or extreme pH conditions the calculated helical structure probability drops, which is in qualitative agreement with the experiment. Analysis of the atomic charges and the interaction between the donor-acceptor pair in main hydrogen bonds shows that the helical structure is stabilized when polarization effect is counted. It again shows that polarization effect is a very important improvement over traditional force field and is essential for protein folding. We also prove that the salt bridge interaction between 4-residue apart GLU and LYS residues is not critical to the stability of helical structure of EK peptide, but is merely an auxiliary factor, also in agreement with the experiment.

show abstract

Folding of a Helix at Room Temperature Is Critically Aided by Electrostatic Polarization of Intraprotein Hydrogen Bonds

Cited by 89 publications

References 58 publications

Communication: The electrostatic polarization is essential to differentiate the helical propensity in polyalanine mutants

Communication: The electrostatic polarization is essential to differentiate the helical propensity in polyalanine mutants

Molecular dynamics simulation exploration of unfolding and refolding of a ten-amino acid miniprotein

Folding of EK peptide and its dependence on salt concentration and pH: A computational study

Contact Info

Product

Resources

About