Fragment Quantum Mechanical Calculation of Proteins and Its Applications

He, Xiao; Zhu, Tong; Wang, Xianwei; Liu, Jinfeng; Zhang, John Z. H.

doi:10.1021/ar500077t

Cited by 192 publications

(217 citation statements)

References 69 publications

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“…44,45 Furthermore, the DNP basis set was able to predict the binding energies calculated using a triple-zeta set within near chemical accuracy. 49 Recently, Vicatos et al 50 investigated the absolute folding free energies in a diverse set of 45 proteins, nding that the best tted value of the dielectric constant 3 for chargecharge interactions and for self-energies is about 40, a value adopted in our simulations. 46,47 Here we applied the COSMO continuum solvation model, together with the linearscaling quantum mechanical MFCC theory to calculate the electrostatic solvation energy of HSA, which is already proven to be an efficient method to study proteins in solution.…”

Section: Methodsmentioning

confidence: 99%

Quantum molecular modelling of ibuprofen bound to human serum albumin

et al. 2015

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The binding of the nonsteroidal anti-inflammatory drug ibuprofen (IBU) to human serum albumin (HSA) is investigated using density functional theory (DFT) calculations within a fragmentation strategy.Crystallographic data for the IBU-HSA supramolecular complex shows that the ligand is confined to a large cavity at the subdomain IIIA and at the interface between the subdomains IIA and IIB, whose binding sites are FA3/FA4 and FA6, respectively. The interaction energy between the IBU molecule and each amino acid residue of these HSA binding pockets was calculated using the Molecular Fractionation with Conjugate Caps (MFCC) approach employing a dispersion corrected exchange-correlation functional. Our investigation shows that the total interaction energy of IBU bound to HSA at binding sites of the fatty acids FA3/FA4 (FA6) converges only for a pocket radius of at least 8.5Å, mainly due to the action of residues Arg410, Lys414 and Ser489 (Lys351, Ser480 and Leu481) and residues in nonhydrophobic domains, namely Ile388, Phe395, Phe403, Leu407, Leu430, Val433, and Leu453 (Phe206, Ala210, Ala213, and Leu327), which is unusual. Our simulations are valuable for a better understanding of the binding mechanism of IBU to albumin and can lead to the rational design and the development of novel IBU-derived drugs with improved potency.

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Section: Methodsmentioning

confidence: 99%

Quantum molecular modelling of ibuprofen bound to human serum albumin

et al. 2015

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“…42,51,[61][62][63] We prepare the parameters for individual fragments using the following procedure. First, we saturate the dangling bonds of each fragment using a capping group, to obtain well-behaved closed-shell structures.…”

Section: Breaking Macromolecules Into Fragmentsmentioning

confidence: 99%

Extension of the Effective Fragment Potential Method to Macromolecules

et al. 2016

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The effective fragment potential (EFP) approach, which can be described as a nonempirical polarizable force field, affords an accurate first-principles treatment of noncovalent interactions in extended systems. EFP can also describe the effect of the environment on the electronic properties (e.g., electronic excitation energies and ionization and electron-attachment energies) of a subsystem via the QM/EFP (quantum mechanics/EFP) polarizable embedding scheme. The original formulation of the method assumes that the system can be separated, without breaking covalent bonds, into closed-shell fragments, such as solvent and solute molecules. Here, we present an extension of the EFP method to macromolecules (mEFP). Several schemes for breaking a large molecule into small fragments described by EFP are presented and benchmarked. We focus on the electronic properties of molecules embedded into a protein environment and consider ionization, electron-attachment, and excitation energies (single-point calculations only). The model systems include chromophores of green and red fluorescent proteins surrounded by several nearby amino acid residues and phenolate bound to the T4 lysozyme. All mEFP schemes show robust performance and accurately reproduce the reference full QM calculations. For further applications of mEFP, we recommend either the scheme in which the peptide is cut along the Cα-C bond, giving rise to one fragment per amino acid, or the scheme with two cuts per amino acid, along the Cα-C and Cα-N bonds. While using these fragmentation schemes, the errors in solvatochromic shifts in electronic energy differences (excitation, ionization, electron detachment, or electron-attachment) do not exceed 0.1 eV. The largest error of QM/mEFP against QM/EFP (no fragmentation of the EFP part) is 0.06 eV (in most cases, the errors are 0.01-0.02 eV). The errors in the QM/molecular mechanics calculations with standard point charges can be as large as 0.3 eV.

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“…9, 23–26 DFT calculations are accurate enough to yield good agreements between chemical shift and molecular structure for medium-sized molecules, 27–28 and have also been explored for protein structure validation and refinement. 23, 29 While this approach has been rarely used for proteins in the past, given the associated computational demands, it currently is starting to gain momentum due to the rapidly increasing availability of sufficiently powerful computational resources and robust software.…”

Section: Introductionmentioning

confidence: 99%

Toward Closing the Gap: Quantum Mechanical Calculations and Experimentally Measured Chemical Shifts of a Microcrystalline Lectin

et al. 2016

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NMR chemical shifts are exquisitely sensitive probes for conformation and dynamics in molecules and supramolecular assemblies. While isotropic chemical shifts are easily measured with high accuracy and precision in conventional NMR experiments, they remain challenging to calculate quantum mechanically, particularly in inherently dynamic biological systems. Using a model benchmark protein, the 133-residue agglutinin from Oscillatoria agardhii (OAA), which has been extensively characterized by us previously, we have explored the integration of X-ray crystallography, solution NMR, MAS NMR, and quantum mechanics/molecular mechanics (QM/MM) calculations for analysis of 13Cα and 15N isotropic chemical shifts. The influence of local interactions, quaternary contacts, and dynamics on the accuracy of calculated chemical shifts is analyzed. Our approach is broadly applicable and expected to be beneficial in chemical shift analysis and chemical-shift-based structure refinement for proteins and protein assemblies.

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Fragment Quantum Mechanical Calculation of Proteins and Its Applications

Cited by 192 publications

References 69 publications

Quantum molecular modelling of ibuprofen bound to human serum albumin

Quantum molecular modelling of ibuprofen bound to human serum albumin

Extension of the Effective Fragment Potential Method to Macromolecules

Toward Closing the Gap: Quantum Mechanical Calculations and Experimentally Measured Chemical Shifts of a Microcrystalline Lectin

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