Molecular modeling for Cu(II)‐aminopolycarboxylate complexes: Structures, conformational energies, and ligand binding affinities

Ćendić, Marina; Matović, Zoran D.; Deeth, Robert J.

doi:10.1002/jcc.23437

Cited by 8 publications

(2 citation statements)

References 57 publications

(105 reference statements)

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“…Ligand field molecular mechanics (LFMM) was introduced by Deeth and co-workers, including explicit d-electron energy terms for transition metals to the standard MM expression 38,39 . This has previously been used to study small 40,41 and large metal-biomolecular systems such as metalloproteins 42,43 , including a range of transition metals such as Cu and Pt [44][45][46][47][48][49] . Recently, our group showed that LFMM is suitable for predicting geometries and exploring the conformational space of transition-metals such as Cu(II) and Pt(II) when bound to amyloid-β peptide, although we found this method fails to reproduce DFT energy 44 .…”

Section: Figure 1: Ghk Structurementioning

confidence: 99%

Theoretical study of copper binding to GHK peptide

Alshammari

Platts

2020

Computational Biology and Chemistry

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We report ligand field molecular mechanics, density functional theory and semi-empirical studies on the binding of Cu(II) to GlyHisLys (GHK) peptide. Following exhaustive conformational searching using molecular mechanics, we show that relative energy and geometry of conformations are in good agreement between GFN2-xTB semi-empirical and B3LYP-D DFT levels. Conventional molecular dynamics simulation of Cu-GHK shows the stability of the copper-peptide binding over 100ps trajectory. Four equatorial bonds in 3N1O coordination remain stable throughout simulation, while a fifth in apical position from Cterminal carboxylate is more fluxional. We also show that the automated conformer and rotamer search algorithm CREST is able to correctly predict the metal binding position from a starting point consisting of separated peptide, copper and water.

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Section: Figure 1: Ghk Structurementioning

confidence: 99%

Theoretical study of copper binding to GHK peptide

Alshammari

Platts

2020

Computational Biology and Chemistry

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“…In our work deriving accurate FFs targeted at specific transition-metal/ligand combinations, we have used both experimental and/or quantum chemical data [ 27 – 35 ]. Here, we focus on a particular class of flexible MOFs which incorporate the four-bladed zinc paddlewheel (ZPW) motif and construct a new, specialized valence FF, ZPW-FF, based on molecular ZPW complexes which then automatically captures the types of structural change displayed by [Zn 2 (bdc) 2 (dabco)] n as a function of adsorbate.…”

Section: Introductionmentioning

confidence: 99%

Molecular modeling of zinc paddlewheel molecular complexes and the pores of a flexible metal organic framework

Alzahrani

Deeth

2016

J Mol Model

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A new all-atom first-principles force field (FF) is constructed for the bimetallic, four-bladed zinc paddlewheel (ZPW) motif. Zinc-ligand interactions are described via Morse functions and the angular geometry at the metal centers is modeled with a pure ligand-ligand repulsion term. The ZPW-FF is principally based on 15 DFT-optimized model systems of general formula ZnPR.nL, where ZnP is the base Zn2(O2CR)4 unit, R = H, CH3 or CF3, L = NH3 or pyridine, and n = 0, 1 or 2. It correctly generates the distorted tetrahedral coordination of the uncapped [Zn2(O2CR)4] species in their ground states as well as giving reasonable structures and energies for the higher symmetry D4h transition state conformations. The zinc-ligand Morse function reference distance, r0, is further refined against 30 complexes located in the Cambridge Structural Database and this FF is applied to pore models of the flexible metal-organic framework (MOF) [Zn(bdc)2(dabco)]n (bdc = 1,4-benzendicarboxylate; dabco = 1,4-diazabicyclo(2.2.2)octane). A single pore model reproduces the unit cell of the evacuated MOF system while a 3×3 grid model is necessary to provide good agreement with the observed pronounced structural changes upon adsorption of either dimethylformamide or benzene.Graphical AbstractStructural simulations of a zinc paddlewheel metal organic framework reproduce the observed breathing behaviourElectronic supplementary materialThe online version of this article (doi:10.1007/s00894-016-2949-5) contains supplementary material, which is available to authorized users.

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