Normal modes for large molecules with arbitrary link constraints in the mobile block Hessian approach.

In a previous paper [Ghysels et al., J. Chem. Phys. 126, 224102 (2007)] the mobile block Hessian (MBH) approach was presented. The method was designed to accurately compute vibrational modes of partially optimized molecular structures. The key concept was the introduction of several blocks of atoms, which can move as rigid bodies with respect to a local, fully optimized subsystem. The choice of the blocks was restricted in the sense that none of them could be connected, and also linear blocks were not taken into consideration. In this paper an extended version of the MBH method is presented that is generally applicable and allows blocks to be adjoined by one or two common atoms. This extension to all possible block partitions of the molecule provides a structural flexibility varying from very rigid to extremely relaxed. The general MBH method is very well suited to study selected normal modes of large macromolecules (such as proteins and polymers) because the number of degrees of freedom can be greatly reduced while still keeping the essential motions of the molecular system. The reduction in the number of degrees of freedom due to the block linkages is imposed here directly using a constraint method, in contrast to restraint methods where stiff harmonic couplings are introduced to restrain the relative motion of the blocks. The computational cost of this constraint method is less than that of an implementation using a restraint method. This is illustrated for the alpha-helix conformation of an alanine-20-polypeptide.

[1]  V Van Speybroeck,et al.  Mobile Block Hessian Approach with Adjoined Blocks: An Efficient Approach for the Calculation of Frequencies in Macromolecules. , 2009, Journal of chemical theory and computation.

[2]  Markus Reiher,et al.  QM/MM vibrational mode tracking , 2008, J. Comput. Chem..

[3]  John D. Head,et al.  COMPUTATION OF VIBRATIONAL FREQUENCIES FOR ADSORBATES ON SURFACES , 1997 .

[4]  Nicholas A Besley,et al.  Computation of the amide I band of polypeptides and proteins using a partial Hessian approach. , 2007, The Journal of chemical physics.

[5]  Florence Tama,et al.  The mechanism and pathway of pH induced swelling in cowpea chlorotic mottle virus. , 2002, Journal of molecular biology.

[6]  Bernard R Brooks,et al.  Vibrational subsystem analysis: A method for probing free energies and correlations in the harmonic limit. , 2008, The Journal of chemical physics.

[7]  R. Schweitzer-Stenner,et al.  Dihedral angles of tripeptides in solution directly determined by polarized Raman and FTIR spectroscopy. , 2002, Biophysical journal.

[8]  Y. Sanejouand,et al.  Hinge‐bending motion in citrate synthase arising from normal mode calculations , 1995, Proteins.

[9]  R. Hochstrasser,et al.  Local Structure of β-Hairpin Isotopomers by FTIR, 2D IR, and Ab Initio Theory , 2006 .

[10]  M. Karplus,et al.  CHARMM: A program for macromolecular energy, minimization, and dynamics calculations , 1983 .

[11]  G. Thomas Raman spectroscopy of protein and nucleic acid assemblies. , 1999, Annual review of biophysics and biomolecular structure.

[12]  T Verstraelen,et al.  Vibrational modes in partially optimized molecular systems. , 2007, The Journal of chemical physics.

[13]  R. Schweitzer‐Stenner Secondary structure analysis of polypeptides based on an excitonic coupling model to describe the band profile of amide I' of IR, raman, and vibrational circular dichroism spectra , 2004 .

[14]  J. Head A vibrational analysis with Fermi resonances for methoxy adsorption on Cu(111) using ab initio cluster calculations , 2000 .

[15]  J. Head,et al.  Characterization of Fermi resonances in adsorbate vibrational spectra using cluster calculations: Methoxy adsorption on Al(111) and Cu(111) , 1999 .

[16]  Shawn T. Brown,et al.  Advances in methods and algorithms in a modern quantum chemistry program package. , 2006, Physical chemistry chemical physics : PCCP.

[17]  M Waroquier,et al.  Cartesian formulation of the mobile block Hessian approach to vibrational analysis in partially optimized systems. , 2007, The Journal of chemical physics.

[18]  Steven A. Siegelbaum,et al.  Effects of Surface Water on Protein Dynamics Studied by a Novel Coarse-Grained Normal Mode Approach , 2008, Biophysical journal.

[19]  Guohui Li,et al.  A coarse-grained normal mode approach for macromolecules: an efficient implementation and application to Ca(2+)-ATPase. , 2002, Biophysical journal.

[20]  Qiang Cui,et al.  Analysis of functional motions in Brownian molecular machines with an efficient block normal mode approach: myosin-II and Ca2+ -ATPase. , 2004, Biophysical journal.

[21]  Theoretical study of the structure and properties of Na-MOR and H-MOR zeolite models. , 2007 .

[22]  Hui Li,et al.  Partial Hessian vibrational analysis: the localization of the molecular vibrational energy and entropy , 2002 .

[23]  T Verstraelen,et al.  Calculating Reaction Rates with Partial Hessians: Validation of the Mobile Block Hessian Approach. , 2008, Journal of chemical theory and computation.

[24]  John D. Head,et al.  Theoretical investigation of molecular water adsorption on the Al(111) surface , 1994 .

[25]  John D. Head,et al.  Theoretically modelling the water bilayer on the Al(111) surface using cluster calculations , 1996 .