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CHARMM potential energy function

Of the biomolecular force fields, AMBER [21] is considered to be transferable, whereas academic CHARMM [20] is not transferable. Considering the simplistic form of the potential energy functions used in these force fields, the extent of transferability should be considered to be minimal, as has been shown recently [52]. As stated above, the user should perform suitable tests on any novel compounds to ensure that the force field is treating the systems of interest with sufficient accuracy. [Pg.17]

Some formulations of the potential energy function (e.g., References 27 and 79, and AMBER, CHARMM, and DISCOVER, as well as most force fields used in small-molecule studies) include terms that allow for bond stretching and bond angle bending, that is, for flexible geometry. Hence, the terms in Eq. [1] are augmented by the expression27... [Pg.86]

The CHARMM code, version c25bl, was chosen for integration with the metal potential. CHARMM is a multi-purpose molecular dynamics program [35], which uses empirical potential energy functions to simulate a variety of systems, including proteins, nucleic acids, lipids, sugars and water. The availability of periodic boundary conditions of various lattice types (for example cubic and orthorhombic) makes it possible to treat solids as well as liquids. [Pg.706]

The success of any molecular simulation method relies on the potential energy function for the system of interest, also known as force fields [27]. In case of proteins, several (semi)empirical atomistic force fields have been developed over the years, of which ENCAD [28,29], AMBER [30], CHARMM [31], GRO-MOS [32], and OPLSAA [33] are the most well known. In principle, the force field should include the electronic structure, but for most except the smallest systems the calculation of the electronic structure is prohibitively expensive, even when using approximations such as density functional theory. Instead, most potential energy functions are (semi)empirical classical approximations of the Born-Oppenheimer energy surface. [Pg.404]

Molecular modeling and computer simulation with empirical potential energy function (force field) are now routinely carried out to help understand and predict structures and dynamics of proteins and other macromolecules of biological relevance in water and membrane environments. After over 40 years of development, popular force fields such as AMBER, CHARMM, OPLS and GROMOS have been widely employed in biomolecular simulations. These force fields are used dominantly in highly optimized molecular dynamics... [Pg.337]

To begin, we must state explicitly the potential energy function. In this example we use the CHARMM potential model ... [Pg.380]

Among the most used force fields of this kind we cite AMBER-GAFF [9, 10], OPLS [11], and CHARMM [12], all relying on intramolecular potential energy functions like the following ... [Pg.44]

Extension of Potential Energy Function,Capability of CHARMM... [Pg.274]

The utility of CHARMM arises not only from the availability of accurate potential energy functions. Equally important, particularly because of the large dimensionality of the systems of interest, is a wide range of facilities in the CHARMM program for the manipulation of macromolecules and for the analysis of the simulation results. The following sections present a number of the functionalities in CHARMM, with emphasis on those added since the original CHARMM paper. ... [Pg.274]

AMI AMBER A Program for Simulation of Biological and Organic Molecules CHARMM The Energy Function and Its Parameterization Combined Quantum Mechanics and Molecular Mechanics Approaches to Chemical and Biochemical Reactivity Density Functional Theory (DFT), Hartree-Fock (HF), and the Self-consistent Field Divide and Conquer for Semiempirical MO Methods Electrostatic Catalysis Force Fields A General Discussion Force Fields CFF GROMOS Force Field Hybrid Methods Hybrid Quantum Mechanical/Molecular Mechanical (QM/MM) Methods Mixed Quantum-Classical Methods MNDO MNDO/d Molecular Dynamics Techniques and Applications to Proteins OPLS Force Fields Parameterization of Semiempirical MO Methods PM3 Protein Force Fields Quantum Mechanical/Molecular Mechanical (QM/MM) Coupled Potentials Quantum Mecha-nics/Molecular Mechanics (QM/MM) SINDOI Parameterization and Application. [Pg.436]

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See also in sourсe #XX -- [ Pg.272 ]



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