Thermodynamic calculations in biological systems

L. Mario Amzel; Xavier Siebert; Anthony Armstrong; German Pabon

doi:10.1016/j.bpc.2005.05.004

Thermodynamic calculations in biological systems

L. Mario Amzel, Xavier Siebert, Anthony Armstrong, German Pabon

Johns Hopkins University

Producción: Contribución a una revista › Artículo de revisión › revisión exhaustiva

5 Citas (Scopus)

Resumen

The ability to compute intra- and inter-molecular interactions provides the opportunity to gain a deeper understanding of previously intractable problems in biochemistry and biophysics. This review presents three examples in which molecular dynamics calculations were used to gain insight into the atomic detail underlying important experimental observations. The three examples are the following: (1) Entropic contribution to rate acceleration that results from conformational constraints imposed on the reactants; (2) Mechanism of force unfolding of a small protein molecule by the application of a force that separates its N- and C-terminals; and (3) Loss of translational entropy experienced by small molecules when they bind to proteins.

Idioma original	Inglés
Páginas (desde-hasta)	239-254
Número de páginas	16
Publicación	Biophysical Chemistry
Volumen	117
N.º	3
DOI	https://doi.org/10.1016/j.bpc.2005.05.004
Estado	Publicada - 03 oct. 2005
Publicado de forma externa	Sí

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title = "Thermodynamic calculations in biological systems",

abstract = "The ability to compute intra- and inter-molecular interactions provides the opportunity to gain a deeper understanding of previously intractable problems in biochemistry and biophysics. This review presents three examples in which molecular dynamics calculations were used to gain insight into the atomic detail underlying important experimental observations. The three examples are the following: (1) Entropic contribution to rate acceleration that results from conformational constraints imposed on the reactants; (2) Mechanism of force unfolding of a small protein molecule by the application of a force that separates its N- and C-terminals; and (3) Loss of translational entropy experienced by small molecules when they bind to proteins.",

keywords = "Extension by force, Molecular dynamics, Rate acceleration, Translational entropy",

author = "Amzel, {L. Mario} and Xavier Siebert and Anthony Armstrong and German Pabon",

note = "Funding Information: We acknowledge the National Cancer Institute for allocation of computing time and support staff at the Frederick Biomedical Supercomputing Center of the Frederick Cancer Research and Development Center. This work was supported by grants GM51362 and GM45540 from NIGMS. We thank Julio Fernandez for helpfull discussions. The work of AAA was supported by the Burroughs Wellcome Fund through its funding of the Johns Hopkins Program in Computational Biology.",

year = "2005",

month = oct,

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doi = "10.1016/j.bpc.2005.05.004",

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journal = "Biophysical Chemistry",

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T1 - Thermodynamic calculations in biological systems

AU - Amzel, L. Mario

AU - Siebert, Xavier

AU - Armstrong, Anthony

AU - Pabon, German

N1 - Funding Information: We acknowledge the National Cancer Institute for allocation of computing time and support staff at the Frederick Biomedical Supercomputing Center of the Frederick Cancer Research and Development Center. This work was supported by grants GM51362 and GM45540 from NIGMS. We thank Julio Fernandez for helpfull discussions. The work of AAA was supported by the Burroughs Wellcome Fund through its funding of the Johns Hopkins Program in Computational Biology.

PY - 2005/10/3

Y1 - 2005/10/3

N2 - The ability to compute intra- and inter-molecular interactions provides the opportunity to gain a deeper understanding of previously intractable problems in biochemistry and biophysics. This review presents three examples in which molecular dynamics calculations were used to gain insight into the atomic detail underlying important experimental observations. The three examples are the following: (1) Entropic contribution to rate acceleration that results from conformational constraints imposed on the reactants; (2) Mechanism of force unfolding of a small protein molecule by the application of a force that separates its N- and C-terminals; and (3) Loss of translational entropy experienced by small molecules when they bind to proteins.

AB - The ability to compute intra- and inter-molecular interactions provides the opportunity to gain a deeper understanding of previously intractable problems in biochemistry and biophysics. This review presents three examples in which molecular dynamics calculations were used to gain insight into the atomic detail underlying important experimental observations. The three examples are the following: (1) Entropic contribution to rate acceleration that results from conformational constraints imposed on the reactants; (2) Mechanism of force unfolding of a small protein molecule by the application of a force that separates its N- and C-terminals; and (3) Loss of translational entropy experienced by small molecules when they bind to proteins.

KW - Extension by force

KW - Molecular dynamics

KW - Rate acceleration

KW - Translational entropy

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DO - 10.1016/j.bpc.2005.05.004

M3 - Review article

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AN - SCOPUS:24344457329

SN - 0301-4622

VL - 117

SP - 239

EP - 254

JO - Biophysical Chemistry

JF - Biophysical Chemistry

IS - 3

ER -

Thermodynamic calculations in biological systems

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