Dynamic complexity of chaotic transitions in high-dimensional classical dynamics: Leu-Enkephalin folding

Dmitry Nerukh; George Karvounis; Robert C. Glen

doi:10.1007/11875741_13

Dynamic complexity of chaotic transitions in high-dimensional classical dynamics: Leu-Enkephalin folding

Dmitry Nerukh, George Karvounis, Robert C. Glen

Research output: Chapter in Book/Published conference output › Conference publication

Abstract

Leu-Enkephalin in explicit water is simulated using classical molecular dynamics. A ß-turn transition is investigated by calculating the topological complexity (in the "computational mechanics" framework [J. P. Crutchfield and K. Young, Phys. Rev. Lett., 63, 105 (1989)]) of the dynamics of both the peptide and the neighbouring water molecules. The complexity of the atomic trajectories of the (relatively short) simulations used in this study reflect the degree of phase space mixing in the system. It is demonstrated that the dynamic complexity of the hydrogen atoms of the peptide and almost all of the hydrogens of the neighbouring waters exhibit a minimum precisely at the moment of the ß-turn transition. This indicates the appearance of simplified periodic patterns in the atomic motion, which could correspond to high-dimensional tori in the phase space. It is hypothesized that this behaviour is the manifestation of the effect described in the approach to molecular transitions by Komatsuzaki and Berry [T. Komatsuzaki and R.S. Berry, Adv. Chem. Phys., 123, 79 (2002)], where a "quasi-regular" dynamics at the transition is suggested. Therefore, for the first time, the less chaotic character of the folding transition in a realistic molecular system is demonstrated.

Original language	English
Title of host publication	Computational life sciences II
Subtitle of host publication	second international symposium, CompLife 2006, Cambridge, UK, September 27-29, 2006. Proceedings
Editors	Michael R. Berthold, Robert C. Glen, Ingrid Fischer
Place of Publication	Berlin (DE)
Publisher	Springer
Pages	129-140
Number of pages	12
ISBN (Electronic)	978-3-540-45768-8
ISBN (Print)	978-3-540-45767-1
DOIs	https://doi.org/10.1007/11875741_13
Publication status	Published - 2006
Event	2nd International Symposium on Computational Life sciences - Cambridge, United Kingdom Duration: 27 Sept 2006 → 29 Sept 2006

Publication series

Name	Lecture notes in computer science
Publisher	Springer
Volume	4216
ISSN (Print)	0302-9743
ISSN (Electronic)	1611-3349

Symposium

Symposium	2nd International Symposium on Computational Life sciences
Abbreviated title	CompLife 2006
Country/Territory	United Kingdom
City	Cambridge
Period	27/09/06 → 29/09/06

Keywords

folding
enkephalin
dynamic complexity
computational mechanics

Access to Document

10.1007/11875741_13

Cite this

Nerukh, D., Karvounis, G., & Glen, R. C. (2006). Dynamic complexity of chaotic transitions in high-dimensional classical dynamics: Leu-Enkephalin folding. In M. R. Berthold, R. C. Glen, & I. Fischer (Eds.), Computational life sciences II: second international symposium, CompLife 2006, Cambridge, UK, September 27-29, 2006. Proceedings (pp. 129-140). (Lecture notes in computer science; Vol. 4216). Springer. https://doi.org/10.1007/11875741_13

Nerukh, Dmitry ; Karvounis, George ; Glen, Robert C. / Dynamic complexity of chaotic transitions in high-dimensional classical dynamics : Leu-Enkephalin folding. Computational life sciences II: second international symposium, CompLife 2006, Cambridge, UK, September 27-29, 2006. Proceedings. editor / Michael R. Berthold ; Robert C. Glen ; Ingrid Fischer. Berlin (DE) : Springer, 2006. pp. 129-140 (Lecture notes in computer science).

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title = "Dynamic complexity of chaotic transitions in high-dimensional classical dynamics: Leu-Enkephalin folding",

abstract = "Leu-Enkephalin in explicit water is simulated using classical molecular dynamics. A {\ss}-turn transition is investigated by calculating the topological complexity (in the {"}computational mechanics{"} framework [J. P. Crutchfield and K. Young, Phys. Rev. Lett., 63, 105 (1989)]) of the dynamics of both the peptide and the neighbouring water molecules. The complexity of the atomic trajectories of the (relatively short) simulations used in this study reflect the degree of phase space mixing in the system. It is demonstrated that the dynamic complexity of the hydrogen atoms of the peptide and almost all of the hydrogens of the neighbouring waters exhibit a minimum precisely at the moment of the {\ss}-turn transition. This indicates the appearance of simplified periodic patterns in the atomic motion, which could correspond to high-dimensional tori in the phase space. It is hypothesized that this behaviour is the manifestation of the effect described in the approach to molecular transitions by Komatsuzaki and Berry [T. Komatsuzaki and R.S. Berry, Adv. Chem. Phys., 123, 79 (2002)], where a {"}quasi-regular{"} dynamics at the transition is suggested. Therefore, for the first time, the less chaotic character of the folding transition in a realistic molecular system is demonstrated.",

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Nerukh, D, Karvounis, G & Glen, RC 2006, Dynamic complexity of chaotic transitions in high-dimensional classical dynamics: Leu-Enkephalin folding. in MR Berthold, RC Glen & I Fischer (eds), Computational life sciences II: second international symposium, CompLife 2006, Cambridge, UK, September 27-29, 2006. Proceedings. Lecture notes in computer science, vol. 4216, Springer, Berlin (DE), pp. 129-140, 2nd International Symposium on Computational Life sciences, Cambridge, United Kingdom, 27/09/06. https://doi.org/10.1007/11875741_13

Dynamic complexity of chaotic transitions in high-dimensional classical dynamics: Leu-Enkephalin folding. / Nerukh, Dmitry; Karvounis, George; Glen, Robert C.
Computational life sciences II: second international symposium, CompLife 2006, Cambridge, UK, September 27-29, 2006. Proceedings. ed. / Michael R. Berthold; Robert C. Glen; Ingrid Fischer. Berlin (DE): Springer, 2006. p. 129-140 (Lecture notes in computer science; Vol. 4216).

Research output: Chapter in Book/Published conference output › Conference publication

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AB - Leu-Enkephalin in explicit water is simulated using classical molecular dynamics. A ß-turn transition is investigated by calculating the topological complexity (in the "computational mechanics" framework [J. P. Crutchfield and K. Young, Phys. Rev. Lett., 63, 105 (1989)]) of the dynamics of both the peptide and the neighbouring water molecules. The complexity of the atomic trajectories of the (relatively short) simulations used in this study reflect the degree of phase space mixing in the system. It is demonstrated that the dynamic complexity of the hydrogen atoms of the peptide and almost all of the hydrogens of the neighbouring waters exhibit a minimum precisely at the moment of the ß-turn transition. This indicates the appearance of simplified periodic patterns in the atomic motion, which could correspond to high-dimensional tori in the phase space. It is hypothesized that this behaviour is the manifestation of the effect described in the approach to molecular transitions by Komatsuzaki and Berry [T. Komatsuzaki and R.S. Berry, Adv. Chem. Phys., 123, 79 (2002)], where a "quasi-regular" dynamics at the transition is suggested. Therefore, for the first time, the less chaotic character of the folding transition in a realistic molecular system is demonstrated.

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Nerukh D, Karvounis G, Glen RC. Dynamic complexity of chaotic transitions in high-dimensional classical dynamics: Leu-Enkephalin folding. In Berthold MR, Glen RC, Fischer I, editors, Computational life sciences II: second international symposium, CompLife 2006, Cambridge, UK, September 27-29, 2006. Proceedings. Berlin (DE): Springer. 2006. p. 129-140. (Lecture notes in computer science). doi: 10.1007/11875741_13

Dynamic complexity of chaotic transitions in high-dimensional classical dynamics: Leu-Enkephalin folding

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