Literature DB >> 33315217

Locating and Navigating Energy Transport Networks in Proteins.

Korey M Reid1, David M Leitner2.   

Abstract

We review computational methods to locate energy transport networks in proteins that are based on the calculation of local energy diffusion in nanoscale systems. As an illustrative example, we discuss energy transport networks computed for the homodimeric hemoglobin from Scapharca inaequivalvis, where channels for facile energy transport, which include the cluster of water molecules at the interface of the globules, have been found to lie along pathways that experiments reveal are important in allosteric processes. We also review recent work on master equation simulations to model energy transport dynamics, including efforts to relate rate constants in the master equation to protein structural dynamics. Results for apomyoglobin involving relations between fluctuations in the length of hydrogen bonds and the energy flux between them are presented.

Entities:  

Keywords:  Allostery; Energy transport networks; Nonbonded networks; Water cluster

Mesh:

Substances:

Year:  2021        PMID: 33315217     DOI: 10.1007/978-1-0716-1154-8_4

Source DB:  PubMed          Journal:  Methods Mol Biol        ISSN: 1064-3745


  89 in total

1.  Direct observation of vibrational energy flow in cytochrome c.

Authors:  Naoki Fujii; Misao Mizuno; Yasuhisa Mizutani
Journal:  J Phys Chem B       Date:  2011-10-13       Impact factor: 2.991

2.  Observing Vibrational Energy Flow in a Protein with the Spatial Resolution of a Single Amino Acid Residue.

Authors:  Naoki Fujii; Misao Mizuno; Haruto Ishikawa; Yasuhisa Mizutani
Journal:  J Phys Chem Lett       Date:  2014-09-10       Impact factor: 6.475

3.  Energy transport in peptide helices.

Authors:  Virgiliu Botan; Ellen H G Backus; Rolf Pfister; Alessandro Moretto; Marco Crisma; Claudio Toniolo; Phuong H Nguyen; Gerhard Stock; Peter Hamm
Journal:  Proc Natl Acad Sci U S A       Date:  2007-07-23       Impact factor: 11.205

4.  Structural flexibility of a helical peptide regulates vibrational energy transport properties.

Authors:  Ellen H G Backus; Phuong H Nguyen; Virgiliu Botan; Alessandro Moretto; Marco Crisma; Claudio Toniolo; Oliver Zerbe; Gerhard Stock; Peter Hamm
Journal:  J Phys Chem B       Date:  2008-12-04       Impact factor: 2.991

5.  Energy transport in peptide helices: a comparison between high- and low-energy excitations.

Authors:  Ellen H G Backus; Phuong H Nguyen; Virgiliu Botan; Rolf Pfister; Alessandro Moretto; Marco Crisma; Claudio Toniolo; Gerhard Stock; Peter Hamm
Journal:  J Phys Chem B       Date:  2008-07-03       Impact factor: 2.991

6.  Dynamical transition in a small helical peptide and its implication for vibrational energy transport.

Authors:  Ellen H G Backus; Robbert Bloem; Rolf Pfister; Alessandro Moretto; Marco Crisma; Claudio Toniolo; Peter Hamm
Journal:  J Phys Chem B       Date:  2009-10-08       Impact factor: 2.991

7.  Energy exchange network of inter-residue interactions within a thermally fluctuating protein molecule: A computational study.

Authors:  Takakazu Ishikura; Yuki Iwata; Tatsuro Hatano; Takahisa Yamato
Journal:  J Comput Chem       Date:  2015-07-06       Impact factor: 3.376

8.  Vibrational energy flow through the green fluorescent protein-water interface: communication maps and thermal boundary conductance.

Authors:  Yao Xu; David M Leitner
Journal:  J Phys Chem B       Date:  2014-02-06       Impact factor: 2.991

9.  Importance of Atomic Contacts in Vibrational Energy Flow in Proteins.

Authors:  Masato Kondoh; Misao Mizuno; Yasuhisa Mizutani
Journal:  J Phys Chem Lett       Date:  2016-05-12       Impact factor: 6.475

10.  Response of villin headpiece-capped gold nanoparticles to ultrafast laser heating.

Authors:  Shabir Hassan; Marco Schade; Christopher P Shaw; Raphaël Lévy; Peter Hamm
Journal:  J Phys Chem B       Date:  2014-03-13       Impact factor: 2.991
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