Thermal stability of solitons in protein α-helices
Abstract
Protein α-helices provide an ordered biological environment that is conducive to soliton-assisted energy transport. The nonlinear interaction between amide I excitons and phonon deformations induced in the hydrogen-bonded lattice of peptide groups leads to self-trapping of the amide I energy, thereby creating a localized quasiparticle (soliton) that persists at zero temperature. The presence of thermal noise, however, could destabilize the protein soliton and dissipate its energy within a finite lifetime. In this work, we have computationally solved the system of stochastic differential equations that govern the quantum dynamics of protein solitons at physiological temperature, T = 310 K, for either a single isolated α-helix spine of hydrogen bonded peptide groups or the full protein α-helix comprised of three parallel α-helix spines. The simulated stochastic dynamics revealed that although the thermal noise is detrimental for the single isolated α-helix spine, the cooperative action of three amide I exciton quanta in the full protein α-helix ensures soliton lifetime of over 30 ps, during which the amide I energy could be transported along the entire extent of an 18-nm-long α-helix. Thus, macromolecular protein complexes, which are built up of protein α-helices could harness soliton-assisted energy transport at physiological temperature. Because the hydrolysis of a single adenosine triphosphate molecule is able to initiate three amide I exciton quanta, it is feasible that multiquantal protein solitons subserve a variety of specialized physiological functions in living systems.
- Publication:
-
Chaos Solitons and Fractals
- Pub Date:
- February 2022
- DOI:
- arXiv:
- arXiv:2202.00525
- Bibcode:
- 2022CSF...15511644G
- Keywords:
-
- Davydov soliton;
- Langevin dynamics;
- Protein α-helix;
- Soliton lifetime;
- Thermal noise;
- Physics - Biological Physics;
- Condensed Matter - Soft Condensed Matter;
- Quantum Physics
- E-Print:
- 27 pages, 12 figures