Litcius/Paper detail

Dependence of Vibrational Energy Transfer on Distance in a Four-Helix Bundle Protein: Equidistant Increments with the Periodicity of α Helices

Satoshi Yamashita, Misao Mizuno, Kazuhiro Takemura, Akio Kitao, Yasuhisa Mizutani

2022The Journal of Physical Chemistry B10 citationsDOI

Abstract

Vibrational energy exchanges between various degrees of freedom are critical to barrier-crossing processes in proteins. Heme proteins are highly suitable for studies of the vibrational energy exchanges in proteins. The migration of excess energy released by heme in a protein moiety can be observed using time-resolved anti-Stokes ultraviolet resonance Raman spectroscopy. The anti-Stokes resonance Raman intensity of a tryptophan residue is an excellent probe for the excess energy and the spatial resolution of a single amino acid residue can be achieved. Here, we studied dependence of vibrational energy transfer on the distance in cytochrome b562, which is a heme-containing, four-helix bundle protein. The vibrational energy transfer from the heme group to a single tryptophan residue introduced by site-directed mutagenesis was examined for different heme-tryptophan distances by a quasi-constant length with the periodicity of α helices. Taken together with structural data obtained by molecular dynamics simulations, the energy transfer could be well described by the model of classical thermal diffusion, which suggests that continuum media provide a good approximation of the protein interior, of which the atomic packing density is very high.

Topics & Concepts

ChemistryHemeMyoglobinTryptophanHemeproteinRaman spectroscopyCrystallographyResonance Raman spectroscopyMolecular dynamicsChemical physicsAmino acidComputational chemistryPhysicsOrganic chemistryOpticsBiochemistryEnzymeHemoglobin structure and functionSpectroscopy and Quantum Chemical StudiesProtein Structure and Dynamics
Dependence of Vibrational Energy Transfer on Distance in a Four-Helix Bundle Protein: Equidistant Increments with the Periodicity of α Helices | Litcius