The Molecular Mechanisms of Light Adaption in Light-harvesting Complexes of Purple Bacteria Revealed by a Multiscale Modeling

Overview

Journal Chem Sci

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2020 Feb 15

PMID 32055335

Citations 15

Authors

Felipe Cardoso Ramos

Michele Nottoli

Lorenzo Cupellini

Benedetta Mennucci

Affiliations

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Abstract

The light-harvesting in photosynthetic purple bacteria can be tuned in response to the light conditions during cell growth. One of the used strategies is to change the energy of the excitons in the major fight-harvesting complex, commonly known as LH2. In the present study we report the first systematic investigation of the microscopic origin of the exciton tuning using three complexes, namely the common (high-light) and the low-light forms of LH2 from plus a third complex analogous to the PucD complex from . The study is based on the combination of classical molecular dynamics of each complex in a lipid membrane and excitonic calculations based on a multiscale quantum mechanics/molecular mechanics approach including a polarizable embedding. From the comparative analysis, it comes out that the mechanisms that govern the adaptation of the complex to different light conditions use the different H-bonding environment around the bacteriochlorophyll pigments to dynamically control both internal and inter-pigment degrees of freedom. While the former have a large effect on the site energies, the latter significantly change the electronic couplings, but only the combination of the two effects can fully reproduce the tuning of the final excitons and explain the observed spectroscopic differences.

Citing Articles

Theory of photosynthetic membrane influence on B800-B850 energy transfer in the LH2 complex.

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Tuning by Hydrogen Bonding in Photosynthesis.

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Spectral changes of light-harvesting complex 2 lacking B800 bacteriochlorophyll a under neutral pH conditions.

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