Litcius/Paper detail

Excitation Energy Transfer between Higher Excited States of Photosynthetic Pigments: 2. Chlorophyll <i>b</i> is a B Band Excitation Trap

Jan P. Götze, Heiko Lokstein

2023ACS Omega13 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Chlorophylls (Chls) are known for fast, subpicosecond internal conversion (IC) from ultraviolet/blue absorbing (“B” or “Soret” states) to the energetically lower, red light-absorbing Q states. Consequently, excitation energy transfer (EET) in photosynthetic pigment–protein complexes involving the B states has so far not been considered. We present, for the first time, a theoretical framework for the existence of B–B EET in tightly coupled Chl aggregates such as photosynthetic pigment–protein complexes. We show that according to a Förster resonance energy transport (FRET) scheme, unmodulated B–B EET has an unexpectedly high range. Unsuppressed, it could pose an existential threat-the damage potential of blue light for photochemical reaction centers (RCs) is well-known. This insight reveals so-far undescribed roles for carotenoids (Crts, cf. previous article in this series) and Chl b (this article) of possibly vital importance. Our model system is the photosynthetic antenna pigment–protein complex (CP29). The focus of the study is on the role of Chl b for EET in the Q and B bands. Further, the initial excited pigment distribution in the B band is computed for relevant solar irradiation and wavelength-centered laser pulses. It is found that both accessory pigment classes compete efficiently with Chl a absorption in the B band, leaving only 40% of B band excitations for Chl a . B state population is preferentially relocated to Chl b after excitation of any Chls, due to a near-perfect match of Chl b B band absorption with Chl a B state emission spectra. This results in an efficient depletion of the Chl a population (0.66 per IC/EET step, as compared to 0.21 in a Chl a -only system). Since Chl b only occurs in the peripheral antenna complexes of plants and algae, and RCs contain only Chl a, this would automatically trap potentially dangerous B state population in the antennae, preventing forwarding to the RCs.

Topics & Concepts

ExcitationExcited statePhotosynthesisEnergy transferChlorophyll aAtomic physicsPigmentChemistryChlorophyllTrap (plumbing)Chlorophyll fluorescencePhotochemistryPhysicsMeteorologyQuantum mechanicsOrganic chemistryBiochemistryPhotosynthetic Processes and MechanismsLight effects on plantsPhotoreceptor and optogenetics research