Your search keyword '"Light-Harvesting Protein Complexes chemistry"' showing total 1,433 results

1. Structural insights into the assembly and energy transfer of haptophyte photosystem I-light-harvesting supercomplex.

Author

He FY, Zhao LS, Qu XX, Li K, Guo JP, Zhao F, Wang N, Qin BY, Chen XL, Gao J, Liu LN, and Zhang YZ

Subjects

Photosystem I Protein Complex metabolism, Photosystem I Protein Complex chemistry, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Energy Transfer, Haptophyta metabolism, Cryoelectron Microscopy methods

Abstract

Haptophyta represents a major taxonomic group, with plastids derived from the primary plastids of red algae. Here, we elucidated the cryoelectron microscopy structure of the photosystem I-light-harvesting complex I (PSI-LHCI) supercomplex from the haptophyte Isochrysis galbana . The PSI core comprises 12 subunits, which have evolved differently from red algae and cryptophytes by losing the PsaO subunit while incorporating the PsaK subunit, which is absent in diatoms and dinoflagellates. The PSI core is encircled by 22 fucoxanthin-chlorophyll a / c -binding light-harvesting antenna proteins (iFCPIs) that form a trilayered antenna arrangement. Moreover, a pigment-binding subunit, L iFP , which has not been identified in any other previously characterized PSI-LHCI supercomplexes, was determined in I. galbana PSI-iFCPI, presumably facilitating the interactions and energy transfer between peripheral iFCPIs and the PSI core. Calculation of excitation energy transfer rates by computational simulations revealed that the intricate pigment network formed within PSI-iFCPI ensures efficient transfer of excitation energy. Overall, our study provides a solid structural foundation for understanding the light-harvesting and energy transfer mechanisms in haptophyte PSI-iFCPI and provides insights into the evolution and structural variations of red-lineage PSI-LHCIs., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

2. Unique structural attributes of the PSI-NDH supercomplex in Physcomitrium patens.

Author

Opatíková M and Kouřil R

Subjects

NADH Dehydrogenase metabolism, NADH Dehydrogenase genetics, Photosynthesis, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes genetics, Light-Harvesting Protein Complexes chemistry, Electron Transport, Bryopsida genetics, Bryopsida metabolism, Photosystem I Protein Complex metabolism, Photosystem I Protein Complex genetics, Plant Proteins metabolism, Plant Proteins genetics

Abstract

Cyclic electron transport around photosystem I (PSI) is essential for the protection of the photosynthetic apparatus in plants under diverse light conditions. This process is primarily mediated by Proton Gradient Regulation 5 protein/Proton Gradient Regulation 5-like photosynthetic phenotype 1 protein (PGR5/PGRL1) and NADH dehydrogenase-like complex (NDH). In angiosperms, NDH interacts with two PSI complexes through distinct monomeric antennae, LHCA5 and LHCA6, which is crucial for its higher stability under variable light conditions. This interaction represents an advanced evolutionary stage and offers limited insight into the origin of the PSI-NDH supercomplex in evolutionarily older organisms. In contrast, the moss Physcomitrium patens (Pp), which retains the lhca5 gene but lacks the lhca6, offers a glimpse into an earlier evolutionary stage of the PSI-NDH supercomplex. Here we present structural evidence of the Pp PSI-NDH supercomplex formation by single particle electron microscopy, demonstrating the unique ability of Pp to bind a single PSI in two different configurations. One configuration closely resembles the angiosperm model, whereas the other exhibits a novel PSI orientation, rotated clockwise. This structural flexibility in Pp is presumably enabled by the variable incorporation of LHCA5 within PSI and is indicative of an early evolutionary adaptation that allowed for greater diversity at the PSI-NDH interface. Our findings suggest that this variability was reduced as the structural complexity of the NDH complex increased in vascular plants, primarily angiosperms. This study not only clarifies the evolutionary development of PSI-NDH supercomplexes but also highlights the dynamic nature of the adaptive mechanisms of plant photosynthesis., (© 2024 The Author(s). The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2024

3. Intramolecular charge transfer and the function of vibronic excitons in photosynthetic light harvesting.

Author

Beck WF

Subjects

Dinoflagellida physiology, Carotenoids metabolism, Carotenoids chemistry, Vibration, Cyanobacteria metabolism, Cyanobacteria physiology, Phycobilisomes metabolism, Phycobilisomes chemistry, Energy Transfer, Photosynthesis physiology, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry

Abstract

A widely discussed explanation for the prevalence of pairs or clusters of closely spaced electronic chromophores in photosynthetic light-harvesting proteins is the presence of ultrafast and highly directional excitation energy transfer pathways mediated by vibronic excitons, the delocalized optical excitations derived from mixing of the electronic and vibrational states of the chromophores. We discuss herein the hypothesis that internal conversion processes between exciton states on the <100 fs timescale are possible when the excitonic potential energy surfaces are controlled by the vibrational modes that induce charge transfer character in a strongly coupled system of chromophores. We discuss two examples, the peridinin-chlorophyll protein from marine dinoflagellates and the intact phycobilisome from cyanobacteria, in which the intramolecular charge-transfer (ICT) character arising from out-of-plane distortion of the conjugation of carotenoid or bilin chromophores also results in localization of the initially delocalized optical excitation on the vibrational timescale. Tuning of the ground state conformations of the chromophores to manipulate their ICT character provides a natural photoregulatory mechanism, which would control the overall quantum yield of excitation energy transfer by turning on and off the delocalized character of the optical excitations., Competing Interests: Declarations. Conflict of interest: The author declares no Conflict of interest., (© 2024. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2024

4. Phylogenetic and spectroscopic insights on the evolution of core antenna proteins in cyanobacteria.

Author

Biswas S, Niedzwiedzki DM, Liberton M, and Pakrasi HB

Subjects

Photosystem II Protein Complex metabolism, Photosystem II Protein Complex genetics, Photosystem II Protein Complex chemistry, Bacterial Proteins metabolism, Bacterial Proteins genetics, Bacterial Proteins chemistry, Evolution, Molecular, Photosystem I Protein Complex metabolism, Photosystem I Protein Complex chemistry, Chlorophyll metabolism, Chlorophyll Binding Proteins metabolism, Chlorophyll Binding Proteins genetics, Chlorophyll Binding Proteins chemistry, Cyanobacteria metabolism, Cyanobacteria genetics, Phylogeny, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes genetics, Light-Harvesting Protein Complexes chemistry

Abstract

Light harvesting by antenna systems is the initial step in a series of electron-transfer reactions in all photosynthetic organisms, leading to energy trapping by reaction center proteins. Cyanobacteria are an ecologically diverse group and are the simplest organisms capable of oxygenic photosynthesis. The primary light-harvesting antenna in cyanobacteria is the large membrane extrinsic pigment-protein complex called the phycobilisome. In addition, cyanobacteria have also evolved specialized membrane-intrinsic chlorophyll-binding antenna proteins that transfer excitation energy to the reaction centers of photosystems I and II (PSI and PSII) and dissipate excess energy through nonphotochemical quenching. Primary among these are the CP43 and CP47 proteins of PSII, but in addition, some cyanobacteria also use IsiA and the prochlorophyte chlorophyll a/b binding (Pcb) family of proteins. Together, these proteins comprise the CP43 family of proteins owing to their sequence similarity with CP43. In this article, we have revisited the evolution of these chlorophyll-binding antenna proteins by examining their protein sequences in parallel with their spectral properties. Our phylogenetic and spectroscopic analyses support the idea of a common ancestor for CP43, IsiA, and Pcb proteins, and suggest that PcbC might be a distant ancestor of IsiA. The similar spectral properties of CP47 and IsiA suggest a closer evolutionary relationship between these proteins compared to CP43., Competing Interests: Declarations. Conflict of interest: The authors declare no competing interests., (© 2023. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2024

5. Spectral modulation of B850 bacteriochlorophyll a in light-harvesting complex 2 from purple photosynthetic bacterium Thermochromatium tepidum by detergents and calcium ions.

Author

Saga Y, Sasamoto Y, Inada K, Wang-Otomo ZY, and Kimura Y

Subjects

Bacterial Proteins metabolism, Bacterial Proteins chemistry, Spectrum Analysis, Raman, Photosynthesis, Chromatiaceae metabolism, Calcium metabolism, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Detergents chemistry, Detergents pharmacology, Bacteriochlorophyll A chemistry, Bacteriochlorophyll A metabolism

Abstract

Spectral variations of light-harvesting (LH) proteins of purple photosynthetic bacteria provide insight into the molecular mechanisms underlying spectral tuning of circular bacteriochlorophyll (BChl) arrays, which play crucial roles in photoenergy conversion in these organisms. Here we investigate spectral changes of the Q y band of B850 BChl a in LH2 protein from purple sulfur bacterium Thermochromatium tepidum (tepidum-LH2) by detergents and Ca 2+ . The tepidum-LH2 solubilized with lauryl dimethylamine N-oxide and n-octyl-β-D-glucoside (LH2 LDAO and LH2 OG , respectively) exhibited blue-shift of the B850 Q y band with hypochromism compared with the tepidum-LH2 solubilized with n-dodecyl-β-D-maltoside (LH2 DDM ), resulting in the LH3-like spectral features. Resonance Raman spectroscopy indicated that this blue-shift was ascribable to the loss of hydrogen-bonding between the C3-acetyl group in B850 BChl a and the LH2 polypeptides. Ca 2+ produced red-shift of the B850 Q y band in LH2 LDAO by forming hydrogen-bond for the C3-acetyl group in B850 BChl a, probably due to a change in the microenvironmental structure around B850. Ca 2+ -induced red-shift was also observed in LH2 OG although the B850 acetyl group is still free from hydrogen-bonding. Therefore, the Ca 2+ -induced B850 red-shift in LH2 OG would originate from an electrostatic effect of Ca 2+ . The current results suggest that the B850 Q y band in tepidum-LH2 is primarily tuned by two mechanisms, namely the hydrogen-bonding of the B850 acetyl group and the electrostatic effect., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2024

6. Molecular events accompanying aggregation-induced energy quenching in fucoxanthin-chlorophyll proteins.

Author

Alexandre MTA, Krüger TPJ, Pascal AA, Veremeienko V, Llansola-Portoles MJ, Gundermann K, van Grondelle R, Büchel C, and Robert B

Subjects

Spectrum Analysis, Raman, Chlorophyll metabolism, Chlorophyll chemistry, Light, Diatoms metabolism, Diatoms chemistry, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Xanthophylls chemistry, Xanthophylls metabolism

Abstract

In high light, the antenna system in oxygenic photosynthetic organisms switches to a photoprotective mode, dissipating excess energy in a process called non-photochemical quenching (NPQ). Diatoms exhibit very efficient NPQ, accompanied by a xanthophyll cycle in which diadinoxanthin is de-epoxidized into diatoxanthin. Diatoms accumulate pigments from this cycle in high light, and exhibit faster and more pronounced NPQ. The mechanisms underlying NPQ in diatoms remain unclear, but it can be mimicked by aggregation of their isolated light-harvesting complexes, FCP (fucoxanthin chlorophyll-a/c protein). We assess this model system by resonance Raman measurements of two peripheral FCPs, trimeric FCPa and nonameric FCPb, isolated from high- and low-light-adapted cells (LL,HL). Quenching is associated with a reorganisation of these proteins, affecting the conformation of their bound carotenoids, and in a manner which is highly dependent on the protein considered. FCPa from LL diatoms exhibits significant changes in diadinoxanthin structure, together with a smaller conformational change of at least one fucoxanthin. For these LL-FCPa, quenching is associated with consecutive events, displaying distinct spectral signatures, and its amplitude correlates with the planarity of the diadinoxanthin structure. HL-FCPa aggregation is associated with a change in planarity of a 515-nm-absorbing fucoxanthin, and, to a lesser extent, of diadinoxanthin. Finally, in FCPb, a blue-absorbing fucoxanthin is primarily affected. FCPs thus possess a plastic structure, undergoing several conformational changes upon aggregation, dependent upon their precise composition and structure. NPQ in diatoms may therefore arise from a combination of structural changes, dependent on the environment the cells are adapted to., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

7. Structural basis for molecular assembly of fucoxanthin chlorophyll a / c -binding proteins in a diatom photosystem I supercomplex.

Author

Kato K, Nakajima Y, Xing J, Kumazawa M, Ogawa H, Shen JR, Ifuku K, and Nagao R

Subjects

Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes genetics, Protein Conformation, Models, Molecular, Protein Binding, Diatoms metabolism, Photosystem I Protein Complex metabolism, Photosystem I Protein Complex chemistry, Chlorophyll Binding Proteins metabolism, Chlorophyll Binding Proteins chemistry, Cryoelectron Microscopy

Abstract

Photosynthetic organisms exhibit remarkable diversity in their light-harvesting complexes (LHCs). LHCs are associated with photosystem I (PSI), forming a PSI-LHCI supercomplex. The number of LHCI subunits, along with their protein sequences and pigment compositions, has been found to differ greatly among the PSI-LHCI structures. However, the mechanisms by which LHCIs recognize their specific binding sites within the PSI core remain unclear. In this study, we determined the cryo-electron microscopy structure of a PSI supercomplex incorporating fucoxanthin chlorophyll a / c -binding proteins (FCPs), designated as PSI-FCPI, isolated from the diatom Thalassiosira pseudonana CCMP1335. Structural analysis of PSI-FCPI revealed five FCPI subunits associated with a PSI monomer; these subunits were identified as RedCAP, Lhcr3, Lhcq10, Lhcf10, and Lhcq8. Through structural and sequence analyses, we identified specific protein-protein interactions at the interfaces between FCPI and PSI subunits, as well as among FCPI subunits themselves. Comparative structural analyses of PSI-FCPI supercomplexes, combined with phylogenetic analysis of FCPs from T. pseudonana and the diatom Chaetoceros gracilis , underscore the evolutionary conservation of protein motifs crucial for the selective binding of individual FCPI subunits. These findings provide significant insights into the molecular mechanisms underlying the assembly and selective binding of FCPIs in diatoms., Competing Interests: KK, YN, JX, MK, HO, JS, KI, RN No competing interests declared, (© 2024, Kato, Nakajima, Xing et al.)

Published

2024

8. Eustigmatophyte model of red-shifted chlorophyll a absorption in light-harvesting complexes.

Author

Agostini A, Bína D, Barcytė D, Bortolus M, Eliáš M, Carbonera D, and Litvín R

Subjects

Phylogeny, Electron Spin Resonance Spectroscopy, Chlorophyll metabolism, Light, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes genetics, Light-Harvesting Protein Complexes chemistry, Chlorophyll A metabolism, Chlorophyll A chemistry

Abstract

Photosynthetic organisms harvest light for energy. Some eukaryotic algae have specialized in harvesting far-red light by tuning chlorophyll a absorption through a mechanism still to be elucidated. Here, we combined optically detected magnetic resonance and pulsed electron paramagnetic resonance measurements on red-adapted light-harvesting complexes, rVCP, isolated from the freshwater eustigmatophyte alga Trachydiscus minutus to identify the location of the pigments responsible for this remarkable adaptation. The pigments have been found to belong to an excitonic cluster of chlorophylls a at the core of the complex, close to the central carotenoids in L1/L2 sites. A pair of structural features of the Chl a403/a603 binding site, namely the histidine-to-asparagine substitution in the magnesium-ligation residue and the small size of the amino acid at the i-4 position, resulting in a [A/G]xxxN motif, are proposed to be the origin of this trait. Phylogenetic analysis of various eukaryotic red antennae identified several potential LHCs that could share this tuning mechanism. This knowledge of the red light acclimation mechanism in algae is a step towards rational design of algal strains in order to enhance light capture and efficiency in large-scale biotechnology applications., (© 2024. The Author(s).)

Published

2024

9. Biomimetic light-harvesting antennas via the self-assembly of chemically programmed chlorophylls.

Author

Matsubara S, Shoji S, and Tamiaki H

Subjects

Energy Transfer, Photosynthesis, Chlorophyll chemistry, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Biomimetic Materials chemistry

Abstract

The photosynthetic pigment "chlorophyll" possesses attractive photophysical properties, including efficient sunlight absorption, photoexcited energy transfer, and charge separation, which are advantageous for applications for photo- and electro-functional materials such as artificial photosynthesis and solar cells. However, these functions cannot be realized by individual chlorophyll molecules alone; rather, they are achieved by the formation of sophisticated supramolecules through the self-assembly of the pigments. Here, we present strategies for constructing and developing artificial light-harvesting systems by mimicking photosynthetic antenna complexes through the highly ordered supramolecular self-assembly of synthetic dyes, particularly chlorophyll derivatives.

Published

2024

10. The development and applications of multidimensional biomolecular spectroscopy illustrated by photosynthetic light harvesting.

Author

Fleming GR and Scholes GD

Subjects

Quantum Theory, Photosynthesis, Spectrum Analysis methods, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry

Abstract

The parallel and synergistic developments of atomic resolution structural information, new spectroscopic methods, their underpinning formalism, and the application of sophisticated theoretical methods have led to a step function change in our understanding of photosynthetic light harvesting, the process by which photosynthetic organisms collect solar energy and supply it to their reaction centers to initiate the chemistry of photosynthesis. The new spectroscopic methods, in particular multidimensional spectroscopies, have enabled a transition from recording rates of processes to focusing on mechanism. We discuss two ultrafast spectroscopies - two-dimensional electronic spectroscopy and two-dimensional electronic-vibrational spectroscopy - and illustrate their development through the lens of photosynthetic light harvesting. Both spectroscopies provide enhanced spectral resolution and, in different ways, reveal pathways of energy flow and coherent oscillations which relate to the quantum mechanical mixing of, for example, electronic excitations (excitons) and nuclear motions. The new types of information present in these spectra provoked the application of sophisticated quantum dynamical theories to describe the temporal evolution of the spectra and provide new questions for experimental investigation. While multidimensional spectroscopies have applications in many other areas of science, we feel that the investigation of photosynthetic light harvesting has had the largest influence on the development of spectroscopic and theoretical methods for the study of quantum dynamics in biology, hence the focus of this review. We conclude with key questions for the next decade of this review.

Published

2024

11. Architectures of photosynthetic RC-LH1 supercomplexes from Rhodobacter blasticus .

Author

Wang P, Christianson BM, Ugurlar D, Mao R, Zhang Y, Liu ZK, Zhang YY, Gardner AM, Gao J, Zhang YZ, and Liu LN

Subjects

Models, Molecular, Cryoelectron Microscopy, Bacterial Proteins metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Protein Multimerization, Protein Conformation, Photosynthetic Reaction Center Complex Proteins metabolism, Photosynthetic Reaction Center Complex Proteins chemistry, Kinetics, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Photosynthesis, Rhodobacter metabolism

Abstract

The reaction center-light-harvesting complex 1 (RC-LH1) plays an essential role in the primary reactions of bacterial photosynthesis. Here, we present high-resolution structures of native monomeric and dimeric RC-LH1 supercomplexes from Rhodobacter ( Rba. ) blasticus using cryo-electron microscopy. The RC-LH1 monomer is composed of an RC encircled by an open LH1 ring comprising 15 αβ heterodimers and a PufX transmembrane polypeptide. In the RC-LH1 dimer, two crossing PufX polypeptides mediate dimerization. Unlike Rhodabacter sphaeroides counterpart, Rba. blasticus RC-LH1 dimer has a less bent conformation, lacks the PufY subunit near the LH1 opening, and includes two extra LH1 αβ subunits, forming a more enclosed S-shaped LH1 ring. Spectroscopic assays reveal that these unique structural features are accompanied by changes in the kinetics of quinone/quinol trafficking between RC-LH1 and cytochrome bc 1 . Our findings reveal the assembly principles and structural variability of photosynthetic RC-LH1 supercomplexes, highlighting diverse strategies used by phototrophic bacteria to optimize light-harvesting and electron transfer in competitive environments.

Published

2024

12. Design principles for energy transfer in the photosystem II supercomplex from kinetic transition networks.

Author

Yang SJ, Wales DJ, Woods EJ, and Fleming GR

Subjects

Kinetics, Photosynthesis, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Photosystem II Protein Complex metabolism, Photosystem II Protein Complex chemistry, Energy Transfer, Monte Carlo Method

Abstract

Photosystem II (PSII) has the unique ability to perform water-splitting. With light-harvesting complexes, it forms the PSII supercomplex (PSII-SC) which is a functional unit that can perform efficient energy conversion, as well as photoprotection, allowing photosynthetic organisms to adapt to the naturally fluctuating sunlight intensity. Achieving these functions requires a collaborative energy transfer network between all subunits of the PSII-SC. In this work, we perform kinetic analyses and characterise the energy landscape of the PSII-SC with a structure-based energy transfer model. With first passage time analyses and kinetic Monte Carlo simulations, we are able to map out the overall energy transfer network. We also investigate how energy transfer pathways are affected when individual protein complexes are removed from the network, revealing the functional roles of the subunits of the PSII-SC. In addition, we provide a quantitative description of the flat energy landscape of the PSII-SC. We show that it is a unique landscape that produces multiple kinetically relevant pathways, corresponding to a high pathway entropy. These design principles are crucial for balancing efficient energy conversion and photoprotection., (© 2024. The Author(s).)

Published

2024

13. Discovery of Multiple Light-Harvesting States of the Photosynthetic Protein PE545.

Author

Norris AC, Oberg C, Spangler LC, Scholes GD, and Schlau-Cohen GS

Subjects

Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Photosynthesis, Protein Conformation, Cryptophyta chemistry, Cryptophyta metabolism, Light, Models, Molecular, Phycoerythrin chemistry, Phycoerythrin metabolism

Abstract

Cryptophytes are photosynthetic microalga that flourish in a remarkable diversity of natural environments by using pigment-containing proteins with absorption maxima tuned to each ecological niche. While this diversity in the absorption has been well established, the subsequent photophysics is highly sensitive to the local protein environment and so may exhibit similar variation. Thermal fluctuations of the protein conformation are expected to introduce photophysical heterogeneity of the pigments that may have evolved important functional properties in a manner similar to that of the absorption. However, such heterogeneity is averaged out in ensemble measurements and, therefore, has not yet been probed. Here, we report single-molecule measurements of phycoerythrin 545 (PE545), the prototypical cryptophyte antenna protein, in its native dimeric form. A conformational ensemble was resolved consisting of distinct photophysical states with different light-harvesting properties. Proteins that did not quench, partially quenched, or fully quenched absorbed light were observed. Light intensity increased the quenched-state population of the dimer, potentially as a mechanism to deal with the extreme light intensities found in aqueous environments. Cross-linking, which mimics local interactions, introduces this light-dependent functionality while also suppressing other conformational dynamics. The cellular organization can, therefore, actively modulate the protein conformation and dynamics, selecting for distinct levels of light harvesting. Thus, the complex conformational equilibrium provides an additional mechanism for cryptophytes and likely other photosynthetic organisms to optimize solar energy capture and conversion.

Published

2024

14. The structural basis for light harvesting in organisms producing phycobiliproteins.

Author

Bryant DA and Gisriel CJ

Subjects

Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Phycobilisomes metabolism, Cryptophyta metabolism, Cryptophyta genetics, Phycobiliproteins metabolism, Rhodophyta metabolism, Cyanobacteria metabolism

Abstract

Cyanobacteria, red algae, and cryptophytes produce 2 classes of proteins for light harvesting: water-soluble phycobiliproteins (PBP) and membrane-intrinsic proteins that bind chlorophylls (Chls) and carotenoids. In cyanobacteria, red algae, and glaucophytes, phycobilisomes (PBS) are complexes of brightly colored PBP and linker (assembly) proteins. To date, 6 structural classes of PBS have been described: hemiellipsoidal, block-shaped, hemidiscoidal, bundle-shaped, paddle-shaped, and far-red-light bicylindrical. Two additional antenna complexes containing single types of PBP have also been described. Since 2017, structures have been reported for examples of all of these complexes except bundle-shaped PBS by cryogenic electron microscopy. PBS range in size from about 4.6 to 18 mDa and can include ∼900 polypeptides and bind >2000 chromophores. Cyanobacteria additionally produce membrane-associated proteins of the PsbC/CP43 superfamily of Chl a/b/d-binding proteins, including the iron-stress protein IsiA and other paralogous Chl-binding proteins (CBP) that can form antenna complexes with Photosystem I (PSI) and/or Photosystem II (PSII). Red and cryptophyte algae also produce CBP associated with PSI but which belong to the Chl a/b-binding protein superfamily and which are unrelated to the CBP of cyanobacteria. This review describes recent progress in structure determination for PBS and the Chl proteins of cyanobacteria, red algae, and cryptophytan algae., Competing Interests: Conflict of Interest Statement. None declared., (© The Author(s) 2024. Published by Oxford University Press on behalf of American Society of Plant Biologists. All rights reserved. For commercial re-use, please contact reprints@oup.com for reprints and translation rights for reprints. All other permissions can be obtained through our RightsLink service via the Permissions link on the article page on our site—for further information please contact journals.permissions@oup.com.)

Published

2024

15. Development of artificial photosystems based on designed proteins for mechanistic insights into photosynthesis.

Author

Serrano GP, Echavarría CF, and Mejias SH

Subjects

Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Models, Molecular, Photosynthesis, Protein Engineering methods

Abstract

This review aims to provide an overview of the progress in protein-based artificial photosystem design and their potential to uncover the underlying principles governing light-harvesting in photosynthesis. While significant advances have been made in this area, a gap persists in reviewing these advances. This review provides a perspective of the field, pinpointing knowledge gaps and unresolved challenges that warrant further inquiry. In particular, it delves into the key considerations when designing photosystems based on the chromophore and protein scaffold characteristics, presents the established strategies for artificial photosystems engineering with their advantages and disadvantages, and underscores the recent breakthroughs in understanding the molecular mechanisms governing light-harvesting, charge separation, and the role of the protein motions in the chromophore's excited state relaxation. By disseminating this knowledge, this article provides a foundational resource for defining the field of bio-hybrid photosystems and aims to inspire the continued exploration of artificial photosystems using protein design., (© 2024 The Protein Society.)

Published

2024

16. Structural insights into the unusual core photocomplex from a triply extremophilic purple bacterium, Halorhodospira halochloris.

Author

Qi CH, Wang GL, Wang FF, Wang J, Wang XP, Zou MJ, Ma F, Madigan MT, Kimura Y, Wang-Otomo ZY, and Yu LJ

Subjects

Bacterial Proteins metabolism, Bacterial Proteins chemistry, Bacteriochlorophylls metabolism, Bacteriochlorophylls chemistry, Rhodospirillaceae metabolism, Cryoelectron Microscopy, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry

Abstract

Halorhodospira (Hlr.) halochloris is a triply extremophilic phototrophic purple sulfur bacterium, as it is thermophilic, alkaliphilic, and extremely halophilic. The light-harvesting-reaction center (LH1-RC) core complex of this bacterium displays an LH1-Q y transition at 1,016 nm, which is the lowest-energy wavelength absorption among all known phototrophs. Here we report the cryo-EM structure of the LH1-RC at 2.42 Å resolution. The LH1 complex forms a tricyclic ring structure composed of 16 αβγ-polypeptides and one αβ-heterodimer around the RC. From the cryo-EM density map, two previously unrecognized integral membrane proteins, referred to as protein G and protein Q, were identified. Both of these proteins are single transmembrane-spanning helices located between the LH1 ring and the RC L-subunit and are absent from the LH1-RC complexes of all other purple bacteria of which the structures have been determined so far. Besides bacteriochlorophyll b molecules (B1020) located on the periplasmic side of the Hlr. halochloris membrane, there are also two arrays of bacteriochlorophyll b molecules (B800 and B820) located on the cytoplasmic side. Only a single copy of a carotenoid (lycopene) was resolved in the Hlr. halochloris LH1-α3β3 and this was positioned within the complex. The potential quinone channel should be the space between the LH1-α3β3 that accommodates the single lycopene but does not contain a γ-polypeptide, B800 and B820. Our results provide a structural explanation for the unusual Q y red shift and carotenoid absorption in the Hlr. halochloris spectrum and reveal new insights into photosynthetic mechanisms employed by a species that thrives under the harshest conditions of any phototrophic microorganism known., (© 2024 The Authors. Journal of Integrative Plant Biology published by John Wiley & Sons Australia, Ltd on behalf of Institute of Botany, Chinese Academy of Sciences.)

Published

2024

17. Ultrafast kinetics of PSI-LHCI super-complex from the moss Physcomitrella patens.

Author

Liu D, Yan Q, Qin X, and Tian L

Subjects

Kinetics, Energy Transfer, Chlorophyll metabolism, Chlorophyll chemistry, Arabidopsis metabolism, Photosynthesis, Plant Proteins metabolism, Plant Proteins chemistry, Bryopsida metabolism, Photosystem I Protein Complex metabolism, Photosystem I Protein Complex chemistry, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry

Abstract

Photosystem I (PSI) is a large membrane photosynthetic complex that harvests sunlight and drives photosynthetic electron transport. In both green algae and higher plants, PSI's ultrafast energy transfer and charge separation kinetics have been characterized. In contrast, it is not yet clear in Physcomitrella patens, even though moss is one of the earliest land plants and represents a critical stage in plant evolution. Here, we measured the time-resolved fluorescence of purified Pp PSI-LHCI at both room temperature (RT) and 77 K. Compared to the PSI kinetics of Arabidopsis thaliana at RT, we found that although the overall trapping time of Pp PSI-LHCI is nearly identical, ∼46 ps, their lifetimes at different wavelength regions differ. Specifically, Pp PSI-LHCI is slower in energy trapping below 720 nm but faster beyond. The slow-down of energy transfer between bulk chlorophylls (Chls, <720 nm) in Pp PSI-LHCI is probably because of the larger spatial gap between the PSI core and LHCI belt, and the acceleration of trapping at longer wavelength is most likely due to the lack of low-energy red-shifted Chls (red Chls). Indeed, time-resolved fluorescence results at 77 K revealed only three types of red Chls of 702 nm, 712 nm, and 720 nm in Pp PSI-LHCI but failed to detect the red Chls of 735 nm that present in LHCI in higher plants. Finally, we briefly discussed the evolutionary adaptations of PSI-LHCI in the context of red Chls from green algae to mosses and to land plants., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024. Published by Elsevier B.V.)

Published

2025

18. Comparative thermo- and piezostability study of photosynthetic core complexes containing bacteriochlorophyll a or b.

Author

Rätsep M, Kangur L, Leiger K, Wang-Otomo ZY, and Freiberg A

Subjects

Temperature, Bacterial Proteins metabolism, Bacterial Proteins chemistry, Rhodospirillum rubrum metabolism, Bacteriochlorophyll A metabolism, Bacteriochlorophyll A chemistry, Bacteriochlorophylls metabolism, Bacteriochlorophylls chemistry, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Photosynthesis

Abstract

The resilience of biological systems to fluctuating environmental conditions is a crucial evolutionary advantage. In this study, we examine the thermo- and piezo-stability of the LH1-RC pigment-protein complex, the simplest photosynthetic unit, in three species of phototropic purple bacteria, each containing only this core complex. Among these species, Blastochloris viridis and Blastochloris tepida utilize bacteriochlorophyll b as the main light-harvesting pigment, while Rhodospirillum rubrum relies on bacteriochlorophyll a. Through spectroscopic analyses, we observed limited reversibility in the effects of temperature and pressure, likely due to the malleability of pigment binding sites within the light-harvesting LH1 complex. In terms of thermal robustness, LH1 complexes in a detergent environment progressively dissociate into dimeric (B820) and monomeric (B777) subunits. However, in the native membrane, degradation primarily occurs directly into B777 without the intermediate formation of B820. Interestingly, while high-pressure compression of core complexes from Blastochloris viridis and Blastochloris tepida caused significant changes in compressibility around 1.3 kbar and the formation of B777 and B820 subunits upon decompression, no such compressibility changes or pressure-induced dissociation were observed in Rhodospirillum rubrum complexes, even at pressures as high as 11 kbar. This study reveals significant differences in the piezo- and thermal properties of phototrophs containing either BChl a or BChl b, underscoring the critical role of structural factors in understanding the temperature- and pressure-induced denaturation phenomena in photosynthetic complexes. Rhodospirillum rubrum, in particular, stands out as one of the most thermodynamically stable systems among phototrophic microorganisms, capable of withstanding temperatures up to 70 °C and pressures exceeding 11 kbar., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2025

19. Structural and spectroscopic characterization of the peridinin-chlorophyll a-protein (PCP) complex from Heterocapsa pygmaea (HPPCP).

Author

Schulte T, Magdaong NCM, Di Valentin M, Agostini A, Tait CE, Niedzwiedzki DM, Carbonera D, and Hofmann E

Subjects

Energy Transfer, Protozoan Proteins chemistry, Protozoan Proteins metabolism, Chlorophyll chemistry, Chlorophyll metabolism, Crystallography, X-Ray, Chlorophyll A chemistry, Chlorophyll A metabolism, Protein Conformation, Models, Molecular, Dinoflagellida metabolism, Dinoflagellida chemistry, Carotenoids chemistry, Carotenoids metabolism, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism

Abstract

Light harvesting proteins are optimized to efficiently collect and transfer light energy for photosynthesis. In eukaryotic dinoflagellates these complexes utilize chlorophylls and a special carotenoid, peridinin, and arrange them for efficient excitation energy transfer. At the same time, the carotenoids protect the system by quenching harmful chlorophyll triplet states. Here we use advanced spectroscopic techniques and X-ray structure analysis to investigate excitation energy transfer processes in the major soluble antenna, the peridinin chlorophyll a protein (PCP) from the free living dinoflagellate Heterocapsa pygmaea. We determined the 3D-structure of this complex at high resolution (1.2 Å). For better comparison, we improved the reference structure of this protein from Amphidinium carterae to a resolution of 1.15 Å. We then used fs and ns time-resolved absorption spectroscopy to study the mechanisms of light harvesting, but also of the photoprotective quenching of the chlorophyll triplet state. The photoprotection site was further characterized by Electron Spin Echo Envelope Modulation (ESEEM) spectroscopy to yield information on water molecules involved in triplet-triplet energy transfer. Similar to other PCP complexes, excitation energy transfer from peridinin to chlorophyll is found to be very efficient, with transfer times in the range of 1.6-2.1 ps. One of the four carotenoids, the peridinin 614, is well positioned to quench the chlorophyll triplet state with high efficiency and transfer times in the range of tens of picoseconds. Our structural and dynamic data further support, that the intrinsic water molecule coordinating the chlorophyll Mg ion plays an essential role in photoprotection., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2025

20. Tuning by Hydrogen Bonding in Photosynthesis.

Author

Timpmann K, Rätsep M, Jalviste E, and Freiberg A

Subjects

Hydrogen Bonding, Rhodobacter sphaeroides metabolism, Photosynthesis, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism

Abstract

Hydrogen bonding plays a crucial role in stabilizing proteins throughout their folding process. In photosynthetic light-harvesting chromoproteins, enriched with pigment chromophores, hydrogen bonds also fine-tune optical absorption to align with the solar irradiation spectrum. Despite its significance for photosynthesis, the precise mechanism of spectral tuning through hydrogen bonding remains inadequately understood. This study investigates wild-type and genetically engineered LH2 and LH1 light-harvesting complexes from Rhodobacter sphaeroides using a unique set of advanced spectroscopic techniques combined with simple exciton modeling. Our findings reveal an intricate interplay between exciton and site energy shift mechanisms, challenging the prevailing belief that spectral changes observed in these complexes upon the modification of tertiary structure hydrogen bonds almost directly follow shifting site energies. These deeper insights into natural adaptation processes hold great promise for advancing sustainable solar energy conversion technologies.

Published

2024

21. Controlling Vibronic Coupling in Chlorophyll Proteins: The Effects of Excitonic Delocalization and Vibrational Localization.

Author

Grechishnikova G, Wat JH, de Cordoba N, Miyake E, Phadkule A, Srivastava A, Savikhin S, Slipchenko L, Huang L, and Reppert M

Subjects

Energy Transfer, Spectrometry, Fluorescence, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Vibration, Chlorophyll chemistry

Abstract

Vibrational-electronic (vibronic) coupling plays a critical role in excitation energy transfer in molecular aggregates and pigment-protein complexes (PPCs). But the interplay between excitonic delocalization and vibronic interactions is complex, often leaving even qualitative questions as to what conceptual framework (e.g., Redfield versus Förster theory) should be used to interpret experimental results. To shed light on this issue, we report here on the interplay between excitonic delocalization and vibronic coupling in site-directed mutants of the water-soluble chlorophyll protein (WSCP), as reflected in 77 K fluorescence spectra. Experimentally, we find that in PPCs where excitonic delocalization is disrupted (either by mutagenesis or heterodimer formation), the relative intensity of the vibrational sideband (VSB) in fluorescence spectra is suppressed by up to 37% compared to that of the native protein. Numerical simulations reveal that this effect results from the localization of high-frequency vibrations in the coupled system; while excitonic delocalization suppresses the purely electronic transition due to H-aggregate-like dipole-dipole interference, high-frequency vibrations are unaffected, leading to a relative enhancement of the VSB. By comparing VSB intensities of PPCs both in the presence and absence of excitonic delocalization, we extract a set of "local" Huang-Rhys (HR) factors for Chl a in WSCP. More generally, our results suggest a significant role for geometric effects in controlling energy-transfer rates (which depend sensitively on absorption/fluorescence line shapes) in molecular aggregates and PPCs.

Published

2024

22. Light harvesting in purple bacteria does not rely on resonance fine-tuning in peripheral antenna complexes.

Author

Keil E, Lokstein H, Cogdell R, Hauer J, Zigmantas D, and Thyrhaug E

Subjects

Bacterial Proteins metabolism, Bacterial Proteins chemistry, Rhodopseudomonas metabolism, Energy Transfer, Light, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry

Abstract

The ring-like peripheral light-harvesting complex 2 (LH2) expressed by many phototrophic purple bacteria is a popular model system in biological light-harvesting research due to its robustness, small size, and known crystal structure. Furthermore, the availability of structural variants with distinct electronic structures and optical properties has made this group of light harvesters an attractive testing ground for studies of structure-function relationships in biological systems. LH2 is one of several pigment-protein complexes for which a link between functionality and effects such as excitonic coherence and vibronic coupling has been proposed. While a direct connection has not yet been demonstrated, many such interactions are highly sensitive to resonance conditions, and a dependence of intra-complex dynamics on detailed electronic structure might be expected. To gauge the sensitivity of energy-level structure and relaxation dynamics to naturally occurring structural changes, we compare the photo-induced dynamics in two structurally distinct LH2 variants. Using polarization-controlled 2D electronic spectroscopy at cryogenic temperatures, we directly access information on dynamic and static disorder in the complexes. The simultaneous optimal spectral and temporal resolution of these experiments further allows us to characterize the ultrafast energy relaxation, including exciton transport within the complexes. Despite the variations in PPC molecular structure manifesting as clear differences in electronic structure and disorder, the energy-transport and-relaxation dynamics remain remarkably similar. This indicates that the light-harvesting functionality of purple bacteria within a single LH2 complex is highly robust to structural perturbations and likely does not rely on finely tuned electronic- or electron-vibrational resonance conditions., (© 2024. The Author(s).)

Published

2024

23. Structural basis for the distinct core-antenna assembly of cryptophyte photosystem II.

Author

Si L, Zhang S, Su X, and Li M

Subjects

Chlorophyll Binding Proteins metabolism, Chlorophyll Binding Proteins chemistry, Photosynthesis, Models, Molecular, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Photosystem II Protein Complex metabolism, Photosystem II Protein Complex chemistry, Cryptophyta metabolism

Abstract

Photosystem II (PSII) catalyzes the light-driven charge separation and water oxidation reactions of photosynthesis. Eukaryotic PSII core is usually associated with membrane-embedded light-harvesting antennae, which greatly increase the absorbance cross-section of the core. The peripheral antennae in different phototrophs vary considerably in protein composition and arrangement. Photosynthetic cryptophytes possess chlorophyll a/c binding proteins (CACs) that serve as their antennae. How these CACs assemble with the PSII core remains unclear. Here, we report the 2.57-Å resolution structure of cryptophyte PSII-CAC purified from cells at nitrogen-limited stationary growth phase. We show that each monomer of the PSII homodimer contains a core complex, six chlorophyll a/c binding proteins (CACs) and a previously unseen chlorophyll-binding protein (termed CAL-II). Six CACs are arranged as a double-layered arc-shaped non-parallel belt, and two such belts attach to the dimeric core from opposite sides. The CAL-II simultaneously interacts with a number of core subunits and five CACs. The distinct organization of CACs and the presence of CAL-II may play a critical role in stabilizing the dimeric PSII-CAC complex under stress conditions. Our study provides mechanistic insights into the assembly and function of the PSII-CAC complex as well as the possible adaptation of cryptophytes in response to environmental stresses., (© 2024. The Author(s).)

Published

2024

24. Simulation of the Pump-Probe Spectra and Excitation Energy Relaxation of the B850 Band of the LH2 Complex in Purple Bacteria.

Author

Huang C, Bai S, and Shi Q

Subjects

Proteobacteria chemistry, Proteobacteria metabolism, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Energy Transfer

Abstract

Ultrafast spectroscopic techniques have been vital in studying excitation energy transfer (EET) in photosynthetic light harvesting complexes. In this paper, we simulate the pump-probe spectra of the B850 band of the light harvesting complex 2 (LH2) of purple bacteria, by using the hierarchical equation of motion method and the optical response function approach. The ground state bleach, stimulated emission, and excited state absorption components of the pump-probe spectra are analyzed in detail. The laser pulse-induced population dynamics are also simulated to help understand the main features of the pump-probe spectra and the EET process. It is shown that the excitation energy relaxation is an ultrafast process with multiple time scales. The first 40 fs of the pump-probe spectra is dominated by the relaxation of the k = ±1 states to both the k = 0 and higher energy states. Dynamics on a longer time scale around 200 fs reflects the relaxation of higher energy states to the k = 0 state.

Published

2024

25. Contrasting packing modes for tubular assemblies in chlorosomes.

Author

Miloslavina YA, Thomas B, Reus M, Gupta KBSS, Oostergetel GT, Andreas LB, Holzwarth AR, and de Groot HJM

Subjects

Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Magnetic Resonance Spectroscopy, Models, Molecular, Chlorobi metabolism

Abstract

The largest light-harvesting antenna in nature, the chlorosome, is a heterogeneous helical BChl self-assembly that has evolved in green bacteria to harvest light for performing photosynthesis in low-light environments. Guided by NMR chemical shifts and distance constraints for Chlorobaculum tepidum wild-type chlorosomes, the two contrasting packing modes for syn-anti parallel stacks of BChl c to form polar 2D arrays, with dipole moments adding up, are explored. Layered assemblies were optimized using local orbital density functional and plane wave pseudopotential methods. The packing mode with the lowest energy contains syn-anti and anti-syn H-bonding between stacks. It can accommodate R and S epimers, and side chain variability. For this packing, a match with the available EM data on the subunit axial repeat and optical data is obtained with multiple concentric cylinders for a rolling vector with the stacks running at an angle of 21° to the cylinder axis and with the BChl dipole moments running at an angle ß ∼ 55° to the tube axis, in accordance with optical data. A packing mode involving alternating syn and anti parallel stacks that is at variance with EM appears higher in energy. A weak cross-peak at -6 ppm in the MAS NMR with 50 kHz spinning, assigned to C-18 1 , matches the shift of antiparallel dimers, which possibly reflects a minor impurity-type fraction in the self-assembled BChl c., (© 2024. The Author(s).)

Published

2024

26. Spectral and conformational characteristics of phycocyanin associated with changes of medium pH.

Author

Parshina EY, Liu W, Yusipovich AI, Gvozdev DA, He Y, Pirutin SK, Klimanova EA, Maksimov EG, and Maksimov GV

Subjects

Hydrogen-Ion Concentration, Fluorescence Polarization, Spectrum Analysis, Raman, Spectrophotometry, Infrared, Protein Structure, Secondary, Protein Folding, Phycocyanin chemistry, Light-Harvesting Protein Complexes chemistry, Spirulina enzymology, Bacterial Proteins chemistry

Abstract

C-phycocyanin (C-PC) is the main component of water-soluble light-harvesting complexes (phycobilisomes, PBS) of cyanobacteria. PBS are involved in the absorption of quantum energy and the transfer of electronic excitation energy to the photosystems. A specific environment of C-PC chromophoric groups is provided by the protein matrix structure including protein-protein contacts between different subunits. Registration of C-PC spectral characteristics and the fluorescence anisotropy decay have revealed a significant pH influence on the chromophore microenvironment: at pH 5.0, a chromophore is more significantly interacts with the solvent, whereas at pH 9.0 the chromophore microenvironment becomes more viscous. Conformations of chromophores and the C-PC protein matrix have been studied by Raman and infrared spectroscopy. A decrease in the medium pH results in changes in the secondary structure either the C-PC apoproteins and chromophores, the last one adopts a more folded conformation., (© 2024. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2024

27. Molecular structure and characterization of the Thermochromatium tepidum light-harvesting 1 photocomplex produced in a foreign host.

Author

Yan YH, Wang GL, Yue XY, Ma F, Madigan MT, Wang-Otomo ZY, Zou MJ, and Yu LJ

Subjects

Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins genetics, Rhodospirillum rubrum genetics, Rhodospirillum rubrum metabolism, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes genetics, Chromatiaceae metabolism, Chromatiaceae genetics

Abstract

Purple phototrophic bacteria possess light-harvesting 1 and reaction center (LH1-RC) core complexes that play a key role in converting solar energy to chemical energy. High-resolution structures of LH1-RC and RC complexes have been intensively studied and have yielded critical insight into the architecture and interactions of their proteins, pigments, and cofactors. Nevertheless, a detailed picture of the structure and assembly of LH1-only complexes is lacking due to the intimate association between LH1 and the RC. To study the intrinsic properties and structure of an LH1-only complex, a genetic system was constructed to express the Thermochromatium (Tch.) tepidum LH1 complex heterologously in a modified Rhodospirillum rubrum mutant strain. The heterologously expressed Tch. tepidum LH1 complex was isolated in a pure form free of the RC and exhibited the characteristic absorption properties of Tch. tepidum. Cryo-EM structures of the LH1-only complexes revealed a closed circular ring consisting of either 14 or 15 αβ-subunits, making it the smallest completely closed LH1 complex discovered thus far. Surprisingly, the Tch. tepidum LH1-only complex displayed even higher thermostability than that of the native LH1-RC complex. These results reveal previously unsuspected plasticity of the LH1 complex, provide new insights into the structure and assembly of the LH1-RC complex, and show how molecular genetics can be exploited to study membrane proteins from phototrophic organisms whose genetic manipulation is not yet possible., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024. Published by Elsevier B.V.)

Published

2024

28. Structure of the red-shifted Fittonia albivenis photosystem I.

Author

Li X, Huang G, Zhu L, Hao C, Sui SF, and Qin X

Subjects

Amino Acid Sequence, Chlorophyll metabolism, Chlorophyll chemistry, Light, Models, Molecular, Plant Proteins metabolism, Plant Proteins chemistry, Acanthaceae, Cryoelectron Microscopy, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Photosystem I Protein Complex chemistry, Photosystem I Protein Complex metabolism, Photosystem I Protein Complex ultrastructure

Abstract

Photosystem I (PSI) from Fittonia albivenis, an Acanthaceae ornamental plant, is notable among green plants for its red-shifted emission spectrum. Here, we solved the structure of a PSI-light harvesting complex I (LHCI) supercomplex from F. albivenis at 2.46-Å resolution using cryo-electron microscopy. The supercomplex contains a core complex of 14 subunits and an LHCI belt with four antenna subunits (Lhca1-4) similar to previously reported angiosperm PSI-LHCI structures; however, Lhca3 differs in three regions surrounding a dimer of low-energy chlorophylls (Chls) termed red Chls, which absorb far-red beyond visible light. The unique amino acid sequences within these regions are exclusively shared by plants with strongly red-shifted fluorescence emission, suggesting candidate structural elements for regulating the energy state of red Chls. These results provide a structural basis for unraveling the mechanisms of light harvest and transfer in PSI-LHCI of under canopy plants and for designing Lhc to harness longer-wavelength light in the far-red spectral range., (© 2024. The Author(s).)

Published

2024

29. Single-Molecule Detection of the Encounter and Productive Electron Transfer Complexes of a Photosynthetic Reaction Center.

Author

Vasilev C, Nguyen J, Bowie AGM, Mayneord GE, Martin EC, Hitchcock A, Pogorelov TV, Singharoy A, Hunter CN, and Johnson MP

Subjects

Electron Transport, Photosynthetic Reaction Center Complex Proteins chemistry, Photosynthetic Reaction Center Complex Proteins metabolism, Cytochromes c2 chemistry, Cytochromes c2 metabolism, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Rhodobacter sphaeroides metabolism

Abstract

Small, diffusible redox proteins play an essential role in electron transfer (ET) in respiration and photosynthesis, sustaining life on Earth by shuttling electrons between membrane-bound complexes via finely tuned and reversible interactions. Ensemble kinetic studies show transient ET complexes form in two distinct stages: an "encounter" complex largely mediated by electrostatic interactions, which subsequently, through subtle reorganization of the binding interface, forms a "productive" ET complex stabilized by additional hydrophobic interactions around the redox-active cofactors. Here, using single-molecule force spectroscopy (SMFS) we dissected the transient ET complexes formed between the photosynthetic reaction center-light harvesting complex 1 (RC-LH1) of Rhodobacter sphaeroides and its native electron donor cytochrome c 2 (cyt c 2 ). Importantly, SMFS resolves the distribution of interaction forces into low (∼150 pN) and high (∼330 pN) components, with the former more susceptible to salt concentration and to alteration of key charged residues on the RC. Thus, the low force component is suggested to reflect the contribution of electrostatic interactions in forming the initial encounter complex, whereas the high force component reflects the additional stabilization provided by hydrophobic interactions to the productive ET complex. Employing molecular dynamics simulations, we resolve five intermediate states that comprise the encounter, productive ET and leaving complexes, predicting a weak interaction between cyt c 2 and the LH1 ring near the RC-L subunit that could lie along the exit path for oxidized cyt c 2 . The multimodal nature of the interactions of ET complexes captured here may have wider implications for ET in all domains of life.

Published

2024

30. Martini 3 Coarse-Grained Model for the Cofactors Involved in Photosynthesis.

Author

Chiariello MG, Zarmiento-Garcia R, and Marrink SJ

Subjects

Chlorophyll metabolism, Chlorophyll chemistry, Thermodynamics, beta Carotene chemistry, beta Carotene metabolism, Lipid Bilayers chemistry, Lipid Bilayers metabolism, Heme chemistry, Heme metabolism, Chlorophyll A chemistry, Chlorophyll A metabolism, Photosynthesis, Photosystem II Protein Complex metabolism, Photosystem II Protein Complex chemistry, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Molecular Dynamics Simulation

Abstract

As a critical step in advancing the simulation of photosynthetic complexes, we present the Martini 3 coarse-grained (CG) models of key cofactors associated with light harvesting (LHCII) proteins and the photosystem II (PSII) core complex. Our work focuses on the parametrization of beta-carotene, plastoquinone/quinol, violaxanthin, lutein, neoxanthin, chlorophyll A, chlorophyll B, and heme. We derived the CG parameters to match the all-atom reference simulations, while structural and thermodynamic properties of the cofactors were compared to experimental values when available. To further assess the reliability of the parameterization, we tested the behavior of these cofactors within their physiological environments, specifically in a lipid bilayer and bound to photosynthetic complexes. The results demonstrate that our CG models maintain the essential features required for realistic simulations. This work lays the groundwork for detailed simulations of the PSII-LHCII super-complex, providing a robust parameter set for future studies.

Published

2024

31. Sulfoquinovosyl diacylglycerol is required for dimerisation of the Rhodobacter sphaeroides reaction centre-light harvesting 1 core complex.

Author

Martin EC, Bowie AGM, Wellfare Reid T, Neil Hunter C, Hitchcock A, and Swainsbury DJK

Subjects

Glycolipids metabolism, Glycolipids chemistry, Models, Molecular, Crystallography, X-Ray, Rhodobacter sphaeroides metabolism, Rhodobacter sphaeroides genetics, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes genetics, Bacterial Proteins metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Protein Multimerization

Abstract

The reaction centre-light harvesting 1 (RC-LH1) core complex is indispensable for anoxygenic photosynthesis. In the purple bacterium Rhodobacter (Rba.) sphaeroides RC-LH1 is produced both as a monomer, in which 14 LH1 subunits form a C-shaped antenna around 1 RC, and as a dimer, where 28 LH1 subunits form an S-shaped antenna surrounding 2 RCs. Alongside the five RC and LH1 subunits, an additional polypeptide known as PufX provides an interface for dimerisation and also prevents LH1 ring closure, introducing a channel for quinone exchange that is essential for photoheterotrophic growth. Structures of Rba. sphaeroides RC-LH1 complexes revealed several new components; protein-Y, which helps to form the quinone channel; protein-Z, of unknown function and seemingly unique to dimers; and a tightly bound sulfoquinovosyl diacylglycerol (SQDG) lipid that interacts with two PufX arginine residues. This lipid lies at the dimer interface alongside weak density for a second molecule, previously proposed to be an ornithine lipid. In this work we have generated strains of Rba. sphaeroides lacking protein-Y, protein-Z, SQDG or ornithine lipids to assess the roles of these previously unknown components in the assembly and activity of RC-LH1. We show that whilst the removal of either protein-Y, protein-Z or ornithine lipids has only subtle effects, SQDG is essential for the formation of RC-LH1 dimers but its absence has no functional effect on the monomeric complex., (© 2024 The Author(s).)

Published

2024

32. Rhodopsin-based light-harvesting system for sustainable synthetic biology.

Author

Tu W, Saeed H, and Huang WE

Subjects

Light, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes genetics, Light-Harvesting Protein Complexes chemistry, Rhodopsin metabolism, Rhodopsin chemistry, Rhodopsin genetics, Synthetic Biology methods

Abstract

Rhodopsins, a diverse class of light-sensitive proteins found in various life domains, have attracted considerable interest for their potential applications in sustainable synthetic biology. These proteins exhibit remarkable photochemical properties, undergoing conformational changes upon light absorption that drive a variety of biological processes. Exploiting rhodopsin's natural properties could pave the way for creating sustainable and energy-efficient technologies. Rhodopsin-based light-harvesting systems offer innovative solutions to a few key challenges in sustainable engineering, from bioproduction to renewable energy conversion. In this opinion article, we explore the recent advancements and future possibilities of employing rhodopsins for sustainable engineering, underscoring the transformative potential of these biomolecules., (© 2024 The Author(s). Microbial Biotechnology published by John Wiley & Sons Ltd.)

Published

2024

33. Structural Diversity in Eukaryotic Photosynthetic Light Harvesting.

Author

Iwai M, Patel-Tupper D, and Niyogi KK

Subjects

Eukaryota metabolism, Cryoelectron Microscopy, Photosynthesis, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes ultrastructure

Abstract

Photosynthesis has been using energy from sunlight to assimilate atmospheric CO 2 for at least 3.5 billion years. Through evolution and natural selection, photosynthetic organisms have flourished in almost all aquatic and terrestrial environments. This is partly due to the diversity of light-harvesting complex (LHC) proteins, which facilitate photosystem assembly, efficient excitation energy transfer, and photoprotection. Structural advances have provided angstrom-level structures of many of these proteins and have expanded our understanding of the pigments, lipids, and residues that drive LHC function. In this review, we compare and contrast recently observed cryo-electron microscopy structures across photosynthetic eukaryotes to identify structural motifs that underlie various light-harvesting strategies. We discuss subtle monomer changes that result in macroscale reorganization of LHC oligomers. Additionally, we find recurring patterns across diverse LHCs that may serve as evolutionary stepping stones for functional diversification. Advancing our understanding of LHC protein-environment interactions will improve our capacity to engineer more productive crops.

Published

2024

34. De novo design of proteins housing excitonically coupled chlorophyll special pairs.

Author

Ennist NM, Wang S, Kennedy MA, Curti M, Sutherland GA, Vasilev C, Redler RL, Maffeis V, Shareef S, Sica AV, Hua AS, Deshmukh AP, Moyer AP, Hicks DR, Swartz AZ, Cacho RA, Novy N, Bera AK, Kang A, Sankaran B, Johnson MP, Phadkule A, Reppert M, Ekiert D, Bhabha G, Stewart L, Caram JR, Stoddard BL, Romero E, Hunter CN, and Baker D

Subjects

Crystallography, X-Ray, Models, Molecular, Photosynthesis, Energy Transfer, Cryoelectron Microscopy, Protein Conformation, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Chlorophyll chemistry, Chlorophyll metabolism

Abstract

Natural photosystems couple light harvesting to charge separation using a 'special pair' of chlorophyll molecules that accepts excitation energy from the antenna and initiates an electron-transfer cascade. To investigate the photophysics of special pairs independently of the complexities of native photosynthetic proteins, and as a first step toward creating synthetic photosystems for new energy conversion technologies, we designed C 2 -symmetric proteins that hold two chlorophyll molecules in closely juxtaposed arrangements. X-ray crystallography confirmed that one designed protein binds two chlorophylls in the same orientation as native special pairs, whereas a second designed protein positions them in a previously unseen geometry. Spectroscopy revealed that the chlorophylls are excitonically coupled, and fluorescence lifetime imaging demonstrated energy transfer. The cryo-electron microscopy structure of a designed 24-chlorophyll octahedral nanocage with a special pair on each edge closely matched the design model. The results suggest that the de novo design of artificial photosynthetic systems is within reach of current computational methods., (© 2024. The Author(s).)

Published

2024

35. Probing the Effect of Mutations on Light Harvesting in CP29 by Transient Absorption and First-Principles Simulations.

Author

Saraceno P, Sardar S, Caferri R, Camargo FVA, Dall'Osto L, D'Andrea C, Bassi R, Cupellini L, Cerullo G, and Mennucci B

Subjects

Kinetics, Arabidopsis chemistry, Arabidopsis genetics, Arabidopsis metabolism, Photosystem II Protein Complex, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes genetics, Mutation, Energy Transfer

Abstract

Natural light harvesting is exceptionally efficient thanks to the local energy funnel created within light-harvesting complexes (LHCs). To understand the design principles underlying energy transport in LHCs, ultrafast spectroscopy is often complemented by mutational studies that introduce perturbations into the excitonic structure of the natural complexes. However, such studies may fall short of identifying all excitation energy transfer (EET) pathways and their changes upon mutation. Here, we show that a synergistic combination of first-principles calculations and ultrafast spectroscopy can give unprecedented insight into the EET pathways occurring within LHCs. We measured the transient absorption spectra of the minor CP29 complex of plants and of two mutants, systematically mapping the kinetic components seen in experiments to the simulated exciton dynamics. With our combined strategy, we show that EET in CP29 is surprisingly robust to the changes in the exciton states induced by mutations, explaining the versatility of plant LHCs.

Published

2024

36. Structure of cryptophyte photosystem II-light-harvesting antennae supercomplex.

Author

Zhang YZ, Li K, Qin BY, Guo JP, Zhang QB, Zhao DL, Chen XL, Gao J, Liu LN, and Zhao LS

Subjects

Photosynthesis, Models, Molecular, Energy Transfer, Photosystem I Protein Complex metabolism, Photosystem I Protein Complex chemistry, Chlorophyll A metabolism, Chlorophyll A chemistry, Photosystem II Protein Complex metabolism, Photosystem II Protein Complex chemistry, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Cryptophyta metabolism, Cryoelectron Microscopy

Abstract

Cryptophytes are ancestral photosynthetic organisms evolved from red algae through secondary endosymbiosis. They have developed alloxanthin-chlorophyll a/c2-binding proteins (ACPs) as light-harvesting complexes (LHCs). The distinctive properties of cryptophytes contribute to efficient oxygenic photosynthesis and underscore the evolutionary relationships of red-lineage plastids. Here we present the cryo-electron microscopy structure of the Photosystem II (PSII)-ACPII supercomplex from the cryptophyte Chroomonas placoidea. The structure includes a PSII dimer and twelve ACPII monomers forming four linear trimers. These trimers structurally resemble red algae LHCs and cryptophyte ACPI trimers that associate with Photosystem I (PSI), suggesting their close evolutionary links. We also determine a Chl a-binding subunit, Psb-γ, essential for stabilizing PSII-ACPII association. Furthermore, computational calculation provides insights into the excitation energy transfer pathways. Our study lays a solid structural foundation for understanding the light-energy capture and transfer in cryptophyte PSII-ACPII, evolutionary variations in PSII-LHCII, and the origin of red-lineage LHCIIs., (© 2024. The Author(s).)

Published

2024

37. An integrated approach towards extracting structural characteristics of chlorosomes from a bchQ mutant of Chlorobaculum tepidum .

Author

Dsouza L, Li X, Erić V, Huijser A, Jansen TLC, Holzwarth AR, Buda F, Bryant DA, Bahri S, Gupta KBSS, Sevink GJA, and de Groot HJM

Subjects

Mutation, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes genetics, Cryoelectron Microscopy, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Chlorobi genetics, Chlorobi metabolism, Bacteriochlorophylls chemistry

Abstract

Chlorosomes, the photosynthetic antenna complexes of green sulfur bacteria, are paradigms for light-harvesting elements in artificial designs, owing to their efficient energy transfer without protein participation. We combined magic angle spinning (MAS) NMR, optical spectroscopy and cryogenic electron microscopy (cryo-EM) to characterize the structure of chlorosomes from a bchQ mutant of Chlorobaculum tepidum . The chlorosomes of this mutant have a more uniform composition of bacteriochlorophyll (BChl) with a predominant homolog, [8Ethyl, 12Ethyl] BChl c , compared to the wild type (WT). Nearly complete 13 C chemical shift assignments were obtained from well-resolved homonuclear 13 C- 13 C RFDR data. For proton assignments heteronuclear 13 C- 1 H (hCH) data sets were collected at 1.2 GHz spinning at 60 kHz. The CHHC experiments revealed intermolecular correlations between 13 2 /3 1 , 13 2 /3 2 , and 12 1 /3 1 , with distance constraints of less than 5 Å. These constraints indicate the syn - anti parallel stacking motif for the aggregates. Fourier transform cryo-EM data reveal an axial repeat of 1.49 nm for the helical tubular aggregates, perpendicular to the inter-tube separation of 2.1 nm. This axial repeat is different from WT and is in line with BChl syn - anti stacks running essentially parallel to the tube axis. Such a packing mode is in agreement with the signature of the Q y band in circular dichroism (CD). Combining the experimental data with computational insight suggests that the packing for the light-harvesting function is similar between WT and bchQ , while the chirality within the chlorosomes is modestly but detectably affected by the reduced compositional heterogeneity in bchQ .

Published

2024

38. Ultrafast Energy Transfer in a Diatom Photosystem II Supercomplex.

Author

Akhtar P, Feng Y, Jana S, Wang W, Shen JR, Tan HS, and Lambrev PH

Subjects

Spectrometry, Fluorescence, Chlorophyll chemistry, Photosystem II Protein Complex chemistry, Photosystem II Protein Complex metabolism, Energy Transfer, Diatoms chemistry, Diatoms metabolism, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism

Abstract

The light-harvesting complexes (LHCs) of diatoms, specifically fucoxanthin-Chl a / c binding proteins (FCPs), exhibit structural and functional diversity, as highlighted by recent structural studies of photosystem II-FCP (PSII-FCPII) supercomplexes from different diatom species. The excitation dynamics of PSII-FCPII supercomplexes isolated from the diatom Thalassiosira pseudonana was explored using time-resolved fluorescence spectroscopy and two-dimensional electronic spectroscopy at room temperature and 77 K. Energy transfer between FCPII and PSII occurred remarkably fast (<5 ps), emphasizing the efficiency of FCPII as a light-harvesting antenna. The presence of long-wavelength chlorophylls may further help concentrate excitations in the core complex and increase the efficiency of light harvesting. Structure-based calculations reveal remarkably strong excitonic couplings between chlorophylls in the FCP antenna and between FCP and the PSII core antenna that are the basis for the rapid energy transfer.

Published

2024

39. Unveiling large charge transfer character of PSII in an iron-deficient cyanobacterial membrane: A Stark fluorescence spectroscopy study.

Author

Ara AM, D'Haene S, van Grondelle R, and Wahadoszamen M

Subjects

Cyanobacteria metabolism, Iron metabolism, Iron Deficiencies, Bacterial Proteins metabolism, Cell Membrane metabolism, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Spectrometry, Fluorescence methods, Photosystem II Protein Complex metabolism

Abstract

In this work, we applied Stark fluorescence spectroscopy to an iron-stressed cyanobacterial membrane to reveal key insights about the electronic structures and excited state dynamics of the two important pigment-protein complexes, IsiA and PSII, both of which prevail simultaneously within the membrane during iron deficiency and whose fluorescence spectra are highly overlapped and hence often hardly resolved by conventional fluorescence spectroscopy. Thanks to the ability of Stark fluorescence spectroscopy, the fluorescence signatures of the two complexes could be plausibly recognized and disentangled. The systematic analysis of the SF spectra, carried out by employing standard Liptay formalism with a realistic spectral deconvolution protocol, revealed that the IsiA in an intact membrane retains almost identical excited state electronic structures and dynamics as compared to the isolated IsiA we reported in our earlier study. Moreover, the analysis uncovered that the excited state of the PSII subunit of the intact membrane possesses a significantly large CT character. The observed notably large magnitude of the excited state CT character may signify the supplementary role of PSII in regulative energy dissipation during iron deficiency., (© 2024. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2024

40. The synergy between the PscC subunits for electron transfer to the P 840 special pair in Chlorobaculum tepidum.

Author

Lyratzakis A, Daskalakis V, Xie H, and Tsiotis G

Subjects

Electron Transport, Protein Subunits metabolism, Protein Subunits chemistry, Photosynthesis, Chlorophyll metabolism, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Chlorobi metabolism, Bacterial Proteins metabolism, Bacterial Proteins chemistry, Molecular Dynamics Simulation

Abstract

The primary photochemical reaction of photosynthesis in green sulfur bacteria occurs in the homodimer PscA core proteins by a special chlorophyll pair. The light induced excited state of the special pair producing P 840 + is rapidly reduced by electron transfer from one of the two PscC subunits. Molecular dynamics (MD) simulations are combined with bioinformatic tools herein to provide structural and dynamic insight into the complex between the two PscA core proteins and the two PscC subunits. The microscopic dynamic model involves extensive sampling at atomic resolution and at a cumulative time-scale of 22µs and reveals well defined protein-protein interactions. The membrane complex is composed of the two PscA and the two PscC subunits and macroscopic connections are revealed within a putative electron transfer pathway from the PscC subunit to the special pair P 840 located within the PscA subunits. Our results provide a structural basis for understanding the electron transport to the homodimer RC of the green sulfur bacteria. The MD based approach can provide the basis to further probe the PscA-PscC complex dynamics and observe electron transfer therein at the quantum level. Furthermore, the transmembrane helices of the different PscC subunits exert distinct dynamics in the complex., (© 2024. The Author(s).)

Published

2024

41. Protein Effects on the Excitation Energies and Exciton Dynamics of the CP24 Antenna Complex.

Author

Sarngadharan P, Holtkamp Y, and Kleinekathöfer U

Subjects

Energy Transfer, Chlorophyll A chemistry, Density Functional Theory, Spectrometry, Fluorescence, Molecular Dynamics Simulation, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Chlorophyll chemistry

Abstract

In this study, the site energy fluctuations, energy transfer dynamics, and some spectroscopic properties of the minor light-harvesting complex CP24 in a membrane environment were determined. For this purpose, a 3 μs-long classical molecular dynamics simulation was performed for the CP24 complex. Furthermore, using the density functional tight binding/molecular mechanics molecular dynamics (DFTB/MM MD) approach, we performed excited state calculations for the chlorophyll a and chlorophyll b molecules in the complex starting from five different positions of the MD trajectory. During the extended simulations, we observed variations in the site energies of the different sets as a result of the fluctuating protein environment. In particular, a water coordination to Chl-b 608 occurred only after about 1 μs in the simulations, demonstrating dynamic changes in the environment of this pigment. From the classical and the DFTB/MM MD simulations, spectral densities and the (time-dependent) Hamiltonian of the complex were determined. Based on these results, three independent strongly coupled chlorophyll clusters were revealed within the complex. In addition, absorption and fluorescence spectra were determined together with the exciton relaxation dynamics, which reasonably well agrees with experimental time scales.

Published

2024

42. Hydrophobic Mismatch in the Thylakoid Membrane Regulates Photosynthetic Light Harvesting.

Author

Wilson S, Clarke CD, Carbajal MA, Buccafusca R, Fleck RA, Daskalakis V, and Ruban AV

Subjects

Galactolipids metabolism, Galactolipids chemistry, Light, Thylakoids metabolism, Thylakoids chemistry, Hydrophobic and Hydrophilic Interactions, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Photosynthesis, Photosystem II Protein Complex metabolism, Photosystem II Protein Complex chemistry

Abstract

The ability to harvest light effectively in a changing environment is necessary to ensure efficient photosynthesis and crop growth. One mechanism, known as qE, protects photosystem II (PSII) and regulates electron transfer through the harmless dissipation of excess absorbed photons as heat. This process involves reversible clustering of the major light-harvesting complexes of PSII (LHCII) in the thylakoid membrane and relies upon the ΔpH gradient and the allosteric modulator protein PsbS. To date, the exact role of PsbS in the qE mechanism has remained elusive. Here, we show that PsbS induces hydrophobic mismatch in the thylakoid membrane through dynamic rearrangement of lipids around LHCII leading to observed membrane thinning. We found that upon illumination, the thylakoid membrane reversibly shrinks from around 4.3 to 3.2 nm, without PsbS, this response is eliminated. Furthermore, we show that the lipid digalactosyldiacylglycerol (DGDG) is repelled from the LHCII-PsbS complex due to an increase in both the p K a of lumenal residues and in the dipole moment of LHCII, which allows for further conformational change and clustering in the membrane. Our results suggest a mechanistic role for PsbS as a facilitator of a hydrophobic mismatch-mediated phase transition between LHCII-PsbS and its environment. This could act as the driving force to sort LHCII into photoprotective nanodomains in the thylakoid membrane. This work shows an example of the key role of the hydrophobic mismatch process in regulating membrane protein function in plants.

Published

2024

43. Structure and distinct supramolecular organization of a PSII-ACPII dimer from a cryptophyte alga Chroomonas placoidea.

Author

Mao Z, Li X, Li Z, Shen L, Li X, Yang Y, Wang W, Kuang T, Shen JR, and Han G

Subjects

Chlorophyll metabolism, Chlorophyll Binding Proteins metabolism, Chlorophyll Binding Proteins chemistry, Protein Multimerization, Chlorophyll A metabolism, Chlorophyll A chemistry, Models, Molecular, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Photosystem II Protein Complex metabolism, Photosystem II Protein Complex chemistry, Cryptophyta metabolism, Cryoelectron Microscopy

Abstract

Cryptophyte algae are an evolutionarily distinct and ecologically important group of photosynthetic unicellular eukaryotes. Photosystem II (PSII) of cryptophyte algae associates with alloxanthin chlorophyll a/c-binding proteins (ACPs) to act as the peripheral light-harvesting system, whose supramolecular organization is unknown. Here, we purify the PSII-ACPII supercomplex from a cryptophyte alga Chroomonas placoidea (C. placoidea), and analyze its structure at a resolution of 2.47 Å using cryo-electron microscopy. This structure reveals a dimeric organization of PSII-ACPII containing two PSII core monomers flanked by six symmetrically arranged ACPII subunits. The PSII core is conserved whereas the organization of ACPII subunits exhibits a distinct pattern, different from those observed so far in PSII of other algae and higher plants. Furthermore, we find a Chl a-binding antenna subunit, CCPII-S, which mediates interaction of ACPII with the PSII core. These results provide a structural basis for the assembly of antennas within the supercomplex and possible excitation energy transfer pathways in cryptophyte algal PSII, shedding light on the diversity of supramolecular organization of photosynthetic machinery., (© 2024. The Author(s).)

Published

2024

44. Ultrafast energy quenching mechanism of LHCSR3-dependent photoprotection in Chlamydomonas.

Author

Zheng M, Pang X, Chen M, and Tian L

Subjects

Thylakoids metabolism, Photosynthesis, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes genetics, Chlorophyll A metabolism, Chlorophyll A chemistry, Light, Kinetics, Chlorophyll metabolism, Chlamydomonas metabolism, Chlamydomonas reinhardtii metabolism, Energy Transfer, Carotenoids metabolism, Carotenoids chemistry

Abstract

Photosynthetic organisms have evolved an essential energy-dependent quenching (qE) mechanism to avoid any lethal damages caused by high light. While the triggering mechanism of qE has been well addressed, candidates for quenchers are often debated. This lack of understanding is because of the tremendous difficulty in measuring intact cells using transient absorption techniques. Here, we have conducted femtosecond pump-probe measurements to characterize this photophysical reaction using micro-sized cell fractions of the green alga Chlamydomonas reinhardtii that retain physiological qE function. Combined with kinetic modeling, we have demonstrated the presence of an ultrafast excitation energy transfer (EET) pathway from Chlorophyll a (Chl a) Q y to a carotenoid (car) S 1 state, therefore proposing that this carotenoid, likely lutein1, is the quencher. This work has provided an easy-to-prepare qE active thylakoid membrane system for advanced spectroscopic studies and demonstrated that the energy dissipation pathway of qE is evolutionarily conserved from green algae to land plants., (© 2024. The Author(s).)

Published

2024

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

Author

Kawato S, Sato S, Kitoh-Nishioka H, and Saga Y

Subjects

Hydrogen-Ion Concentration, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Temperature, Dimethylamines chemistry, Energy Transfer, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Bacteriochlorophyll A chemistry, Bacteriochlorophyll A metabolism

Abstract

Exchange of B800 bacteriochlorophyll (BChl) a in light-harvesting complex 2 (LH2) is promising for a better understanding of the mechanism on intracomplex excitation energy transfer of this protein. Structural and spectroscopic properties of LH2 lacking B800 BChl a (B800-depleted LH2), which is an important intermediate protein in the B800 exchange, will be useful to tackle the energy transfer mechanism in LH2 by the B800 exchange strategy. In this study, we report a unique spectral change of B800-depleted LH2, in which the Q y absorption band of B800 BChl a is automatically recovered under neutral pH conditions. This spectral change was facilitated by factors for destabilization of LH2, namely, a detergent, lauryl dimethylamine N-oxide, and an increase in temperature. Spectral analyses in the preparation of an LH2 variant denoted as B800-recovered LH2 indicated that most BChl a that was released by decomposition of part of B800-depleted LH2 was a source of the production of B800-recovered LH2. Characterization of purified B800-recovered LH2 demonstrated that its spectroscopic and structural features was quite similar to those of native LH2. The current results indicate that the recovery of the B800 Q y band of B800-depleted LH2 originates from the combination of decomposition of part of B800-depleted LH2 and in situ reconstitution of BChl a into the B800 binding pockets of residual B800-depleted LH2, resulting in the formation of stable B800-recovered LH2., (© 2024. The Author(s), under exclusive licence to European Photochemistry Association, European Society for Photobiology.)

Published

2024

46. Efficient two-step excitation energy transfer in artificial light-harvesting antenna based on bacteriochlorophyll aggregates.

Author

Malina T, Bína D, Collins AM, Alster J, and Pšenčík J

Subjects

beta Carotene, Light-Harvesting Protein Complexes chemistry, Bacterial Proteins metabolism, Energy Transfer, Photosynthesis, Bacteriochlorophylls chemistry, Bacteriochlorophyll A chemistry

Abstract

Chlorosomes of green photosynthetic bacteria are large light-harvesting complexes enabling these organisms to survive at extremely low-light conditions. Bacteriochlorophylls found in chlorosomes self-organize and are ideal candidates for use in biomimetic light-harvesting in artificial photosynthesis and other applications for solar energy utilization. Here we report on the construction and characterization of an artificial antenna consisting of bacteriochlorophyll c co-aggregated with β-carotene, which is used to extend the light-harvesting spectral range, and bacteriochlorophyll a, which acts as a final acceptor for excitation energy. Efficient energy transfer between all three components was observed by means of fluorescence spectroscopy. The efficiency varies with the β-carotene content, which increases the average distance between the donor and acceptor in both energy transfer steps. The efficiency ranges from 89 to 37% for the transfer from β-carotene to bacteriochlorophyll c, and from 93 to 69% for the bacteriochlorophyll c to bacteriochlorophyll a step. A significant part of this study was dedicated to a development of methods for determination of energy transfer efficiency. These methods may be applied also for study of chlorosomes and other pigment complexes., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2024

47. PigmentHunter: A point-and-click application for automated chlorophyll-protein simulations.

Author

Ahad S, Lin C, and Reppert M

Subjects

Circular Dichroism, Photosynthesis, Molecular Dynamics Simulation, Chlorophyll, Light-Harvesting Protein Complexes chemistry

Abstract

Chlorophyll proteins (CPs) are the workhorses of biological photosynthesis, working together to absorb solar energy, transfer it to chemically active reaction centers, and control the charge-separation process that drives its storage as chemical energy. Yet predicting CP optical and electronic properties remains a serious challenge, driven by the computational difficulty of treating large, electronically coupled molecular pigments embedded in a dynamically structured protein environment. To address this challenge, we introduce here an analysis tool called PigmentHunter, which automates the process of preparing CP structures for molecular dynamics (MD), running short MD simulations on the nanoHUB.org science gateway, and then using electrostatic and steric analysis routines to predict optical absorption, fluorescence, and circular dichroism spectra within a Frenkel exciton model. Inter-pigment couplings are evaluated using point-dipole or transition-charge coupling models, while site energies can be estimated using both electrostatic and ring-deformation approaches. The package is built in a Jupyter Notebook environment, with a point-and-click interface that can be used either to manually prepare individual structures or to batch-process many structures at once. We illustrate PigmentHunter's capabilities with example simulations on spectral line shapes in the light harvesting 2 complex, site energies in the Fenna-Matthews-Olson protein, and ring deformation in photosystems I and II., (© 2024 Author(s). Published under an exclusive license by AIP Publishing.)

Published

2024

48. Light-Quality-Adapted Carotenoid Photoprotection in the Photosystem of Roseiflexus castenholzii .

Author

Hao JF, Qi CH, Yu BY, Wang HY, Gao RY, Yamano N, Ma F, Wang P, Xin YY, Zhang CF, Yu LJ, and Zhang JP

Subjects

Carotenoids, Light-Harvesting Protein Complexes chemistry, Photosynthesis, Bacteriochlorophylls metabolism, Bacterial Proteins chemistry, Chloroflexi chemistry, Chloroflexi metabolism

Abstract

The photosystem of filamentous anoxygenic phototroph Roseiflexus ( Rfl .) castenholzii comprises a light-harvesting (LH) complex encircling a reaction center (RC), which intensely absorbs blue-green light by carotenoid (Car) and near-infrared light by bacteriochlorophyll (BChl). To explore the influence of light quality (color) on the photosynthetic activity, we compared the pigment compositions and triplet excitation dynamics of the LH-RCs from Rfl . castenholzii was adapted to blue-green light ( bg -LH-RC) and to near-infrared light ( nir -LH-RC). Both LH-RCs bind γ-carotene derivatives; however, compared to that of nir -LH-RC (12%), bg -LH-RC contains substantially higher keto-γ-carotene content (43%) and shows considerably faster BChl-to-Car triplet excitation transfer (10.9 ns vs 15.0 ns). For bg -LH-RC, but not nir -LH-RC, selective photoexcitation of Car and the 800 nm-absorbing BChl led to Car-to-Car triplet transfer and BChl-Car singlet fission reactions, respectively. The unique excitation dynamics of bg -LH-RC enhances its photoprotection, which is crucial for the survival of aquatic anoxygenic phototrophs from photooxidative stress.

Published

2024

49. Site-Directed Mutagenesis of the Chlorophyll-Binding Sites Modulates Excited-State Lifetime and Chlorophyll-Xanthophyll Energy Transfer in the Monomeric Light-Harvesting Complex CP29.

Author

Sardar S, Caferri R, Camargo FVA, Capaldi S, Ghezzi A, Dall'Osto L, D'Andrea C, Cerullo G, and Bassi R

Subjects

Light-Harvesting Protein Complexes chemistry, Photosystem II Protein Complex metabolism, Energy Transfer, Xanthophylls, Binding Sites, Mutagenesis, Site-Directed, Chlorophyll chemistry, Lutein

Abstract

We combine site-directed mutagenesis with picosecond time-resolved fluorescence and femtosecond transient absorption (TA) spectroscopies to identify excitation energy transfer (EET) processes between chlorophylls (Chls) and xanthophylls (Xant) in the minor antenna complex CP29 assembled inside nanodiscs, which result in quenching. When compared to WT CP29, a longer lifetime was observed in the A 2 mutant, missing Chl a612, which closely interacts with Xant Lutein in site L1. Conversely, a shorter lifetime was obtained in the A 5 mutant, in which the interaction between Chl a603 and Chl a609 is strengthened, shifting absorption to lower energy and enhancing Chl-Xant EET. Global analysis of TA data indicated that EET from Chl a Q y to a Car dark state S* is active in both the A 2 and A 5 mutants and that their rate constants are modulated by mutations. Our study provides experimental evidence that multiple Chl-Xant interactions are involved in the quenching activity of CP29.

Published

2024

50. Exciton interactions of chlorophyll tetramer in water-soluble chlorophyll-binding protein BoWSCP.

Author

Cherepanov DA, Milanovsky GE, Neverov KV, Obukhov YN, Maleeva YV, Aybush AV, Kritsky MS, and Nadtochenko VA

Subjects

Chlorophyll A, Water chemistry, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Chlorophyll chemistry, Carrier Proteins

Abstract

The exciton interaction of four chlorophyll a (Chl a) molecules in a symmetrical tetrameric complex of the water-soluble chlorophyll-binding protein BoWSCP was analyzed in the pH range of 3-11. Exciton splitting ΔE = 232 ± 2 cm -1 of the Q y band of Chl a into two subcomponents with relative intensities of 78.1 ± 0.7 % and 21.9 ± 0.7 % was determined by a joint decomposition of the absorption and circular dichroism spectra into Gaussian functions. The exciton coupling parameters were calculated based on the BoWSCP atomic structure in three approximations: the point dipole model, the distributed atomic monopoles, and direct ab initio calculations in the TDDFT/PCM approximation. The Coulomb interactions of monomers were calculated within the continuum model using three values of optical permittivity. The models based on the properties of free Chl a in solution suffer from significant errors both in estimating the absolute value of the exciton interaction and in the relative intensity of exciton transitions. Calculations within the TDDFT/PCM approximation reproduce the experimentally determined parameters of the exciton splitting and the relative intensities of the exciton bands. The following factors of pigment-protein and pigment-pigment interactions were examined: deviation of the macrocycle geometry from the planar conformation of free Chl; the formation of hydrogen bonds between the macrocycle and water molecules; the overlap of wave functions of monomers at close distances. The most significant factor is the geometrical deformation of the porphyrin macrocycle, which leads to an increase in the dipole moment of Chl monomer from 5.5 to 6.9 D and to a rotation of the dipole moment by 15° towards the cyclopentane ring. The contributions of resonant charge-transfer states to the wave functions of the Chl dimer were determined and the transition dipole moments of the symmetric and antisymmetric charge-transfer states were estimated., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2024