A pathway for protective quenching in antenna proteins of Photosystem II

Papadatos, Sotiris; Charalambous, Antreas C.; Daskalakis, Vangelis

doi:10.1038/s41598-017-02892-w

Cited by 24 publications

(35 citation statements)

References 86 publications

(139 reference statements)

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“…Nowadays, different LHC genes from plants, i.e., LHCII Balevičius et al 2017;Thallmair et al 2019), CP29 (Ioannidis et al 2016;Papadatos et al 2017) and PsbS Liguori et al 2019), have been simulated up to the μs timescale with atomistic resolution. Most of these works have focused in particular on characterizing how the interactions among the Chls and Cars bound to LHCs change depending on the different protein conformations sampled via MD (Liguori et al 1 3 2015; Balevičius et al 2017;López-Tarifa et al 2017;Maity et al 2019).…”

Section: (Sub)μs Timescale: Fast Conformational Changes Of the Photosmentioning

confidence: 99%

“…The protonation pattern was chosen to model either acidic or neutral conditions in the thylakoid lumen and was kept fixed during the whole simulation. As a result of protonation of luminal residues, a conformational change was detected at the level of helix D in both LHCII and CP29 and such change was found to be able to modify the energetics of a selected Chl dimer (Ioannidis et al 2016;Papadatos et al 2017). Because from in vitro as well as in vivo results, no spectral differences are expected to be induced directly by pH in CP29 (Crimi et al 2001) and LHCII (Tokutsu and Minagawa 2013;Dinc et al 2016;Liguori et al 2016), it could be possible that the actual pKa of CP29 and LHCII residues is too low to match the protonation pattern assigned in these simulations.…”

Section: (Sub)μs Timescale: Fast Conformational Changes Of the Photosmentioning

confidence: 99%

See 1 more Smart Citation

Molecular dynamics simulations in photosynthesis

Liguori¹,

Croce²,

Marrink

et al. 2020

Photosynth Res

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Photosynthesis is regulated by a dynamic interplay between proteins, enzymes, pigments, lipids, and cofactors that takes place on a large spatio-temporal scale. Molecular dynamics (MD) simulations provide a powerful toolkit to investigate dynamical processes in (bio)molecular ensembles from the (sub)picosecond to the (sub)millisecond regime and from the Å to hundreds of nm length scale. Therefore, MD is well suited to address a variety of questions arising in the field of photosynthesis research. In this review, we provide an introduction to the basic concepts of MD simulations, at atomistic and coarse-grained level of resolution. Furthermore, we discuss applications of MD simulations to model photosynthetic systems of different sizes and complexity and their connection to experimental observables. Finally, we provide a brief glance on which methods provide opportunities to capture phenomena beyond the applicability of classical MD.Publisher's Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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Section: (Sub)μs Timescale: Fast Conformational Changes Of the Photosmentioning

confidence: 99%

Section: (Sub)μs Timescale: Fast Conformational Changes Of the Photosmentioning

confidence: 99%

Molecular dynamics simulations in photosynthesis

Liguori¹,

Croce²,

Marrink

et al. 2020

Photosynth Res

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“…Energy quenching in LHCII is activated under high light, for instance during the operation of the xanthophyll cycle, which induces the pH-dependent de-epoxydation of violaxanthin into zeaxanthin and implicates xanthophyll molecules present in Lhcb complexes. However the precise mechanism involved in the quencher formation remains to be determined and so far the binding of zeaxanthin has been proposed to favor a conformational change of LHCII by inducing new chlorophyll-chlorophyll or xanthophyll-chlorophyll interactions that would open an energy dissipation channel [62][63][64]. This mechanism however seems to be common to multiple, if not all Lhcb sequences, as the pigment binding properties seem shared between complexes.…”

Section: Sequence Conservation and Divergence Clues For Regulation Mmentioning

confidence: 99%

Functions and Evolution of Lhcb Isoforms Composing LHCII, the Major Light Harvesting Complex of Photosystem II of Green Eukaryotic Organisms

Crepin

Caffarri

2018

CPPS

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Oxygenic photosynthesis provides energy and oxygen for almost all forms of life on earth. This process is based on the energy of photons, which is used to split water and use its electrons to reduce carbon atoms to create organic molecules and thus fix the light energy into a chemical form. Two photosytems working in series are involved in light harvesting and conversion. Both are multi-protein supercomplexes composed of a core complex, where the photochemical reaction takes place, and an antenna system involved in light harvesting. In plants and green algae, the antenna of photosystem II, the photosynthetic complex involved in water splitting, comprises the Light Harvesting Complex II (LHCII) trimers, the most abundant membrane protein on earth. LHCII is composed of highly conserved Lhcb isoforms and all green organisms count a high number of Lhcb. In vascular plants they are classified in three distinct subclasses, Lhcb1, 2 and 3, while in algae and non-vascular plants, these isoforms are less differentiated and called Lhcbm proteins. In this review, we compare LHCII proteins of different organisms, from green algae to angiosperms, and discuss the role of the modifications that occurred through evolution. We highlight the various functions of the different isoforms in photosynthesis, ranging from light harvesting, a common role to all these proteins, to regulations of photosynthesis that rely on specific isoforms.

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“…Still using classical MD, Croce and coworkers suggested that NPQ in LHCII is probably connected to some conformational changes in the system structure [134]. Finally, Papadatos et al used MD trajectories to asses the role of pH variation and of the xanthophyll cycle on the NPQ of LHCII [135,136]. To the best of our knowledge, NPQ in cyanobacteria, instead, has never been studied with atomistic computational techniques.…”

Section: From the Lh Function To Its Photoregulationmentioning

confidence: 99%

Successes & challenges in the atomistic modeling of light-harvesting and its photoregulation

Cupellini

Bondanza

Nottoli

et al. 2020

Biochimica et Biophysica Acta (BBA) - Bioenergetics

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Light-harvesting is a crucial step of photosynthesis. Its mechanisms and related energetics have been revealed by a combination of experimental investigations and theoretical modeling. The success of theoretical modeling is largely due to the application of atomistic descriptions combining quantum chemistry, classical models and molecular dynamics techniques. Besides the important achievements obtained so far, a complete and quantitative understanding of how the many different light-harvesting complexes exploit their structural specificity is still missing. Moreover, many questions remain unanswered regarding the mechanisms through which light-harvesting is regulated in response to variable light conditions. Here we show that, in both fields, a major role will be played once more by atomistic descriptions, possibly generalized to tackle the numerous time and space scales on which the regulation takes place: going from the ultrafast electronic excitation of the multichromophoric aggregate, through the subsequent conformational changes in the embedding protein, up to the interaction between proteins.

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A pathway for protective quenching in antenna proteins of Photosystem II

Cited by 24 publications

References 86 publications

Molecular dynamics simulations in photosynthesis

Molecular dynamics simulations in photosynthesis

Functions and Evolution of Lhcb Isoforms Composing LHCII, the Major Light Harvesting Complex of Photosystem II of Green Eukaryotic Organisms

Successes & challenges in the atomistic modeling of light-harvesting and its photoregulation

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