Your search keyword '"Bassi, Roberto"' showing total 77 results

1. Analysis of state 1-state 2 transitions by genome editing and complementation reveals a quenching component independent from the formation of PSI-LHCI-LHCII supercomplex in Arabidopsis thaliana.

Author

Cutolo EA, Caferri R, Guardini Z, Dall'Osto L, and Bassi R

Subjects

Gene Editing, Plastoquinone, Phosphorylation, Carbon, Arabidopsis genetics

Abstract

Background: The light-harvesting antennae of photosystem (PS) I and PSII are pigment-protein complexes responsible of the initial steps of sunlight conversion into chemical energy. In natural environments plants are constantly confronted with the variability of the photosynthetically active light spectrum. PSII and PSI operate in series but have different optimal excitation wavelengths. The prompt adjustment of light absorption by photosystems is thus crucial to ensure efficient electron flow needed to sustain downstream carbon fixing reactions. Fast structural rearrangements equilibrate the partition of excitation pressure between PSII and PSI following the enrichment in the red (PSII-favoring) or far-red (PSI-favoring) spectra. Redox imbalances trigger state transitions (ST), a photoacclimation mechanism which involves the reversible phosphorylation/dephosphorylation of light harvesting complex II (LHCII) proteins by the antagonistic activities of the State Transition 7 (STN7) kinase/TAP38 phosphatase enzyme pair. During ST, a mobile PSII antenna pool associates with PSI increasing its absorption cross section. LHCII consists of assorted trimeric assemblies of Lhcb1, Lhcb2 and Lhcb3 protein isoforms (LHCII), several being substrates of STN7. However, the precise roles of Lhcb phosphorylation during ST remain largely elusive., Results: We inactivated the complete Lhcb1 and Lhcb2 gene clades in Arabidopsis thaliana and reintroduced either wild type Lhcb1.3 and Lhcb2.1 isoforms, respectively, or versions lacking N-terminal phosphorylatable residues proposed to mediate state transitions. While the substitution of Lhcb2.1 Thr-40 prevented the formation of the PSI-LHCI-LHCII complex, replacement of Lhcb1.3 Thr-38 did not affect the formation of this supercomplex, nor did influence the amplitude or kinetics of PSII fluorescence quenching upon state 1-state 2 transition., Conclusions: Phosphorylation of Lhcb2 Thr-40 by STN7 alone accounts for ≈ 60% of PSII fluorescence quenching during state transitions. Instead, the presence of Thr-38 phosphosite in Lhcb1.3 was not required for the formation of the PSI-LHCI-LHCII supercomplex nor for re-equilibration of the plastoquinone redox state. The Lhcb2 phosphomutant was still capable of ≈ 40% residual fluorescence quenching, implying that a yet uncharacterized, STN7-dependent, component of state transitions, which is unrelated to Lhcb2 Thr-40 phosphorylation and to the formation of the PSI-LHCI-LHCII supercomplex, contributes to the equilibration of the PSI/PSII excitation pressure upon plastoquinone over-reduction., (© 2023. BioMed Central Ltd., part of Springer Nature.)

Published

2023

2. Loss of a single chlorophyll in CP29 triggers re-organization of the Photosystem II supramolecular assembly.

Author

Guardini Z, Gomez RL, Caferri R, Dall'Osto L, and Bassi R

Subjects

Chlorophyll A metabolism, Photosynthesis, Photosystem II Protein Complex metabolism, Arabidopsis genetics, Arabidopsis metabolism, Chlorophyll metabolism

Abstract

In land plants, both efficient light capture and photoprotective dissipation of chlorophyll excited states in excess require proper assembly of Photosystem II supercomplexes PSII-LHCs. These include a dimeric core moiety and a peripheral antenna system made of trimeric LHCII proteins connected to the core through monomeric LHC subunits. Regulation of light harvesting involves re-organization of the PSII supercomplex, including dissociation of its LHCII-CP24-CP29 domain under excess light. The Chl a603-a609-a616 chromophore cluster within CP29 was recently identified as responsible for the fast component of Non-Photochemical Quenching of chlorophyll fluorescence. Here, we pinpointed a chlorophyll-protein domain of CP29 involved in the macro-organization of PSII-LHCs. By complementing an Arabidopsis knock-out mutant with CP29 sequences deleted in the residue binding chlorophyll b614/b3-binding, we found that the site is promiscuous for chlorophyll a and b. By plotting NPQ amplitude vs. CP29 content we observed that quenching activity was significantly reduced in mutants compared to the wild type. Analysis of pigment-binding supercomplexes showed that the missing Chl did hamper the assembly of PSII-LHCs supercomplexes, while observation by electron microscopy of grana membranes highlighted the PSII particles were organized in two-dimensional arrays in mutant grana partitions. As an effect of such array formation electron transport rate between Q A and Q B reduced, likely due to restricted plastoquinone diffusion. We conclude that chlorophyll b614, rather being part of pigment cluster responsible for quenching, is needed to maintain full rate of electron flow in the thylakoids by controlling protein-protein interactions between PSII units in grana partitions., (Copyright © 2022 Elsevier B.V. All rights reserved.)

Published

2022

3. Violaxanthin and Zeaxanthin May Replace Lutein at the L1 Site of LHCII, Conserving the Interactions with Surrounding Chlorophylls and the Capability of Triplet-Triplet Energy Transfer.

Author

Carbonera D, Agostini A, Bortolus M, Dall'Osto L, and Bassi R

Subjects

Carotenoids metabolism, Chlorophyll metabolism, Energy Transfer, Light-Harvesting Protein Complexes metabolism, Photosystem II Protein Complex metabolism, Xanthophylls chemistry, Zeaxanthins metabolism, Arabidopsis metabolism, Lutein

Abstract

Carotenoids represent the first line of defence of photosystems against singlet oxygen ( 1 O 2 ) toxicity, because of their capacity to quench the chlorophyll triplet state ( 3 Chl) through a physical mechanism based on the transfer of triplet excitation (triplet-triplet energy transfer, TTET). In previous works, we showed that the antenna LHCII is characterised by a robust photoprotective mechanism, able to adapt to the removal of individual chlorophylls while maintaining a remarkable capacity for 3 Chl quenching. In this work, we investigated the effects on this quenching induced in LHCII by the replacement of the lutein bound at the L1 site with violaxanthin and zeaxanthin. We studied LHCII isolated from the Arabidopsis thaliana mutants lut2 -in which lutein is replaced by violaxanthin-and lut2 npq2 , in which all xanthophylls are replaced constitutively by zeaxanthin. We characterised the photophysics of these systems via optically detected magnetic resonance (ODMR) and time-resolved electron paramagnetic resonance (TR-EPR). We concluded that, in LHCII, lutein-binding sites have conserved characteristics, and ensure efficient TTET regardless of the identity of the carotenoid accommodated.

Published

2022

4. The role of light-harvesting complex I in excitation energy transfer from LHCII to photosystem I in Arabidopsis.

Author

Schiphorst C, Achterberg L, Gómez R, Koehorst R, Bassi R, van Amerongen H, Dall'Osto L, and Wientjes E

Subjects

Energy Transfer, Light-Harvesting Protein Complexes metabolism, Photosystem II Protein Complex metabolism, Thylakoids metabolism, Arabidopsis metabolism, Photosystem I Protein Complex metabolism

Abstract

Photosynthesis powers nearly all life on Earth. Light absorbed by photosystems drives the conversion of water and carbon dioxide into sugars. In plants, photosystem I (PSI) and photosystem II (PSII) work in series to drive the electron transport from water to NADP+. As both photosystems largely work in series, a balanced excitation pressure is required for optimal photosynthetic performance. Both photosystems are composed of a core and light-harvesting complexes (LHCI) for PSI and LHCII for PSII. When the light conditions favor the excitation of one photosystem over the other, a mobile pool of trimeric LHCII moves between both photosystems thus tuning their antenna cross-section in a process called state transitions. When PSII is overexcited multiple LHCIIs can associate with PSI. A trimeric LHCII binds to PSI at the PsaH/L/O site to form a well-characterized PSI-LHCI-LHCII supercomplex. The binding site(s) of the "additional" LHCII is still unclear, although a mediating role for LHCI has been proposed. In this work, we measured the PSI antenna size and trapping kinetics of photosynthetic membranes from Arabidopsis (Arabidopsis thaliana) plants. Membranes from wild-type (WT) plants were compared to those of the ΔLhca mutant that completely lacks the LHCI antenna. The results showed that "additional" LHCII complexes can transfer energy directly to the PSI core in the absence of LHCI. However, the transfer is about two times faster and therefore more efficient, when LHCI is present. This suggests LHCI mediates excitation energy transfer from loosely bound LHCII to PSI in WT plants., (© The Author(s) 2021. Published by Oxford University Press on behalf of American Society of Plant Biologists.)

Published

2022

5. Supramolecular assembly of chloroplast NADH dehydrogenase-like complex with photosystem I from Arabidopsis thaliana.

Author

Su X, Cao D, Pan X, Shi L, Liu Z, Dall'Osto L, Bassi R, Zhang X, and Li M

Subjects

Chloroplasts metabolism, Light-Harvesting Protein Complexes metabolism, NADH Dehydrogenase metabolism, Photosystem I Protein Complex metabolism, Arabidopsis metabolism, Arabidopsis Proteins metabolism

Abstract

Cyclic electron transport/flow (CET/CEF) in chloroplasts is a regulatory process essential for the optimization of plant photosynthetic efficiency. A crucial CEF pathway is catalyzed by a membrane-embedded NADH dehydrogenase-like (NDH) complex that contains at least 29 protein subunits and associates with photosystem I (PSI) to form the NDH-PSI supercomplex. Here, we report the 3.9 Å resolution structure of the Arabidopsis thaliana NDH-PSI (AtNDH-PSI) supercomplex. We constructed structural models for 26 AtNDH subunits, among which 11 are unique to chloroplasts and stabilize the core part of the NDH complex. In the supercomplex, one NDH can bind up to two PSI-light-harvesting complex I (PSI-LHCI) complexes at both sides of its membrane arm. Two minor LHCIs, Lhca5 and Lhca6, each present in one PSI-LHCI, interact with NDH and contribute to supercomplex formation and stabilization. Collectively, our study reveals the structural details of the AtNDH-PSI supercomplex assembly and provides a molecular basis for further investigation of the regulatory mechanism of CEF in plants., (Copyright © 2022 The Author. Published by Elsevier Inc. All rights reserved.)

Published

2022

6. A new function for the xanthophyll zeaxanthin: glueing chlorophyll biosynthesis to thylakoid protein assembly.

Author

Bassi R

Subjects

Adhesives metabolism, Animals, Chlorophyll metabolism, Humans, Photosynthesis, Thylakoids metabolism, Zeaxanthins metabolism, Arabidopsis metabolism, Xanthophylls metabolism

Abstract

Xanthophylls are coloured isoprenoid metabolites synthesized in many organisms with a variety of functions from the attraction of animals for impollination to absorption of light energy for photosynthesis to photoprotection against photooxidative stress. The finding by Proctor and co-workers makes a new addition to the last type of functions by showing that zeaxanthin is instrumental in coordinating chlorophyll biosynthesis with the insertion of pigment-binding proteins into the photosynthetic membrane by glueing the protein components catalyzing these functions into a supercomplex and regulating its activity., (© 2021 The Author(s).)

Published

2021

7. Identification of a pigment cluster catalysing fast photoprotective quenching response in CP29.

Author

Guardini Z, Bressan M, Caferri R, Bassi R, and Dall'Osto L

Subjects

Arabidopsis chemistry, Arabidopsis Proteins metabolism, Catalysis, Chloroplast Proteins metabolism, Ribonucleoproteins metabolism, Arabidopsis metabolism, Arabidopsis Proteins chemistry, Chlorophyll metabolism, Chloroplast Proteins chemistry, Photosynthesis, Pigments, Biological metabolism, Protein Domains, Ribonucleoproteins chemistry

Abstract

Non-photochemical quenching is the photoprotective heat dissipation of chlorophyll-excited states. In higher plants, two quenching sites are located in trimeric LHCII and monomeric CP29 proteins. Catalysis of dissipative reactions requires interactions between chromophores, either carotenoid, chlorophyll or both. We identified CP29 protein domains involved in quenching by complementing an Arabidopsis deletion mutant with sequences deleted in pigment-binding or pH-sensitive sites. Acidic residues exposed to the thylakoid lumen were found not essential for activation of thermal dissipation in vivo. Chlorophylls a603 (a5) and a616 were identified as components of the catalytic pigment cluster responsible for quenching reaction(s), in addition to xanthophyll L2 and chlorophyll a609 (b5). We suggest that a conformational change induced by acidification in PsbS is transduced to CP29, thus bringing chlorophylls a603, a609 and a616 into close contact and activating a dissipative channel. Consistently, mutations on putative protonatable residues, exposed to the thylakoid lumen and previously suggested to regulate xanthophyll exchange at binding site L2, did not affect quenching efficiency.

Published

2020

8. Optimized Cas9 expression systems for highly efficient Arabidopsis genome editing facilitate isolation of complex alleles in a single generation.

Author

Ordon J, Bressan M, Kretschmer C, Dall'Osto L, Marillonnet S, Bassi R, and Stuttmann J

Subjects

Alleles, CRISPR-Associated Protein 9 metabolism, CRISPR-Cas Systems, Gene Deletion, Genome, Plant, Mutation, Promoter Regions, Genetic, Ubiquitin genetics, Arabidopsis genetics, CRISPR-Associated Protein 9 genetics, Gene Editing methods

Abstract

Genetic resources for the model plant Arabidopsis comprise mutant lines defective in almost any single gene in reference accession Columbia. However, gene redundancy and/or close linkage often render it extremely laborious or even impossible to isolate a desired line lacking a specific function or set of genes from segregating populations. Therefore, we here evaluated strategies and efficiencies for the inactivation of multiple genes by Cas9-based nucleases and multiplexing. In first attempts, we succeeded in isolating a mutant line carrying a 70 kb deletion, which occurred at a frequency of ~ 1.6% in the T 2 generation, through PCR-based screening of numerous individuals. However, we failed to isolate a line lacking Lhcb1 genes, which are present in five copies organized at two loci in the Arabidopsis genome. To improve efficiency of our Cas9-based nuclease system, regulatory sequences controlling Cas9 expression levels and timing were systematically compared. Indeed, use of DD45 and RPS5a promoters improved efficiency of our genome editing system by approximately 25-30-fold in comparison to the previous ubiquitin promoter. Using an optimized genome editing system with RPS5a promoter-driven Cas9, putatively quintuple mutant lines lacking detectable amounts of Lhcb1 protein represented approximately 30% of T 1 transformants. These results show how improved genome editing systems facilitate the isolation of complex mutant alleles, previously considered impossible to generate, at high frequency even in a single (T 1 ) generation.

Published

2020

9. Functional analysis of LHCSR1, a protein catalyzing NPQ in mosses, by heterologous expression in Arabidopsis thaliana.

Author

Dikaios I, Schiphorst C, Dall'Osto L, Alboresi A, Bassi R, and Pinnola A

Subjects

Arabidopsis genetics, Gene Expression Regulation, Plant, Light, Light-Harvesting Protein Complexes genetics, Mutation, Oxidoreductases genetics, Oxidoreductases metabolism, Photochemical Processes, Photosynthesis, Plants, Genetically Modified, Recombinant Proteins genetics, Recombinant Proteins metabolism, Thylakoids genetics, Thylakoids metabolism, Xanthophylls metabolism, Zeaxanthins metabolism, Arabidopsis metabolism, Bryopsida genetics, Light-Harvesting Protein Complexes metabolism, Plant Proteins genetics, Plant Proteins metabolism

Abstract

Non-photochemical quenching, NPQ, of chlorophyll fluorescence regulates the heat dissipation of chlorophyll excited states and determines the efficiency of the oxygenic photosynthetic systems. NPQ is regulated by a pH-sensing protein, responding to the chloroplast lumen acidification induced by excess light, coupled to an actuator, a chlorophyll/xanthophyll subunit where quenching reactions are catalyzed. In plants, the sensor is PSBS, while the two pigment-binding proteins Lhcb4 (also known as CP29) and LHCII are the actuators. In algae and mosses, stress-related light-harvesting proteins (LHCSR) comprise both functions of sensor and actuator within a single subunit. Here, we report on expressing the lhcsr1 gene from the moss Physcomitrella patens into several Arabidopsis thaliana npq4 mutants lacking the pH sensing PSBS protein essential for NPQ activity. The heterologous protein LHCSR1 accumulates in thylakoids of A. thaliana and NPQ activity can be partially restored. Complementation of double mutants lacking, besides PSBS, specific xanthophylls, allowed analyzing chromophore requirement for LHCSR-dependent quenching activity. We show that the partial recovery of NPQ is mostly due to the lower levels of Zeaxanthin in A. thaliana in comparison to P. patens. Complemented npq2npq4 mutants, lacking besides PSBS, Zeaxanthin Epoxidase, showed an NPQ recovery of up to 70% in comparison to A. thaliana wild type. Furthermore, we show that Lutein is not essential for the folding nor for the quenching activity of LHCSR1. In short, we have developed a system to study the function of LHCSR proteins using heterologous expression in a variety of A. thaliana mutants.

Published

2019

10. Loss of LHCI system affects LHCII re-distribution between thylakoid domains upon state transitions.

Author

Bressan M, Bassi R, and Dall'Osto L

Subjects

Arabidopsis ultrastructure, Chlorophyll metabolism, Gene Knockout Techniques, Mesophyll Cells metabolism, Mesophyll Cells ultrastructure, Mutation genetics, Photosystem I Protein Complex metabolism, Spectrometry, Fluorescence, Thylakoids ultrastructure, Arabidopsis metabolism, Light-Harvesting Protein Complexes metabolism, Thylakoids metabolism

Abstract

LHCI, the peripheral antenna system of Photosystem I, includes four light-harvesting proteins (Lhca1-Lhca4) in higher plants, all of which are devoid in the Arabidopsis thaliana knock-out mutant ΔLhca. PSI absorption cross-section was reduced in the mutant, thus affecting the redox balance of the photosynthetic electron chain and resulting in a more reduced PQ with respect to the wild type. ΔLhca plants developed compensatory response by enhancing LHCII binding to PSI. However, the amplitude of state transitions, as measured from changes of chlorophyll fluorescence in vivo, was unexpectedly low than the high level of PSI-LHCII supercomplex established. In order to elucidate the reasons for discrepancy, we further analyzed state transition in ΔLhca plants. The STN7 kinase was fully active in the mutant as judged from up-regulation of LHCII phosphorylation in state II. Instead, the lateral heterogeneity of thylakoids was affected by lack of LHCI, with LHCII being enriched in stroma membranes with respect to the wild type. Re-distribution of this complex affected the overall fluorescence yield of thylakoids already in state I and minimized changes in RT fluorescence yield when LHCII did connect to PSI reaction center. We conclude that interpretation of chlorophyll fluorescence analysis of state transitions becomes problematic when applied to mutants whose thylakoid architecture is significantly modified with respect to the wild type.

Published

2018

11. Two mechanisms for dissipation of excess light in monomeric and trimeric light-harvesting complexes.

Author

Dall'Osto L, Cazzaniga S, Bressan M, Paleček D, Židek K, Niyogi KK, Fleming GR, Zigmantas D, and Bassi R

Subjects

Arabidopsis chemistry, Cations metabolism, Energy Transfer, Light-Harvesting Protein Complexes chemistry, Mutation, Protein Multimerization, Arabidopsis physiology, Light, Light-Harvesting Protein Complexes metabolism, Lutein physiology, Zeaxanthins physiology

Abstract

Oxygenic photoautotrophs require mechanisms for rapidly matching the level of chlorophyll excited states from light harvesting with the rate of electron transport from water to carbon dioxide. These photoprotective reactions prevent formation of reactive excited states and photoinhibition. The fastest response to excess illumination is the so-called non-photochemical quenching which, in higher plants, requires the luminal pH sensor PsbS and other yet unidentified components of the photosystem II antenna. Both trimeric light-harvesting complex II (LHCII) and monomeric LHC proteins have been indicated as site(s) of the heat-dissipative reactions. Different mechanisms have been proposed: energy transfer to a lutein quencher in trimers, formation of a zeaxanthin radical cation in monomers. Here, we report on the construction of a mutant lacking all monomeric LHC proteins but retaining LHCII trimers. Its non-photochemical quenching induction rate was substantially slower with respect to the wild type. A carotenoid radical cation signal was detected in the wild type, although it was lost in the mutant. We conclude that non-photochemical quenching is catalysed by two independent mechanisms, with the fastest activated response catalysed within monomeric LHC proteins depending on both zeaxanthin and lutein and on the formation of a radical cation. Trimeric LHCII was responsible for the slowly activated quenching component whereas inclusion in supercomplexes was not required. This latter activity does not depend on lutein nor on charge transfer events, whereas zeaxanthin was essential.

Published

2017

12. LHCII can substitute for LHCI as an antenna for photosystem I but with reduced light-harvesting capacity.

Author

Bressan M, Dall'Osto L, Bargigia I, Alcocer MJ, Viola D, Cerullo G, D'Andrea C, Bassi R, and Ballottari M

Subjects

Energy Transfer, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Chlorophyll Binding Proteins metabolism, Photosynthesis, Photosystem I Protein Complex metabolism

Abstract

Light-harvesting complexes (LHCs) are major constituents of the antenna systems in higher plant photosystems. Four Lhca subunits are tightly bound to the photosystem I (PSI) core complex, forming its outer antenna moiety called LHCI. The Arabidopsis thaliana mutant ΔLhca lacks all Lhca1-4 subunits and compensates for its decreased antenna size by binding LHCII trimers, the main constituent of the photosystem II antenna system, to PSI. In this work we have investigated the effect of LHCI/LHCII substitution by comparing the light harvesting and excitation energy transfer efficiency properties of PSI complexes isolated from ΔLhca mutants and from the wild type, as well as the consequences for plant growth. We show that the excitation energy transfer efficiency was not compromised by the substitution of LHCI with LHCII but a significant reduction in the absorption cross-section was observed. The absence of LHCI subunits in PSI thus significantly limits light harvesting, even on LHCII binding, inducing, as a consequence, a strong reduction in growth.

Published

2016

13. Regulation of photosystem I light harvesting by zeaxanthin.

Author

Ballottari M, Alcocer MJ, D'Andrea C, Viola D, Ahn TK, Petrozza A, Polli D, Fleming GR, Cerullo G, and Bassi R

Subjects

Arabidopsis genetics, Chlorophyll metabolism, Fluorescence, Kinetics, Light, Light-Harvesting Protein Complexes genetics, Luminescent Measurements instrumentation, Luminescent Measurements methods, Mutation, Photosynthesis radiation effects, Photosystem I Protein Complex genetics, Plant Leaves genetics, Plant Leaves metabolism, Protein Binding, Time Factors, Zeaxanthins, Arabidopsis metabolism, Light-Harvesting Protein Complexes metabolism, Photosystem I Protein Complex metabolism, Xanthophylls metabolism

Abstract

In oxygenic photosynthetic eukaryotes, the hydroxylated carotenoid zeaxanthin is produced from preexisting violaxanthin upon exposure to excess light conditions. Zeaxanthin binding to components of the photosystem II (PSII) antenna system has been investigated thoroughly and shown to help in the dissipation of excess chlorophyll-excited states and scavenging of oxygen radicals. However, the functional consequences of the accumulation of the light-harvesting complex I (LHCI) proteins in the photosystem I (PSI) antenna have remained unclarified so far. In this work we investigated the effect of zeaxanthin binding on photoprotection of PSI-LHCI by comparing preparations isolated from wild-type Arabidopsis thaliana (i.e., with violaxanthin) and those isolated from the A. thaliana nonphotochemical quenching 2 mutant, in which violaxanthin is replaced by zeaxanthin. Time-resolved fluorescence measurements showed that zeaxanthin binding leads to a previously unrecognized quenching effect on PSI-LHCI fluorescence. The efficiency of energy transfer from the LHCI moiety of the complex to the PSI reaction center was down-regulated, and an enhanced PSI resistance to photoinhibition was observed both in vitro and in vivo. Thus, zeaxanthin was shown to be effective in inducing dissipative states in PSI, similar to its well-known effect on PSII. We propose that, upon acclimation to high light, PSI-LHCI changes its light-harvesting efficiency by a zeaxanthin-dependent quenching of the absorbed excitation energy, whereas in PSII the stoichiometry of LHC antenna proteins per reaction center is reduced directly.

Published

2014

14. On the origin of a slowly reversible fluorescence decay component in the Arabidopsis npq4 mutant.

Author

Dall'Osto L, Cazzaniga S, Wada M, and Bassi R

Subjects

Carotenoids biosynthesis, Kinetics, Mutation genetics, Photosynthesis genetics, Arabidopsis genetics, Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Fluorescence, Light, Light-Harvesting Protein Complexes genetics, Light-Harvesting Protein Complexes metabolism, Photosynthesis physiology, Photosystem II Protein Complex genetics, Photosystem II Protein Complex metabolism

Abstract

Over-excitation of photosynthetic apparatus causing photoinhibition is counteracted by non-photochemical quenching (NPQ) of chlorophyll fluorescence, dissipating excess absorbed energy into heat. The PsbS protein plays a key role in this process, thus making the PsbS-less npq4 mutant unable to carry out qE, the major and most rapid component of NPQ. It was proposed that npq4 does perform qE-type quenching, although at lower rate than WT Arabidopsis. Here, we investigated the kinetics of NPQ in PsbS-depleted mutants of Arabidopsis. We show that red light was less effective than white light in decreasing maximal fluorescence in npq4 mutants. Also, the kinetics of fluorescence dark recovery included a decay component, qM, exhibiting the same amplitude and half-life in both WT and npq4 mutants. This component was uncoupler-sensitive and unaffected by photosystem II repair or mitochondrial ATP synthesis inhibitors. Targeted reverse genetic analysis showed that traits affecting composition of the photosynthetic apparatus, carotenoid biosynthesis and state transitions did not affect qM. This was depleted in the npq4phot2 mutant which is impaired in chloroplast photorelocation, implying that fluorescence decay, previously described as a quenching component in npq4 is, in fact, the result of decreased photon absorption caused by chloroplast relocation rather than a change in the activity of quenching reactions.

Published

2014

15. Interaction between avoidance of photon absorption, excess energy dissipation and zeaxanthin synthesis against photooxidative stress in Arabidopsis.

Author

Cazzaniga S, Dall' Osto L, Kong SG, Wada M, and Bassi R

Subjects

Absorption, Arabidopsis metabolism, Cold Temperature, Electron Transport, Energy Metabolism, Photons, Photosynthesis, Zeaxanthins, Arabidopsis radiation effects, Chloroplasts radiation effects, Oxidative Stress, Xanthophylls biosynthesis

Abstract

Plants evolved photoprotective mechanisms in order to counteract the damaging effects of excess light in oxygenic environments. Among them, chloroplast avoidance and non-photochemical quenching concur in reducing the concentration of chlorophyll excited states in the photosynthetic apparatus to avoid photooxidation. We evaluated their relative importance in regulating excitation pressure on photosystem II. To this aim, genotypes were constructed carrying mutations impairing the chloroplast avoidance response (phot2) as well as mutations affecting the biosynthesis of the photoprotective xanthophyll zeaxanthin (npq1) or the activation of non-photochemical quenching (npq4), followed by evaluation of their photosensitivity in vivo. Suppression of avoidance response resulted in oxidative stress under excess light at low temperature, while removing either zeaxanthin or PsbS had a milder effect. The double mutants phot2 npq1 and phot2 npq4 showed the highest sensitivity to photooxidative stress, indicating that xanthophyll cycle and qE have additive effects over the avoidance response. The interactions between non-photochemical quenching and avoidance responses were studied by analyzing the kinetics of fluorescence decay and recovery at different light intensities. phot2 fluorescence decay lacked a component, here named as qM. This kinetic component linearly correlated with the leaf transmittance changes due to chloroplast relocation induced by white light and was absent when red light was used as actinic source. On these basis we conclude that a decrease in leaf optical density affects the apparent non-photochemical quenching (NPQ) rise kinetic. Thus, excess light-induced fluorescence decrease is in part due to avoidance of photon absorption rather than to a genuine quenching process., (© 2013 The Authors The Plant Journal © 2013 John Wiley & Sons Ltd.)

Published

2013

16. Post-transcriptional control of light-harvesting genes expression under light stress.

Author

Floris M, Bassi R, Robaglia C, Alboresi A, and Lanet E

Subjects

Arabidopsis physiology, Chloroplasts metabolism, Chloroplasts radiation effects, Cytoplasm metabolism, Cytoplasm radiation effects, Genes, Plant genetics, Light-Harvesting Protein Complexes metabolism, Polyribosomes metabolism, Polyribosomes radiation effects, Protein Biosynthesis radiation effects, RNA, Messenger genetics, RNA, Messenger metabolism, Signal Transduction genetics, Signal Transduction radiation effects, Stress, Physiological genetics, Arabidopsis genetics, Arabidopsis radiation effects, Gene Expression Regulation, Plant radiation effects, Light, Light-Harvesting Protein Complexes genetics, Stress, Physiological radiation effects, Transcription, Genetic radiation effects

Abstract

Plants have to deal with fluctuating light environment and the regulation of the photosynthetic apparatus is crucial for their survival. The large multigenic family of nuclear encoded chloroplastic proteins called light harvesting complex (LHC) is involved in both light harvesting and photoprotection. Changes in light intensity induce a complex set of molecular events within both the chloroplast and the cytoplasmic compartments of the cell leading to reorganization of the photosynthetic apparatus in order to optimize photosynthesis to the new conditions. In this study we have investigated the occurrence of translational regulations during light stress in Arabidopsis thaliana by using polysomes profiling. We have observed a strong effect of light on global translation activity of the cell. We show that individual LHC genes are translationally regulated in response to light conditions by changing the ratio between polysomal versus total messenger RNA. In addition, we found that cytoplasmic translational regulation can precede nuclear transcriptional regulation. Thus translational control appears as an important component of the crosstalk between chloroplast and the nucleus in plant cells.

Published

2013

17. The Arabidopsis nox mutant lacking carotene hydroxylase activity reveals a critical role for xanthophylls in photosystem I biogenesis.

Author

Dall'Osto L, Piques M, Ronzani M, Molesini B, Alboresi A, Cazzaniga S, and Bassi R

Subjects

Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Carotenoids metabolism, Light, Light-Harvesting Protein Complexes genetics, Light-Harvesting Protein Complexes metabolism, Mixed Function Oxygenases metabolism, Mutation, Photosystem I Protein Complex genetics, Photosystem II Protein Complex metabolism, Plant Leaves genetics, Plant Leaves metabolism, Protein Subunits metabolism, Xanthophylls genetics, beta Carotene metabolism, Arabidopsis genetics, Arabidopsis metabolism, Photosystem I Protein Complex metabolism, Xanthophylls metabolism

Abstract

Carotenes, and their oxygenated derivatives xanthophylls, are essential components of the photosynthetic apparatus. They contribute to the assembly of photosynthetic complexes and participate in light absorption and chloroplast photoprotection. Here, we studied the role of xanthophylls, as distinct from that of carotenes, by characterizing a no xanthophylls (nox) mutant of Arabidopsis thaliana, which was obtained by combining mutations targeting the four carotenoid hydroxylase genes. nox plants retained α- and β-carotenes but were devoid in xanthophylls. The phenotype included depletion of light-harvesting complex (LHC) subunits and impairment of nonphotochemical quenching, two effects consistent with the location of xanthophylls in photosystem II antenna, but also a decreased efficiency of photosynthetic electron transfer, photosensitivity, and lethality in soil. Biochemical analysis revealed that the nox mutant was specifically depleted in photosystem I function due to a severe deficiency in PsaA/B subunits. While the stationary level of psaA/B transcripts showed no major differences between genotypes, the stability of newly synthesized PsaA/B proteins was decreased and translation of psaA/B mRNA was impaired in nox with respect to wild-type plants. We conclude that xanthophylls, besides their role in photoprotection and LHC assembly, are also needed for photosystem I core translation and stability, thus making these compounds indispensable for autotrophic growth.

Published

2013

18. Effects of altered α- and β-branch carotenoid biosynthesis on photoprotection and whole-plant acclimation of Arabidopsis to photo-oxidative stress.

Author

Caliandro R, Nagel KA, Kastenholz B, Bassi R, Li Z, Niyogi KK, Pogson BJ, Schurr U, and Matsubara S

Subjects

Adaptation, Physiological radiation effects, Arabidopsis Proteins metabolism, Biosynthetic Pathways radiation effects, Chlorophyll metabolism, Darkness, Light-Harvesting Protein Complexes metabolism, Mutation genetics, Photosystem II Protein Complex metabolism, Plant Leaves growth & development, Plant Leaves metabolism, Plant Leaves radiation effects, Plant Roots growth & development, Plant Roots radiation effects, Seeds growth & development, Seeds radiation effects, Acclimatization radiation effects, Arabidopsis physiology, Arabidopsis radiation effects, Carotenoids biosynthesis, Carotenoids chemistry, Light, Oxidative Stress radiation effects

Abstract

Functions of α- and β-branch carotenoids in whole-plant acclimation to photo-oxidative stress were studied in Arabidopsis thaliana wild-type (wt) and carotenoid mutants, lutein deficient (lut2, lut5), non-photochemical quenching1 (npq1) and suppressor of zeaxanthin-less1 (szl1) npq1 double mutant. Photo-oxidative stress was applied by exposing plants to sunflecks. The sunflecks caused reduction of chlorophyll content in all plants, but more severely in those having high α- to β-branch carotenoid composition (α/β-ratio) (lut5, szl1npq1). While this did not alter carotenoid composition in wt or lut2, which accumulates only β-branch carotenoids, increased xanthophyll levels were found in the mutants with high α/β-ratios (lut5, szl1npq1) or without xanthophyll-cycle operation (npq1, szl1npq1). The PsbS protein content increased in all sunfleck plants but lut2. These changes were accompanied by no change (npq1, szl1npq1) or enhanced capacity (wt, lut5) of NPQ. Leaf mass per area increased in lut2, but decreased in wt and lut5 that showed increased NPQ. The sunflecks decelerated primary root growth in wt and npq1 having normal α/β-ratios, but suppressed lateral root formation in lut5 and szl1npq1 having high α/β-ratios. The results highlight the importance of proper regulation of the α- and β-branch carotenoid pathways for whole-plant acclimation, not only leaf photoprotection, under photo-oxidative stress., (© 2012 Blackwell Publishing Ltd.)

Published

2013

19. Zeaxanthin protects plant photosynthesis by modulating chlorophyll triplet yield in specific light-harvesting antenna subunits.

Author

Dall'Osto L, Holt NE, Kaligotla S, Fuciman M, Cazzaniga S, Carbonera D, Frank HA, Alric J, and Bassi R

Subjects

Arabidopsis genetics, Chlorophyll genetics, Light-Harvesting Protein Complexes genetics, Photosynthesis genetics, Photosystem II Protein Complex genetics, Singlet Oxygen metabolism, Zeaxanthins, Arabidopsis metabolism, Chlorophyll metabolism, Light-Harvesting Protein Complexes metabolism, Photosynthesis drug effects, Photosystem II Protein Complex metabolism, Xanthophylls pharmacology

Abstract

Plants are particularly prone to photo-oxidative damage caused by excess light. Photoprotection is essential for photosynthesis to proceed in oxygenic environments either by scavenging harmful reactive intermediates or preventing their accumulation to avoid photoinhibition. Carotenoids play a key role in protecting photosynthesis from the toxic effect of over-excitation; under excess light conditions, plants accumulate a specific carotenoid, zeaxanthin, that was shown to increase photoprotection. In this work we genetically dissected different components of zeaxanthin-dependent photoprotection. By using time-resolved differential spectroscopy in vivo, we identified a zeaxanthin-dependent optical signal characterized by a red shift in the carotenoid peak of the triplet-minus-singlet spectrum of leaves and pigment-binding proteins. By fractionating thylakoids into their component pigment binding complexes, the signal was found to originate from the monomeric Lhcb4-6 antenna components of Photosystem II and the Lhca1-4 subunits of Photosystem I. By analyzing mutants based on their sensitivity to excess light, the red-shifted triplet-minus-singlet signal was tightly correlated with photoprotection in the chloroplasts, suggesting the signal implies an increased efficiency of zeaxanthin in controlling chlorophyll triplet formation. Fluorescence-detected magnetic resonance analysis showed a decrease in the amplitude of signals assigned to chlorophyll triplets belonging to the monomeric antenna complexes of Photosystem II upon zeaxanthin binding; however, the amplitude of carotenoid triplet signal does not increase correspondingly. Results show that the high light-induced binding of zeaxanthin to specific proteins plays a major role in enhancing photoprotection by modulating the yield of potentially dangerous chlorophyll-excited states in vivo and preventing the production of singlet oxygen.

Published

2012

20. The Arabidopsis szl1 mutant reveals a critical role of β-carotene in photosystem I photoprotection.

Author

Cazzaniga S, Li Z, Niyogi KK, Bassi R, and Dall'Osto L

Subjects

Arabidopsis genetics, Arabidopsis Proteins metabolism, Chlorophyll metabolism, Chlorophyll Binding Proteins metabolism, Electron Transport radiation effects, Energy Metabolism radiation effects, Fluorescence, Genotype, Intramolecular Lyases metabolism, Oxidation-Reduction radiation effects, Photosynthesis radiation effects, Superoxides metabolism, Temperature, Xanthophylls metabolism, Arabidopsis metabolism, Arabidopsis radiation effects, Arabidopsis Proteins genetics, Intramolecular Lyases genetics, Light, Mutation genetics, Photosystem I Protein Complex metabolism, beta Carotene metabolism

Abstract

Carotenes and their oxygenated derivatives, the xanthophylls, are structural determinants in both photosystems (PS) I and II. They bind and stabilize photosynthetic complexes, increase the light-harvesting capacity of chlorophyll-binding proteins, and have a major role in chloroplast photoprotection. Localization of carotenoid species within each PS is highly conserved: Core complexes bind carotenes, whereas peripheral light-harvesting systems bind xanthophylls. The specific functional role of each xanthophyll species has been recently described by genetic dissection, however the in vivo role of carotenes has not been similarly defined. Here, we have analyzed the function of carotenes in photosynthesis and photoprotection, distinct from that of xanthophylls, by characterizing the suppressor of zeaxanthin-less (szl) mutant of Arabidopsis (Arabidopsis thaliana) which, due to the decreased activity of the lycopene-β-cyclase, shows a lower carotene content than wild-type plants. When grown at room temperature, mutant plants showed a lower content in PSI light-harvesting complex I complex than the wild type, and a reduced capacity for chlorophyll fluorescence quenching, the rapidly reversible component of nonphotochemical quenching. When exposed to high light at chilling temperature, szl1 plants showed stronger photoxidation than wild-type plants. Both PSI and PSII from szl1 were similarly depleted in carotenes and yet PSI activity was more sensitive to light stress than PSII as shown by the stronger photoinhibition of PSI and increased rate of singlet oxygen release from isolated PSI light-harvesting complex I complexes of szl1 compared with the wild type. We conclude that carotene depletion in the core complexes impairs photoprotection of both PS under high light at chilling temperature, with PSI being far more affected than PSII.

Published

2012

21. A quadruple mutant of Arabidopsis reveals a β-carotene hydroxylation activity for LUT1/CYP97C1 and a regulatory role of xanthophylls on determination of the PSI/PSII ratio.

Author

Fiore A, Dall'Osto L, Cazzaniga S, Diretto G, Giuliano G, and Bassi R

Subjects

Arabidopsis Proteins genetics, Mutation, Arabidopsis genetics, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Photosystem I Protein Complex metabolism, Photosystem II Protein Complex metabolism, Xanthophylls metabolism, beta Carotene metabolism

Abstract

Background: Xanthophylls are oxygenated carotenoids playing an essential role as structural components of the photosynthetic apparatus. Xanthophylls contribute to the assembly and stability of light-harvesting complex, to light absorbance and to photoprotection. The first step in xanthophyll biosynthesis from α- and β-carotene is the hydroxylation of ε- and β-rings, performed by both non-heme iron oxygenases (CHY1, CHY2) and P450 cytochromes (LUT1/CYP97C1, LUT5/CYP97A3). The Arabidopsis triple chy1chy2lut5 mutant is almost completely depleted in β-xanthophylls., Results: Here we report on the quadruple chy1chy2lut2lut5 mutant, additionally carrying the lut2 mutation (affecting lycopene ε-cyclase). This genotype lacks lutein and yet it shows a compensatory increase in β-xanthophylls with respect to chy1chy2lut5 mutant. Mutant plants show an even stronger photosensitivity than chy1chy2lut5, a complete lack of qE, the rapidly reversible component of non-photochemical quenching, and a peculiar organization of the pigment binding complexes into thylakoids. Biochemical analysis reveals that the chy1chy2lut2lut5 mutant is depleted in Lhcb subunits and is specifically affected in Photosystem I function, showing a deficiency in PSI-LHCI supercomplexes. Moreover, by analyzing a series of single, double, triple and quadruple Arabidopsis mutants in xanthophyll biosynthesis, we show a hitherto undescribed correlation between xanthophyll levels and the PSI-PSII ratio. The decrease in the xanthophyll/carotenoid ratio causes a proportional decrease in the LHCII and PSI core levels with respect to PSII., Conclusions: The physiological and biochemical phenotype of the chy1chy2lut2lut5 mutant shows that (i) LUT1/CYP97C1 protein reveals a major β-carotene hydroxylase activity in vivo when depleted in its preferred substrate α-carotene; (ii) xanthophylls are needed for normal level of Photosystem I and LHCII accumulation.

Published

2012

22. Role of xanthophylls in light harvesting in green plants: a spectroscopic investigation of mutant LHCII and Lhcb pigment-protein complexes.

Author

Fuciman M, Enriquez MM, Polívka T, Dall'Osto L, Bassi R, and Frank HA

Subjects

Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Energy Transfer, Light-Harvesting Protein Complexes genetics, Light-Harvesting Protein Complexes metabolism, Lutein chemistry, Mutation, Spectrometry, Fluorescence, Zeaxanthins, Arabidopsis metabolism, Arabidopsis Proteins chemistry, Light-Harvesting Protein Complexes chemistry, Xanthophylls chemistry

Abstract

The spectroscopic properties and energy transfer dynamics of the protein-bound chlorophylls and xanthophylls in monomeric, major LHCII complexes, and minor Lhcb complexes from genetically altered Arabidopsis thaliana plants have been investigated using both steady-state and time-resolved absorption and fluorescence spectroscopic methods. The pigment-protein complexes that were studied contain Chl a, Chl b, and variable amounts of the xanthophylls, zeaxanthin (Z), violaxanthin (V), neoxanthin (N), and lutein (L). The complexes were derived from mutants of plants denoted npq1 (NVL), npq2lut2 (Z), aba4npq1lut2 (V), aba4npq1 (VL), npq1lut2 (NV), and npq2 (LZ). The data reveal specific singlet energy transfer routes and excited state spectra and dynamics that depend on the xanthophyll present in the complex.

Published

2012

23. Quenching in Arabidopsis thaliana mutants lacking monomeric antenna proteins of photosystem II.

Author

Miloslavina Y, de Bianchi S, Dall'Osto L, Bassi R, and Holzwarth AR

Subjects

Arabidopsis genetics, Arabidopsis Proteins genetics, Chloroplast Proteins genetics, Gene Knockdown Techniques, Photosystem II Protein Complex genetics, Plants, Genetically Modified genetics, Plants, Genetically Modified metabolism, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Chloroplast Proteins metabolism, Photosynthesis physiology, Photosystem II Protein Complex metabolism

Abstract

The minor light-harvesting complexes CP24, CP26, and CP29 have been proposed to play a key role in the zeaxanthin (Zx)-dependent high light-induced regulation (NPQ) of excitation energy in higher plants. To characterize the detailed roles of these minor complexes in NPQ and to determine their specific quenching effects we have studied the ultrafast fluorescence kinetics in knockout (ko) mutants koCP26, koCP29, and the double mutant koCP24/CP26. The data provide detailed insight into the quenching processes and the reorganization of the Photosystem (PS) II supercomplex under quenching conditions. All genotypes showed two NPQ quenching sites. Quenching site Q1 is formed by a light-induced functional detachment of parts of the PSII supercomplex and a pronounced quenching of the detached antenna parts. The antenna remaining bound to the PSII core was also quenched substantially in all genotypes under NPQ conditions (quenching site Q2) as compared with the dark-adapted state. The latter quenching was about equally strong in koCP26 and the koCP24/CP26 mutants as in the WT. Q2 quenching was substantially reduced, however, in koCP29 mutants suggesting a key role for CP29 in the total NPQ. The observed quenching effects in the knockout mutants are complicated by the fact that other minor antenna complexes do compensate in part for the lack of the CP24 and/or CP29 complexes. Their lack also causes some LHCII dissociation already in the dark.

Published

2011

24. Arabidopsis mutants deleted in the light-harvesting protein Lhcb4 have a disrupted photosystem II macrostructure and are defective in photoprotection.

Author

de Bianchi S, Betterle N, Kouril R, Cazzaniga S, Boekema E, Bassi R, and Dall'Osto L

Subjects

Arabidopsis Proteins genetics, Chlorophyll chemistry, Chlorophyll Binding Proteins genetics, Fluorescence, Gene Knockdown Techniques, Light, Lipid Peroxidation, Membrane Lipids chemistry, Membrane Lipids metabolism, Oxidation-Reduction, Oxidative Stress, Oxygen metabolism, Photosynthesis physiology, Photosynthetic Reaction Center Complex Proteins genetics, Photosynthetic Reaction Center Complex Proteins metabolism, Photosystem I Protein Complex metabolism, Photosystem II Protein Complex metabolism, Protein Isoforms genetics, Temperature, Thylakoids chemistry, Thylakoids metabolism, Thylakoids ultrastructure, Arabidopsis genetics, Arabidopsis physiology, Arabidopsis ultrastructure, Arabidopsis Proteins metabolism, Chlorophyll Binding Proteins metabolism, Photosystem II Protein Complex ultrastructure, Protein Isoforms metabolism

Abstract

The role of the light-harvesting complex Lhcb4 (CP29) in photosynthesis was investigated in Arabidopsis thaliana by characterizing knockout lines for each of the three Lhcb4 isoforms (Lhcb4.1/4.2/4.3). Plants lacking all isoforms (koLhcb4) showed a compensatory increase of Lhcb1 and a slightly reduced photosystem II/I ratio with respect to the wild type. The absence of Lhcb4 did not result in alteration in electron transport rates. However, the kinetic of state transition was faster in the mutant, and nonphotochemical quenching activity was lower in koLhcb4 plants with respect to either wild type or mutants retaining a single Lhcb4 isoform. KoLhcb4 plants were more sensitive to photoinhibition, while this effect was not observed in knockout lines for any other photosystem II antenna subunit. Ultrastructural analysis of thylakoid grana membranes showed a lower density of photosystem II complexes in koLhcb4. Moreover, analysis of isolated supercomplexes showed a different overall shape of the C₂S₂ particles due to a different binding mode of the S-trimer to the core complex. An empty space was observed within the photosystem II supercomplex at the Lhcb4 position, implying that the missing Lhcb4 was not replaced by other Lhc subunits. This suggests that Lhcb4 is unique among photosystem II antenna proteins and determinant for photosystem II macro-organization and photoprotection.

Published

2011

25. Reactive oxygen species and transcript analysis upon excess light treatment in wild-type Arabidopsis thaliana vs a photosensitive mutant lacking zeaxanthin and lutein.

Author

Alboresi A, Dall'osto L, Aprile A, Carillo P, Roncaglia E, Cattivelli L, and Bassi R

Subjects

Arabidopsis genetics, Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Gene Expression Regulation, Plant, Light, Photosynthesis radiation effects, Zeaxanthins, Arabidopsis metabolism, Arabidopsis radiation effects, Lutein deficiency, Mutation, Reactive Oxygen Species metabolism, Transcription, Genetic radiation effects, Xanthophylls deficiency

Abstract

Background: Reactive oxygen species (ROS) are unavoidable by-products of oxygenic photosynthesis, causing progressive oxidative damage and ultimately cell death. Despite their destructive activity they are also signalling molecules, priming the acclimatory response to stress stimuli., Results: To investigate this role further, we exposed wild type Arabidopsis thaliana plants and the double mutant npq1lut2 to excess light. The mutant does not produce the xanthophylls lutein and zeaxanthin, whose key roles include ROS scavenging and prevention of ROS synthesis. Biochemical analysis revealed that singlet oxygen (1O2) accumulated to higher levels in the mutant while other ROS were unaffected, allowing to define the transcriptomic signature of the acclimatory response mediated by 1O2 which is enhanced by the lack of these xanthophylls species. The group of genes differentially regulated in npq1lut2 is enriched in sequences encoding chloroplast proteins involved in cell protection against the damaging effect of ROS. Among the early fine-tuned components, are proteins involved in tetrapyrrole biosynthesis, chlorophyll catabolism, protein import, folding and turnover, synthesis and membrane insertion of photosynthetic subunits. Up to now, the flu mutant was the only biological system adopted to define the regulation of gene expression by 1O2. In this work, we propose the use of mutants accumulating 1O2 by mechanisms different from those activated in flu to better identify ROS signalling., Conclusions: We propose that the lack of zeaxanthin and lutein leads to 1O2 accumulation and this represents a signalling pathway in the early stages of stress acclimation, beside the response to ADP/ATP ratio and to the redox state of both plastoquinone pool. Chloroplasts respond to 1O2 accumulation by undergoing a significant change in composition and function towards a fast acclimatory response. The physiological implications of this signalling specificity are discussed.

Published

2011

26. Dynamics of zeaxanthin binding to the photosystem II monomeric antenna protein Lhcb6 (CP24) and modulation of its photoprotection properties.

Author

Betterle N, Ballottari M, Hienerwadel R, Dall'Osto L, and Bassi R

Subjects

Arabidopsis cytology, Chlorophyll metabolism, Chlorophyll Binding Proteins, Epoxy Compounds chemistry, Kinetics, Photobleaching, Photosystem II Protein Complex metabolism, Plant Leaves metabolism, Plant Leaves radiation effects, Protein Binding, Singlet Oxygen metabolism, Spectrum Analysis, Thylakoids metabolism, Xanthophylls chemistry, Zeaxanthins, Arabidopsis metabolism, Arabidopsis radiation effects, Arabidopsis Proteins metabolism, Light, Light-Harvesting Protein Complexes metabolism, Photosystem II Protein Complex chemistry, Xanthophylls metabolism

Abstract

Lhcb6 (CP24) is a monomeric antenna protein of photosystem II, which has been shown to play special roles in photoprotective mechanisms, such as the Non-Photochemical Quenching and reorganization of grana membranes in excess light conditions. In this work we analyzed Lhcb6 in vivo and in vitro: we show this protein, upon activation of the xanthophyll cycle, accumulates zeaxanthin into inner binding sites faster and to a larger extent than any other pigment-protein complex. By comparative analysis of Lhcb6 complexes violaxanthin or zeaxanthin binding, we demonstrate that zeaxanthin not only down-regulates chlorophyll singlet excited states, but also increases the efficiency of chlorophyll triplet quenching, with consequent reduction of singlet oxygen production and significant enhancement of photo-stability. On these bases we propose that Lhcb6, the most recent addition to the Lhcb protein family which evolved concomitantly to the adaptation of photosynthesis to land environment, has a crucial role in zeaxanthin-dependent photoprotection., (Copyright © 2010 Elsevier Inc. All rights reserved.)

Published

2010

27. Effect of antenna-depletion in Photosystem II on excitation energy transfer in Arabidopsis thaliana.

Author

van Oort B, Alberts M, de Bianchi S, Dall'Osto L, Bassi R, Trinkunas G, Croce R, and van Amerongen H

Subjects

Kinetics, Models, Molecular, Mutation genetics, Spectrometry, Fluorescence, Thylakoids metabolism, Time Factors, Arabidopsis metabolism, Energy Transfer, Photosystem I Protein Complex metabolism, Photosystem II Protein Complex metabolism

Abstract

The role of individual photosynthetic antenna complexes of Photosystem II (PSII) both in membrane organization and excitation energy transfer have been investigated. Thylakoid membranes from wild-type Arabidopsis thaliana, and three mutants lacking light-harvesting complexes CP24, CP26, or CP29, respectively, were studied by picosecond-fluorescence spectroscopy. By using different excitation/detection wavelength combinations it was possible for the first time, to our knowledge, to separate PSI and PSII fluorescence kinetics. The sub-100 ps component, previously ascribed entirely to PSI, turns out to be due partly to PSII. Moreover, the migration time of excitations from antenna to PSII reaction center (RC) was determined for the first time, to our knowledge, for thylakoid membranes. It is four times longer than for PSII-only membranes, due to additional antenna complexes, which are less well connected to the RC. The results in the absence of CP26 are very similar to those of wild-type, demonstrating that the PSII organization is not disturbed. However, the kinetics in the absence of CP29 and, especially, of CP24 show that a large fraction of the light-harvesting complexes becomes badly connected to the RCs. Interestingly, the excited-state lifetimes of the disconnected light-harvesting complexes seem to be substantially quenched., (2010 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2010

28. A structural basis for the pH-dependent xanthophyll cycle in Arabidopsis thaliana.

Author

Arnoux P, Morosinotto T, Saga G, Bassi R, and Pignol D

Subjects

Amino Acid Sequence, Arabidopsis enzymology, Ascorbic Acid metabolism, Crystallography, X-Ray, Gene Expression Regulation, Plant physiology, Hydrogen-Ion Concentration, Models, Molecular, Molecular Sequence Data, Oxidoreductases metabolism, Photosynthesis physiology, Protein Multimerization, Protein Structure, Secondary, Protein Structure, Tertiary, Sequence Homology, Amino Acid, Substrate Specificity, Thylakoids metabolism, Zeaxanthins, Arabidopsis metabolism, Oxidoreductases chemistry, Xanthophylls metabolism

Abstract

Plants adjust their photosynthetic activity to changing light conditions. A central regulation of photosynthesis depends on the xanthophyll cycle, in which the carotenoid violaxanthin is converted into zeaxanthin in strong light, thus activating the dissipation of the excess absorbed energy as heat and the scavenging of reactive oxygen species. Violaxanthin deepoxidase (VDE), the enzyme responsible for zeaxanthin synthesis, is activated by the acidification of the thylakoid lumen when photosynthetic electron transport exceeds the capacity of assimilatory reactions: at neutral pH, VDE is a soluble and inactive enzyme, whereas at acidic pH, it attaches to the thylakoid membrane where it binds its violaxanthin substrate. VDE also uses ascorbate as a cosubstrate with a pH-dependent Km that may reflect a preference for ascorbic acid. We determined the structures of the central lipocalin domain of VDE (VDEcd) at acidic and neutral pH. At neutral pH, VDEcd is monomeric with its active site occluded within a lipocalin barrel. Upon acidification, the barrel opens up and the enzyme appears as a dimer. A channel linking the two active sites of the dimer can harbor the entire carotenoid substrate and thus may permit the parallel deepoxidation of the two violaxanthin beta-ionone rings, making VDE an elegant example of the adaptation of an asymmetric enzyme to its symmetric substrate.

Published

2009

29. Lutein accumulation in the absence of zeaxanthin restores nonphotochemical quenching in the Arabidopsis thaliana npq1 mutant.

Author

Li Z, Ahn TK, Avenson TJ, Ballottari M, Cruz JA, Kramer DM, Bassi R, Fleming GR, Keasling JD, and Niyogi KK

Subjects

Amino Acid Sequence, Arabidopsis genetics, Arabidopsis radiation effects, Arabidopsis Proteins metabolism, Base Sequence, Intramolecular Lyases genetics, Light, Molecular Sequence Data, Mutation, Oxidoreductases metabolism, Sequence Alignment, Zeaxanthins, Arabidopsis metabolism, Arabidopsis Proteins genetics, Lutein metabolism, Oxidoreductases genetics, Xanthophylls metabolism

Abstract

Plants protect themselves from excess absorbed light energy through thermal dissipation, which is measured as nonphotochemical quenching of chlorophyll fluorescence (NPQ). The major component of NPQ, qE, is induced by high transthylakoid DeltapH in excess light and depends on the xanthophyll cycle, in which violaxanthin and antheraxanthin are deepoxidized to form zeaxanthin. To investigate the xanthophyll dependence of qE, we identified suppressor of zeaxanthin-less1 (szl1) as a suppressor of the Arabidopsis thaliana npq1 mutant, which lacks zeaxanthin. szl1 npq1 plants have a partially restored qE but lack zeaxanthin and have low levels of violaxanthin, antheraxanthin, and neoxanthin. However, they accumulate more lutein and alpha-carotene than the wild type. szl1 contains a point mutation in the lycopene beta-cyclase (LCYB) gene. Based on the pigment analysis, LCYB appears to be the major lycopene beta-cyclase and is not involved in neoxanthin synthesis. The Lhcb4 (CP29) and Lhcb5 (CP26) protein levels are reduced by 50% in szl1 npq1 relative to the wild type, whereas other Lhcb proteins are present at wild-type levels. Analysis of carotenoid radical cation formation and leaf absorbance changes strongly suggest that the higher amount of lutein substitutes for zeaxanthin in qE, implying a direct role in qE, as well as a mechanism that is weakly sensitive to carotenoid structural properties.

Published

2009

30. Light-induced dissociation of an antenna hetero-oligomer is needed for non-photochemical quenching induction.

Author

Betterle N, Ballottari M, Zorzan S, de Bianchi S, Cazzaniga S, Dall'osto L, Morosinotto T, and Bassi R

Subjects

Arabidopsis Proteins metabolism, Intracellular Membranes radiation effects, Intracellular Membranes ultrastructure, Light-Harvesting Protein Complexes, Mutation genetics, Photosynthetic Reaction Center Complex Proteins metabolism, Pigments, Biological metabolism, Plant Leaves radiation effects, Plant Leaves ultrastructure, Protein Structure, Quaternary, Thylakoids radiation effects, Thylakoids ultrastructure, Time Factors, Arabidopsis metabolism, Arabidopsis radiation effects, Light, Photosystem II Protein Complex metabolism

Abstract

PsbS plays a major role in activating the photoprotection mechanism known as "non-photochemical quenching," which dissipates chlorophyll excited states exceeding the capacity for photosynthetic electron transport. PsbS activity is known to be triggered by low lumenal pH. However, the molecular mechanism by which this subunit regulates light harvesting efficiency is still unknown. Here we show that PsbS controls the association/dissociation of a five-subunit membrane complex, composed of two monomeric Lhcb proteins (CP29 and CP24) and the trimeric LHCII-M. Dissociation of this supercomplex is indispensable for the onset of non-photochemical fluorescence quenching in high light, strongly suggesting that protein subunits catalyzing the reaction of heat dissipation are buried into the complex and thus not available for interaction with PsbS. Consistently, we showed that knock-out mutants on two subunits participating to the B4C complex were strongly affected in heat dissipation. Direct observation by electron microscopy and image analysis showed that B4C dissociation leads to the redistribution of PSII within grana membranes. We interpreted these results to mean that the dissociation of B4C makes quenching sites, possibly CP29 and CP24, available for the switch to an energy-quenching conformation. These changes are reversible and do not require protein synthesis/degradation, thus allowing for changes in PSII antenna size and adaptation to rapidly changing environmental conditions.

Published

2009

31. Occupancy and functional architecture of the pigment binding sites of photosystem II antenna complex Lhcb5.

Author

Ballottari M, Mozzo M, Croce R, Morosinotto T, and Bassi R

Subjects

Arabidopsis genetics, Arabidopsis Proteins genetics, Binding Sites physiology, Chlorophyll genetics, Chlorophyll A, Chlorophyll Binding Proteins, Light-Harvesting Protein Complexes genetics, Photosystem II Protein Complex genetics, Protein Binding physiology, Structure-Activity Relationship, Xanthophylls genetics, Arabidopsis enzymology, Arabidopsis Proteins metabolism, Chlorophyll metabolism, Light-Harvesting Protein Complexes metabolism, Photosystem II Protein Complex metabolism, Protein Folding, Xanthophylls metabolism

Abstract

Lhcb5 is an antenna protein that is highly conserved in plants and green algae. It is part of the inner layer of photosystem II antenna system retained in high light acclimated plants. To study the structure-function relation and the role of individual pigments in this complex, we (i) "knocked out" each of the chromophores bound to multiple (nine total) chlorophyll sites and (ii) exchanged the xanthophylls bound to the three xanthophyll sites. The occupancy and associated energy of the pigment binding sites were determined. The role of the individual pigments in protein folding, stability, energy transfer, and dissipation was studied in vitro. The results indicate that lutein has a primary role in the folding and stability of the complex, whereas violaxanthin and zeaxanthin have a negative effect on folding yield and stability, respectively. The data showed a distinct function for the L1 and L2 carotenoid binding sites, the former preferentially involved in gathering the excitation energy to chlorophyll a (Chl a), whereas the latter modulates the concentration of chlorophyll singlet excited states dependent on the xanthophylls bound to it, likely via an interaction with Chl-603. Our results also underscored the role of zeaxanthin and lutein in quenching the excitation energy, whereas violaxanthin was shown to be very effective in energy transfer. The characteristics of the isolated proteins were consistent with the observed role of Lhcb5 in vivo in catalyzing fluorescence quenching upon zeaxanthin binding.

Published

2009

32. Lutein can act as a switchable charge transfer quencher in the CP26 light-harvesting complex.

Author

Avenson TJ, Ahn TK, Niyogi KK, Ballottari M, Bassi R, and Fleming GR

Subjects

Arabidopsis Proteins metabolism, Cations, Chlorophyll Binding Proteins, Chromatography, High Pressure Liquid, Light-Harvesting Protein Complexes metabolism, Photosystem II Protein Complex metabolism, Arabidopsis metabolism, Arabidopsis Proteins drug effects, Light-Harvesting Protein Complexes drug effects, Lutein pharmacology, Photosystem II Protein Complex drug effects

Abstract

Energy-dependent quenching of excitons in photosystem II of plants, or qE, has been positively correlated with the transient production of carotenoid radical cation species. Zeaxanthin was shown to be the donor species in the CP29 antenna complex. We report transient absorbance analyses of CP24 and CP26 complexes that bind lutein and zeaxanthin in the L1 and L2 domains, respectively. For CP24 complexes, the transient absorbance difference profiles give a reconstructed transient absorbance spectrum with a single peak centered at approximately 980 nm, consistent with zeaxanthin radical cation formation. In contrast, CP26 gives constants for the decay components probed at 940 and 980 nm of 144 and 194 ps, a transient absorbance spectrum that has a main peak at 980 nm, and a substantial shoulder at 940 nm. This suggests the presence of two charge transfer quenching sites in CP26 involving zeaxanthin radical cation and lutein radical cation species. We also show that lutein radical cation formation in CP26 is dependent on binding of zeaxanthin to the L2 domain, implying that zeaxanthin acts as an allosteric effector of charge transfer quenching involving lutein in the L1 domain.

Published

2009

33. Improper excess light energy dissipation in Arabidopsis results in a metabolic reprogramming.

Author

Frenkel M, Külheim C, Jänkänpää HJ, Skogström O, Dall'Osto L, Agren J, Bassi R, Moritz T, Moen J, and Jansson S

Subjects

Acetates pharmacology, Arabidopsis drug effects, Arabidopsis genetics, Arabidopsis radiation effects, Arabidopsis Proteins genetics, Carbohydrate Metabolism, Chloroplasts metabolism, Cyclopentanes metabolism, Cyclopentanes pharmacology, Gene Expression Profiling, Gene Expression Regulation, Plant, Genotype, Light-Harvesting Protein Complexes, Oligonucleotide Array Sequence Analysis, Oxylipins metabolism, Oxylipins pharmacology, Ozone pharmacology, Photosynthesis, Photosynthetic Reaction Center Complex Proteins genetics, Photosystem II Protein Complex genetics, Stress, Physiological, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Light, Photosynthetic Reaction Center Complex Proteins metabolism, Photosystem II Protein Complex metabolism

Abstract

Background: Plant performance is affected by the level of expression of PsbS, a key photoprotective protein involved in the process of feedback de-excitation (FDE), or the qE component of non-photochemical quenching, NPQ., Results: In studies presented here, under constant laboratory conditions the metabolite profiles of leaves of wild-type Arabidopsis thaliana and plants lacking or overexpressing PsbS were very similar, but under natural conditions their differences in levels of PsbS expression were associated with major changes in metabolite profiles. Some carbohydrates and amino acids differed ten-fold in abundance between PsbS-lacking mutants and over-expressers, with wild-type plants having intermediate amounts, showing that a metabolic shift had occurred. The transcriptomes of the genotypes also varied under field conditions, and the genes induced in plants lacking PsbS were similar to those reportedly induced in plants exposed to ozone stress or treated with methyl jasmonate (MeJA). Genes involved in the biosynthesis of JA were up-regulated, and enzymes involved in this pathway accumulated. JA levels in the undamaged leaves of field-grown plants did not differ between wild-type and PsbS-lacking mutants, but they were higher in the mutants when they were exposed to herbivory., Conclusion: These findings suggest that lack of FDE results in increased photooxidative stress in the chloroplasts of Arabidopsis plants grown in the field, which elicits a response at the transcriptome level, causing a redirection of metabolism from growth towards defence that resembles a MeJA/JA response.

Published

2009

34. Trap-limited charge separation kinetics in higher plant photosystem I complexes.

Author

Slavov C, Ballottari M, Morosinotto T, Bassi R, and Holzwarth AR

Subjects

Energy Transfer, Fluorescence, Kinetics, Light-Harvesting Protein Complexes chemistry, Time Factors, Arabidopsis enzymology, Photosystem I Protein Complex chemistry, Photosystem I Protein Complex metabolism

Abstract

Time-resolved fluorescence measurements were performed on isolated core and intact Photosystem I (PS I) particles and stroma membranes from Arabidopsis thaliana to characterize the type of energy-trapping kinetics in higher plant PS I. Target analysis confirms the previously proposed "charge recombination" model. No bottleneck in the energy flow from the bulk antenna compartments to the reaction center has been found. For both particles a trap-limited kinetics is realized, with an apparent charge separation lifetime of approximately 6 ps. No red chlorophylls (Chls) are found in the PS I-core complex from A. thaliana. Rather, the observed red-shifted fluorescence (700-710 nm range) originates from the reaction center. In contrast, two red Chl compartments, located in the peripheral light-harvesting complexes, are resolved in the intact PS I particles (decay lifetimes 33 and 95 ps, respectively). These two red states have been attributed to the two red states found in Lhca 3 and Lhca 4, respectively. The influence of the red Chls on the slowing of the overall trapping kinetics in the intact PS I complex is estimated to be approximately four times larger than the effect of the bulk antenna enlargement.

Published

2008

35. Minor antenna proteins CP24 and CP26 affect the interactions between photosystem II subunits and the electron transport rate in grana membranes of Arabidopsis.

Author

de Bianchi S, Dall'Osto L, Tognon G, Morosinotto T, and Bassi R

Subjects

Chloroplasts metabolism, Chloroplasts ultrastructure, Electron Transport, Electrophoresis, Polyacrylamide Gel, Fluorescence, Kinetics, Microscopy, Electron, Scanning, Oxidation-Reduction, Protein Binding, Arabidopsis physiology, Arabidopsis Proteins physiology, Photosystem II Protein Complex metabolism

Abstract

We investigated the function of chlorophyll a/b binding antenna proteins Chlorophyll Protein 26 (CP26) and CP24 in light harvesting and regulation of photosynthesis by isolating Arabidopsis thaliana knockout lines that completely lacked one or both of these proteins. All three mutant lines had a decreased efficiency of energy transfer from trimeric light-harvesting complex II (LHCII) to the reaction center of photosystem II (PSII) due to the physical disconnection of LHCII from PSII and formation of PSII reaction center depleted domains in grana partitions. Photosynthesis was affected in plants lacking CP24 but not in plants lacking CP26: the former mutant had decreased electron transport rates, a lower DeltapH gradient across the grana membranes, reduced capacity for nonphotochemical quenching, and limited growth. Furthermore, the PSII particles of these plants were organized in unusual two-dimensional arrays in the grana membranes. Surprisingly, overall electron transport, nonphotochemical quenching, and growth of the double mutant were restored to wild type. Fluorescence induction kinetics and electron transport measurements at selected steps of the photosynthetic chain suggested that limitation in electron transport was due to restricted electron transport between Q(A) and Q(B), which retards plastoquinone diffusion. We conclude that CP24 absence alters PSII organization and consequently limits plastoquinone diffusion.

Published

2008

36. Photoprotection in the antenna complexes of photosystem II: role of individual xanthophylls in chlorophyll triplet quenching.

Author

Mozzo M, Dall'Osto L, Hienerwadel R, Bassi R, and Croce R

Subjects

Arabidopsis Proteins metabolism, Chlorophyll Binding Proteins, Light-Harvesting Protein Complexes metabolism, Arabidopsis metabolism, Chlorophyll metabolism, Lutein metabolism, Oxygen metabolism, Photosystem II Protein Complex metabolism, Xanthophylls metabolism

Abstract

In this work the photoprotective role of all xanthophylls in LHCII, Lhcb4, and Lhcb5 is investigated by laser-induced Triplet-minus-Singlet (TmS) spectroscopy. The comparison of native LHCII trimeric complexes with different carotenoid composition shows that the xanthophylls in sites V1 and N1 do not directly contribute to the chlorophyll triplet quenching. The largest part of the triplets is quenched by the lutein bound in site L1, which is located in close proximity to the chlorophylls responsible for the low energy state of the complex. The lutein in the L2 site is also active in triplet quenching, and it shows a longer triplet lifetime than the lutein in the L1 site. This lifetime difference depends on the occupancy of the N1 binding site, where neoxanthin acts as an oxygen barrier, limiting the access of O(2) to the inner domain of the Lhc complex, thereby strongly contributing to the photostability. The carotenoid triplet decay of monomeric Lhcb1, Lhcb4, and Lhcb5 is mono-exponential, with shorter lifetimes than observed for trimeric LHCII, suggesting that their inner domains are more accessible for O(2). As for trimeric LHCII, only the xanthophylls in sites L1 and L2 are active in triplet quenching. Although the chlorophyll to carotenoid triplet transfer is efficient (95%) in all complexes, it is not perfect, leaving 5% of the chlorophyll triplets unquenched. This effect appears to be intrinsically related to the molecular organization of the Lhcb proteins.

Published

2008

37. Zeaxanthin radical cation formation in minor light-harvesting complexes of higher plant antenna.

Author

Avenson TJ, Ahn TK, Zigmantas D, Niyogi KK, Li Z, Ballottari M, Bassi R, and Fleming GR

Subjects

Dimerization, Hydrogen-Ion Concentration, Kinetics, Models, Chemical, Models, Molecular, Plant Physiological Phenomena, Spectrometry, Fluorescence, Spectrophotometry methods, Spectroscopy, Near-Infrared, Thylakoids metabolism, Zeaxanthins, Arabidopsis metabolism, Cations, Gene Expression Regulation, Plant, Light-Harvesting Protein Complexes chemistry, Xanthophylls chemistry

Abstract

Previous work on intact thylakoid membranes showed that transient formation of a zeaxanthin radical cation was correlated with regulation of photosynthetic light-harvesting via energy-dependent quenching. A molecular mechanism for such quenching was proposed to involve charge transfer within a chlorophyll-zeaxanthin heterodimer. Using near infrared (880-1100 nm) transient absorption spectroscopy, we demonstrate that carotenoid (mainly zeaxanthin) radical cation generation occurs solely in isolated minor light-harvesting complexes that bind zeaxanthin, consistent with the engagement of charge transfer quenching therein. We estimated that less than 0.5% of the isolated minor complexes undergo charge transfer quenching in vitro, whereas the fraction of minor complexes estimated to be engaged in charge transfer quenching in isolated thylakoids was more than 80 times higher. We conclude that minor complexes which bind zeaxanthin are sites of charge transfer quenching in vivo and that they can assume Non-quenching and Quenching conformations, the equilibrium LHC(N) <==> LHC(Q) of which is modulated by the transthylakoid pH gradient, the PsbS protein, and protein-protein interactions.

Published

2008

38. Zeaxanthin has enhanced antioxidant capacity with respect to all other xanthophylls in Arabidopsis leaves and functions independent of binding to PSII antennae.

Author

Havaux M, Dall'osto L, and Bassi R

Subjects

Arabidopsis genetics, Arabidopsis Proteins metabolism, Chlorophyll genetics, Chlorophyll metabolism, Chlorophyll Binding Proteins, Crosses, Genetic, Intramolecular Transferases metabolism, Light, Light-Harvesting Protein Complexes metabolism, Mutation, Phenotype, Zeaxanthins, Antioxidants metabolism, Arabidopsis metabolism, Photosystem II Protein Complex metabolism, Plant Leaves metabolism, Xanthophylls metabolism

Abstract

The ch1 mutant of Arabidopsis (Arabidopsis thaliana) lacks chlorophyll (Chl) b. Leaves of this mutant are devoid of photosystem II (PSII) Chl-protein antenna complexes and have a very low capacity of nonphotochemical quenching (NPQ) of Chl fluorescence. Lhcb5 was the only PSII antenna protein that accumulated to a significant level in ch1 mutant leaves, but the apoprotein did not assemble in vivo with Chls to form a functional antenna. The abundance of Lhca proteins was also reduced to approximately 20% of the wild-type level. ch1 was crossed with various xanthophyll mutants to analyze the antioxidant activity of carotenoids unbound to PSII antenna. Suppression of zeaxanthin by crossing ch1 with npq1 resulted in oxidative stress in high light, while removing other xanthophylls or the PSII protein PsbS had no such effect. The tocopherol-deficient ch1 vte1 double mutant was as sensitive to high light as ch1 npq1, and the triple mutant ch1 npq1 vte1 exhibited an extreme sensitivity to photooxidative stress, indicating that zeaxanthin and tocopherols have cumulative effects. Conversely, constitutive accumulation of zeaxanthin in the ch1 npq2 double mutant led to an increased phototolerance relative to ch1. Comparison of ch1 npq2 with another zeaxanthin-accumulating mutant (ch1 lut2) that lacks lutein suggests that protection of polyunsaturated lipids by zeaxanthin is enhanced when lutein is also present. During photooxidative stress, alpha-tocopherol noticeably decreased in ch1 npq1 and increased in ch1 npq2 relative to ch1, suggesting protection of vitamin E by high zeaxanthin levels. Our results indicate that the antioxidant activity of zeaxanthin, distinct from NPQ, can occur in the absence of PSII light-harvesting complexes. The capacity of zeaxanthin to protect thylakoid membrane lipids is comparable to that of vitamin E but noticeably higher than that of all other xanthophylls of Arabidopsis leaves.

Published

2007

39. The light stress-induced protein ELIP2 is a regulator of chlorophyll synthesis in Arabidopsis thaliana.

Author

Tzvetkova-Chevolleau T, Franck F, Alawady AE, Dall'Osto L, Carrière F, Bassi R, Grimm B, Nussaume L, and Havaux M

Subjects

Arabidopsis Proteins biosynthesis, Arabidopsis Proteins radiation effects, Ferrochelatase genetics, Ferrochelatase metabolism, Gene Expression Regulation, Plant, Oxidative Stress, Plant Leaves physiology, Plants, Genetically Modified metabolism, Arabidopsis metabolism, Arabidopsis Proteins genetics, Chlorophyll biosynthesis, Light adverse effects, Photosynthesis

Abstract

The early light-induced proteins (ELIPs) belong to the multigenic family of pigment-binding light-harvesting complexes. ELIPs accumulate transiently and are believed to play a protective role in plants exposed to high levels of light. Constitutive expression of the ELIP2 gene in Arabidopsis resulted in a marked reduction of the pigment content of the chloroplasts, both in mature leaves and during greening of etiolated seedlings. The chlorophyll loss was associated with a decrease in the number of photosystems in the thylakoid membranes, but the photosystems present were fully assembled and functional. A detailed analysis of the chlorophyll-synthesizing pathway indicated that ELIP2 accumulation downregulated the level and activity of two important regulatory steps: 5-aminolevulinate synthesis and Mg-protoporphyrin IX (Mg-Proto IX) chelatase activity. The contents of glutamyl tRNA reductase and Mg chelatase subunits CHLH and CHLI were lowered in response to ELIP2 accumulation. In contrast, ferrochelatase activity was not affected and the inhibition of Heme synthesis was null or very moderate. As a result of reduced metabolic flow from 5-aminolevulinic acid, the steady state levels of various chlorophyll precursors (from protoporphyrin IX to protochlorophyllide) were strongly reduced in the ELIP2 overexpressors. Taken together, our results indicate that the physiological function of ELIPs could be related to the regulation of chlorophyll concentration in thylakoids. This seems to occur through an inhibition of the entire chlorophyll biosynthesis pathway from the initial precursor of tetrapyrroles, 5-aminolevulinic acid. We suggest that ELIPs work as chlorophyll sensors that modulate chlorophyll synthesis to prevent accumulation of free chlorophyll, and hence prevent photooxidative stress.

Published

2007

40. Singlet and triplet state transitions of carotenoids in the antenna complexes of higher-plant photosystem I.

Author

Croce R, Mozzo M, Morosinotto T, Romeo A, Hienerwadel R, and Bassi R

Subjects

Arabidopsis chemistry, Arabidopsis genetics, Arabidopsis Proteins chemistry, Arabidopsis Proteins genetics, Binding Sites, Carotenoids chemistry, Carotenoids genetics, Chlorophyll Binding Proteins, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes genetics, Photosystem I Protein Complex chemistry, Photosystem I Protein Complex genetics, Plants, Genetically Modified chemistry, Plants, Genetically Modified genetics, Plants, Genetically Modified metabolism, Spectrometry, Fluorescence, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Carotenoids metabolism, Light-Harvesting Protein Complexes metabolism, Photosystem I Protein Complex metabolism

Abstract

In this work, the spectroscopic characteristics of carotenoids associated with the antenna complexes of Photosystem I have been studied. Pigment composition, absorption spectra, and laser-induced triplet-minus-singlet (T-S) spectra were determined for native LHCI from the wild type (WT) and lut2 mutant from Arabidopsis thaliana as well as for reconstituted individual Lhca WT and mutated complexes. All WT complexes bind lutein and violaxanthin, while beta-carotene was found to be associated only with the native LHCI preparation and recombinant Lhca3. In the native complexes, the main lutein absorption bands are located at 492 and 510 nm. It is shown that violaxanthin is able to occupy all lutein binding sites, but its absorption is blue-shifted to 487 and 501 nm. The "red" lutein absorbing at 510 nm was found to be associated with Lhca3 and Lhca4 which also show a second carotenoid, peaking around 490 nm. Both these xanthophylls are involved in triplet quenching and show two T-S maxima: one at 507 nm (corresponding to the 490 nm singlet absorption) and the second at 525 nm (with absorption at 510 nm). The "blue"-absorbing xanthophyll is located in site L1 and can receive triplets from chlorophylls (Chl) 1012, 1011, and possibly 1013. The red-shifted spectral component is assigned to a lutein molecule located in the L2 site. A 510 nm lutein was also observed in the trimers of LHCII but was absent in the monomers. In the case of Lhca, the 510 nm band is present in both the monomeric and dimeric complexes. We suggest that the large red shift observed for this xanthophyll is due to interaction with the neighbor Chl 1015. In the native T-S spectrum, the contribution of carotenoids associated with Lhca2 is visible while the one of Lhca1 is not. This suggests that in the Lhca2-Lhca3 heterodimeric complex energy equilibration is not complete at least on a fast time scale.

Published

2007

41. Contrasting behavior of higher plant photosystem I and II antenna systems during acclimation.

Author

Ballottari M, Dall'Osto L, Morosinotto T, and Bassi R

Subjects

Chloroplasts metabolism, Electron Transport, Light, Light-Harvesting Protein Complexes, Peptides chemistry, Photosynthesis, Photosystem II Protein Complex metabolism, Plant Physiological Phenomena, Temperature, Xanthophylls metabolism, Acclimatization, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Photosynthetic Reaction Center Complex Proteins metabolism, Photosystem I Protein Complex physiology, Photosystem II Protein Complex physiology, Plant Proteins metabolism

Abstract

In this work we analyzed the photosynthetic apparatus in Arabidopsis thaliana plants acclimated to different light intensity and temperature conditions. Plants showed the ability to acclimate into different environments and avoid photoinhibition. When grown in high light, plants had a faster activation rate for energy dissipation (qE). This ability was correlated to higher accumulation levels of a specific photosystem II subunit, PsbS. The photosystem II antenna size was also regulated according to light exposure; smaller antenna size was observed in high light-acclimated plants with respect to low light plants. Different antenna polypeptides did not behave similarly, and Lhcb1, Lchb2, and Lhcb6 (CP24) are shown to undergo major levels of regulation, whereas Lhcb4 and Lhcb5 (CP29 and CP26) maintained their stoichiometry with respect to the reaction center in all growth conditions. The effect of acclimation on photosystem I antenna was different; in fact, the stoichiometry of any Lhca antenna proteins with respect to photosystem I core complex was not affected by growth conditions. Despite this stability in antenna stoichiometry, photosystem I light harvesting function was shown to be regulated through different mechanisms like the control of photosystem I to photosystem II ratio and the association or dissociation of Lhcb polypeptides to photosystem I.

Published

2007

42. The Arabidopsis aba4-1 mutant reveals a specific function for neoxanthin in protection against photooxidative stress.

Author

Dall'Osto L, Cazzaniga S, North H, Marion-Poll A, and Bassi R

Subjects

Arabidopsis drug effects, Binding Sites, Centrifugation, Density Gradient, Chlorophyll metabolism, Energy Metabolism drug effects, Energy Metabolism radiation effects, Free Radical Scavengers metabolism, Light-Harvesting Protein Complexes isolation & purification, Light-Harvesting Protein Complexes metabolism, Models, Molecular, Molecular Sequence Data, Oxidants pharmacology, Oxidative Stress drug effects, Photosynthesis radiation effects, Photosynthetic Reaction Center Complex Proteins metabolism, Photosystem II Protein Complex metabolism, Plant Leaves drug effects, Plant Leaves metabolism, Plant Leaves radiation effects, Protein Binding drug effects, Protein Binding radiation effects, Reactive Oxygen Species metabolism, Temperature, Arabidopsis metabolism, Arabidopsis radiation effects, Arabidopsis Proteins metabolism, Light, Mutation genetics, Oxidative Stress radiation effects, Xanthophylls metabolism

Abstract

The aba4-1 mutant completely lacks neoxanthin but retains all other xanthophyll species. The missing neoxanthin in light-harvesting complex (Lhc) proteins is compensated for by higher levels of violaxanthin, albeit with lower capacity for photoprotection compared with proteins with wild-type levels of neoxanthin. Detached leaves of aba4-1 were more sensitive to oxidative stress than the wild type when exposed to high light and incubated in a solution of photosensitizer agents. Both treatments caused more rapid pigment bleaching and lipid oxidation in aba4-1 than wild-type plants, suggesting that neoxanthin acts as an antioxidant within the photosystem II (PSII) supercomplex in thylakoids. While neoxanthin-depleted Lhc proteins and leaves had similar sensitivity as the wild type to hydrogen peroxide and singlet oxygen, they were more sensitive to superoxide anions. aba4-1 intact plants were not more sensitive than the wild type to high-light stress, indicating the existence of compensatory mechanisms of photoprotection involving the accumulation of zeaxanthin. However, the aba4-1 npq1 double mutant, lacking zeaxanthin and neoxanthin, underwent stronger PSII photoinhibition and more extensive oxidation of pigments than the npq1 mutant, which still contains neoxanthin. We conclude that neoxanthin preserves PSII from photoinactivation and protects membrane lipids from photooxidation by reactive oxygen species. Neoxanthin appears particularly active against superoxide anions produced by the Mehler's reaction, whose rate is known to be enhanced in abiotic stress conditions.

Published

2007

43. Elucidation of the beta-carotene hydroxylation pathway in Arabidopsis thaliana.

Author

Fiore A, Dall'osto L, Fraser PD, Bassi R, and Giuliano G

Subjects

Arabidopsis genetics, Base Sequence, DNA Primers, Genes, Plant, Hydroxylation, Reverse Transcriptase Polymerase Chain Reaction, Arabidopsis metabolism, beta Carotene metabolism

Abstract

The first dedicated step in plant xanthophyll biosynthesis is carotenoid hydroxylation. In Arabidopsis thaliana, this reaction is performed by both heme (LUT1 and LUT5) and non-heme (CHY1 and CHY2) hydroxylases. No mutant completely abolishing alpha- or beta-carotene hydroxylation has been described to date. We constructed double and triple mutant combinations in CHY1, CHY2, LUT1, LUT5 and LUT2 (lycopene epsilon-cyclase). In chy1chy2lut2, 80% of leaf carotenoids is represented by beta-carotene. In chy1chy2lut5, beta-carotene hydroxylation is completely abolished, while hydroxylation of the beta-ring of alpha-carotene is still observed. The data are consistent with a role of LUT5 in beta-ring hydroxylation, and with the existence of an additional hydroxylase, acting on the beta-ring of alpha-, but not beta-carotene.

Published

2006

44. The association of the antenna system to photosystem I in higher plants. Cooperative interactions stabilize the supramolecular complex and enhance red-shifted spectral forms.

Author

Morosinotto T, Ballottari M, Klimmek F, Jansson S, and Bassi R

Subjects

Arabidopsis Proteins chemistry, Circular Dichroism, Electrophoresis, Gel, Two-Dimensional, Electrophoresis, Polyacrylamide Gel methods, Light, Molecular Structure, Pigments, Biological chemistry, Protein Conformation, Protein Denaturation, Thylakoids chemistry, Thylakoids metabolism, Arabidopsis chemistry, Arabidopsis physiology, Arabidopsis Proteins metabolism, Light-Harvesting Protein Complexes physiology, Photosystem I Protein Complex physiology

Abstract

We report on the association of the antenna system to the reaction center in Photosystem I. Biochemical analysis of mutants depleted in antenna polypeptides showed that the binding of the antenna moiety is strongly cooperative. The minimal building block for the antenna system was shown to be a dimer. Specific protein-protein interactions play an important role in antenna association, and the gap pigments, bound at the interface between core and antenna, are proposed to mediate these interactions Gap pigments have been characterized by comparing the spectra of the Photosystem I to those of the isolated antenna and core components. CD spectroscopy showed that they are involved in pigment-pigment interactions, supporting their relevance in energy transfer from antenna to the reaction center. Moreover, gap pigments contribute to the red-shifted emission forms of Photosystem I antenna. When compared with Photosystem II, the association of peripheral antenna complexes in PSI appears to be more stable, but far less flexible and functional implications are discussed.

Published

2005

45. A mechanism of nonphotochemical energy dissipation, independent from PsbS, revealed by a conformational change in the antenna protein CP26.

Author

Dall'Osto L, Caffarri S, and Bassi R

Subjects

Allosteric Site physiology, Arabidopsis Proteins metabolism, Binding Sites physiology, Carotenoids biosynthesis, Chlorophyll metabolism, Chlorophyll Binding Proteins, Light-Harvesting Protein Complexes metabolism, Mutation physiology, Photosystem II Protein Complex metabolism, Protein Binding physiology, Protein Conformation radiation effects, Xanthophylls, Zeaxanthins, beta Carotene metabolism, Arabidopsis metabolism, Arabidopsis Proteins chemistry, Energy Metabolism physiology, Light-Harvesting Protein Complexes chemistry, Photosynthesis physiology, Photosystem II Protein Complex chemistry, beta Carotene analogs & derivatives

Abstract

The regulation of light harvesting in higher plant photosynthesis, defined as stress-dependent modulation of the ratio of energy transfer to the reaction centers versus heat dissipation, was studied by means of carotenoid biosynthesis mutants and recombinant light harvesting complexes (LHCs) with modified chromophore binding. The npq2 mutant of Arabidopsis thaliana, blocked in the biosynthesis of violaxanthin and thus accumulating zeaxanthin, was shown to have a lower fluorescence yield of chlorophyll in vivo and, correspondingly, a higher level of energy dissipation, with respect to the wild-type strain and npq1 mutant, the latter of which is incapable of zeaxanthin accumulation. Experiments on purified thylakoid membranes from all three mutants showed that the major source of the difference between the npq2 and wild-type preparations was a change in pigment to protein interactions, which can explain the lower chlorophyll fluorescence yield in the npq2 samples. Analysis of the xanthophyll binding LHC proteins showed that the Lhcb5 photosystem II subunit (also called CP26) undergoes a change in its pI upon binding of zeaxanthin. The same effect was observed in wild-type CP26 upon treatment that leads to the accumulation of zeaxanthin in the membrane and was interpreted as the consequence of a conformational change. This hypothesis was confirmed by the analysis of two recombinant proteins obtained by overexpression of the Lhcb5 apoprotein in Escherichia coli and reconstitution in vitro with either violaxanthin or zeaxanthin. The V and Z containing pigment-protein complexes obtained by this procedure showed different pIs and high and low fluorescence yields, respectively. These results confirm that LHC proteins exist in multiple conformations, an idea suggested by previous spectroscopic measurements (Moya et al., 2001), and imply that the switch between the different LHC protein conformations is activated by the binding of zeaxanthin to the allosteric site L2. The results suggest that the quenching process induced by the accumulation of zeaxanthin contributes to qI, a component of NPQ whose origin was previously poorly understood.

Published

2005

46. Origin of the 701-nm fluorescence emission of the Lhca2 subunit of higher plant photosystem I.

Author

Croce R, Morosinotto T, Ihalainen JA, Chojnicka A, Breton J, Dekker JP, van Grondelle R, and Bassi R

Subjects

Anisotropy, Arabidopsis Proteins metabolism, Chlorophyll chemistry, Chlorophyll Binding Proteins, Chromatography, High Pressure Liquid, Circular Dichroism, DNA, Complementary chemistry, Hydrogen Bonding, Light-Harvesting Protein Complexes metabolism, Mutation, Normal Distribution, Recombinant Proteins chemistry, Spectrometry, Fluorescence, Spectrophotometry, Temperature, Arabidopsis metabolism, Arabidopsis Proteins chemistry, Light-Harvesting Protein Complexes chemistry, Photosystem I Protein Complex chemistry, Photosystem I Protein Complex metabolism, Plant Proteins chemistry

Abstract

Photosystem I of higher plants is characterized by red-shifted spectral forms deriving from chlorophyll chromophores. Each of the four Lhca1 to -4 subunits exhibits a specific fluorescence emission spectrum, peaking at 688, 701, 725, and 733 nm, respectively. Recent analysis revealed the role of chlorophyll-chlorophyll interactions of the red forms in Lhca3 and Lhca4, whereas the basis for the fluorescence emission at 701 nm in Lhca2 is not yet clear. We report a detailed characterization of the Lhca2 subunit using molecular biology, biochemistry, and spectroscopy and show that the 701-nm emission form originates from a broad absorption band at 690 nm. Spectroscopy on recombinant mutant proteins assesses that this band represents the low energy form of an excitonic interaction involving two chlorophyll a molecules bound to sites A5 and B5, the same protein domains previously identified for Lhca3 and Lhca4. The resulting emission is, however, substantially shifted to higher energies. These results are discussed on the basis of the structural information that recently became available from x-ray crystallography (Ben Shem, A., Frolow, F., and Nelson, N. (2003) Nature 426, 630-635). We suggest that, within the Lhca subfamily, spectroscopic properties of chromophores are modulated by the strength of the excitonic coupling between the chromophores A5 and B5, thus yielding fluorescence emission spanning a large wavelength interval. It is concluded that the interchromophore distance rather than the transition energy of the individual chromophores or the orientation of transition vectors represents the critical factor in determining the excitonic coupling in Lhca pigment-protein complexes.

Published

2004

47. The effect of zeaxanthin as the only xanthophyll on the structure and function of the photosynthetic apparatus in Arabidopsis thaliana.

Author

Havaux M, Dall'Osto L, Cuiné S, Giuliano G, and Bassi R

Subjects

Acclimatization physiology, Apoproteins metabolism, Electron Transport, Mutation, Oxidative Stress physiology, Phenotype, Photosystem II Protein Complex chemistry, Photosystem II Protein Complex genetics, Photosystem II Protein Complex metabolism, Plant Leaves physiology, Protein Structure, Tertiary, Xanthophylls, Zeaxanthins, beta Carotene analogs & derivatives, Arabidopsis physiology, Photosynthesis physiology, Plant Proteins, beta Carotene genetics, beta Carotene metabolism

Abstract

In green plants, the xanthophyll carotenoid zeaxanthin is synthesized transiently under conditions of excess light energy and participates in photoprotection. In the Arabidopsis lut2 npq2 double mutant, all xanthophylls were replaced constitutively by zeaxanthin, the only xanthophyll whose synthesis was not impaired. The relative proportions of the different chlorophyll antenna proteins were strongly affected with respect to the wild-type strain. The major antenna, LHCII, did not form trimers, and its abundance was strongly reduced as was CP26, albeit to a lesser extent. In contrast, CP29, CP24, LHCI proteins, and the PSI and PSII core complexes did not undergo major changes. PSII-LHCII supercomplexes were not detectable while the PSI-LHCI supercomplex remained unaffected. The effect of zeaxanthin accumulation on the stability of the different Lhc proteins was uneven: the LHCII proteins from lut2 npq2 had a lower melting temperature as compared with the wild-type complex while LHCI showed increased resistance to heat denaturation. Consistent with the loss of LHCII, light-state 1 to state 2 transitions were suppressed, the photochemical efficiency in limiting light was reduced and photosynthesis was saturated at higher light intensities in lut2 npq2 leaves, resulting in a photosynthetic phenotype resembling that of high light-acclimated leaves. Zeaxanthin functioned in vivo as a light-harvesting accessory pigment in lut2 npq2 chlorophyll antennae. As a whole, the in vivo data are consistent with the results obtained by using recombinant Lhc proteins reconstituted in vitro with purified zeaxanthin. While PSII photoinhibition was similar in wild type and lut2 npq2 exposed to high light at low temperature, the double mutant was much more resistant to photooxidative stress and lipid peroxidation than the wild type. The latter observation is consistent with an antioxidant and lipid protective role of zeaxanthin in vivo.

Published

2004

48. Light harvesting complex I is essential for Photosystem II photoprotection under variable light conditions in Arabidopsis thaliana.

Author

Bressan, Mauro, Bassi, Roberto, and Dall’Osto, Luca

Subjects

*PHOTOSYSTEMS, *ARABIDOPSIS, *CHLOROPHYLL-binding proteins, *LIGHT-harvesting complex (Photosynthesis), *IRRADIATION

Abstract

Higher plant Photosystem I (PSI) includes a peripheral antenna system (LHCI) composed of four light-harvesting proteins (Lhca1-Lhca4). The LHCI system is highly conserved, suggesting that it plays a specific role within the LHC family. In order to elucidate the specific function of LHCI, the phenotype of an Arabidopsis mutant devoid of the whole LHCI system was studied over a range of conditions, including rapid changes in irradiation. ΔLhca plants displayed stunted growth and reduced thylakoid lumen acidification respect to wild type, suggesting that the lack of LHCI affected electron transport rate. Under rapidly changing light intensity, growth rate of the mutant was further reduced and the redox balance of the photosynthetic electron chain impaired. Instead, under constant, excess light regime, the ΔLhca plants did not suffer enhanced photooxidation vs. wild type, implying LHCI optimizes the flow rate through the electron transport chain by maintaining high PSI activity at all irradiances. We conclude that a complete PSI supercomplex, including LHCI, is crucial for the dynamic regulation of PQ redox state and therefore for PSII photoprotection. [ABSTRACT FROM AUTHOR]

Published

2018

49. The Arabidopsis szl1 Mutant Reveals a Critical Role of β-Carotene in Photosystem I Photoprotection1[C][W]

Author

Cazzaniga, Stefano, Li, Zhirong, Niyogi, Krishna K., Bassi, Roberto, and Dall’Osto, Luca

Subjects

Chlorophyll, Genotype, Light, Photosystem I Protein Complex, Arabidopsis Proteins, Arabidopsis, Temperature, food and beverages, Xanthophylls, beta Carotene, Fluorescence, Electron Transport, Superoxides, Mutation, Chlorophyll Binding Proteins, Photosynthesis, Energy Metabolism, Intramolecular Lyases, Oxidation-Reduction, Bioenergetics and Photosynthesis

Abstract

Carotenes and their oxygenated derivatives, the xanthophylls, are structural determinants in both photosystems (PS) I and II. They bind and stabilize photosynthetic complexes, increase the light-harvesting capacity of chlorophyll-binding proteins, and have a major role in chloroplast photoprotection. Localization of carotenoid species within each PS is highly conserved: Core complexes bind carotenes, whereas peripheral light-harvesting systems bind xanthophylls. The specific functional role of each xanthophyll species has been recently described by genetic dissection, however the in vivo role of carotenes has not been similarly defined. Here, we have analyzed the function of carotenes in photosynthesis and photoprotection, distinct from that of xanthophylls, by characterizing the suppressor of zeaxanthin-less (szl) mutant of Arabidopsis (Arabidopsis thaliana) which, due to the decreased activity of the lycopene-β-cyclase, shows a lower carotene content than wild-type plants. When grown at room temperature, mutant plants showed a lower content in PSI light-harvesting complex I complex than the wild type, and a reduced capacity for chlorophyll fluorescence quenching, the rapidly reversible component of nonphotochemical quenching. When exposed to high light at chilling temperature, szl1 plants showed stronger photoxidation than wild-type plants. Both PSI and PSII from szl1 were similarly depleted in carotenes and yet PSI activity was more sensitive to light stress than PSII as shown by the stronger photoinhibition of PSI and increased rate of singlet oxygen release from isolated PSI light-harvesting complex I complexes of szl1 compared with the wild type. We conclude that carotene depletion in the core complexes impairs photoprotection of both PS under high light at chilling temperature, with PSI being far more affected than PSII.

Published

2012

50. Photoprotection in the antenna complexes of photosystem II:Role of individual xanthophylls in chlorophyll triplet quenching

Author

Mozzo, Milena, Dall'Osto, Luca, Hienerwadel, Rainer, Bassi, Roberto, Croce, Roberta, Biophysics Photosynthesis/Energy, and LaserLaB - Energy

Subjects

Chlorophyll, triplet quenching, Arabidopsis Proteins, Lutein, Arabidopsis, Light-Harvesting Protein Complexes, Photosystem II Protein Complex, Xanthophylls, Oxygen, photoprotection, SDG 7 - Affordable and Clean Energy, Chlorophyll Binding Proteins, xanthophylls

Abstract

In this work the photoprotective role of all xanthophylls in LHCII, Lhcb4, and Lhcb5 is investigated by laser-induced Triplet-minus-Singlet (TmS) spectroscopy. The comparison of native LHCII trimeric complexes with different carotenoid composition shows that the xanthophylls in sites V1 and N1 do not directly contribute to the chlorophyll triplet quenching. The largest part of the triplets is quenched by the lutein bound in site L1, which is located in close proximity to the chlorophylls responsible for the low energy state of the complex. The lutein in the L2 site is also active in triplet quenching, and it shows a longer triplet lifetime than the lutein in the L1 site. This lifetime difference depends on the occupancy of the N1 binding site, where neoxanthin acts as an oxygen barrier, limiting the access of O2 to the inner domain of the Lhc complex, thereby strongly contributing to the photostability. The carotenoid triplet decay of monomeric Lhcb1, Lhcb4, and Lhcb5 is mono-exponential, with shorter lifetimes than observed for trimeric LHCII, suggesting that their inner domains are more accessible for O2. As for trimeric LHCII, only the xanthophylls in sites L1 and L2 are active in triplet quenching. Although the chlorophyll to carotenoid triplet transfer is efficient (95%) in all complexes, it is not perfect, leaving 5% of the chlorophyll triplets unquenched. This effect appears to be intrinsically related to the molecular organization of the Lhcb proteins.

Published

2008