Project description:Non-photochemical quenching (NPQ), the dissipation of excess light energy as heat, has been long recognized as a major protective mechanism that minimizes the potential for oxidative damage to photosystem II (PSII) reaction centers. Two major positive contributors to NPQ are the carotenoid zeaxanthin, generated from violaxanthin by the enzyme violaxanthin de epoxidase (VDE or NPQ1), and the thylakoid protein PsbS (NPQ4). The involvement of the lumenal Deg proteases in the repair of PSII from photoinhibition prompted us to further explore their possible role in other responses of Arabidopsis thaliana to high light. Here we show that upon exposure to high light, the single deg1 and the triple deg158 mutants display different levels and kinetics of NPQ, compared to the deg58 mutant and WT that behave alike. In response to high light, the two genotypes lacking Deg1 over-accumulate NPQ1 and NPQ4. After temporal inhibition of protein translation in vivo, the level of these two proteins in deg1 is higher than in WT. Together, the results suggest that Deg1 represents a new level of regulation of the NPQ process through adjusting the quantity of NPQ1 and NPQ4 proteins, probably through their proteolysis.

Project description:Photosynthesis, the fundamental process using light energy to convert carbon dioxide to organic matter, is vital for life on Earth. It relies on capturing light through light-harvesting complexes (LHC) in photosystem I (PSI) and PSII and on the conversion of light energy into chemical energy. Composition and organization of PSI and PSII core complexes are well conserved across evolution. PSII is particularly sensitive to photodamage but benefits from a large diversity of photoprotective mechanisms, finely tuned to handle the dynamic and ever-changing light conditions. Light Harvesting Complex protein family members (LHC and LHC-like families) have acquired a dual function during evolution. Members of the LHC antenna complexes of PS capture light energy, whereas others dissipate excess energy that cannot be harnessed for photosynthesis. This process mainly occurs through nonphotochemical quenching (NPQ). In this work, we focus on the Light Harvesting complex-Like 4 (LHL4) protein, a LHC-like protein induced by ultraviolet-B (UV-B) and blue light through UV Resistance locus 8 (UVR8) and phototropin photoreceptor-activated signaling pathways in the model green microalgae Chlamydomonas reinhardtii. We demonstrate that alongside established NPQ effectors, LHL4 plays a key role in photoprotection, preventing singlet oxygen accumulation in PSII and promoting cell survival upon light stress. LHL4 protective function is distinct from that of NPQ-related proteins, as LHL4 specifically and uniquely binds to the transient monomeric form of the core PSII complex, safeguarding its integrity. LHL4 characterization expands our understanding of the interplay between light harvesting and photoprotection mechanisms upon light stress in photosynthetic microalgae.

Project description:PsbS Protein Interactions during Non-photochemical quenching The non-photochemical quenching of excitation energy (NPQ) describes a photoprotective mechanism in the antenna of PSII which dissipates excess excitation energy as heat at the level of 1Chl* and by that prevents the formation of singlet oxygen in PSII. Four different components contribute to NPQ, namely qT, qE, qZ and qI. Under saturating light conditions, the qE represents the dominant NPQ component; qE is based on a complex mechanism which strictly depends on the ΔpH across the thylakoid membrane, the PsbS protein and the xanthophyll zeaxanthin (Zx). The central role of PsbS in these processes is related to the function of PsbS as sensor of the lumen pH. However, the molecular basis of this central function and particularly the underlying interactions of PsbS with PSII antenna proteins that lead to energy quenching are largely unclear. In this work, we present an in vitro approach to identify protein transient interactions involving the PsbS protein during NPQ induction and relaxation in Arabidopsis thaliana, revealing its direct role in the formation of quenching sites in the antenna complexes of photosystem II.

Project description:Coping of evergreen conifers of boreal forests with freezing temperatures on bright winter days puts the photosynthetic machinery in great risk of oxidative damage. To survive harsh winter conditions, conifers have evolved a unique but poorly characterised photoprotection mechanism, a sustained form of non-photochemical quenching (sustained NPQ). Here we focused on functional properties and underlying molecular mechanisms related to the development of sustained NPQ in Norway spruce (Picea abies). Data was collected during four consecutive years (2016-19) from trees growing in sun and shade habitats. When day temperatures dropped below -4°C, specific N-terminally triply phosphorylated LHCB1 isoform (3p-LHCII) and phosphorylated PSBS (p-PSBS) were detected in the thylakoid membrane. Development of sustained NPQ coincided with the highest level of 3p-LHCII and p-PSBS, occurring after prolonged combination of bright winter days and temperature close to -10°C. Artificial induction of both the sustained NPQ and recovery from naturally induced sustained NPQ provided information on differential dynamics and light-dependence of 3p-LHCII and p-PSBS accumulation and dephosphorylation as essential prerequisites of sustained NPQ. Data obtained collectively suggest three novel components related to sustained NPQ in spruce. (i) Freezing temperatures induce 3p-LHCII accumulation independently of light, which is suggested to initiate de-stacking of appressed thylakoid membranes due to increased electrostatic repulsion of adjacent membranes. (ii) p-PSBS accumulation is both light- and temperature-dependent and closely linked to the initiation of sustained NPQ, which (iii) in concert with PSII photoinhibition is likely to trigger sustained NPQ in spruce.

Project description:The membrane-integrated metallo-protease FtsH11 of Arabidopsis thaliana is proposed to be dual targeted to mitochondria and chloroplasts. A bleached phenotype was observed in ftsh11 grown at long days or continuous light, pointing to disturbances in the chloroplast. Under these growth conditions the morphology of the chloroplast became drastically altered, accompanied by a drop of NPQ, and the amount of PSI decreased relative to PSII. The abundance of plastidic proteins, especially of photosynthetic proteins, was altered in ftsh11 even during growth in normal conditions and short days. FtsH11 is crucial for chloroplast structure and function during growth in prolonged photoperiod . In chloroplasts FtsH11 was found to be located exclusively in the chloroplast envelope. Thanks to proteomic analyses, the Tic22-like protein and YGGT, both chloroplast proteins of unknown function, are proposed to be the substrates of FtsH11 .

Project description:Photosynthesis, the fundamental process using light energy to convert CO2 to organic matter, is vital for life on Earth. It relies on capturing light through light-harvesting complexes in photosystems I and II and converting light energy into chemical energy. Composition and organization of photosystem core complexes are well conserved across evolution, and are highly susceptible to photodamage. Consequently, a large diversity of photoprotective mechanisms have evolved in photoautotrophs, finely tuned for the specific light conditions. Light Harvesting Complex protein family (LHC and LHC-like families) have acquired a dual function during evolution. Members of the LHC antenna complexes of photosystems capture light energy whereas others dissipate excess energy that cannot be harnessed for photosynthesis. This process mainly occurs through non photochemical quenching (NPQ). In this work, we focus on the LHL4 protein, which is induced by UV-B and blue light photoreceptor signaling pathways in the model green microalgae Chlamydomonas reinhardtii. Our work demonstrates that alongside established NPQ effectors, LHL4 plays a key role in photoprotection, preventing singlet oxygen accumulation in photosystem II and thereby promoting cell survival upon light stress. LHL4 protective function is distinct from that of NPQ-related proteins, since it directly binds to the transient monomeric form of the core photosystem II complex, safeguarding its integrity. Our LHL4 characterization expands our understanding of the interplay between light harvesting and photoprotection mechanisms upon light stress in photosynthetic microalgae.

Project description:Drought is a major cause of crop yield loss worldwide. Plants can adopt different mechanisms to survive under water deficit, where stomatal closure leads to CO2 limitation. This requires increased dissipation of light energy as heat by non-photochemical quenching (NPQ), changes in the structural configuration of light-harvesting complexes, or changes in the mode of photosynthetic electron flow (i.e. linear vs. cyclic). Under field conditions, where light intensity can change rapidly, this problem becomes even more challenging. Particularly the slow release from photoprotection (NPQ relaxation) was recently shown to cause significant loss of potential yield. We analyzed the acclimation of two different wheat varieties and compared their molecular acclimation strategy to Arabidopsis under moderate drought stress at a slow soil dehydration rate, mimicking realistic field conditions. We monitored their photosynthetic activity under fluctuating light intensities and integrated functional and structural data, based on a detailed analysis of photosynthetic parameters combined with biochemical analysis and unbiased shot-gun proteomics. Contrary to previous models based on the damage of photosynthetic complexes as consequence of drought, we found that plants actively preserve and fine-tune their photosynthetic machinery under drought to adjust the photosynthetic electron transfer to fast changes of light intensity. Strikingly, Arabidopsis and wheat use different molecular strategies for this acclimation. While clear differences in NPQ relaxation and phosphorylation levels of photosynthetic proteins were observed in wheat, Arabidopsis modified the light energy distribution among photosynthetic complexes without changing PSII-LHCII phosphorylation. The fine-tuning of NPQ relaxation can therefore represent a potential trait for crop breeding.

Project description:Series of 6 repetitions of hybridization of treatment (PSII_DCMU) and control (PSII) each. Comparison of plants grown under PSII-specific light and treated with the electron transport inhibitor DCMU versus plants grown under PSII-specific light without DCMU treatment. T. Pfannschmidt, unpublished Keywords: repeat sample

Project description:To analyze the impact of photosynthetic redox signals, light sources with spectral qualities that preferentially excite either Photosystem I (PSI light) or Photosystem II (PSII light) were used. The light sources have been described in (Fey et al., 2005). Strong reduction and oxidation signals were induced by light shifts from PSI to PSII light (PSI-II) and the reverse light shift (PSII-I), respectivly. The acclimation responses were monitored at 0.5, 2, 8, and 48h after a light shift. Samples taken prior to changing the light quality (0h) served as control. Keywords: photosynthesis, redox regulation, light acclimation, retrograde signalling, long term response Experiments were performed with plant material corresponding to pools of at least 250-500 individuals of Arabidopsis thaliana (Col-0). To abtain healthy and unstressed plants, seedlings were initially grown for 21 days under white light (short day periods, 8-h light/16-h dark) on soil. Plants were then pre-acclimated to PSI-light for 3 days and reference samples were taken. Plants were then shifted to PSII light and tissue was harvested at the described time points. Similarly, samples were harvested before and after the reverse light shift. As additional control, plants acclimated to white light were also analyzed. RNA isolation: Leaf material was harvested and frozen in liquid N2 under the respective light source. Isolation of total RNA was performed as adapted from (Westhoff et al., 1991). Array analyses using the 3292-GST nylon array were performed as described earlier (Richly et al., 2003; Fey et al., 2005). Three independent experiments with different filters and independent cDNA probes were performed (for each timepoint).

Project description:To analyze the impact of photosynthetic redox signals, light sources with spectral qualities that preferentially excite either Photosystem I (PSI light) or Photosystem II (PSII light) were used. The light sources have been described in (Fey et al., 2005). Strong reduction and oxidation signals were induced by light shifts from PSI to PSII light (PSI-II) and the reverse light shift (PSII-I), respectivly. The acclimation responses were monitored at 0.5, 2, 8, and 48h after a light shift. Samples taken prior to changing the light quality (0h) served as control. Keywords: photosynthesis, redox regulation, light acclimation, retrograde signalling, long term response