Project description:Here we describe TROL (thylakoid rhodanese-like protein), a nuclear-encoded component of thylakoid membranes that is required for sustaining efficient linear electron flow in vascular plants. Thus, TROL might represent a missing thylakoid membrane linker for the assembly of a ternary complex between FNR, ferredoxin and NADP+. Such a complex is necessary for maintaining photosynthetic redox poise and balancing between several alternative electron-transport pathways of oxygenic photosynthesis. TROL inactivation modulates the expression of 638 nuclear genes, revealing a novel retrograde signaling pathway. Chloroplasts are the major source of NADPH which is exported to the cytosol where it participates in various redox-dependent processes. TROL is most likely the first element in a metabolic signaling pathway which influences the expression of a large set of stress related genes. Among them are O-methyltransferases and anthocyanin 5-aromatic acyltransferase which are highly upregulated. Microarray analysis was performed in order to identify metabolic networks and pathways regulated by the deficient protein TROL. Comparing ATH1 Affymetrix data results, 317 genes were down-regulated and 321 genes were classified as up-regulated, amongst which mostly affected enzymes were catalyses, oxigenases, monooxygenases and reductases involved in the process of photosynthesis.

Project description:Plants are subjected to perpetual fluctuations of light intensity and spectral composition in their natural growth environment, particularly due to movement of clouds and upper canopy leaves. Sudden exposure to intense light is accompanied by absorption of excess light energy, which results in an overload of photosynthetic electron transport chain and generation of reactive oxygen species in and around thylakoid membranes. To cope with this photooxidative stress and to prevent chronic photoinhibition under dynamically changing light intensities, plants have evolved various short- and long-term photoprotective mechanisms. We used quantitative mass spectrometry to investigate long-term acclimation of Arabidopsis thaliana leaf proteome to fluctuating light (FL) which induces photooxidative stress. After three days of FL exposure the proteomes of young and mature leaves were analyzed separately in the morning and at the end of day to examine possible interaction between FL acclimation and leaf development or time of day.

Project description:Thylakoid membranes are the specialized internal membrane system produced in plants, algae, and cyanobacteria to convert sunlight to chemical energy via oxygenic photosynthesis. Cyanobacterial thylakoid membranes harbor the protein complexes and electron transport molecules that are necessary for photosynthetic light reactions and respiratory electron flow. The thylakoid membranes sit between the plasma membrane and the central cytoplasm, leading to intricate cellular compartmentalization. How thylakoid membranes are generated to form the functional network and how protein complexes are recruited into thylakoids remain elusive. Here, we developed a method to modulate thylakoid biogenesis in the model cyanobacterium Synechococcus elongatus PCC7942 and probed the spatial-temporal stepwise biogenesis process of cyanobacterial thylakoid membranes, using electron microscopy, in situ cryo-electron tomography, confocal microscopy, mass spectroscopy, and biochemical approaches. Our results revealed that the plasma membrane and regularly-arranged concentric thylakoid layers have no physical connections. The newly synthesized thylakoid membrane fragments commerce between the plasma membrane and pre-existing thylakoids, where the initial biogenesis of Photosystem II occurs. Photosystem I monomers appear in thylakoid membranes earlier than other photosystem assemblies. Redistribution of photosynthetic protein complexes during thylakoid biogenesis ensures establishment of the spatial organization of the functional thylakoid membrane network. This study provides insights into the molecular processes of the photosynthetic machinery biosynthesis and organization.

Project description:Alkali-salinity exerts severe osmotic, ionic, and high-pH stresses to plants. Photosynthetic machinery is especially sensitive to saline-alkali stress. In addition, reversible protein phosphorylation also play crucial roles in plant salt resistance. While our knowledge on protein phosphorylation events in salt stress response is very limited. Few studies have been published involving photosynthetic protein phosphorylation modulation to improve salt resistance. In the present study, we investigated the Na2CO3-responsive characteristics in Puccinellia tenuiflora chloroplasts using stable isotope dimethyl labeled phosphoproteomic approach. A total of 161 unique phosphopeptides were identified, and 137 phosphopeptides were quantified by dimethyl labeling. Among them, 50 proteins were quantified as Na2CO3-responsive proteins with 57 phosphosites, including 33 increased and 14 decreased. Importantly, 26 phosphosites were newly identified as Na2CO3-responsive phosphoproteins in plants, which were supposed to be crucial for regulating photosynthesis, membrane and transporting, signaling, stress response, and protein synthesis and turnover. Among them, seven light harvesting proteins, six PSII proteins, five PSI proteins, three electron transfer chain proteins, and two Calvin cycle-related proteins were increased, but five ATP synthase subunits and sucrose-phosphate synthase were decreased at phosphorylation level. Besides, Na+/H+ antiporter, villin-2, and two thylakoid organization related proteins were increased at phosphorylation level. Two signaling related proteins and most protein species in charge of gene expression and protein turnover were enhanced at phosphorylation level at 24h after Na2CO3 treatment.

Project description:STN7-dependent phosphorylation of an as yet unknown thylakoid protein triggers the signaling events associated with the long-term acclimatory response (LTR). The LTR-associated signaling events regulate the expression of photosynthesis-related genes on the post-transcriptional level (nucleus), as indicated by transcript profiling in LTR mutants.

Project description:In addition to leaves, the main site of photosynthetic reactions, active photosynthesis also takes place in stems, siliques and tree trunks. Although non-foliar photosynthesis has a marked effect on plant growth and yield, only limited information on the expression patterns of photosynthesis-related genes and the structure of photosynthetic machinery in different plant organs has been available. Here, we report the results of transcriptomic analysis of various organs of Arabidopsis thaliana and compare the gene expression profiles of young and mature leaves with a special focus on photosynthetic genes. Further, we analyzed the composition and organization of the photosynthetic electron transfer machinery in leaves, stems and green siliques at the protein level using BN-PAGE. RNA-Seq analysis revealed unique gene expression profiles in different plant organs and showed major differences in the expression of photosynthesis-related genes in young as compared to mature rosettes. Gel-based proteomic analysis of the thylakoid protein complex organization further showed that all studied plant organs contain the necessary components of the photosynthetic electron transfer chain. Intriguingly, stems accumulate high amounts of PSI-NDH complex, which has previously been implicated in cyclic electron transfer.

Project description:Plants often face more than one type of stress at a time, and how plants respond to combined stress factors is therefore of great interest. Here, we used protoplasts of the moss Physcomitrella patens as a model to study the effects of short-term combined stress on the chloroplast proteome. In this system, biotic stress is mimicked by exposure to cell wall-hydrolyzing enzymes, and abiotic stress is related to plasmolysis. We used SWATH-MS to perform label-free comparative quantitative proteomic analysis of the chloroplast proteome. Overall, we quantified 480 chloroplast proteins, 220 of which showed a more than 1.4-fold change in abundance in protoplasts. We additionally quantified 1422 chloroplast proteins using emPAI. We observed degradation of a significant portion of the chloroplast proteome during the first hour of stress. Electron-transport chain (ETC) components underwent the heaviest degradation, resulting in the decline of photosynthetic activity. We also compared the proteome changes to those in the transcriptional level of nuclear-encoded chloroplast genes. Globally, the levels of the quantified proteins and their corresponding mRNAs showed limited correlation. Genes involved in the biosynthesis of chlorophyll and components of the outer chloroplast membrane showed decreases in both transcript and protein abundance. However, proteins like dehydroascorbate reductase 1 and 2-cys peroxiredoxin B responsible for ROS detoxification increased in abundance. Further, genes such as thylakoid ascorbate peroxidase were induced at the transcriptional level but down-regulated at the proteomic level. Together, our results demonstrate that the initial chloroplast reaction to stress is due changes at the proteomic level.

Project description:Plants often face more than one type of stress at a time, and how plants respond to combined stress factors is therefore of great interest. Here, we used protoplasts of the moss Physcomitrella patens as a model to study the effects of short-term combined stress on the chloroplast proteome. In this system, biotic stress is mimicked by exposure to cell wall-hydrolyzing enzymes, and abiotic stress is related to plasmolysis. We used SWATH-MS to perform label-free comparative quantitative proteomic analysis of the chloroplast proteome. Overall, we quantified 480 chloroplast proteins, 220 of which showed a more than 1.4-fold change in abundance in protoplasts. We additionally quantified 1422 chloroplast proteins using emPAI. We observed degradation of a significant portion of the chloroplast proteome during the first hour of stress. Electron-transport chain (ETC) components underwent the heaviest degradation, resulting in the decline of photosynthetic activity. We also compared the proteome changes to those in the transcriptional level of nuclear-encoded chloroplast genes. Globally, the levels of the quantified proteins and their corresponding mRNAs showed limited correlation. Genes involved in the biosynthesis of chlorophyll and components of the outer chloroplast membrane showed decreases in both transcript and protein abundance. However, proteins like dehydroascorbate reductase 1 and 2-cys peroxiredoxin B responsible for ROS detoxification increased in abundance. Further, genes such as thylakoid ascorbate peroxidase were induced at the transcriptional level but down-regulated at the proteomic level. Together, our results demonstrate that the initial chloroplast reaction to stress is due changes at the proteomic level.

Project description:In photosynthesis, light is absorbed by the thylakoid embedded light harvesting pigment protein complexes (LHCs) that surround the photosynthetic reaction centers, photosystem II (PSII) and photosystem I (PSI). The distribution of light energy between the photosystems is balanced through state transitions1,2, which refer to the phosphorylation-dependent association of the loosely bound (L) LHCII antenna trimer either to PSII or PSI 3,4. Apart from phosphorylation, other mechanisms regulating state transitions have not been reported this far. In this study we demonstrate that lysine (Lys) acetylation of chloroplast proteins is a prerequisite for state transitions in Arabidopsis thaliana. Knock-out mutants lacking a chloroplast acetyltransferase NSI (At1g32070; AtNSI, SNAT) show selective decreases in the Lys acetylation status of several photosynthetic proteins including PSI, PSII and LHCII subunits. Fluorescence measurements revealed that changes in the wavelength of illumination do not cause state transitions in the nsi mutants even though their LHCII phosphorylation status is not defected. Furthermore, biochemical analyses of thylakoid proteins and protein complexes showed that nsi plants are not able to accumulate the phosphorylation dependent PSI-LHCII megacomplex. Our results manifest that Lys acetylation by NSI has an integral role in the regulation of state transitions in Arabidopsis.

Project description:Phosphorus (Pi) starvation prevents a good match between light energy absorption and photosynthetic carbon metabolism. Photosynthetic electron-transport chain switches to use molecular oxygen as an electron carrier, generating photo-reactive oxygen species (photo-ROS) in chloroplast. In rice (Oryza sativa), DEEP GREEN PANICLE1 (DGP1) is robustly up-regulated in response to Pi-deficiency stress. DGP1 decreases the DNA-binding activities of the photosynthetic activators GLK1/2 on the genes involved in chlorophyll biosynthesis, light harvesting and electron transport. This Pi-starvation-induced mechanism dampens electron transport rates (ETRI and ETRII) and alleviates the electron-excessive stress in mesophyll cells. Meanwhile, DGP1 hijacks glycolytic enzymes GAPC1/2/3, redirecting glucose metabolism toward pentose phosphate pathway with superfluous NADPH production. Phenotypically, light irradiation induces O2– accumulation in Pi-starved WT leaves, but was observably accelerated in dgp1 mutant and impaired in GAPCsRNAi line and glk1glk2 double mutant. Interestingly, overexpression of DGP1 in rice caused hyposensitivity to the ROS-inducers (catechin and methyl viologen) and dgp1 mutant shows a similar inhibitory growth with the WT plants. We conclude that DGP1 gene serves as a specific antagonizer against Pi-starvation-induced photo-ROS, which integrates light-absorbing and anti-oxidative systems by orchestrating transcriptional and metabolic regulations, respectively.