Role of the PsbI Protein in Photosystem II Assembly and Repair in the Cyanobacterium <i>Synechocystis</i> sp. PCC 6803

Dobáková, Marika; Tichý, Martin; Komenda, Josef

doi:10.1104/pp.107.107805

Cited by 77 publications

(66 citation statements)

References 28 publications

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“…In the case of D1, unassembled D1 protein can only be detected in WT when using a much shorter radioactive pulse and a lower temperature (15). Under these conditions, all three forms of D1 can be detected: the unprocessed form, pD1; the incompletely processed form, iD1; and mature D1 (15).…”

Section: Autorad Up)mentioning

confidence: 97%

“…The remaining complex, RCb, was present in too low amounts for reliable detection of YCF48 (see also Ref. 15), but after sub-jecting thylakoids to multiple freeze/thaw cycles, its content markedly increased. Subsequent immunoblotting failed to detect YCF48 in RCb.…”

Section: Ycf48 Is a Component Of Psii Rc Assembly Complexes Inmentioning

confidence: 99%

“…2, see also Ref. 15). Their precise subunit composition is unclear but each contains D2, either D1 or its processing intermediate iD1, both subunits of cytochrome b 559 and PsbI, and each lacks both CP43 and CP47.…”

Section: Ycf48 Is a Component Of Psii Rc Assembly Complexes Inmentioning

confidence: 99%

“…PSII assembly appears to occur in a stepwise fashion and involves the formation of a PSII RC-like complex, possibly from D2-cytochrome b 559 and pD1-PsbI pre-complexes (14,15). Then the antennae, CP47 and CP43, plus other low-molecular mass polypeptides, become sequentially attached to form the PSII non-oxygen-evolving core complex.…”

Section: The Photosystem II (Psii)mentioning

confidence: 99%

“…1). Small amounts of the PSII proteins, D2 and D1, also accumulate in two smaller PSII complexes: a core subcomplex lacking CP43 (termed RC47) and a RC-like assembly complex (RCa) lacking both CP47 and CP43 (15,17). YCF48 could not be detected in RCC(1) and RCC(2) and was found to be mainly present in the low-molecular weight region, probably in an unassembled state.…”

Section: Ycf48 Is a Component Of Psii Rc Assembly Complexes Inmentioning

confidence: 99%

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The Cyanobacterial Homologue of HCF136/YCF48 Is a Component of an Early Photosystem II Assembly Complex and Is Important for Both the Efficient Assembly and Repair of Photosystem II in Synechocystis sp. PCC 6803

Komenda

Nickelsen

Tichý

et al. 2008

Journal of Biological Chemistry

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171

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The role of the slr2034 (ycf48) gene product in the assembly and repair of photosystem II (PSII) has been studied in the cyanobacterium Synechocystis PCC 6803. YCF48 (HCF136) is involved in the assembly of Arabidopsis thaliana PSII reaction center (RC) complexes but its mode of action is unclear. We show here that YCF48 is a component of two cyanobacterial PSII RC-like complexes in vivo and is absent in larger PSII core complexes. Interruption of ycf48 slowed the formation of PSII complexes in wild type, as judged from pulse-labeling experiments, and caused a decrease in the final level of PSII core complexes in wild type and a marked reduction in the levels of PSII assembly complexes in strains lacking either CP43 or CP47. Absence of YCF48 also led to a dramatic decrease in the levels of the COOH-terminal precursor (pD1) and the partially processed form, iD1, in a variety of PSII mutants and only low levels of unassembled mature D1 were observed. Yeast two-hybrid analyses using the split ubiquitin system showed an interaction of YCF48 with unassembled pD1 and, to a lesser extent, unassembled iD1, but not with unassembled mature D1 or D2. Overall our results indicate a role for YCF48 in the stabilization of newly synthesized pD1 and in its subsequent binding to a D2-cytochrome b 559 pre-complex, also identified in this study. Besides a role in assembly, we show for the first time that YCF48 also functions in the selective replacement of photodamaged D1 during PSII repair. The photosystem II (PSII)2 complex of plants, algae, and cyanobacteria is a multisubunit pigment-protein complex responsible for water oxidation during oxygenic photosynthesis (1). The complex consists of over 20 intrinsic and peripheral membrane proteins, which must be assembled in a highly coordinated manner to ensure proper functioning of the complex (2). At the heart of the complex is a heterodimer of the D1 (the psbA gene product) and related D2 (the psbD gene product) polypeptides, which binds most of the redox-active cofactors involved in PSII electron transfer (3). The isolated PSII reaction center (RC) complex contains, in addition to D1 and D2, the intrinsic PsbI subunit and cytochrome b 559 , which bind to D1 and D2, respectively (4). Surrounding the PSII RC complex are two chlorophyll-binding proteins, CP43 (the psbC gene product) and CP47 (the psbB gene product). D1 and CP43 also provide several amino acid ligands to the Mn 4 Ca cluster involved in the oxidation of water (5, 6).In vivo, the D1 protein exhibits much faster synthesis and degradation (or protein turnover) than the other PSII subunits (7). This feature reflects the operation of a PSII repair cycle to overcome the effects of PSII photoinhibition, which primarily causes irreversible damage to D1 (8). In most PSII-containing organisms, D1 is synthesized as a precursor protein (pD1) with a carboxyl-terminal extension (9). In the cyanobacterium Synechocystis sp. PCC 6803 this extension consists of 16 amino acid residues, which is removed in two steps by the CtpA endoprotein...

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Section: Autorad Up)mentioning

confidence: 97%

Section: Ycf48 Is a Component Of Psii Rc Assembly Complexes Inmentioning

confidence: 99%

Section: Ycf48 Is a Component Of Psii Rc Assembly Complexes Inmentioning

confidence: 99%

Section: The Photosystem II (Psii)mentioning

confidence: 99%

Section: Ycf48 Is a Component Of Psii Rc Assembly Complexes Inmentioning

confidence: 99%

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The Cyanobacterial Homologue of HCF136/YCF48 Is a Component of an Early Photosystem II Assembly Complex and Is Important for Both the Efficient Assembly and Repair of Photosystem II in Synechocystis sp. PCC 6803

Komenda

Nickelsen

Tichý

et al. 2008

Journal of Biological Chemistry

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140

171

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Molecular investigation of the radiation resistance of edible cyanobacterium Arthrospira sp. PCC 8005

et al. 2015

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The aim of this work was to characterize in detail the response of Arthrospira to ionizing radiation, to better understand its radiation resistance capacity. Live cells of Arthrospira sp. PCC 8005 were irradiated with 60Co gamma rays. This study is the first, showing that Arthrospira is highly tolerant to gamma rays, and can survive at least 6400 Gy (dose rate of 527 Gy h−1), which identified Arthrospira sp. PCC 8005 as a radiation resistant bacterium. Biochemical, including proteomic and transcriptomic, analysis after irradiation with 3200 or 5000 Gy showed a decline in photosystem II quantum yield, reduced carbon fixation, and reduced pigment, lipid, and secondary metabolite synthesis. Transcription of photo-sensing and signaling pathways, and thiol-based antioxidant systems was induced. Transcriptomics did show significant activation of ssDNA repair systems and mobile genetic elements (MGEs) at the RNA level. Surprisingly, the cells did not induce the classical antioxidant or DNA repair systems, such superoxide dismutase (SOD) enzyme and the RecA protein. Arthrospira cells lack the catalase gene and the LexA repressor. Irradiated Arthrospira cells did induce strongly a group of conserved proteins, of which the function in radiation resistance remains to be elucidated, but which are a promising novel routes to be explored. This study revealed the radiation resistance of Arthrospira, and the molecular systems involved, paving the way for its further and better exploitation.

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Quantitative analysis of protein turnover in plants

Nelson

Millar

2014

Proteomics

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Proteins are constantly being synthesised and degraded as plant cells age and as plants grow, develop and adapt the proteome. Given that plants develop through a series of events from germination to fruiting and even undertake whole organ senescence, an understanding of protein turnover as a fundamental part of this process in plants is essential. Both synthesis and degradation processes are spatially separated in a cell across its compartmented structure. The majority of protein synthesis occurs in the cytosol, while synthesis of specific components occurs inside plastids and mitochondria. Degradation of proteins occurs in both the cytosol, through the action of the plant proteasome, and in organelles and lytic structures through different protease classes. Tracking the specific synthesis and degradation rate of individual proteins can be undertaken using stable isotope feeding and the ability of peptide MS to track labelled peptide fractions over time. Mathematical modelling can be used to follow the isotope signature of newly synthesised protein as it accumulates and natural abundance proteins as they are lost through degradation. Different technical and biological constraints govern the potential for the use of (13)C, (15)N, (2)H and (18)O for these experiments in complete labelling and partial labelling strategies. Future development of quantitative protein turnover analysis will involve analysis of protein populations in complexes and subcellular compartments, assessing the effect of PTMs and integrating turnover studies into wider system biology study of plants.

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Role of the PsbI Protein in Photosystem II Assembly and Repair in the Cyanobacterium Synechocystis sp. PCC 6803

Cited by 77 publications

References 28 publications

The Cyanobacterial Homologue of HCF136/YCF48 Is a Component of an Early Photosystem II Assembly Complex and Is Important for Both the Efficient Assembly and Repair of Photosystem II in Synechocystis sp. PCC 6803

The Cyanobacterial Homologue of HCF136/YCF48 Is a Component of an Early Photosystem II Assembly Complex and Is Important for Both the Efficient Assembly and Repair of Photosystem II in Synechocystis sp. PCC 6803

Molecular investigation of the radiation resistance of edible cyanobacterium Arthrospira sp. PCC 8005

Quantitative analysis of protein turnover in plants

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