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Stromal Side (stromal + side)
Selected AbstractsInsertion of light-harvesting chlorophyll a/b protein into the thylakoidFEBS JOURNAL, Issue 4 2000Topographical studies The major light-harvesting chlorophyll a/b -binding protein (Lhcb1,2) of photosystem II is inserted into the thylakoid via the signal recognition particle dependent pathway. However, the mechanism by which the protein enters the membrane is at this time unknown. In order to define some topographical restrictions for this process, we constructed several recombinant derivatives of Lhcb1 carrying hexahistidine tags at either protein terminus or in the stromal loop domain. Additionally, green fluorescent protein (GFP) was fused to either terminus. None of the modifications significantly impair the pigment-binding properties of the protein in the in vitro reconstitution of LHCII. With the exception of the C-terminal GFP fusion, all mutants stably insert into isolated thylakoids in the absence of Ni2+ ions. The addition of low concentrations of Ni2+ ions abolishes the thylakoid insertion of C-terminally His-tagged mutants whereas the other His-tagged proteins fail to insert only at higher Ni2+ concentrations. The C-terminus of Lhcb1 must cross the membrane during protein insertion whereas the other sites of Lhcb1 modification are positioned on the stromal side of LHCII. We conclude that a Ni2+ -complexed His tag and fusion to GFP inhibit translocation of the protein C-terminus across the thylakoid. Our observations indicate that the N-terminal and stromal domain of Lhcb1 need not traverse the thylakoid during protein insertion and are consistent with a loop mechanism in which only the C-terminus and the lumenal loop of Lhcb1 are translocated across the thylakoid. [source] Molecular dissection of photosystem I in higher plants: topology, structure and functionPHYSIOLOGIA PLANTARUM, Issue 3 2003Poul Erik Jensen Photosystem I catalyses the light driven electron transfer from plastocyanin/cytochrome c6 on the lumenal side of the thylakoid membrane to ferredoxin/flavodoxin at the stromal side. Photosystem I of higher plants consists of 18 different protein subunits. Fourteen of these make up the chlorophyll a -containing core, which also contains the cofactors involved in the electron transfer reactions, and four make up the peripheral chlorophyll a/b -containing antenna. Arabidopsis plants devoid of the nuclear-encoded photosystem I subunits have been obtained either by different suppression techniques or by insertional knock-out of the genes. This has allowed a detailed analysis of the role and function of the individual subunits. This review is focused on recent developments in the role of the individual subunit in the structure and function of photosystem I of higher plants. [source] CO2 limitation induces specific redox-dependent protein phosphorylation in Chlamydomonas reinhardtiiPROTEINS: STRUCTURE, FUNCTION AND BIOINFORMATICS, Issue 9 2006Maria V. Turkina Abstract Acclimation of the green alga Chlamydomonas reinhardtii to limiting environmental CO2 induced specific protein phosphorylation at the surface of photosynthetic thylakoid membranes. Four phosphopeptides were identified and sequenced by nanospray quadrupole TOF MS from the cells acclimating to limiting CO2. One phosphopeptide originated from a protein that has not been annotated. We found that this unknown expressed protein (UEP) was encoded in the genome of C.,reinhardtii. Three other phosphorylated peptides belonged to Lci5 protein encoded by the low-CO2 -inducible gene,5 (lci5). The phosphorylation sites were mapped in the tandem repeats of Lci5 ensuring phosphorylation of four serine and three threonine residues in the protein. Immunoblotting with Lci5-specific antibodies revealed that Lci5 was localized in chloroplast and confined to the stromal side of the thylakoid membranes. Phosphorylation of Lci5 and UEP occurred strictly at limiting CO2; it required reduction of electron carriers in the thylakoid membrane, but was not induced by light. Both proteins were phosphorylated in the low-CO2 -exposed algal mutant deficient in the light-activated protein kinase,Stt7. Phosphorylation of previously unknown basic proteins UEP and Lci5 by specific redox-dependent protein kinase(s) in the photosynthetic membranes reveals the early response of green algae to limitation in the environmental inorganic carbon. [source] Two short-chain dehydrogenase/reductases, NON-YELLOW COLORING 1 and NYC1-LIKE, are required for chlorophyll b and light-harvesting complex II degradation during senescence in riceTHE PLANT JOURNAL, Issue 1 2009Yutaka Sato Summary Yellowing, which is related to the degradation of chlorophyll and chlorophyll,protein complexes, is a notable phenomenon during leaf senescence. NON-YELLOW COLORING1 (NYC1) in rice encodes a membrane-localized short-chain dehydrogenase/reductase (SDR) that is thought to represent a chlorophyll b reductase necessary for catalyzing the first step of chlorophyll b degradation. Analysis of the nyc1 mutant, which shows the stay-green phenotype, revealed that chlorophyll b degradation is required for the degradation of light-harvesting complex II and thylakoid grana in leaf senescence. Phylogenetic analysis further revealed the existence of NYC1-LIKE (NOL) as the most closely related protein to NYC1. In the present paper, the nol mutant in rice was also found to show a stay-green phenotype very similar to that of the nyc1 mutant, i.e. the degradation of chlorophyll b was severely inhibited and light-harvesting complex II was selectively retained during senescence, resulting in the retention of thylakoid grana even at a late stage of senescence. The nyc1 nol double mutant did not show prominent enhancement of inhibition of chlorophyll degradation. NOL was localized on the stromal side of the thylakoid membrane despite the lack of a transmembrane domain. Immunoprecipitation analysis revealed that NOL and NYC1 interact physically in vitro. These observations suggest that NOL and NYC1 are co-localized in the thylakoid membrane and act in the form of a complex as a chlorophyll b reductase in rice. [source] Evidence for chloroplast control of external Ca2+ -induced cytosolic Ca2+ transients and stomatal closureTHE PLANT JOURNAL, Issue 6 2008Hironari Nomura Summary The role of guard cell chloroplasts in stomatal function is controversial. It is usually assumed that stomatal closure is preceded by a transient increase in cytosolic free Ca2+ concentration ([Ca2+]cyt) in the guard cells. Here, we provide the evidence that chloroplasts play a critical role in the generation of extracellular Ca2+ ([Ca2+]ext)-induced [Ca2+]cyt transients and stomatal closure in Arabidopsis. CAS (Ca2+ sensing receptor) is a plant-specific putative Ca2+ -binding protein that was originally proposed to be a plasma membrane-localized external Ca2+ sensor. In the present study, we characterized the intracellular localization of CAS in Arabidopsis with a combination of techniques, including (i) in vivo localization of green fluorescent protein (GFP) fused gene expression, (ii) subcellular fractionation and fractional analysis of CAS with Western blots, and (iii) database analysis of thylakoid membrane proteomes. Each technique produced consistent results. CAS was localized mainly to chloroplasts. It is an integral thylakoid membrane protein, and the N-terminus acidic Ca2+ -binding region is likely exposed to the stromal side of the membrane. The phenotype of T-DNA insertion CAS knockout mutants and cDNA mutant-complemented plants revealed that CAS is essential for stomatal closure induced by external Ca2+. In contrast, overexpression of CAS promoted stomatal closure in the absence of externally applied Ca2+. Furthermore, using the transgenic aequorin system, we showed that [Ca2+]ext -induced [Ca2+]cyt transients were significantly reduced in CAS knockout mutants. Our results suggest that thylakoid membrane-localized CAS is essential for [Ca2+]ext -induced [Ca2+]cyt transients and stomatal closure. [source] | |||||||||||||