The reaction center of green sulfur bacteria1Dedicated to the memory of Jan Amesz.1

Hauska, Günter; Schoedl, Thomas; Rémigy, Hervé W.; Tsiotis, Georgios

doi:10.1016/s0005-2728(01)00200-6

Cited by 165 publications

(84 citation statements)

References 102 publications

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“…The RC complex of the green sulfur bacterium Chlorobium tepidum consists of four subunits, PscA, PscB, PscC, and PscD with an antenna size of about 30 bacteriochlorophyll (BChl) molecules, whereas the heterodimeric photosystem I complex is made of 12 polypeptides with a much larger antenna size of nearly 100 chlorophyll (Chl) molecules (4,5). The functions of PscA, PscB, and PscC have been studied intensively using biochemical and spectroscopic methods.…”

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confidence: 99%

Function of a PscD Subunit in a Homodimeric Reaction Center Complex of the Photosynthetic Green Sulfur Bacterium Chlorobium tepidum Studied by Insertional Gene Inactivation

Tsukatani

Miyamoto

Itoh

et al. 2004

Journal of Biological Chemistry

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The PscD subunit in the homodimeric "type I" photosynthetic reaction center (RC) complex of the green sulfur bacterium Chlorobium tepidum was disrupted by insertional mutagenesis of its relevant pscD gene. This is the first report on the use of the direct mutagenic approach into the RC-related genes in green sulfur bacteria. The RC complex of C. tepidum is supposed to form a homodimer of two identical PscA subunits together with three other subunits: PscB (F A /F B -containing protein), PscC (cytochrome c z ), and PscD. PscD shows a relatively low but significant similarity in its amino acid sequence to PsaD in the photosystem I of plants and cyanobacteria. We studied the biochemical and spectroscopic properties of a mutant lacking PscD in order to elucidate its unknown function. 1) The RC complex isolated from the mutant cells showed no band corresponding to PscD on SDS-PAGE analysis. 2) The growth rate of the PscD-less mutant was slower than that of the wildtype cells at low light intensities. 3) Time-resolved fluorescence spectra at 77 K revealed prolonged decay times of the fluorescence from bacteriochlorophyll c on the antenna chlorosome and from bacteriochlorophyll a on the Fenna-Matthews-Olson antenna protein in the mutant cells. The loss of PscD led to a much slower energy transfer from the antenna pigments to the special pair bacteriochlorophyll a (P840). 4) The mutant strain exhibited slightly less activity of ferredoxin-mediated NADP ؉ photoreduction compared with that in the wild-type strain. The extent of suppression, however, was less significant than that reported in the PsaD-less mutants of cyanobacterial photosystem I. The evolutionary relationship between PscD and PsaD was also discussed based on a structural homology modeling of the former.Photosynthetic organisms convert light energy into electrochemical free energy by carrying out a series of light-driven electron transfer reactions. This process, which is fundamental for life, is mediated by reaction center (RC) 1 complexes. The RCs are primarily grouped into two types based on their terminal electron acceptors, type I (FeS-type) RCs and type II (quinone-type) RCs. Purple photosynthetic bacteria contain only type II RCs, which do not evolve oxygen, whereas oxygenic cyanobacteria and plants utilize both type I (photosystem I) and type II (photosystem II) RCs, which are connected in-line through the b 6 f complex. Green sulfur bacteria and heliobacteria have unique type I RCs, so-called "homodimeric" RCs, which are made of two identical core polypeptides.The "heterodimeric" type I and II RCs, which are found in all photosynthetic organisms other than green sulfur bacteria and heliobacteria, consist of a set of two partially different core polypeptides that produce a slightly asymmetric arrangement of cofactors. A three-dimensional structure of the heterodimeric RC was first obtained from the type II RC of the purple bacterium Blastochloris viridis in 1985 (1). Recently, those of photosystem I and II RCs from the thermophilic cyanobacterium Sy...

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confidence: 99%

Function of a PscD Subunit in a Homodimeric Reaction Center Complex of the Photosynthetic Green Sulfur Bacterium Chlorobium tepidum Studied by Insertional Gene Inactivation

Tsukatani

Miyamoto

Itoh

et al. 2004

Journal of Biological Chemistry

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“…Of the multiple sulfide oxidation electron transport pathways with photooxidized P840 as the terminal electron acceptor in C. tepidum, the one involving SQR appears to be more efficient in terms of energy conversion than the others, because it should generate a proton-motive force through a cyt b-Riesketype iron-sulfur protein complex during the oxidation of sulfide by photooxidized P840, and the others do not. 30) Although the FCSD and SoxF pathways are energetically inefficient as compared with the SQR pathway and the affinities for sulfide did not differ very much, retention of these activities is likely favored under certain environmental conditions, because sulfide is a diffusible substrate required by many bacterial species occupying the same ecological niche. 6) Oxidation of sulfide by FCSD or SoxF, or even by core TOMES to elemental sulfur, allows an individual bacterium to utilize sulfide and subsequently generate six electrons as electron donors for further reactions.…”

Section: Thiosulfatophilummentioning

confidence: 95%

“…29) The primary donor of the reaction center (RC) is a special pair of bacteriochlorophylls called P840, and its immediate electron donor is RC-bound cyt c-551. 30) Itoh et al 31) found that a soluble mono-heme cyt c-554 of about 10 kDa (the CT0075 protein, 10) sometimes called a small soluble cytochrome c) donates electrons to bound cyt c-551 rather than directly to oxidized P840. In the reconstituted core TOMES (SoxAXK, SoxB, SoxYZ) of this bacterium, cyt c-554 functioned as an efficient electron acceptor.…”

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Biochemical Studies of asoxF-Encoded Monomeric Flavoprotein Purified from the Green Sulfur BacteriumChlorobaculum tepidumThat Stimulatesin VitroThiosulfate Oxidation

Ogawa

Furusawa

Shiga

et al. 2010

Bioscience, Biotechnology, and Biochemistry

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“…Similar results were observed by Frigaard et al (28) for the bchK mutant. The absorption band near 800 nm was derived from a combination of BChl a-binding proteins, including CsmA, Fenna-Matthews-Olson protein, and the reaction centers (28,31,32). Fig.…”

Section: Identification Of Potential Bchl C D and E Biosynthesis Gene-mentioning

confidence: 99%

Identification of a Gene Essential for the First Committed Step in the Biosynthesis of Bacteriochlorophyll c

Bryant

2011

Journal of Biological Chemistry

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Bacteriochlorophylls (BChls) c, d, and e are the major chlorophylls in chlorosomes, which are the largest and one of the most efficient antennae produced by chlorophototrophic organisms. In the biosynthesis of these three BChls, a C-13 2 -methylcarboxyl group found in all other chlorophylls (Chls) must be removed. This reaction is postulated to be the first committed step in the synthesis of these BChls. Analyses of gene neighborhoods of (B)Chl biosynthesis genes and distribution patterns in organisms producing chlorosomes helped to identify a gene (bciC) that appeared to be a good candidate to produce the enzyme involved in this biochemical reaction. To confirm that this was the case, a deletion mutant of an open reading frame orthologous to bciC, CT1077, was constructed in Chlorobaculum tepidum, a genetically tractible green sulfur bacterium. The CT1077 deletion mutant was unable to synthesize BChl c but still synthesized BChl a and Chl a. The deletion mutant accumulated large amounts of various (bacterio)pheophorbides, all of which still had C-13 2 -methylcarboxyl groups. A C. tepidum strain in which CT1077 was replaced by an orthologous gene, Cabther_B0031 from "Candidatus Chloracidobacterium thermophilum" was constructed. Although the product of Cabther_B0031 was only 28% identical to the product of CT1077, this strain synthesized BChl c, BChl a, and Chl a in amounts similar to wild-type C. tepidum cells. To indicate their roles in the first committed step of BChl c, d, and e biosynthesis, open reading frames CT1077 and Cabther_B0031 have been redesignated bciC. The potential mechanism by which BciC removes the C-13 2 -methylcarboxyl moiety of chlorophyllide a is discussed.

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The reaction center of green sulfur bacteria1Dedicated to the memory of Jan Amesz.1

Cited by 165 publications

References 102 publications

Function of a PscD Subunit in a Homodimeric Reaction Center Complex of the Photosynthetic Green Sulfur Bacterium Chlorobium tepidum Studied by Insertional Gene Inactivation

Function of a PscD Subunit in a Homodimeric Reaction Center Complex of the Photosynthetic Green Sulfur Bacterium Chlorobium tepidum Studied by Insertional Gene Inactivation

Biochemical Studies of asoxF-Encoded Monomeric Flavoprotein Purified from the Green Sulfur BacteriumChlorobaculum tepidumThat Stimulatesin VitroThiosulfate Oxidation

Identification of a Gene Essential for the First Committed Step in the Biosynthesis of Bacteriochlorophyll c

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