Identification of the Basic Residues of Cytochrome <i>f</i> Responsible for Electrostatic Docking Interactions with Plastocyanin in Vitro:  Relevance to the Electron Transfer Reaction in Vivo

Soriano, Glenda M.; Ponamarev, Mikhail V.; Piskorowski, Rebecca A.; Cramer, William A.

doi:10.1021/bi9807714

Cited by 64 publications

(67 citation statements)

References 50 publications

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“…At 25°C the value of the rate constant is 62 ϫ 10 6 M Ϫ1 s Ϫ1 in the presence of 150 mM NaCl. Assuming the same ionic strength dependence of the reaction rate at 5 (see below) and 25°C, this value extrapolates to a rate constant of 185 ϫ 10 6 M Ϫ1 s Ϫ1 at 90 mM NaCl, which is by a factor of 4 faster than that reported for truncated cyt f under these conditions (24,25,27) but comparable to the value of 100 ϫ 10 6 M Ϫ1 s Ϫ1 found recently (29). To analyze the surface regions of plastocyanin involved in the rate-limiting step of the reaction with the cyt bf complex, the role of residues in the hydrophobic and acidic patches of spinach plastocyanin was probed using site-directed mutagenesis.…”

Section: Resultssupporting

confidence: 83%

“…Electrostatic Interaction-The effect of the ionic strength on the electron transfer from the cyt bf complex to plastocyanin indicates the attraction of two oppositely charged regions in the rate-determining step in good agreement with most studies using soluble cyt f and plastocyanin from heterologous (19,26) or homologous sources (29). It is not consistent with results showing no effect of mutated charges of residues 59 -61 (13,14) or an increase of the rate constant at increasing ionic strength below 40 mM (45) (cf.…”

Section: Does Tyr-83 Play a Significant Role In The Electronsupporting

confidence: 77%

“…A decrease of the rate constant determined by stopped-flow experiments after mutation of these residues to neutral or negative ones indicate their effect on the complex formation. However, in intact C. reinhardtii, these mutations showed only minor effects on the oxidation kinetics of cyt f after laser-induced oxidation of P700 (29). This difference is not fully understood but may partially be explained by the release of oxidized plastocyanin from PSI being rate-limiting for the oxidation of cyt f (18).…”

Section: Does Tyr-83 Play a Significant Role In The Electronmentioning

confidence: 97%

“…In the majority of these studies, the C-terminal trans-membrane helix of cyt f was removed to convert this cytochrome to a soluble protein. Furthermore, cyt f and plastocyanin were generally from heterologous sources, except for a recent study with the proteins from C. reinhardtii (29). Lee et al (13) have reported that exclusively mutations of the negative patch of residues 42-45 exerted an effect on the interaction with the solubilized cyt f. On the other hand, Kannt et al (26) found that both acidic patches are involved in this interaction and concluded that binding and not the rate of the intracomplex electron transfer is affected.…”

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confidence: 99%

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Dynamic Interaction of Plastocyanin with the Cytochrome bf Complex

Illerhaus

Altschmied

Reichert

et al. 2000

Journal of Biological Chemistry

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The interaction between plastocyanin and the intact cytochrome bf complex, both from spinach, has been studied by stopped-flow kinetics with mutant plastocyanin to elucidate the site of electron transfer and the docking regions of the molecule. Mutation of Tyr-83 to Arg or Leu provides no evidence for a second electron transfer path via Tyr-83 of plastocyanin, which has been proposed to be the site of electron transfer from cytochrome f. The data found with mutations of acidic residues indicate that both conserved negative patches are essential for the binding of plastocyanin to the intact cytochrome bf complex. Replacing Ala-90 and Gly-10 at the flat hydrophobic surface of plastocyanin by larger residues slowed down and accelerated, respectively, the rate of electron transfer as compared with wild-type plastocyanin. These opposing effects reveal that the hydrophobic region around the electron transfer site at His-87 is divided up into two regions, of which only that with Ala-90 contributes to the attachment to the cytochrome bf complex. These binding sites of plastocyanin are substantially different from those interacting with photosystem I. It appears that each of the two binding regions of plastocyanin is split into halves, which are used in different combinations in the molecular recognition at the two membrane complexes.

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Section: Resultssupporting

confidence: 83%

Section: Does Tyr-83 Play a Significant Role In The Electronsupporting

confidence: 77%

Section: Does Tyr-83 Play a Significant Role In The Electronmentioning

confidence: 97%

mentioning

confidence: 99%

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Dynamic Interaction of Plastocyanin with the Cytochrome bf Complex

Illerhaus

Altschmied

Reichert

et al. 2000

Journal of Biological Chemistry

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“…The lumenal and intramembrane domains of the cytochrome b 6 f complex of oxygenic photosynthesis contain four redox centers: cytochrome f with one covalently bound c-type heme, cytochrome b with two noncovalently bound b-type hemes, and one [2Fe-2S] cluster in the Rieske iron-sulfur protein (1)(2)(3). The electron transfer pathway, plastoquinol 3 Rieske ISP 1 3 cytochrome f 3 plastocyanin or cytochrome c 6 3 photosystem I on the lumen (p-side) of the membrane, comprises the high potential electron transport chain of the plastoquinol oxidase, whereas electron transfer between the two b-hemes, heme b p 3 heme b n , to a putative n-side bound quinone defines the low potential chain.…”

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confidence: 99%

Electron Transfer from the Rieske Iron-Sulfur Protein (ISP) to Cytochrome f in Vitro

Soriano

Guo

Vitry

et al. 2002

Journal of Biological Chemistry

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(ISP-f) was independent of pH and ionic strength, implying no significant role of electrostatic interactions. Effective pK values of 6.2 and 8.3, respectively, of oxidized and reduced ISP were derived from the pH dependence of the amplitude of cytochrome f reduction. The firstorder rate constant, k 1 (ISP-f) , predicted from k 2 (ISP-f) is ϳ10 and ϳ150 times smaller than the millisecond and microsecond phases of cytochrome f reduction observed in vivo. It is proposed that in the absence of electrostatic guidance, a productive docking geometry for fast electron transfer is imposed by the guided trajectory of the ISP extrinsic domain. The requirement of a specific electrically neutral docking configuration for ISP electron transfer is consistent with structure data for the related cytochrome bc 1 complex.

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Cytochromef

Soriano¹,

Smith²

2004

Handbook of Metalloproteins

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Cytochrome f ( f , folium, leaf), a c ‐type cytochrome with a characteristic CysXXCysHis amino acid sequence for heme ligation, is the largest of the four major protein subunits of the membrane‐embedded cytochrome b 6 f complex of oxygenic photosynthesis. It contains 285–86 amino acids, consisting of a soluble 250‐residue domain on the p‐side (positive‐side) or lumen‐side of the membrane, a single trans‐membrane 20‐residue α‐helix, and an n‐ or stromal‐side segment consisting of 15 residues. These domains contain, respectively, the heme prosthetic group and intraprotein electron transfer pathway, the membrane anchor and a short segment that is important in the assembly of the b 6 f complex. The function of the cytochrome f in oxygenic photosynthesis is to act as the terminal electron acceptor in the membrane‐embedded cytochrome b 6 f complex that provides the electron transport connection between the photosystem II and photosystem I reaction centers. Electron transfer through the complex is coupled to proton translocation and generation of a proton electrochemical potential that is utilized to drive the synthesis of ATP through the proton‐motive ATP synthase. These functions of the cytochrome b 6 f complex are analogous to those of the multisubunit cytochrome bc 1 complex (ubiquinol:cytochrome c oxidoreductase) of the mitochondrial respiratory chain and photosynthetic bacteria. Both complexes contain four redox centers with very similar redox and structural properties: a covalently bound c ‐type heme in cytochrome f or c 1 , the 2Fe–2S cluster of the Rieske ISP, and the two noncovalently bound hemes of cytochrome b . The structure properties have been defined in 3.0–3.1 Å structures of the b 6 f complex from a thermophilic cyanobacterium and a green alga. These structures also defined a fifth redox prosthetic group, a novel covalently bound heme, tentatively called heme x . With the exception of the extrinsic cytochromes f and c 1 that, except for the heme‐binding peptide sequence, are completely different, the redox‐active protein subunits of the bc 1 and b 6 f complexes are structurally similar. For the b 6 f complex, structures at the level of atomic resolution (<2 Å) have also been obtained for the p‐side or lumen‐side extrinsic domains of cytochrome f and the Rieske high potential [2Fe–2S] protein, which together constitute approximately 40% of the total mass of the complex.

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Identification of the Basic Residues of Cytochrome f Responsible for Electrostatic Docking Interactions with Plastocyanin in Vitro: Relevance to the Electron Transfer Reaction in Vivo

Cited by 64 publications

References 50 publications

Dynamic Interaction of Plastocyanin with the Cytochrome bf Complex

Dynamic Interaction of Plastocyanin with the Cytochrome bf Complex

Electron Transfer from the Rieske Iron-Sulfur Protein (ISP) to Cytochrome f in Vitro

Cytochromef

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