Abstract
The aim of this review is to analyze the current state of knowledge concerning the blue copper protein plastocyanin (PC) focusing on its interactions with its reaction partners cytochromef and P700. Plastocyanin is a 10 kD blue copper protein which is located in the lumen of the thylakoid where it functions as a mobileelectron carrier shuttling electrons from cytochromef to P700 in Photosystem I. PC is a typical β-barrel protein containing a single copper center which is ligated to two histidines, a methionine and a cysteine in a distorted tetrahedral geometry. PC has two potential binding sites for reaction partners. Site 1 consists of the H87 ligand to the copper and Site 2 consists of Y83 which is surrounded by two clusters of negative charges which are highly conserved in higher plant PCs.
The interaction of PC with cytochromef has been studied extensively. It is electrostatic in nature with negative charges on PC interacting with positive charges on cytochromef. Evidence from cross-linking, chemical modification, kinetics and site-directed mutagenesis studies implicate Site 2 as the binding site for Cytf. The interaction is thought to occur in two stages: an initial diffusional approach guided by electrostatic interactions, followed by more precise docking to form a final electron transfer complex.
Due to the multisubunit nature of the Photosystem I complex, the evidence is not as clear for the binding site for P700. However, a small positively-charged subunit (Subunit III) of Photosystem I has been implicated in PC binding. Also, both chemical modification and site-directed mutagenesis experiments have suggested that PC interacts with P700 via Site 1.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- Cytb 6 f :
-
cytochromeb 6 f complex
- Cytf :
-
cytochromef
- Cytc :
-
cytochromec
- EDA:
-
ethylenediamine
- EPR:
-
electron paramagnetic resonance
- NHE:
-
normal hydrogen electrode
- NMR:
-
nuclear magnetic resonance
- PC:
-
plastocyanin
- P700:
-
reaction center chlorophyll in Photosystem I
References
Adam Z and Malkin R (1989) On the interaction of cytochromef and plastocyanin. Biochim Biophys Acta 975: 158–163
Anderson GP, Draheim JE and Gross EL (1985) Plastocyanin conformation: The effect of oxidation state on the pKa of nitrotyrosine-83. Biochim Biophys Acta 810: 123–131
Anderson GP, Sanderson DG, Lee CH, Durell S, Anderson LB and Gross EL (1987) The effect of ethylenediamine chemical modification of plastocyanin on the rate of cytochromef oxidation and P700+ reduction. Biochim Biophys Acta 894: 386–398
Augustin MA, Chapman SK, Davies DM, Sykes AG, Speck SH and Margoliash E (1983) Interaction of cytochromec with the blue copper proteins, plastocyanin and azurin. J Biol Chem 258: 6405–6409
Bagby S, Driscoll PC, Goodall KG, Redfield C and Hill HAO (1990) The complex formed between plastocyanin and cytochromec. Investigation by NMR spectroscopy. Eur J Biochemistry 188: 411–420
Bengis J and Nelson N (1985) Subunit structure of chloroplast Photosystem I reaction center. J Biol Chem 252: 4564–4569
Beoku-Betts D, Chapman SK, Knox CV and Sykes AG (1983) Concerning t5he binding site on plastocyanin for its natural redox partner cytochromef. J Chem Soc Chem Commun 1983: 1150–1152
Beoku-Betts D, Chapman SK, Knox CV and Sykes AG (1985) Kinetic studies on 1:1 electron transfer reactions involving blue copper proteins. 1. Effects of pH, competitive inhibition, and chromium(III) modification on the reaction of plastocyanin with cytochromef. Inorg Chem 24: 1677–1681
Bernstein FC, Doetzle TF, Williams GJB, MyerJr EF, Brice MD, Rodgers JR, Kennard O, Shimanouchi T and Tasumni M (1977) The Protein Data Bank: A computer-based archival file for macromolecular structures. J Mol Biol 112: 535–542
Betts JN, Beratan DN and Onuchic JN (1992) Mapping electron tunneling pathways: An algorithm that finds the ‘minimum length’/maximum coupling pathway between electron donors and acceptors in proteins. J Am Chem Soc 114: 4043–4046
Boulter D, Haslett BG, Peacock D, Ramshaw JAM and Scawen MD (1977) Chemistry, function and evolution of plastocyanins. Intl Rev Biochem 13: 1–40
Briggs LM, Pecoraro VL and McIntosh L (1990) Copper-induced expression, cloning and regulatory studies of the plastocyanin gene from the cyanobacteriumSynechocystis sp PCC 6803. Plant Mol Biol 15: 633–642
Burkey KO and Gross EL (1981a) Use of chemical modification to study the relationship between activity and net protein charge of the Photosystem I core complex. Biochemistry 20: 2961–2967
Burkey KO and Gross EL (1981b) Effect of carboxyl group modification on the redox properties and electron donation capability of spinach plastocyanin. Biochemistry 20: 5495–5499
Burkey KO and Gross EL (1982) Chemical modification of spinach plastocyanin: Separation and characterization of four different forms. Biochemistry 21: 5886–5890
Chang TK, Iverson SA, Rodrigues CG, Kiser CN, Lew AYC, Germanas JP and Richards JH (1991) Gene synthesis, expression, and mutagenesis of the blue copper proteins azurin and plastocyanin. Proc Natl Acad Sci 88: 1325–1329
Chitnis VP, Cohen Y, Zhu Q, George D and Chitnis PR (1992) Mutational analyses of the accessory subunits of Photosystem I. Proc 18th Ann Midwest Photosynth Conf, p 7
Christensen HEM, Conraad LS and Ulstrup J (1992) Effects of NO2-modification of Tyr 83 on the reactivity of spinach plastocyanin with cytochromef. Biochim Biophys Acta 1099: 35–44
Church WB, Guss JM, Potter JJ and Freeman HC (1966) The crystal structure of mercury-substituted poplar plastocyanin at 1.9 Å resolution. J Biol Chem 261: 234–237
Coleman PM, Freeman HC, Guss JM, Murata M, Norris VA, Ramshaw JAM and Venkatappa MP (1978) X-ray crystal analysis of plastocyanin at 2.7 Å resolution. Nature 272: 319–324
Collyer CA, Guss JM, Sugimura Y, Yoshizaki FY and Freeman HC (1990) Crystal structure of plastocyanin from a green alga,Enteromorpha prolifera. J Mol Biol 211: 617–632
Cookson DJ, Hayes MT and Wright PE (1980) NMR Studies of the interaction of plastocyanin with chromium (III) analogues of inorganic electron transfer reagents. Biochim Biophys Acta 591: 162–176
Davis DJ and Hough K (1983) Preparation of a covalently linked adduct between plastocyanin and cytochromef. Biochem Biophys Res Commun 116: 1000–1006
Durell SR, Labanowski J and Gross EL (1990) Modeling of the electrostatic potential field of plastocyanin. Arch Biochem Biophys 277: 241–254
Freeman HC (1981) Electron transfer in ‘blue’ copper proteins. Coord Chem 21: 29–51
Garrett TPJ, Clingeleffer DJ, Guss JM, Rogers SH and Freeman HC (1984) The crystal structure of poplar apoplastocyanin at 1.8 Å resolution. The geometry of the copper-binding site is created by the polypeptide. J Biol Chem 159: 2822–2825
Gilson MK and Honig BH (1988) Energetics of charge-charge interactions in proteins. Proteins: Structure Function and Genetics 3: 32–52
Gilson MK, Sharp KA and Honig BH (1987) Calculating the electrostatic potential of molecules in solution: Method and error assessment. J Comput Chem 9: 327–335
Gray JC (1992) Cytochromef: Structure, function and biosynthesis. Photosynthe Res 34: 359–374
Gross EL and Curtiss A (1991) The interactions of nitrotyrosine-83 plastocyanin with cytochromesf andc: pH dependence and the effect of an additional negative charge on plastocyanin. Biochim Biophys Acta 1056: 166–172
Gross EL, Anderson GP, Ketchner SL and Draheim JE (1985) Plastocyanin conformation. The effect of nitrotyrosine modification and pH. Biochim Biophys Acta 808: 437–447
Gross EL, Curtiss A, Durell SR and White D (1990) Chemical modification of spinach plastocyanin using 4-chloro-3,5-dinitrobenzoic acid: Characterization of four singly-modified forms. Biochim Biophys Acta 1016: 107–114
Gross EL, Molnar S, Curtiss A, Reuter RA and Berg SP (1991) The use of monoclonal antibodies to study the structure and function of cytochromef. Arch Biochem Biophys 289: 244–255
Gross EL, Draheim JE, Curtiss AS, Crombie B, Scheffer A, Pan B, Chiang C and Lopez A (1992) Thermal denaturation of plastocyanin: The effect of oxidation state, reductants, and anaerobicity. Arch Biochem Biophys 298: 413–419
Guss JM and Freeman HC (1983) Structure of oxidized poplar plastocyanin at 1.6 Å resolution. J Mol Biol 169: 521–563
Guss JM, Harrowell PR, Murata M, Norris VA and Freeman HC (1986) Crystal structure analyses of reduced poplar plastocyanin at six pH values. J Mol Biol 192: 361–387
Handford PM, Hill HAO, Lee RW-K, Henderson RA and Sykes AG (1980) Investigation of the binding of inorganic complexes to blue copper proteins by proton NMR spectroscopy. I. The interaction between the [Cr(phen)3]3+ and [Cr(CN)5]+3 ions and the Cu (I) form of parsley PC. J Inorg Biochem 13: 83–88
Hauska G, Hurt E, Gabellini N and Lockau W (1983) Comparison of aspects of the quinol-cytochromec/plastocyanin oxidoreductases. Biochem Biophys Acta 726: 97–133
Hauska G, Nitschke W and Hermann RG (1988) Amino acid identities in the three redox center carrying polypeptides of the cytochrome bc1/b6f complexes. J Bioenerget Biomemb 20: 211–228
He S, Modi S, Bendall DA and Gray JC (1991) The surface-exposed residue tyrosine Tyr 83 of pea plastocyanin is involved in both binding and electron transfer reactions with cytochromef. EMBO J 10: 4011–4016
Hippler M, Ratajczak R and Haehnel W (1989) Identification of the plastocyanin binding subunit of Photosystem I. FEBS Lett 250: 280–284
King GC, Binstead RA and Wright PE (1985) NMR and kinetic characterization of the interaction between French bean plastocyanin and horse cytochromec. Biochim Biophys Acta 806: 262–271
Klapper I, Hagstron R, Fine R, Sharp K and Honig B (1986) Focusing of electric fields in the active site of Cu-Zn superoxide dismutase: Effects of ionic strength and aminoacid modification. Proteins: Structure, Function and Genetics 1: 47–59
Last DI and Gray JC (1989) Synthesis and accumulation of transgenic tobacco plants. Plant Mol Biol 12: 655–666
Margoliash E and Bosshard HR (1983) Guided by electrostatics, a textbook protein comes of age. Trends Biochem Sci 8: 316–320
Martinez SE, Smith JL, Huang D, Szczepaniak A and Cramer WA (1992) Crystallographic studies of the lumen-side domain of turnip cytochromef. In: Murata N (ed) Research in Photosynthesis, Vol II, pp 495–498. Kluwer Academic Publishers, Dordrecht
Merchant S and Bogorad L (1986) Rapid degradation of apoplastocyanin in Cu (II) deficient cells ofChlamydomonas reinhardii. J Biol Chem 261: 15850–15853
Modi S, He S, Gray JC and Bendall DS (1992a) The role of surface-exposed Tyr 83 of plastocyanin in electron transfer from cytochromec. Biochim Biophys Acta 1101: 64–68
Modi S, Nordling M, Lundberg LG, Orjan, Hannson and Bendell DS (1992b) Reactivity of cytochromesc andf with mutant forms of spinach plastocyanin. Biochim Biophys Acta 1102: 85–90
Morand LZ, Frame MK, Colvert KK, Johnson DA, Krogmann DW and Davis DJ (1989) Plastocyanin cytochromef interaction. Biochemistry 28: 8039–8047
Moore JM, Case DA, Chazin WJ, Gippert GP, Havel TF, Powls R and Wright PE (1988) Three-dimensional solution structure of plastocyanin from the green algaScenedesmus obliquus. Science 240: 314–317
Moore JM, Lepre CA, Gippert GP, Chazin WJ, Case DA and Wright PE (1991) High-resolution solution structure of French bean plastocyanin and comparison with the crystal structure of poplar plastocyanin. J Mol Biol 221: 533–555
Niwa S, Ishikawa H, Nikai S and Takabe T (1980) Electron transfer reactions between cytochromef and plastocyanin fromBrassica komatuna. J Biochem 88: 1177–1183
Nordling M, Olausson and Lundberg LG (1990) Expression of plastocyanin inE. Coli. FEBS Lett 276: 98–102
Nordling M, Sigfridsson K, Young S, Lundberg LG and Hansson O (1991) Flash-photolysis studies of the electron transfer from genetically modified spinach plastocyanin to Photosystem I. FEBS Lett: 291: 327–330
Northrup SH, Boles JO and Reynolds JCL (1988) Brownian dynamics of cytochromec and cytochromec peroxidase association. Science 241: 67–70
Ort DR and Melandri BA (1982) Mechanism of ATP synthesis. In: Govindjee (ed) Photosynthesis: Energy Conversion by Plants and Bacteria, Vol I, pp 537–588. Academic Press, New York
Pan LP, Frame M, Durham B, Davis D and Millet F (1990) Photoinduced electron transfer within complexes between plastocyanin and ruthenium bisbipyridine dicarboxybipyridine cytochromec derivatives. Biochemistry 29: 3231–3236
Peerey LM and Kostic NM (1989) Oxidoreduction reactions involving the electrostatic and the covalent complex of cytochromec and plastocyanin: Importance of the protein rearrangement for the intracomplex electron-transfer reactions. Biochemistry 28: 1861–1868
Peerey LM, BrothersII HM, Hazzard JT, Tollin G and Kostic NM (1992) Unimolecular and bimolecular oxidoreduction reactions involving diprotein complexes of cytochromec and plastocyanin. Dependence of electron transfer reactivity on charge and orientation of the docked metalloprotein. Biochemistry 30: 9297–9304
Qin L and Kostic NM (1992) Electron-transfer reactions of cytochromef with flavin semiquinones and with plastocyanin: Importance of protein-protein electrostatic interactions and donor-acceptor coupling. Biochemistry 31: 5145–5150
Roberts VA, Freeman HC, Olson AJ, Tainer JA and Getzoff ED (1991) Electrostatic orientation of the electron-transfer complex between plastocyanin and cytochromec. J Biol Chem 266: 13431–13441
Rush JD, Levine F and Koppenol WH (1988) The electrontransfer site of spinach plastocyanin. Biochemistry 27: 5876–5884
Sanderson DG, Anderson LB and Gross EL (1986) Determination of the redox potential and diffusion coefficient of the protein plastocyanin using optically transparent filar electrodes. Biochim Biophys Acta 852: 269–278
Scawen MD, Hewitt EJ and James DM (1975) Preparation, crystallization and properties ofCucurbita pepo plastocyanin and ferredoxin. Phytochem 14: 1225–1233
Selak MA and Whitmarsh J (1984) Charge transfer from Photosystem I to the cytochromeb/f complex: Diffusion and membrane lateral heterogeneity. Photochem Photobiol 39: 485–490
Scheller HV and Moller BL (1990) Photosystem I polypeptides. Physiol Plantarum 78: 484–494
Sheller HV, Andersen B, Okkels S, Swendsen I and Moller BL (1990) Photosystem I in barley: Subunit I is not essential for the interaction with plastocyanin. In: Baltscheffsky M (ed) Current Research In Photosynthesis, Vol II, pp 679–682. Kluwer Academic Publishers, Dordrecht
Sinclair-Day JD, Sisley MJ, Sykes AG, King GC and Wright PE (1985) Acid dissociation constants for plastocyanin in the Cu1 state. J Chem Soc Chem Commun 1985: 505–507
Skolnick J and Kolinski A (1990) Simulations of the folding of a globular protein. Science 250: 1121–1125
Sykes AG (1985) Structure and electron transfer reactivity of the blue copper protein plastocyanin. Chem Soc Rev 14: 283–315
Sykes AG (1991) Plastocyanin and the blue copper proteins. Struct Bond 75: 175–224
Takabe T, and Ishikawa H (1989) Kinetic studies on a cross-linked complex between plastocyanin and cytochromef. J Biochem 105: 98–102
Takabe T, Ishikawa H, Niwa S and Itoh S (1983) Electron transfer between plastocyanin and P700 in highly purified Photosystem I reaction center complex. Effects of pH, cations, and peptide subunit composition. J Biochem 94: 1901–1911
Takabe T, Ishikawa H, Niwa S and Tanaka Y (1984) Electron transfer reactions of chemically-modified plastocyanins with P700 and cytochromef. Importance of local charges. J Biochem 96: 385–393
Takabe T, Takenaka K, Kawamura H and Beppu Y (1986) Charges on proteins and distances of electron transfer in metallopoprotein redox reactions. J Biochem 99: 833–840
Takenaka K and Takabe T (1984) Importance of local positive charges on cytochromef for electron transport to plastocyanin and potassium ferricyanide. J Biochem 96: 1813–1821
Wendoloski JJ, Matthew JB, Weber PC and Salemme FR (1991) Molecular dynamics of a cytochromec-cytochrome b5electron transfer complex. Science 238: 794–797
Widger WR (1991) The cloning and sequencing ofSynechococcus PCC 7002 pet CA operon: Implications for the cytochromec-553 binding domain of cytochromef. Photosynth Res 30: 71–85
Willey DL, Auffret AD and Gray JC (1984) Structure and topology of cytochromef from pea chloroplast membranes Cell 36: 555–562
Wood PM (1974) Rate of electron transfer between plastocyanin, cytochromef, related proteins and artificial redox reagents in solution. Biochim Biophys Acta 357: 370–379
Wynn RM and Malkin R (1988) Interaction of plastocyanin with PS I: A chemical cross-linking study of the polypeptide that binds plastocyanin. Biochemistry 27: 5863–5869
Zhou JS and Kostic NM (1992) Zinc cytochromec as a photochemical probe for studying electron-transfer reactions in metalloprotein complexes. Spectrum 5 (2): 1–6
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Gross, E.L. Plastocyanin: Structure and function. Photosynth Res 37, 103–116 (1993). https://doi.org/10.1007/BF02187469
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF02187469