Fluorescence polarization studies on four biliproteins and a bilin model for phycoerythrin 545.

Fluorescence (excitation) polarization spectroscopy in the wavelength region of the bilin chromophores was applied to phycoerythrocyanin (CV-phycocyanin), phycocyanins 645 and 612, and phycoerythrin 545. The cryptomonad biliproteins - phycoerythrin 545 and phycocyanins 612 and 645 - were studied as both protein dimers having an alpha(2)beta(2) polypeptide structure and as alphabeta monomers. The cyanobacterial phycoerythrocyanin (CV-phycocyanin) was a trimeric oligomer. The changes in polarization across the spectrum were attributed to transfers of energy between bilins. Cryptomonad biliproteins are isolated as dimers. The similarities between their steady-state fluorescence polarization spectra and those of the corresponding monomers suggested that the monomers' conformations were analogous to the dimers. This supports the use of monomers in the study of dimer bilin organization. The unusual polarization spectrum of phycoerythrin 545 was explained using a model for the topography of its bilins. Obtaining the emission spectra of phycoerythrin 545 at several temperatures and a deconvolution of the dimer circular dichroism spectrum also successfully tested the bilin model. Circular dichroism spectroscopy was used to determine which polarization changes are formed by Förster resonance energy transfers and which may be produced by internal conversions between high- and low-energy states of pairs of exciton-coupled bilins. Attempts were made to assign energy transfer events to the corresponding changes in fluorescence polarization for each of the four biliproteins.

Bilin organization in cryptomonad biliproteins.

The bilin organization of three cryptomonad biliproteins (phycocyanins 612 and 645 and phycoerythrin 545) was examined in detail. Two others (phycocyanin 630 and phycoerythrin 566) were studied less extensively. Phycocyanin 645 and phycoerythrin 545 were suggested to have one bilin in each monomeric (alphabeta) unit of the dimer (alpha2beta2) isolated from the others, and the remaining six bilins may be in pairs. One pair was found across the monomer-monomer interface of the protein dimer, and two identical pairs were proposed to be within the monomer protein units. For phycocyanin 612, a major surprise was that a pair of bilins was apparently not found across the monomer-monomer interface, but the remaining bilins were distributed as in the other two cryptomonad proteins. The effect of temperature on the CD spectra of phycocyainin 612 demonstrated that two of the bands (one positive and one negative) behaved identically, which is required if they are coupled. The two lowest-energy CD bands of phycocyanin 612 originated from paired bilins, and the two higher-energy bands were from more isolated bilins. The paired bilins within the protein monomers contained the lowest-energy transition for these biliproteins. Using the bilins as naturally occurring reporter groups, phycocyanin 612 was shown to undergo a reversible change in tertiary structure at 40 degrees C. Protein monomers were shown to be functioning biliproteins. A hypothesis is that the coupled pair of bilins within the monomeric units offers important advantages for efficient energy migration, and other bilins transfer energy to this pair, extending the wavelength range or efficiency of light absorption.

The bilirubin-binding motif of bilitranslocase and its relation to conserved motifs in ancient biliproteins.

In the primary structure of bilitranslocase, currently under study in our laboratory, an aminoacid motif was identified and found to be conserved in a number of alpha-phycocyanines, ancient biliproteins present in cyanobacteria. To test the possibility that such a motif could be at least part of the binding site for bilirubin, epitope-specific antibodies were raised. The target corresponds to the sequence 65-75 of bilitranslocase and covers the central portion of the motif identified. The antibodies were shown: 1) to inhibit the electrogenic BSP transport by plasmamembrane vesicles; 2) to react with purified bilitranslocase; and 3) to identify only one protein band with electrophoretic mobility identical to bilitranslocase in Western blots of solubilised plasmamembrane vesicles. The presence of either bilirubin or nicotinate during pre-incubation with the antibodies decreases concentration-wise the inhibition kinetics. From these experiments a dissociation constant of 2.2 +/- 0.3 and 11.3 +/- 1.3 nM for bilirubin-bilitranslocase and nicotinate-bilitranslocase complexes were calculated.

Genes of the R-phycocyanin II locus of marine Synechococcus spp., and comparison of protein-chromophore interactions in phycocyanins differing in bilin composition.

R-phycocyanin II (RPCII) is a recently discovered member of the phycocyanin family of photosynthetic light-harvesting proteins. Genes encoding the alpha and beta subunits of RPCII were cloned and sequenced from marine Synechococcus sp. strains WH8020 and WH8103. The deduced amino acid sequences of RPCII were compared to two other types of phycocyanin, C-phycocyanin (CPC) and phycoerythrocyanin (PEC). These three types vary in the composition of their covalently bound bilin prosthetic groups. In terms of amino acid sequence identity RPCII is highly homologous to CPC and PEC, suggesting that the known three-dimensional structures of the latter two are representative of RPCII. Thus the amino acid residues contacting the three bilins of RPCII could be inferred and compared to those in CPC and PEC. Certain residues were identified among the three phycocyanins as possibly correlating with specific bilin isomers. In overall sequence RPCII and CPC are more homologous to one another than either is to PEC. This probably reflects functional homology in the roles of RPCII and CPC in the transfer of light energy to the core of the phycobilisome, a function not attributed to PEC. The genomes of Synechococcus sp. strains WH8020, WH8103 and WH7803 share homologous open reading frames in the vicinity of RPCII genes. The nucleotide sequence extending 3' from RPCII genes in strain WH8020 revealed two open reading frames homologous to components of an alpha CPC phycocyanobilin lyase. These open reading frames may encode a lyase specific for the attachment of phycoerythrobilin to alpha RPCII.

Refined three-dimensional structure of phycoerythrocyanin from the cyanobacterium Mastigocladus laminosus at 2.7 A.

The structure of the phycobiliprotein phycoerythrocyanin from the thermophilic cyanobacterium Mastigocladus laminosus has been determined at 2.7 A resolution by X-ray diffraction methods on the basis of the molecular model of C-phycocyanin from the same organism. Hexagonal phycoerythrocyanin crystals of space group P6(3) with cell constants a = b = 156.86 A, c = 40.39 A, alpha = beta = 90 degrees, gamma = 120 degrees are almost isomorphous to C-phycocyanin crystals. The crystal structure has been refined by energy-restrained crystallographic refinement and model building. The conventional crystallographic R-factor of the final model was 19.2% with data to 2.7 A resolution. In phycoerythrocyanin, the three (alpha beta)-subunits are arranged around a 3-fold symmetry axis, as in C-phycocyanin. The two structures are very similar. After superposition, the 162 C alpha atoms of the alpha-subunit have a mean difference of 0.71 A and the 171 C alpha atoms of the beta-subunit differ by 0.51 A. The stereochemistry of the chiral atoms in the phycobiliviolin chromophore A84 is C(31)-R, C(4)-S. The configuration of the chromophore is C(10)-Z, C(15)-Z and the conformation C(5)-anti, C(9)-syn and C(14)-anti like the phycocyanobilin chromophores in phycoerythrocyanin and C-phycocyanin.

In vitro attachment of bilins to apophycocyanin. I. Specific covalent adduct formation at cysteinyl residues involved in phycocyanobilin binding in C-phycocyanin.

Expression of cloned alpha and beta subunit genes of Synechococcus sp. PCC7002 C-phycocyanin in Escherichia coli led to the production of large amounts of apophycocyanin. The apophycocyanin was purified to homogeneity and shown to be an alpha beta monomer. The reactivity of the apoprotein toward a number of open chain and cyclic tetrapyrroles was examined. Phycocyanobilin (PCB), phycoerythrobilin, and biliverdin all formed covalent adducts with apophycocyanin in 50 mM sodium phosphate buffer at pH 7.0. Mesobiliverdin, bilirubin, PCB dimethyl ester, protoporphyrin IX, and hemin did not react with the apoprotein. None of these tetrapyrroles reacted with 2 mM 2-mercaptoethanol, cysteine, or reduced glutathione under the same conditions. The adduct with PCB was investigated in greater detail. Its visible absorption spectrum, with a maximum at 646 nm, is more similar to that of allophycocyanin than phycocyanin. Two PCBs are bound per alpha beta monomer when the reaction is performed with excess bilin. While tryptic digestion of the adduct generates numerous bilin peptides, amino acid analysis of these chromopeptides revealed that PCB reacted specifically at alpha-Cys-84 and beta-Cys-82, two of the three cysteinyl residues that serve as the attachment sites for PCB in native phycocyanin. The major bilin peptides arising from in vitro adduct formation at each of these sites differed both in chromatographic behavior and in spectroscopic properties from the corresponding PCB peptides isolated from tryptic digests of native C-phycocyanin.

In vitro attachment of bilins to apophycocyanin. III. Properties of the phycoerythrobilin adduct.

Addition of phycoerythrobilin (PEB) to apophycocyanin at pH 7.0 resulted in covalent adduct formation. The adduct showed absorbance maxima at 575 and 605 nm and fluorescence emission maxima at 582 and 619 nm. Analysis of bilin peptides obtained upon tryptic digestion of the adduct showed residues alpha-Cys-84 and beta-Cys-82 to be the sites of bilin addition. The product of PEB addition at the alpha-Cys-84 site was shown by 1H NMR analysis to be a dihydrobiliviolinoid peptide-linked pigment differing in structure from that of the naturally occurring PEB-adduct by the presence of a double bond in between C2 and C3 of ring A. At the beta-Cys-82 site both a dihydrobiliviolinoid and a PEB adduct were obtained. Biliverdin also formed a covalent adduct with apophycocyanin with a lambda max of 669 nm. These results show that the spontaneous in vitro addition of bilins to apophycocyanin does not exhibit the site selectivity of bilin addition observed in vivo. This offers the opportunity to form novel semisynthetic phycobiliproteins.

In vitro attachment of bilins to apophycocyanin. II. Determination of the structures of tryptic bilin peptides derived from the phycocyanobilin adduct.

In vitro reaction of phycocyanobilin (PCB) with apophycocyanin results in the specific addition of the bilin to two of the cysteinyl residues, alpha-Cys-84 and beta-Cys-82, which normally function in PCB attachment (Arciero, D. M., Bryant, D. A., and Glazer, A. N. (1988) J. Biol. Chem. 263, 18343-18349). These bilin binding sites are designated alpha-1 and beta-1, respectively. Tryptic digestion of the apophycocyanin-PCB adduct releases two major bilin peptides, alpha-1 mesobiliverdin (MBV) and beta-1 MBV, which encompass the two bilin-binding sites. These peptides were examined by 1H NMR and fast atom bombardment mass spectroscopies. The NMR spectra show that the bilin is attached to each peptide through a thioether linkage identical to the linkage observed in the corresponding tryptic peptides, alpha-1 PCB and beta-1 PCB, derived from the natural product, C-phycocyanin. However, the NMR spectra of the adduct peptides lack the resonances corresponding to protons at positions C2 and C3 of ring A seen in the spectra of the alpha-1 PCB and beta-1 PCB peptides. Fast atom bombardment mass spectroscopy shows the masses of the alpha-1 MBV and beta-1 MBV peptides to be 2 atomic mass units lower than those of the alpha-1 PCB and beta-1 PCB peptides, respectively. Comparison of the bilin portion of the NMR spectra of the alpha-1 MBV and beta-1 MBV peptides to the NMR spectra of PCB and mesobiliverdin confirms that the bilin of the two adduct peptides resembles mesobiliverdin in having an extra double bond in the C2-C3 position of ring A. These results show that the major bilin products arising from the reaction of PCB with apophycocyanin differ from the bilins present in C-phycocyanin. The relevance of these results to the biosynthetic pathway for the attachment of tetrapyrroles to phycobiliproteins is discussed.

R-phycocyanin II, a new phycocyanin occurring in marine Synechococcus species. Identification of the terminal energy acceptor bilin in phycocyanins.

A new member of the phycocyanin family of phycobiliproteins, R-phycocyanin II (R-PC II) has been discovered in several strains of marine Synechococcus sp. R-PC II has absorption maxima at 533 and 554 nm, a subsidiary maximum at 615 nm, and a fluorescence emission maximum at 646 nm. It is the first phycoerythrobilin (PEB)-containing phycocyanin of cyanobacterial origin. The purified protein is made up of alpha and beta subunits in equal amounts and is in an (alpha beta)2 aggregation state. The alpha and beta subunits of this protein are homologous to the corresponding subunits of previously described C- and R-phycocyanins as assessed by amino-terminal sequence determination and analyses of sequences about sites of bilin attachment. R-PC II carries phycocyanobilin (PCB) at beta-84 and PEB at alpha-84 and beta-155 (residue numbering is that for C-phycocyanin), whereas in C-phycocyanin PCB is present at all three positions. In R-phycocyanin, the bilin distribution is alpha-84 (PCB), beta-84 (PCB), beta-155 (PEB). In both R-phycocyanin and R-phycocyanin II excitation at 550 nm, absorbed primarily by PEB groups, leads to emission at 625 nm from PCB. These comparative data support the conclusion that the invariant beta-84 PCB serves as the terminal energy acceptor in phycocyanins.

The photosensitizing action of phycobiliproteins in the adsorbed state.

In connection with the elucidation of the possibility of photochemical participation of phycobiliproteins in the primary processes of photosynthesis, the ability of a mixture of phycocyanin + allophycocyanin (PC + APC) for photosensitization of redox reactions in the adsorbed state was investigated. It was shown that adsorbates of PC + APC on Sephadexes G-200 and G-25, diethylaminoethylcellulose, carboxyethylcellulose, Bacto-agar, Lifogel, polyethylene glycol, Dowex 50Wx2, and aluminum oxide are capable of sensitizing the photoreduction of methyl red by ascorbid acid. In this case the effectiveness of the sensitizing action depends on the concentration of the adsorbate, the pigment concentration on the carrier, the pH of the medium, and the nature of the solvent. It was shown that in the case of binding to a carrier, the sensitizing ability of PC + APC increases in comparison with that for pigments in the dissolved state. It is suggested that this is promoted by an increase in the concentration and a mutual approach of the reagents after adsorption, and the possible formation of complexes of some or all the participants of the reaction on the surface of the adsorbent.