Energy transfer in phycobilisomes from phycoerythrin to allophycocyanin

Allophycocyanin appears to be the pigment through which energy trapped by phycobiliproteins is funneled to the chloroplast lamellae. Isolated, intact phycobilisomes from Porphyridium cruentum have a maximum fluorescence emission peak at 675–680 nm when excited at 545 nm. Upon dissociation, when the energy transfer is interrupted the 675–680-nm peak declines. Excitation at 435 nm produced no significant fluorescence at this wavelength.     

Rod substructure in cyanobacterial phycobilisomes: phycoerythrin assembly in synechocystis 6701 phycobilisomes

Synechocystis 6701 phycobilisomes consist of a core of three cylindrical elements in an equilateral array from which extend in a fanlike manner six rods, each made up of three to four stacked disks. Previous studies (see Gingrich, J. C., L. K. Blaha, and A. N. Glazer, 1982. J. Cell Biol. 92:261-268) have shown that the rods consist of four disk-shaped complexes of biliproteins with "linker" polypeptides of 27-, 33.5-, 31.5-, and 30.5-kdaltons, listed in order starting with the disk proximal to the core: phycocyanin (alpha beta)6-27 kdalton, phycocyanin (alpha beta)6-33.5 kdalton, phycoerythrin (alpha beta)6- 31.5 kdalton, phycoerythrin (alpha beta)6-30.5 kdalton, where alpha beta is the monomer of the biliprotein. Phycoerythrin complexes of the 31.5- and 30.5-kdalton polypeptides were isolated in low salt. In 0.05 M K-phosphate-1 mM EDTA at pH 7.0, these complexes had the average composition (alpha beta)2-31.5 and (alpha beta)-30.5 kdalton polypeptide, respectively. Peptide mapping of purified 31.5- and 30.5- kdalton polypeptides showed that they differed significantly in primary structure. In 0.65 M Na-K-phosphate at pH 8, these phycoerythrin complexes formed rods of stacked disks of composition (alpha beta)6- 31.5 or (alpha beta)6-30.5 kdaltons. For the (alpha beta)-30.5 kdalton complex, the yield of rod assemblies was variable and the self- association of free phycoerythrin to smaller aggregates was an important competing reaction. Complementation experiments were performed with incomplete phycobilisomes from Synechocystis 6701 mutant strain CM25. These phycobilisomes are totally lacking in phycoerythrin and the 31.5- and 30.5-kdalton polypeptides, but have no other apparent structural defects. In high phosphate at pH 8, the phycoerythrin-31.5- kdalton complex formed disk assemblies at the end of the rod substructures of CM25 phycobilisomes whereas no interaction with the phycoerythrin-30.5 kdalton complex was detected. In mixtures of both the phycoerythrin-31.5 and -30.5 kdalton complexes with CM25 phycobilisomes, both complexes were incorporated at the distal ends of the rod substructures. The efficiency of energy transfer from the added phycoerythrin in complemented phycobilisomes was approximately 96%. The results show that the ordered assembly of phycoerythrin complexes seen in phycobilisomes is reproduced in the in vitro assembly process.     

Resonance Raman spectra of phycocyanin, allophycocyanin and phycobilisomes from blue-green alga Anacystis nidulans

Resonance Raman spectra of native C-phycocyanin, allophycocyanin and whole, intact phycobilisomes from the blue-green alga Anacystis nidulans (Synechococcus 6301) are reported. A tentative assignment for the more prominent resonance Raman bands is suggested. The possibly sensitive regions for inter-chromophore interactions in the case of phycobilisomes are also discussed.     

Energy migration in phycobilisomes

Fluorescence emission and polarization spectra of the phycobilisomes (PBS) of the blue-green alga Nostoc muscorum were measured at 20, -73 and -196 degrees C while exciting at the absorption maximum of each pigment in the PBS. The emission spectra were deconvoluted into a number of Gaussian components and energy migration coefficients and quantum yields of fluorescence for the 8 forms of the phycobilins constituting the PBS were calculated. The overlap integrals and the critical and real distances for the energy transfer in the donor-acceptor pairs were evaluated. The general scheme of the energy transfer in the PBS is proposed according to which there is a homogeneous energy migration within each pigment form and a following effective heterogeneous migration directed from the short wavelength forms via the intermediate ones to the terminal long wavelength acceptors. The transfer passes one or more steps of the energy "staircase" which is formed by the excited levels of the forms. The backward "uphill" energy transfer does not take place. These data and the estimates of the real distances of the energy transfer allowed us to make a conclusion on the regular arrangement of the pigments in the PBS, to determine the distances between the chromophores and their localization in a pigment molecule and the distances between the chromophores of different pigments and thus to specify the structure of the PBS.     

Use of phycoerythrin and allophycocyanin for fluorescence resonance energy transfer analyzed by flow cytometry: advantages and limitations

BACKGROUND: This study validates the use of phycoerythrin (PE) and allophycocyanin (APC) for fluorescence energy transfer (FRET) analyzed by flow cytometry. METHODS: FRET was detected when a pair of antibody conjugates directed against two noncompetitive epitopes on the same CD8alpha chain was used. FRET was also detected between antibody conjugate pairs specific for the two chains of the heterodimeric alpha (4)beta(1) integrin. Similarly, the association of T-cell receptor (TCR) with a soluble antigen ligand was detected by FRET when anti-TCR antibody and MHC class I/peptide complexes () were used. RESULTS: FRET efficiency was always less than 10%, probably because of steric effects associated with the size and structure of PE and APC. Some suggestions are given to take into account this and other effects (e.g., donor and acceptor concentrations) for a better interpretation of FRET results obtained with this pair of fluorochromes. CONCLUSIONS: We conclude that FRET assays can be carried out easily with commercially available antibodies and flow cytometers to study arrays of multimolecular complexes.     

Charge transfer states in phycobilisomes

Phycobilisomes (PBs) absorb light and supply downstream photosynthetic processes with excitation energy in many cyanobacteria and algae. In response to a sudden increase in light intensity, excess excitation energy is photoprotectively dissipated in PBs by means of the orange carotenoid protein (OCP)-related mechanism or via a light-activated intrinsic decay channel. Recently, we have identified that both mechanisms are associated with far-red emission states. Here, we investigate the far-red states involved with the light-induced intrinsic mechanism by exploring the energy landscape and electro-optical properties of the pigments in PBs. While Stark spectroscopy showed that the far-red states in PBs exhibit a strong charge-transfer (CT) character at cryogenic temperatures, single molecule spectroscopy revealed that CT states should also be present at room temperature. Owing to the strong environmental sensitivity of CT states, the knowledge gained from this study may contribute to the design of a new generation of fluorescence markers.     

Sorbitol regulates energy transfer from allophycocyanin to the terminal emitter within phycobilisomes in <Emphasis Type="Italic">Synechocystis</Emphasis> sp

The effects of sorbitol on energy transfer of phycobilisomes (PBSs) in vivo were investigated in a chlN deletion mutant of Synechocystis sp. PCC 6803. When the mutant was grown in the dark, it contained intact and functional PBSs but essentially no chlorophyll or photosystems. Therefore, the structural and functional changes of the mutant PBSs in vivo can be detected by measurement of low temperature (77 K) and room temperature fluorescence emission spectra. Our results, for the first time, demonstrate that sorbitol decreases the energy transfer from allophycocyanin to the terminal emitter, indicating the site for osmotic regulation of excitation transfer in PBSs.     

Factors affecting energy transfer from phycobilisomes to thylakoids in Anacystis nidulans.

Short illumination with white light of dark-maintained Anacystis nidulans prior to immersion in liquid nitrogen resulted in a marked change of fluorescence emission characteristics at 77 K. The fluorescence of Photosystem II-associated membrane bound pigments increases, while the emission due to phycobilins decreases. This effect seems to be due to a light-dependent alteration in the extent of contact between phycobilisomes and thylakoids, since the effect is reversible in the dark and is abolished by short glutaraldehyde fixation. The preillumination effect is not inhibited by DCMU. Emission spectra obtained with actively growing and CO2-starved cells indicate that the light-dependent increase in energy transfer from phycobilins to chlorophyll depends upon the physiological state of the cells.     

Spectral analysis of allophycocyanin I, II, III and B from Nostoc sp. phycobilisomes

Low temperature (-196C) and room temperature (25C) absorption spectra of a family of allophycocyanin spectral forms isolated from Nostoc sp. phycobilisomes as well as of the phycobilisomes themselves have been analyzed by Gaussian curve-fitting. Allophycocyanin I and B share long wavelength components at 668 and 679 nm, bands that are absent from allophycocyanin II and III. These long wavelength absorption components are apparently responsible for the 20 nm difference between the 680 nm fluorescence emission maximum of allophycocyanin I and B and the 660 nm maximum of II and III. This indicates that allophycocyanin I and B are the final acceptors of excitation energy in the phycobilisome and the excitation energy transfer bridge linking the phycobilisome with the chlorophyll-containing thylakoid membranes. These Gaussian components are also found in resolved spectra of phycobilisomes, are arguing against this family of allophycocyanin molecules being artifactual products of protein purification procedures.     

Molecular architecture of a light-harvesting antenna. Core substructure in Synechococcus 6301 phycobilisomes: two new allophycocyanin and allophycocyanin B complexes

Two new allophycocyanin-containing complexes were found among the products of partial dissociation of the phycobilisomes of Synechococcus 6301 strain AN112. These complexes were purified to homogeneity and characterized with respect to composition, stability, and spectroscopic properties. The structures of the complexes were established to be (alpha AP beta AP)3 . 10.5K and (alpha 1APB alpha 2AP beta 3AP) . 10.5 K, where alpha AP and beta AP are subunits of allophycocyanin, and alpha APB is the subunit of allophycocyanin B (see Lundell, D. J., and Glazer, A. N. (1981) J. Biol. Chem. 256, 12600-12606), and 10.5K is an uncolored polypeptide of 10.5-kilodaltons. These complexes are derived from the core substructure of the phycobilisome. Electron microscopic studies of the morphology of the core of strain AN112 phycobilisomes (Yamanaka, G., Glazer, A. N., and Williams, R. C. (1980) J. Biol. Chem. 255, 11004-11010) as well as structural studies of an 18 S subassembly derived from the phycobilisomes by partial dissociation (Yamanaka, G., Lundell, D. J., and Glazer, A. N. (1982) J. Biol. Chem. 257, 4077-4086) indicated that the core assembly consisted of two cylindrical elements each made up of the same four distinct "trimeric" biliprotein-containing complexes. Two such core components, (alpha AP beta AP)3 and alpha 2AP beta 2AP. 18.3K . 75K (where 18.3K and 75K are polypeptides of 18.3- and 75-kilodaltons), were shown to be contained within the 18 S subassembly (Lundell, D. J., and Glazer, A. N. (1983) J. Biol. Chem. 258, 894-901). The isolation of the two allophycocyanin-containing complexes described here completes the characterization of the four types of components in the Synechococcus 6301 phycobilisome core. Two lines of evidence indicate that each of the four complexes is present twice in the core: comparison of the compositions (and yields) of the complexes with that of the intact AN112 phycobilisome, and near-coincidence of the molar absorption spectrum of the phycobilisome with that generated by summing the spectra of the constituent complexes taken in appropriate molar proportions.     

Factors affecting energy transfer from phycobilisomes to thylakoids in Anacystis nidulans

Short illumination with white light of dark-maintained Anacystis nidulans prior to immersion in liquid nitrogen resulted in a marked change of fluorescence emission characteristics at 77 K. The fluorescence of Photosystem II-associated membrane bound pigments increases, while the emission due to phycobilins decreases. This effect seems to be due to a light-dependent alteration in the extent of contact between phycobilisomes and thylakoids, since the effect is reversible in the dark and is abolished by short glutaraldehyde fixation. The preillumination effect is not inhibited by DCMU. Emission spectra obtained with actively growing and CO₂-starved cells indicate that the light-dependent increase in energy transfer from phycobilins to chlorophyll depends upon the physiological state of the cells.     

Variety in excitation energy transfer processes from phycobilisomes to photosystems I and II

Photosynthesis Research - The light-harvesting antennas of oxygenic photosynthetic organisms capture light energy and transfer it to the reaction centers of their photosystems. The light-harvesting...     

Subparticles of Anabaena phycobilisomes. II. Molecular assembly of allophycocyanin cores in reference to "anchor" protein

Entire phycobilisomes (PBS) and two derived particles, whole allophycocyanin (APC) cores and the far-red-emitting fragment of APC cores (14.5 S APC), all containing the 115-kDa polypeptide ("anchor protein"), were compared for the readiness with which the 115-kDa protein could be modified chemically, be degraded by chymotrypsin, and react with the anti-115-kDa serum. The 115 kDa in PBS and the whole APC cores were digested slightly by chymotrypsin and did not react with anti-115-kDa IgG. In contrast, the 115 kDa in 14.5 S APC was digested to 42 kDa and showed a positive reaction with anti-115-kDa IgG. Reconstitution of APC cores from 14.5 S APC and APC trimers was inhibited by the anti-115-kDa IgG, and APC particles with partly digested 115-kDa cannot reconstitute APC cores. These results imply that 115 kDa is embedded mostly inside PBS and is involved more in the maintenance of the molecular assembly of APC cores than in the "anchoring" of PBS to thylakoid. The PBS from Anabaena variabilis (M3) have an APC core larger than those of other PBS and show atypical morphology consisting of five APC discs. They have a polypeptide (115 kDa) that is significantly longer than the corresponding polypeptides (around 95 kDa) of other blue-green algae. This can be interpreted by assuming a relationship between the size of APC cores and the length of the polypeptide.     

Energy transfer processes in Gloeobacter violaceus PCC 7421 that possesses phycobilisomes with a unique morphology

We examined energy transfer dynamics in phycobilisomes (PBSs) of cyanobacteria in relation to the morphology and pigment compositions of PBSs. We used Gloeobacter violaceus PCC 7421 and measured time-resolved fluorescence spectra in three types of samples, i.e., intact cells, PBSs, and rod assemblies separated from cores. Fremyella diplosiphon, a cyanobacterial species well known for its complementary chromatic adaptation, was used for comparison after growing under red or green light. Spectral data were analyzed by the fluorescence decay-associated spectra with components common in lifetimes with a time resolution of 3 ps/channel and a spectral resolution of 2 nm/channel. This ensured a higher resolution of the energy transfer kinetics than those obtained by global analysis with fewer sampling intervals. We resolved four spectral components in phycoerythrin (PE), three in phycocyanin (PC), two in allophycocyanin, and two in photosystem II. The bundle-like PBSs of G. violaceus showed multiple energy transfer pathways; fast ( approximately 10 ps) and slow ( approximately 100 ps and approximately 500 ps) pathways were found in rods consisting of PE and PC. Energy transfer time from PE to PC was two times slower in G. violaceus than in F. diplosiphon grown under green light.     

Cyanobacterial ycf27 gene products regulate energy transfer from phycobilisomes to photosystems I and II

Two open reading frames (slr0115 and slr0947) in the genome of the cyanobacterium Synechocystis sp. PCC 6803 are shown to be involved in the regulation of the coupling of phycobilisomes to photosynthetic reaction centres. Homologues of these genes, called ycf27, have been found in a range of phycobilin-containing organisms. The slr0115 and slr0947 gene products are OmpR-type DNA-binding response regulator proteins. Deletion of slr0115 results in increased efficiency of energy transfer from phycobilisomes to photosystem II relative to photosystem I. Reduction of the copy number of slr0947 has the opposite phenotypic effect. We have given the slr0115 and slr0947 genes the designations rpaA and rpaB respectively.     

Energy transfer processes in Gloeobacter violaceus PCC 7421 that possesses phycobilisomes with a unique morphology

We examined energy transfer dynamics in phycobilisomes (PBSs) of cyanobacteria in relation to the morphology and pigment compositions of PBSs. We used Gloeobacter violaceus PCC 7421 and measured time-resolved fluorescence spectra in three types of samples, i.e., intact cells, PBSs, and rod assemblies separated from cores. Fremyella diplosiphon, a cyanobacterial species well known for its complementary chromatic adaptation, was used for comparison after growing under red or green light. Spectral data were analyzed by the fluorescence decay-associated spectra with components common in lifetimes with a time resolution of 3 ps/channel and a spectral resolution of 2 nm/channel. This ensured a higher resolution of the energy transfer kinetics than those obtained by global analysis with fewer sampling intervals. We resolved four spectral components in phycoerythrin (PE), three in phycocyanin (PC), two in allophycocyanin, and two in photosystem II. The bundle-like PBSs of G. violaceus showed multiple energy transfer pathways; fast (≈ 10 ps) and slow (≈ 100 ps and ≈ 500 ps) pathways were found in rods consisting of PE and PC. Energy transfer time from PE to PC was two times slower in G. violaceus than in F. diplosiphon grown under green light.     

Biliprotein assembly in the disc-shaped phycobilisomes of Rhodella violacea electron microscopical and biochemical analyses of C-phycocyanin and allophycocyanin aggregates

C-phycocyanin and allophycocyanin from the red alga Rhodella violacea were investigated by electron microscopy and biochemical methods using samples taken from the same fractions.The molecular weights of the native biliprotein aggregates C-phycocyanin and allophycocyanin are about 139,000 (140,000) and 130,000 (145,000) as revealed by calibrated gel chromatography, gradient gel electrophoresis and morphological measurements on the basis of an average protein packing density. These molecular weights are direct evidence for a trimeric aggregation form ()₃ of these biliproteins. Independently, their monomers were determined to be about 34,400 (C-phycocyanin) and 33,900 (allophycocyanin).C-phycocyanin and allophycocyanin are ringshaped, six-membered, biliprotein aggregates with dimensions of about 10.2×3.0 nm and 10.0×3.0 nm, respectively. The aggregates are made up of six subunits, 3 and 3, which are assumed to be associated in alternating positions. They are arranged in regular hexagons in C₆ symmetry. Hexameric aggregates ()₆, so far only isolated for C-phycocyanin, originate by face to face association of two trimeric aggregates.     

The fluorescence spectra of red algae and the transfer of energy from phycoerythrin to phycocyanin and chlorophyll

1. The fluorescence spectra of the alga Porphyridium have been recorded as energy distribution curves for eleven different incident wave lengths of monochromatic incident light between wave lengths 405 and 546 mµ. 2. In these spectra chlorophyll fluorescence predominates when the incident light is in the blue part of the spectrum which is strongly absorbed by chlorophyll. 3. For blue-green and green light the spectrum excited in Porphyridium contains in addition to chlorophyll fluorescence, the fluorescence bands characteristic of phycoerythrin and of phycocyanin. 4. From these spectra the approximate curves for the fluorescence of the individual pigments phycoerythrin, phycocyanin, and chlorophyll in the living material have been derived and the relative intensity of each of them has been obtained for each of the eleven incident wave lengths. 5. The effectiveness spectrum for the excitation of the fluorescence of these three pigments in vivo has been plotted. 6. From comparisons of the effectiveness spectrum for the excitation of each of these pigments it appears that both phycocyanin and chlorophyll receive energy from light which is absorbed by phycoerythrin. 7. It is suggested that phycocyanin may be an intermediate in the resonance transfer of energy from phycoerythrin to chlorophyll. 8. Since phycoerythrin and phycocyanin transfer energy to chlorophyll, it appears probable that chlorophyll plays a specific chemical role in photosynthesis in addition to acting as a light absorber.     

A newly developed SGB buffer greatly enhances energy transfer efficiency from phycobilisomes to photosystem II in cyanobacteria in vitro

The transfer of light energy from phycobilisomes (PBS) to photosystem II (PSII) reaction centers is vital for photosynthesis in cyanobacteria and red algae. To investigate the relationship between PBS and PSII and to optimize the energy transfer efficiency from PBS to PSII, isolation of the PBS-PSII supercomplex is necessary. SPC (sucrose/phosphate/citrate) is a conventional buffer for isolating PBS-PSII supercomplex in cyanobacteria. However, the energy transfer occurring in the supercomplex is poor. Here, we developed a new buffer named SGB by adding 1M glycinebetaine and additional sucrose to SPC buffer. Compared to SPC, the newly developed SGB buffer greatly enhanced the associated populations of PBS with thylakoid membranes and PSII and further improved the energy transfer efficiency from PBS to PSII reaction centers in cyanobacteria in vitro. Therefore, we conclude that SGB is an excellent buffer for isolating the PBS-PSII supercomplex and for enhancing the energy transfer efficiency from PBS to PSII reaction centers in cyanobacteria in vitro.