Phycobilisome Structure of Porphyridium cruentum: POLYPEPTIDE COMPOSITION

Purified phycobilisomes of Porphyridium cruentum were solubilized in sodium dodecyl sulfate and resolved by sodium dodecyl sulfate-acrylamide gel electrophoresis into nine colored and nine colorless polypeptides. The colored polypeptides accounted for about 84% of the total stainable protein, and the colorless polypeptides accounted for the remaining 16%. Five of the colored polypeptides ranging in molecular weight from 13,300 to 19,500 were identified as the α and β subunits of allophycocyanin, R-phycocyanin, and phycoerythrin. Three others (29,000-30,500) were orange and are probably related to the γ subunit of phycoerythrin. Another colored polypeptide had a molecular weight of 95,000 and the characteristics of long wavelength-emitting allophycocyanin. Sequential dissociation of phycobilisomes, and analysis of the polypeptides in each fraction, revealed the association of a 32,500 molecular weight colorless polypeptide with a phycoerythrin fraction. The remaining eight colorless polypeptides were in the core fraction of the phycobilisome, which also was enriched in allophycocyanin. In addition, the core fraction was enriched in a colored 95,000 dalton polypeptide. Inasmuch as a polypeptide with the same molecular weight is found in thylakoid membranes (free of phycobilisomes), it is suggested that this polypeptide is involved in anchoring phycobilisomes to thylakoid membranes.     

Allophycocyanin I and the 95 Kilodalton Polypeptide : The Bridge between Phycobilisomes and Membranes

Allophycocyanin was isolated from dissociated phycobilisomes from Nostoc sp. and was separated into allophycocyanin I, II, III, and B as described elsewhere. If the separation of the proteins following phycobilisome isolation is done in the presence of the protease inhibitor, phenylmethylsulfonylfluoride, associated with allophycocyanin I are two colored polypeptides of 95 kilodalton (kD) and 80 kD, belonging to the class of Group I polypeptides as defined by Tandeau de Marsac and Cohen-Bazire (Proc Natl Acad Sci USA 1977 74: 1635-1639). Allophycocyanin I has a fluorescence maximum of 680 nanometers as do intact phycobilisomes and has thus been suggested to be the final emitter of excitation energy in phycobilisomes. Thylakoid membranes washed in low ionic strength buffer containing phenylmethylsulfonylfluoride lose all biliproteins, but retain the 95 kD and 80 kD polypeptides. As suggested by Tandeau de Marsac and Cohen-Bazire, these are likely to be the polypeptides involved in binding the phycobilisome to the membrane. As these polypeptides are isolated with allophycocyanin I, structural evidence is provided for placing allophycocyanin I as the bridge between the phycobilisome and the membrane. These Group I polypeptides and the 29 kD polypeptide (involved in rod attachment to the APC core) are particularly susceptible to proteolytic breakdown. It is thought that in vivo the active protease may be selectively attacking these polypeptides to detach the phycobilisome from the membrane and release the phycoerythrin and phycocyanin containing rods from the allophycocyanin core for greater susceptibility of the biliproteins to protease attack.     

Differentiation between Phycobiliprotein and Colorless Linker Polypeptides by Fluorescence in the Presence of ZnSO(4)

Microcystis aeruginosa, a unicellular cyanobacterium, contains small phycobilisomes consisting of C-phycocyanin, allophycocyanin, and linker polypeptides. SDS-polyacrylamide gels of the phycobilisomes were examined for fluorescent bands before and after spraying with a solution of ZnSO₄, followed by Coomassie brilliant blue staining for protein. This procedure provides a rapid and sensitive method for detecting small amounts of phycobilin-containing polypeptides and distinguishing them from other tetrapyrrole-containing polypeptides and from `colorless' ones. Three polypeptide bands, in addition to the α and β phycobiliprotein subunits, have been detected under these conditions. An 85 kilodalton polypeptide was identified as a phycobiliprotein due to its enhanced fluorescence in the presence of ZnSO₄. The other polypeptides do not contain chromophores and are colorless. They are approximately 34.5 and 30 kilodaltons in size.     

Integration of Apo-α-Phycocyanin into Phycobilisomes and Its Association with FNRL in the Absence of the Phycocyanin α-Subunit Lyase (CpcF) in Synechocystis sp. PCC 6803

Phycocyanin is an important component of the phycobilisome, which is the principal light-harvesting complex in cyanobacteria. The covalent attachment of the phycocyanobilin chromophore to phycocyanin is catalyzed by the enzyme phycocyanin lyase. The photosynthetic properties and phycobilisome assembly state were characterized in wild type and two mutants which lack holo-α-phycocyanin. Insertional inactivation of the phycocyanin α-subunit lyase (ΔcpcF mutant) prevents the ligation of phycocyanobilin to α-phycocyanin (CpcA), while disruption of the cpcB/A/C2/C1 operon in the CK mutant prevents synthesis of both apo-α-phycocyanin (apo-CpcA) and apo-β-phycocyanin (apo-CpcB). Both mutants exhibited similar light saturation curves under white actinic light illumination conditions, indicating the phycobilisomes in the ΔcpcF mutant are not fully functional in excitation energy transfer. Under red actinic light illumination, wild type and both phycocyanin mutant strains exhibited similar light saturation characteristics. This indicates that all three strains contain functional allophycocyanin cores associated with their phycobilisomes. Analysis of the phycobilisome content of these strains indicated that, as expected, wild type exhibited normal phycobilisome assembly and the CK mutant assembled only the allophycocyanin core. However, the ΔcpcF mutant assembled phycobilisomes which, while much larger than the allophycocyanin core observed in the CK mutant, were significantly smaller than phycobilisomes observed in wild type. Interestingly, the phycobilisomes from the ΔcpcF mutant contained holo-CpcB and apo-CpcA. Additionally, we found that the large form of FNR (FNR_L) accumulated to normal levels in wild type and the ΔcpcF mutant. In the CK mutant, however, significantly less FNR_L accumulated. FNR_L has been reported to associate with the phycocyanin rods in phycobilisomes via its N-terminal domain, which shares sequence homology with a phycocyanin linker polypeptide. We suggest that the assembly of apo-CpcA in the phycobilisomes of ΔcpcF can stabilize FNR_L and modulate its function. These phycobilisomes, however, inefficiently transfer excitation energy to Photosystem II.     

Isolation and Characterization of the Central Component of the Phycobilisome Core of Nostoc sp

Freshly isolated allophycocyanin is recovered from linear sucrose gradients made in 0.75 molar potassium phosphate buffer (pH 7.0) in three sizes: 19s, 10.3s, and 5.5s. The largest aggregate is a complex of a 680 nm fluorescing allophycocyanin I in the form (αβ)₃γ, where γ is the 95 kilodalton (kD) polypeptide, and two 660 nanometer fluorescing allophycocyanin II (αβ)₃ molecules; the complex, stabilized in high phosphate concentrations, fluoresces maximally at 675 nanometers. The 10.3s fraction is a hexamer of allophycocyanin of the 660 nanometer fluorescing type, perhaps attached through two polypeptides of 46 kD and 44 kD. The 5.5s component of the allophycocyanin pool is the usual trimeric form of allophycocyanin (αβ)₃. A similar 19s fraction is the major component of allophycocyanin I isolated under optimum conditions in the presence of the protease inhibitor, phenylmethylsulfonylfluoride. This 19s fraction is apparently a central component of the core of the phycobilisome with its 95 kD polypeptide the attachment point of the phycobilisome and membrane. The 95 kD polypeptide has both long wavelength absorption and fluorescence bands which seem to account for the long wavelength fluorescence properties of allophycocyanin I.     

Effect of Light Quality on Phycobilisome Components of the Cyanobacterium Spirulina platensis

Phycobilisomes from the nonchromatic adapting cyanobacterium Spirulina platensis are composed of a central core containing allophycocyanin and rods with phycocyanin and linker polypeptides in a regular array. Room temperature absorption spectra of phycobilisomes from this organism indicated the presence of phycocyanin and allophycocyanin. However, low temperature absorption spectra showed the association of a phycobiliviolin type of chromophore within phycobilisomes. This chromophore had an absorption maximum at 590 nanometers when phycobilisomes were suspended in 0.75 molar K-phosphate buffer (pH 7.0). Purified phycocyanin from this cyanobacterium was found to consist of three subparticles and the phycobiliviolin type of chromophore was associated with the lowest density subparticle. Circular dichroism spectra of phycocyanin subparticles also indicated the association of this chromophore with the lowest density subparticle. Absorption spectral analysis of α and β subunits of phycocyanin showed that phycobiliviolin type of chromophore was attached to the α subunit, but not the β subunit. Effect of light quality showed that green light enhanced the synthesis of this chromophore as analyzed from the room temperature absorption spectra of phycocyanin subparticles and subunits, while red or white light did not have any effect. Low temperature absorption spectra of phycobilisomes isolated from green, red, and white light conditions also indicated the enhancement of phycobiliviolin type of chromophore under green light.     

Role of the Colorless Polypeptides in Phycobilisome Assembly in Nostoc sp

We have identified the function of the `extra' polypeptides involved in phycobilisome assembly in Nostoc sp. These phycobilisomes, as those of other cyanobacteria, are composed of an allophycocyanin core, phycoerythrin- and phycocyanin-containing rods, and five additional polypeptides of 95, 34.5, 34, 32, and 29 kilodaltons. The 95 kilodalton polypeptide anchors the phycobilisome to the thylakoid membrane (Rusckowski, Zilinskas 1982 Plant Physiol 70: 1055-1059); the 29 kilodalton polypeptide attaches the phycoerythrin- and phycocyanin-containing rods to the allophycocyanin core (Glick, Zilinskas 1982 Plant Physiol 69: 991-997). Two populations of rods can exist simultaneously or separately in phycobilisomes, depending upon illumination conditions. In white light, only one type of rod with phycoerythrin and phycocyanin in a 2:1 molar ratio is synthesized. Associated with this rod are the 29, 32, and 34 kilodalton colorless polypeptides; the 32 kilodalton polypeptide links the two phycoerythrin hexamers, and the 34 kilodalton polypeptide attaches a phycoerythrin hexamer to a phycocyanin hexamer. The second rod, containing predominantly phycocyanin, and the 34.5 and 29 kilodalton polypeptides, is synthesized by redlight-adapted cells; the 34.5 kilodalton polypeptide links two phycocyanin hexamers. These assignments are based on isolation of rods, dissociation of these rods into their component biliproteins, and analysis of colorless polypeptide composition, followed by investigation of complexes formed or not formed upon their recombination.     

Cyanobacterial phycobilisomes

Cyanobacterial phycobilisomes harvest light and cause energy migration usually toward photosystem II reaction centers. Energy transfer from phycobilisomes directly to photosystem I may occur under certain light conditions. The phycobilisomes are highly organized complexes of various biliproteins and linker polypeptides. Phycobilisomes are composed of rods and a core. The biliproteins have their bilins (chromophores) arranged to produce rapid and directional energy migration through the phycobilisomes and to chlorophyll a in the thylakoid membrane. The modulation of the energy levels of the four chemically different bilins by a variety of influences produces more efficient light harvesting and energy migration. Acclimation of cyanobacterial phycobilisomes to growth light by complementary chromatic adaptation is a complex process that changes the ratio of phycocyanin to phycoerythrin in rods of certain phycobilisomes to improve light harvesting in changing habitats. The linkers govern the assembly of the biliproteins into phycobilisomes, and, even if colorless, in certain cases they have been shown to improve the energy migration process. The Lcm polypeptide has several functions, including the linker function of determining the organization of the phycobilisome cores. Details of how linkers perform their tasks are still topics of interest. The transfer of excitation energy from bilin to bilin is considered, particularly for monomers and trimers of C-phycocyanin, phycoerythrocyanin, and allophycocyanin. Phycobilisomes are one of the ways cyanobacteria thrive in varying and sometimes extreme habitats. Various biliprotein properties perhaps not related to photosynthesis are considered: the photoreversibility of phycoviolobilin, biophysical studies, and biliproteins in evolution. Copyright 1998 Academic Press.     

Further evidence for a phycobilisome model from selective dissociation,fluorescence emission,immunoprecipitation, and electron microscopy

Phycobilisomes, isolated in 500 mM Sorensen's phosphate buffer pH 6.8 from the red alga, Porphyridium cruentum, were analyzed by selective dissociation at various phosphate concentrations. The results are consistent with a structural model consisting of an allophycocyanin core, surrounded by a hemispherical layer of R-phycocyanin, with phycoerythrin being on the periphery. Such a structure also allows maximum energy transfer.Intact phycobilisomes transfer excitation energy ultimately to a pigment with a fluorescence emission maximum at 675 nm. This pigment is presumed to be allophycocyanin in an aggregated state. Uncoupling of energy transfer among the pigments, and physical release of the phycobiliproteins from the phycobilisome follow a parallel time-course; phycoerythrin is released first, followed by R-phycocyanin, and then allophycocyanin. In 55 mM phosphate buffer, the times at which 50% of each phycobiliprotein has dissociated are: phycoerythrin 40 min, R-phycocyanin 75 min, and allophycocyanin 140 min.The proposed arrangement of phycobiliproteins within phycobilisomes is also consistent with the results from precipitation reactions with monospecific antisera on intact and dissociated phycobilisomes. Anti-phycoerythrin reacts almost immediately with intact phycobilisomes, but reactivity with anti-R-phycocyanin and anti-allophycocyanin is considerably delayed, suggesting that the antigens are not accessible until a loosening of the phycobilisome structure occurs. Reaction with anti-allophycocyanin is very slow in P. cruentum phycobilisomes, but is much more rapid in phycobilisomes of Nostoc sp. which contains 6–8 times more allophycocyanin. It is proposed that allophycocyanin is partially exposed on the base of isolated intact phycobilisomes of both algae, but that in P. cruentum there are too few accessible sites to permit a rapid formation of a precipitate with anti-allophyocyanin.Phycobilisome dissociation is inversely proportional to phosphate concentration (500 mM to 2 mM), and is essentially unaffected by protein concentration in the range used (30–200 μg/ml). Phycobiliprotein release occurs in the same order (phycoerythrin > R-phycocyanin > allophycocyanin) in the pH range 5.4–8.0.     

Molecular architecture of a light-harvesting antenna. Isolation and characterization of phycobilisome subassembly particles

Synechococcus 6301 mutant, strain AN112, produces phycobilisomes containing two major biliproteins, phycocyanin and allophycocyanin, and two major linker polypeptides of 27 and 75 kilodaltons (27K and 75K). These phycobilisomes have a molecular weight of approximately 2.5 X 10(6) and are the smallest of these particles known to date. Sucrose density gradient centrifugation of AN112 phycobilisomes partially dissociated in 50 mM N-[tris(hydroxymethyl)methyl]glycine, 5 mM CaCl2, 10% (w/v) glycerol, pH 7.8, separated three distinct fractions: (1) free trimeric biliproteins, (2) hexameric complexes of phycocyanin with 27K (11 S particles), and (3) phycobilisome subassemblies equivalent in mass to approximately 25% of the intact phycobilisome (18 S particles). The 18 S particles contained equimolar amounts of phycocyanin and allophycocyanin, which represented approximately 30 and 50%, respectively, of the content of these biliproteins in the AN112 phycobilisome. The 18 S particles also contained 75% and 100%, respectively, of 27K and 75K polypeptides; i.e. 75K was present in a 2-fold higher amount than in the intact phycobilisome. The absorption spectrum (lambda max 648 nm) of the 18 S particles was similar to that of allophycocyanin. Upon excitation at 580 nm, these particles exhibited a fluorescence emission spectrum consisting of 680 and 660 nm components, identical with that of intact phycobilisomes. The circular dichroism spectra of AN112 phycobilisomes and of the 18 S particles, in the region between 650 and 700 nm, were also very similar. Allophycocyanin B, which fluoresces at 680 nm, was found in fraction 1, and was totally absent from the 18 S particle. Thus, the long wavelength emission of the 18 S particle must have arisen from another terminal energy acceptor. The most probable candidate is the 75K polypeptide, which has been shown to carry a bilin chromophore and emit near 680 nm (Lundell, D. J., Yamanaka, G., and Glazer, A. N. (1980) J. Cell Biol. 91, 315-319). The 27K polypeptide, present in both fractions 2 and 3, was a component of different complexes in the two fractions. Fraction 2 displayed the physical and spectroscopic properties characteristic of the phycocyanin-linker complex, (alpha beta)6.27K. However, in the 18 S particle, 27K functioned in the assembly and attachment of phycocyanin trimers to a core domain. Based on the analysis of the components in fractions 1-3, a model is proposed which describes the structure of the AN112 phycobilisome, with emphasis on the roles of the linker polypeptides in the assembly of the core.     

Growth and Chromatic Adaptation of Nostoc sp. Strain MAC and the Pigment Mutant R-MAC

A spontaneous, stable, pigmentation mutant of Nostoc sp. strain MAC was isolated. Under various growth conditions, this mutant, R-MAC, had similar phycoerythrin contents (relative to allophycocyanin) but significantly lower phycocyanin contents (relative to allophycocyanin) than the parent strain. In saturating white light, the mutant grew more slowly than the parent strain. In nonsaturating red light, MAC grew with a shorter generation time than the mutant; however, R-MAC grew more quickly in nonsaturating green light.

When the parental and mutant strains were grown in green light, the phycoerythrin contents, relative to allophycocyanin, were significantly higher than the phycoerythrin contents of cells grown in red light. For both strains, the relative phycocyanin contents were only slightly higher for cells grown in red light than for cells grown in green light. These changes characterize both MAC and R-MAC as belonging to chromatic adaptation group II: phycoerythrin synthesis alone photocontrolled.

A comparative analysis of the phycobilisomes, isolated from cultures of MAC and R-MAC grown in both red and green light, was performed by polyacrylamide gel electrophoresis in the presence of 8.0 molar urea or sodium dodecyl sulfate. Consistent with the assignment of MAC and R-MAC to chromatic adaptation group II, no evidence for the synthesis of red light-inducible phycocyanin subunits was found in either strain. Phycobilisomes isolated from MAC and R-MAC contained linker polypeptides with relative molecular masses of 95, 34.5, 34, 32, and 29 kilodaltons. When grown in red light, phycobilisomes of the mutant R-MAC appeared to contain a slightly higher amount of the 32-kilodalton linker polypeptide than did the phycobilisomes isolated from the parental strain under the same conditions. The 34.5-kilodalton linker polypeptide was totally absent from phycobilisomes isolated from cells of either MAC or R-MAC grown in green light.

     

Isolation and Function of Allophycocyanin B of Porphyridium cruentum

Allophycocyanin B was purified to homogeneity from the eukaryotic red alga Porphyridium cruentum. This biliprotein is distinct from the allophycocyanin of P. cruentum with respect to subunit molecular weights, and spectroscopic and immunological properties. The purified allophycocyanin B has a long wavelength absorption maximum at 669 nm at room temperature and at 675 nm at −196 C while the fluorescence emission maximum is at 673 nm at room temperature and 679 nm at −196 C. The emission spectrum of allophycocyanin shifted only 1 nm, from 659 to 660 nm, on cooling to −196 C, and was the same with allophycocyanin crystals as it was with pure solutions of the pigment. Phycobilisomes from P. cruentum have a major fluorescence emission band at 680 nm at −196 C which emanates from the small amount of allophycocyanin B present in the phycobilisomes. Light energy absorbed by the bulk of the biliprotein pigments is transferred to allophycocyanin B with high efficiency.     

Role of the colorless polypeptides in phycobilisome reconstitution from separated phycobiliproteins

A phycoerythrin (PE) and phycocyanin (PC) mixture was separated from allophycocyanin on calcium phosphate chromatography from completely dissociated phycobilisomes of the blue-green alga, Nostoc sp. After dialysis of the PE-PC mixture in 0.75 m potassium phosphate, pH 7, which allows reassociation of the dissociated pigment-proteins, complexes of PE and PC in a 2:1 m ratio (PE/PC complex) as well as complexes predominantly of PC (PC/PE complex) were then separated by sedimentation on linear sucrose gradients. These complexes resemble the rods of intact phycobilisomes and transfer energy efficiently from PE to PC. They contain the Group II colorless polypeptides described by Tandeau de Marsac and Cohen-Bazire (1977 Proc Natl Acad Sci USA 74: 1635 61639). Phycobilisomes can be reconstituted by combining the allophycocyanin pool with (a) the PE-PC mixture, (b) the PE/PC complex, or (c) the PC/PE complex. Successful reconstitution is measured by absorption, fluorescence, circular dichroism, and electron microscopy. The major requirement for reconstitution is the 29-kilodalton colorless polypeptide. In its absence, no phycobilisomes are formed. It is the only colorless polypeptide common to both the PE/PC complex and the PC/PE complex, and appears to be the polypeptide responsible for rod attachment to the allophycocyanin. In addition, high phosphate concentrations and 20 degrees C temperatures are needed for reconstitution.     

Expression of Two Different Glutamine Synthetase Polypeptides during Root Development in Phaseolus vulgaris L

Immunoprecipitation and two-dimensional gel electrophoresis analysis of the glutamine synthetase (GS) polypeptides (α and β) during Phaseolus vulgaris root development shows that the α polypeptide is the main component of the enzyme in the embryo and in up to 5 day old roots. From 5 days on, the β polypeptide becomes the root predominant GS monomer. The α/β ratio of the in vitro translated GS polypeptides from the total polysomal RNA isolated at different root ages correlates with the α/β ratio observed in the root extracts. These results suggest that the two root GS polypeptides are encoded by different mRNA species in Phaseolus vulgaris.     

Native and in vitro-associated phycobilisomes of Nostoc sp. Composition,energy transfer,and effect of antibodies

The relationship of the structure and function of the light-harvesting antennae in the blue-green alga Nostoc sp. was further elucidated by reconstitution experiments. Separated phycoerythrin-phycocyanin complexes and allophycocyanin fractions were reassociated as described earlier (Canaani, O., Lipschultz, C.A. and Gantt, E. (1980) FEBS Lett. 115, 225–229) into functional phycobilisomes with a 70% yield. Native and reassociated physobilisomes had molar ratios of about 1.4:1.1:1.0 of phycoerythrin:phycocyanin:allophycocyanim. Energy transfer was demonstrated by their fluorescence emission maximum at approx. 675 nm (20°C), and their excitation spectra (emission wavelength 680 nm) which reflected the contribution of the three constitutive phycobiliproteins. Scans of Coomassie blue-stained SDS-polyacrylamide gels showed that the polypeptide composition of native and reassociated phycobilisomes was virtually indistinguishable. Reassociation of phycobilisomes was dependent on the interaction of allophycocyanin and phycocyanin, because it could be blocked with antisera to phycocyanin and allophycocyanin, but not to phycoerythrin. In addition, reassociation did not occur when a 31 000 Da polypeptide, which is part of the phycoerythrin-phycocyanin complex, was reduced in size (by 4000 Da). These results suggest that at least two domains are required for functional reassociation of phycobilisomes involving phycocyanin and allophycocyanin.     

Picosecond study of energy-transfer kinetics in phycobilisomes of Synechococcus 6301 and the mutant AN 112

Excitation-energy-transfer kinetics in isolated phycobilisomes from the cyanobacterium Synechococcus 6301 (Anacystis nidulans) and the mutant AN 112 (rods containing one hexameric C-phycocyanin unit only) was investigated by picosecond absorption and fluorescence techniques. The different chromophores in the phycobilisomes were selectively excited. A lifetime component of about 10 ps was found for both C-phycocyanin and allophycocyanin in both types of phycobilisomes. We assign these signals to a transfer of excitation energy from sensitizing (‘s’) to fluorescing (‘f’) chromophores within C-phycocyanin and allophycocyanin units. A 10 ps component was also observed in the anisotropy relaxation measurements. The anisotropy decay is attributed mainly to differently oriented transition dipole moments of ‘s’- and ‘f’-chromophores and partially to ‘f’ → ‘f’ transfer. An absorption recovery signal of τ ≈ 90 ps at λ ≤ 630 nm in phycobilisomes of Synechococcus 6301 is reduced to 40–50 ps in AN 112 phycobilisomes. This is rationalized in terms of a decreased rod → core transfer time in the shorter rods of AN 112. The 40–50 ps lifetime of fluorescence and absorption recovery in AN 112 phycobilisomes is assigned mainly to a rate-limiting transfer step between C-phycocyanin and the allophycocyanin core. A decay component of allophycocyanin τ ≈ 50 ps was observed both in absorption recovery measurements and in fluorescence decay. It is assigned to energy transfer to the terminal chromophores. The final emitter(s) of the phycobilisomes from AN 112 have fluorescence lifetimes of 1.9 and 1.3 ns. We find a good correlation in the fluorescence kinetics between the decay times of phycocyanin and allophycocyanin and the fluorescence risetimes of the terminal emitters.     

Light Intensity Adaptation and Phycobilisome Composition of Microcystis aeruginosa

Phycobilisomes isolated from Microcystis aeruginosa grown to midlog at high light (270 microeinsteins per square meter per second) or at low light intensities (40 microeinsteins per square meter per second) were found to be identical. Electron micrographs established that they have a triangular central core apparently consisting of three allophycocyanin trimers surrounded by six rods, each composed of two hexameric phycocyanin molecules. The apparent mass of a phycobilisome obtained by gel filtration is 2.96 × 10⁶ daltons. The molar ratio of the phycobiliproteins per phycobilisome is 12 phycocyanin hexamers:9 allophycocyanin trimers. The electron microscopic observations combined with the phycobilisome apparent mass and the phycobiliprotein stoichiometry data indicate that M. aeruginosa phycobilisomes are composed of a triangular central core of three stacks of three allophycocyanin trimers and six rods each containing two phycocyanin hexamers. Adaptation of M. aeruginosa to high light intensity results in a decrease in the number of phycobilisomes per cell with no alteration in phycobilisome composition or structure.     

Comparative Evaluation of the Gut Microbiota Associated with the Below- and Above-Ground Life Stages (Larvae and Beetles) of the Forest Cockchafer,Melolontha hippocastani

A comparison of the diversity of bacterial communities in the larval midgut and adult gut of the European forest cockchafer (Melolontha hippocastani) was carried out using approaches that were both dependent on and independent of cultivation. Clone libraries of the 16S rRNA gene revealed 150 operational taxonomic units (OTUs) that belong to 11 taxonomical classes and two other groups that could be classified only to the phylum level. The most abundant classes were β, δ and γ-proteobacteria, Clostridia, Bacilli, Erysipelotrichi and Sphingobacteria. Although the insect’s gut is emptied in the prepupal stage and the beetle undergoes a long diapause period, a subset of eight taxonomic classes from the aforementioned eleven were found to be common in the guts of diapausing adults and the larval midguts (L2, L3). Moreover, several bacterial phylotypes belonging to these common bacterial classes were found to be shared by the larval midgut and the adult gut. Despite this, the adult gut bacterial community represented a subset of that found in the larvae midgut. Consequently, the midgut of the larval instars contains a more diverse bacterial community compared to the adult gut. On the other hand, after the bacteria present in the larvae were cultivated, eight bacterial species were isolated. Moreover, we found evidence of the active role of some of the bacterial species isolated in food digestion, namely, the presence of amylase and xylanolytic properties. Finally, fluorescence in situ hybridization allowed us to confirm the presence of selected species in the insect gut and through this, their ecological niche as well as the metagenomic results. The results presented here elucidated the heterogeneity of aerobic and facultative bacteria in the gut of a holometabolous insect species having two different feeding habits.