Characterization of transposon Tn5469 from the cyanobacterium Fremyella diplosiphon.

A transposon, designated Tn5469, was isolated from mutant strain FdR1 of the filamentous cyanobacterium Fremyella diplosiphon following its insertion into the rcaC gene. Tn5469 is a 4,904-bp noncomposite transposon with 25-bp near-perfect terminal inverted repeats and has three tandemly arranged, slightly overlapping potential open reading frames (ORFs) encoding proteins of 104.6 kDa (909 residues), 42.5 kDa (375 residues), and 31.9 kDa (272 residues). Insertion of Tn5469 into the rcaC gene in strain FdR1 generated a duplicate 5-bp target sequence. On the basis of amino acid sequence identifies, the largest ORF, designated tnpA, is predicted to encode a composite transposase protein. A 230-residue domain near the amino terminus of the TnpA protein has 15.4% amino acid sequence identity with a corresponding domain for the putative transposase encoded by Lactococcus lactis insertion sequence S1 (ISS1). In addition, the sequence for the carboxyl-terminal 600 residues of the TnpA protein is 20.0% identical to that for the TniA transposase encoded by Tn5090 on Klebsiella aerogenes plasmid R751. The TnpA and TniA proteins contain the D,D(35)E motif characteristic of a recently defined superfamily consisting of bacterial transposases and integrase proteins of eukaryotic retroelements and retrotransposons. The two remaining ORFs on Tn5469 encode proteins of unknown function. Southern blot analysis showed that wild-type F. diplosiphon harbors five genomic copies of Tn5469. In comparison, mutant strain FdR1 harbors an extra genomic copy of Tn5469 which was localized to the inactivated rcaC gene. Among five morphologically distinct cyanobacterial strains examined, none was found to contain genomic sequences homologous to Tn5469.     

Purification and Characterization of RNA Polymerase from Fremyella diplosiphon

We have purified and characterized a DNA-dependent RNA polymerase from the blue-green alga Fremyella diplosiphon. This enzyme, purified by gel filtration, DEAE-cellulose chromatography, and glycerol gradient centrifugation, is comprised of five polypeptide subunits. Their masses are 161,000, 134,000, 91,000, 72,000, and 41,000 daltons. Preparative electrophoresis of the purified enzyme on nondenaturing gels separates the 41,000-dalton polypeptide from the rest of the enzyme. The enzyme is extremely labile in the presence of a variety of salts of strong acids and bases; the purification procedure was devised to avoid exposure to such compounds.     

The complete amino-acid sequence of C-phycoerythrin from the cyanobacterium Fremyella diplosiphon

The amino-acid sequences of both subunits of C-phycoerythrin from the cyanobacterium Fremyella diplosiphon have been determined. The alpha-subunit contains 164 amino acid residues, two phycoerythrobilin (PEB) chromophores and has a molecular mass of 18,368 Da (protein: 17,192 Da + 2 PEB, one PEB accounting for 588 Da). The beta-subunit consists of 184 residues, three PEB chromophores and has a molecular mass of 20,931 Da (protein: 19,168 Da and 3 PEB: 1,764 Da). The five PEB chromophores (open chain tetrapyrroles) are covalently bound to six cysteine residues (one of them doubly bound to two cysteine residues). On the alpha-subunit, the first chromophore was found at position 84, homologous to the chromophore binding site of the other biliproteins APC, PC and PEC. The second chromophore, unique for the alpha-subunit of PE, is inserted together with a pentapeptide at position 143 a. On the beta-subunit, a doubly bound chromophore is attached to cysteine residues 50 and 61, similar to the rhodophytan phycoerythrins (B-PE and R-PE). The second and third chromophores were found at positions 84 and 155, homologous to the other biliproteins. A unique peptide insertion of 14 amino acid residues (without chromophore) was found at position 141 a-o in the beta-subunit and probably is located in the three-dimensional model near the additional chromophores of the C-PE alpha- and beta-subunits. Both additional chromophores of the C-PE alpha- and beta-subunit may be located at the periphery of the C-PE-trimer. The amino-acid sequence homology between C-PE alpha- and beta-subunit is 26% and to the alpha- and beta-subunits of C-PC from Mastigocladus laminosus 49% and 48%, respectively.     

Action spectra for chromatic adaptation in the blue-green alga Fremyella diplosiphon

Action spectra for chromatic adaptation in Fremyella diplosiphon Drouet have been determined using techniques previously described. Action maxima are at 540 nm, with a half-band width of 80 nm, for induction of phycoerythrin synthesis (green action) and at 650 nm, with a half-band width of 90 nm, for reversal of induction of phycoerythrin synthesis (red action). The red-action spectrum includes a secondary action band centered at ca. 360 nm. Red and green action overlap from 570 to 590 nm with an isosbestic point in the vicinity of 580 nm. Shoulders are present at 520 and 630 nm. Red light is more active than green light. The 540:650-nm quantum effectiveness ratio is 1:7. There is relatively little action of either kind in the blue. The 387:540 nm and 460:650-nm quantum effectiveness ratios are zero. These results contrast strongly with previous determinations in the same organism, with major activity indicated in the blue; they are consistent with the control of photomorphogenesis in the Cyanophyta by a master pigment, analogous to phytochrome.Abbreviations APC allophycocyanin - PC physocyanin - PE phycoerythrin     

Chromatic adaptation in a mutant of Fremyella diplosiphon incapable of phycoerythrin synthesis

A mutant of the chromatically adapting cyanobacterium Fremyella diplosiphon, incapable of phycoerythrin synthesis but responding to wavelength modulation of its biliprotein content, was isolated. The biliprotein composition of the mutant and of the wild type were identical after growth in red light, but green light induced, in the mutant, the synthesis of a biliviolin-type chromophore bound to some of the alpha subunits of its phycocyanin. Implications of the results on the regulation and possible pathways of biliprotein biosynthesis are discussed.     

Action Spectra for Phycobiliprotein Synthesis in a Chromatically Adapting Cyanophyte, Fremyella diplosiphon

The action spectra for phycocyanin production by the cyanophyte Fremyella diplosiphon shows maxima at 463 and 641 nm. The action spectrum for phycoerythrin production includes maxima at 387 and 550 nm. The maxima are based on a relative response rate well within the linear ascending portion of the dose response curves; the positions of the maxima are independent of the relative response rates chosen for reference over a 3-fold range although the comparative effectiveness of light at pairs of wavelengths varies with the standard used for comparison. These action spectra differ from those reported previously for Tolypothrix tenuis by Fujita and Hattori (Plant Cell Physiol. 3: 209-220) and by Diakoff and Scheibe (Plant Physiol. 51: 382-385) in that blue light strongly promotes phycobiliprotein synthesis in F. diphosiphon but has been reported to have little or no effect on T. tenuis.     

Convergence and divergence of the photoregulation of pigmentation and cellular morphology in Fremyella diplosiphon

Photosynthetic pigment accumulation and cellular and filament morphology are regulated reversibly by green light (GL) and red light (RL) in the cyanobacterium Fremyella diplosiphon during complementary chromatic adaptation (CCA). The photoreceptor RcaE (regulator of chromatic adaptation), which appears to function as a light-responsive sensor kinase, controls both of these responses. Recent findings indicate that downstream of RcaE, the signaling pathways leading to light-dependent changes in morphology or pigment synthesis and/or accumulation branch, and utilize distinct molecular components. We recently reported that the regulation of the accumulation of the GL-absorbing photosynthetic accessory protein phycoerythrin (PE) and photoregulation of cellular morphology are largely independent, as many mutants with severe PE accumulation defects do not have major disruptions in the regulation of cellular morphology. Furthermore, morphology can be disrupted under GL without impacting GL-dependent PE accumulation. Most recently, however, we determined that the disruption of the cpeR gene, which encodes a protein that is known to function as an activator of PE synthesis under GL, results in disruption of cellular morphology under GL and RL. Thus, apart from RcaE, CpeR is only the second known regulator to impact morphology under both light conditions in F. diplosiphon.     

Photoregulation of cellular morphology during complementary chromatic adaptation requires sensor-kinase-class protein RcaE in Fremyella diplosiphon

We used wild-type UTEX481; SF33, a shortened-filament mutant strain that shows normal complementary chromatic adaptation pigmentation responses; and FdBk14, an RcaE-deficient strain that lacks light-dependent pigmentation responses, to investigate the molecular basis of the photoregulation of cellular morphology in the cyanobacterium Fremyella diplosiphon. Detailed microscopic and biochemical analyses indicate that RcaE is required for the photoregulation of cell and filament morphologies of F. diplosiphon in response to red and green light.     

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.     

A novel role for a TonB-family protein and photoregulation of iron acclimation in Fremyella diplosiphon

Photosynthetic organisms display adaptations to changes in light and nutrient availability. Iron, which is required for the function of photosynthetic photosystems and other important biochemical processes, is an essential mineral that consequently impacts not only overall photosynthetic efficiency, but also the physiology of organisms in general. Our recent study represents the first functional characterization of a cyanobacterial TonB protein. TonB proteins classically are membrane proteins that support the transport of iron and vitamin B12 into cells. TonB proteins thus generally serve a critical role in organismal iron acclimation. We recently identified FdTonB, a TonB-family protein, in the filamentous freshwater cyanobacterium Fremyella diplosiphon. FdTonB contains conserved TonB residues and domains, as well as novel protein domains. Our recent study, however, supports a novel function for this protein in the photoregulation of morphology, rather than iron acclimation, in F. diplosiphon. Our detailed investigations into the responses of SF33 wild-type and ΔtonB mutant strains did not support a role for FdTonB in organismal responses to iron limitation. However, close examination of our recent results did highlight a novel interaction between light and iron acclimation in F. diplosiphon.Key words: cellular morphology, complementary chromatic adaptation, cyanobacteria, iron, phycobiliprotein, photomorphogenesis, photoregulation, siderophores     

Role of electrostatic interaction in the stability of the hexamer of constitutive phycocyanin from Fremyella diplosiphon

The role of electrostatic interactions between the charges carried by the titratable groups in the different aggregates of constitutive phycocyanin from Fremyella diplosiphon has been studied by using a simple theoretical approach based on the modified Tanford-Kirkwood model. The electrostatic potential has also been calculated by means of a numerical solution of the linearized Poisson-Boltzmann equations using the finite-differences technique. The pH dependence of the electrostatic contribution to free energy suggests an electrostatic stabilization of the alpha- and beta-subunits as well as of the (alpha beta)-monomer over a broad pH interval. The charge distributions in the individual alpha- and beta-subunits produce electrostatic complementarity and promote the assembly of the subunits to the (alpha beta)-monomer, as well as of the monomers to the larger trimeric and hexameric aggregates. Trimer-trimer electrostatic interactions exhibit strong pH dependence, predicting an association/dissociation equilibrium with a midpoint at pH 6. The electrostatic trimer-trimer interactions correspond to the steric fit, suggesting that electrostatic interactions may initially help to orient the trimers during aggregation. The distribution of the electrostatic potential of the monomers and of the higher aggregates suggests that it plays an important role also in phycocyanin-linker protein binding.