The biology of carbonate precipitation by cyanobacteria
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Addadi, L. &Weiner, S. (1985): Interactions between acidic proteins and crystals: Stereochemical requirements in biomineralization. —Proc. Natl. Acad. Sci. U.S.A.,82/6, 4110–4114, 5 Figs., Washington
Badger, M.R. &Andrews, T.J. (1982): Photosynthesis and inorganic carbon usage by the marine cyanobacterium,Synechococcus sp..—Plant Physiol.,70/2, 517–523, 9 Figs., 1 Tab., Lancaster, Pa.
Badger, M.R., Bassett, M. &Commins, H.N. (1985): A model of HCO 3 − accumulation and photosynthesis in the cyanobacteriumSynechococcus sp.,—Plant Physiol.,77/2, 465–471, 7 Figs., Lancaster, Pa.
Badger, M.R. &Price, G.D. (1989): Carbonic anhydrase activity associated with the cyanobacteriumSynechococcus PCC 7942. —Plant Physiol.,88/1, 51–60, 2 Tabs., 5 Figs., Lancaster, Pa.
Borowitzka, M.A. (1982): Mechanisms in algal calcification.— In:Round, F.E., Chapman, D.J. (eds.): Progress in Phycological Research, vol.1, 137–178, 11 Figs., 2 Tab., Amsterdam (Elsevier Biomedical Press)
— (1986): Physiology and biochemistry of calcification in the Chlorophyceae.— In:Leadbeater, B.S.C., Riding, R. (eds.): Biomineralization in Lower Plants and Animals.—The Systematic Association, Spec. Vol. 30, 400 pp., 107–124, 2 Figs., 1 Tab., Oxford (Clarendon Press)
Borowitzka, M.A. (1989): Carbonate calcification in algae-Initiation and control.—In:Mann, S., Webb, J., Williams, R.J.P. (eds.): Biomineralization: chemical and biochemical perspectives. — 541 pp., 63–94, 10 Figs., 4 Tabs., Weinheim (VCH Verlagsgesellschaft mbH)
Borowitzka, M.A. &Larkum, A.W.D. (1976): Calcification of the green algaeHalimeda; IV. The action of metabolic inhibitors on the photosynthesis and calcification.—J. Exp. Bot.,27, 894–907, 5 Figs., 4 Tabs., Oxford
— & — (1977): Calcification in the green algaeHalimeda; I: An ultrastucture study of thallus development.—J. Phycol.,13/1, 6–16, 24 Figs., New York
Braithawatie, C.J.R., Casanova, J., Frevert, F., Whitton, B.A. (1989): Recent stromatolites in landlocked pools on Aldabra, western Indian Ocean.—Paleogeogr., Paleoclimat., Paleoecol.,69/3–4, 145–165, 4 Pls., 23 Figs., Amsterdam
Calder, J.A., Parker, P.L. (1973): Geochemical implications of induced changes in 13C fractionation by blue-green algae.— Geochim. Cosmochim. Acta,37/1, 133–140, 2 Figs., 3 Tabs., New York
Castenholz, R.W. (1982): Motility and taxes.—Carr, N.G. &Whitton, B.A. (eds.): The Biology of Cyanobacteria.— 688 pp., 414–439, Oxford (Blackwell)
Cox, G., James, J.M., Leggett, K.E.A., Osborne, R., Armstrong, L. (1989): Cyanobacterially deposited speleothems: subaerial stromatolites.—Geomicrobiol. J., 7, 245–252, 7 Figs., New York
Cummings, C.E., McCarthy, H.M. (1982): Stable carbon istope ratios inAstrangia danae: evidence for algal modification of carbon pools used in calcification.—Geochim. Cosmochim. Acta,46/6, 1125–1129, 2 Figs., 2 Tabs., New York
Defarge, C., Trichet, J., Sin, P. (1985): First data on the biogeochemistry of Kopara deposits from Rangiroa Atoll.— Proceed. 5th Int. Coral Reef Congress, Tahiti,3, 365–370, 6 Figs., 2 Tabs., Moorea
Drever, J. (1988): The Geochemistry of Natural Waters.— 2nd Ed., 437 pp., Englewood Cliffs (Prentice Hall)
Epstein, S. &Mayeda, T. (1953): Variation of18O content of waters from natural sources.—Geochim. Cosmochim. Acta,4/5, 213–224, 3 Figs., 1 Tab., New York
Espie, G.S., Miller, A.G. &Canvin, D.T. (1989): Selective and reversible inhibition of active CO2 transport by hydrogen sulfide in a cyanobacterium.—Plant. Physiol.,91/1, 387–294, 7 Figs., Lancaster, Pa.
Estep, M.F. (1984): Carbon and hydrogen isotopic compositions of algae and bacteria from hydrothermal environments, Yellowstone National Park.— Geochim. Cosmochim. Acta,48/3, 591–599, 6 Figs., 10 Tabs., New York
Fritz, P., Poplawski, S. (1974): 18O and 13C in the sheaths of freshwater molluscs and their environments.—Earth Planet. Sci. Lett.,24, 91–98, 6 Figs., 1 Tab., Amsterdam
Gieskes, J. (1986): Water chemistry procedures aboard Joides Resolution-some coments.-Ocean Drilling Program, Technical Note No.5, 46 pp., College Station
Giraud, G. &Cabioch, J. (1979): Ultrastructure and the elaboration of calcified cell-walls in the coralline algae (Rhodophyta, Cryptonemiales).—Biol. Cellulaire,36, 81–86, Paris
Gleason, P.J. (1972): The origin, sedimentation and stratigraphy of a calcitic mud located in the southern fresh-water Everglades. —PhD-Thesis, Pennsylvania State Univ., 355 pp., University Park
Gleason, P.J. & Spackman, W.Jr. (1974): Calcareous periphyton and water chemistry in the Everglades.—In:Gleason, P.J. (ed.): Environments in South Florida, Present and Past.—146–181, 34 Figs., 9 Tab., Miami
Golubic, S. (1972): The relationship between blue-green algae and carbonate deposits.—In:Carr, N.G. &Whitton, B.A. (eds.): The Biology of Blue-Green Algae.—676 pp., 434–472, 19 Figs., Oxford (Blackwell)
— (1983): Stromatolites, fossil and recent: a case history.—In:Westbroek, P., de Jong, E.W. (eds.). Biomineralization and biological metal accumulation.—313–326, 6 Figs., Dordrecht (Reidel)
Golubic, S. &Campbell, S.E. (1981): Biogenically formed aragonite concretions in marineRivularia.—In:Monty, C. (ed.): Phanerozoic Stromatolites: Case histories.—249 pp., 209–229, 3 Pls., 2 Figs., 1 Tab., Berlin (Springer)
Gran, G. (1952): Determination of the equivalence point in potentiometric titrations, Part I.—Analyst,77, 661–671, London
Greenfield, E.M., Wilson, D.C. &Crenshaw, M.A. (1984): Ionotropic nucleation of calcium carbonate by molluscan matrix. —Am. Zool.,24/4, 925–932, 7 figs., Bloomington, Indiana
Häder, D.-P. (1987): Photomovement.—In:Fay, P., Van Baalen, C. (eds.): The Cyanobacteria.—325–345, 10 Figs., 1 Tab., Amsterdam (Elsevier)
Hardie, L.A. &Ginsburg, R.N. (1977): Layering: The origin and environmental significance of lamination and thin bedding.— In:Hardie, A. (ed.): Sedimentation on the Modern Carbonate Tidal Flats of NW Andros-Island, Bahamas.—Johns Hopkins Univ. Studies in Geol.,22, 203 pp., 50–123, 94 Figs., 16 Tabs., Baltimore
Helder, R.J. (1988): A quantitative approach to the inorganic carbon in aqueous media used in the biological research; dilute solutions isolated from the atrnosphere.—Plant Cell Environment,11, 211–230, 4 Figs., 5 Tabs., Oxford
Horodyski, R.J. &Vonder Haar, S.P. (1975): Recent calcareous stromatolites from Laguna Mormona (Baja California) Mexico. —J. Sed. Petrol.,45/4, 894–906, 7 Figs., Tulsa
Jones, B. &Kahle, C.F. (1986): Dendritic calcite crystals formed by calcification of algal filaments in a vadose environment.—J. Sed. Petrol.,56/2, 217–222, 7 Figs., Tulsa
Kaplan, A. (1981): Photoinhibition inSpirulina platensis: Response of photosynthesis and HCO3 − uptake capability to CO2-depleted conditions.—J. Exp. Bot.,32/2, 669–677, 4, Figs., 1 Tab., Oxford
— (1981): Photoinhibition inSpirulina platensis: Response of photosynthesis and HCO3-uptake capability to CO2-depleted conditions.—J. Exp. Bot.,32/2, 669–677, 4 Figs., 1 Tab., Oxford
Kaplan, A. (1985): Adaptation to CO2 levels: Induction and the mechanism for inorganic carbon uptake.—In:Lucas, W.J. & Berry, J.A. (eds.) Inorganic Carbon Uptake by Aquatic Photosynthetic Organisms.—Am. Soc. Plant Physiol., 325–338, 9 Figs., Rockville, MD.
Kaplan, A., Marcus, Y., Zenvirth, D., Omata, T., Reinhold, L. &Ogawa, T. (1987): The mechanism of inorganic carbon uptake by cyanobacteria: energetization and activation by light.—In:Biggins, J. (ed.): Progress in Photosynthesis Research, vol. IV, 6.301–6.307, 8 Figs., Dordrecht (M. Nijhoff Publ.)
Kazmierczak, J., Itiekot, V. &Degens, E.T. (1985): Biocalcification through time: environmental challenge and cellular response.— Paläontolog. Zeitschr.,59/1–2, 15–33, 6 Figs., Stuttgart
Keith, M.L. &Weber, J.N. (1965): Systematic relationships between carbon and oxygen isotopes in carbonates deposited by modern corals and algae.—Science,150, 498–501, 2 Figs., 1 Tab., Washington
Kempe, S. &Kazmierczak, J. (1990): Calcium carbonate supersaturation and the formation of in situ calcified stromatolites.— In:Ittekkot, V, Kempe, S., Michaelis, W., Spitzy, A. (eds.): Facets of modern biogeochemistry, 433 pp., 161 Figs, 255–278, 4 Figs., 4 Tabs., Berlin (Springer)
Krause, G.H. (1988): Photoinhibition of photosynthesis. An evaluation of damaging and protective mechanisms.—Physiol. Plant.,74/3, 566–574, 2 Figs., Copenhagen
Krumbein, W.E. &Giele, C. (1979): Calcification in a coccoid cyanobacterium associated with the formation of desert stromatolites. —Sedimentology,26/4, 593–604, 9 Figs., Amsterdam
Krumbein, W.E. &Potts, M. (1979): Girvanella-like stuctures formed by Plectonema gloeophilum (Cyanophyta) from the Borrego desert in Southern California.—Geomicrobiol. J.,1/3, 211–217, 4 Figs., 1 Tab., New York
Leinfelder, R.R. (1985): Cyanophyta calcification, morphotypes and depositional environments (Alenquer oncolite, Upper Kimmeridgian?. Portugal).—Facies,12, 253–274, 2 Pls., 3 Figs., 2 Tab., Erlangen
Littler, M.M. (1976): Calcification and its role among macroalgae. —Micronesia,12/1, 27–41, 7 Figs., 3 Tabs., Agana
Lucas, W.J. (1979): Alkaline band formation in Chara corallina.— Plant Physiol.,63/2, 248–254, 9 Figs., 1 Tab., Lancaster, Pa.
Lucas, W.J. (1983): Photosynthetic assimilation of exogenous HCO3-by aquatic plants.—Ann. Rev. Plant Physiol.,34, 71–104, 5 Figs., Palo Alto, Pa.
Lyons, B.W., Long, D.T., Hines, M.E., Gaudette, H.E., Armstrong, P.B. (1984): Calcification of cyanobacterial mats in Solar Lake, Sinai.—Geology,12/10, 623–626, 1 Fig., 2 Tabs., Boulder
McConaughey, T. (1989):13C and18O isotopic disequilibrium in biological carbonates: I. patterns.—Geochim. Cosmochim. Acta,53/1, 151–162, 15 Figs., 2 Tabs., New York
Merz, M.U.E. (1990): Karbonatfällung durch Cyanobakterien im Süßwasserbereich der Everglades, Florida.—unpubl. PhD-Thesis, Univ. of Marburg, 71 pp., 19 Figs., 7 Tabs., Marburg
Merz, M.U.E. & Zankl, H. (submitted): The influence of the sheath on carbonate precipitation by cyanobacteria.—submitted to Boll. Soc. Pal. Italiana, Modena
Miller, A.G. &Colman, B. (1980): Evidence for HCO3-transport by the blue, green alga (cyanobacterium)Coccochloris peniocystis. —Plant Physiol.65/2, 397–402, 7 Figs., Lancaster, Pa.
Miller, A.G., Espie, G.S. &Canvin, D.T. (1990): Physiological aspects of CO2 and HCO3-transport by cyanobacteria: areview. —Can. J. Bot.,68/6, 1291–1302, 10 Figs., Ottawa
Millero, F.J. (1979): The thermodynamics of the carbonate systems in seawater.—Geochim. Cosmochim. Acta,43/10, 1651–1661, 9 Figs., 9 Tabs., New York
Monty, C.L.V. (1972): Recent algal stromatolitic deposits, Andros Island, Bahamas, Preliminary report.—Geol. Rdsch.,61, 742–783, 32 Figs., 1 Tab., Stuttgart
Mook, W. G. & Vogel, J.C. (1968): Isotopic equilibrium between shells and their environment.—Science,159, No. 3817, 1 Fig., Washington
Müller-Jungbluth, W.-U. (1968): Sedimentary petrologic investigation of the Upper Triassic ‘Hauptdolomit’ of the Lechtaler Alps, Tirol, Austria.—In:Müller, G. &Friedman, G. (eds.) Recent Developments in Carbonate Sedimentology in Central Europe.—255 pp., 228–239, 14 Figs., Berlin (Springer)
Müller-Jungbluth, W.-U. (1970): Sedimentologische Untersuchung des Hauptdolomit der Östlichen Lechtaler Alpen, Tirol.-Festbd. Geol. Inst. 300-J.-Feier Univ. Innsbruck, 255–308, Innsbruck
Obenlüneschloss, J. &Schneider, J. (1990): Ecology and calcification patterns of Rivularia (Cyanobacteria).—In:Anagnostidis, K., Hickel, B. &Komarek, J. (eds.) Proc. 11th Symp. IAC.— Arch. Hydrobiol., Suppl. Vol., Algological Studies, Berlin
Ogawa, T. &Kaplan, A. (1987): A model for inorganic carbon accumulation in cyanobacteria.—In:Biggins, J. (ed.): Progress in Photosynthesis Research, vol. IV.—6.297–6.300, 3 Figs., 1 Tab., Dordrecht (M. Nijhoff Publ.)
Paasche, E. (1964): A tracer study of the inorganic carbon uptake during coccolith formation and photosynthesis in the coccolithophorid Coccolithus huxleyi.—Physiol. Plant. (suppl.) III, 1–82, Copenhagen
Pentecost, A. (1978): Blue-green algae and freshwater carbonate deposits.—Proc. R. Soc. London, Ser. B,200, 43–61, 1 Pl., 11 Figs., 10 Tab., London
— (1984): Effects of sedimentation and light intensity on a matforming Oscillatoriacea with particular reference toMicrocoleus lyngbyaceus Gomont.—J. Gen. Microbiol.130, 983–990, 4 Figs., London
— (1985): Association of cyanobacteria with tufa deposits: Identity, enumeration, and nature of the sheath material revealed by histochemistry.—Geomicrobiol. J.,4/3, 286–297, 7 Tab., New York
— (1988): Observations on the growth and calcium carbonate deposition in the green alga Gongrosira.—New Phytol.,110/2, 2 Figs., 7 Tab., 249–253, London
Pentecost, A. &Riding, R. (1986): Calcification in cyanobacteria. —In:Leadbeater, B.S.C., Riding, R. (ed.) The Systematic Association, Spec. Vol. 30, Biomineralization in Lower Plants and Animals.—400 pp., 73–90, 6 Figs., Oxford (Clarendon Press)
Prins, H.B.A. &Elzenga, J.T.M. (1989): Bicarbonate utilization: Function and mechanism.—Aquatic Bot.,34/1, 59–83, 3 Figs., 1 Tab., Amsterdam
Price, G.D. &Badger, M.R. (1989a): Ethoxyzolamide inhibition of CO2 uptake in the cyanobacterium Synechococcus PCC 7942 without apparent inhibition of internal carbonic anhydrase activity.—Plant Physiol.,89/1, 37–43, 8 Figs., Lancaster, Pa.
Price, G.D. &Badger, M.R. (1989b): Ethoxyzolamide inhibition of CO2-dependent photosynthesis in the cyanobacterium Synechococcus PCC 7942.—Plant Physiol.,89/1, 44–50, 3 Figs., 8 Tabs., Lancaster, Pa.
Raven, J.A. & Lucas, W.J. (1985): Energy costs of carbon acquisition.—In:Lucas, W.J., & Berry, J.A. (eds.): Inorganic Carbon Uptake by Aquatic Photosynthetic Organisms.—Am. Soc. Plant Physiol., 305–325, Rockville
Raven, J.A., Smith, F.A. &Walter, N.A. (1986): Biomineralization in the Charophyceae sensu lato.—In:Leadbeater, S.C., Riding, R. (eds.) The Systematic Association, Spec. Vol. 30, Biomineralization in Lower Plants and Animals.—400 pp., 125–139, 1 Tab., Oxford (Clarendon Press)
Reinhold, L., Zviman, M. &Kaplan, A. (1987): Inorganic carbon fluxes in cyanobacteria: A quantitative model.—In:Biggins, J. (eds.): Progress in Photosynthesis Research, vol. IV, 6.289–6.296, 6 Figs., Dordrecht (M. Nijhoff Publ.)
Riding, R. (1977a): CalcifiedPlectonema (blue-green algae), a recent example ofGirvanella from Aldabra Atoll.—Palaeontology,20/1, 33–46, 1 Pl., 5, Figs., London
— (1977b): Problems of affinity in Paleozoic calcareous algae.— In:Flügel, E. (ed.): Fossil algae, recent results and developements.— 375 pp., 202–211, 2 Tabs., Berlin (Springer)
— (1982): Cyanophyte calcification and changes in ocean chemistry. —Nature,299, No. 5886, 814–815, 1 Fig., London
Rowland, S.M. &Gangloff, R.A. (1988): Structure and paleoecology of Lower Cambrian reefs.—Palaios,3, Reefs Issue, 111–135, 18 Figs., Tulsa
Rubinson, M. &Clayton, R.N. (1969): Carbon-13 fractionation between aragonite and calcite.—Geochim. Cosmochim. Acta,33/8, 997–1002, 3 Tabs., New York
Sabater, S. (1989): Encrusting algal assemblages in a mediterranean river basin.—Arch. Hydrobiol.,114/4, 555–573, 5 Figs., 6 Tabs., Berlin
Scherer, S., Riege, H. &Böger, P. (1988a): Light-induced proton efflux of the cyanobacteriumAnabaena variabilis.—In:Rogers, L.J., Gallon, J.P. (eds.) Biochemistry of the algae and cyanbacteria. —121–129, Oxford (Clarendon Press)
Scherer, S., Chen, T.W. &Böger, P. (1988b): A new UV-A/B absorbing pigment in the terrestrial cyanobacgerium Nostoc commune.—Plant Physiol.,88/2, 1055–1057, 4 Figs., 1 Tab., Lancaster, Pa.
Scholl, D.W., Craighead, F.C. &Stuiver, M. (1969): Florida submergence curve revised: its relation to coastal sedimentation. —Science,163, No. 3867, 562–564, 3 Figs., Washington
Sharkey, T.D. & Berry, J.A. (1985): Carbon isotope fractionation of algae as influenced by an inducible CO2 concentrating mechanism.—In:Lucas, W.J. & Berry, J.A. (eds.) Inorganic carbon uptake by aquatic photosynthetic organisms.—Am. Soc. Plant Physiol., 389–403, 4 Figs., 1 Tab., Rockville
Sikes, C.S., Roer, R.D. &Wilbur, K.M. (1980): Photosynthesis and coccolith formation: Inorganic carbon sources and net inorganic reaction of deposition.—Limnol. Oceanogr.,25/2, 248–261, 7 Figs., 2 Tabs., Baltimore
Sikes, C.S. &Wilbur, K.M. (1982): Functions of coccolith formation. —Limnol. Oceanogr.,27/1, 18–26, 3 Figs., 3 Tabs., Baltimore
Somers, G.F. &Brown, M. (1978): The affinity of trichomes of blue-green algae for calcium ions.—Estuaries,1, 17–28, 2 Figs., 7 Tabs., Solomons
Swart, P.K. (1983): Carbon and oxygen isotope fractionation in scleractinian corals: a review.—Earth Sci. Rev.,19, 51–80, 10 Figs., Amsterdam
Swart, P.K., Sternberg, L.D.S.L., Steinen, R. &Harrison, S.A. (1989): Controls on the oxygen and hydrogen isotopic composition of the waters of Florida Bay, U.S.A..—Chem. Geol., Isotope Geosci.,10, 113–125, 8 Figs., 2 Tabs., Amsterdam
Tuffery, A.A. (1969): Light and electron microscopy of the sheath of a blue-green alga.—J. Gen. Microbiol.,57/1, 41–50, 5 Plts., London
VanLiere, L. &Walsby, A.E. (1982): Interactions of cyanobacteria with light.—In: Carr, N.G., Whitton, B.A. (eds.): The Biology of Cyanobacteria.—Bot. Monographs, Vol.19, 688 pp. 9–45, 13 Figs., 2 Tabs., Oxford (Blackwell)
Volokita, M., Zenvirth, D., Kaplan, A. &Reinhold, L. (1984): Nature of the inorganic carbon species actively taken up by the cyanobacterium Anabaena variabilis.—Plant Physiol.76/3, 599–602, 5 Figs., Lancaster
Walsby, A.E. (1968): Mucilage secretion and the movement of blue-green algae.—Protoplasma,65/1–2, 223–238, 17 Figs., Wien
Weckesser, J., Hofmann, K., Jürgens, U.J., Whitton, B.A. &Raffelsberger, B. (1988): Isolation and chemical analysis of the sheaths of the filamentous cyanobacteriaCalothrix parietina andC. scopulorum.—J. Gen. Microbiol.,134/3, 629–634, 1 Fig., 2 Tabs., London
Wheeler, A.P. &Sikes, S. (1984): Regulation of carbonate calcification by organic matrix.—Amer. Zool.,24/4, 933–944, 3 Figs., 1 Tab., Bloomington, Indiana