PH banding in charophyte algae

Plant Electrophysiology: Methods and Cell Electrophysiology

Volumn , Issue , 2012, Pages 247-271

  Beilby, Mary J ^a   Bisson, Mary A ^b  

^a UNIVERSITY OF NEW SOUTH WALES   (Australia)

^b UNIVERSITY AT BUFFALO   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

EID: 84878620933     PISSN: None     EISSN: None     Source Type: Book    
DOI: 10.1007/978-3-642-29119-7_11     Document Type: Chapter

References (97)

1. Al Khazaaly S., Beilby M.J. (2012) Zinc ion blocks H+/OH- channels in Chara australis. Plant Cell Environ (published on line)
2. Amtmann A, Sanders D. (1999) Mechanism of Na+ uptake by plant cells. Adv Bot Res 29:75-112
3. Arens K (1939) Physiologische multipolaritat der zelle von Nitella der photosynthese. Protoplasma 33:295-300
4. Babourina O, Voltchanskii K, Newman I. (2004) Ion flux interaction with cytoplasmic streaming in branchlets of Chara australis. J Exp Bot 55:2505-2512
5. Beilby MJ, Al Khazaaly S (2009) The role of H+/OH- channels in salt stress response of Chara australis. J Membr Biol 230:21-34
6. Beilby MJ, Mimura T, Shimmen T. (1993) The proton pump, high pH channels, and excitation: voltage clamp studies of intact and perfused cells of Nitellopsis obtusa. Protoplasma 175:144-152
7. Beilby MJ, Walker N.A. (1996) Modelling the current-voltage characteristics of Chara membranes. I. the effect of ATP and zero turgor. J Membr Biol 149:89-101
8. Beilby MJ (1984) Current-voltage characteristics of the proton pump at Chara plasmalemma: I. pH dependence. J Membr Biol 81:113-125
9. Beilby MJ (1986) Potassium channels and different states of Chara plasmalemma. J Membr Biol 89:241-249
10. Beilby MJ (1989) Electrophysiology of giant algal cells. In: Fleischer S, Fleischer B (eds) Methods in enzymology, vol 174. Academic Press, San Diego, pp 403-443
11. Beilby MJ (1990) Current-voltage curves for plant membrane studies: a critical analysis of the method. J Exp Bot 41:165-182
12. Beilby MJ (2007) Action potential in charophytes. In: Jeon KW (ed) International review of cytology, vol 257. Elsevier Inc. San Diego, California, pp 43-82
13. Beilby MJ, Bisson M.A. (1992) Chara plasmalemma at high pH: voltage dependence of the conductance at rest and during excitation. J Membr Biol 125:25-39
14. Beilby MJ, Shepherd V.A. (1989) Cytoplasm-enriched fragments of Chara: structure and electrophysiology. Protoplasma 148:150-163
15. Bisson MA (1984) Calcium effects on electrogenic pump and passive permeability of the plasma membrane of Chara corallina. J Membr Biol 81:59-67
16. Bisson MA (1986a) Inhibitors of proton pumping. Effect on passive proton transport. Plant Physiol 81:55-59
17. Bisson MA (1986b) The effect of darkness on active and passive transport in Chara corallina. J Exp Bot 37:8-21
18. Bisson MA, Siegel A, Chan R., Gelsomino SA, Herdic S.L. (1991) Distribution of charasomes in Chara - banding-pattern and effect of photosynthetic inhibitors. Aust J Plant Physiol 18:81-93
19. Bisson MA, Walker N.A. (1980) The Chara plasmalemma at high pH. Electrical measurements show rapid specific passive uniport of H+ or OH-. J Membr Biol 56:1-7
20. Bisson MA, Walker N.A. (1981) The hyperpolarisation of the Chara membrane at high pH: effects of external potassium, internal pH, and DCCD. J Exp Bot 32:951-971
21. Bisson MA, Walker N.A. (1982) Control of passive permeability in the Chara plasmalemma. J Exp Bot 33:520-532
22. Brechignac F, Lucas W.J. (1987) Photorespiration and Internal CO2 accumulation in Chara corallina as inferred from the influence of DIC and O2 on photosynthesis. Plant Physiol 83:163-169
23. Bulychev AA, Cherkashin AA, Rubin A.B., Vredenberg WJ, Zykov VS, Muller S.C. (2001a) Comparative study on photosynthetic activity of chloroplasts in acid and alkaline zones of Chara corallina. Bioelectrochemistry 53:225-232
24. Bulychev AA, Kamzolkina NA, Luengviriya J, Rubin A.B., Muller S.C. (2004) Effect of a single excitation stimulus on photosynthetic activity and light-dependent pH banding in Chara cells. J Membr Biol 202:11-19
25. Bulychev AA, Kamzolkina NA, Rubin A.B. (2005) Effect of plasmalemma electrical excitation on photosystem II activity and nonphotochemical quenching in chloroplasts of cell domains in Chara corallina. Dokl Biochem Biophys 401:127-130
26. Bulychev AA, Krupenina N.A. (2009) Transient removal of alkaline zones after excitation of Chara cells is associated with inactivation of high conductance in the plasmalemma. Plant Signalling Behav 4:727-734
27. Bulychev AA, Krupenina N.A. (2010) Inactivation of plasmalemma conductance in alkaline zones of Chara corallina after generation of action potential. Biochemistry (Moscow) supplement series A. Membr Cell Biol 4:232-239
28. Bulychev AA, Polezhaev AA, Zykov S.V., Pljusnina TYu, Riznichenko GYu, Rubin AB, Jantos W, Zykov V.S., Muller S.C. (2001b) Light-triggered pH banding profile in Chara cells revealed with a scanning pH microprobe and its relation to self-organisation phenomena. J Theor Biol 212:275-294
29. Bulychev AA, Vredenberg W. (2003) Spatio-temporal patterns of photosystem II activity and plasma membrane proton flows in Chara corallina cells exposed to overall and local illumination. Planta 218:143-151
30. Bulychev AA, Zykov SV, Rubin A.B., Muller S.C. (2003) Transitions from alkaline spots to regular bands during pH pattern formation at the plasmalemma of Chara cells. Eur Biophys J 32:144-153
31. Chau R, Bisson MA, Siegel A, Elkin G., Klim P, Strabinger R.M. (1994) Distribution of charasomes in Chara - reestablishment and loss in darkness and correlation with banding and inorganic carbon uptake. Aust J Plant Physiol 21:113-123
32. Coster HGL, Smith J.R. (1977) Low-frequency impedance of Chara corallina: simultaneous measurements of the separate plasmalemma and tonoplast capacitance and conductance. Aust J Plant Physiol 4:667-674
33. Dodonova SO, Bulychev A.A. (2011) Cyclosis-related asymmetry of chloroplast-plasma membrane interactions at the margins of illuminated area in Chara corallina cells. Protoplasma 248:737-749
34. Dorn A, Weisenseel M.H. (1984) Growth and the current pattern around internodal cells of Nitella flexilis L. J Exp Bot 35:373-383
35. Eremin A, Bulychev AA, Krupenina N.A., Mair T., Hauser MJB, Stannarius R, Muller S.C., Rubin A.B. (2007) Excitation-induced dynamics of external pH pattern in Chara corallina cells and its dependence on external calcium concentration. Photochem Photobiol Sci 6:103-109
36. Feijo J, Sainhas J, Hackett G.R., Kinkel JG, Hepler P.K. (1999) Growing pollen tubes possess a constitutive alkaline band in the clear zone and a growth-dependent acidic tip. J Cell Biol 144:483-496
37. Felle HH (1982) Effects of fusicoccin upon membrane potential, resistance and current-voltage characteristics in root hairs of Sinapis alba. Plant Sci Lett 25:219-225
38. Findlay GP, Hope A.B. (1964) Ionic relations of cells of Chara australis: VII. The separate electrical characteristics of the plasmalemma and tonoplast. Aust J Biol Sci 17:62-77
39. Fisahn J, Lucas W.J. (1995) Spatial organisation of transport domains and subdomains formation in the plasma membrane of Chara corallina. J Membr Biol 147:275-281
40. Franceschi VR, Lucas W.J. (1980) Structure and possible function(s) of charasomes; complex plasmalemma-cell wall elaborations present in some characeaen species. Protoplasma 104:253-271
41. Gutknecht J, Bisson MA, Tosteson D.C. (1977) Diffusion of carbon dioxide across lipid bilayer membranes. J Gen Physiol 69:779-794
42. Hansen U-P, Gradmann D., Sanders D, Slayman C.L. (1981) Interpretation of current-voltage relationship for "active" ion transport systems: I. Steady-state reaction-kinetic analysis of class I mechanisms. J Membr Biol 63:165-190
43. Hope AB, Walker N.A. (1975) The physiology of giant algal cells. Cambridge University Press, London
44. Karol KG, McCourt RM, Cimino M.T., Delwiche C.F. (2001) The closest living relatives of land plants. Science 294:2351-2353
45. Kiegle EA, Bisson M.A. (1996) Plasma membrane Na+ transport in a salt-tolerant charophyte. Plant Physiol 111:1191-1197
46. Kitasato H (1968) The influence of H+ on the membrane potential and ion fluxes of Nitella. J Gen Physiol 52:60-87
47. Krupenina NA, Bulychev AA, Roelfsema M.R., Screiber U. (2008) Action potential in Chara cells intensifies spatial patterns of photosynthetic electron flow and non-photochemical quenching in parallel with inhibition of pH banding. Photochem Photobiol Sci 7:681-688
48. Lucas WJ (1975a) Photosynthetic fixation of 14Carbon by internodal cells of Chara corallina. J Exp Bot 26:331-346
49. Lucas WJ (1975b) The influence of light intensity on the activation and operation of the hydroxyl efflux system of Chara corallina. J Exp Bot 26:347-360
50. Lucas WJ (1979) Alkaline band formation in Chara corallina: due to OH- efflux or H+ influx? Plant Physiol 63:248-254
51. Lucas WJ (1983) Photosynthetic assimilation of exogenous HCO3- by aquatic plants. Annu Rev Plant Physiol 34:71-104
52. Lucas WJ, Brechignac F, Mimura T., Oross J.W. (1989) Charasomes are not essential for photosynthetic utilization of exogenous HCO3- in Chara corallina. Protoplasma 151:106-114
53. Lucas WJ, Dainty J. (1977) Spatial distribution of functional OH- carriers along a characean internodal cell: determined by the effect of cytochalasin B on H14CO3- assimilation. J Membr Biol 32:75-92
54. Lucas WJ, Keifer DW, Pescareta T.C. (1986) Influence of culture medium pH on charasome development and chloride transport in Chara corallina. Protoplasma 130:5-11
55. Lucas WJ, Keifer DW, Sanders D. (1983) Bicarbonate transport in Chara corallina: evidence for cotransport of HCO3- with H+. J Membr Biol 73:263-274
56. Lucas WJ, Nuccitelli R. (1980) HCO3- and OH- transport across the plasmalemma of Chara corallina: spatial resolution obtained using extracellular vibrating probe. Planta 150:120-131
57. Lucas WJ, Shimmen T. (1981) Intracellular perfusion and cell centrifugation studies on plasmalemma transport processes in Chara corallina. J Membr Biol 58:227-237
58. Lucas WJ, Smith F.A. (1973) The formation of alkaline and acid regions at the surface of Chara corallina cells. J Exp Bot 24:1-14
59. McConnaughey TA (1991) Calcification in Chara corallina: CO2 hydroxylation generates protons for bicarbonate assimilation. Limnol Oceanogr 36:619-628
60. McConnaughey TA, Falk R.H. (1991) Calcium-proton exchange during algal calcification. Biol Bull 180:185-195
61. McCourt RM, Delwiche CF, Karol K.G. (2004) Charophyte algae and land plant origins. Trends Ecol EVol 19:661-666
62. Mimura T, Muller R, Kaiser W.M., Shimmen T., Dietz K-J (1993) ATP-dependent carbon transport in perfused Chara cells. Plant Cell Environ 16:653-661
63. Mimura T, Tazawa M. (1986) Light-induced membrane hyperpolarization and adenine nucleotide levels in perfused characean cells. Plant Cell Physiol 27:319-330
64. Newman I (2001) Ion transport in roots: measurement of fluxes using ion-selective microelectrodes to characterise transporter function. Plant Cell Environ 24:1-14
65. Ogata K, Chilcott TC, Coster HGL (1983) Spatial variation of the electrical properties of Chara australis. I. External potentials and membrane conductance. Aust J Plant Physiol 10:339-351
66. Plieth C, Tabrizi H, Hansen U-P (1994) Relationship between banding and photosynthetic activity in Chara corallina as studied by the spatially different induction curves of chlorophyll fluorescence observed by an image analysis system. Physiol Plant 91:205-211
67. Price DP, Badger M.R. (2002) Advances in understanding how aquatic photosynthetic organisms utilize sources of dissolved inorganic carbon for CO2 fixation. Funct Plant Biol 29:117-121
68. Price GD, Badger M.R. (1985) Inhibition by proton buffers of photosynthetic utilization of bicarbonate in Chara corallina. Aust J Plant Physiol 12:257-267
69. Price GD, Badger MR, Bassett M.E., Whitecross M.I. (1985) Involvement of plasmalemmasomes and carbonic anhydrase in photosynthetic utilisation of bicarbonate in Chara corallina. Aust J Plant Physiol 12:242-256
70. Prins HBA, Snel JFH, Helder RJ, Zanstra P.E. (1980) Photosynthetic HCO3- utilization and OH-excretion in aquatic angiosperms. Plant Physiol 66:818-822
71. Raven JA (1991) Terrestrial rhizophytes and H+ currents circulating over at least a millimeter: an obligate relationship? New Phytol 117:177-185
72. Ray SM, Klenell M, Choo K-S, Pedersen M, Snoeijs P. (2003) Carbon acquisition mechanisms in Chara tomentosa. Aquat Bot 76:141-154
73. Reid RJ, Smith F.A. (1992) Measurement of calcium fluxes in plants using 45Ca. Planta 186:558-566
74. Schmolzer P, Hoftberger M, Foissner I. (2011) Plasma membrane domains participate in pH-banding of Chara internodal cells. Plant and cell physiol 52:1274-1288
75. Sehnke PC, DeLille JM, Ferl R.J. (2002) Consummating signal transduction: the role of 14-3-3 proteins in the completion of signal induced transitions in protein activity. Plant Cell 14:S339-S354
76. Shimmen T, Kikuyama M, Tazawa M. (1976) Demonstration of two stable potential states of plasmalemma of Chara without tonoplast. J Membr Biol 30:249-270
77. Shimmen T, Tazawa M. (1977) Control of membrane potential and excitability of Chara cells with ATP and Mg2+. J Membr Biol 37:167-192
78. Shiraiwa Y, Kikuyama M. (1989) Role of carbonic anhydrase and identification of the active species of inorganic carbon utilised for photosynthesis in Chara corallina. Plant Cell Physiol 30:581-587
79. Simons R (1979) Strong electric field effects on transfer between membrane-bound amines and water. Nature 280:824-826
80. Smith FA (1968) Rates of photosynthesis in characeaen cells: II. Photosynthetic 14CO2 fixation and 14C-bicarbonate uptake by characean cells. J Exp Bot 19:207-217
81. Smith FA, Walker N.A. (1980) Photosynthesis by aquatic plants: effect of unstirred layers in relation to assimilation of CO2 and HCO3- and to carbon isotopic discrimination. New Phytol 86:245-259
82. Smith JR (1984) The electrical properties of plant cell membranes. II. Distortion of non-linear current-voltage characteristics induced by the cable properties of Chara. Aust J Plant Physiol 11:211-224
83. Smith JR, Beilby M.J. (1983) Inhibition of electrogenic transport associated with the action potential in Chara. J Membr Biol 71:131-140
84. Smith JR, Walker N.A. (1983) Membrane conductance of Chara measured in the acid and basic zones. J Membr Biol 73:193-202
85. Spanswick RM (1972) Evidence for an electrogenic ion pump in Nitella translucens: I. The effects of pH, K+, Na+, light and temperature on the membrane potential and resistance. Biochim Biophys Acta 288:73-89
86. Spear DG, Barr JK, Barr C.E. (1969) Localization of hydrogen ion and chloride ion fluxes in Nitella. J Gen Physiol 54:397-414
87. Sze H, Li X, Palmgren M.G. (1999) Energization of plant cell membranes by H+ - pumping ATPases: regulation and biosynthesis. Plant Cell 11:677-689
88. Takeshige K, Shimmen T, Tazawa M. (1986) Quantitative analysis of ATP-dependent H+ efflux and pump current driven by an electrogenic pump in Nitellopsis obtusa. Plant Cell Physiology 27:337-348
89. Tazawa M (1964) Studies on Nitella having artificial cell sap. I Replacement of the cell sap with artificial solutions. Plant Cell Physiol 5:33-43
90. Tazawa M, Kikuyama M, Shimmen T. (1976) Electric characteristics and cytoplasmic streaming of characeae cells lacking tonoplast. Cell Struct Funct 1:165-175
91. Toko K, Nosaka M, Fujiyoshi T., Yamafuji K, Ogata K. (1988) Periodic band pattern as a dissipative structure in ion transport system with cylindrical shape. Bull Math Biol 50:255-288
92. Walker NA (1955) Microelectrode experiments on Nitella. Aust J Biol Sci 8:476-489
93. Walker NA, Smith F.A. (1977) Circulating electric currents between acid and alkaline zones associated with HCO3- assimilation in Chara. J Exp Bot 28:1190-1206
94. Walker NA, Smith FA, Cathers I.R. (1980) Bicarbonate assimilation by freshwater charophytes and higher plants: I. membrane transport of bicarbonate ions. J Membr Biol 57:51-58
95. Whittington J, Bisson M.A. (1994) Na+ fluxes in Chara under salt stress. J Exp Bot 45:657-665
96. Williamson RE (1975) Cytoplasmic streaming in Chara: a cell model activated by ATP and inhibited by cytochalasin B. J Cell Sci 17:655-668
97. Yao X, Bisson MA, Brzezicki L.J. (1992) ATP-driven proton pumping in two species of Chara differing in their salt tolerance. Plant Cell Environ 15:199-210