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Dielectric measurements ofNitellopsis obtusa cells with intracellular electrodes
Bernhardt J., Pauly H.
Radiation and Environmental Biophysics. 1974 11(2). p.91
Potassium channels in the membrane ofHydrodictyon africanum
Findlay G. P., Coleman H. A.
The Journal of Membrane Biology. 1983 75(3). p.241
(2001)
Pharmacology of K+ channels in the plasmalemma of the green algaChara corallina
Tester Mark
The Journal of Membrane Biology. 1988 103(2). p.159
Intestinal Absorption of Metal Ions, Trace Elements and Radionuclides (1971)
Bioelectrical response of the Nitella flexilis cell to illumination: A new possible state of plasmalemma in a plant cell
Volkov G.A.
Biochimica et Biophysica Acta (BBA) - Bioenergetics. 1973 314(1). p.83
Intracellular pH in Chara corallina measured by DMO distribution
Walker N.A., Smith F.A.
Plant Science Letters. 1975 4(2). p.125
Excitation ofCharaceae cell membranes as a result of activation of calcium and chloride channels
Lunevsky V. Z.,
Zherelova O. M.,
Vostrikov I. Y., Berestovsky G. N.
The Journal of Membrane Biology. 1983 72(1-2). p.43
Transport in Plants II (1976)
Mechanosensitive Ion Channels in Chara: Influence of Water Channel Inhibitors, HgCl2 and ZnCl2, on Generation of Receptor Potential
Iwabuchi Kosei,
Kaneko Toshiyuki, Kikuyama Munehiro
Journal of Membrane Biology. 2008 221(1). p.27
Voltage-gated calcium and Ca2+-activated chloride channels and Ca2+ transients: voltage-clamp studies of perfused and intact cells of Chara
Berestovsky Genrikh N., Kataev Anatoly A.
European Biophysics Journal. 2005 34(8). p.973
Cytoplasmic calcium affects the gating of potassium channels in the plasma membrane ofChara corallina: a whole-cell study using calcium-channel effectors
Tester M., MacRobbie E. A. C.
Planta. 1990 180(4). p.569
A kinetic analysis of the electrogenic pump ofChara corallina: III. Pump activity during action potential
Kishimoto Uichiro,
Takeuchi Yuko,
Ohkawa Taka-aki, Kami-ike Nobunori
The Journal of Membrane Biology. 1985 86(1). p.27
Characteristics of the vacuolar membrane ofNitella
Kikuyama Munehiro, Tazawa Masashi
The Journal of Membrane Biology. 1976 30(1). p.225
Reminiscences of work with Alex Hope: the movement of water and ions in giant algal cells, 1963–1967
Barry Peter H.
European Biophysics Journal. 2009 39(1). p.179
Ionic Channels in Cells and Model Systems (1986)
Does active K+ influx to roots occur?
Cheeseman John M., Hanson J.B.
Plant Science Letters. 1980 18(1). p.81
Potassium channels in plasmalemma ofNitella cells at rest
Sokolik A. I., Yurin V. M.
The Journal of Membrane Biology. 1986 89(1). p.9
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Blatt Michael R.
The Journal of Membrane Biology. 1991 124(2). p.95
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Coleman H. A., Findlay G. P.
The Journal of Membrane Biology. 1985 83(1-2). p.109
(2007)
Potential dependence of the admittance ofChara plasmalemma
Beilby M. J., Beilby B. N.
The Journal of Membrane Biology. 1983 74(3). p.229
Evidence for active CO2 uptake by a CO2-ATPase in the acidophilic green alga Eremosphaera viridis
Deveau Jason ST,
Lew Roger R, Colman Brian
Canadian Journal of Botany. 2001 79(11). p.1274
Role of calcium ion in the excitability and electrogenic pump activity of theChara corallina membrane: I. Effects of La3+, verapamil, EGTA, W-7, and TFP on the action potential
Tsutsui Izuo,
Ohkawa Taka-aki,
Nagai Reiko, Kishimoto Uichiro
The Journal of Membrane Biology. 1987 96(1). p.65
Ruhe- und Aktionspotential vonNitella mucronata (A. Braun) Miquel unter Normalbedingungen
Koppenh�fer Eilhard
Pfl�gers Archiv European Journal of Physiology. 1972 336(4). p.289
Rapid effect of light on the K+ channel in the plasmalemma ofNitella
Vanselow Klaus Heinrich, Hansen Ulf-Peter
The Journal of Membrane Biology. 1989 110(2). p.175
Chara braunii genome: a new resource for plant electrophysiology
Beilby M. J.
Biophysical Reviews. 2019 11(2). p.235
Ion Exchange in
Escherichia coli
: Potassium-Binding Proteins
Damadian Raymond
Science. 1969 165(3888). p.79
The Physiology of Characean Cells (2014)
Current-voltage relationships of a sodium-sensitive potassium channel in the tonoplast ofChara corallina
Bertl Adam
The Journal of Membrane Biology. 1989 109(1). p.9
Potassium Ion Activity in the Cytoplasm and the Vacuole of Cells of Chara and Griffithsia
VOROBIEV L. N.
Nature. 1967 216(5122). p.1325
The role of protons in determining membrane electrical characteristics inChara corallina
Richards J. L., Hope A. B.
The Journal of Membrane Biology. 1974 16(1). p.121
Simultaneous Measurement of the Bioelectric Potential of the Cell Wall and the Vacuoles during the Oscillatory Response to the Nitella Cell
RADENOVIĆ Č., VUČINIĆ Ž.
Physiologia Plantarum. 1976 37(3). p.207
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Williams Stephen E., Pickard Barbara G.
Planta. 1972 103(3). p.222
Tonoplast action potential inNitella in relation to vacuolar chloride concentration
Kikuyama Munehiro, Tazawa Masashi
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Transport Across Multi-Membrane Systems (1978)
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Modern Bioelectrochemistry (1986)
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Shimmen Teruo
Journal of Plant Research. 1994 107(4). p.371
Demonstration and characterization of Ca2+ channel in tonoplast-free cells ofNitellopsis obtusa
Shiina T., Tazawa M.
The Journal of Membrane Biology. 1987 96(3). p.263
Biomembranes Part U: Cellular and Subcellular Transport: Eukaryotic (Nonepithelial) Cells (1989)
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Sanders Dale
The Journal of Membrane Biology. 1980 53(2). p.129
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Al Khazaaly Sabah,
Alan Walker N.,
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European Biophysics Journal. 2009 39(1). p.167
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Wayne Randy
The Botanical Review. 1994 60(3). p.265
Ion-driven communication and acclimation strategies in microalgae
Amaral Raquel,
Duci Damiano,
Cotta Francisco C.,
Bacellar Felipe L.,
Oliveira Soraia,
Verret Frédéric,
Asadi Kamal,
Vandamme Lode K.J.,
Reis Nuno M.,
Bryant Lee D.,
Tosh David,
Mouget Jean-Luc,
Perkins Rupert, Rocha Paulo R.F.
Chemical Engineering Journal. 2023 473 p.144985
The Cytoskeleton (2019)
Participation of Ca2+ in cessation of cytoplasmic streaming induced by membrane excitation inCharaceae internodal cells
Hayama T.,
Shimmen T., Tazawa M.
Protoplasma. 1979 99(4). p.305
Current-voltage characteristics of the proton pump atChara plasmalemma: I. pH dependence
Beilby M. J.
The Journal of Membrane Biology. 1984 81(2). p.113
Chloride currents inChara—A patch-clamp study
Coleman H. A.
The Journal of Membrane Biology. 1986 93(1). p.55
Electrogenic pump activity in red beet: Its relation to ATP levels and to cation influx
Mercier A. Joffre, Poole Ronald J.
The Journal of Membrane Biology. 1980 55(3). p.165
The spatial variation of plasmalemma potential in a spherical cell polarized by a small current source
Pickard William F.
Mathematical Biosciences. 1971 10(3-4). p.307
Membrane depolarization induced by transcellular osmosis in internodal cells ofNitella flexilis
Hayama T.,
Nakagawa S., Tazawa M.
Protoplasma. 1979 98(1-2). p.73
Evolution of long-distance signalling upon plant terrestrialization: comparison of action potentials in Characean algae and liverworts
Kisnieriene Vilma,
Trębacz Kazimierz,
Pupkis Vilmantas,
Koselski Mateusz, Lapeikaite Indre
Annals of Botany. 2022 130(4). p.457
Fortschritte der Botanik (1967)
A non-inactivating high-voltage-activated two-pore Na+ channel that supports ultra-long action potentials and membrane bistability
Cang Chunlei,
Aranda Kimberly, Ren Dejian
Nature Communications. 2014 5(1).
Steady-state voltage-dependent gating and conduction kinetics of single K+ channels in the membrane of cytoplasmic drops ofChara australis
Laver D. R., Walker N. A.
The Journal of Membrane Biology. 1987 100(1). p.31
Effets des cations externes sur l'activité des chlorures cytoplasmiques dosés par l'électrode Ag-AgCl introduite dans la cellule de Nitella
Lefebvre J., Gillet C.
Biochimica et Biophysica Acta (BBA) - Biomembranes. 1971 249(2). p.556
Biographical memoir: Alexander Beaumont Hope, Australian biophysicist, 1928–2008
Barry Peter H.,
Coster Hans G. L., Chow Wah Soon
European Biophysics Journal. 2009 39(1). p.175
Inward membrane current inChara inflata: I. A voltage- and time-dependent Cl− component
Tyerman S. D.,
Findlay G. P., Paterson G. J.
The Journal of Membrane Biology. 1986 89(2). p.139
Activation by Ca2+ and block by divalent ions of the K+ channel in the membrane of cytoplasmic drops fromChara australis
Laver D. R., Walker N. A.
The Journal of Membrane Biology. 1991 120(2). p.131
Temperature dependence of the action potential in Nitella flexilis
Blatt F.J.
Biochimica et Biophysica Acta (BBA) - Biomembranes. 1974 339(3). p.382
The (K+-Na+)-dependence of the membrane parameters of Nitella translucens
Williams E.J., Hogg J.
Biochimica et Biophysica Acta (BBA) - Biomembranes. 1970 203(1). p.170
The Plant Vacuole (1997)
Membrane characteristics as revealed by water and ionic relations of algal cells
Tazawa M.
Protoplasma. 1972 75(4). p.427
Studies on the tonoplast action potential ofNitella flexilis
Shimmen Teruo, Nishikawa Shuh-ichi
The Journal of Membrane Biology. 1988 101(1). p.133
Plant Electrophysiology (2012)
Determination of the Inorganic Pyrophosphate Level and Its Subcellular Localization in Chara corallina
Takeshige K, Tazawa M
Journal of Biological Chemistry. 1989 264(6). p.3262
Free Ca2+ and cytoplasmic streaming in the alga Chara
Williamson R. E., Ashley C. C.
Nature. 1982 296(5858). p.647
Calcium and plant action potentials
BEILBY M. J.
Plant, Cell & Environment. 1984 7(6). p.415
Resistance and capacity in the thallus of Marchantia polymorpha
Paszewski A.,
Bulanda W.,
Dziubiñska H., Trębacz K.
Physiologia Plantarum. 1982 54(2). p.213
Ion Transport in Plants (1973)
Calcium effects on electrogenic pump and passive permeability of the plasma membrane ofChara corallina
Bisson M. A.
The Journal of Membrane Biology. 1984 81(1). p.59
Spontaneous and induced changes in the membrane potential and resistance ofAcetabularia mediterranea
Saddler H. D. W.
The Journal of Membrane Biology. 1971 5(3). p.250
Investigation of the effects of continuous‐wave, pulse‐ and amplitude‐modulated microwaves on single excitable cells of chara corallina
Liu Li‐Ming,
Garber Francine, Cleary Stephen F.
Bioelectromagnetics. 1982 3(2). p.203
Effects of ultraviolet radiation on the membranes ofChara corallina
Doughty C. J., Hope A. B.
The Journal of Membrane Biology. 1973 13(1). p.185
Electrical properties of parenchymal cell membranes in the oat coleoptile
Goldsmith Mary Helen M.,
Fern�dez Hector R., Goldsmith Timothy H.
Planta. 1972 102(4). p.302
Inhibition of electrogenic transport associated with the action potential inChara
Smith J. R., Beilby Mary J.
The Journal of Membrane Biology. 1983 71(1-2). p.131
Blockade of the K+ channel of Chara contraria by Cs+ and tetraethylammonium resembles that of K+ channels in animal cells
Zanello L.P., Barrantes F.J.
Plant Science. 1992 86(1). p.49
Annual Plant Reviews online (2018)
Modeling the Action Potential in Characeae Nitellopsis obtusa: Effect of Saline Stress
Kisnieriene Vilma,
Lapeikaite Indre,
Pupkis Vilmantas, Beilby Mary Jane
Frontiers in Plant Science. 2019 10
Voltage-clamp and current-clamp studies on the action potential in Nitella translucens
Williams E.J., Bradley J.
Biochimica et Biophysica Acta (BBA) - Biomembranes. 1968 150(4). p.626
