Your search keyword '"Chara physiology"' showing total 3 results

1. Mechanosensitive ion channels in chara: influence of water channel inhibitors, HgCl2 and ZnCl2, on generation of receptor potential.

Author

Iwabuchi K, Kaneko T, and Kikuyama M

Subjects

Algal Proteins physiology, Aquaporins physiology, Chara physiology, Electrophysiology instrumentation, Electrophysiology methods, Mechanotransduction, Cellular drug effects, Mechanotransduction, Cellular physiology, Membrane Potentials drug effects, Algal Proteins antagonists & inhibitors, Aquaporins antagonists & inhibitors, Chara drug effects, Chlorides pharmacology, Mercuric Chloride pharmacology, Zinc Compounds pharmacology

Abstract

Characean internodal cells generate receptor potential (DeltaE (m)) in response to mechanical stimuli. Upon a long-lasting stimulus, the cells generated DeltaE (m) at the moment of both compression and decompression, and the amplitude of DeltaE (m) at the moment of decompression, (DeltaE (m))(E), was larger than that at compression. The long-lasting stimulus caused a membrane deformation (DeltaD (m)) having two components, a rapid one, (DeltaD (m))(rapid), at the moment of compression and a slower one, (DeltaD (m))(slow), during the long-lasting compression. We assumed that (DeltaD (m))(slow) might have some causal relation with the larger DeltaE (m) at (DeltaE (m))(E). We treated internodal cells with either HgCl(2) or ZnCl(2), water channel inhibitors, to decrease (DeltaD (m))(slow). Both inhibitors attenuated (DeltaD (m))(slow) during compression. Cells treated with HgCl(2) generated smaller (DeltaE (m))(E) compared to nontreated cells. On the other hand, cells treated with ZnCl(2) never attenuated (DeltaE (m))(E) but, rather, amplified it. Thus, the amplitude of (DeltaD (m))(slow) did not always show tight correlation with the amplitude of (DeltaE (m))(E). Furthermore, when a constant deformation was applied to an internodal cell in a medium with higher or lower osmotic value, a cell having higher turgor always showed a larger (DeltaE (m))(E). Thus, we concluded that changes in tension at the membrane may be the most important factor to induce activation of mechanosensitive Ca(2+) channel.

Published

2008

2. Electrophysiology of turgor regulation in marine siphonous green algae.

Author

Bisson MA, Beilby MJ, and Shepherd VA

Subjects

Chara physiology, Osmotic Pressure, Electrophysiology, Eukaryota physiology

Abstract

We review electrophysiological measures of turgor regulation in some siphonous green algae, primarily the giant-celled marine algae, Valonia and Ventricaria, with particular comparison to the well studied charophyte algae Chara and Lamprothamnium. The siphonous green algae have a less negative plasma membrane potential, and are unlikely to have a proton-based chemiosmotic transport system, dominated by active electrogenic K(+) uptake. We also make note of the unusual cellular structure of the siphonous green algae. Hypertonic stress, due to increased external osmotic pressure, is accompanied by positive-going potential difference (PD), increase in conductance, and slow turgor regulation. The relationship between these is not yet resolved, but may involve changes in K(+ )conductance (G (K)) or active K(+) transport at both membranes. Hypotonic turgor regulation, in response to decreased external osmotic pressure, is approximately 3 times faster than hypertonic turgor regulation. It is accompanied by a negative-going PD, although conductance also increases. The conductance increase and the magnitude of the PD change are strongly correlated with the magnitude of hypotonic stress.

Published

2006

3. Effect of a single excitation stimulus on photosynthetic activity and light-dependent pH banding in Chara cells.

Author

Bulychev AA, Kamzolkina NA, Luengviriya J, Rubin AB, and Müller SC

Subjects

Cell Membrane chemistry, Cell Membrane radiation effects, Chara chemistry, Chara radiation effects, Chlorophyll chemistry, Dose-Response Relationship, Radiation, Hydrogen-Ion Concentration, Light, Photosynthesis radiation effects, Action Potentials physiology, Cell Membrane physiology, Chara physiology, Chlorophyll metabolism, Electric Stimulation methods, Photosynthesis physiology

Abstract

Using pH microelectrodes and a Microscopy PAM (pulse-amplitude modulated) chlorophyll fluorometer, it is shown that a propagation of an action potential in Chara corallina leads to transient suppression of spatially periodic pH profiles along the illuminated cell. The suppression was manifested as a large pH decrease in the alkaline zones and a slight pH increase in the acid zones. The propagating action potential diminished the maximum yield of chlorophyll fluorescence (F(m)') in the alkaline cell regions, as well as the quantum yield of photosystem II photochemistry, without affecting F(m)' in the acid cell regions. The results indicate an interference of membrane excitation in the mechanisms responsible for pH banding patterns in Characean algae. Apparently, the electrical excitation of the plasma membrane in the alkaline cell regions initiates a pathway that can modulate membrane events at the thylakoid membrane.

Published

2004