Application of leaf extract causes repetitive action potentials inBiophytum sensitivum

A wound stimulus evoked a number of repetivite action potentials in the leaf ofBiophytum sensitivum. When the cut end of a leaf was immersed in a leaf extract, the resulting repetitive action potentials continue for a long time. These repetitive action potentials disappeared immediately when the leaf extract, which contains a proposed stimulant, was removed and the cut end was washed with water.     

Electrotonic Coupling between Adjacent Internodal Cells of Chara braunii: Transmission of Action Potentials beyond the Node

Many nodal cells are interposed between two internodal cellsof Chara braunii. When an action potential conducted in an internodereached the node, no electrical activation in the nodal cellscould be found, although an area of the membrane bordering thenodal cells in this internode was partially activated (end-membraneaction potential). When the action potential approached thenode along the stimulated internode, an electrotonic potentialchange (depolarization) was produced in the other internode.This depolarization was greatly depressed by the end-membraneaction potential of the stimulated internode, so that hardlyany transmission took place. The ratio of the potential changein the surface membrane of the adjoining ("postsynaptic") internode(cell b) to that of the stimulated one (cell a), the couplingratio, e_b/e_a, can be estimated from a simple equivalent circuitof the nodal region composed of two surface-membrane resistances(R_a, R_b) and intercellular resistance (R_n). If R_n remains thesame, a higher ratio should be produced with a larger R_b, butthe ratio does not depend on any change in R_a, which could beproved experimentally. Transmission of the action potentialbeyond the node was frequent when the coupling ratio was increasedand when the threshold that elicits the action potential waslowered by immersing the node in a K or Na salt solution. ¹ Present address: Department of Physiology, Tohoku UniversitySchool of Dentistry, Sendai 980, Japan. (Received December 1, 1980; Accepted January 23, 1981)     

Ionic composition and pH of the vacuolar sap in marine dinoflagellate Noctiluca

Ionic composition of the vacuolar sap of Noctiluca miliariswas as follows: [Na⁺] = 487.3 mM, [K⁺]=24.1 mM, [Ca²⁺]=6.6 mM,[Mg²⁺]=2.8 mM, [Cl^–]=500mM, [NH₄⁺]=15–25 mM, and[SO₄^2–]=undetectable. To measure the vacuolar pH of singleliving cells, a pH-sensitive glass microelectrode was used.The vacuolar pH value was 3.50 ±0.18. When the cellswere transferred from normal sea water into osmotically adjusted50% sea water for one day, the vacuolar ion concentrations remainedalmost constant. Upon immersing the cells in osmotically unadjustedsea water of various concentrations for one day, the observedincrements or decrements of the vacuolar ion concentrationscould be accounted for largely by the migration of water outof or into the cells. The intrinsic ionic composition of thevacuole seems to be constant against changes in ion concentrationsof the bathing medium. (Received October 20, 1975; )     

The flash-triggering action potential of the luminescent dinoflagellate Noctiluca

The action potential which elicits luminescence in Noctiluca is recorded from the flotation vacuole as a transient all-or-none hyperpolarization in response to either local or general application of inward (bath to vacuole) current. Experiments were performed to determine whether the unorthodox polarities of both the stimulus current and the potential response resulted from uncommon bioelectric mechanisms or from special morphological features of this species. The findings all indicate that the action potential belongs to the familiar class of responses which have their origin in voltage- and time-dependent selective increases in membrane permeability, and that morphological factors account for the observed deviations from normal behavior. Both the stimulus and the response have orthodox polarities provided the vacuole is designated as an "external" extracytoplasmic compartment. Differential recording between vacuole and cytoplasm showed that the action potential occurs across the vacuolar membrane, with the cytoplasmic potential, which at rest is negative with respect to the vacuole, overshooting zero and reversing sign to become transiently electropositive. The rising phase of the action potential therefore depends on active current flow through the vacuolar membrane from the vacuole into the cytoplasm. Propagation of the action potential over the subspherical cell from the locus of stimulation is thought to depend largely on the core conductor properties of the thin perivacuolar shell of cytoplasm which is bounded on its inner surface by the excitable membrane and on its outer surface by inexcitable membranes.     

Conduction Velocity and Blockage of Action Potential in Chara Internodal Cells

Conduction velocity of the action potential in Chara brauniiinternodal cells was 0.21 ?0.05 cms in moist air and 1.5?0.9cms in artificial pond water (APW). The action potential waspropagated at an almost constant velocity along the cell inmoist air except within 0.3 cm from an end of the cell, whereasin APW, the velocity increased to 5.7 ? 2.3 cms within 1.8 cmfrom the end of the cell. When part of the cell was put in moistair and the other part was immersed in APW, conduction of theaction potential in moist air decreased in velocity and sometimesstopped in the vicinity of the boundary between moist air andAPW. Some cells from the plants collected in late autumn towinter generated an action potential which could not propagatein moist air. In these cells, an increase in the threshold andpartial cessation of protoplasmic streaming were observed. ¹Present address: Department of Physiology, Tohoku UniversitySchool of Dentistry, Seiryo-machi, Sendai 980 ²Present address: Biology Laboratory, Kyoritsu Women's University,Hachioji, Tokyo 193, Japan. (Received March 10, 1987; Accepted July 6, 1987)     

Local ion currents controlling the localized cytoplasmic movement associated with feeding initiation ofNoctiluca

Summary We used an extracellular vibrating probe to investigate local transmembrane ion currents that occur just before and during localized cytoplasmic movement associated with feeding initiation in the marine dinoflagellateNoctiluca, Our results indicates that the currents flow only through a specialized cellular region, the sulcus, suggesting a heterogeneous distribution of an ion channel in the cell membrane. A current enters into the middle of the sulcus where the cytostome exists and leaves from both ends of the sulcus. The mean inward and outward current densities were approx. + 11 and — 1 A·cm^–2, respectively. The cytoplasm began to stream toward the cytostome in association with the currents and then aggregated around it. Removal of Ca²⁺, Na⁺, or Mg²⁺ ions from the external medium diminished the inward current. Ca²⁺ ions were proved to carry only 5% of the inward current. The Ca²⁺ current appears to be enough to raise Ca²⁺ concentration in a localized region of the cytoplasm, causing the cytostome-directed cytoplasmic movement. Rest of the current seems to be carried by Na⁺ ions. Most of the outward current was inhibited by an ion pump inhibitor, but the current-carrying ion species could not be identified.     

Light- and Auxin-Induced Leaflet Opening in Detached Pinnae of Mimosa pudica

Leaflet pairs from detached pinnae of Mimosa pudica opened afterthe pinnae had been irradiated with light (2 W·m^–2)of 726 or 403 nm, whereas they remained almost closed with lightof 585 or 656 nm. Light-induced leaflet opening was observedonly in the daytime, from 6:00 to 16:00. Application of IAAat more than 30 µg/ml to the cut end of the pinna rachisesmade the leaflets open even in darkness with almost constantlag times of about 100 min which were independent of the concentration.NAA and 2,4-D also made the leaflet open at lower concentrationsthan IAA. Auxin-induced leaflet opening showed diurnal variation.Application of IAA for 2 to 6 min, depending on the concentration,was enough to open the leaflets. Autoradiography showed thatIAA was transferred from the cut end of a rachis throughouta pinna within 4 min. ¹Present address: Biological Institute, Faculty of Science,Kobe University, Kobe 657, Japan. (Received September 24, 1982; Accepted March 4, 1983)     

An electrophysiological study of the membrane in aplanospore-like cell of Boergesenia forbesii

Membrane potential and resistance, each of which was the sumof those of the plasmalemma and tonoplast, measured in the coenocyticthallus of Boergesenia forbesii were 6.7 mv inside positiveand 2.8 k.cm², respectively. Protoplasm squeezed from the thallus into artificial sea water(ASW) formed numerous spherical bodies, which are termed aplanospore-likecells (simply "spores"). The following electrical propertiesof the "spores" 20–40 hr after squeezing were obtained:potential difference (p.d.) across plasmalemma (E_co) was –66mv (– means inside negative), plasmalemma resistance 665cm², p.d. across the tonoplast (E_vc) +73 mv, and tonoplast resistance2.6 k.cm². Tenfold increase in external [K⁺] caused +45 mv changein E_co and +17 mv in E_vc. The plasmalemma was entirely depolarizedin Ca⁺⁺-free ASW or ASW containing Triton X-100. When the "spore" was immersed in potassium-rich (277 mil) ASW,E_co was almost zero and the tonoplast showed two states (I andII, E_ve about +70 mv and +20 mv, respectively). E_vc went backand forth between the two states spontaneously or when a smallcurrent was applied. In most cases oscillatory changes in E^vcoccurred after the lapse of a long time in the K+-rich sea water.Membrane resistances in states I and II were 5 and 9 k.cm²,respectively. (Received July 11, 1977; )     

Modification of voltage-sensitive inactivation of Na+ current by external Ca2+ in the marine dinoflagellateNoctiluca miliaris

Effects of the external Ca²⁺ concentration on the depolarization-induced transient inward Na⁺ current responsible for the Na⁺ spike in the dinoflagellate Noctiluca miliaris were examined. The peak value and the duration of the Na⁺ current increased when lowering the external Ca²⁺ concentration. The threshold potential level for activation and the reversal potential level of the current were not affected by the external Ca²⁺ concentration. The inactivation took place even in a solution containing EGTA with very low (<10^–9 M) Ca²⁺ concentration. Voltage dependency of the inactivation was scarcely affected by the external Ca²⁺ concentration. It is concluded that inactivation of Na⁺ channels responsible for the current is dependent on membrane depolarization and that the external Ca²⁺ modulates the inactivation kinetics. Appearance of a Na⁺ spike in a solution with reduced Ca²⁺ concentration is caused by a lowered rate of inactivation of the Na⁺ channels.