The study of microviscosity of plasma membranes of Nitella cells during rest and excitation

Changes in the microviscosity of excitable membranes was investigated using resonance Raman spectroscopy of carotenoids. The Raman resonance spectra of carotenoids in Nitella cells were excited by 514.5 nm line of an argon ion laser. The bands at 1525 cm-1, 1160 cm-1 and 1008 cm-1 were observed and they were assigned to C=C, C-C and C-CH vibrations, respectively. The rhythmic excitation of cell reduced the intensity and increased the ratios of intensity of major carotenoid bands with no noticeable shift in the position of peaks. The Arrhenius plot of relative intensity ratios of 1525 cm-1 and 1160 cm-1 bands versus reciprocal temperature showed a change of the slope in the range of 13-18 degrees C. This indicates a membrane phase transitions in which a reorientation of carotenoids species takes place. The interpretation was supported by parallel microcalorimetric and EPR measurements. The decrease of microviscosity with increasing temperature is probably caused by changes in polyene chain conformation. It is suggested that membrane microviscosity during NH4(+)-stimulated rhythmic excitation of algal cells increases, and membrane-associated carotenoids act as microviscosity-sensitive "potential sensor" for the channel.     

Rhythmic change of membrane potential and cyclosis of Nitella internode

The membrane potential of Nitella internode shows a spontaneousrhythmicity. The period depends largely upon temperature andthe length of the cell. Moreover, the period is reversibly prolongedat low temperature and also by treatment with cytochalasin B.We concluded that this bioelectrical rhythm is closely relatedto cytoplasmic streaming. (Received August 11, 1975; )     

Light-induced hyperpolarization of membrane potential in Nitella flexilis call plasmalemma

Light-induced hyperpolarization of the membrane potential in Nitella flexilis cell plasmalemma was investigated by the clamping method. It is shown that this response is of an excitation character. The equivalent electric diagram used in the work and the electromotive force included on its basis allowed consideration of two possible (from the common point of view) mechanisms of the response: the action of the electrogenic ion pump and membrane specific permeability to a definite ion. The membrane being in the hyperpolarization state is not capable of acting as a bicarbonate electrode. It is suggested that the response under study is defined by the action of the electrogenic pump, the role of which is performed by HCO2(3)-dependent H+-ATPase with the ion channel as an exciting one.     

Endoplasmic filaments generate the motive force for rotational streaming in Nitella

The streaming endoplasm of characean cells has been shown to contain previously unreported endoplasmic filaments along which bending waves are observed under the light microscope using special techniques. The bending waves are similar to those propagated along sperm tails causing propulsion of sperm. In Nitella there is reason to believe that nearly all of the filaments are anchored in the cortex and that their beating propels the endoplasm in which they are suspended. This hypothesis is supported by calculations in which typical and average wave parameters have been inserted into the classical hydrodynamic equations derived for sperm tail bending waves. These calculations come within an order of magnitude of predicting the velocity of streaming and they show that waves of the character described, propagated along an estimated 52 m of endoplasmic filaments per cell, must generate a total motive force per cell within less than an order of magnitude of the forces measured experimentally by others. If we assume that undulating filaments produce the force driving the endoplasm, then the method described for measuring the motive force could lead to a lower than actual value for the motive force, since both centrifugation and vacuolar perfusion would reverse the orientation of some filaments. Observations of the initiation of particle translation in association with the filaments suggest that particle transport and wave propagation, which occur at the same velocity, may both be dependent on the same process. The possibility that some form of contractility provides the motive force for filament flection and particle transport is discussed.     

Resting membrane potential and action potential of Nitella expansa protoplasts

Inside negative membrane potentials were observed for protoplastsobtained from Nitella expansa leaf internodal cells in mediacontaining 1 to 100 mM CaCl₂ using the microelectrode technique.The potential values were less negative than the membrane potentialof intact N. expansa leaf internodal cells. In addition, anaction potential consisting of two components—a fast componentand a slow component—was induced by electrical stimulationfor the protoplasts as well as the intact cells. (Received December 18, 1979; )     

Coupling of excitation and cessation of cyclois in Nitella: role of divalent cations

The effect of external divalent cation salt solutions upon the association of an action potential and cessation of cytoplasmic streaming in Nitella was studied. Nitella cells remained excitable when immersed in solutions of CaCl₂, MgCl₂, BaCl₂, and SrCl₂. Cessation of streaming coincident with excitation occurred in solutions of CaCl₂ or SrCl₂ but not in solutions of MgCl₂ or BaCl₂. In cells exposed to solutions containing mixtures of MgCl₂ and CaCl₂, or MgCl₂ and SrCl₂, it was the [Ca]/[Mg] or [Sr]/[Mg] which determined the effect of an action potential upon the rate of streaming, rather than the absolute concentrations Ca⁺⁺ or Sr⁺⁺. The implications of these data are discussed with respect to the structure involved in the generation of cytoplasmic streaming and the relation of streaming to other types of biological motion.     

Dynamic property of membrane formation in a protoplasmic droplet of Nitella

A theory is presented to explain the dynamic characteristics of an electric potential and the resistance of a surface membrane during the formation of a protoplasmic droplet isolated from Nitella. Basic equations are coupled ones for describing ion concentrations near the surface of the droplet, active and passive ion fluxes on the surface, and kinetics of membrane-constituting molecules diffusing from the inside of the protoplasm. The present results give a good explanation of the observed kinetics of electric properties throughout the formative process of surface membranes after the ion concentrations are replaced by lower ones. The results can also explain well the observed data on the steady state. Oscillatory changes in the membrane potential induced by ions strongly adsorbed on the surface membrane are discussed in relation to growth and regeneration phenomena in biological systems such as bean roots and Acetabularia.     

Nitella fluctuation and instability in the membrane potential near threshold.

Excitation of Nitella internodal cell was investigated as an example of the phase transition in an open system far more thermal equilibrium. The power density spectrum of the membrane potential fluctuation had a bulge in a frequency range lower than 1 Hz at the resting state and a peak at approximately 0.03 Hz at a depolarized state near the threshold. A critical oscillation in the membrane potential was observed when threshold was gradually approached from the resting state. Repetitive firing was observed under a step-current of the superthreshold value. The frequency of spectral peaking, critical oscillation, and repetitive firing agree well with each other. The result suggests that the hard-mode instability occurs in the Nitella internodal cell. The membrane impedance had no peak in the same frequency region as the peak of the voltage spectrum. The spectral peak may be ascribed to be electrogenic pump modulated by the metabolic feedback system in photosynthesis.     

The electromotive force of the Chara membrane during the hyperpolarizing response

The hyperpolarizing response of the Chara internodal cell wasstudied by applying the voltage clamp and constant current techniques.By assuming the membrane as an electromotive force (emf) inseries with a resistance r (which is the sum of a series resistancer_s and the membrane resistance r_m), it was shown that the hyperpolarizingresponse was brought about not only by the increase in membraneresistance but by the increase in membrane emf. The time dependentcurrent-voltage (I–V_m) curve obtained under the voltageclamp during the hyperpolarizing response showed a negativeresistance. The hyperpolarizing response is also an excitation,since it is a transition process of the membrane across a negativeresistance region. (Received July 22, 1974; )     

The light-dependent effect of external pH on the membrane potential of Nitella

In the light the membrane potential of Nitella flexilis andNitella axilliformis was hyperpolarized by raising the externalpH above pH 5.5, at the rate of 30–40 mV/pH below pH 8.This hyperpolarization was largely reduced in the dark. The membrane potential was sensitive to the external pH of mediawith a low potassium concentration, where it was relativelyinsensitive to potassium concentration. In media of a high concentrationwhere it was sensitive to the potassium concentration, the membranebecame insensitive to the external pH. The transition from apH-sensitive to a pH-insensitive state occurred rather abruptlyon increasing the external potassium concentration. (Received September 1, 1972; )