Photo-induced H+ Transport between Chloroplasts and the Cytoplasm in a Protoplasmic Droplet of Characeae

Svintitskikh, V. A., Andrianov, V. K. and Bulychev, A. A. 1985.Photo-induced H⁺ transport between chloroplasts and the cytoplasmin a protoplasmic droplet of Characeae.—J. exp. Bot. 36:1414–1429. The effects of light on the membrane potential and cytoplasmicpH of isolated droplets of protoplasm from Nitella have beenstudied using microcapillary electrodes and pH-sensitive antimonymicro-electrodes. Illumination of chloroplast-containing dropletscaused a change of the membrane potential with a concomitantacidification of both the cytoplasm and the outer medium, butit had no effect on the electrical resistance of the surfacemembrane. Treatment of protoplasmic droplets with uncouplers(NH₄Cl and CCCP) resulted in a complete inhibition of the light-inducedacidification of the cytoplasm, whereas the energy transferinhibitor DCCD had no effect. A correlation between the formationof a pH gradient across the thylakoid membrane and the acidificationof the cytoplasm was explicable in terms of the assumption ofrestricted spatial communication between the intra-thylakoidvolume and the cytoplasm in intact chloroplast. The photo-inducedacidification of the boundary layer of an external medium wasmarkedly stimulated under the action of inhibitors of H⁺-ATPaseDCCD and DES. These findings suggest that the active extrusionof H⁺ from the cytoplasm into the external medium is not drivenby an ATPase, although H+-conducting channels of membrane ATPaseprovide a pathway for a passive diffusion of protons from outsideinto the cytoplasm Key words: Transport of protons, protoplasmic droplet, intact chloroplasts, Characeae     

THE EXPERIMENTAL PRODUCTION OF DOUBLE PEAKS IN CHARA ACTION CURVES AND THEIR RELATION TO THE MOVEMENT OF POTASSIUM

The action curve in Chara seems to depend (as in Nitella) on the outward movement of K⁺ from the sap. Presumably the increase in permeability in the inner protoplasmic surface and the outward movement of K⁺ destroy the concentration gradient of K⁺ across the inner protoplasmic surface. Hence the outwardly directed P.D. disappears, causing the rise (spike) of the action curve. The outer protoplasmic surface is normally insensitive to K⁺. But when it is made sensitive to K⁺ by treatment with guanidine the outwardly moving K⁺ sets up a positive P.D. on reaching the outer surface and this causes the action curve to fall, producing a peak. Then the curve has 2 peaks, the second being due to the process of recovery. The action curve thus comes to resemble that of Nitella in which the outer protoplasmic surface is normally sensitive to K⁺.     

Studies of excitable membrane formed on the surface of protoplasmic drops isolated from Nitella II. Tension at the surface of protoplasmic drops

A protoplasmic drop isolated from an internodal cell of Nitella became electrically excitable in a solution containing 0.5 mM NaCl, 0.5 mM KNO₃, 1mM Ca(NO₃)₂ and 2mM Mg(NO₃)₂. A thermodynamic property of the excitable membrane was characterized in terms of tension at the surface of the protoplasmic drop. This was determined by the compression method and/or by the sessile-drop method. The surface tension of the membrane was obtained as a function of the composition of the salts in the external solution, and the time during the formative period of the excitable surface membrane. The results are summarized as follows:

1. 1. The surface of the protoplasmic drop increased with time starting from 0.003 dyne/cm and approached a steady value of about 0.1 dyne/cm within 1 h after the drop was placed in the test solution described above. The membrane became electrically excitable when the surface tension attained the steady value.

2. 2. Increase of concentration of either Na⁺ or K⁺ in the solution induced a sudden decrease of the surface tension, which followed a suppression of the excitability. The critical concentration of Na⁺ or K⁺ was about 10 mM.

3. 3. The surface tension remained constant at about 0.1 dyne/cm in a Ca²⁺ concentration ranging between about 0.1 and 10 mM. At this concentration the drop was excitable. Below and above this range of Ca²⁺ concentration, the surface tension changed sharply with concentration, and the excitability disappeared. At about 0.1 mM Ca²⁺ concentration a discrete variation of the surface tension was observed.

4. 4. The surface tension of the drop stayed constant at 0.1 dyne/cm in the range between 1 and 10 mM of Mg²⁺ concentration. Above and below this range of Mg²⁺ concentration, the surface tension increased sharply with the variation of Mg²⁺ concentration.

These results indicate that the protoplasmic drop retains its excitability in a limited range of salt composition in the external solution. This implies that the excitable membrane of the drop must be very labile in its structure against external perturbations such as electrical stimulus and/or slight variation of salt composition in the solution.     

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.     

ACTION CURVES WITH SINGLE PEAKS IN NITELLA IN RELATION TO THE MOVEMENT OF POTASSIUM

In Nitella the action curve has two peaks, apparently because both protoplasmic surfaces (inner and outer) are sensitive to K⁺. Leaching in distilled water makes the outer surface insensitive to K⁺. We may therefore expect the action curve to have only one peak. This expectation is realized. The action curve thus obtained resembles that of Chara which has an outer protoplasmic surface that is normally insensitive to K⁺. The facts indicate that the movement of K⁺ plays an important part in determining the shape of the action curve.     

CHANGES OF APPARENT IONIC MOBILITIES IN PROTOPLASM : IV. INFLUENCE OF GUAIACOL ON THE EFFECTS OF SODIUM AND POTASSIUM IN NITELLA

In Nitella, as in Halicystis, guaiacol increases the mobility of Na⁺ in the outer protoplasmic surface but leaves the mobility of K⁺ unaffected. This differs from the situation in Valonia where the mobility of Na⁺ is increased and that of K⁺ is decreased. The partition coefficient of Na⁺ in the outer protoplasmic surface is increased and that of K⁺ left unchanged. Recovery after the action current is delayed in the presence of guaiacol and the action curves are "square topped."     

Studies of excitable membrane formed on the surface of protoplasmic drops isolated from Nitella III. Impedance of the surface membrane

A protoplasmic drop isolated from an internodal cell of Nitella in an initial solution composed of 70 mM KNO₃, 50 mM NaNO₃ and 5 mM CaCl₂ became electrically excitable when the drop was placed in the final solution containing 0.5 mM KNO₃, 0.5 mM NaCl, 1 mM Ca(NO₃)₂ and 2 mM Mg(NO₃)₂. The electrical impedance of the surface membrane of the drop was measured both in the initial and final solutions at frequencies between 60 Hz and 100 kHz.The impedance and admittance loci of the surface membrane fell on circular arcs. The d.c. resistance R_m°, and the d.c. capacitance C_m° were determined by extrapolating the circular arcs to the low frequency limit. R_m° thus determined was in the range of 50–200 Ω·cm² in the initial solution, and increased to a steady value of 0.4–4.0 kΩ·cm² when the external solution was replaced by the final solution. After the protoplasmic drop was isolated from the internodal cell of Nitella, C_m° decreased monotonically from about 1.5 μF/cm² within 20 min and approached $\text{1.25±0.1 μ}\text{F/cm}{}^2$ both in the initial and final solutions. No appreciable difference was observed for C_m° in these two solutions.The impedance data were discussed in relation to the process of formation of the membrane at the surface of the protoplasmic drop. After the excitable stage was reached, the drop membrane impedance was found to decrease by a factor of 10 during excitation.     

Characterization of Two Proton Transport Systems in the Tonoplast of Plasmalemma-Permeabilized Nitella Cells

ATP-dependent and PP_i-dependent H⁺-transport systems of thetonoplast were characterized in plasmalemma-permeabilized Nitellacells, where direct access to the protoplasmic surface of thetonoplast was possible. Since H⁺ transport across the tonoplastcan be measured in situ, the identity of the membrane responsiblefor H⁺ pumping is unequivocal. H⁺ transport was evaluated bythe accumulation of neutral red. While both transport systemswere obligately dependent on Mg²⁺, the two transport systemsshowed completely different sensitivity to NO₃^– and K⁺,suggesting the presence of two types of H⁺-pumps in Nitellatonoplast. NO₃^– applied to the protoplasmic surface, completelyand reversibly inhibited ATP-dependent transport but had noeffect on PP_i-dependent transport. By contrast, NO₃^– appliedinto the vacuole by the vacuolar perfusion technique did notinhibit ATP-dependent or PP_i-dependent H⁺ transport. Replacementof K⁺ with the organic cation, BTP, inhibited PP_i-dependenttransport but not the ATP-dependent one, indicating that PP_i-dependenttransport is K⁺ dependent. The sensitivities of the H⁺ transportsystems found in the tonoplast of Nitella are quite similarto those of higher plant tonoplasts. ¹ Present address: Department of Botany, Faculty of Science,University of Tokyo, Hongo, Tokyo 113, Japan. (Received February 21, 1987; Accepted May 27, 1987)     

Electron Microscopy of the Spherical Body of Oral Spirochetes In Vitro: Further Studies

The surface and inner structure of the spherical bodies (SB) produced by the human oral treponeme strain G7201, similar to Treponema macrodentium, were studied by electron microscopy. Ultrathin sectioning and scanning techniques demonstrated that in the presence of a high concentration of sucrose, the outer envelope of one or both terminal ends of this oral spirochete changed into a swollen structure, the SB. Spirochetal cells adhered firmly to the surface of the resultant body. The membrane of the SB, i.e. the outer envelope, enclosed the coiled protoplasmic cylinder and five axial fibrils which were located between the envelope and the cylinder. Large expanded protoplasmic cylinders were observed, surrounded by a partially disrupted double membrane in some SBs. A number of frizzly fibrous structures, which differed from axial fibrils in number and shape, were also observed within these SBs. Except for abnormal or partially broken cylinders, the protoplasmic cylinders tended to be located close to the inner surface of the SB membrane, resulting in a central vacant space with occasional axial fibrils. These findings suggest that the oral spirochete produces an SB by terminal expansion of the outer envelope in the presence of high concentrations of sucrose. The outer envelope of the SB, which consists of two electron-dense layers, has the property of binding spirochetal cells to its outer layer and the protoplasmic cylinder and axial fibrils to the inner layer. Some protoplasmic cylinders were also observed to be swollen in the presence of high sucrose concentrations.     

DIFFERING RATES OF DEATH AT INNER AND OUTER SURFACES OF THE PROTOPLASM : I. EFFECTS OF FORMALDEHYDE ON NITELLA

When protoplasm dies it becomes completely and irreversibly permeable and this may be used as a criterion of death. On this basis we may say that when 0.2 M formaldehyde plus 0.001 M NaCl is applied to Nitella death arrives sooner at the inner protoplasmic surface than at the outer. If, however, we apply 0.17 M formaldehyde plus 0.01 M KCl death arrives sooner at the outer protoplasmic surface. The difference appears to be due largely to the conditions at the two surfaces. With 0.2 M formaldehyde plus 0.001 M NaCl the inner surface is subject to a greater electrical pressure than the outer and is in contact with a higher concentration of KCl. In the other case these conditions are more nearly equal so that the layer first reached by the reagent is the first to become permeable. The outer protoplasmic surface has the ability to distinguish electrically between K⁺ and Na⁺ (potassium effect). Under the influence of formaldehyde this ability is lost. This is chiefly due to a falling off in the partition coefficient of KCl in the outer protoplasmic surface. At about the same time the inner protoplasmic surface becomes completely permeable. But the outer protoplasmic surface retains its ability to distinguish electrically between different concentrations of the same salt, showing that it has not become completely permeable. After the potential has disappeared the turgidity (hydrostatic pressure inside the cell) persists for some time, probably because the outer protoplasmic surface has not become completely permeable.     

STUDIES OF THE INNER AND OUTER PROTOPLASMIC SURFACES OF LARGE PLANT CELLS : II. MECHANICAL PROPERTIES OF THE VACUOLAR SURFACE

The vacuolar surface of Nitella is covered with a non-aqueous film too thin to be visible as a separate membrane. The motion of the protoplasm may subject this film to a good deal of mechanical disturbance. Apparently this does not rupture the film for no dye escapes into the protoplasm as the result of such disturbance when the vacuolar sap is deeply stained with neutral red or brilliant cresyl blue. When the deeply stained central vacuole breaks up into several smaller vacuoles, leaving the outer protoplasmic surface in its normal position, there is no evidence of the escape of dye into the protoplasm through the film surrounding the vacuole.     

Voltage-Dependent K-Channel in Protoplasmic Droplets of Chara corallina: A Single Channel Patch Clamp Study

Passive transport of potassium through the plasma membrane of a protoplasmic droplet isolated from large internodal cells of Chara corallina Klein ex Willd., em, R.D.W. has been investigated using the patchclamp technique. When the membrane is hyperpolarized the conductance of a single K⁺-channel is of the order of magnitude of 100 picoSiemens and is reduced by tetraethylammonium chloride. Its open time is voltage dependent. This voltage-dependent K⁺-channel displays rectifying properties. The channel density is about 0.1 channel per square micrometer of membrane. When the membrane is depolarized the conductance of a single channel is of the order of magnitude of 30 picoSiemens and is insensitive to tetraethylammonium chloride. These results suggest that K⁺-channels are incorporated in the plasma membrane during membranogenesis of a protoplasmic droplet. They constitute further evidence for the existence of voltage-dependent K⁺-channels in plant cells.     

Protoplasmic streaming of an internodal cell of Nitella flexilis; its correlation with electric stimulus

The sudden cessation or sudden decrease in velocity of the protoplasmic streaming of Nitella flexilis is observed whenever an action potential is elicited. The action potential can be generated by an electric stimulus after its refractory period, whether the flow is at a complete standstill or on the way to recovery. The membrane potential is generally decreased more or less when the rate of flow is decreased on application of salts or other agents. There is, however, no parallelism between these two. The membrane potential decreases proportionally with applied voltage of subthreshold intensity, while the rate of flow does not change appreciably. Only on application of a superthreshold voltage does the flow stop suddenly. In one case the rate of flow decreased to half without appreciable decrease in membrane potential. In another case it continued flowing at about one-half rate, although the membrane potential was almost zero. The Q₁₀ of the rate of flow is about 2, while it is 1.1 to 1.5 for the membrane potential. The sudden cessation of the protoplasmic streaming is supposed to be caused by the temporary formation of certain interlinkages among contractile protein networks in the endoplasm during excitation at the cathodal half of Nitella.     

The Influence of the Cell Membrane on some Toxicity Effects of Growth Substances in Nitella

When cells of Nitella are placed in a solution of some plantgrowth substances there is a profound increase in the membraneresistance as measured by means of an internal silver/silverchloride micro-electrode. This impedance effect is accompaniedby some marked visible changes within the cell cytoplasm, thesechanges being dependent upon the concentration of undissociatedgrowth substance in the vicinity of the membrane, and upon thepH of the external environment. A detailed study is made of these visible changes and, takinginto account the negatively charged membrane, one possible interpretationof the results is that only undissociated molecules of the growthsubstance may enter the cytoplasm of Nitella from the environment,the diffusion obeying a simple Fick Law relationship. The substances are used in sufficient quantity to kill the Nitellacell, death following the visible effects, and they appear tobe unique in that their toxic effect produces a system of highmembrane impedance.     

Membrane attachment and structure models of lipid storage droplet protein 1

Neutral lipid triglycerides, a main reserve for fat and energy, are stored in organelles called lipid droplets. The storage and release of triglycerides are actively regulated by several proteins specific to the droplet surface, one of which in insects is PLIN1. PLIN1 plays a key role in the activation of triglyceride hydrolysis upon phosphorylation. However, the structure of PLIN1 and its relation to functions remain elusive due to its insolubility and crystallization difficulty. Here we report the first solid-state NMR study on the Drosophila melanogaster PLIN1 in combination with molecular dynamics simulation to show the structural basis for its lipid droplet attachment. NMR spin diffusion experiments were consistent with the predicted membrane attachment motif of PLIN1. The data indicated that PLIN1 has close contact with the terminal methyl groups of the phospholipid acyl chains. Structure models for the membrane attachment motif were generated based on hydrophobicity analysis and NMR membrane insertion depth information. Simulated NMR spectra from a trans-model agreed with experimental spectra. In this model, lipids from the bottom leaflet were very close to the surface in the region enclosed by membrane attachment motif. This may imply that in real lipid droplet, triglyceride molecules might be brought close to the surface by the same mechanism, ready to leave the droplet in the event of lipolysis. Juxtaposition of triglyceride lipase structure to the trans-model suggested a possible interaction of a conserved segment with the lipase by electrostatic interactions, opening the lipase lid to expose the catalytic center.     

Fluorescence staining of living cells with fluorescamine

Summary The interaction of fluorescamine with living plant and animal cells was investigated to determine which subcellular structures and molecular species might react with the dye and to assess its effects on cell viability and function.Plasma and nuclear membranes ofXenopus erythrocytes, mitochondria of sea urchin sperm, growing apices of Timothy root hairs, and various organelles ofNitella andEuglena were labelled as judged by fluorescence microscopy. Cytoplasmic fluorescence was particulate inNitella and easily displaced by moderate centrifugal fields in sea urchin eggs. Chloroplasts and nuclei isolated from cells labelledin vivo exhibited fluorescamine dependent fluorescence.Reaction seemed to have little or no effect on cell viability (Euglena) photoautotrophic growth (Euglena), cell motility (sperm), fertilizability (sperm or egg), embryonic development (sea urchin), or cytoplasmic streaming (Nitella, Timothy).Quantitative fluorometric analysis of thein vivo reactants in sperm indicated a reaction preference for phospholipid over protein compared to control cells dissociated in SDS prior to labelling. The bulk of labelled lipid was phosphatidylethanolamine.These results suggest that fluorescamine is a true vital dye which can label the cell surface as well as penetrate deeply within cells to label a variety of organelles. The distribution of fluorescence and results of chemical analysis suggest thatin vivo the dye may preferentially react with membrane.     

Light Climate and Metabolism of Nitella flexilis (L.) AG. In the Bottom Waters of Oligotrophic Lake Grane Langsø, Denmark

The irradiance reaching Nitella at 11.5 m depths was almost the same during three years: 1000 cal cm⁻² year⁻¹ PAR, or 2.2% of the surface irradiance PAR. Green light (500–600 nm) constituted most (62–88%) of the irradiance on Nitella. Net photosynthesis by Nitella was linearly correlated to irradiance. Nitella had a positive oxygen balance from mid-May to late September and a minor negative one at other times. The annual turnover of biomass was potentially high, and the dark-respiration was very important in the metabolic balance. The contribution of Nitella to total autotrophic production and to oxygen conditions in the hypolimnion is discussed.