Internal calcium concentration and potassium permeability in Paramecium

Distinct patterns of exocytosis elicited by Ca2+, Sr2+ and Ba2+ in bovine chromaffin cells

Three divalent cations can elicit secretory responses in most neuroendocrine cells, including chromaffin cells. The extent to which secretion is elicited by the cations in intact depolarized cells was Ba²⁺ > Sr²⁺ ≥ Ca²⁺, contrasting with that elicited by these cations in permeabilized cells (Ca²⁺ > Sr²⁺ > Ba²⁺). Current-clamp recordings show that extracellular Sr²⁺ and Ba²⁺ cause membrane depolarization and action potentials, which are not blocked by Cd²⁺ but that can be mimicked by tetra-ethyl-ammonium. When applied intracellularly, only Ba²⁺ provokes action potentials. Voltage-clamp monitoring of Ca²⁺-activated K⁺ channels (K_Ca) shows that Ba²⁺ reduces outward currents, which were enhanced by Sr²⁺. Extracellular Ba²⁺ increases cytosolic Ca²⁺ concentrations in Fura-2-loaded intact cells, and it induces long-lasting catecholamine release. Conversely, amperometric recordings of permeabilized cells show that Ca²⁺ promotes the longest lasting secretion, as Ba²⁺ only provokes secretion while it is present and Sr²⁺ induces intermediate-lasting secretion. Intracellular Ba²⁺ dialysis provokes exocytosis at concentrations 100-fold higher than those of Ca²⁺, whereas Sr²⁺ exhibits an intermediate sensitivity. These results are compatible with the following sequence of events: Ba²⁺ blocks K_Ca channels from both the outside and inside of the cell, causing membrane depolarization that, in turn, opens voltage-sensitive Ca²⁺ channels and favors the entry of Ca²⁺ and Ba²⁺. Although Ca²⁺ is less permeable through its own channels, it is more efficient in triggering exocytosis. Strontium possesses both an intermediate permeability and an intermediate ability to induce secretion.

Membrane excitability and membrane currents in the marine ciliate Euplotes vannus

Electrical properties of E. vannus were investigated by use of constant current injection, voltage-clamp, and isoosmotic ion substitution. The resting potential of approximately -40 mV was K(+) and Ca(2+)-dependent. Spontaneous depolarizations occurred frequently with peaks around -20 mV and durations from several hundred ms to several s. External Ba(2+) or internal Cs(+) induced all-or-none action potentials. Current stimuli induced Ca(2+)-dependent graded action potentials. Sr(2+) or Ba(2+), but not Mg(2+), instead of Ca(2+) increased the regenerative response. Repolarization occurred in two steps: a first fast and a second slow one. It was strongly modified by the Ca(2+) substitutes. A voltage-dependent small Ca(2+) inward current was activated at depolarizations beyond -20 mV. It triggered a fast and a slowly activating K(+) outward current and was itself short-circuited by the fast K(+) current. Therefore, it could only be measured when K(+) currents were not activated or inhibited. A slowly activating Na(+) inward current was identified that turned to outward direction after replacement of external Na(+) by choline(+). The K(+) outward currents differed in their sensitivity to external TEA(+) and in their inactivation kinetics. All currents were correlated to the voltage-dependent influx of Ca(2+).

Calmodulin defects cause the loss of Ca2(+)-dependent K+ currents in two pantophobiac mutants of Paramecium tetraurelia

Two behavioral mutants of Paramecium tetraurelia, pantophobiacs A1 and A2, have single amino acid defects in the structure of calmodulin. The mutants exhibit several major ion current defects under voltage clamp: (i) the Ca2(+)-dependent K+ current activated upon depolarization of Paramecium is greatly reduced or missing in both mutants, (ii) both mutants lack a Ca2(+)-dependent K+ current activated upon hyperpolarization, and (iii) the Ca2(+)-dependent Na+ current is significantly smaller in pantophobiac A1 compared with the wild type, whereas this current is slightly increased in pantophobiac A2. Other, minor defects include a reduction in peak amplitude of the depolarization-activated Ca2+ current in pantophobiac A2, increased rates of voltage-dependent inactivation of this Ca2+ current in both pantophobiac A1 and pantophobiac A2, and an increase in the time required for the hyperpolarization-activated Ca2+ current to recover from inactivation in the pantophobiacs. The diversity of the pantophobiac mutations' effects on ion current function may indicate specific associations of calmodulin with a variety of Ca2(+)-related ion channel species in Paramecium.

Biochemical characterization of a genetically altered calmodulin in Paramecium

Recent evidence proposes that the calcium-binding protein, calmodulin, plays a crucial role in the regulation or modulation of the calcium-dependent potassium conductance in Paramecium tetraurelia (Hinrichsen, R.D., Burgess-Cassler, A., Soltvedt, B.C., Hennessey, T. and Kung, C. (1986) Science 323, 503-506). We purified the calmodulins from both the wild type and pantophobiac A (a mutant lacking the above-mentioned conductance and whose phenotypic defect is traceable to its calmodulin) by hydrophobic interaction and immunoaffinity chromatographies, and examined them biochemically. In this paper we address the preliminary characterization of the two calmodulins and discuss the consequences of the genetic alteration. The differences described here are in their electrophoretic mobilities in polyacrylamide gel electrophoresis and in their binding characteristics to monoclonal antibodies raised against calmodulin from wild-type paramecia. Also, we present data which indicate a difference in the stimulation of the calmodulin-dependent enzyme bovine brain phosphodiesterase under certain conditions.

Chemoreception in Paramecium tetraurelia: acetate and folate-induced membrane hyperpolarization

Acetic and folic acids hyperpolarize the membrane potential of Paramecium tetraurelia in a concentration-dependent manner. The membrane responses are accompanied by small changes in cell resistance, and are significantly reduced by increasing extracellular cation concentrations, suggesting that the attractants bring about the membrane potential change by increasing cell permeability to cations. The inability to show a reversal potential for the hyperpolarization to attractants suggests that the effects of cations on the response are non-specific, however. The possible roles of Ca++, K+, and Na+ in the attractant-induced responses were further investigated by applying acetate and folate to cells with genetic defects in specific ion conductances, by collapsing the driving forces for these ions, and by testing the effects of ion channel blockers on the responses. These studies suggest that the membrane responses to attractants are not due to the direct effects of increased or decreased membrane permeability to cations. Attempts to block the acetate and folate-induced hyperpolarization by collapsing surface potential or using a mutant with reduced surface charge were inconclusive, as were studies on the possible role of attractant transport in the membrane responses. We hypothesize that the membrane hyperpolarization may be due to either the indirect effects of increased calcium permeability, to extrusion of calcium through activation of a calcium pump, or to a proton efflux.

A single gene mutation that affects a potassium conductance and resting membrane potential in Paramecium

A new mutant of Paramecium tetraurelia has been isolated with a profound defect in the regulation of membrane potential. This mutant, restless, hyperpolarizes as a potassium electrode below 8 mM external K+ whereas wild-type cells can maintain a constant resting cell potential independent of low external K+ concentration. restless dies in solutions of low K+ concentration in which wild-type can survive indefinitely. restless is not allelic to mutations that affect the depolarization-dependent Ca2+ current, the Ca2+-activated K+ current, and the Ca2+-activated Na+ current. The results suggest that restless is a new class of mutant affecting a K+ conductance hitherto not characterized genetically in Paramecium.

Mutant analysis shows that the Ca2+-induced K+ current shuts off one type of excitation in Paramecium

Two mutants of Paramecium tetraurelia, called "pantophobiacs," were found to lack most of the slow Ca2+-induced K+ outward current. Passive properties, the transient Ca2+ inward current, and the fast depolarization-induced K+ outward current remain normal. The mutant defect reduces the ability to shut off a normal, excited state of the membrane and results in repeated, long backward swimming instead of the wild-type jerks in response to a variety of ions, to heat, and to touch.

Ion regulation in potassium-sensitive mutants of Paramecium tetraurelia

Two recessive mutations of Paramecium tetraurelia confer sensitivity to potassium: While wild-type cells survive when up to 30 mM KCl is added to their growth medium, mutants cease to grow and die when levels of added KCl reach 20-25 mM. Similar sensitivities are seen to Rb+ and Cs+, but not to Na+. Swimming behavior of mutants is indistinguishable from wild type when placed in stimulating solutions containing Na+, K+, or Ba2+. Behavioral adaptation to low levels of K+ also is indistinguishable from wild type. Flame photometry reveals that one mutant is unable to keep out K+ and Na+ when those ions are at low levels in the medium. Both mutants have markedly lower internal Na+ than does wild type. Problems with K+ permeability account for the sensitivity of the one mutant to elevated external K+, but the basis of sensitivity in the other mutant is unclear. These mutants expand the range of ion regulation mutants in Paramecium and demonstrate that lesions in cellular ion regulation in this organism need not result in changes in swimming behavior.

Calcium-mediated inactivation of calcium current in Paramecium

1. The Ca current seen in response to depolarization was investigated in Paramecium caudatum under voltage clamp. Inactivation of the current was measured with the double pulse method; a fixed test pulse of an amplitude sufficient to evoke maximal inward current was preceded by a conditioning pulse of variable amplitude (0-120 mV).2. The amplitude of the current recorded during the test pulse was related to the potential of the conditioning pulse. Reduction of test pulse current was taken as an index of Ca current inactivation. The current recorded during a test pulse showed a progressive decrease to a minimum as the potential of the conditioning pulse approached +10 to +30 mV. Further increase in conditioning pulse amplitude was accompanied by a progressive restoration of the test pulse current. Conditioning pulses near the calcium equilibrium potential had only a slight inactivating effect on the test pulse current.3. Injection of a mixture of Cs and TEA which blocked late outward current had essentially no effect on the inward current or its inactivation.4. Elevation of external Ca from 0.5 to 5 mM was accompanied by increased inactivation of the test pulse current. The enhanced inactivation of the test pulse current was approximately proportional to the increase in current recorded during the conditioning pulse.5. Following injection of the Ca chelating agent, EGTA, the inactivation of the test pulse current was diminished; in addition, the transient inward current relaxed slightly more slowly, and the transient was followed by a steady net inward current.6. The time course of recovery from inactivation in the double pulse experiment approximated a single exponential having a time constant of 80-110 msec. Injection of EGTA shortened the time constant by as much as 50%.7. It is concluded that interference with the entry of Ca or enhanced removal of intracellular free Ca(2+) interferes with the process of Ca current inactivation, while enhanced entry of Ca promotes the process of inactivation. While the mechanism of inactivation is unknown, arguments are presented that the accumulation of intracellular Ca influences the Ca channel conductance.