Ca2+ transport and chemoreception in Paramecium

Intracellular Ca²⁺ levels in Paramecium must be tightly controlled, yet little is understood about the mechanisms of control. We describe here indirect evidence that a phosphoenzyme intermediate is the calmodulin-regulated plasma membrane Ca²⁺ pump and that a Ca²⁺-ATPase activity in pellicles (the complex of cell body surface membranes) is the enzyme correlate of the plasma membrane pump protein. A change in Ca²⁺ pump activity has been implicated in the chemoresponse of paramecia to some attractant stimuli. Indirect support for this is demonstrated using mutants with different modifications of calmodulin to correlate defects in chemoresponse with altered Ca²⁺ homeostasis and pump activity.Abbreviations EGTA ethyleneglycol tetra-acetate - ER endoplasmic reticulum - IBMX isobutyl methylxanthine - I _che index of chemokinesis - Mops 3-[N-morpholino] propanesulfonic acid - PEI phosphoenzyme intermediate - STEN sucrose, TRIS, EDTA, sodium chloride - TCA trichloroacetic acid - TRIS tris[hydroxymethyl] aminomethane     

Paramecium Na+ channels activated by Ca2+-calmodulin: Calmodulin is the Ca2+ sensor in the channel gating mechanism

Paramecium Na⁺ channels, which were Ca²⁺-calmodulin activated, were studied in the inside-out mode of patch clamp. After excision of the membrane patch, they were active in the presence of 10^–5 to 10^–3 m Ca²⁺ in the bath. They became much less active in the presence of 10^–6 m Ca²⁺, and their activity subsided completely at 10^–8 m Ca²⁺. A Hill plot showed a dissociation constant of 6 m for Ca²⁺ binding. This dissociation constant shifted to a submicromolar range in the presence of 1 mm Mg²⁺. The channels also exhibited a mild voltage dependence. When exposed to 10^–8 m Ca²⁺ for an extended period of 2–4 min, channels were further inactivated even after bath Ca²⁺ was restored to 10^–4 m. Whereas neither high voltage (+100 mV) nor high Ca²⁺ (10^–3 m) was effective in reactivation of the inactive channels, addition of Paramecium wild-type calmodulin together with high Ca²⁺ to the bath restored channel activity without a requirement of additional Mg²⁺ and metabolites such as ATP. The channels reactivated by calmodulin had the same ion conductance, ion selectivity and Ca²⁺ sensitivity as those prior to inactivation. These inactivation and reactivation of the channels could be repeated, indicating that the direct calmodulin effect on the Na⁺ channel was reversible. Thus, calmodulin is a physiological factor critically required for Na⁺ channel activation, and is the Ca²⁺ sensor of the Na⁺-channel gating machinery.We thank C. Kung for his kind support, and A. Boileau for critical reading. Supported by grants from National Institutes of Health GM 22714-20 and 36386-09.     

Physical coupling between ryanodine receptor-calcium release channels

Ryanodine receptor-calcium release channels play a pivotal role in the calcium signaling that mediates muscle excitation-contraction coupling. Their membrane organization into regular patterns, functional gating studies and theoretical analysis of receptor clustering have led to models that invoke allosteric interaction between individual channel oligomers as a critical mechanism for control of calcium release. Here we show that in reconstituted "checkerboard-like" lattices that mimic in situ membrane channel arrays, each oligomer is interlocked physically with four adjacent oligomers via a specific domain-domain interaction. Direct physical coupling between ryanodine receptors provides structural evidence for an inter-oligomer allosteric mechanism in channel regulation. Therefore, in addition to established cytosolic and luminal regulation of function, these observations indicate that channel-channel communication through physical coupling provides a novel mode of regulation of intracellular calcium release channels.     

Functional reconstitution of photosystem I reaction center from cyanobacteriumSynechocystis sp PCC6803 into liposomes using a new reconstitution procedure

Photosystem I reaction center from the cyanobacteriumSynechocystis sp PCC6803 was reconstituted into phosphatidylcholine/phosphatidic acid liposomes. Liposomes prepared by reversephase evaporation were treated with various amounts of different detergents and protein incorporation was analyzed at each step of the solubilization process. After detergent removal the activities of the resulting proteoliposomes were measured. The most efficient reconstitution was obtained by insertion of the protein complex into preformed liposomes destabilized by saturating amounts of octylglucoside. In the presence of N-methylphenazonium methosulfate and ascorbic acid, liposomes containing the reaction center catalyzed a light-dependent net H⁺ uptake as measured by the 9-aminoacridine fluorescence quenching and the pH meter. An important benefit of the new reconstitution procedure is that it produces a homogeneous population of large-size proteoliposomes with a low ionic permeability and with a majority inwardly directed H⁺ transport activity. In optimal conditions, a light-induced pH of about 1.8 units could be sustained at 20C in the presence of valinomycin. In the absence of valinomycin, a back-pressure effect of an electrical transmembrane potential decreased both the rate and the extent of the H⁺ transport. The reaction center was also co-reconstituted with F₀F₁ H⁺-ATPases from chloroplasts and from the thermophilic bacterium, PS3. The coreconstituted system was shown to catalyze a light-dependent phosphorylation which could only be measured in the presence of a high concentration of PSI (low lipid/PSI ratios) while no pH could be detected.     

Sub-second calcium coupling between outside medium and subplasmalemmal stores during overstimulation/depolarisation-induced ciliary beat reversal in Paramecium cells

As amply documented by electrophysiology, depolarisation in Paramecium induces a Ca(2+) influx selectively via ciliary voltage-dependent Ca(2+)-channels, thus inducing ciliary beat reversal. Subsequent downregulation of ciliary Ca(2+) has remained enigmatic. We now analysed this aspect, eventually under overstimulation conditions, by quenched-flow/cryofixation, combined with electron microscope X-ray microanalysis which registers total calcium concentrations, [Ca]. This allows to follow Ca-signals within a time period (> or =30ms) smaller than one ciliary beat ( approximately 50ms) and beyond. Particularly under overstimulation conditions ( approximately 10(-5)M Ca(2+) before, 0.5mM Ca(2+) during stimulation) we find in cilia a [Ca] peak at approximately 80ms and its decay to near-basal levels within 110ms (90%) to 170ms (100% decay). This [Ca] wave is followed, with little delay, by a [Ca] wave into subplasmalemmal Ca-stores (alveolar sacs), culminating at approximately 100ms, with a decay to original levels within 170ms. Also with little delay [Ca] slightly increases in the cytoplasm below. This implies rapid dissipation of Ca(2+) through the ciliary basis, paralleled by a rapid, transient uptake by, and release from cortical stores, suggesting fast exchange mechanisms to be analysed as yet. This novel type of coupling may be relevant for some phenomena described for other cells.     

Inhibition of Mg2+ current by single-gene mutation in Paramecium

Eccentric is a newly-isolated mutant of Paramecium tetraurelia that fails to swim backwards in response to Mg²⁺. In the wild type, this backward swimming results from Mg²⁺ influx via a Mg²⁺-specific ion conductance (I _Mg. Voltage-clamp analysis confirmed that, as suspected, step changes in membrane potential over a physiological range fail to elicit I _Mg from eccentric. Further electrophysiological investigation revealed a number of additional ion-current defects in eccentric: (i) The Ca²⁺ current activated upon depolarization inactivates more slowly in eccentric than in the wild type, and it requires longer to recover from this inactivation. (ii) The Ca²⁺-dependent Na⁺ current deactivates significantly faster in the mutant, (iii) The two K⁺ currents observed upon hyperpolarization are reduced by >60% in eccentric. It is difficult to envision how these varied pleiotropic effects could result from loss of a single ion current. Rather, they suggest that the eccentric mutation affects a global regulatory system. Two plausible hypotheses are discussed.We are grateful to Dr. Yoshiro Saimi for his comments and suggestions on this work, and for the support of the Lucille P. Markey Charitable trust and the National Institutes of Health (GM22714 and GM38646).     

Reconstitution and regulation of cation-selective channels from cardiac sarcoplasmic reticulum

In order to study the conductances of the Sarcoplasmic Reticulum (SR) membrane, microsomal fractions from cardiac SR were isolated by differential and sucrose gradient centrifugations and fused into planar lipid bilayers (PLB) made of phospholipids. Using either KCl or K-gluconate solutions, a large conducting K+ selective channel was characterized by its ohmic conductance (152 pS in 150 mM K⁺), and the presence of short and long lasting subconducting states. Its open probability P_o increased with depolarizing voltages, thus supporting the idea that this channel might allow counter-charge movements of monovalent cations during rapid SR Ca²⁺ release. An heterogeneity in the kinetic behavior of this channel would suggest that the cardiac SR K⁺ channels might be regulated by cytoplasmic, luminal, or intra SR membrane biochemical mechanisms. Since the behavior was not modified by variations of [Ca²⁺] nor by the addition of soluble metabolites such as ATP, GTP, cAMP, cGMP, nor by phosphorylation conditions on both sides of the PLB, a specific interaction with a SR membrane component is postulated. Another cation selective channel was studied in asymmetric Ca²⁺, Ba²⁺ or Mg²⁺-HEPES buffers. This channel displayed large conductance values for the above divalent cations 90, 100, and 40 pS, respectively. This channel was activated by µM Ca²⁺ while its Ca²⁺ sensitivity was potentiated by millimolar ATP. However Mg²⁺ and calmodulin modulated its gating behavior. Ca²⁺ releasing drugs such as caffeine and ryanodine increased its P_o. All these features are characteristics of the SR Ca²⁺ release channel. The ryanodine receptor which has been purified and reconstituted into PLB, may form a cation selective pathway. This channel displays all the regulatory sites of the native cardiac SR Ca²⁺ release channel. However, when NA was used as charge carrier, multiple subconducting states were observed. In conclusion, the reconstitution experiments have yield a great deal of informations about the biochemical and biophysical events that may regulated the ionic flux across the SR membrane.     

Regulation of neuronal ion channels via P2Y receptors

Within the last 15 years, at least 8 different G protein-coupled P2Y receptors have been characterized. These mediate slow metabotropic effects of nucleotides in neurons as well as non-neural cells, as opposed to the fast ionotropic effects which are mediated by P2X receptors. One class of effector systems regulated by various G protein-coupled receptors are voltage-gated and ligand-gated ion channels. This review summarizes the current knowledge about the modulation of such neuronal ion channels via P2Y receptors. The regulated proteins include voltage-gated Ca²⁺ and K⁺ channels, as well as N-methyl-d-aspartate, vanilloid, and P2X receptors, and the regulating entities include most of the known P2Y receptor subtypes. The functional consequences of the modulation of ion channels by nucleotides acting at pre- or postsynaptic P2Y receptors are changes in the strength of synaptic transmission. Accordingly, ATP and related nucleotides may act not only as fast transmitters (via P2X receptors) in the nervous system, but also as neuromodulators (via P2Y receptors). Hence, nucleotides are as universal transmitters as, for instance, acetylcholine, glutamate, or -aminobutyric acid.     

Both N- and C-lobes of calmodulin are required for Ca-dependent regulations of CaV1.2 Ca channels

We investigated the concentration- and Ca²⁺-dependent effects of CaM mutants, CaM₁₂ and CaM₃₄, in which Ca²⁺-binding to its N- and C-lobes was eliminated, respectively, on the Ca_V1.2 Ca²⁺ channel by inside-out patch clamp in guinea-pig cardiomyocytes. Both CaM₁₂ and CaM₃₄ (0.7-10 μM) applied with 3 mM ATP produced channel activity after “rundown”. Concentration-response curves were bell-shaped, similar to that for wild-type CaM. However, there was no obvious leftward shift of the curves by increasing [Ca²⁺], suggesting that both functional lobes of CaM were necessary for the Ca²⁺-dependent shift. However, channel activity induced by the CaM mutants showed Ca²⁺-dependent decrease, implying a Ca²⁺ sensor existing besides CaM. These results suggest that both N- and C-lobes of CaM are required for the Ca²⁺-dependent regulations of Ca_V1.2 Ca²⁺ channels.     

Functional triads consisting of ryanodine receptors, Ca(2+) channels, and Ca(2+)-activated K(+) channels in bullfrog sympathetic neurons. Plastic modulation of action potential

Fluorescent ryanodine revealed the distribution of ryanodine receptors in the submembrane cytoplasm (less than a few micrometers) of cultured bullfrog sympathetic ganglion cells. Rises in cytosolic Ca(2+) ([Ca(2+)](i)) elicited by single or repetitive action potentials (APs) propagated at a high speed (150 microm/s) in constant amplitude and rate of rise in the cytoplasm bearing ryanodine receptors, and then in the slower, waning manner in the deeper region. Ryanodine (10 microM), a ryanodine receptor blocker (and/or a half opener), or thapsigargin (1-2 microM), a Ca(2+)-pump blocker, or omega-conotoxin GVIA (omega-CgTx, 1 microM), a N-type Ca(2+) channel blocker, blocked the fast propagation, but did not affect the slower spread. Ca(2+) entry thus triggered the regenerative activation of Ca(2+)-induced Ca(2+) release (CICR) in the submembrane region, followed by buffered Ca(2+) diffusion in the deeper cytoplasm. Computer simulation assuming Ca(2+) release in the submembrane region reproduced the Ca(2+) dynamics. Ryanodine or thapsigargin decreased the rate of spike repolarization of an AP to 80%, but not in the presence of iberiotoxin (IbTx, 100 nM), a BK-type Ca(2+)-activated K(+) channel blocker, or omega-CgTx, both of which decreased the rate to 50%. The spike repolarization rate and the amplitude of a single AP-induced rise in [Ca(2+)](i) gradually decreased to a plateau during repetition of APs at 50 Hz, but reduced less in the presence of ryanodine or thapsigargin. The amplitude of each of the [Ca(2+)](i) rise correlated well with the reduction in the IbTx-sensitive component of spike repolarization. The apamin-sensitive SK-type Ca(2+)-activated K(+) current, underlying the afterhyperpolarization of APs, increased during repetitive APs, decayed faster than the accompanying rise in [Ca(2+)](i), and was suppressed by CICR blockers. Thus, ryanodine receptors form a functional triad with N-type Ca(2+) channels and BK channels, and a loose coupling with SK channels in bullfrog sympathetic neurons, plastically modulating AP.     

Activation of Ca(2+)-dependent K(+) channels contributes to rhythmic firing of action potentials in mouse pancreatic beta cells

We have applied the perforated patch whole-cell technique to beta cells within intact pancreatic islets to identify the current underlying the glucose-induced rhythmic firing of action potentials. Trains of depolarizations (to simulate glucose-induced electrical activity) resulted in the gradual (time constant: 2.3 s) development of a small (<0.8 nS) K(+) conductance. The current was dependent on Ca(2+) influx but unaffected by apamin and charybdotoxin, two blockers of Ca(2+)-activated K(+) channels, and was insensitive to tolbutamide (a blocker of ATP-regulated K(+) channels) but partially (>60%) blocked by high (10-20 mM) concentrations of tetraethylammonium. Upon cessation of electrical stimulation, the current deactivated exponentially with a time constant of 6.5 s. This is similar to the interval between two successive bursts of action potentials. We propose that this Ca(2+)-activated K(+) current plays an important role in the generation of oscillatory electrical activity in the beta cell.     

Functional coupling of Ca(2+) channels to ryanodine receptors at presynaptic terminals. Amplification of exocytosis and plasticity

Ca(2+)-induced Ca(2+) release (CICR) enhances a variety of cellular Ca(2+) signaling and functions. How CICR affects impulse-evoked transmitter release is unknown. At frog motor nerve terminals, repetitive Ca(2+) entries slowly prime and subsequently activate the mechanism of CICR via ryanodine receptors and asynchronous exocytosis of transmitters. Further Ca(2+) entry inactivates the CICR mechanism and the absence of Ca(2+) entry for >1 min results in its slow depriming. We now report here that the activation of this unique CICR markedly enhances impulse-evoked exocytosis of transmitter. The conditioning nerve stimulation (10-20 Hz, 2-10 min) that primes the CICR mechanism produced the marked enhancement of the amplitude and quantal content of end-plate potentials (EPPs) that decayed double exponentially with time constants of 1.85 and 10 min. The enhancement was blocked by inhibitors of ryanodine receptors and was accompanied by a slight prolongation of the peak times of EPP and the end-plate currents estimated from deconvolution of EPP. The conditioning nerve stimulation also enhanced single impulse- and tetanus-induced rises in intracellular Ca(2+) in the terminals with little change in time course. There was no change in the rate of growth of the amplitudes of EPPs in a short train after the conditioning stimulation. On the other hand, the augmentation and potentiation of EPP were enhanced, and then decreased in parallel with changes in intraterminal Ca(2+) during repetition of tetani. The results suggest that ryanodine receptors exist close to voltage-gated Ca(2+) channels in the presynaptic terminals and amplify the impulse-evoked exocytosis and its plasticity via CICR after Ca(2+)-dependent priming.     

Plasma membrane Ca2+ channels in roots of higher plants and their role in aluminium toxicity

Single Ca²⁺ channel records were obtained from plasma membrane-enriched fractions of wheat roots incorporated into artificial planar lipid bilayers. The channel had a unitary conductance of 15 pS for a 10 to 95 mM CaCl₂ gradient (cytoplasm: outside of the cell). The voltage dependence displayed by the channel agreed with that expected for Ca²⁺ channels in the plasma membrane. The channel gating was strongly modified by addition of 20 M extracellular verapamil (a Ca²⁺ channel antagonist). Extracellular AlCl₃ (70 M, pH 4.9) almost completely blocked the channel.     

Decalmodulation of Cav1 channels by CaBPs

Ca²⁺-dependent inactivation (CDI) is a negative feedback regulation of voltage-gated Ca_v1 and Ca_v2 channels that is mediated by the Ca²⁺ sensing protein, calmodulin (CaM), binding to the pore-forming Ca_v α₁ subunit. David Yue and his colleagues made seminal contributions to our understanding of this process, as well as factors that regulate CDI. Important in this regard are members of a family of Ca²⁺ binding proteins (CaBPs) that are related to calmodulin. CaBPs are expressed mainly in neural tissues and can antagonize CaM-dependent CDI for Ca_v1 L-type channels. This review will focus on the roles of CaBPs as Ca_v1-interacting proteins, and the significance of these interactions for vision, hearing, and neuronal Ca²⁺ signaling events.     

Reconstitution of sodium channels in large liposomes formed by the addition of acidic phospholipids and freeze-thaw sonication

Phosphatidylcholine (PC) alone or with phosphatidylethanolamine (PE) are sufficient for the reconstitution of Na+ channels in planar lipid bilayers. However, when Na+ channels were first reconstituted into liposomes using the freeze-thaw-sonication method, addition of acidic phospholipids, such as phosphatidylserine (PS), to the neutral phospholipids was necessary to obtain a significant toxin-modulated 22Na uptake. To further investigate the acidic phospholipid effect on reconstitution into liposomes, Na+ channels purified from Electrophorus electricus electrocytes were reconstituted into liposomes of different composition by freeze-thaw sonication and the effect of batrachotoxin and tetrodotoxin on the 22Na flux was measured. The results revealed that, under our experimental conditions, the presence of an acidic phospholipid was also necessary to obtain a significant neurotoxin-modulated 22Na influx. Though neurotoxin-modulated 22Na fluxes have been reported in proteoliposomes made with purified Na+ channels and PC alone, the 22Na fluxes were smaller than those found using lipid mixtures containing acidic phospholipids. Electron microscopy of negatively stained proteoliposomes prepared with PC, PC/PS (1:1 molar ratio), and PS revealed that the acidic phospholipid increases the size of the reconstituted proteoliposomes. The increment in size caused by the acidic phospholipid, due to the associated increase in internal volume for 22Na uptake and in area for Na+ channel incorporation, appears to be responsible for the large neurotoxin-modulated 22Na fluxes observed.     

Ion channels and anti-cancer immunity

The outcome of a malignant disease depends on the efficacy of the immune system to destroy cancer cells. Key steps in this process, for example the generation of a proper Ca²⁺ signal induced by recognition of a specific antigen, are regulated by various ion channel including voltage-gated Kv1.3 and Ca²⁺-activated KCa3.1 K⁺ channels, and the interplay between Orai and STIM to produce the Ca²⁺-release-activated Ca²⁺ (CRAC) current required for T-cell proliferation and function. Understanding the immune cell subset-specific expression of ion channels along with their particular function in a given cell type, and the role of cancer tissue-dependent factors in the regulation of operation of these ion channels are emerging questions to be addressed in the fight against cancer disease. Answering these questions might lead to a better understanding of the immunosuppression phenomenon in cancer tissue and the development of drugs aimed at skewing the distribution of immune cell types towards killing of the tumour cells.     

Proteolytic activation of a hyperpolarization- and calcium-dependent potassium channel inParamecium

Summary The effects of proteolysis on a hyperpolarization- and Ca²⁺-dependent K channel from the surface membrane ofParamecium tetraurelia were examined in the inside-out excised patch mode. Treatment with trypsin, pronase or thermolysin removed the Ca²⁺-dependence of the channel activation, yielding an increase in channel activity greater than 2.5-fold at all Ca²⁺ concentrations between 10^–4 and 10^–8 m. Thermolysin addition-ally removed the voltage dependence of channel opening and gave the most activation among the three proteases tested. Proteolysis did not affect the single-channel conductance. In an analogy to the mechanism of activation of many Ca²⁺-dependent enzymes it is suggested that thisParamecium channel has a cytoplasmic inhibitory domain which can be removed by proteolysis, and that the physiological activation by Ca²⁺ is due to a temporary removal of this inhibition. Moreover, these findings indicate structural differences between depolarization-, Ca²⁺-dependent K channels (BK channels) and the hyperpolarization-, Ca²⁺-dependent K channels inParamecium.     

Aminoglycoside blockade of Ca2+-activated K+ channel from rat brain synaptosomal membranes incorporated into planar bilayers

Summary Ca²⁺-activated K⁺ channels from rat brain synaptosomal membranes were incorporated into planar lipid bilayers, and the effects of aminoglycoside antibiotics on the single channel conductance (258±13 pS at 100mm K⁺) were investigated. Aminoglycosides reduced the single channel conductance from the cis (cytoplasmic) side in a dose- and voltage-dependent manner. Voltage dependence of the blockade indicated an interaction between positively charged amino residues of aminoglycoside antibiotics and a binding site located within the electric field of the ion-conducting pathway. The order of blocking potency was consistent with that of the number of amino residues of aminoglycosides (neomycin (6)>dibekacin (5)>ribostamycin (4)=kanamycin (4)), while the electrical distance (z=0.46–0.49) of the binding site kept almost constant for each drug. Thesezs were almost the same with those (0.46–0.51) of alkyldiamine blockers with two amino residues (total net charge of +2) and approximately twice of those (0.25–0.26) of alkylmonoamine blockers (total net charge of +1). Assuming that amino residues of aminoglycosides and alkylamines shared the same binding site located at 25% voltage drop from the cytoplasmic surface of the channel, the site would have to be at least large enough to accommodate one diamino sugar residue of the aminoglycoside in order to simultaneously interact with two positively charged amino groups. Dose- and voltage-dependent blockade of the channel by gallamine, an extremely bulky trivalent organic cation, supported the picture that the channel has a wide mouth on the cytoplasmic side and its pore region, where voltage drop occurs, may also be quite wide and nonselective, suddenly tapering to a constriction where most charged cations block the channel by occluding the K⁺-conducting pathway.     

K<Superscript>+</Superscript>-induced Ca<Superscript>2+</Superscript> Conductance Responsible for the Prolonged Backward Swimming in K<Superscript>+</Superscript>-agitated Mutant of <Emphasis Type="Italic">Paramecium caudatum</Emphasis>

The K⁺-agitated (Kag) mutant of Paramecium caudatum shows prolonged backward swimming in K⁺-rich solution. To understand the regulation mechanisms of the ciliary motility in P. caudatum, we examined the membrane electrical properties of the Kag mutant. The duration of the backward swimming of the Kag in K⁺-rich solution was about 10 times longer than that of the wild type. In response to an injection of the outward current, the wild type produced an initial action potential and a subsequent membrane depolarization due to I-R potential drop, while the Kag exhibited repetitive action potentials during the depolarization. Under voltage-clamp conditions, the depolarization-activated transient inward current exhibited by the Kag was slightly smaller than that exhibited by the wild type. In response to an application of K⁺-rich solution, both the wild type and the Kag exhibited a depolarizing afterpotential representing the activation of the K⁺-induced Ca²⁺ conductance. The inactivation time course of the K⁺-induced Ca²⁺ conductance of Kag was about 10 times longer than that of the wild type. This difference corresponds well with the difference in behavioral responses between Kag and wild type to K⁺-rich solution. We conclude that the overreaction of the Kag mutant to the K⁺-rich solution is caused by slowing down of the inactivation of the K⁺-induced Ca²⁺ conductance.