Pannexin channels in ATP release and beyond: An unexpected rendezvous at the endoplasmic reticulum

The pannexin (Panx) family of proteins, which is co-expressed with connexins (Cxs) in vertebrates, was found to be a new GJ-forming protein family related to invertebrate innexins. During the past ten years, different studies showed that Panxs mainly form hemichannels in the plasma membrane and mediate paracrine signalling by providing a flux pathway for ions such as Ca²⁺, for ATP and perhaps for other compounds, in response to physiological and pathological stimuli. Although the physiological role of Panxs as a hemichannel was questioned, there is increasing evidence that Panx play a role in vasodilatation, initiation of inflammatory responses, ischemic death of neurons, epilepsy and in tumor suppression. Moreover, it is intriguing that Panxs may also function at the endoplasmic reticulum (ER) as intracellular Ca²⁺-leak channel and may be involved in ER-related functions. Although the physiological significance and meaning of such Panx-regulated intracellular Ca²⁺ leak requires further exploration, this functional property places Panx at the centre of many physiological and pathophysiological processes, given the fundamental role of intracellular Ca²⁺ homeostasis and dynamics in a plethora of physiological processes. In this review, we therefore want to focus on Panx as channels at the plasma membrane and at the ER membranes with a particular emphasis on the potential implications of the latter in intracellular Ca²⁺ signalling.     

Reversible changes of extracellular pH during action potential generation in a higher plant Cucurbita pepo

A pH-sensitive electrode was applied to measure activity of H⁺ ions in the medium surrounding excitable cells of pumpkin (Cucurbita pepo L.) seedlings during cooling-induced generation of action potential (AP). Reversible alkalization shifts were found to occur synchronously with AP, which could be due to the influx of H⁺ ions from external medium into excitable cells. Ethacrynic acid (an anion channel blocker) reduced the AP amplitude but had no effect on the transient alkalization of the medium. An inhibitor of plasma membrane H⁺-ATPase, N,N’-dicyclohexylcarbodiimide suppressed both the AP amplitude and the extent of alkalization. In experiments with plasma membrane vesicles, the hydrolytic H⁺-ATPase activity was subjected to inhibition by Ca²⁺ concentrations in the range characteristic of cytosolic changes during AP generation. The addition of a calcium channel blocker verapamil and a chelating agent EGTA to inhibit Ca²⁺ influx from the medium eliminated the AP spike and diminished reversible alkalization of the external solution. An inhibitor of protein kinase, H-7 alleviated the inhibitory effect of Ca²⁺ on hydrolytic H⁺-ATPase activity in plasma membrane vesicles and suppressed the reversible alkalization of the medium during AP generation. The results provide evidence that the depolarization phase of AP is associated not only with activation of chloride channels and Cl^? efflux but also with temporary suppression of plasma membrane H⁺-ATPase manifested as H⁺ influx. The Ca²⁺-induced inhibition of the plasma membrane H⁺-ATPase is supposedly mediated by protein kinases.     

Ca signaling and STIM1

An increase in the intracellular calcium ion concentration ([Ca²⁺]) impacts a diverse range of cell functions, including adhesion, motility, gene expression and proliferation. Elevation of intracellular calcium ion (Ca²⁺) regulates various cellular events after the stimulation of cells. Initial increase in Ca²⁺ comes from the endoplasmic reticulum (ER), intracellular storage space. However, the continuous influx of extracellular Ca²⁺ is required to maintain the increased level of Ca²⁺ inside cells. Store-operated Ca²⁺ entry (SOCE) manages this process, and STIM1, a newly discovered molecule, has a unique and essential role in SOCE. STIM1 can sense the exhaustion of Ca²⁺ in the ER, and activate the SOC channel in the plasma membrane, leading to the continuous influx of extracellular Ca²⁺. STIM1 senses the status of the intracellular Ca²⁺ stores via a luminal N-terminal Ca²⁺-binding EF-hand domain. Dissociation of Ca²⁺ from this domain induces the clustering of STIM1 to regions of the ER that lie close to the plasma membrane, where it regulates the activity of the store-operated Ca²⁺ channels/entry (calcium-release-activated calcium channels/entry). In this review, we summarize the mechanism by which STIM1 regulates SOCE, and also its role in the control of mast cell functions and allergic responses.     

Intracellular Ca(2+) oscillations induced by over-expressed Ca(V)3.1 T-type Ca(2+) channels in NG108-15 cells

T-type Ca²⁺ channel family includes three subunits Ca_V3.1, Ca_V3.2 and Ca_V3.3 and have been shown to control burst firing and intracellular Ca²⁺ concentration ([Ca²⁺]_i) in neurons. Here, we investigated whether Ca_V3.1 channels could generate a pacemaker current and contribute to cell excitability. Ca_V3.1 clones were over-expressed in the neuronal cell line NG108-15. Ca_V3.1 channel expression induced repetitive action potentials, generating spontaneous membrane potential oscillations (MPOs) and concomitant [Ca²⁺]_i oscillations. These oscillations were inhibited by T-type channels antagonists and were present only if the membrane potential was around −61 mV. [Ca²⁺]_i oscillations were critically dependent on Ca²⁺ influx through Ca_V3.1 channels and did not involve Ca²⁺ release from the endoplasmic reticulum. The waveform and frequency of the MPOs are constrained by electrophysiological properties of the Ca_V3.1 channels. The trigger of the oscillations was the Ca_V3.1 window current. This current induced continuous [Ca²⁺]_i increase at −60 mV that depolarized the cells and triggered MPOs. Shifting the Ca_V3.1 window current potential range by increasing the external Ca²⁺ concentration resulted in a corresponding shift of the MPOs threshold. The hyperpolarization-activated cation current (I_h) was not required to induce MPOs, but when expressed together with Ca_V3.1 channels, it broadened the membrane potential range over which MPOs were observed. Overall, the data demonstrate that the Ca_V3.1 window current is critical in triggering intrinsic electrical and [Ca²⁺]_i oscillations.     

Localization and regulation of Ca entry and exit pathways in exocrine gland cells

Studies of Ca²⁺ transport pathways in exocrine gland cells have been useful, chiefly because of the polarized nature of the secretory epithelial cells. In pancreatic acinar cells, for example, Ca²⁺ reloading of empty intracellular stores can occur solely via Ca²⁺ entry through the basal part of the plasma membrane. On the other hand, the principal site for intracellular Ca²⁺ release—with the highest concentration of inositol 1,4,5-trisphosphate (IP₃) receptors—is in the apical secretory pole close to the apical plasma membrane. This apical part of the plasma membrane contains the highest density of Ca²⁺ pumps and is therefore the principal site for Ca²⁺ extrusion. On the basis of the known properties of Ca²⁺ entry and exit pathways in exocrine gland cells, the mechanisms controlling Ca²⁺ exit and entry are discussed in relation to recent direct information about Ca²⁺ transport into and out of the endoplasmic reticulum (ER) and the mitochondria in these cells.     

Constitutively active calcium channels in plasma membrane of T-lymphocytes

Compensated influx and efflux of calcium ions maintain the constancy of Ca²⁺ concentration in cytoplasm of quiescent cells under variable external conditions. In cell plasma membrane there exist several types of Ca²⁺ channels with different properties, regulation mechanisms, and pharmacology. Using fluorescent Ca²⁺-sensitive probes, we have shown here that in T-lymphocytes under resting conditions, Ca²⁺ influx occurs through special constitutively active Ca²⁺ channels, permeable to Ni²⁺ and Mn²⁺. These channels differ from the receptor-activated SOC channels, from Ca²⁺ channels activated by arachidonic acid, and from calmidazolium-activated channels. Ca²⁺ influx rate in quiescent cells increases with a rise in temperature (Q₁₀ =1.9). The strong dependence of the constitutively active channel activity on temperature coincided with the plasma membrane Ca²⁺-ATPase dependence, indicating that intracellular enzymes regulate the channel activity. To identify the constitutively active channel, we analyzed the effects of L-type Ca²⁺ channels, SOC channels, Ca²⁺-independent phospholipase A2, and calmodulin inhibitors. Of all inhibitors listed only dihydropyridine blocker of L-type voltage-dependent Ca²⁺ channels, isradipin, at a concentration of 1.5 μM completely suppressed calcium influx. However, the channels did not exhibit sensitivity to changes in membrane potential. Our observations testify to the existence of a new nonselective Ca²⁺ channel in T-lymphocyte plasma membrane and characterize the new channels pharmacologically. The results obtained are important for understanding the regulation mechanisms of Ca²⁺ channels in plasma membrane of non-excitable cells.     

Permeation of Ca2+ through K+ channels in the plasma membrane of Vicia faba guard cells

Summary The whole-cell patch-clamp method has been used to measure Ca²⁺ influx through otherwise K⁺-selective channels in the plasma membrane surrounding protoplasts from guard cells of Vicia faba. These channels are activated by membrane hyperpolarization. The resulting K⁺ influx contributes to the increase in guard cell turgor which causes stomatal opening during the regulation of leaf-air gas exchange. We find that after opening the K⁺ channels by hyperpolarization, depolarization of the membrane results in tail current at voltages where there is no electrochemical force to drive K⁺ inward through the channels. Tail current remains when the reversal potential for permeant ions other than Ca²⁺ is more negative than or equal to the K⁺ equilibrium potential (–47 mV), indicating that the current is due to Ca²⁺ influx through the K⁺ channels prior to their closure. Decreasing internal [Ca²⁺] (Ca _i ) from 200 to 2 nm or increasing the external [Ca²⁺] (Ca _o ) from 1 to 10 mm increases the amplitude of tail current and shifts the observed reversal potential to more positive values. Such increases in the electrochemical force driving Ca²⁺ influx also decrease the amplitude of time-activated current, indicating that Ca²⁺ permeation is slower than K⁺ permeation, and so causes a partial block. Increasing Ca _o also (i) causes a positive shift in the voltage dependence of current, presumably by decreasing the membrane surface potential, and (ii) results in a U-shaped current-voltage relationship with peak inward current ca. –160 mV, indicating that the Ca^2– block is voltage dependent and suggesting that the cation binding site is within the electric field of the membrane. K⁺ channels in Zea mays guard cells also appear to have a Ca _i -, and Ca _o -dependent ability to mediate Ca²⁺ influx. We suggest that the inwardly rectiying K⁺ channels are part of a regulatory mechanism for Ca _i . Changes in Ca _o and (associated) changes in Ca _i regulate a variety of intracellular processes and ion fluxes, including the K⁺ and anion fluxes associated with stomatal aperture change.This work was supported by grants to S.M.A. from NSF (DCB-8904041) and from the McKnight Foundation. K.F.-G. is a Charles Gilbert Heydon Travelling Fellow. The authors thank Dr. R. MacKinnon (Harvard Medical School) and two anonymous reviewers for helpful comments.     

Role of voltage-dependent ionic currents in coupling glucose stimulation to insulin secretion in canine pancreatic islet B-Cells

Summary Glucose-induced electrical activity in canine pancreatic islet B cells is distinct from that in rodent islets, though both display Ca²⁺-dependent insulin secretion. Rodent islet B cells undergo regular bursts of Ca²⁺-dependent action potentials, while canine islet B cells generate isolated Na⁺-dependent action potentials which often give way to a plateau depolarization. Here we present evidence to reconcile the species difference in electrical activity with the similarity of Ca²⁺ dependence of secretion. (i) In canine B cells increasing glucose concentrations produce membrane depolarization and increasing frequency of Na_o-dependent action potentials until a background membrane potential (-40mV) is reached where Na⁺ currents are inactivated. (ii) Voltage-dependent Ca²⁺ currents are present which are activated over the voltage excursion of the action potential (–50 to +20 mV) and inactivate slowly, (over seconds) in the range of the plateau depolarization (–40 to –25 mV). Hence, they are available to contribute to both phases of depolarization. (iii) Tetrodotoxin (TTX) reduces by half an early transient phase of glucosestimulated insulin secretion but not a subsequent prolonged plateau phase. The transient phase of secretion often corresponds well in time to the period of initial high frequency action potential activity. These latter results suggest that in canine B cells voltagedependent Na⁺ and Ca²⁺ currents mediate biphasic glucose-induced insulin secretion. The early train of Na⁺-dependent action potentials, by transiently activating Ca²⁺ channels and allowing pulsatile Ca²⁺ entry, may promote an early transient phase of insulin secretion. The subsequent sustained plateau depolarization, by allowing sustained Ca²⁺ entry, may permit steady insulin release.     

(Questions) on phloem biology. 1. Electropotential waves, Ca fluxes and cellular cascades along the propagation pathway

This review explores the relationships between electrical long-distance signalling, Ca²⁺ influx coincident with propagation of electropotential waves, and cellular responses to Ca²⁺ influx including the consequences for sieve-tube conductivity and mass flow. Ca²⁺ influx is inherent to electropotential waves and appears to constitute the key link between rapid physical signals and resultant chemical cascades in sieve tubes and adjacent cells. Members of several channel groups are likely involved the regulation of Ca²⁺ levels in sieve elements. Among them are hyperpolarization-activated, depolarization-activated, and mechanosensitive Ca²⁺ channels located in the plasma membrane and Ca²⁺ dependent Ca²⁺ channels that reside in ER-membranes of sieve elements. These channels collectively determine intracellular Ca²⁺ levels in sieve elements and their neighbour cells. The latter cells react to Ca²⁺ elevation by inducing diverse functional responses dependent on the cell type. If the Ca²⁺ concentration in sieve elements surpasses a threshold level, dual sieve-plate occlusion by proteins and callose deposition is triggered. Occlusion is reversed when Ca²⁺ levels subside. Electrical messages may regulate the degree of sieve plate hydraulic conductivity in intact plants by partial sieve-plate occlusion that has a major impact on volume flow through sieve tubes. Furthermore, complete but temporary occlusion of sieve tubes may modify mass flow patterns in intact plants.     

Spontaneous inactivation of the Ca-sensitive K channels of human red cells at high intracellular Ca activity

Ionophore A23187-mediated Ca²⁺-induced oscillations in the conductance of the Ca²⁺-sensitive K⁺ channels of human red cells were monitored with ion specific electrodes. The membrane potential was continuously reflected in CCCP-mediated pH changes in the buffer-free medium, changes in extracellular K⁺ activity were followed with a K⁺-selective electrode, and changes in the intracellular concentration of ionized calcium were calculated on the basis of cellular ⁴⁵Ca content. An increased cellular ⁴⁵Ca content at the successive minima of the oscillations where the K⁺ channels are closed indicates that the activation of the channels might be a (dCa²⁺/dt)-sensitive process and that accommodation to enhanced levels of intracellular free calcium may occur. An incipient inactivation of the K⁺ channels at intracellular ionized calcium levels of about 10 μM and a concurrent membrane potential of about −65 mV was observed. At a membrane potential of about −70 mV and an intracellular concentration of about 2·10⁻⁴M no inactivation of K⁺ channels took place. Inactivation of the K⁺ channels is suggested to be a compound function of the intracellular level of free calcium and the membrane potential. The observed sharp peak values in cellular ⁴⁵Ca content support the notion that a necessary component of the oscillatory system is a Ca²⁺ pump operating with a significant delay in the activation/inactivation process in response to changes in cellular concentration of ionized calcium.     

Calcium channels and signal transduction in plant cells

An increasing number of studies indicate that changes in cytosolic free Ca²⁺ ([Ca²⁺]_c) mediate specific types of signal transduction in plant cells. Modulation of [Ca²⁺]_c is likely to be achieved through changes in the activity of Ca²⁺ channels, which catalyse passive influx of Ca²⁺ to the cytosol from extracellular and intracellular compartments. Voltage-sensitive Ca²⁺ channels have been detected in the plasma membranes of algae, where they control membrane electrical properties and cell turgor. These channels are sensitive to 1,4-dihydropyridines, which in animal cells specifically affect one class of voltage-regulated plasma membrane Ca²⁺ channel. Ca²⁺-permeable channels with different pharmacological properties have been found in the plasma membrane of higher plants. Recent evidence suggests the existence of two discrete classes of Ca²⁺ channel co-resident in the vacuolar membrane (tonoplast) of higher plants. The first is gated by inositol 1,4,5-trisphosphate, and bears a number of similarities to its animal counterpart which is located in the endoplasmic reticulum (ER). The second tonoplast Ca²⁺ channel is voltage-operated. However, the specific roles of these tonoplast channels in signal transduction have yet to be elucidated.     

Intracellular Monovalent Ions as Second Messengers

It is generally accepted that electrochemical gradients of monovalent ions across the plasma membrane, created by the coupled function of pumps, carriers and channels, are involved in the maintenance of resting and action membrane potential, cell volume adjustment, intracellular Ca²⁺ handling and accumulation of glucose, amino acids, nucleotides and other precursors of macromolecular synthesis. In the present review, we summarize data showing that side-by-side with these classic functions, modulation of the intracellular concentration of monovalent ions in a physiologically reasonable range is sufficient to trigger numerous cellular responses, including changes in enzyme activity, gene expression, protein synthesis, cell proliferation and death. Importantly, the engagement of monovalent ions in regulation of the above-listed cellular responses occurs at steps upstream of Ca²⁺ _i and other key intermediates of intracellular signaling, which allows them to be considered as second messengers. With the exception of HCO ₃ ⁻ -sensitive soluble adenylyl cyclase, the molecular origin of sensors involved in the function of monovalent ions as second messengers remains unknown.     

The effect of exogenous Ca2+ ions on pollen grain germination and pollen tube growth

Summary The involvement of exogenous calcium ions in the regulation of pollen tube formation has been investigated in Haemanthus albiflos L. and Oenothera biennis L. by following the changes that occur in pollen germination, tube growth, and ⁴⁵⁺Ca²⁺ uptake and distribution upon application of Verapamil (an inhibitor of calcium channels), lanthanum (a Ca²⁺ substitute), and ruthenium red (believed to raise the intracellular calcium level). It was found that exogenous Ca²⁺ takes part in the formation of the calcium gradient present in germinating pollen grains and growing pollen tubes. Ca²⁺ ions enter the cells through calcium channels. Raising or reducing ⁴⁵Ca²⁺ uptake causes disturbances in the germination of the pollen grains and in the growth of the pollen tubes.     

A dynamic model of saliva secretion

We construct a mathematical model of the parotid acinar cell with the aim of investigating how the distribution of K⁺ and Cl⁻ channels affects saliva production. Secretion of fluid is initiated by Ca²⁺ signals acting on Ca²⁺ dependent K⁺ and Cl⁻ channels. The opening of these channels facilitates the movement of Cl⁻ ions into the lumen which water follows by osmosis. We use recent results into both the release of Ca²⁺ from internal stores via the inositol (1,4,5)-trisphosphate receptor (IP₃R) and IP₃ dynamics to create a physiologically realistic Ca²⁺ model which is able to recreate important experimentally observed behaviours seen in parotid acinar cells. We formulate an equivalent electrical circuit diagram for the movement of ions responsible for water flow which enables us to calculate and include distinct apical and basal membrane potentials to the model. We show that maximum saliva production occurs when a small amount of K⁺ conductance is located at the apical membrane, with the majority in the basal membrane. The maximum fluid output is found to coincide with a minimum in the apical membrane potential. The traditional model whereby all Cl⁻ channels are located in the apical membrane is shown to be the most efficient Cl⁻ channel distribution.     

Growth hormone-releasing factor reduces voltage-gated Ca2+ channel current in Rat GH3 cells

Summary The action of GRF on GH₃ cell membrane was examined by patch electrode techniques. Under current clamp with patch elecrtrode, spontaneous action potentials were partially to totally eliminated by application of GRF. In the case of partial elimination, the duration of remaining spontaneous action potentials was prolonged and the amplitude of afterhyperpolarization was decreased. The evoked actiion potential in the cells which did not show spontaneous action potentials was also eliminated by GRF. In order to examine what channels were affected by GRF, voltage-clamp analysis was performed. It was revealed that voltage-gated Ca²⁺ channel current and Ca²⁺-induced K⁺ channels current were decreased by GRF, while voltage-gated Na⁺ channel and delayed K⁺ channel current was considered to be a consequence of he decrease of voltage-gated Ca²⁺ channels current. Therefore it is likely that the effect of GRF on GH₃ cells was due to the block of voltage-gated Ca²⁺ channels. The elimination of action potential under current clamp corresponded to the block of voltage-gated Ca²⁺ channels and the prolongation of action potential could be explained by the decrease of Ca²⁺-induced K⁺ channel current. The amplitude decrease of afterhyperpolarization could also be explained by the reduction of Ca²⁺-induced K⁺ channel current. Thus the results under current clamp well coincide with the results under voltage clamp. Hormone secretion from GH₃ cells was not stimulated by GRF. However, the finding that GRF solely blocked voltage-gated Ca²⁺ channel suggested the specific action of GRF on GH₃ cell membranes.     

Genes for calcium-permeable channels in the plasma membrane of plant root cells

In plant cells, Ca²⁺ is required for both structural and biophysical roles. In addition, changes in cytosolic Ca²⁺ concentration ([Ca²⁺]_cyt) orchestrate responses to developmental and environmental signals. In many instances, [Ca²⁺]_cyt is increased by Ca²⁺ influx across the plasma membrane through ion channels. Although the electrophysiological and biochemical characteristics of Ca²⁺-permeable channels in the plasma membrane of plant cells are well known, genes encoding putative Ca²⁺-permeable channels have only recently been identified. By comparing the tissue expression patterns and electrophysiology of Ca²⁺-permeable channels in the plasma membrane of root cells with those of genes encoding candidate plasma membrane Ca²⁺ channels, the genetic counterparts of specific Ca²⁺-permeable channels can be deduced. Sequence homologies and the physiology of transgenic antisense plants suggest that the Arabidopsis AtTPC1 gene encodes a depolarisation-activated Ca²⁺ channel. Members of the annexin gene family are likely to encode hyperpolarisation-activated Ca²⁺ channels, based on their corresponding occurrence in secretory or elongating root cells, their inhibition by La³⁺ and nifedipine, and their increased activity as [Ca²⁺]_cyt is raised. Based on their electrophysiology and tissue expression patterns, AtSKOR encodes a depolarisation-activated outward-rectifying (Ca²⁺-permeable) K⁺ channel (KORC) in stelar cells and AtGORK is likely to encode a KORC in the plasma membrane of other Arabidopsis root cells. Two candidate gene families, of cyclic-nucleotide gated channels (CNGC) and ionotropic glutamate receptor (GLR) homologues, are proposed as the genetic correlates of voltage-independent cation (VIC) channels.     

Ca<Superscript>2+</Superscript> channels and Ca<Superscript>2+</Superscript> signals involved in abiotic stress responses in plant cells: recent advances

Calcium (Ca²⁺) signals are essential transducers and regulators in many adaptive and developmental processes in plants. Protective responses of plants to a variety of environmental stress factors are mediated by transient changes of Ca²⁺ concentration in plant cells. Ca²⁺ ions are quickly transported by channel proteins present on the plasma membrane. During responses to external stimuli, various signal molecules are transported directly from extracellular to intracellular compartments via Ca²⁺ channel proteins. Three types of Ca²⁺ channels have been identified in plant cell membranes: voltage-dependent Ca²⁺-permeable channels (VDCCs), which is sorted to depolarization-activated Ca²⁺-permeable channels (DACCs) and hyperpolarization-activated Ca²⁺-permeable channels (HACCs), voltage-independent Ca²⁺-permeable channels (VICCs). They make functions in the abiotic stress such as TPCs, CNGCs, MS channels, annexins which distribute in the organelles, plasma membrane, mitochondria, cytosol, intracelluar membrane. This review summarizes recent advances in our knowledge of many types of Ca²⁺ channels and Ca²⁺ signals involved in abiotic stress resistance and responses in plant cells.