Triggered Ca2+ influx is required for extended synaptotagmin 1-induced ER-plasma membrane tethering

The extended synaptotagmins (E-Syts) are ER proteins that act as Ca²⁺-regulated tethers between the ER and the plasma membrane (PM) and have a putative role in lipid transport between the two membranes. Ca²⁺ regulation of their tethering function, as well as the interplay of their different domains in such function, remains poorly understood. By exposing semi-intact cells to buffers of variable Ca²⁺ concentrations, we found that binding of E-Syt1 to the PI(4,5)P₂-rich PM critically requires its C2C and C2E domains and that the EC₅₀ of such binding is in the low micromolar Ca²⁺ range. Accordingly, E-Syt1 accumulation at ER-PM contact sites occurred only upon experimental manipulations known to achieve these levels of Ca²⁺ via its influx from the extracellular medium, such as store-operated Ca²⁺ entry in fibroblasts and membrane depolarization in β-cells. We also show that in spite of their very different physiological functions, membrane tethering by E-Syt1 (ER to PM) and by synaptotagmin (secretory vesicles to PM) undergo a similar regulation by plasma membrane lipids and cytosolic Ca²⁺.     

STIM and Orai: Dynamic Intermembrane Coupling to Control Cellular Calcium Signals

Ca²⁺ signals controlling a vast array of cell functions involve both Ca²⁺ store release and external Ca²⁺ entry. These two events are coordinated through a dynamic intermembrane coupling between two distinct membrane proteins, STIM and Orai. STIM proteins are endoplasmic reticulum (ER) luminal Ca²⁺ sensors that undergo a profound redistribution into discrete junctional ER domains closely juxtaposed with the plasma membrane (PM). Orai proteins are PM Ca²⁺ channels that migrate and become tethered by STIM within the ER-PM junctions, where they mediate exceedingly selective Ca²⁺ entry. We describe a new understanding of the nature of the proteins and how they function to mediate this remarkable intermembrane signaling process controlling Ca²⁺ signals.     

Ca signaling and regulation of fluid secretion in salivary gland acinar cells

Neurotransmitter stimulation of plasma membrane receptors stimulates salivary gland fluid secretion via a complex process that is determined by coordinated temporal and spatial regulation of several Ca²⁺ signaling processes as well as ion flux systems. Studies over the past four decades have demonstrated that Ca²⁺ is a critical factor in the control of salivary gland function. Importantly, critical components of this process have now been identified, including plasma membrane receptors, calcium channels, and regulatory proteins. The key event in activation of fluid secretion is an increase in intracellular [Ca²⁺] ([Ca²⁺]_i) triggered by IP₃-induced release of Ca²⁺ from ER via the IP₃R. This increase regulates the ion fluxes required to drive vectorial fluid secretion. IP₃Rs determine the site of initiation and the pattern of [Ca²⁺]_i signal in the cell. However, Ca²⁺ entry into the cell is required to sustain the elevation of [Ca²⁺]_i and fluid secretion. This Ca²⁺ influx pathway, store-operated calcium influx pathway (SOCE), has been studied in great detail and the regulatory mechanisms as well as key molecular components have now been identified. Orai1, TRPC1, and STIM1 are critical components of SOCE and among these, Ca²⁺ entry via TRPC1 is a major determinant of fluid secretion. The receptor-evoked Ca²⁺ signal in salivary gland acinar cells is unique in that it starts at the apical pole and then rapidly increases across the cell. The basis for the polarized Ca²⁺ signal can be ascribed to the polarized arrangement of the Ca²⁺ channels, transporters, and signaling proteins. Distinct localization of these proteins in the cell suggests compartmentalization of Ca²⁺ signals during regulation of fluid secretion. This chapter will discuss new concepts and findings regarding the polarization and control of Ca²⁺ signals in the regulation of fluid secretion.     

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.     

Oligomerization and Ca2+/calmodulin control binding of the ER Ca2+-sensors STIM1 and STIM2 to plasma membrane lipids

Ca²⁺ (calcium) homoeostasis and signalling rely on physical contacts between Ca²⁺ sensors in the ER (endoplasmic reticulum) and Ca²⁺ channels in the PM (plasma membrane). STIM1 (stromal interaction molecule 1) and STIM2 Ca²⁺ sensors oligomerize upon Ca²⁺ depletion in the ER lumen, contact phosphoinositides at the PM via their cytosolic lysine (K)-rich domains, and activate Ca²⁺ channels. Differential sensitivities of STIM1 and STIM2 towards ER luminal Ca²⁺ have been studied but responses towards elevated cytosolic Ca²⁺ concentration and the mechanism of lipid binding remain unclear. We found that tetramerization of the STIM1 K-rich domain is necessary for efficient binding to PI(4,5)P₂-containing PM-like liposomes consistent with an oligomerization-driven STIM1 activation. In contrast, dimerization of STIM2 K-rich domain was sufficient for lipid binding. Furthermore, the K-rich domain of STIM2, but not of STIM1, forms an amphipathic α-helix. These distinct features of the STIM2 K-rich domain cause an increased affinity for PI(4,5)P₂, consistent with the lower activation threshold of STIM2 and a function as regulator of basal Ca²⁺ levels. Concomitant with higher affinity for PM lipids, binding of CaM (calmodulin) inhibited the interaction of the STIM2 K-rich domain with liposomes in a Ca²⁺ and PI(4,5)P₂ concentration-dependent manner. Therefore we suggest that elevated cytosolic Ca²⁺ concentration down-regulates STIM2-mediated ER–PM contacts via CaM binding.     

Bidirectional Ca2+ signaling occurs between the endoplasmic reticulum and acidic organelles

The endoplasmic reticulum (ER) and acidic organelles (endo-lysosomes) act as separate Ca²⁺ stores that release Ca²⁺ in response to the second messengers IP₃ and cADPR (ER) or NAADP (acidic organelles). Typically, trigger Ca²⁺ released from acidic organelles by NAADP subsequently recruits IP₃ or ryanodine receptors on the ER, an anterograde signal important for amplification and Ca²⁺ oscillations/waves. We therefore investigated whether the ER can signal back to acidic organelles, using organelle pH as a reporter of NAADP action. We show that Ca²⁺ released from the ER can activate the NAADP pathway in two ways: first, by stimulating Ca²⁺-dependent NAADP synthesis; second, by activating NAADP-regulated channels. Moreover, the differential effects of EGTA and BAPTA (slow and fast Ca²⁺ chelators, respectively) suggest that the acidic organelles are preferentially activated by local microdomains of high Ca²⁺ at junctions between the ER and acidic organelles. Bidirectional organelle communication may have wider implications for endo-lysosomal function as well as the generation of Ca²⁺ oscillations and waves.     

Lipid rafts/caveolae as microdomains of calcium signaling

Ca²⁺ is a major signaling molecule in both excitable and non-excitable cells, where it serves critical functions ranging from cell growth to differentiation to cell death. The physiological functions of these cells are tightly regulated in response to changes in cytosolic Ca²⁺ that is achieved by the activation of several plasma membrane (PM) Ca²⁺ channels as well as release of Ca²⁺ from the internal stores. One such channel is referred to as store-operated Ca²⁺ channel that is activated by the release of endoplasmic reticulum (ER) Ca²⁺ which initiates store-operated Ca²⁺ entry (SOCE). Recent advances in the field suggest that some members of TRPCs and Orai channels function as SOCE channels. However, the molecular mechanisms that regulate channel activity and the exact nature of where these channels are assembled and regulated remain elusive. Research from several laboratories has demonstrated that key proteins involved in Ca²⁺ signaling are localized in discrete PM lipid rafts/caveolar microdomains. Lipid rafts are cholesterol and sphingolipid-enriched microdomains that function as unique signal transduction platforms. In addition lipid rafts are dynamic in nature which tends to scaffold certain signaling molecules while excluding others. By such spatial segregation, lipid rafts not only provide a favorable environment for intra-molecular cross-talk but also aid to expedite the signal relay. Importantly, Ca²⁺ signaling is shown to initiate from these lipid raft microdomains. Clustering of Ca²⁺ channels and their regulators in such microdomains can provide an exquisite spatiotemporal regulation of Ca²⁺-mediated cellular function. Thus in this review we discuss PM lipid rafts and caveolae as Ca²⁺-signaling microdomains and highlight their importance in organizing and regulating SOCE channels.     

Calcium signaling in pancreatic β-cells in health and in Type 2 diabetes

Changes in cytosolic free Ca²⁺ concentration ([Ca²⁺]_c) play a crucial role in the control of insulin secretion from the electrically excitable pancreatic β-cell. Secretion is controlled by the finely tuned balance between Ca²⁺ influx (mainly through voltage-dependent Ca²⁺ channels, but also through voltage-independent Ca²⁺ channels like store-operated channels) and efflux pathways. Changes in [Ca²⁺]_c directly affect [Ca²⁺] in various organelles including the endoplasmic reticulum (ER), mitochondria, the Golgi apparatus, secretory granules and lysosomes, as imaged using recombinant targeted probes. Because most of these organelles have specific Ca²⁺ influx and efflux pathways, they mutually influence free [Ca²⁺] in the others. In this article, we review the mechanisms of control of [Ca²⁺] in various compartments and particularly the cytosol, the endoplasmic reticulum ([Ca²⁺]_ER), acidic stores and mitochondrial matrix ([Ca²⁺]_mito), focusing chiefly on the most important physiological stimulus of β-cells, glucose. We also briefly review some alterations of β-cell Ca²⁺ homeostasis in Type 2 diabetes.     

TRICking SOCE into altered oscillations

Defective ER/SR-cytosol Ca²⁺ cycling is associated with increased ER stress, pathological heart conditions and muscular defects. Within the SR, ryanodine receptor 2 (RyR2) is required for excitation/contraction coupling. Ca²⁺ release from the SR is counterbalanced by K⁺ influx through trimeric intracellular cation (TRIC) channels to maintain ER/SR polarity. New functions of TRIC channels have been discovered.     

Calcium and diacylglycerol control of secretion

Measurements of intracellular Ca²⁺ in adrenal medullary cells suggest that a transient rise in Ca²⁺ leads to a transient secretory response, the rise in Ca²⁺ being brought about by an influx through voltage-sensitive Ca channels which subsequently inactivate. The level of Ca²⁺ observed is much smaller than the Ca²⁺ needed to trigger secretion when introduced directly into the cell. The discrepancy is removed by the presence of diacylglycerot, which increases the sensitivity of the secretory process to Ca²⁺. The site of action of Ca²⁺ and diacylglycerol is probably protein kinase C, and tile different secretory responses to increases of Ca²⁺ and diacylglycerol can be modelled in terms of a preferential order of binding of these two substrates to the enzyme. ATP is needed for secretion: one role is possibly to confer stability to the secretory apparatus; another may involve phosphorylation of some key protein. The kinetics of secretion suggest that if Ca²⁺ regulates phosphorylation or dephosphorylation, then it is therate of change of phosphorylation that controls secretion rather than theextent of phosphorylation or dephosphorylation. Guanine nucleotide-binding proteins may play a role not only at the level of signal transduction coupling, but also at or near the site of exocytosis, and the mechanism by which some Botulinum toxins inhibit secretion may be associated with these proteins.     

Calcium-sensing receptor activation contributed to apoptosis stimulates TRPC6 channel in rat neonatal ventricular myocytes

Capacitative calcium entry (CCE) refers to the influx of calcium through plasma membrane channels activated on depletion of endoplasmic sarcoplasmic/reticulum (ER/SR) Ca²⁺ stores, which is performed mainly by the transient receptor potential (TRP) channels. TRP channels are expressed in cardiomyocytes. Calcium-sensing receptor (CaR) is also expressed in rat cardiac tissue and plays an important role in mediating cardiomyocyte apoptosis. However, there are no data regarding the link between CaR and TRP channels in rat heart. In this study, in rat neonatal myocytes, by Ca²⁺ imaging, we found that the depletion of ER/SR Ca²⁺ stores by thapsigargin (TG) elicited a transient rise in cytoplasmic Ca²⁺ ([Ca²⁺]_i), followed by sustained increase depending on extracellular Ca²⁺. But, TRP channels inhibitor (SKF96365), not L-type channels or the Na⁺/Ca²⁺ exchanger inhibitors, inhibited [Ca²⁺]_i relatively high. Then, we found that the stimulation of CaR with its activator gadolinium chloride (GdCl₃) or by an increased extracellular Ca²⁺([Ca²⁺]_o) increased the concentration of intracelluar Ca²⁺, whereas, the sustained elevation of [Ca²⁺]_i was reduced in the presence of SKF96365. Similarly, the duration of [Ca²⁺]_i increase was also shortened in the absence of extracellular Ca²⁺. Western blot analysis showed that GdCl₃ increased the expression of TRPC6, which was reversed by SKF96365. Additionally, SKF96365 reduced cardiomyocyte apoptosis induced by GdCl₃. Our results suggested that CCE exhibited in rat neonatal myocytes and CaR activation induced Ca²⁺-permeable cationic channels TRPCs to gate the CCE, for which TRPC6 was one of the most likely candidates. TRPC6 channel was functionally coupled with CaR to enhance the cardiomyocyte apoptosis.     

Phosphatidylinositol 4,5-bisphosphate and calcium at ER-PM junctions — Complex interplay of simple messengers

Endoplasmic reticulum-plasma membrane contact sites (ER-PM MCS) are a specialised domain involved in the control of Ca²⁺ dynamics and various Ca²⁺-dependent cellular processes. Intracellular Ca²⁺ signals are broadly supported by Ca²⁺ release from intracellular Ca²⁺ channels such as inositol 1,4,5-trisphosphate receptors (IP₃Rs) and subsequent store-operated Ca²⁺ entry (SOCE) across the PM to replenish store content. IP₃Rs sit in close proximity to the PM where they can easily access newly synthesised IP₃, interact with binding partners such as actin, and localise adjacent to ER-PM MCS populated by the SOCE machinery, STIM1–2 and Orai1–3, to possibly form a locally regulated unit of Ca²⁺ influx. PtdIns(4,5)P₂ is a multiplex regulator of Ca²⁺ signalling at the ER-PM MCS interacting with multiple proteins at these junctions such as actin and STIM1, whilst also being consumed as a substrate for phospholipase C to produce IP₃ in response to extracellular stimuli. In this review, we consider the mechanisms regulating the synthesis and turnover of PtdIns(4,5)P₂ via the phosphoinositide cycle and its significance for sustained signalling at the ER-PM MCS. Furthermore, we highlight recent insights into the role of PtdIns(4,5)P₂ in the spatiotemporal organization of signalling at ER-PM junctions and raise outstanding questions on how this multi-faceted regulation occurs.     

Suppression of Ca2+ syntillas increases spontaneous exocytosis in mouse adrenal chromaffin cells

A central concept in the physiology of neurosecretion is that a rise in cytosolic [Ca²⁺] in the vicinity of plasmalemmal Ca²⁺ channels due to Ca²⁺ influx elicits exocytosis. Here, we examine the effect on spontaneous exocytosis of a rise in focal cytosolic [Ca²⁺] in the vicinity of ryanodine receptors (RYRs) due to release from internal stores in the form of Ca²⁺ syntillas. Ca²⁺ syntillas are focal cytosolic transients mediated by RYRs, which we first found in hypothalamic magnocellular neuronal terminals. (scintilla, Latin for spark; found in nerve terminals, normally synaptic structures.) We have also observed Ca²⁺ syntillas in mouse adrenal chromaffin cells. Here, we examine the effect of Ca²⁺ syntillas on exocytosis in chromaffin cells. In such a study on elicited exocytosis, there are two sources of Ca²⁺: one due to influx from the cell exterior through voltage-gated Ca²⁺ channels, and that due to release from intracellular stores. To eliminate complications arising from Ca²⁺ influx, we have examined spontaneous exocytosis where influx is not activated. We report here that decreasing syntillas leads to an increase in spontaneous exocytosis measured amperometrically. Two independent lines of experimentation each lead to this conclusion. In one case, release from stores was blocked by ryanodine; in another, stores were partially emptied using thapsigargin plus caffeine, after which syntillas were decreased. We conclude that Ca²⁺ syntillas act to inhibit spontaneous exocytosis, and we propose a simple model to account quantitatively for this action of syntillas.     

Ribosome-free Terminals of Rough ER Allow Formation of STIM1 Puncta and Segregation of STIM1 from IP3 Receptors

Store-operated Ca²⁺ entry is a ubiquitous mechanism that prevents the depletion of endoplasmic reticulum (ER) calcium [1]. A reduction of ER calcium triggers translocation of STIM proteins, which serve as calcium sensors in the ER, to subplasmalemmal puncta where they interact with and activate Orai channels ([2], [3], [4], [5], [6], [7] and [8]; reviewed in [9]). In pancreatic acinar cells, inositol 1,4,5-trisphosphate (IP₃) receptors populate the apical part of the ER. Here, however, we observe that STIM1 translocates exclusively to the lateral and basal regions following ER Ca²⁺ loss. This finding is paradoxical because the basal and lateral regions of the acinar cells contain rough ER (RER); the size of the ribosomes that decorate RER is larger than the distance that can be spanned by a STIM-Orai complex [5] and [10], and STIM1 function should therefore not be possible. We resolve this paradox and characterize ribosome-free terminals of the RER that form junctions between the reticulum and the plasma membrane in the basal and lateral regions of the acinar cells. Our findings indicate that different ER compartments specialize in different calcium-handling functions (Ca²⁺ release and Ca²⁺ reloading) and that any potential interference between Ca²⁺ release and Ca²⁺ influx is minimized by the spatial separation of the two processes.     

Polarized but Differential Localization and Recruitment of STIM1, Orai1 and TRPC Channels in Secretory Cells

Polarized Ca²⁺ signals in secretory epithelial cells are determined by compartmentalized localization of Ca²⁺ signaling proteins at the apical pole. Recently the ER Ca²⁺ sensor STIM1 (stromal interaction molecule 1) and the Orai channels were shown to play a critical role in store‐dependent Ca²⁺ influx. STIM1 also gates the transient receptor potential‐canonical (TRPC) channels. Here, we asked how cell stimulation affects the localization, recruitment and function of the native proteins in polarized cells. Inhibition of Orai1, STIM1, or deletion of TRPC1 reduces Ca²⁺ influx and frequency of Ca²⁺ oscillations. Orai1 localization is restricted to the apical pole of the lateral membrane. Surprisingly, cell stimulation does not lead to robust clustering of native Orai1, as is observed with expressed Orai1. Unexpectedly, cell stimulation causes polarized recruitment of native STIM1 to both the apical and lateral regions, thus to regions with and without Orai1. Accordingly, STIM1 and Orai1 show only 40% colocalization. Consequently, STIM1 shows higher colocalization with the basolateral membrane marker E‐cadherin than does Orai1, while Orai1 showed higher colocalization with the tight junction protein ZO1. TRPC1 is expressed in both apical and basolateral regions of the plasma membrane. Co‐IP of STIM1/Orai1/IP₃ receptors (IP₃Rs)/TRPCs is enhanced by cell stimulation and disrupted by 2‐aminoethoxydiphenyl borate (2APB). The polarized localization and recruitment of these proteins results in preferred Ca²⁺ entry that is initiated at the apical pole. These findings reveal that in addition to Orai1, STIM1 likely regulates other Ca²⁺ permeable channels, such as the TRPCs. Both channels contribute to the frequency of [Ca²⁺] oscillations and thus impact critical cellular functions.     

Store-operated Ca2+ influx and subplasmalemmal mitochondria

Calcium depletion of the endoplasmic reticulum (ER) induces oligomerisation, puncta formation and translocation of the ER Ca²⁺ sensor proteins, STIM1 and -2 into plasma membrane (PM)-adjacent regions of the ER, where they activate the Orai1, -2 or -3 proteins present in the opposing PM. These proteins form ion channels through which store-operated Ca²⁺ influx (SOC) occurs. Calcium ions exert negative feed-back on SOC. Here we examined whether subplasmalemmal mitochondria, which reduce this feed-back by Ca²⁺ uptake, are located within or out of the high-Ca²⁺ microdomains (HCMDs) formed between the ER and plasmalemmal Orai1 channels. For this purpose, COS-7 cells were cotransfected with Orai1, STIM1 labelled with YFP or mRFP and the mitochondrially targeted Ca²⁺ sensitive fluorescent protein inverse-Pericam. Depletion of ER Ca²⁺ with ATP + thapsigargin (in Ca²⁺-free medium) induced the appearance of STIM1 puncta in the ≤100 nm wide subplasmalemmal space, as examined with TIRF. Mitochondria were located either in the gaps between STIM1-tagged puncta or in remote, STIM1-free regions. After addition of Ca²⁺ mitochondrial Ca²⁺ concentration increased irrespective of the mitochondrion–STIM1 distance. These observations indicate that mitochondria are exposed to Ca²⁺ diffused laterally from the HCMDs formed between the PM and the subplasmalemmal ER.     

Polyamine Triggering of Exocytosis in Paramecium Involves an Extracellular Ca2+/(Polyvalent Cation)-Sensing Receptor, Subplasmalemmal Ca-Store Mobilization and Store-Operated Ca2+-Influx via Unspecific Cation Channels

The polyamine secretagogue, aminoethyldextran (AED), causes a cortical [Ca²⁺] transient in Paramecium cells, as analyzed by fluorochrome imaging. Our most essential findings are: (i) Cortical Ca²⁺ signals also occur when AED is applied in presence of the fast Ca²⁺ chelator, BAPTA. (ii) Extracellular La³⁺ application causes within seconds a rapid, reversible fluorescence signal whose reversibility can be attributed to a physiological [Ca²⁺] _i transient (while injected La³⁺ causes a sustained fluorescence signal). (iii) Simply increasing [Ca²⁺] _o causes a similar rapid, short-lived [Ca²⁺] _i transient. All these phenomena, (i–iii), are compatible with activation of an extracellular ``Ca<sup>2+</sup>/(polyvalent cation)-sensing receptor' known from some higher eukaryotic systems, where this sensor (responding to Ca<sup>2+</sup>, La<sup>3+</sup> and some multiply charged cations) is linked to cortical calcium stores which, thus, are activated. In Paramecium, such subplasmalemmal stores (``alveolar sacs') are physically linked to the cell membrane and they can also be activated by the Ca²⁺ releasing agent, 4-chloro-m-cresol, just like in Sarcoplasmic Reticulum. Since this drug causes a cortical Ca²⁺ signal also in absence of Ca²⁺ _o we largely exclude a ``Ca<sup>2+</sup>-induced Ca<sup>2+</sup> release' (CICR) mechanism. Our finding of increased cortical Ca<sup>2+</sup> signals after store depletion and re-addition of extracellular Ca<sup>2+</sup> can be explained by a ``store-operated Ca²⁺ influx' (SOC), i.e., a Ca²⁺ influx superimposing store activation. AED stimulation in presence of Mn²⁺ _o causes fluorescence quenching in Fura-2 loaded cells, indicating involvement of unspecific cation channels. Such channels, known to occur in Paramecium, share some general characteristics of SOC-type Ca²⁺ influx channels. In conclusion, we assume the following sequence of events during AED stimulated exocytosis: (i) activation of an extracellular Ca²⁺/polyamine-sensing receptor, (ii) release of Ca²⁺ from subplasmalemmal stores, (iii) and Ca²⁺ influx via unspecific cation channels. All three steps are required to produce a steep cortical [Ca²⁺] signal increase to a level required for full exocytosis activation. In addition, we show formation of [Ca²⁺] microdomains (≤0.5 μm, ≤33 msec) upon stimulation. Received: 30 August 1999/Revised: 1 December 1999     

Trichocysts—Paramecium's Projectile‐like Secretory Organelles

This review summarizes biogenesis, composition, intracellular transport, and possible functions of trichocysts. Trichocyst release by Paramecium is the fastest dense core‐secretory vesicle exocytosis known. This is enabled by the crystalline nature of the trichocyst “body” whose matrix proteins (tmp), upon contact with extracellular Ca²⁺, undergo explosive recrystallization that propagates cooperatively throughout the organelle. Membrane fusion during stimulated trichocyst exocytosis involves Ca²⁺ mobilization from alveolar sacs and tightly coupled store‐operated Ca²⁺‐influx, initiated by activation of ryanodine receptor‐like Ca²⁺‐release channels. Particularly, aminoethyldextran perfectly mimics a physiological function of trichocysts, i.e. defense against predators, by vigorous, local trichocyst discharge. The tmp's contained in the main “body” of a trichocyst are arranged in a defined pattern, resulting in crossstriation, whose period expands upon expulsion. The second part of a trichocyst, the “tip”, contains secretory lectins which diffuse upon discharge. Repulsion from predators may not be the only function of trichocysts. We consider ciliary reversal accompanying stimulated trichocyst exocytosis (also in mutants devoid of depolarization‐activated Ca²⁺ channels) a second, automatically superimposed defense mechanism. A third defensive mechanism may be effectuated by the secretory lectins of the trichocyst tip; they may inhibit toxicyst exocytosis in Dileptus by crosslinking surface proteins (an effect mimicked in Paramecium by antibodies against cell surface components). Some of the proteins, body and tip, are glycosylated as visualized by binding of exogenous lectins. This reflects the biogenetic pathway, from the endoplasmic reticulum via the Golgi apparatus, which is also supported by details from molecular biology. There are fragile links connecting the matrix of a trichocyst with its membrane; these may signal the filling state, full or empty, before and after tmp release upon exocytosis, respectively. This is supported by experimentally produced “frustrated exocytosis”, i.e. membrane fusion without contents release, followed by membrane resealing and entry in a new cycle of reattachment for stimulated exocytosis. There are some more puzzles to be solved: Considering the absence of any detectable Ca²⁺ and of acidity in the organelle, what causes the striking effects of silencing the genes of some specific Ca²⁺‐release channels and of subunits of the H⁺‐ATPase? What determines the inherent polarity of a trichocyst? What precisely causes the inability of trichocyst mutants to dock at the cell membrane? Many details now call for further experimental work to unravel more secrets about these fascinating organelles.     

Sigma1 receptors inhibit store-operated Ca2+ entry by attenuating coupling of STIM1 to Orai1

Sigma1 receptors (σ1Rs) are expressed widely; they bind diverse ligands, including psychotropic drugs and steroids, regulate many ion channels, and are implicated in cancer and addiction. It is not known how σ1Rs exert such varied effects. We demonstrate that σ1Rs inhibit store-operated Ca²⁺ entry (SOCE), a major Ca²⁺ influx pathway, and reduce the Ca²⁺ content of the intracellular stores. SOCE was inhibited by expression of σ1R or an agonist of σ1R and enhanced by loss of σ1R or an antagonist. Within the endoplasmic reticulum (ER), σ1R associated with STIM1, the ER Ca²⁺ sensor that regulates SOCE. This interaction was modulated by σ1R ligands. After depletion of Ca²⁺ stores, σ1R accompanied STIM1 to ER–plasma membrane (PM) junctions where STIM1 stimulated opening of the Ca²⁺ channel, Orai1. The association of STIM1 with σ1R slowed the recruitment of STIM1 to ER–PM junctions and reduced binding of STIM1 to PM Orai1. We conclude that σ1R attenuates STIM1 coupling to Orai1 and thereby inhibits SOCE.