Blockade by zinc ions of K+-induced contraction and calcium in guinea pigTaenia coli

Preincubation with 0.3 mM Zn²⁺ markedly inhibited both the tonic response and Ca²⁺ binding at low affinity sites induced by K⁺ (60 mM), with smaller effects on the phasic response and the high affinity Ca²⁺ sites, inTaenia coli. However, when the muscle was kept in Zn²⁺-containing medium following the first stimulation with the K⁺, the phasic response and the high affinity Ca²⁺ sites were more severely inhibited during the second stimulation with K⁺. This probably indicates that Zn²⁺ reduced the tonic tension response to K⁺ mainly by inhibiting Ca²⁺ influx at the cell membranes ofTaenia coli. However, when Zn²⁺ is continuously present, Ca²⁺ is not supplied at the storage sites and is not available for the phasic response to a second stimulation with K⁺.     

Transduction of the chemotactic cAMP signal across the plasma membrane ofDictyostelium cells

AggregatingDictyostelium cells secrete cAMP during cell aggregation. cAMP induces two fast responses, the production of more cAMP (relay) and directed cell locomotion (chemotaxis). Extracellular cAMP binds to G-protein-coupled receptors leading to the activation of second messenger pathways, including the activation of adenylyl cyclase, guanylyl cyclase, phospholipase C and the opening of plasma membrane Ca²⁺ channels. Many genes encoding these sensory transduction proteins have been cloned and null mutants of nearly all components have been characterized in detail. Undoubtedly, activation of adenylyl cyclase is the most complex, involving G-proteins, a soluble protein called CRAC and components of the MAP kinase pathway. Null mutants in this pathway do not aggregate, but can exhibit chemotaxis and develop normally when supplied with exogenous cAMP. The pathways leading to the activation of phospholipase C were identified, but unexpectedly, deletion of the phospholipase C gene has no effect on chemotaxis and development, nor on intracellular Ins(1,4,5)P₃ levels; the metabolism of this second messenger will be discussed in some detail. Activation of guanylyl cyclase is G-protein-dependent and essential for chemotaxis. Analysis of a collection of chemotactic mutants reveals that most mutants are defective in either the production or intracellular detection of cGMP, thereby placing this second messenger at the center of chemotactic signal transduction. Analysis of the cAMP-mediated opening of plasma membrane calcium channels in signal transduction mutants suggests that it has two components, one that depends on G-proteins and intracellular cGMP and one that is G-protein-independent.     

Sr2+ can become incorporated into an agonist-sensitive,cytoplasmic Ca2+ store in a cell line derived from the equine sweat gland epithelium

We have explored the properties of a Ca²⁺-dependent cell-signalling pathway that becomes active when cultured equine sweat gland cells are stimulated with ATP. The ATP-regulated, Ca²⁺-influx pathway allowed Sr²⁺ to enter the cytoplasm but permitted only a minimal influx of Ba²⁺. Experiments in which cells were repeatedly stimulated with ATP suggested that Sr²⁺, but not Ba²⁺, could become incorporated into the agonist-sensitive, cytoplasmic Ca²⁺ store. Further evidence for this was provided by experiments using ionomycin, a Ca²⁺ ionophore which has no affinity for Sr²⁺.     

EP2 receptor stimulation promotes calcium responses in astrocytes via activation of the adenylyl cyclase pathway

Astrocytes are a heterogeneous population of cells that are endowed with a great variety of receptors for neurotransmitters and neuromodulators. Recently prostaglandin E₂ has attracted great interest since it is not only released by astrocytes but also activates receptors coupled to either phospholipase C or adenylyl cyclase. We report that EP₂ receptor stimulation triggers cAMP production but also causes release of Ca²⁺ from intracellular stores. This effect is shared by other receptors similarly coupled to adenylyl cyclase and elicited by direct stimulation of the enzyme or application of cAMP analogues. However, the stimulation of the Ca²⁺ response by cAMP is not mediated by protein kinase A, since a specific antagonist of this kinase had no effect. Such a cross-talk between cAMP and Ca²⁺ was not observed in all astrocytes. It might therefore reflect a specific resource of either a subpopulation or astrocytes in a specific functional state. Received 6 June 2006; received after revision 25 July 2006; accepted 31 August 2006     

The role of Ca2+/calmodulin-stimulable adenylyl cyclases as molecular coincidence detectors in memory formation

Evidence from systems as diverse as mollusks, insects and mammals has revealed that adenylyl cyclase, cyclic adenosine 3′,5′-monophosphate (cAMP) cascade, cAMP-dependent protein kinases and their substrates are required for the cellular events underlying the short-term and long-term forms of memory. In Aplysia and Drosophila models, the coincident activation of independent paths converge to produce a synergistic activation of Ca²⁺/calmodulin-stimulable adenylyl cyclase, thereby enhancing the cAMP level that appears as the primary mediator of downstream events that strengthen enduring memory. In mammals, in which long-term memories require hippocampal function, our understanding of the role of adenylyl cyclases is still fragmentary. Of the differently regulated isoforms present in the hippocampus, the susceptibility of type 1 and type 8 to stimulation by the complex Ca²⁺/calmodulin and their expression in the hippocampus suggest a role for these two isoforms as a molecular coincidence device for hippocampus-related memory function. Here, we review the key features of Ca²⁺/calmodulin stimulable adenylyl cyclases, as well as the involvement of cAMP-regulated signaling pathway in the processes of learning and memory.     

Guanylate cyclase stimulation by nitro-compounds is dependent on free Ca2+1

Summary The stimulatory effect of nitro-compounds on arterial and hepatic guanylate cyclase became significantly depressed at 0.2 M and higher concentration of free Ca²⁺. The basal enzyme activity proved to be Ca²⁺-independent.This study was supported by the Anton Dreher-Foundation for Medical Research.     

Complex modulation of Cav3.1 T-type calcium channel by nickel

Nickel is considered to be a selective blocker of low-voltage-activated T-type calcium channel. Recently, the Ni²⁺-binding site with critical histidine-191 (H191) within the extracellular IS3–IS4 domain of the most Ni²⁺-sensitive Ca_v3.2 T-channel isoform has been identified. All calcium channels are postulated to also have intrapore-binding site limiting maximal current carried by permeating divalent cations (PDC) and determining the blockade by non-permeating ones. However, the contribution of the two sites to the overall Ni²⁺ effect and its dependence on PDC remain uncertain. Here we compared Ni²⁺ action on the wild-type “Ni²⁺-insensitive” Ca_v3.1_w/t channel and Ca_v3.1_Q172H mutant having glutamine (Q) equivalent to H191 of Ca_v3.2 replaced by histidine. Each channel was expressed in Xenopus oocytes, and Ni²⁺ blockade of Ca²⁺, Sr²⁺, or Ba²⁺ currents was assessed by electrophysiology. Inhibition of Ca_v3.1_w/t by Ni²⁺ conformed to two sites binding. Ni²⁺ binding with high-affinity site (IC₅₀ = 0.03–3 μM depending on PDC) produced maximal inhibition of 20–30 % and was voltage-dependent, consistent with its location within the channel’s pore. Most of the inhibition (70–80 %) was produced by Ni²⁺ binding with low-affinity site (IC₅₀ = 240–700 μM). Q172H-mutation mainly affected low-affinity binding (IC₅₀ = 120–160 μM). The IC₅₀ of Ni²⁺ binding with both sites in the Ca_v3.1_w/t and Ca_v3.1_Q172H was differentially modulated by PDC, suggesting a varying degree of competition of Ca²⁺, Sr²⁺, or Ba²⁺ with Ni²⁺. We conclude that differential Ni²⁺-sensitivity of T-channel subtypes is determined only by H-containing external binding sites, which, in the absence of Ni²⁺, may be occupied by PDC, influencing in turn the channel’s permeation.     

Proinsulin C-peptide and its analogues induce intracellular Ca2+ increases in human renal tubular cells

Based on the findings that proinsulin C-peptide binds specifically to cell membranes, we investigated the effects of C-peptide and related molecules on the intracellular Ca²⁺ concentration ([Ca²⁺]_i) in human renal tubular cells using the indicator fura-2/AM. The results show that human C-peptide and its C-terminal pentapeptide (positions 27–31, EGSLQ), but not the des (27–31) C-peptide or randomly scrambled C-peptide, elicit a transient increase in [Ca²⁺]_i. Rat C-peptide and rat C-terminal pentapeptide also induce a [Ca²⁺]_i response in human tubular cells, while a human pentapeptide analogue with Ala at position 1 gives no [Ca²⁺]_i response, and those with Ala at positions 2–5 induce responses with different amplitudes. These results define a species cross-reactivity for C-peptide and demonstrate the importance of Glu at position 1 of the pentapeptide. Preincubation of cells with pertussis toxin abolishes the effect on [Ca²⁺]_i by both C-peptide and the pentapeptide. These results are compatible with previous data on C-peptide binding to cells and activation of Na⁺,K⁺ATPase. Combined, all data show that C-peptide is a bioactive peptide and suggest that it elicits changes in [Ca²⁺]_i via G-protein-coupled pathways, giving downstream enzyme effects. Received 13 May 2002; accepted 16 May 2002     

A high molecular weight inhibitor of Ca2+-dependent neutral protease in rat brain

Summary An endogenous, heat-stable inhibitor of high mol. wt (approximately 3×10⁵) was found to be present in rat brain, which inhibited Ca²⁺-dependent neutral protease specifically but not due to its binding of Ca²⁺ in the medium.     

Structure and function of a calmodulin-dependent smooth muscle myosin light chain kinase

Summary In smooth muscle the M_r 20,000 light chain of myosin is phosphorylated by a calmodulin-dependent protein kinase. It consists of 2 subunits: calmodulin, an acidic protein of M_r 17,000 that binds 4 moles of Ca²⁺; and a larger protein of M_r circa 130,000. Activation of the kinase is dependent upon their association in the presence of Ca²⁺. Cyclic AMP-dependent protein kinase phosphorylation of the myosin light chain kinase occurs at 2 sites. It decreases the affinity of the kinase for calmodulin and a reduction in the rate of light chain phosphorylation occurs. The kinase has an overall asymmetric shape composed of a globular head and tail region for the skeletal muscle enzyme. Trypsin digestion of this kinase releases a fragment of M_r 36,000 from the globular region that contains the catalytic and calmodulin binding sites. Chymotrypsin digestion of the kinase from smooth muscle generates a fragment of M_r 80,000 that does not contain the calmodulin binding or cyclic AMP-dependent protein kinase phosphorylation sites. It is a Ca²⁺-independent form of the kinase that phosphorylates the light chain of myosin. These structural features indicate a regulatory role for the kinase in smooth muscle phosphorylation and contraction.     

Poly(ADP-ribose)glycohydrolase is an upstream regulator of Ca<Superscript>2+</Superscript> fluxes in oxidative cell death

Oxidative DNA damage to cells activates poly(ADP-ribose)polymerase-1 (PARP-1) and the poly(ADP-ribose) formed is rapidly degraded to ADP-ribose by poly(ADP-ribose)glycohydrolase (PARG). Here we show that PARP-1 and PARG control extracellular Ca²⁺ fluxes through melastatin-like transient receptor potential 2 channels (TRPM2) in a cell death signaling pathway. TRPM2 activation accounts for essentially the entire Ca²⁺ influx into the cytosol, activating caspases and causing the translocation of apoptosis inducing factor (AIF) from the inner mitochondrial membrane to the nucleus followed by cell death. Abrogation of PARP-1 or PARG function disrupts these signals and reduces cell death. ADP-ribose-loading of cells induces Ca²⁺ fluxes in the absence of oxidative damage, suggesting that ADP-ribose is the key metabolite of the PARP-1/PARG system regulating TRPM2. We conclude that PARP-1/PARG control a cell death signal pathway that operates between five different cell compartments and communicates via three types of chemical messengers: a nucleotide, a cation, and proteins.     

The role of calcium in aggregation and development ofDictyostelium

Changes in cytosolic Ca²⁺ play an important role in a wide array of cell types and the control of its concentration depends upon the interplay of many cellular constituents. Resting cells maintain cytosolic calcium ([Ca²⁺]_i) at a low level in the face of steep gradients of extracellular and sequestered Ca²⁺. Many different signals can provoke the opening of calcium channels in the plasma membrane or in intracellular compartments and cause rapid influx of Ca²⁺ into the cytosol and elevation of [Ca²⁺]_i. After such stimulation Ca²⁺ ATPases located in the plasma membrane and in the membranes of intracellular stores rapidly return [Ca²⁺]_i to its basal level. Such responses to elevation of [Ca²⁺]_i are a part of an important signal transduction mechanism that uses calcium (often via the binding protein calmodulin) to mediate a variety of cellular actions responsive to outside influences.     

Effect of phosphorylation of myosin light chains on interaction of heavy meromyosin with regulated F-actin in ghost fibers

Summary The binding of phosphorylated heavy meromyosin to regulated F-actin in ghost fibers at high Ca²⁺ concentration increases, and at low Ca²⁺ concentration decreases, the anisotropy of intrinsic tryptophan fluorescence of F-actin. The effect is opposite to the effect of the binding of dephosphorylated heavy meromyosin.     

Functional interaction between calsequestrin and ryanodine receptor in the heart

Evidence obtained in the last two decades indicates that calsequestrin (CSQ2), as the major Ca²⁺-binding protein in the sarcoplasmic reticulum of cardiac myocytes, communicates changes in the luminal Ca²⁺ concentration to the cardiac ryanodine receptor (RYR2) channel. This review summarizes the major aspects in the interaction between CSQ2 and the RYR2 channel. The single channel properties of RYR2 channels, discussed here in the context of structural changes in CSQ2 after Ca²⁺ binding, are particularly important. We focus on five important questions concerning: (1) the method for reliable detection of CSQ2 on the reconstituted RYR2 channel complex; (2) the power of the procedure to strip CSQ2 from the RYR2 channel complex; (3) structural changes in CSQ2 upon binding of Ca²⁺ which cause CSQ2 dissociation; (4) the potential role of CSQ2-independent regulation of the RYR2 activity by luminal Ca²⁺; and (5) the vizualization of CSQ2 dissociation from the RYR2 channel complex on the single channel level. We discuss the potential sources of the conflicting experimental results which may aid detailed understanding of the CSQ2 regulatory role. Although we mainly focus on the cardiac isoform of the proteins, some aspects of more extensive work carried out on the skeletal isoform are also discussed.     

Sulfhydryl oxidation induces calcium release from fragmented sarcoplasmic reticulum even in the presence of glutathione

Alcian blue and plumbagin induced transient Ca²⁺ release from fragmented sarcoplasmic reticulum. Dithiothreitol (DTT) and glutathione (GSH) partially blocked Ca²⁺ release induced by these oxidizing compounds. Pretreatment of alcian blue and plumbagin with DTT or GSH for more than 1 min was required to abolish the ability of the oxidizing compounds to release Ca²⁺. Mg²⁺ and ruthenium red completely blocked alcian blue-and plumbagin-induced Ca²⁺ release. These results suggest that oxidation of sulfhydryls on Ca²⁺ release channels induces Ca²⁺ release even in the presence of GSH in situ.     

Biochemical events associated with rapid cellular damage during the oxygen-and calcium-paradoxes of the mammalian heart

Summary The O_2– and Ca²⁺-paradoxes have a number of features in common and it is suggested that release of cytosolic proteins in both paradoxes is initiated by the activation of a sarcolemma NAD(P)H dehydrogenase which can generate a transmembrane flow of H⁺ and e^– and also oxygen radicals or recox cycling which damage ion channels and membrane proteins (phase I). Entry of Ca²⁺ through the damaged ion channels then exacerbates the damage by further activating this system, either directly or indirectly, and the redox cycling and/or oxygen radicals cause further damage to integral and cytoskeletal proteins of the sarcolemma resulting in microdamage to the integrity of the membrane (phase II) and the consequent release or exocytosis of cytoplasmic proteins and, under specialised condition, the blebbing of the sarcolemma. The system may be primed either by removal of extracellular Ca²⁺ or by raising [Ca²⁺]_i by a variety of measures, these two actions being synergistic. The system is initially activated in the Ca²⁺-paradox by the membrane perturbation associated with removal of extracellular Ca²⁺; prolonged anoxia in the metabolically active cardiac muscle causes a depletion of the ATP supply, particularly in the absence of glucose, and hence a rise in [Ca²⁺]_i in phase I of the oxygen paradox with the consequent activation of the NAD(P)H oxidase at the sarcolemma. Oxygen radicals are probably generated in both paradoxes and may have a partial role in the genesis of damage, but are not essential in the Ca²⁺-paradox which continues under anoxia. Massive entry of Ca²⁺ also activates an intracellularly localised dehydrogenase (probably at the SR) which produces myofilament damage by redox cycling.     

Neuronal calcium signaling: function and dysfunction

Calcium (Ca²⁺) is an universal second messenger that regulates the most important activities of all eukaryotic cells. It is of critical importance to neurons as it participates in the transmission of the depolarizing signal and contributes to synaptic activity. Neurons have thus developed extensive and intricate Ca²⁺ signaling pathways to couple the Ca²⁺ signal to their biochemical machinery. Ca²⁺ influx into neurons occurs through plasma membrane receptors and voltage-dependent ion channels. The release of Ca²⁺ from the intracellular stores, such as the endoplasmic reticulum, by intracellular channels also contributes to the elevation of cytosolic Ca²⁺. Inside the cell, Ca²⁺ is controlled by the buffering action of cytosolic Ca²⁺-binding proteins and by its uptake and release by mitochondria. The uptake of Ca²⁺ in the mitochondrial matrix stimulates the citric acid cycle, thus enhancing ATP production and the removal of Ca²⁺ from the cytosol by the ATP-driven pumps in the endoplasmic reticulum and the plasma membrane. A Na⁺/Ca²⁺ exchanger in the plasma membrane also participates in the control of neuronal Ca²⁺. The impaired ability of neurons to maintain an adequate energy level may impact Ca²⁺ signaling: this occurs during aging and in neurodegenerative disease processes. The focus of this review is on neuronal Ca²⁺ signaling and its involvement in synaptic signaling processes, neuronal energy metabolism, and neurotransmission. The contribution of altered Ca²⁺ signaling in the most important neurological disorders will then be considered.     

Ca2+ release-activated Ca2+ (CRAC) current, structure, and function

Store-operated Ca²⁺ entry describes the phenomenon that connects a depletion of internal Ca²⁺ stores to an activation of plasma membrane-located Ca²⁺ selective ion channels. Tremendous progress towards the underlying molecular mechanism came with the discovery of the two respective limiting components, STIM and Orai. STIM1 represents the ER-located Ca²⁺ sensor and transmits the signal of store depletion to the plasma membrane. Here it couples to and activates Orai, the highly Ca²⁺-selective pore-forming subunit of Ca²⁺ release-activated Ca²⁺ channels. In this review, we focus on the molecular steps that these two proteins undergo from store-depletion to their coupling, the activation, and regulation of Ca²⁺ currents.     

Molecular regulation of CRAC channels and their role in lymphocyte function

Calcium (Ca²⁺) influx is required for the activation and function of all cells in the immune system. It is mediated mainly by store-operated Ca²⁺ entry (SOCE) through Ca²⁺ release-activated Ca²⁺ (CRAC) channels located in the plasma membrane. CRAC channels are composed of ORAI proteins that form the channel pore and are activated by stromal interaction molecules (STIM) 1 and 2. Located in the membrane of the endoplasmic reticulum, STIM1 and STIM2 have the dual function of sensing the intraluminal Ca²⁺ concentration in the ER and to activate CRAC channels. A decrease in the ER’s Ca²⁺ concentration induces STIM multimerization and translocation into puncta close to the plasma membrane where they bind to and activate ORAI channels. Since the identification of ORAI and STIM genes as the principal mediators of CRAC channel function, substantial advances have been achieved in understanding the molecular regulation and physiological role of CRAC channels in cells of the immune system and other organs. In this review, we discuss the mechanisms that regulate CRAC channel function and SOCE, the role of recently identified proteins and mechanisms that modulate the activation of ORAI/STIM proteins and the consequences of CRAC channel dysregulation for lymphocyte function and immunity.