Action potential prolongation in cardiac myocytes of old rats is an adaptation to sustain youthful intracellular Ca2+ regulation

Advanced age in rats is accompanied by reduced expression of the sarcoplasmic reticulum (SR) Ca2+ pump (SERCA-2). The amplitudes of intracellular Ca2+ (Ca2+(i)) transients and contractions in ventricular myocytes isolated from old (23-24-months) rats (OR), however, are similar to those of young (4-6-months) rat myocytes (YR). OR myocytes also manifest slowed inactivation of L-type Ca2+ current (I(CaL)) and marked prolongation of action potential (AP) duration. To determine whether and how age-associated AP prolongation preserves the Ca2+(i) transient amplitude in OR myocytes, we employed an AP-clamp technique with simultaneous measurements of I(CaL) (with Na+ current, K+ currents and Ca2+ influx via sarcolemmal Na+-Ca2+ exchanger blocked) and Ca2+(i) transients in OR rat ventricular myocytes dialyzed with the fluorescent Ca2+ probe, indo-1. Myocytes were stimulated with AP-shaped voltage clamp waveforms approximating the configuration of prolonged, i.e. the native, AP of OR cells (AP-L), or with short AP waveforms (AP-S), typical of YR myocytes. Changes in SR Ca2+ load were assessed by rapid, complete SR Ca2+ depletions with caffeine. As expected, during stimulation with AP-S vs AP-L, peak I(CaL) increased, by 21+/-4%, while the I(CaL) integral decreased, by 19+/-3% (P<0.01 for each). Compared to AP-L, stimulation of OR myocytes with AP-S reduced the amplitudes of the Ca2+(i) transient by 31+/-6%, its maximal rate of rise (+dCa2+(i)/dt(max); a sensitive index of SR Ca2+ release flux) by 37+/-4%, and decreased the SR Ca2+ load by 29+/-4% (P<0.01 for each). Intriguingly, AP-S also reduced the maximal rate of the Ca2+(i) transient relaxation and prolonged its time to 50% decline, by 35+/-5% and 33+/-7%, respectively (P<0.01 for each). During stimulation with AP-S, the gain of Ca2+-induced Ca2+ release (CICR), indexed by +dCa2+(i)/dt(max)/I(CaL), was reduced by 46+/-4% vs AP-L (P<0.01). We conclude that the effects of an application of a shorter AP to OR myocytes to reduce +dCa2+(i)/dt(max) and the Ca2+ transient amplitude are attributable to a reduction in SR Ca2+ load, presumably due to a reduced I(CaL) integral and likely also to an increased Ca2+ extrusion via sarcolemmal Na+-Ca2+ exchanger. The decrease in the Ca2+(i) transient relaxation rate in OR cells stimulated with shorter APs may reflect a reduction of Ca2+/calmodulin-kinase II-regulated modulation of Ca2+ uptake via SERCA-2, consequent to a reduced local Ca2+ release in the vicinity of SERCA-2, also attributable to reduced SR Ca2+ load. Thus, the reduction of CICR gain during stimulation with AP-S is the net result of both a diminished SR Ca2+ release and an increased peak I(CaL). These results suggest that ventricular myocytes of old rats utilize AP prolongation to preserve an optimal SR Ca2+ loading, CICR gain and relaxation of Ca2+(i) transients.     

Excitation-dependent intracellular Ca2+ waves at the border zone of the cryo-injured rat heart revealed by real-time confocal microscopy

Intracellular Ca2+ waves, which develop under Ca2+-overloaded conditions of the injured myocardium, are regarded as an important substrate for triggered arrhythmias. However, little is known about whether Ca2+ waves arise or become proarrhythmic in the injured heart in situ. On the hypothesis that injured myocardium manifests frequent Ca2+ waves and produce an oscillatory [Ca2+]i rise leading to triggered activity, we applied cryo-injury to the epicardial surface of fluo 3-AM-loaded perfused rat hearts and analyzed spatiotemporal [Ca2+]i changes at border zones of the injured myocardium using real-time confocal microscopy. In intact regions Ca2+ waves barely emerged, whereas the border zone myocardium exhibited frequent Ca2+ waves, propagating randomly within the individual cells. Two different types of Ca2+ waves were identified: highly frequent waves (159.6+/-86.5 waves/min/cell, n=266) adjacent to the cryo-ablated regions, and less frequent waves (79.0+/-50.1 waves/min/cell, n=160) slightly farther (>2 cells) away from the ablated regions (vicinities). The former Ca2+ waves emerged asynchronously to Ca2+ transients. Contrariwise, the latter depended on ventricular excitation: they vanished instantaneously on Ca2+ transients, but emerged more frequently and propagated more swiftly after cessation of higher-frequency pacing. Immediately after 3-Hz pacing, some cryo-injured hearts exhibited oscillatory [Ca2+]i rises; an instantaneous and synchronous elevation of [Ca2+]i followed by burst occurrence of Ca2+ waves with a gradual decrease in incidence and propagation velocity in a considerable number of cells. These observations indicate that myocardial injury induces Ca2+ waves in the heart, and that their synchronous occurrence could become a substrate for triggered arrhythmias.     

Ca2+ regulation in the Na+/Ca2+ exchanger features a dual electrostatic switch mechanism

Regulation of ion-transport in the Na⁺/Ca²⁺ exchanger (NCX) occurs via its cytoplasmic Ca²⁺-binding domains, CBD1 and CBD2. Here, we present a mechanism for NCX activation and inactivation based on data obtained using NMR, isothermal titration calorimetry (ITC) and small-angle X-ray scattering (SAXS). We initially determined the structure of the Ca²⁺-free form of CBD2-AD and the structure of CBD2-BD that represent the two major splice variant classes in NCX1. Although the apo-form of CBD2-AD displays partially disordered Ca²⁺-binding sites, those of CBD2-BD are entirely unstructured even in an excess of Ca²⁺. Striking differences in the electrostatic potential between the Ca²⁺-bound and -free forms strongly suggest that Ca²⁺-binding sites in CBD1 and CBD2 form electrostatic switches analogous to C₂-domains. SAXS analysis of a construct containing CBD1 and CBD2 reveals a conformational change mediated by Ca²⁺-binding to CBD1. We propose that the electrostatic switch in CBD1 and the associated conformational change are necessary for exchanger activation. The response of the CBD1 switch to intracellular Ca²⁺ is influenced by the closely located cassette exons. We further propose that Ca²⁺-binding to CBD2 induces a second electrostatic switch, required to alleviate Na⁺-dependent inactivation of Na⁺/Ca²⁺ exchange. In contrast to CBD1, the electrostatic switch in CBD2 is isoform- and splice variant-specific and allows for tailored exchange activities.     

Ca2+ release-activated Ca2+ channel blockade as a potential tool in antipancreatitis therapy

Alcohol-related acute pancreatitis can be mediated by a combination of alcohol and fatty acids (fatty acid ethyl esters) and is initiated by a sustained elevation of the Ca²⁺ concentration inside pancreatic acinar cells ([Ca²⁺]_i), due to excessive release of Ca²⁺ stored inside the cells followed by Ca²⁺ entry from the interstitial fluid. The sustained [Ca²⁺]_i elevation activates intracellular digestive proenzymes resulting in necrosis and inflammation. We tested the hypothesis that pharmacological blockade of store-operated or Ca²⁺ release-activated Ca²⁺ channels (CRAC) would prevent sustained elevation of [Ca²⁺]_i and therefore protease activation and necrosis. In isolated mouse pancreatic acinar cells, CRAC channels were activated by blocking Ca²⁺ ATPase pumps in the endoplasmic reticulum with thapsigargin in the absence of external Ca²⁺. Ca²⁺ entry then occurred upon admission of Ca²⁺ to the extracellular solution. The CRAC channel blocker developed by GlaxoSmithKline, GSK-7975A, inhibited store-operated Ca²⁺ entry in a concentration-dependent manner within the range of 1 to 50 μM (IC₅₀ = 3.4 μM), but had little or no effect on the physiological Ca²⁺ spiking evoked by acetylcholine or cholecystokinin. Palmitoleic acid ethyl ester (100 μM), an important mediator of alcohol-related pancreatitis, evoked a sustained elevation of [Ca²⁺]_i, which was markedly reduced by CRAC blockade. Importantly, the palmitoleic acid ethyl ester-induced trypsin and protease activity as well as necrosis were almost abolished by blocking CRAC channels. There is currently no specific treatment of pancreatitis, but our data show that pharmacological CRAC blockade is highly effective against toxic [Ca²⁺]_i elevation, necrosis, and trypsin/protease activity and therefore has potential to effectively treat pancreatitis.     

Distinct intracellular Ca2+ response to extracellular adenosine triphosphate in pancreatic beta-cells in rats and mice

Extracellular adenosine triphosphate (ATP) has distinct effects on insulin secretion from pancreatic β-cells between rats and mice. Using a confocal microscope, we compared changes between rats and mice in cytosolic free calcium concentration ([Ca²⁺]_c) in pancreatic β-cells stimulated by extracellular ATP. Extracellular ATP (50 μM) induced calcium release from intracellular calcium stores by activating P2Y receptors in both rat and mouse β-cells. The intracellular calcium release stimulated by extracellular ATP is significantly smaller in amplitude and longer in duration in rat β-cells than in mouse. In response to extracellular ATP, rat β-cells activate store-operated calcium entry following intracellular calcium release. This response is lacking in mouse β-cells. Rat and mouse β-cells both responded to 9 mM glucose by increasing [Ca²⁺]_c. This increase, however, was pronounced only in the rat β-cells. In 9 mM glucose, extracellular ATP induced a pro-nounced calcium release above the increased level of [Ca²⁺]_c in rat β-cells. In mouse β-cells, however, extracellular ATP did not exhibit calcium release on top of the increased level of [Ca²⁺]_c in 9 mM glucose. These results demonstrate distinct responses between rat and mouse β-cells to extracellular ATP under the condition of low and high glucose. Considering that extracellular ATP inhibits insulin secretion from mouse β-cells but stimulates insulin secretion from rat β-cells, we suggest that store-operated Ca²⁺ entry may be related to exocytosis in pancreatic rat β-cells.     

Beta-cell hubs maintain Ca2+ oscillations in human and mouse islet simulations

Islet β-cells are responsible for secreting all circulating insulin in response to rising plasma glucose concentrations. These cells are a phenotypically diverse population that express great functional heterogeneity. In mice, certain β-cells (termed ‘hubs’) have been shown to be crucial for dictating the islet response to high glucose, with inhibition of these hub cells abolishing the coordinated Ca²⁺ oscillations necessary for driving insulin secretion. These β-cell hubs were found to be highly metabolic and susceptible to pro-inflammatory and glucolipotoxic insults. In this study, we explored the importance of hub cells in human by constructing mathematical models of Ca²⁺ activity in human islets. Our simulations revealed that hubs dictate the coordinated Ca²⁺ response in both mouse and human islets; silencing a small proportion of hubs abolished whole-islet Ca²⁺ activity. We also observed that if hubs are assumed to be preferentially gap junction coupled, then the simulations better adhere to the available experimental data. Our simulations of 16 size-matched mouse and human islet architectures revealed that there are species differences in the role of hubs; Ca²⁺ activity in human islets was more vulnerable to hub inhibition than mouse islets. These simulation results not only substantiate the existence of β-cell hubs, but also suggest that hubs may be favorably coupled in the electrical and metabolic network of the islet, and that targeted destruction of these cells would greatly impair human islet function.     

Intracellular Ca2+ signaling and store-operated Ca2+ entry are required in Drosophila neurons for flight

Neuronal Ca²⁺ signals can affect excitability and neural circuit formation. Ca²⁺ signals are modified by Ca²⁺ flux from intracellular stores as well as the extracellular milieu. However, the contribution of intracellular Ca²⁺ stores and their release to neuronal processes is poorly understood. Here, we show by neuron-specific siRNA depletion that activity of the recently identified store-operated channel encoded by dOrai and the endoplasmic reticulum Ca²⁺ store sensor encoded by dSTIM are necessary for normal flight and associated patterns of rhythmic firing of the flight motoneurons of Drosophila melanogaster. Also, dOrai overexpression in flightless mutants for the Drosophila inositol 1,4,5-trisphosphate receptor (InsP₃R) can partially compensate for their loss of flight. Ca²⁺ measurements show that Orai gain-of-function contributes to the quanta of Ca²⁺-release through mutant InsP₃Rs and elevates store-operated Ca²⁺ entry in Drosophila neurons. Our data show that replenishment of intracellular store Ca²⁺ in neurons is required for Drosophila flight.     

Overexpression of diacylglycerol kinase zeta inhibits endothelin-1-induced decreases in Ca2+ transients and cell shortening in mouse ventricular myocytes

Endothelin-1 (ET-1) is released in various cardiovascular disorders including congestive heart failure, and may modulate significantly the disease process by its potent action on vascular and cardiac muscle cell function and gene regulation. In adult mouse ventricular cardiomyocytes loaded with indo-1, ET-1 induced a sustained negative inotropic effect (NIE) in association with decreases in Ca²⁺ transients. The ET-1-induced effects on Ca²⁺ transients and cell shortening were abolished in diacylglycerol (DAG) kinase ζ-overexpressing mouse ventricular myocytes. A nonselective protein kinase C (PKC) inhibitor, GF109203X, inhibited the ET-1-induced decreases in Ca²⁺ transients and cell shortening in concentration-dependent manners, whereas a selective Ca²⁺-dependent PKC inhibitor, Gö6976, did not affect the ET-1-induced effects. A phospholipase Cβ inhibitor, U73122, and an inhibitor of phospholipase D, C₂-ceramide, partially, but significantly, attenuated the ET-1-induced effects. Derivatives of the respective inhibitors with no specific effects, U73343 and dihydro-C₂-ceramide, did not affect the ET-1-induced effects. Taken together, these results indicate that activation of a Ca²⁺-independent PKC isozyme by 1,2-DAG, which is generated by phospholipase Cβ and phospholipase D activation and inactivated by phosphorylation via DAG kinase, is responsible for the ET-1-induced decreases in Ca²⁺ transients and cell shortening in mouse ventricular cardiomyocytes.     

Loss of luminal Ca2+ activation in the cardiac ryanodine receptor is associated with ventricular fibrillation and sudden death

Different forms of ventricular arrhythmias have been linked to mutations in the cardiac ryanodine receptor (RyR)2, but the molecular basis for this phenotypic heterogeneity is unknown. We have recently demonstrated that an enhanced sensitivity to luminal Ca(2+) and an increased propensity for spontaneous Ca(2+) release or store-overload-induced Ca(2+) release (SOICR) are common defects of RyR2 mutations associated with catecholaminergic polymorphic or bidirectional ventricular tachycardia. Here, we investigated the properties of a unique RyR2 mutation associated with catecholaminergic idiopathic ventricular fibrillation, A4860G. Single-channel analyses revealed that, unlike all other disease-linked RyR2 mutations characterized previously, the A4860G mutation diminished the response of RyR2 to activation by luminal Ca(2+), but had little effect on the sensitivity of the channel to activation by cytosolic Ca(2+). This specific impact of the A4860G mutation indicates that the luminal Ca(2+) activation of RyR2 is distinct from its cytosolic Ca(2+) activation. Stable, inducible HEK293 cells expressing the A4860G mutant showed caffeine-induced Ca(2+) release but exhibited no SOICR. Importantly, HL-1 cardiac cells transfected with the A4860G mutant displayed attenuated SOICR activity compared with cells transfected with RyR2 WT. These observations provide the first evidence that a loss of luminal Ca(2+) activation and SOICR activity can cause ventricular fibrillation and sudden death. These findings also indicate that although suppressing enhanced SOICR is a promising antiarrhythmic strategy, its oversuppression can also lead to arrhythmias.     

From the Cover: Salt stress-induced Ca2+ waves are associated with rapid,long-distance root-to-shoot signaling in plants

Their sessile lifestyle means that plants have to be exquisitely sensitive to their environment, integrating many signals to appropriate developmental and physiological responses. Stimuli ranging from wounding and pathogen attack to the distribution of water and nutrients in the soil are frequently presented in a localized manner but responses are often elicited throughout the plant. Such systemic signaling is thought to operate through the redistribution of a host of chemical regulators including peptides, RNAs, ions, metabolites, and hormones. However, there are hints of a much more rapid communication network that has been proposed to involve signals ranging from action and system potentials to reactive oxygen species. We now show that plants also possess a rapid stress signaling system based on Ca²⁺ waves that propagate through the plant at rates of up to ∼400 µm/s. In the case of local salt stress to the Arabidopsis thaliana root, Ca²⁺ wave propagation is channeled through the cortex and endodermal cell layers and this movement is dependent on the vacuolar ion channel TPC1. We also provide evidence that the Ca²⁺ wave/TPC1 system likely elicits systemic molecular responses in target organs and may contribute to whole-plant stress tolerance. These results suggest that, although plants do not have a nervous system, they do possess a sensory network that uses ion fluxes moving through defined cell types to rapidly transmit information between distant sites within the organism.Plants are constantly tailoring their responses to current environmental conditions via a complex array of chemical regulators that integrate developmental and physiological programs across the plant body. Environmental stimuli are often highly localized in nature, but the subsequent plant response is often elicited throughout the entire organism. For example, soil is a highly heterogeneous environment and the root encounters stimuli that are presented in a patchy manner. Thus, factors including dry or waterlogged regions of the soil, variations in the osmotic environment, and stresses such as elevated levels of salt are all likely to be encountered locally by individual root tips, but the information may have to be acted on by the plant as a whole.In animals, long-range signaling to integrate activities across the organism occurs through rapid ionic/membrane potential-driven signaling through the nervous system in addition to operating via long-distance chemical signaling. Plants have also been proposed to possess a rapid, systemic communication network, potentially mediated through signals ranging from changes in membrane potential/ion fluxes (1–3) and levels of reactive oxygen species (ROS) (4, 5) to altered hydraulics in the vasculature (6). Even so, the molecular mechanisms behind rapid, systemic signaling in plants and whether such signals indeed carry regulatory information remains largely unknown. Suggestions that Ca²⁺ channels play a role in signals that occlude sieve tube elements (7), or that mediate systemic electrical signaling (2) in response to remote wounding, highlight Ca²⁺-dependent signaling events as a strong candidate for mediating some of these long-range responses. Similarly, cooling of roots elicits Ca²⁺ increases in the shoot within minutes (8), suggesting systemic signals can elicit Ca²⁺-dependent responses at distal sites within the plant. However, despite extensive characterization of Ca²⁺ signals (reviewed in ref. 9), their roles in a possible plant-wide communication network remain poorly understood. Therefore, to visualize how Ca²⁺ might act in local and systemic signaling, we generated Arabidopsis plants expressing the highly sensitive, GFP-based, cytoplasmic Ca²⁺ sensor YCNano-65 (10). We observed that a range of abiotic stresses including H₂O₂, touch, NaCl, and cold shock triggered Ca²⁺ increases at the point of application. However, NaCl also elicited a Ca²⁺ increase that moved away from the point of stress application. Propagation of this Ca²⁺ increase was associated with subsequent systemic changes in gene expression. We also report that this salt stress-induced long-distance Ca²⁺ wave is dependent on the activity of the ion channel protein Two Pore Channel 1 (TPC1), which also appears to contribute to whole-plant stress tolerance.     

Ca2+ waves require sequential activation of inositol trisphosphate receptors and ryanodine receptors in pancreatic acini

BACKGROUND & AIMS: The inositol 1,4,5-trisphosphate (InsP3) receptor (InsP3R) and the ryanodine receptor (RyR) are the principal Ca2+-release channels in cells and are believed to serve distinct roles in cytosolic Ca2+ (Ca(i)2+) signaling. This study investigated whether these receptors instead can release Ca2+ in a coordinated fashion. METHODS: Apical and basolateral Ca(i)2+ signals were monitored in rat pancreatic acinar cells by time-lapse confocal microscopy. Caged forms of second messengers were microinjected into individual cells and then photoreleased in a controlled fashion by either UV or 2-photon flash photolysis. RESULTS: InsP3 increased Ca(i)2+ primarily in the apical region of pancreatic acinar cells, whereas the RyR agonist cyclic adenosine diphosphate ribose (cADPR) increased Ca(i)2+ primarily in the basolateral region. Apical-to-basal Ca(i)2+ waves were induced by acetylcholine and initiation of these waves was blocked by the InsP3R inhibitor heparin, whereas propagation into the basolateral region was inhibited by the cADPR inhibitor 8-amino-cADPR. To examine integration of apical and basolateral Ca(i)2+ signals, Ca2+ was selectively released either apically or basolaterally using 2-photon flash photolysis. Ca(i)2+ increases were transient and localized in unstimulated cells. More complex Ca(i)2+ signaling patterns, including polarized Ca(i)2+ waves, were observed when Ca2+ was photoreleased in cells stimulated with subthreshold concentrations of acetylcholine. CONCLUSIONS: Polarized Ca(i)2+ waves are induced in acinar cells by serial activation of apical InsP3Rs and then basolateral RyRs, and subcellular release of Ca2+ coordinates the actions of these 2 types of Ca2+ channels. This subcellular integration of Ca2+-release channels shows a new level of complexity in the formation of Ca(i)2+ waves.     

Crystal structure of Ca2+/H+ antiporter protein YfkE reveals the mechanisms of Ca2+ efflux and its pH regulation

Ca²⁺ efflux by Ca²⁺ cation antiporter (CaCA) proteins is important for maintenance of Ca²⁺ homeostasis across the cell membrane. Recently, the monomeric structure of the prokaryotic Na⁺/Ca²⁺ exchanger (NCX) antiporter NCX_Mj protein from Methanococcus jannaschii shows an outward-facing conformation suggesting a hypothesis of alternating substrate access for Ca²⁺ efflux. To demonstrate conformational changes essential for the CaCA mechanism, we present the crystal structure of the Ca²⁺/H⁺ antiporter protein YfkE from Bacillus subtilis at 3.1-Å resolution. YfkE forms a homotrimer, confirmed by disulfide crosslinking. The protonated state of YfkE exhibits an inward-facing conformation with a large hydrophilic cavity opening to the cytoplasm in each protomer and ending in the middle of the membrane at the Ca²⁺-binding site. A hydrophobic “seal” closes its periplasmic exit. Four conserved α-repeat helices assemble in an X-like conformation to form a Ca²⁺/H⁺ exchange pathway. In the Ca²⁺-binding site, two essential glutamate residues exhibit different conformations compared with their counterparts in NCX_Mj, whereas several amino acid substitutions occlude the Na⁺-binding sites. The structural differences between the inward-facing YfkE and the outward-facing NCX_Mj suggest that the conformational transition is triggered by the rotation of the kink angles of transmembrane helices 2 and 7 and is mediated by large conformational changes in their adjacent transmembrane helices 1 and 6. Our structural and mutational analyses not only establish structural bases for mechanisms of Ca²⁺/H⁺ exchange and its pH regulation but also shed light on the evolutionary adaptation to different energy modes in the CaCA protein family.     

Hyperpolarization induced by K+ channel openers inhibits Ca2+ influx and Ca2+ release in coronary artery

The vasodilating mechanisms of the K⁺ channel openers—cromakalim, pinacidil, nicorandil, KRN2391, and Ki4032—were examined by measurement of the cytoplasmic Ca²⁺ concentration ([Ca²⁺]_i) using the fura-2 method in canine or porcine coronary arterial smooth muscle. The five K⁺ channel openers all produced a reduction of [Ca²⁺]_i in 5 and 30 mM KCl physiological salt solution (PSS), the effects of which were antagonized by tetrabutylammonium (TBA) or glibenclamide, but failed to affect [Ca²⁺]_i in 45 and 90 mM MCl-PSS. Cromakalim and Ki4032 only partially inhibited the 30 mM KCl-induced contractures, whereas pinacidil, nicorandil, and KRN2391 nearly abolished contractions produced by high KCl-PSS. The increased [Ca²⁺]_i and force produced by a thromboxane A₂ analogue, U46619, were inhibited by K⁺ channel openers and verapamil. In the absence of extracellular Ca²⁺, U46619 induced a transient increase in [Ca²⁺]_i with a contraction, which is effectively inhibited by cromakalim and Ki4032. Their inhibitory effects were blocked by TBA and counteracted by 20 mM KCl-induced depolarization. Cromakalim and Ki4032 did not affect caffeine-induced Ca²⁺ release. Cromakalim reduced U46619-induced IP₃ production and TBA blocked this inhibitory effect. Thus, cromakalim and Ki4032 are more specific K⁺ channel openers than pinacidil, nicorandil, and KRN2391. The vasodilation related with a reduction of [Ca²⁺]_i produced by K⁺ channel openers is due to the hyperpolarization of the plasma membrane resulting in not only the closure of voltage-dependent Ca²⁺ channels but also inhibition of the production of IP₃ and Ca²⁺ release from intracellular stores related to stimulation of the thromboxane A₂ receptor.     

Extracellular polyamines regulate fluid secretion in rat colonic crypts via the extracellular calcium-sensing receptor

BACKGROUND AND AIMS: Polyamines are essential for the normal postnatal development, maintenance, and function of gastrointestinal epithelia. The extracellular Ca(2+) (Ca(2+)(o)/nutrient)-sensing receptor is expressed on both luminal and basolateral membranes of colonocytes, and, in other cell systems, this receptor has been shown to respond to polyamines. Thus, the Ca(2+)-sensing receptor could provide a mechanism for modulation of colonocyte function by dietary and systemic extracellular polyamines. In the present study, we investigated the interaction of polyamines, particularly spermine, and extracellular Ca(2+) on second messenger generation by, and on function of, rat distal colonic crypts. METHODS: Calcium-sensing receptor activation was assessed in colonic epithelial cells and intact crypts freshly isolated from distal colon by monitoring intracellular IP(3) and Ca(2+) accumulation using radioimmunoassay and Fluo-3 fluorometry, respectively. Interactions of extracellular Ca(2+) and spermine on regulation of both basal and forskolin-stimulated fluid transport were measured in crypts microperfused in vitro. RESULTS: Polyamine (spermine > spermidine > putrescine)-mediated enhancement of intracellular D-myo-inositol 1,4,5-trisphosphate (IP(3)) and Ca(2+) accumulation required extracellular Ca(2+), and the EC(50) for extracellular Ca(2+)-mediated activation of the calcium-sensing receptor was reduced by polyamines. Extracellular spermine modulated both basal and forskolin-stimulated fluid secretion in perfused colonic crypts, and the EC(50) for spermine-induced reduction in forskolin-stimulated fluid secretion was inversely dependent on extracellular Ca(2+) (Ca(2+)(o)). CONCLUSIONS: The interactions of extracellular Ca(2+) and polyamines on second messenger accumulation and fluid secretion support a role for the luminal and basolateral calcium-sensing receptors in mediating some of the effects of polyamines on distal colonic epithelial cells.     

Reduced phosphatidylinositol 4,5-bisphosphate synthesis impairs inner ear Ca2+ signaling and high-frequency hearing acquisition

Phosphatidylinositol phosphate kinase type 1γ (PIPKIγ) is a key enzyme in the generation of phosphatidylinositol 4,5-bisphosphate [PI(4,5)P(2)] and is expressed at high levels in the nervous system. Homozygous knockout mice lacking this enzyme die postnatally within 24 h, whereas PIPKIγ(+/-) siblings breed normally and have no reported phenotype. Here we show that adult PIPKIγ(+/-) mice have dramatically elevated hearing thresholds for high-frequency sounds. During the first postnatal week we observed a reduction of ATP-dependent Ca(2+) signaling activity in cochlear nonsensory cells. Because Ca(2+) signaling under these conditions depends on inositol-1,4,5-trisphosphate generation from phospholipase C (PLC)-dependent hydrolysis of PI(4,5)P(2), we conclude that (i) PIPKIγ is primarily responsible for the synthesis of the receptor-regulated PLC-sensitive PI(4,5)P(2) pool in the cell syncytia that supports auditory hair cells; (ii) spatially graded impairment of this signaling pathway in cochlear nonsensory cells causes a selective alteration in the acquisition of hearing in PIPKIγ(+/-) mice. This mouse model also suggests that PIPKIγ may determine the level of gap junction contribution to cochlear development.     

Quantification in crude homogenates of rat myocardial Na+, K+-and Ca2+-ATPase by K+ and Ca2+-dependent pNPPase. Age-dependent changes

Assays for complete quantification of Na⁺, K⁺-and Ca²⁺-ATPase in crude homogenates of rat ventricular myocardium by determination of K⁺-and Ca²⁺-dependentp-nitrophenyl phosphatase (pNPPase) activities were evaluated and optimized. Using these assays the total K⁺-and Ca²⁺-dependentpNPPase activities in ventricular myocardium of 11–12 week-old rats were found to be 2.98±0.10 and 0.29±0.02 mol×min^–1×g^–1 wet wt. (mean±SEM) (n=5), respectively. Coefficient of variance of interindividual determinations was 7 and 12%, respectively. The total Na⁺, K⁺-and Ca²⁺-ATPase concentrations were estimated to 2 and 10 nmol×g^–1 wet wt., respectively. Evaluation of a putative developmental variation revealed a biphasic age-related change in the rat myocardial Ca²⁺-dependentpNPPase activity with an increase from birth to around the third week of life followed by a decrease. By contrast, the K⁺-dependentpNPPase activity of the rat myocardium showed a decrease from birth to adulthood. It was excluded that the changes were simple out-come of variations in water and protein content of myocardium. Expressed per heart, the K⁺-and Ca²⁺-dependentpNPPase activity gradually increased to a plateau. The present assay for Na⁺, K⁺-ATPase quantification has the advantage over [³H] ouabain binding of being applicable on the ouabain-resistant rat myocardium, and is more simple and rapid than measurements of K⁺-dependent 3-0-methylfluorescein phosphatase (3-0-MFPase) in crude tissue homogenates. Furthermore, with few modifications thepNPPase assay allows quantification of Ca²⁺-ATPase on crude myocardial homogenates. Age-dependent changes in K⁺-and Ca²⁺-dependentpNPPase activities are of developmental interest and indicate the importance of close age match in studies of quantitative aspects of Na⁺, K⁺-and Ca²⁺-ATPase in excitable tissues.Abbreviations Na⁺, K⁺-ATPase sodium, potassium-dependent ATPase - Ca²⁺-ATPase caldium-dependent ATPase - pNP p-nitrophenyl - pNPP p-nitrophenyl phosphate - 3-0-MFP 3-0 methylfluorescein phosphate - DOC sodium deoxycholate