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Ca2+ Waves (ca2+ + wave)

Distribution by Scientific Domains

Life Sciences	80%
Medical Sciences	19%

Kinds of Ca2+ Waves

spontaneous ca2+ wave

Selected Abstracts

Spontaneous Ca2+ Waves in Rabbit Corpus Cavernosum: Modulation by Nitric Oxide and cGMP

THE JOURNAL OF SEXUAL MEDICINE, Issue 4 2009
Gerard P. Sergeant PhD
ABSTRACT Introduction., Detumescent tone and subsequent relaxation by nitric oxide (NO) are essential processes that determine the erectile state of the penis. Despite this, the mechanisms involved are incompletely understood. It is often assumed that the tone is associated with a sustained high cytosolic Ca2+ level in the corpus cavernosum smooth muscle cells, however, an alternative possibility is that oscillatory Ca2+ signals regulate tone, and erection occurs as a result of inhibition of Ca2+ oscillations by NO. Aims., The aim of this study is to determine if smooth muscle cells displayed spontaneous Ca2+ oscillations and, if so, whether these were regulated by NO. Methods., Male New Zealand white rabbits were euthanized and smooth muscle cells were isolated by enzymatic dispersal for confocal imaging of intracellular Ca2+ (using fluo-4AM) and patch clamp recording of spontaneous membrane currents. Thin tissue slices were also loaded with fluo-4AM for live imaging of Ca2+. Main Outcome Measure., Cytosolic Ca2+ was measured in isolated smooth muscle cells and tissue slices. Results., Isolated rabbit corpus cavernosum smooth muscle cells developed spontaneous Ca2+ waves that spread at a mean velocity of 65 µm/s. Dual voltage clamp/confocal recordings revealed that each of the Ca2+ waves was associated with an inward current typical of the Ca2+ -activated Cl - currents developed by these cells. The waves depended on an intact sarcoplasmic reticulum Ca2+ store, as they were blocked by cyclopiazonic acid (Calbiochem, San Diego, CA, USA) and agents that interfere with ryanodine receptors and IP3 -mediated Ca2+ release. The waves were also inhibited by an NO donor (diethylamine NO; Tocris Bioscience, Bristol, Avon, UK), 3-(5-hydroxymethyl-2-furyl)-1-benzyl indazole (YC-1) (Alexis Biochemicals, Bingham, Notts, UK), 8-bromo-cyclic guanosine mono-phosphate (Tocris), and sildenafil (Viagra, Pfizer, Sandwich, Kent, UK). Regular Ca2+ oscillations were also observed in whole tissue slices where they were clearly seen to precede contraction. This activity was also markedly inhibited by sildenafil, suggesting that it was under NO regulation. Conclusions., These results provide a new basis for understanding detumescent tone in the corpus cavernosum and its inhibition by NO. Sergeant GP, Craven M, Hollywood MA, McHale NG, and Thornbury KD. Spontaneous Ca2+ waves in rabbit corpus cavernosum: Modulation by nitric oxide and cGMP. J Sex Med **;**:**,**. [source]

Modulation of calcium signalling by intracellular organelles seen with targeted aequorins

ACTA PHYSIOLOGICA, Issue 1 2009
M. T. Alonso
Abstract The cytosolic Ca2+ signals that trigger cell responses occur either as localized domains of high Ca2+ concentration or as propagating Ca2+ waves. Cytoplasmic organelles, taking up or releasing Ca2+ to the cytosol, shape the cytosolic signals. On the other hand, Ca2+ concentration inside organelles is also important in physiology and pathophysiology. Comprehensive study of these matters requires to measure [Ca2+] inside organelles and at the relevant cytosolic domains. Aequorins, the best-known chemiluminescent Ca2+ probes, are excellent for this end as they do not require stressing illumination, have a large dynamic range and a sharp Ca2+ -dependence, can be targeted to the appropriate location and engineered to have the proper Ca2+ affinity. Using this methodology, we have evidenced the existence in chromaffin cells of functional units composed by three closely interrelated elements: (1) plasma membrane Ca2+ channels, (2) subplasmalemmal endoplasmic reticulum and (3) mitochondria. These Ca2+ -signalling triads optimize Ca2+ microdomains for secretion and prevent propagation of the Ca2+ wave towards the cell core. Oscillatory cytosolic Ca2+ signals originate also oscillations of mitochondrial Ca2+ in several cell types. The nuclear envelope slows down the propagation of the Ca2+ wave to the nucleus and filters high frequencies. On the other hand, inositol-trisphosphate may produce direct release of Ca2+ to the nucleoplasm in GH3 pituitary cells, thus providing mechanisms for selective nuclear signalling. Aequorins emitting at different wavelengths, prepared by fusion either with green or red fluorescent protein, permit simultaneous and independent monitorization of the Ca2+ signals in different subcellular domains within the same cell. [source]

Agonist-evoked Ca2+ wave progression requires Ca2+ and IP3

JOURNAL OF CELLULAR PHYSIOLOGY, Issue 2 2010
John G. McCarron
Smooth muscle responds to IP3 -generating agonists by producing Ca2+ waves. Here, the mechanism of wave progression has been investigated in voltage-clamped single smooth muscle cells using localized photolysis of caged IP3 and the caged Ca2+ buffer diazo-2. Waves, evoked by the IP3 -generating agonist carbachol (CCh), initiated as a uniform rise in cytoplasmic Ca2+ concentration ([Ca2+]c) over a single though substantial length (,30,µm) of the cell. During regenerative propagation, the wave-front was about 1/3 the length (,9,µm) of the initiation site. The wave-front progressed at a relatively constant velocity although amplitude varied through the cell; differences in sensitivity to IP3 may explain the amplitude changes. Ca2+ was required for IP3 -mediated wave progression to occur. Increasing the Ca2+ buffer capacity in a small (2,µm) region immediately in front of a CCh-evoked Ca2+ wave halted progression at the site. However, the wave front does not progress by Ca2+ -dependent positive feedback alone. In support, colliding [Ca2+]c increases from locally released IP3 did not annihilate but approximately doubled in amplitude. This result suggests that local IP3 -evoked [Ca2+]c increases diffused passively. Failure of local increases in IP3 to evoke waves appears to arise from the restricted nature of the IP3 increase. When IP3 was elevated throughout the cell, a localized increase in Ca2+ now propagated as a wave. Together, these results suggest that waves initiate over a surprisingly large length of the cell and that both IP3 and Ca2+ are required for active propagation of the wave front to occur. J. Cell. Physiol. 224: 334,344, 2010. © 2010 Wiley-Liss, Inc. [source]

Spontaneous oscillation and mechanically induced calcium waves in chondrocytes

CELL BIOCHEMISTRY AND FUNCTION, Issue 2 2006
Taisuke Kono
Abstract The characteristics of spontaneous calcium (Ca2+) oscillation and mechanically induced Ca2+ waves in articular chondrocytes were studied. In some, but not all, chondrocytes in sliced cartilage and primary cultures, we observed spontaneous oscillation of intracellular Ca2+ that never spread to adjacent cells. In contrast, a mechanical stimulus to a single cell by touching with a glass rod induced an increase of intracellular Ca2+ that spread to neighboring cells in a wave-like manner, even though there was no physical contact between the cells. This indicated the release of some paracrine factor from the mechanically stimulated cells. Application of ultrasonic vibration also induced an oscillation of intracellular Ca2+. The application of a uridine 5,-triphosphate (UTP), UTP, induced a transient increase in intracellular Ca2+ and the release of adenosine 5,-triphosphate (ATP) in cultured chondrocytes. A P2 receptor antagonist (suramin) and blockers of Cl, channels, niflumic acid and 4,4,-diisothiocyanostilbene-2,2,-disulfonic acid (DIDS), reduced the UTP-induced ATP release. The results indicated that Cl, channels were involved in the extracellular release of ATP following mechanical or P2Y receptor stimulation. Thus, ATP stimulation of P2Y receptors elicits an increase in intracellular Ca2+, triggering further release of ATP from adjacent cells, thereby expanding the Ca2+ wave in chondrocytes. Copyright © 2005 John Wiley & Sons, Ltd. [source]

Generation and propagation of gastric slow waves

CLINICAL AND EXPERIMENTAL PHARMACOLOGY AND PHYSIOLOGY, Issue 4 2010
Dirk F Van Helden
Summary 1. Mechanisms underlying the generation and propagation of gastrointestinal slow wave depolarizations have long been controversial. The present review aims to collate present knowledge on this subject with specific reference to slow waves in gastric smooth muscle. 2. At present, there is strong agreement that interstitial cells of Cajal (ICC) are the pacemaker cells that generate slow waves. What has been less clear is the relative role of primary types of ICC, including the network in the myenteric plexus (ICC-MY) and the intramuscular network (ICC-IM). It is concluded that both ICC-MY and ICC-IM are likely to serve a major role in slow wave generation and propagation. 3. There has been long-standing controversy as to how slow waves ,propagate' circumferentially and down the gastrointestinal tract. Two mechanisms have been proposed, one being action potential (AP)-like conduction and the other phase wave-based ,propagation' resulting from an interaction of coupled oscillators. Studies made on single bundle gastric strips indicate that both mechanisms apply with relative dominance depending on conditions; the phase wave mechanism is dominant under circumstances of rhythmically generating slow waves and the AP-like propagation is dominant when the system is perturbed. 4. The phase wave mechanism (termed Ca2+ phase wave) uses cyclical Ca2+ release as the oscillator, with coupling between oscillators mediated by several factors, including: (i) store-induced depolarization; (ii) resultant electrical current flow/depolarization through the pacemaker cell network; and (iii) depolarization-induced increase in excitability of downstream Ca2+ stores. An analogy is provided by pendulums in an array coupled together by a network of springs. These, when randomly activated, entrain to swing at the same frequency but with a relative delay along the row giving the impression of a propagating wave. 5. The AP-like mechanism (termed voltage-accelerated Ca2+ wave) propagates sequentially like a conducting AP. However, it is different in that it depends on regenerative store Ca2+ release and resultant depolarization rather than regenerative activation of voltage-dependent channels in the cell membrane. 6. The applicability of these mechanisms to describing propagation in large intact gastrointestinal tissues, where voltage-dependent Ca2+ entry is also likely to be functional, is discussed. [source]

Calmodulin kinase II initiates arrhythmogenicity during metabolic acidification in murine hearts

ACTA PHYSIOLOGICA, Issue 1 2009
T. H. Pedersen
Abstract Aim:, The multifunctional signal molecule calmodulin kinase II (CaMKII) has been associated with cardiac arrhythmogenesis under conditions where its activity is chronically elevated. Recent studies report that its activity is also acutely elevated during acidosis. We test a hypothesis implicating CaMKII in the arrhythmogenesis accompanying metabolic acidification. Methods:, We obtained monophasic action potential recordings from Langendorff-perfused whole heart preparations and single cell action potentials (AP) using whole-cell patch-clamped ventricular myocytes. Spontaneous sarcoplasmic reticular (SR) Ca2+release events during metabolic acidification were investigated using confocal microscope imaging of Fluo-4-loaded ventricular myocytes. Results:, In Langendorff-perfused murine hearts, introduction of lactic acid into the Krebs-Henseleit perfusate resulted in abnormal electrical activity and ventricular tachycardia. The CaMKII inhibitor, KN-93 (2 ,m), reversibly suppressed this spontaneous arrhythmogenesis during intrinsic rhythm and regular 8 Hz pacing. However, it failed to suppress arrhythmia evoked by programmed electrical stimulation. These findings paralleled a CaMKII-independent reduction in the transmural repolarization gradients during acidosis, which previously has been associated with the re-entrant substrate under other conditions. Similar acidification produced spontaneous AP firing and membrane potential oscillations in patch-clamped isolated ventricular myocytes when pipette solutions permitted cytosolic Ca2+ to increase following acidification. However, these were abolished by both KN-93 and use of pipette solutions that held cytosolic Ca2+ constant during acidosis. Acidosis also induced spontaneous Ca2+ waves in isolated intact Fluo-4-loaded myocytes studied using confocal microscopy that were abolished by KN-93. Conclusion:, These findings together implicate CaMKII-dependent SR Ca2+ waves in spontaneous arrhythmic events during metabolic acidification. [source]

Modulation of calcium signalling by intracellular organelles seen with targeted aequorins

Could chronic pain and spread of pain sensation be induced and maintained by glial activation?

ACTA PHYSIOLOGICA, Issue 1-2 2006
E. Hansson
Abstract An injury often starts with acute physiological pain, which becomes inflammatory or neuropathic, and may sometimes become chronic. It has been proposed recently that activated glial cells, astrocytes and microglia within the central nervous system could maintain the pain sensation even after the original injury or inflammation has healed, and convert it into chronic by altering neuronal excitability. Glial cell activation has also been proposed to be involved in the phenomenon of spread of pain sensation ipsilaterally or to the contralateral side (i.e. mirror image pain). Substance P and calcitonin gene-related peptide, released due to an inflammatory process, interact with the endothelial cells of the blood,spinal cord and blood,brain barriers. The barriers open partially and substances may influence adjacent glial cells. Such substances are also released from neurones carrying the ,pain message' all the way from the injury to the cerebral cortex. Pro-inflammatory cytokines may be released from the microglial cells, and astroglial Ca2+ -transients or oscillations may spread within the astroglial networks. One theory is that Ca2+ -oscillations could facilitate the formation of new synapses. These new synapses could establish neuronal contacts for maintaining and spreading the pain sensation. If this theory holds true, it is possible that Ca2+ waves, production of cytokines and growth factors could be modified by selective anti-inflammatory drugs to achieve a balance in the activities of the different intercellular and intracellular processes. This paper reviews current knowledge about glial mechanisms underlying the phenomena of chronic pain and spread of the pain sensation. [source]

Long-range oscillatory Ca2+ waves in rat spinal dorsal horn

EUROPEAN JOURNAL OF NEUROSCIENCE, Issue 8 2005
Ruth Ruscheweyh
Abstract Synchronous activity of large populations of neurons shapes neuronal networks during development. However, re-emergence of such activity at later stages of development could severely disrupt the orderly processing of sensory information, e.g. in the spinal dorsal horn. We used Ca2+ imaging in spinal cord slices of neonatal and young rats to assess under which conditions synchronous activity occurs in dorsal horn. No spontaneous synchronous Ca2+ transients were detected. However, increasing neuronal excitability by application of 4-aminopyridine after pretreatment of the slice with blockers of (RS)-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)/kainate, ,-aminobutyric acid (GABA)A and glycine receptors evoked repetitive Ca2+ waves in dorsal horn. These waves spread mediolaterally with a speed of 1.0 ± 0.1 mm/s and affected virtually every dorsal horn neuron. The Ca2+ waves were associated with large depolarizing shifts of the membrane potential of participating neurons and were most likely synaptically mediated because they were abolished by blockade of action potentials or N -methyl- d -aspartate (NMDA) receptors. They were most pronounced in the superficial dorsal horn and absent from the ventral horn. A significant proportion of the Ca2+ waves spread to the contralateral dorsal horn. This seemed to be enabled by disinhibition as primary afferent-induced dorsal horn excitation crossed the midline only when GABAA and glycine receptors were blocked. Interestingly, the Ca2+ waves occurred under conditions where AMPA/kainate receptors were blocked. Thus, superficial dorsal horn NMDA receptors are able to sustain synchronous neuronal excitation in the absence of functional AMPA/kainate receptors. [source]

Failure of Ca2+ -activated, CREB-dependent transcription in astrocytes

GLIA, Issue 8 2009
Peter D. Murray
Abstract Astrocytes participate in signaling via Ca2+ transients that spread from cell to cell across a multicellular syncytium. The effect, if any, of these Ca2+ waves on the transcription of Ca2+/cAMP-regulatory element binding protein (CREB)-dependent genes is not known. We report here that, unlike neurons, increasing intracellular Ca2+ in cultured mouse cortical astrocytes failed to activate CREB-dependent transcription, even though CREB was phosphorylated at serine 133. In contrast, both CREB phosphorylation and CREB-dependent transcription were robustly stimulated by increasing cAMP. The failure of Ca2+ -activated transcription in astrocytes was correlated with the absence of CaMKIV, a Ca2+ -dependent protein kinase required for Ca2+ -stimulated gene transcription in neurons. The inability of Ca2+ to signal via CaMKIV may insulate CREB-dependent gene transcription in astrocytes from activation by Ca2+ waves. © 2008 Wiley-Liss, Inc. [source]

Calcium signaling in specialized glial cells,

GLIA, Issue 7 2006
Monica R. Metea
Abstract This article reviews calcium signaling in three specialized types of glial cells: Müller cells of the retina, Bergmann glial cells of the cerebellum, and radial glial cells of the developing cortex. Müller cells generate spontaneous and neuronal activity-evoked increases in Ca2+. Neuron to Müller cell signaling is mediated by neuronal release of ATP and activation of glial P2Y receptors. Müller cells, in turn, modulate neuronal excitability and mediate vasomotor responses. Bergmann glial cells also generate spontaneous and activity-evoked Ca2+ increases. Neuron to Bergmann glia signaling is mediated by neuronal release of nitric oxide, noradrenaline, and glutamate. In Bergmann glia, Ca2+ increases control the structural and functional interactions between these cells and Purkinje cell synapses. In the ventricular zone of the developing cortex, radial glial cells generate spontaneous Ca2+ increases that propagate as Ca2+ waves through clusters of neighboring glial cells. These Ca2+ increases control cell proliferation and neurogenesis. © 2006 Wiley-Liss, Inc. [source]

Agonist-evoked Ca2+ wave progression requires Ca2+ and IP3

Role of mitochondria in modulation of spontaneous Ca2+ waves in freshly dispersed interstitial cells of Cajal from the rabbit urethra

THE JOURNAL OF PHYSIOLOGY, Issue 19 2008
Gerard P. Sergeant
Interstitial cells of Cajal (ICC) isolated from the rabbit urethra exhibit pacemaker activity that results from spontaneous Ca2+ waves. The purpose of this study was to investigate if this activity was influenced by Ca2+ uptake into mitochondria. Spontaneous Ca2+ waves were recorded using a Nipkow spinning disk confocal microscope and spontaneous transient inward currents (STICs) were recorded using the whole-cell patch clamp technique. Disruption of the mitochondrial membrane potential with the electron transport chain inhibitors rotenone (10 ,m) and antimycin A (5 ,m) abolished Ca2+ waves and increased basal Ca2+ levels. Similar results were achieved when mitochondria membrane potential was collapsed using the protonophores FCCP (0.2 ,m) and CCCP (1 ,m). Spontaneous Ca2+ waves were not inhibited by the ATP synthase inhibitor oligomycin (1 ,m), suggesting that these effects were not attributable to an effect on ATP levels. STICs recorded under voltage clamp at ,60 mV were also inhibited by CCCP and antimycin A. Dialysis of cells with the mitochondrial uniporter inhibitor RU360 (10 ,m) also inhibited STICS. Stimulation of Ca2+ uptake into mitochondria using the plant flavonoid kaempferol (10 ,m) induced a series of propagating Ca2+ waves. The kaempferol-induced activity was inhibited by application of caffeine (10 mm) or removal of extracellular Ca2+, but was not significantly affected by the IP3 receptor blocker 2-APB (100 ,m). These data suggest that spontaneous Ca2+ waves in urethral ICC are regulated by buffering of cytoplasmic Ca2+ by mitochondria. [source]

Mitochondrial modulation of Ca2+ sparks and transient KCa currents in smooth muscle cells of rat cerebral arteries

THE JOURNAL OF PHYSIOLOGY, Issue 3 2004
Serguei Y. Cheranov
Mitochondria sequester and release calcium (Ca2+) and regulate intracellular Ca2+ concentration ([Ca2+]i) in eukaryotic cells. However, the regulation of different Ca2+ signalling modalities by mitochondria in smooth muscle cells is poorly understood. Here, we investigated the regulation of Ca2+ sparks, Ca2+ waves and global [Ca2+]i by mitochondria in cerebral artery smooth muscle cells. CCCP (a protonophore; 1 ,m) and rotenone (an electron transport chain complex I inhibitor; 10 ,m) depolarized mitochondria, reduced Ca2+ spark and wave frequency, and elevated global [Ca2+]i in smooth muscle cells of intact arteries. In voltage-clamped (,40 mV) cells, mitochondrial depolarization elevated global [Ca2+]i, reduced Ca2+ spark amplitude, spatial spread and the effective coupling of sparks to large-conductance Ca2+ -activated potassium (KCa) channels, and decreased transient KCa current frequency and amplitude. Inhibition of Ca2+ sparks and transient KCa currents by mitochondrial depolarization could not be explained by a decrease in intracellular ATP or a reduction in sarcoplasmic reticulum Ca2+ load, and occurred in the presence of diltiazem, a voltage-dependent Ca2+ channel blocker. Ru360 (10 ,m), a mitochondrial Ca2+ uptake blocker, and lonidamine (100 ,m), a permeability transition pore (PTP) opener, inhibited transient KCa currents similarly to mitochondrial depolarization. In contrast, CGP37157 (10 ,m), a mitochondrial Na+,Ca2+ exchange blocker, activated these events. The PTP blockers bongkrekic acid and cyclosporin A both reduced inhibition of transient KCa currents by mitochondrial depolarization. These results indicate that mitochondrial depolarization leads to a voltage-independent elevation in global [Ca2+]i and Ca2+ spark and transient KCa current inhibition. Data also suggest that mitochondrial depolarization inhibits Ca2+ sparks and transient KCa currents via PTP opening and a decrease in intramitochondrial [Ca2+]. [source]