Localized and transient elevations of intracellular Ca2+ induce the dedifferentiation of axonal segments into growth cones

The formation of a growth cone at the tip of a severed axon is a key step in its successful regeneration. This process involves major structural and functional alterations in the formerly differentiated axonal segment. Here we examined the hypothesis that the large, localized, and transient elevation in the free intracellular calcium concentration ([Ca2+]i) that follows axotomy provides a signal sufficient to trigger the dedifferentiation of the axonal segment into a growth cone. Ratiometric fluorescence microscopy and electron microscopy were used to study the relations among spatiotemporal changes in [Ca2+]i, growth cone formation, and ultrastructural alterations in axotomized and intact Aplysia californica neurons in culture. We report that, in neurons primed to grow, a growth cone forms within 10 min of axotomy near the tip of the transected axon. The nascent growth cone extends initially from a region in which peak intracellular Ca2+ concentrations of 300-500 microM are recorded after axotomy. Similar [Ca2+]i transients, produced in intact axons by focal applications of ionomycin, induce the formation of ectopic growth cones and subsequent neuritogenesis. Electron microscopy analysis reveals that the ultrastructural alterations associated with axotomy and ionomycin-induced growth cone formation are practically identical. In both cases, growth cones extend from regions in which sharp transitions are observed between axoplasm with major ultrastructural alterations and axoplasm in which the ultrastructure is unaltered. These findings suggest that transient elevations of [Ca2+]i to 300-500 microM, such as those caused by mechanical injury, may be sufficient to induce the transformation of differentiated axonal segments into growth cones.     

Effects of glibenclamide on blood pressure and cardiovascular responsiveness in non-insulin dependent diabetes mellitus

1. The incubation of mouse isolated diaphragm with guanidine for 60 min produced ultrastructural changes in the neuromuscular junction, the intramuscular fascicles of the phrenic nerve and the skeletal muscle fibers. 2. The main morphological characteristics of both the end terminals and the nerve fibers were a swollen appearance and an electron-lucent axoplasm. In addition, the mitochondria in these regions were markedly swollen and showed a rarefaction of their cristae as well as a "washed aspect" of their matrix. Occasional periaxonal vacuoles were present in the myelinated axons. There was a reduction in the number of synaptic vesicles, which was accentuated by the enlarged areas of the majority of the terminals. 3. Muscle cells underwent a range of morphological alterations in the myofibrils and mitochondria. The most drastic type of necrosis affecting these cells was complete dissolution of the myofibrils, which resulted in an apparently "empty" cell with only the sarcolemma and a few mitochondria remaining intact. 4. Tetrodotoxin was unable to provide total protection against these guanidine-induced changes. 5. We conclude that the ultrastructural effects evoked by guanidine may be associated with modifications in the permeability of the axolemmal and sarcolemmal membranes as a result of changes in ionic conductance. Such ionic disturbances also interfere with the metabolism of mitochondria and the sarcoplasmic reticulum and may account for the well-known inhibitory effect of guanidine on K+ channels and consequently on Ca2+ and Na+ conductances. 6. It is also suggested that the guanidine-induced alterations in the presynaptic and postsynaptic sites could have independent mechanisms of action.     

Protection of the axonal cytoskeleton in anoxic optic nerve by decreased extracellular calcium

Since CNS white matter tracts contain axons, oligodendrocytes and astrocytes but not synapses, it is likely that anoxic injury of white matter is mediated by cellular mechanisms that do not involve synapses. In order to test the hypothesis, that anoxic injury of white matter is mediated by an influx of Ca2+ into the intracellular compartment of axons, we compared the ultrastructure of axons in rat optic nerve exposed to 60 min of anoxia in artificial cerebrospinal fluid (aCSF) containing normal (2 mM) Ca2+, and in aCSF containing zero-Ca2+ together with 5 mM EGTA. Optic nerves fixed at the end of 60 min of anoxia in 2 mM Ca2+ exhibit extensive ultrastructural alterations including disruption of microtubules and neurofilaments within the axonal cytoskeleton, development of membranous profiles and empty spaces between the axon and the ensheathing myelin, and swelling of mitochondria with loss of cristae. Bathing the nerves in zero-Ca2+ aCSF during anoxia protected the axons from cytoskeletal changes; after 60 min of anoxia, optic nerve axons retained normal-appearing microtubules and neurofilaments. Membranous profiles were rare, and empty spaces between axons and myelin did not develop in anoxic optic nerves bathed in zero-Ca2+ aCSF. Disorganization of cristae in axonal mitochondria was observed in anoxic optic nerves even when Ca2+ was omitted from the medium. Because Ca(2+)-mediated injury is known to disrupt the axonal cytoskeleton, these results support the hypothesis that anoxia triggers an abnormal influx of Ca2+ into myelinated axons in CNS white matter.     

Steady-state calcium fluxes: membrane versus mitochondrial control of ionized calcium in axoplasm

Squid axons appear in a steady state with respect to ionized Ca when [Ca]o is ca. 3 mM and [Ca]i is ca. 30 nM. A membrane pump energized by the Na gradient across the membrane is capable of maintaining this ratio of ionized Ca if four Na enter per Ca extruded. Empirically, it is noted that if the difference between the electrochemical gradient for Na+ and that for Ca2+ is large and positive, Ca efflux is large; for a large but negative difference in the gradient, Ca influx is large. Net fluxes of Ca into the fiber are induced by Na-free solutions or stimulation. These are buffered in axoplasm principally by a high affinity Ca buffer. Mitochondria apparently do not contain large amounts of stored Ca as CN poisoning does not increase ionized Ca in axoplasm if the seawater is Ca-free.     

Ultrastructural co-localization of calmodulin and B-50/growth-associated protein-43 at the plasma membrane of proximal unmyelinated axon shafts studied in the model of the regenerating rat sciatic nerve

Calmodulin and de-phosphorylated B-50/growth-associated protein-43 (GAP-43) have been shown to bind in vitro in a molecular complex, but evidence for an in situ association in the nervous system does not exist. Previously, we have reported that, in the model of the regenerating rat sciatic nerve, the B-50/GAP-43 immunoreactivity is increased and concentrated at the axolemma of unmyelinated axons located proximal to the site of injury and axon outgrowth. To explore a putative function of B-50/GAP-43, namely, the capacity of binding calmodulin to the plasma membrane, we examined the ultrastructural distribution of calmodulin in the proximal unmyelinated axon shafts of this model, using double immunolabelling and detection by fluorescent or gold probes conjugated to second antibodies. Immunofluorescence showed that seven days post-sciatic nerve crush the calmodulin immunoreactivity, similar to B-50/GAP-43 immunoreactivity, was intense in unmyelinated axon shafts located proximal to the site of injury of the regenerating nerve. Ultrastructurally, calmodulin was located at the axolemma of these regenerating unmyelinated axon shafts and inside the axoplasm, where it was associated with vesicles and microtubules. The plasma membrane labelling (approximately 69%) was significantly higher than the axoplasmic labelling. Over 60% of the plasma membrane-associated calmodulin co-localized with B-50/GAP-43 in a non-random distribution. Since normally calmodulin is largely present in the cytoplasm, these data suggest that calmodulin has been concentrated at the plasma membrane of unmyelinated axons, most probably by B-50/GAP-43. If the concentrating effect is due to B-50/GAP-43, then there is a possibility that these proteins may be present as a molecular complex in situ. The physiological significance could be that this association regulates the local availability of both B-50/GAP-43 and calmodulin for other interactions.     

Differential membrane-binding and activation mechanisms of protein kinase C-alpha and -epsilon

To elucidate the mechanisms of membrane binding and activation of conventional and novel protein kinase C (PKC), we measured the interactions of rat PKC-alpha and -epsilon with phospholipid monolayers and vesicles of various compositions. Besides the established difference in calcium requirement, the two isoforms showed major differences in their membrane-binding and activation mechanisms. For PKC-alpha, diacylglycerol (DG) specifically enhanced the binding of PKC-alpha to phosphatidylserine (PS)-containing vesicles by 2 orders of magnitude, allowing PKC-alpha high specificity for PS. Also, PKC-alpha could penetrate into the phospholipid monolayer with a packing density comparable to that of the cell membrane only in the presence of Ca2+ and PS. When compared to PKC-alpha, PKC-epsilon had lower binding affinity for PS-containing vesicles both in the presence and in the absence of DG. As a result, PKC-epsilon did not show pronounced specificity for PS. Also, PKC-epsilon showed reduced penetration into PS-containing monolayers, which was comparable to the Ca2+-independent penetration of PKC-alpha into the same monolayers. Taken together, these results suggest the following: (1) The role of Ca2+ in the membrane binding of PKC-alpha is to expose a specific PS-binding site. (2) Once bound to membrane surfaces, PS specifically induces the partial membrane penetration of PKC-alpha that allows its optimal interactions with DG, hence the enhanced membrane binding and activation. (3) PKC-epsilon, due to the lack of Ca2+ binding, cannot specifically interact with PS and DG, which implies the presence of other physiological activator(s) for this isoform.     

NMDA receptor-mediated control of presynaptic calcium and neurotransmitter release

Before action potential-evoked Ca2+ transients, basal presynaptic Ca2+ concentration may profoundly affect the amplitude of subsequent neurotransmitter release. Reticulospinal axons of the lamprey spinal cord receive glutamatergic synaptic input. We have investigated the effect of this input on presynaptic Ca2+ concentrations and evoked release of neurotransmitter. Paired recordings were made between reticulospinal axons and the neurons that make axo-axonic synapses onto those axons. Both excitatory and inhibitory paired-cell responses were recorded in the axons. Excitatory synaptic inputs were blocked by the AMPA receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 10 microM) and by the NMDA receptor antagonist 2-amino-5-phosphonopentanoate (AP-5; 50 microM). Application of NMDA evoked an increase in presynaptic Ca2+ in reticulospinal axons. Extracellular stimulation evoked Ca2+ transients in axons when applied either directly over the axon or lateral to the axons. Transients evoked by the two types of stimulation differed in magnitude and sensitivity to AP-5. Simultaneous microelectrode recordings from the axons during Ca2+ imaging revealed that stimulation of synaptic inputs directed to the axons evoked Ca2+ entry. By the use of paired-cell recordings between reticulospinal axons and their postsynaptic targets, NMDA receptor activation was shown to enhance evoked release of transmitter from the axons that received axoaxonic inputs. When the synaptic input to the axon was stimulated before eliciting an action potential in the axon, transmitter release from the axon was enhanced. We conclude that NMDA receptor-mediated input to reticulospinal axons increases basal Ca2+ within the axons and that this Ca2+ is sufficient to enhance release from the axons.     

Sensory terminals on extrafusal muscle fibres in myotendinous regions of developing rat muscles

Axon terminals were observed to form neuromuscular contacts with extrafusal muscle fibres in myotendinous regions of developing rat muscles up to 5 days after birth. These neuromuscular contacts are found in fascicles of muscle fibres connected with differentiating Golgi tendon organs. Axon terminals establishing these contacts are obviously sensory, since they do not degenerate after de-efferentation performed in neonatal rats. The terminals contain mainly clear and dense core vesicles and form neuromuscular connections resembling developing motor endplates, with a cleft about 60 nm wide and basal lamina interposed between the axolemma and the sarcolemma. Each terminal, however, also forms a close contact in a restricted region where the basal lamina is missing; there the cleft is reduced to 20 nm and the axolemmal and sarcolemmal membranes are linked by desmosome-like attachment plaques. After the fifth postnatal day, axon terminals become detached from muscle fibres and are only found among collagen bundles of the tendon organ. The functional significance of these temporary neuromuscular contacts is not clear.     

Identification of separate receptors for adenosine and adenosine 5''-triphosphate in causing relaxations of the isolated taenia of the guinea-pig caecum

An ultrastructural investigation showed that there was a neurohaemal organ in the wall of the ampulla of the antennal pulsatile organ. The neurosecretory axon terminals occurred singly or in small groups, rather than closely packed together as in other neurohaemal organs. All axons contained the same type of neurosecretory granule. The granules had varying electron density and a diameter in the range 1000-2500 A. Some terminals contained small, elliptical electron-transparent vesicles and the axolemma was apposed to the stroma. Other terminals were large and enveloped by glial tissue and the contents of the terminals exhibited varying degrees of autolytic degeneration. Autolysis was characterized by the occurrence of dense bodies and multilaminate bodies which enclosed mitochondria and neurosecretory granules. It was suggested that the neurosecretory material affects antennal function.     

Stimulatory effect of regucalcin on ATP-dependent calcium transport in rat liver plasma membranes

The effect of regucalcin, a calcium-binding protein isolated from rat liver cytoplasm, on ATP-dependent calcium transport in the plasma membrane vesicles of rat liver was investigated. (Ca(2+)- Mg2+)-ATPase activity in the liver plasma membranes was significantly increased by the presence of regucalcin (0.1-0.5 microM) in the enzyme reaction mixture. This increase was completely inhibited by the presence of sulfhydryl group modifying reagent Nethylmaleimide (5.0 mM NEM) or digitonin (0.04%), which can solubilize the membranous lipids. When ATP-dependent calcium uptake by liver plasma membrane vesicles was measured by using 45CaCl2, the presence of regucalcin (0.1-0.5 microM) in the reaction mixture caused a significant increase in the 45Ca2+ uptake. This increase was about 2-fold with 0.5 microM regucalcin addition. An appreciable increase was seen by 5 min incubation with regucalcin addition. The regucalcin-enhanced ATP-dependent 45Ca2+ uptake by the plasma membrane vesicles was completely inhibited by the presence of NEM (5.0 mM) or digitonin (0.04%). These results demonstrate that regucalcin activates (Ca(2+)-Mg2+)-ATPase in the liver plasma membranes and that it can stimulate ATP-dependent calcium transport across the plasma membranes.     

Frequent detection of Kaposi''s sarcoma-associated herpesvirus (human herpesvirus 8) DNA in saliva of human immunodeficiency virus-infected men: clinical and immunologic correlates

Extracellular Ca2+ mediates the cellular and molecular responses to cell stimulation of Chlamydomonas reinhardtii. Extracellular Ca2+ concentrations ([Ca2+]e) must exceed certain threshold values to support flagellar excision by acid shock and to stimulate flagellar outgrowth following mechanical shear of the flagella. Also, the magnitude and duration of flagellar RNA accumulations following acid shock or mechanical shear increase with increasing [Ca2+]e. To better understand the role of Ca2+ in flagellar excision, RNA induction, and outgrowth, we have performed a survey of the ion selectivity of each of these responses to acid shock. We found that flagellar excision in vivo following acid shock was supported by Sr2+ and Ca2+, but no other ion tested. LaCl3 and neomycin prevented flagellar excision following acid shock of cells in Ca2+- or Sr2+-containing buffer. Sr2+ addition to detergent-permeabilized cell models, however, failed to elicit flagellar excision in vitro. Cells failed to regrow flagella following flagellar excision in Sr2+-containing buffer unless exogenous Ca2+ was added. Flagellar RNA accumulations of lower magnitude and shorter duration were measured in cells acid-shocked in Sr2+-containing buffer than in Ca2+-containing buffer. These results demonstrate that a Sr2+ influx can evoke flagellar excision following acid shock, but cannot directly activate the machinery for flagellar excision, suggesting that a Sr2+ influx induces excision by stimulating an intracellular Ca2+ release. Furthermore, they suggest that flagellar outgrowth and normal flagellar RNA induction have a strict requirement for Ca2+, which is not satisfied by the proposed intracellular Ca2+ release.     

Ca2+-induced deprotonation of peptide hormones inside secretory vesicles in preparation for release

The acidic environment inside secretory vesicles ensures that neuropeptides and peptide hormones are packaged in a concentrated condensed form. Although this is optimal for storage, decondensation limits release. Thus, it would be advantageous to alter the physical state of peptides in preparation for exocytosis. Here, we report that depolarization of the plasma membrane rapidly increases enhanced green fluorescent protein (EGFP)-tagged hormone fluorescence inside secretory vesicles. This effect requires Ca2+ influx and persists when exocytosis is inhibited by N-ethylmaleimide. Peptide deprotonation appears to produce this response, because it is not seen when the vesicle pH gradient is collapsed or when a pH-insensitive GFP variant is used. These data demonstrate that Ca2+ evokes alkalinization of the inside of secretory vesicles before exocytosis. Thus, Ca2+ influx into the cytoplasm alters the physical state of intravesicular contents in preparation for release.     

Similarity in calcium channel activity of annexin V and matrix vesicles in planar lipid bilayers

Matrix vesicles (MVs), structures that accumulate Ca2+ during the initiation of mineral formation in growing bone, are rich in annexin V. When MVs are fused with planar phospholipid bilayers, a multiconductance Ca2+ channel is formed, with activity essentially identical to that observed when annexin V is delivered to the bilayer with phosphatidylserine liposomes. Ca2+ currents through this channel, from either MV or annexin V liposomes, are blocked by Zn2+, as is Ca2+ uptake by MV incubated in synthetic cartilage lymph. Blockage by Zn2+ was most effective when applied to the side containing the MV or liposomes. ATP and GTP differentially modulated the activity of this channel: ATP increased the amplitude of the current and the number of conductance states; GTP dramatically reduced the number of events and conductance states, leading to well-defined Ca2+ channel activity from either MV or the annexin V liposomes. In the distinctive effects of ATP, GTP, and Zn2+ on the Ca2+ channel activity observed in both the MV and the liposome systems, the common factor was the presence of annexin V. From this we conclude that Ca2+ entry into MV results from the presence of annexin V in these membrane-enclosed structures.     

The interaction between cytoplasmic dynein and dynactin is required for fast axonal transport

Fast axonal transport is characterized by the bidirectional, microtubule-based movement of membranous organelles. Cytoplasmic dynein is necessary but not sufficient for retrograde transport directed from the synapse to the cell body. Dynactin is a heteromultimeric protein complex, enriched in neurons, that binds to both microtubules and cytoplasmic dynein. To determine whether dynactin is required for retrograde axonal transport, we examined the effects of anti-dynactin antibodies on organelle transport in extruded axoplasm. Treatment of axoplasm with antibodies to the p150(Glued) subunit of dynactin resulted in a significant decrease in the velocity of microtubule-based organelle transport, with many organelles bound along microtubules. We examined the molecular mechanism of the observed inhibition of motility, and we demonstrated that antibodies to p150(Glued) disrupted the binding of cytoplasmic dynein to dynactin and also inhibited the association of cytoplasmic dynein with organelles. In contrast, the anti-p150(Glued) antibodies had no effect on the binding of dynactin to microtubules nor on cytoplasmic dynein-driven microtubule gliding. These results indicate that the interaction between cytoplasmic dynein and the dynactin complex is required for the axonal transport of membrane-bound vesicles and support the hypothesis that dynactin may function as a link between the organelle, the microtubule, and cytoplasmic dynein during vesicle transport.     

Local anaesthetic bupivacaine alters function of sarcoplasmic reticulum and sarcolemmal vesicles from rabbit masseter muscle

The effects of local anaesthetics, bupivacaine and lidocaine, on Ca2+ flux behaviour of sarcoplasmic reticulum and on sarcolemmal functions were studied in the rabbit masseter muscle. The experiments were performed on sarcoplasmic reticulum and sarcolemmal vesicles prepared at 1 to 10 days after injection of local anaesthetics or saline into masseter muscle as well as on sarcoplasmic reticulum vesicles prepared from non-treated rabbits (for assessment of the effect on in vitro incubation with local anaesthetics). Bupivacaine potently reduced the efficiency of active sarcoplasmic reticulum Ca2+ transport as evaluated by coupling ratio (Ca2+ transported/ATP hydrolyzed, in the presence of oxalate) at 3 days after the injection; there was only a slight degree of uncoupling of Ca2+ transport from ATP hydrolysis with lidocaine injection. Bupivacaine but not lidocaine, at 3 days after injection, decreased both the apparent permeability of sarcoplasmic reticulum vesicles to Ca2+, determined by measuring net efflux of Ca2+ after stopping pump-mediated fluxes, and the steady-state Ca2+ load in sarcoplasmic reticulum, but had no effect on overall turnover of the Ca2+ATPase. The effects of bupivacaine on apparent sarcoplasmic reticulum Ca2+ permeability and steady-state Ca2+ load were inhibited by a Ca2+ antagonist verapamil. The reduction of Ca2+ uptake of sarcoplasmic reticulum and the protective effect of verapamil were reproduced in unfractionated homogenates prepared at 3 days after bupivacaine injection. In vitro exposure of sarcoplasmic reticulum vesicles to bupivacaine (0.5 to 50 mM) reduced steady-state Ca2+ load in a dose-dependent manner. The observed effect elicited by bupivacaine (25 mM) was partially protected by procaine, an inhibitor of Ca2(+)-induced Ca2+ release from sarcoplasmic reticulum, or by specific closure of the sarcoplasmic reticulum Ca2+ release channel by ryanodine, suggesting the possibility that in vitro exposure of sarcoplasmic reticulum vesicles to bupivacaine may produce an increase in apparent permeability of sarcoplasmic reticulum to Ca2+. In sarcolemma, bupivacaine reduced Na+,K(+)-ATPase and Na(+)-Ca2+ exchange activities at 3 days after injection; the effects on sarcolemmal vesicles were prevented by verapamil. These results suggest that although the effects elicited by bupivacaine injection and the in vitro exposure to bupivacaine on steady-state Ca2+ load of sarcoplasmic reticulum vesicles were similar, the membrane properties of the vesicles from bupivacaine-treated masseter muscles and those from normal untreated muscles may not be the same, which indicates that pure bupivacaine effect is due partly by an effect on ryanodine- and procaine-sensitive Ca2+ channels.(ABSTRACT TRUNCATED AT 400 WORDS)     

Dissociation of Ca2+ accumulation from protein release in calcium paradox: effect of barium

Experiments were undertaken to establish whether Ba2+ can substitute for Ca2+ in maintaining the structural and functional integrity of the glycocalyx. Adult rat hearts were perfused with Ca2+-free buffer at 37 degrees C, with and without added Ba2+. Ten minutes later Ba2+-free, Ca-containing medium was reintroduced. Hearts that had been perfused with Ca2+-free medium exhibited a distorted glycocalyx. On reperfusion with Ca2+-containing medium these hearts released protein (P less than 0.001), gained Ca2+ (P less than 0.001), and depleted their tissue stores of ATP (P less than 0.001) and CP (P less than 0.001). Hearts that had been perfused with Ca2+-free, Ba2+-containing medium retained an apparently intact glycocalyx. On reperfusion with Ca2+-containing. Ba2+-free medium they gained Ca2+ but did not lose protein. These results suggest that Ba2+ only partially replaces Ca2+ in maintaining the integrity of the cell surface. It is also concluded that the absence of protein release does not necessarily exclude the occurrence of severe changes in ionic permeability after cell injury.     

The role of voltage-gated Ca2+ channels in anoxic injury of spinal cord white matter

Dorsal column axons of the rat spinal cord are partially protected from anoxic injury following blockade of voltage-sensitive Na+ channels and the Na+/--Ca2+ exchanger. To examine the potential contribution of voltage-gated Ca2+ channels to anoxic injury of spinal cord axons, we studied axonal conduction in rat dorsal columns in vitro following a 60-min period of anoxia. Glass microelectrodes were used to record field potentials from the dorsal columns following distal local surface stimulation. Perfusion solutions containing blockers of voltage-gated Ca2+ channels were introduced 60 min prior to onset of anoxia and continued until 10 min after reoxygenation. Pharmacological blocking agents which are relatively selective for L- (verapamil, diltiazem, nifedipine) and N- (omega-conotoxin GVIA) type calcium channels were significantly protective against anoxia-induced loss of conduction, as was non-specific block using divalent cations. Other Ca2+ channel blockers (neomycin and omega-conotoxin MVIIC) that affect multiple Ca2+ channel types were also neuroprotective. Ni2+, which preferentially blocks R-type Ca2+ channels more than T-type channels, was also protective in a dose-dependent manner. These data suggest that the influx of Ca2+, through L-, N- and possibly R-type voltage-gated Ca2+ channels, participates in the pathophysiology of the Ca2+-mediated injury of spinal cord axons that is triggered by anoxia.     

Biochemical and functional heterogeneity of rat cerebrum microsomal membranes in relation to SERCA Ca(2+)-ATPases and Ca2+ release channels

Rat cerebrum microsomes were subfractionated on isopycnic linear sucrose (20-42%) density gradients. The Ca2+ loading/release properties and the distribution of intracellular Ca2+ store channels, inositol 1,4,5-trisphosphate (IP3) receptor and ryanodine (Ry) receptor, and SERCA pumps, were monitored in each subfraction by ligand binding and 45Ca2+ loading/release assays. Three different classes of vesicles were identified: (i) heavy density vesicles with high content of Ry receptors and Ca2+ pumps and high thapsigargin (TG)-sensitivity of Ca2+ loading; (ii) intermediate sucrose density vesicles with high content of IP3 receptor, high IP(S)3-sensitivity of Ca2+ loading and low content of Ry receptors; and (iii) light sucrose density vesicles with high content of Ry receptors, low content of IP3 receptors and low content of SERCA pumps highly sensitive to TG. Isolation of molecularly heterogeneous rat cerebrum microsomes and identification of specific Ca2+ loading/release properties support the presence of multiple, potentially active, heterogeneous rapidly exchanging Ca2+ stores in rat cerebrum.     

Trophoblast class I major histocompatibility complex (MHC) products are resistant to rapid degradation imposed by the human cytomegalovirus (HCMV) gene products US2 and US11

The ryanodine receptor Ca2+ channel (RyRC) constitutes the Ca2+-release pathway in sarcoplasmic reticulum (SR) of cardiac muscle. A direct mechanical and a Ca2+-triggered mechanism (Ca2+-induced Ca2+ release) have been proposed to explain the in situ activation of Ca2+ release in cardiac muscle. A variety of chemical oxidants have been shown to activate RyRC; however, the role of modification induced by oxygen-derived free radicals in pathological states of the muscle remains to be elucidated. It has been hypothesized that oxygen-derived free radicals initiate Ca2+-mediated functional changes in or damage to cardiac muscle by acting on the SR and promoting an increase in Ca2+ release. We confirmed that superoxide anion radical (O2-) generated from hypoxanthine-xanthine oxidase reaction decreases calmodulin content and increases 45Ca2+ efflux from the heavy fraction of canine cardiac SR vesicles; hypoxanthine-xanthine oxidase also decreases Ca2+ free within the intravesicular space of the SR with no effect on Ca2+-ATPase activity. Current fluctuations through single Ca2+-release channels have been monitored after incorporation into planar phospholipid bilayers. We demonstrate that activation of the channel by O2- is dependent of the presence of calmodulin and identified calmodulin as a functional mediator of O2--triggered Ca2+ release through the RyRC. For the first time, we show that O2- stimulates Ca2+ release from heavy SR vesicles and suggest the importance of accessory proteins such as calmodulin in modulating the effect of O2-. The decreased calmodulin content induced by oxygen-derived free radicals, especially O2-, is a likely mechanism of accumulation of cytosolic Ca2+ (due to increased Ca2+ release from SR) after reperfusion of the ischemic heart.     

Calcium waves in retinal glial cells

Calcium signals were recorded from glial cells in acutely isolated rat retina to determine whether Ca2+ waves occur in glial cells of intact central nervous system tissue. Chemical (adenosine triphosphate), electrical, and mechanical stimulation of astrocytes initiated increases in the intracellular concentration of Ca2+ that propagated at approximately 23 micrometers per second through astrocytes and Müller cells as intercellular waves. The Ca2+ waves persisted in the absence of extracellular Ca2+ but were largely abolished by thapsigargin and intracellular heparin, indicating that Ca2+ was released from intracellular stores. The waves did not evoke changes in cell membrane potential but traveled synchronously in astrocytes and Müller cells, suggesting a functional linkage between these two types of glial cells. Such glial Ca2+ waves may constitute an extraneuronal signaling pathway in the central nervous system.