Astroglial Gap Junction Communication Is Increased by Treatment with Either Glutamate or High K+ Concentration

Abstract: Astroglia are extensively coupled by gap junctions and form a functional syncytium. Astroglial gap junctions are thought to be involved in the spatial buffering of K⁺ in vivo and in the Ca²⁺ waves seen on glutamate receptor activation. The conductivity of gap junctions is regulated by several second messengers, with up-regulation by cyclic AMP and down-regulation through activation of protein kinase C, decreases in intracellular pH, or increases in the free cytosolic Ca²⁺ concentration. The results presented here indicate that dye coupling of astroglia is significantly up-regulated by membrane depolarization, both by increases in the extracellular K⁺ concentration and directly by ionophores. Furthermore, glutamate, kainate, and quisqualate, which depolarize astroglial cells through activation of ionotropic receptors, also increase dye coupling in astroglia. The effect of kainate and quisqualate was reversed by 6-cyano-7-nitroquinoxaline-2,3-dione, an inhibitor of the ionotropic glutamate receptor. A dose-dependent decrease in dye coupling was seen when the cells were injected with increasing concentrations of Ca²⁺. However, if the cells were simultaneously depolarized, the inhibitory effect of Ca²⁺ on gap junctional conductance was reversed. Significant increases over basal coupling was attained when the cells were injected with Ca²⁺ if they were treated with kainate or K⁺. These data suggest that ligands that depolarize astroglia enhance gap junction communication between astroglia and that this enhancement may be important in maintaining communication between astroglia in the face of elevated Ca²⁺ levels.     

Nogo-66 inhibits the dye-coupling of astrocytic gap junctions in vitro

Communication between astrocytes via the gap junction is crucial for maintaining homeostasis of the extra-neuronal microenvironment of the central nervous system. Dysfunction of astrocytic gap junctions is involved in many brain disorders. Our previous studies demonstrated a novel co-localization of Nogo-66 receptor at glial gap junctions in rat cerebellum and posterior pituitary. The present study was aimed at exploring whether Nogo-66 can modulate glial gap junctions in vitro. We confirmed the co-localization of Nogo-66 receptor with Cx43 in cultured astrocytes, and stimulated astrocytes with myelin extracts, or Nogo-66-Fc conditioned medium. Finally, we expressed and purified a functionally effective GST-Nogo-66 peptide. Lucifer yellow transfer assay was adopted to measure the gap junction permeability. The results showed that the spreading of Lucifer yellow was inhibited significantly by all three treatments as compared with their corresponding controls. Therefore, this study shows a novel inhibitory effect of Nogo-66 on the permeability of astrocytic gap junctions, suggesting a presumable role of Nogo-66 receptor in modulating the glial gap junction.     

Neuroprotective Role of Astrocytic Gap Junctions in Ischemic Stroke

The role of astrocytic gap junctions in ischemia remains controversial. Several studies support that astrocytic gap junctions play a role in the spread of hypoxic injury, while other reports have demonstrated that blocking astrocytic gap junctions increases neuronal death. Using a stroke model on animals in which the astrocytic gap junction protein connexin43 (Cx43) was compromised, we explored the neuroprotective role of astrocytic gap junctions. A focal brain stroke was performed on heterozygous Cx43 null [Cx43(+/?)] mice, wild type [Cx43(+/+)] mice, astrocyte-directed Cx43 deficient [Cx43^{fl/ fl}/hGFAP-cre] mice (here designated as Cre(+) mice), and their corresponding controls [Cx43^fl/fl] (here designated as Cre(?) mice). Four days following stroke, ischemic lesions were measured for size and analyzed immunohistochemically. Stroke volume was significantly larger in Cx43(+/?) and Cre(+) mice compared to Cx43(+/+) and Cre(?) mice, respectively. Apoptosis as detected by TUNEL labeling and caspase-3 immunostaining was amplified in Cx43(+/?) and Cre(+) mice compared to their control groups. Furthermore, increased inflammation as characterized by the immunohistochemical staining of the microglial marker CD11b was observed in the Cre(+) mice penumbra. Astrocytic gap junctions may reduce apoptosis and inflammation in the penumbra following ischemic insult, suggesting that coupled astrocytes fulfill a neuroprotective role under ischemic stroke conditions.     

Neuroprotective role of astrocytic gap junctions in ischemic stroke

The role of astrocytic gap junctions in ischemia remains controversial. Several studies support that astrocytic gap junctions play a role in the spread of hypoxic injury, while other reports have demonstrated that blocking astrocytic gap junctions increases neuronal death. Using a stroke model on animals in which the astrocytic gap junction protein connexin43 (Cx43) was compromised, we explored the neuroprotective role of astrocytic gap junctions. A focal brain stroke was performed on heterozygous Cx43 null [Cx43(+/-)] mice, wild type [Cx43(+/+)] mice, astrocyte-directed Cx43 deficient [Cx43(fl/ fl)/hGFAP-cre] mice (here designated as Cre(+) mice), and their corresponding controls [Cx43(fl/fl)] (here designated as Cre(-) mice). Four days following stroke, ischemic lesions were measured for size and analyzed immunohistochemically. Stroke volume was significantly larger in Cx43(+/-) and Cre(+) mice compared to Cx43(+/+) and Cre(-) mice, respectively. Apoptosis as detected by TUNEL labeling and caspase-3 immunostaining was amplified in Cx43(+/-) and Cre(+) mice compared to their control groups. Furthermore, increased inflammation as characterized by the immunohistochemical staining of the microglial marker CD11b was observed in the Cre(+) mice penumbra. Astrocytic gap junctions may reduce apoptosis and inflammation in the penumbra following ischemic insult, suggesting that coupled astrocytes fulfill a neuroprotective role under ischemic stroke conditions.     

Oxygen-glucose deprivation-induced enhancement of extracellular ATP-P2Y purinoceptors signaling for the propagation of astrocytic calcium waves

Waves of elevated intracellular free Ca²⁺ that propagate between neighboring astrocytes (Ca²⁺ waves) are important for the communication among astrocytes. We have previously revealed that focal photolysis of a caged calcium ionophore results in an increase in the concentration of intracellular Ca²⁺ in the target astrocytes, then the increase propagates to neighboring astrocytes through gap junctions. The extracellular ATP-purinoceptors signaling pathways are not primarily responsible for the propagation of the photolytic flash-induced Ca²⁺ waves. Here we examined whether and if so how the dynamics of Ca²⁺ waves changed after treatment with sublethal simulated ischemia; oxygen-glucose deprivation (OGD). OGD treatment increased the astrocytic expression of P2Y₁ and P2Y₂ receptors early during reperfusion, resulting in an increase in the propagating waves speed. In contrast, the expression of a gap junction protein was not changed significantly by the OGD suggesting that the extracellular ATP-P2Y receptors signaling pathways were preferentially enhanced after OGD. The present method to induce Ca²⁺ waves by focal photolysis of a caged calcium ionophore may provide a valuable tool with which to analyze glial Ca²⁺ waves under not only normal but also pathologic conditions.     

The predominant mechanism of intercellular calcium wave propagation changes during long-term culture of human osteoblast-like cells

Intercellular calcium waves (ICW) are calcium transients that spread from cell to cell in response to different stimuli. We previously demonstrated that human osteoblast-like cells in culture propagate ICW in response to mechanical stimulation by two mechanisms. One mechanism involves autocrine activation of P2Y receptors, and the other requires gap junctional communication. In the current work we ask whether long-term culture of osteoblast-like cells affects the propagation of ICW by these two mechanisms. Human osteoblast-like cells were isolated from bone marrow. Mechanically induced ICW were assessed by video imaging of Fura-2 loaded cells after 1, 2 and 4 months culture. The P2Y2 receptor and the gap junction protein Cx43 were assessed by Western blot and real-time PCR. In resting conditions, P2Y mediated ICW prevailed and spread rapidly to about 13 cells. P2Y receptor desensitization by ATP disclosed gap junction-mediated ICW which diffused more slowly and involved not more than five to six cells. After 2 months in culture, ICW appeared slower and wave propagation was much less inhibited by P2Y desensitization, suggesting an increase in gap junction-mediated ICW. After 4 months in culture cells still responded to addition of ATP, but P2Y desensitization did not inhibit ICW propagation. Our data indicate that the relative role of P2Y-mediated and gap junction-mediated ICW changes during osteoblast differentiation in vitro. In less differentiated cells, P2Y-mediated ICW predominate, but as cells differentiate in culture, gap-junction-mediated ICW become more prominent. These results suggest that P2Y receptor-mediated and gap junction-mediated mechanisms of intercellular calcium signaling may play different roles during differentiation of bone-forming cells.     

Orchestrating aquaporin-4 and connexin-43 expression in brain: Differential roles of α1- and β1-syntrophin

Aquaporin-4 (AQP4) water channels and gap junction proteins (connexins) are two classes of astrocytic membrane proteins critically involved in brain water and ion homeostasis. AQP4 channels are anchored by α1-syntrophin to the perivascular astrocytic endfoot membrane domains where they control water flux at the blood-brain interface while connexins cluster at the lateral aspects of the astrocytic endfeet forming gap junctions that allow water and ions to dissipate through the astrocyte syncytium. Recent studies have pointed to an interdependence between astrocytic AQP4 and astrocytic gap junctions but the underlying mechanism remains to be explored. Here we use a novel transgenic mouse line to unravel whether β1-syntrophin (coexpressed with α1-syntrophin in astrocytic plasma membranes) is implicated in the expression of AQP4 isoforms and formation of gap junctions in brain. Our results show that while the effect of β1-syntrophin deletion is rather limited, double knockout of α1- and β1-syntrophin causes a downregulation of the novel AQP4 isoform AQP4ex and an increase in the number of astrocytic gap junctions. The present study highlight the importance of syntrophins in orchestrating specialized functional domains of brain astrocytes.     

A role for protein kinase C-mediated phosphorylation in the mobilization of arachidonic acid in mouse macrophages

Mouse peritoneal macrophages respond to activators of protein kinase C and to zymosan particles and calcium ionophore by rapid enhancement of a phospholipase A pathway and mobilization of arachidonic acid. The pattern of protein phosphorylation induced in these cells by 4 beta-phorbol 12-myristate 13-acetate (PMA), 1,2-dioctanoyl-sn-glycerol, exogenous phospholipase C and by zymosan and ionophore A23187 was found to be virtually identical. The time course of phosphorylation differed among the phosphoprotein bands and in only some of those identified (i.e., those of 45 and 65 kDa) was the phosphorylation sufficiently rapid to be involved in the activation of the phospholipase A pathway. Phosphorylation of lipocortin I or II could not be detected. Down-regulation of kinase C by a 24-h pretreatment with PMA resulted in extensive inhibition of both protein phosphorylation and the mobilization of arachidonic acid in response to PMA or dioctanoylglycerol. The phosphorylation of the 45 kDa protein in response to zymosan and A23187 was also inhibited by pretreatment with PMA, while only arachidonic acid release induced by zymosan was inhibited by this pretreatment. Depletion of intracellular calcium had little effect on kinase C-dependent phosphorylation, although arachidonic acid mobilization is severely inhibited under these conditions. Bacterial lipopolysaccharide and lipid A induced a phosphorylation pattern different from that induced by PMA, and down-regulation of protein kinase C did not affect lipopolysaccharide-induced protein phosphorylation. The results indicate (i) that protein kinase C plays a critical role also in zymosan-induced activation of the phospholipase A pathway mobilizing arachidonic acid; (ii) that such activation requires calcium at some step distal to kinase C-mediated phosphorylation and (iii) that phosphorylation of lipocortins does not explain the kinase C-dependent activation.     

Ca2+ and phorbol ester activation of protein kinase C at intracellular Ca2+ concentrations and the effect of TMB-8

A calcium-activated, phospholipid-dependent protein kinase (protein kinase C) was purified to near homogeneity from human polymorphonuclear leukocytes and shown to be identical to bovine protein kinase C. The Ca2+ activation of the enzyme was studied and the Ca2+ concentrations required to activate the enzyme were compared to free cytosolic Ca2+ concentrations in resting and activated polymorphonuclear leukocytes. The free calcium concentrations in the cytosol and in the enzyme assay mixture were determined using the calcium indicator quin 2. The enzyme activity was almost totally dependent upon phosphatidylserine and could be strongly activated by Ca2+ concentrations in the micromolar range, but was not activated by phosphatidylserine at Ca2+ concentrations corresponding to the intracellular free Ca2+ concentration under resting conditions. However, at similar Ca2+ concentrations (less than 2.5 X 10(-7) M) the enzyme was highly activated by phorbol 12-myristate 13-acetate (PMA) or diolein in the presence of phosphatidylserine. It was demonstrated that PMA stimulation of human polymorphonuclear leukocytes did not induce any increase in the level of the intracellular free calcium concentration. It was concluded that PMA activation of protein kinase C occurred independently of a rise in the intracellular Ca2+ concentration. K0.5 (half-maximal activation) for the PMA activation of purified protein kinase C was shown to be equivalent to the K0.5 for PMA stimulation of superoxide (O-2) production in human polymorphonuclear leukocytes, suggesting that protein kinase C is involved in activation of the NADPH oxidase. The presumed intracellular Ca2+ antagonist TMB-8 inhibited the PMA-induced superoxide production, but neither by an intracellular Ca2+ antagonism nor by a direct inhibition of protein kinase C activity.     

Gap junctions do not underlie changes in whole-cell conductance in anoxic turtle brain

An acute reduction in cell membrane permeability could provide an effective strategy to prolong anoxic survival. A previous study has shown that in the western painted turtle whole-cell neuronal conductance (G(w)) decreases during anoxia, which may be mediated by the activation of adenosine A(1) receptors and calcium. Reduction in G(w) is thought to be the result of ion channel closure, but closure of gap junctions could also be responsible for this phenomenon. In our study, antibody staining of connexin 32 and 43 (Cx32 and Cx43) suggested the presence of gap junctional components in the turtle cortex. To examine if gap junctions were involved in the previously measured anoxic decrease in G(w), neuronal connectivity was assessed through the measurement of whole-cell capacitance (C(w)). Turtle cortical sheets were perfused with normoxic (95%O(2)/5%CO(2)), anoxic (95%N(2)/5%CO(2)), high calcium (4 mM) and adenosine (200 microm) artificial cerebral spinal fluid (aCSF). No significant change in C(w) was observed under any of the above conditions. However, during hypo-osmotic aCSF perfusion C(w) decreased significantly, with the lowest value of 50+/-10.4 pF (P<0.05) occurring at 30 min. To visualize changes in gap junction permeability lucifer yellow was loaded into turtle neurons during normoxic, anoxic, 0 calcium, hypo-osmotic, cold shock, (+)-isoproterenol, nitric oxide donor S-nitoso-acetyl penicillamine, and 8-bromo-guanosine 3',5'-cyclic monophosphate aCSF perfusion. Dye propagation was only observed in 3 of 20 cold shock experiments (4 degrees C). We conclude that gap junctions are not involved in the acute reduction in G(w) previously observed during anoxia and that our results support the hypothesis that ion channel arrest is involved.     

Gap junctions with varied permeability properties establish cell-type specific communication pathways in the rat seminiferous epithelium

Dye coupling experiments were performed to determine whether the gap junctions connecting Sertoli cells with other Sertoli cells and different germ cell stages in rats showed functional variations. Chop loading of adult rat seminiferous tubules was conducted using fluorescent dextran controls and a variety of low-molecular-weight tracers (lucifer yellow, biotin-X-cadaverine, biotin cadaverine, and neurobiotin) to evaluate dye coupling in situ, and scrape loading was used to study dye coupling in Sertoli-germ cell cocultures established using prepuberal rats. Sertoli-Sertoli coupling is relatively short range and nonselective in situ, whereas coupling between Sertoli cells and chains of spermatogonia is strongly selective for the positively charged biotin tracers relative to negatively charged lucifer yellow. Coupling between Sertoli cells and spermatogonia was also asymmetric; lucifer yellow in germ cells never diffused into Sertoli cells, and biotinylated tracers only weakly diffused from spermatogonia to Sertoli cells. Asymmetric coupling would facilitate the concentration in germ cells of molecules diffusing through junctions from Sertoli cells. Dye coupling between Sertoli cells and adluminal germ cells was too weak to detect by fluorescence microscopy, suggesting that the junctional communication between these cells may be functionally different from that between Sertoli and basal germ cells. The results show that there are multiple routes of gap junction communication in rat seminiferous tubules that differ in permeability properties and show alternative gating states. Functional diversity of gap junctions may permit regulated communication among the many interacting Sertoli cells and germ cell stages in the seminiferous epithelium.     

Vesicular ATP is the predominant cause of intercellular calcium waves in astrocytes

Brain astrocytes signal to each other and neurons. They use changes in their intracellular calcium levels to trigger release of transmitters into the extracellular space. These can then activate receptors on other nearby astrocytes and trigger a propagated calcium wave that can travel several hundred micrometers over a timescale of seconds. A role for endogenous ATP in calcium wave propagation in hippocampal astrocytes has been suggested, but the mechanisms remain incompletely understood. Here we explored how calcium waves arise and directly tested whether endogenously released ATP contributes to astrocyte calcium wave propagation in hippocampal astrocytes. We find that vesicular ATP is the major, if not the sole, determinant of astrocyte calcium wave propagation over distances between approximately 100 and 250 microm, and approximately 15 s from the point of wave initiation. These actions of ATP are mediated by P2Y1 receptors. In contrast, metabotropic glutamate receptors and gap junctions do not contribute significantly to calcium wave propagation. Our data suggest that endogenous extracellular astrocytic ATP can signal over broad spatiotemporal scales.     

Analysis of calcium homeostasis in activated human polymorphonuclear leukocytes. Evidence for two distinct mechanisms for lowering cytosolic calcium

The stimulation of polymorphonuclear leukocytes (PMNs) by chemoattractants triggers a rapid rise in cytosolic free calcium concentration(s) ([Ca2+]i), which quickly returns to base line, suggesting a role for calcium removal in the homeostasis of activated PMNs. To investigate cytosolic calcium homeostasis, PMNs were treated with a fluoroprobe and ionomycin to induce a sustained elevation of [Ca2+]i. The cells were then stimulated, and attenuation of the fluorescence signal was measured as an indication of calcium loss from the cytosol. The formyl peptide chemoattractant N-formyl-methionyl-leucyl-phenylalanine (fMLP), phorbol myristate acetate (PMA), and 1,2-dioctanoyl-sn-glycerol, but not the inactive phorbol ester 4 alpha-phorbol didecanoate, induced a dose-dependent decrease in [Ca2+]i in ionomycin-pretreated cells. However, the decline in [Ca2+]i caused by PMA was sustained and occurred following a lag time, whereas the response to fMLP was immediate, lasted approximately 2 min, and then was followed by a return of [Ca2+]i to its initial level. The restoration of [Ca2+]i required extracellular calcium. Varying the ionomycin concentration allowed studies at different initial [Ca2+]i, which in untreated PMNs was approximately 135 nM. In contrast to fMLP, PMA did not lower calcium at concentrations below 200 nM. The decline in [Ca2+]i induced by fMLP, but not PMA, was blocked by pertussis toxin. In contrast, the decrease in [Ca2+]i caused by PMA and 1,2-dioctanoyl-sn-glycerol, but not fMLP, was inhibited by the protein kinase C antagonists staurosporine, H-7, and sphingosine. These results suggest that formyl peptide chemoattractants transiently stimulate an activity which lowers [Ca2+]i to normal intracellular levels. Activation of this process appears to be independent of protein kinase C. An additional cytosolic calcium lowering activity, dependent on protein kinase C, operates at [Ca2+]i above 200 nM. Thus, activated PMNs can use at least two processes for attentuation of elevated cytosolic calcium levels.     

A novel form of cellular communication among thymic epithelial cells: intercellular calcium wave propagation

We here describe intercellular calcium waves as a novel form of cellular communication among thymic epithelial cells. We first characterized the mechanical induction of intercellular calcium waves in different thymic epithelial cell preparations: cortical 1-4C18 and medullary 3-10 thymic epithelial cell lines and primary cultures of thymic "nurse" cells. All thymic epithelial preparations responded with intercellular calcium wave propagation after mechanical stimulation. In general, the propagation efficacy of intercellular calcium waves in these cells was high, reaching 80-100% of the cells within a given confocal microscopic field, with a mean velocity of 6-10 µm/s and mean amplitude of 1.4- to 1.7-fold the basal calcium level. As evaluated by heptanol and suramin treatment, our results suggest the participation of both gap junctions and P2 receptors in the propagation of intercellular calcium waves in thymic nurse cells and the more prominent participation of gap junctions in thymic epithelial cell lines. Finally, in cocultures, the transmission of intercellular calcium wave was not observed between the mechanically stimulated thymic epithelial cell and adherent thymocytes, suggesting that intercellular calcium wave propagation is limited to thymic epithelial cells and does not affect the neighboring thymocytes. In conclusion, these data describe for the first time intercellular calcium waves in thymic epithelial cells and the participation of both gap junctions and P2 receptors in their propagation. gap junctions; connexin43; P2 receptors; intercellular communication     

Phosphorylation of liver gap junction protein by protein kinase C

The 27 kDa protein, a major component of rat liver gap junctions, was shown to be phosphorylated in vitro by protein kinase C. The stoichiometry of the phosphorylation indicated that approx. 0.33 mol phosphate was incorporated per mol 27 kDa protein. Phosphorylation was entirely dependent on the presence of calcium and was virtually specific for serine residues. For comparison, the gap junction protein was also examined for its phosphorylation by cAMP-dependent protein kinase, the extent of phosphorylation being one-tenth that exerted by protein kinase C.     

Agents that mimic antigen receptor signaling inhibit proliferation of cloned murine T lymphocytes induced by IL-2

We have shown previously that stimulation of cloned murine T lymphocytes via the TCR inhibits their responsiveness to rIL-2. Signaling via the TCR is believed to result in a variety of biochemical events that include a rise in intracellular free calcium and activation (translocation) of protein kinase C. These two signals also can be generated by calcium ionophores, such as ionomycin, and by activators of protein kinase C, such as PMA. We report here that treatment of cloned murine T lymphocytes with PMA, ionomycin, or the combination led to a dose-dependent inhibition of IL-2-dependent proliferation but did not inhibit lymphokine secretion. Concentrations of PMA and ionomycin that maximally inhibited proliferation stimulated maximal lymphokine secretion and increased mitochondrial activity as assessed by measurement of cleavage of 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium-bromide. Furthermore, PMA, ionomycin, the combination, or immobilized anti-CD3 mAb added after 12 to 16 h of culture with IL-2 could inhibit proliferation. These results demonstrate that PMA and ionomycin mimic stimulation of the TCR by high concentrations of immobilized anti-TCR mAb in that proliferation is inhibited and lymphokine secretion is induced. In addition, PMA or ionomycin could independently inhibit proliferation of some cells. These findings suggest that alternative mechanisms exist to regulate proliferation. Either increased levels of intracellular calcium or the physiologic events corresponding to those induced by PMA can inhibit IL-2-dependent replication of T lymphocytes.     

Stimulation of a histone H4 protein kinase in Triton X-100 lysates of rabbit peritoneal neutrophils pretreated with chemotactic factors. Effect of fMet-Leu-Phe and partial characterization of the protein kinase

Rabbit peritoneal neutrophils were stimulated with either the chemotactic factor, fMet-Leu-Phe (10(-8) M, 10 s) or the protein kinase C activator, phorbol-12-myristate-13-acetate (PMA), (0.1 microgram/ml, 3 min) at 37 degrees C, lysed with Triton X-100 at the indicated times and the histone H4 kinase activity of the lysate measured. The histone H4 protein kinase activity was increased severalfold by fMet-Leu-Phe but not PMA. The inclusion of the potent protein kinase C inhibitor, 1-(5-isoquinoline-sulfonyl)-2-methylpiperazine (50 microM) inhibited little if any of the histone H4 protein kinase activity. The effect of fMet-Leu-Phe was transient, maximum stimulation occurring within 10 s and decaying thereafter. The soluble fraction (extract) of the Triton X-100 lysates from control and fMet-Leu-Phe-treated cells was found to contain both histone H4 protein kinase and calcium-phospholipid-activated protein kinase (protein kinase C) activities. The histone H4 protein kinase activity obtained after fMet-Leu-Phe treatment was very little affected by calcium, phospholipid, and PMA and preferred histone H4 but not H1 or H2A as its substrate. In contrast, the calcium-phospholipid-activated protein kinase activity of the extract preferred histones H1 or H2A as substrates and was strongly inhibited by 1-(5-isoquinoline-sulfonyl)-2-methylpiperazine. The histone H4 protein kinase was partially separated from kinase C by DEAE-cellulose and phenyl-Sepharose 4B chromatography. It phosphorylated mostly serine in histone H4. The results indicate that the chemotactic factor, fMet-Leu-Phe, stimulates a protein kinase with substrate specificity and biochemical properties distinct from calcium-phospholipid-activated protein kinase C.     

Intercellular Ca2+ waves in mechanically stimulated articular chondrocytes

Articular cartilage is a tissue designed to withstand compression during joint movement and, in vivo, is subjected to a wide range of mechanical loading forces. Mechanosensitivity has been demonstrated to influence chondrocyte metabolism and cartilage homeostasis, but the mechanisms underlying mechanotransduction in these cells are poorly understood. In many cell types mechanical stimulation induces increases of the cytosolic Ca2+ concentration that propagates from cell to cell as an intercellular Ca2+ wave. Cell-to-cell communication through gap junctions underlies tissue co-ordination of metabolism and sensitivity to extracellular stimuli: gap junctional permeability to intracellular second messengers allows signal transduction pathways to be shared among several cells, ultimately resulting in co-ordinated tissue responses. Mechanically-induced Ca2+ signalling was investigated with digital fluorescence video imaging in primary cultures of rabbit articular chondrocytes. Mechanical stimulation of a single cell, obtained by briefly distorting the plasmamembrane with a micropipette, induced a wave of increased Ca2+ that was communicated to surrounding cells. Intercellular Ca2+ spreading was inhibited by 18 alpha-glycyrrhetinic acid, suggesting the involvement of gap junctions in signal propagation. The functional expression of gap junctions was assessed, in confluent chondrocyte cultures, by the intercellular transfer of Lucifer yellow dye in microinjection experiments while the expression of connexin 43 could be detected in Western blots. A series of pharmacological tools known to interfere with the cell calcium handling capacity were employed to investigate the mechanism of mechanically-induced Ca2+ signalling. In the absence of extracellular Ca2+ mechanical stimulation induced communicated Ca2+ waves similar to controls. Mechanical stress induced Ca2+ influx both in the stimulated chondrocyte but not in the adjacent cells, as assessed by the Mn2+ quenching technique. Cells treatment with thapsigargin and with the phospholipase C inhibitor U73122 blocked mechanically-induced signal propagation. These results provide evidence that in chondrocytes mechanical stimulation activates phospholipase C, thus leading to an increase of intracellular inositol 1,4,5-trisphosphate. The second messenger, by permeating gap junctions, stimulates intracellular Ca2+ release in neighbouring cells. Intercellular Ca2+ waves may provide a mechanism to co-ordinate tissue responses in cartilage physiology.     

Calcium waves in astrocytes-filling in the gaps.

Stimulus-evoked cellular responses are sometimes organized in the form of propagating waves of cytoplasmic Ca2+ increase. Ca2+ waves can be elicited in cultured astrocytes by the neurotransmitter glutamate; however, the propagation mechanism is unknown. Here, qualitative and quantitative features of propagation suggest that astrocytic Ca2+ waves are mediated by an intracellular signal that crosses intercellular junctions. The role of gap junctions in cell-cell Ca2+ wave propagation was specifically tested. Functional gap junctions were demonstrated using a noninvasive fluorescence recovery method and the gap junction blockers halothane and octanol. Gap junction closure prevented intracellular waves from propagating between cells without affecting the velocity of the intracellular wave itself. The pivotal role played by the gap junction creates the potential for dynamic changes in glial connectivity and long-range glial signaling.