Electrophysiological demonstration of Na+/Ca2+ exchange in bovine articular chondrocytes

Altered fluxes of Ca2+ across the chondrocyte membrane have been proposed as one pathway by which mechanical load can modulate cartilage turnover. In many cells, Na+/Ca2+ exchange (NCX) plays a key role in Ca2+ homeostasis, and recent studies have suggested it is operative in articular chondrocytes. In this study, an electrophysiological characterisation of NCX in articular bovine chondrocytes has been performed, using the whole-cell patch clamp technique, and the effects of inhibitors and the transmembrane electrochemical gradients of Na+ and Ca2+ on NCX function have been assessed. A Ni2+-sensitive current (I(NCX)) which exhibited outward rectification, was elicited by a voltage ramp protocol. The current was also attenuated by the NCX inhibitors benzamil and KBR7943, without significant differences between the effect of these two compounds upon outward and inward currents. The Ni2+-sensitive current was modulated by changes in extracellular and pipette Na+ and Ca2+ in a manner characteristic of I(NCX). Measured values for the reversal potential differed significantly from those predicted for an exchanger stoichiometry of 3Na+ : 1Ca2+, implying that accumulation of intracellular Ca2+ (from influx or release from stores) or more than one transport mode is occurring. These results demonstrate the operation of NCX in articular chondrocytes and suggest that changes in its turnover rate, as might occur in response to mechanical load, may modify cell composition and thereby dictate cartilage turnover.     

Modulation of H+ transport mechanisms by interleukin-1 in isolated bovine articular chondrocytes.

The proinflammatory cytokine interleukin-1 (IL-1) promotes the degradation of articular cartilage by inhibiting matrix synthesis and stimulating degradative enzyme activity. Generation of nitric oxide (NO) in response to IL-1 is implicated in these actions. The catabolic actions of IL-1 can be inhibited by manoeuvres which are predicted to dissipate H+ gradients across the chondrocyte plasma membrane. In the present study, the effects of IL-1 on H+ extrusion from bovine articular chondrocytes were investigated. pH was measured using the H+-sensitive fluorescent dye BCECF. Cells were acidified by ammonium rebound and the contribution of the Na+-H+ exchanger (NHE) and of the vacuolar H+-ATPase to acid extrusion was characterised by ion substitution and inhibitor studies. Overnight (18 h) exposure to IL-1 stimulated acid extrusion in a dose-dependent fashion. This effect represented stimulation of both NHE and the ATPase. Characterisation of the timecourse of this response indicated that, while stimulation of acid extrusion was rapid, effects on the ATPase were only apparent after greater than 8h incubation with the cytokine. In keeping with this observation, the protein synthesis inhibitor cycloheximide abolished the stimulatory effect of IL-1 on ATPase-mediated extrusion. The upregulation of ATPase activity by IL-1 was inhibited by the NOS inhibitor L-NAME and by the NO scavenger PTIO. In cells which had not been exposed to IL-1, treatment with the NO donor SNAP also stimulated acid extrusion by the ATPase. In contrast, NHE activity was not altered by any of these compounds. Taken together, these results imply that IL-1 can stimulate acid extrusion in chondrocytes and that this reflects rapid upregulation of NHE with slower induction of H+-ATPase activity which requires elevated levels of NO. While ATPase induction involves protein synthesis, this process may not constitute synthesis of ATPase proteins per se, but rather of some associated regulatory process.     

TRPV4 channels activity in bovine articular chondrocytes: Regulation by obesity-associated mediators

Turnover of the cartilage extracellular matrix depends exclusively on chondrocytes and varies in response to load and osmolarity fluctuations. Obesity can affect chondrocyte physiology; adipokines, insulin and proinflammatory cytokines levels are all altered in the obese and are related to matrix turnover impairments and thus to osteoarthritis. TRPV4, a mechanosensitive cation channel, is responsible for reacting to hypotonic variations. In this study, the presence and activity of TRPV4 channels in bovine chondrocytes were evaluated using the whole-cell patch-clamp technique and fluorescence measurements to perform characterisations of these channels and to determine intracellular calcium responses. The expression of TRPV4 was determined by RT-PCR. The TRPV4 regulation by hypotonic shock, insulin and adipokines were analysed. Hypoosmolarity induced a Gd³⁺-, ruthenium red-, and HC-067047-sensitive current, predominantly inward, an intracellular Ca²⁺ concentration increase and a membrane depolarisation. The current had a reversal potential of +28 ± 4 mV and exhibited preferential permeability to Ca²⁺; 4αPDD, a specific TRPV4 agonist, evoked the same response. TNFα, IL-1β, insulin, and, to a lesser degree, leptin and resistin attenuated the TRPV4-mediated effects; in contrast, adiponectin did not affect them. These results confirm the function of TRPV4 in bovine articular chondrocytes and its regulation by obesity-associated mediators.     

Characterisation of inorganic phosphate transport in bovine articular chondrocytes.

In mineralising tissues such as growth plate cartilage extracellular organelles derived from the chondrocyte membrane are present. These matrix vesicles (MV) possess membrane transporters that accumulate Ca(2+) and inorganic phosphate (P(i)), and initiate the formation of hydroxyapatite crystals. MV are also present in articular cartilage, and hydroxyapatite crystals are believed to promote cartilage degradation in osteoarthritic joints. In the present study, P(i) transport pathways in isolated bovine articular chondrocytes have been characterised. P(i) uptake was temperature-sensitive and could be resolved into Na(+)-dependent and Na(+)-independent components. The Na(+)-dependent component saturated at high concentrations of extracellular P(i), with a K(m) for P(i) of 0.17 mM. In solutions lacking Na(+), uptake did not fully saturate, implying that under these conditions carrier-mediated uptake is supplemented by a diffusive pathway. Both Na(+)-dependent and Na(+)-independent components were sensitive to the P(i) transport inhibitors phosphonoacetate and arsenate, although a fraction of Na(+)-independent P(i) uptake was resistant to these anions. Total P(i) uptake was optimal at pH 7.4, and reduced as pH was made more acidic or more alkaline, an effect that represented reduced Na(+)-dependent influx. RT-PCR analysis confirmed that two members of the NaPi III family, Pit-1 and Pit-2, are expressed, but that NaPi II transporters are not.     

Integrins and stretch activated ion channels; putative components of functional cell surface mechanoreceptors in articular chondrocytes.

Perception of mechanical signals and the biological responses to such stimuli are fundamental properties of load bearing articular cartilage in diarthrodial joints. Chondrocytes utilize mechanical signals to synthesize an extracellular matrix capable of withstanding high loads and shear stresses. Recent studies have shown that chondrocytes undergo changes in shape and volume in a coordinated manner with load induced deformation of the matrix. These matrix changes, together with alterations in hydrostatic pressure, ionic and osmotic composition, interstitial fluid and streaming potentials are, in turn, perceived by chondrocytes. Chondrocyte responses to these stimuli are specific and well coordinated to bring about changes in gene expression, protein synthesis, matrix composition and ultimately biomechanical competence. In this hypothesis paper we propose a chondrocyte mechanoreceptor model incorporating key extracellular matrix macromolecules, integrins, mechanosensitive ion channels, the cytoskeleton and subcellular signal transduction pathways that maintain the chondrocyte phenotype, prevent chondrocyte apoptosis and regulate chondrocyte-specific gene expression.     

Histamine H2 receptors on chondrocytes derived from human, canine and bovine articular cartilage.

Histamine (1-100 microM) induced a concentration-dependent increase in intracellular cyclic AMP in monolayer cultures of human, canine and foetal-bovine articular chondrocytes. The dose-response curve for histamine in each culture was progressively displaced to the right with increasing concentrations of cimetidine, an H2-receptor antagonist. The histamine-induced cyclic AMP elevation in human articular chondrocytes was also significantly decreased by ranitidine, another H2 antagonist, but not by the H1 antagonists mepyramine and chlorpheniramine. These findings indicate that histamine activates chondrocyte adenylate cyclase through an H2 receptor. The cyclic AMP response of human chondrocytes to histamine was many times greater than that measured for synovial fibroblasts under similar conditions. Such findings suggest that mast-cell-chondrocyte interactions in vivo may contribute to changed chondrocyte metabolism in joint disease.     

Histamine H2 receptors on foetal-bovine articular chondrocytes.

The dose-response curve of histamine-induced cyclic AMP elevation in monolayer cultures of primary foetal-bovine articular chondrocytes was displaced to the right by cimetidine. In addition, H2 but not H1 antagonists prevented the histamine-induced cyclic AMP elevation, suggesting histamine activates chondrocyte adenylate cyclase through an H2 receptor.     

Oscillating fluid flow regulates cytosolic calcium concentration in bovine articular chondrocytes.

Mechanical loading is a well-known regulator of cartilage metabolism. This suggests that a loading-induced physical signal regulates chondrocyte behavior. Previous studies have focused on the effects of steady fluid flow on chondrocytes. In contrast to steady flow, loading induced fluid flow occurs in an oscillatory pattern and includes a reversal of flow direction with each loading event. In this study we examined the hypothesis that oscillating fluid flow increases cytosolic Ca2+ concentration ([Ca2+]i) in bovine articular chondrocytes (BAC) in a frequency-dependent manner and that the presence of serum affects this response. The aims of our study were to examine (1) whether BAC respond to physiologic oscillating fluid flow in vitro and compare these results to steady fluid flow, (2) the effect of fetal bovine serum on fluid flow responsiveness of BAC and (3) whether the response of BAC to fluid flow is flow rate and/or frequency dependent. [Ca2+]i was quantified using the fluorescent dye fura-2. BAC were exposed to steady, 0.5, 1, or 5 Hz sinusoidal oscillating fluid flow at five different flow rates in a parallel plate flow chamber. Our findings demonstrate that BAC respond to oscillating fluid flow with an increase in [Ca2+]i (p > 0.05), and furthermore, chondrocyte responsiveness to fluid flow increases with peak flow rate (p < 0.0001) and decreases with increasing frequencies (p < 0.0001). Finally, the presence of serum in the media potentiated the responsiveness of BAC to fluid flow (p < 0.0001). Our results suggest an important role for mechanical load-induced oscillating fluid flow in chondrocyte mechanotransduction.     

The production of prostanoids by cultured bovine articular chondrocytes

Bovine articular chondrocytes, cultured as cell suspensions and monolayers, produced prostaglandin (PG) E₂ and PGI₂ (assayed as 6 keto PGF₁α), rather less PGF₂α and irregular quantities of thromboxane (Tx) B₂. Addition of foetal calf serum to the medium greatly stimulated PG production (a sixfold increase in PGE₂ and a twofold increase in 6 keto PGF₁α).Prostanoid production by cell suspension grown in serum-free medium generally plateaued after 24 hours. In the presence of 20% foetal calf serum, prostanoid production in long-term monolayer cultures increased during the first 6 days of culture. Levels of PGE₂α levels remained high. Indomethacin (10-⁶M) inhibited chondrocyte PG production both in the presence and absence of added arachidonic acid (10-⁴M). Prostanoids produced by chondrocytes may play a role in the modulation of cartilage metabolism .     

Bupivacaine inhibits large conductance,voltage- and Ca2+- activated K+ channels in human umbilical artery smooth muscle cells

Bupivacaine is a local anesthetic compound belonging to the amino amide group. Its anesthetic effect is commonly related to its inhibitory effect on voltage-gated sodium channels. However, several studies have shown that this drug can also inhibit voltage-operated K⁺ channels by a different blocking mechanism. This could explain the observed contractile effects of bupivacaine on blood vessels. Up to now, there were no previous reports in the literature about bupivacaine effects on large conductance voltage- and Ca²⁺-activated K⁺ channels (BK_Ca). Using the patch-clamp technique, it is shown that bupivacaine inhibits single-channel and whole-cell K⁺ currents carried by BK_Ca channels in smooth muscle cells isolated from human umbilical artery (HUA). At the single-channel level bupivacaine produced, in a concentration- and voltage-dependent manner (IC₅₀ 324 µM at +80 mV), a reduction of single-channel current amplitude and induced a flickery mode of the open channel state. Bupivacaine (300 µM) can also block whole-cell K⁺ currents (~45% blockage) in which, under our working conditions, BK_Ca is the main component. This study presents a new inhibitory effect of bupivacaine on an ion channel involved in different cell functions. Hence, the inhibitory effect of bupivacaine on BK_Ca channel activity could affect different physiological functions where these channels are involved. Since bupivacaine is commonly used during labor and delivery, its effects on umbilical arteries, where this channel is highly expressed, should be taken into account.     

Bupivacaine inhibits large conductance, voltage- and Ca2+- activated K+ channels in human umbilical artery smooth muscle cells

Bupivacaine is a local anesthetic compound belonging to the amino amide group. Its anesthetic effect is commonly related to its inhibitory effect on voltage-gated sodium channels. However, several studies have shown that this drug can also inhibit voltage-operated K(+) channels by a different blocking mechanism. This could explain the observed contractile effects of bupivacaine on blood vessels. Up to now, there were no previous reports in the literature about bupivacaine effects on large conductance voltage- and Ca(2+) -activated K(+) channels (BK(Ca)). Using the patch-clamp technique, it is shown that bupivacaine inhibits single-channel and whole-cell K(+) currents carried by BK(Ca) channels in smooth muscle cells isolated from human umbilical artery (HUA). At the single-channel level bupivacaine produced, in a concentration- and voltage-dependent manner (IC(50) 324 μM at +80 mV), a reduction of single-channel current amplitude and induced a flickery mode of the open channel state. Bupivacaine (300 μM) can also block whole-cell K(+) currents (~45% blockage) in which, under our working conditions, BK(Ca) is the main component. This study presents a new inhibitory effect of bupivacaine on an ion channel involved in different cell functions. Hence, the inhibitory effect of bupivacaine on BK(Ca) channel activity could affect different physiological functions where these channels are involved. Since bupivacaine is commonly used during labor and delivery, its effects on umbilical arteries, where this channel is highly expressed, should be taken into account.     

Permeation of Pb2+ through calcium channels: fura-2 measurements of voltage- and dihydropyridine-sensitive Pb2+ entry in isolated bovine chromaffin cells.

Fura-2 was used to monitor Pb2+ entry into isolated bovine chromaffin cells exposed to micromolar concentrations of Pb2+ in media containing basal or high concentrations of K+. The entry of Pb2+ consists of voltage-independent and voltage-dependent (K(+)-stimulated) components. The voltage-dependent Pb2+ entry is enhanced by Ca2+ channel agonist BAY K 8644 and blocked by the channel antagonist nifedipine, suggesting the involvement of the L-type Ca2+ channels. In contrast to the transient, K(+)-depolarization-dependent increase in [Ca2+]i, the increase in [Pb2+]i is sustained over a period of several minutes, suggesting the absence of channel inactivation and/or the saturation of Pb(2+)-buffering capacity of the cell cytosol.     

Effects of hypotonic shock on intracellular pH in bovine articular chondrocytes

Chondrocytes inhabit an unusual environment, in which they are repeatedly subjected to osmotic challenges as fluid is expressed from the extracellular matrix during static joint loading. In the present study, the effects of hypotonic shock on intracellular pH, pH(i), have been studied in isolated bovine articular chondrocytes using the pH-sensitive fluroprobe BCECF. Cells subjected to a 50% dilution rapidly alkalinised, by approximately 0.2 pH units, a sustained plateau being achieved within 300 s. The effect was not altered by inhibitors of pH regulators, such as amiloride, bafilomycin and SITS, but was absent when cells were subjected to hypotonic shocks in solutions in which Na(+) ions were replaced by NMDG(+). The response was found to be sensitive to Gd(3+) ions, blockers of stretch-activated cation channels. Alkalinisation was also inhibited by treatment with Zn(2+) ions, at a concentration reported to block voltage-activated H(+) channels (VAHC). Depolarisation using high K(+) solutions supplemented with valinomycin also induced intracellular alkalinisation. Measurements using a membrane potential (E(m)) fluorescent dye showed that E(m) was approximately -44 mV, but was depolarised by over 50 mV following HTS. The depolarisation was also inhibited by Na(+) substitution with NMDG(+) or treatment with Gd(3+). We conclude that in response to HTS the opening of a stretch-activated cation channel leads to Na(+) influx, which results in a membrane depolarisation. Subsequent activation of VAHC permits H(+) ion efflux along the prevailing electrochemcial gradient, leading to the alkalinisation, which we record.     

Antigenic profiles of human,bovine and canine articular chondrocytes

Summary Human, bovine and canine articular chondrocytes have been shown to bear cartilage matrix, chondrocyte-specific and histocompatibility antigens. These cell-surface antigens of chondrocytes were demonstrated both simultaneously and separately either by complement-mediated cytotoxicity or by immunohistochemical reactions. The chondrocyte-specific antigens involve subsets of species-common and species-specific determinants, which are also present on the surfaces of rib and laryngeal chondrocytes. In addition to these antigens, human and calf articular chondrocytes also express unique cell-surface components that are capable of producing a blastogenic stimulation of autologous T-lymphocytes in vitro. These putative autoantigens segregated from lymphocytes in vivo could be released in trauma and in inflammatory joint diseases triggering the immune system of the host.     

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.     

Cycle number and waveform of fluid flow affect bovine articular chondrocytes

Many studies have shown that a loading-induced (bio)physical signal regulates chondrocyte behavior. In a recent study our group has demonstrated the shear stress level- and frequency-dependent effect of sinusoidal oscillatory fluid flow on bovine articular chondrocyte (BAC) cytosolic calcium concentration ([Ca(2+)](i)), neglecting the fact that chondrocytes are not likely to see these ideal waveform in vivo or in vitro. Furthermore, possible overload of articular cartilage or excessive shear stress in chondrocyte cultures are more likely to be of a short nature. Therefore, in this study we choose to investigate a saw-tooth waveform oscillating fluid flow at varying exposure times in comparison to the established sinusoidal oscillatory waveform. [Ca(2+)](i), as an early signaling molecule, was quantified using the fluorescent dye fura-2. BAC were exposed to 1 Hz sinusoidal or saw-tooth waveform oscillating fluid flow at 2.2 Pa flow rates in a parallel plate flow chamber for 8 different loading times. As little as 5 cycles of oscillatory fluid flow were sufficient to increase [Ca(2+)](i) significantly over baseline. The number of responding cells could not be increased any further after a sufficient number of cycles (11), regardless of the waveform. Furthermore, a saw-tooth waveform appeared to be more stimulatory than regular sinusoidal oscillating flow at higher cycle numbers. BAC appear to be able to respond to these biophysical stimuli in a differentiated manner. This ability might give every single chondrocyte the capability to maintain its territory autonomously, since chondrocytes distributed in articular cartilage without the possibility to interact, e.g., via cell processes.     

Regulation of Na+, K+-ATPase density by the extracellular ionic and osmotic environment in bovine articular chondrocytes

The abundance of Na+, K+-ATPase in cartilage is controlled by the ionic composition of the extracellular environment of chondrocytes, and specifically depends on the local concentration of polyanionic matrix proteoglycans. In this study, it was found that the plasma membrane density of Na+, K+-ATPase in isolated chondrocytes is sensitive to both ionic and osmotic changes in the extracellular environment. The upregulation observed experimentally was similar in magnitude as measured by 3H-ouabain binding, which indicates that chondrocytes respond adaptively to both ionic and osmotic stimuli. The precise mechanism for this novel mode of Na+, K+-ATPase regulation has yet to be elucidated. Physiological perturbation of the ionic and osmotic environment of chondrocytes may alter intracellular Na+ concentration and this may be one of a number of stimuli responsible for alterations to the expression and plasma membrane abundance of Na+, K+-ATPase in the cells.