Ca(2+)-calmodulin can activate and inactivate cardiac ryanodine receptors.

BACKGROUND AND PURPOSE: Ca(2+)-calmodulin (Ca(2+)CaM) is widely accepted as an inhibitor of cardiac ryanodine receptors (RyR2); however, the effects of physiologically relevant CaM concentrations have not been fully investigated. EXPERIMENTAL APPROACH: We investigated the effects of low concentrations of Ca(2+)CaM (50-100 nmol.L(-1)) on the gating of native sheep RyR2, reconstituted into bilayers. Suramin displaces CaM from RyR2 and we have used a gel-shift assay to provide evidence of the mechanism underlying this effect. Finally, using suramin to displace endogenous CaM from RyR2 in permeabilized cardiac cells, we have investigated the effects of 50 nmol.L(-1) CaM on sarcoplasmic reticulum (SR) Ca(2+)-release. KEY RESULTS: Ca(2+)CaM activated or inhibited single RyR2, but activation was much more likely at low (50-100 nmol.L(-1)) concentrations. Also, suramin displaced CaM from a peptide of the CaM binding domain of RyR2, indicating that, like the skeletal isoform (RyR1), suramin directly competes with CaM for its binding site on the channel. Pre-treatment of rat permeabilized ventricular myocytes with suramin to displace CaM, followed by addition of 50 nmol x L(-1) CaM to the mock cytoplasmic solution caused an increase in the frequency of spontaneous Ca(2+)-release events. Application of caffeine demonstrated that 50 nmol x L(-1) CaM reduced SR Ca(2+) content. CONCLUSIONS AND IMPLICATIONS: We describe for the first time how Ca(2+)CaM is capable, not only of inactivating, but also of activating RyR2 channels in bilayers in a CaM kinase II-independent manner. Similarly, in cardiac cells, CaM stimulates SR Ca(2+)-release and the use of caffeine suggests that this is a RyR2-mediated effect.

Diadenosine pentaphosphate is a potent activator of cardiac ryanodine receptors revealing a novel high-affinity binding site for adenine nucleotides.

BACKGROUND AND PURPOSE: Diadenosine polyphosphates are normally present in cells at low levels, but significant increases in concentrations can occur during cellular stress. The aim of this study was to investigate the effects of diadenosine pentaphosphate (Ap5A) and an oxidized analogue, oAp5A on the gating of sheep cardiac ryanodine receptors (RyR2). EXPERIMENTAL APPROACH: RyR2 channel function was monitored after incorporation into planar bilayers under voltage-clamp conditions. KEY RESULTS: With10 micromol.L(-1) cytosolic Ca2+, a significant 'hump' or plateau at the base of the dose-response relationship to Ap5A was revealed. Open probability (Po) was significantly increased to a plateau of approximately 0.2 in the concentration range 100 pmol x L(-1)-10 micromol x L(-1). High Po values were observed at >10 micromol x L(-1) Ap5A, and Po values close to 1 could be achieved. Nanomolar levels of ATP and adenosine also revealed a hump at the base of the dose-response relationships, although GTP did not activate at any concentration, indicating a common, high-affinity binding site on RyR2 for adenine-based compounds. The oxidized analogue, oAp5A, did not significantly activate RyR2 via the high-affinity binding site; however, it could fully open the channel with an EC(50) of 16 micromol.L(-1) (Ap5A EC(50) = 140 micromol x L(-1)). Perfusion experiments suggest that oAp5A and Ap5A dissociate slowly from their binding sites on RyR2. CONCLUSIONS AND IMPLICATIONS: The ability of Ap5A compounds to increase Po even in the presence of ATP and their slow dissociation from the channel may enable these compounds to act as physiological regulators of RyR2, particularly under conditions of cellular stress.

Effects of eicosapentaenoic acid on cardiac SR Ca(2+)-release and ryanodine receptor function.

n-3 polyunsaturated fatty acids (PUFAs) can prevent life-threatening arrhythmias but the mechanisms responsible have not been established. There is strong evidence that part of the antiarrhythmic action of PUFAs is mediated through inhibition of the Ca(2+)-release mechanism of the sarcoplasmic reticulum (SR). It has also been shown that PUFAs activate protein kinase A (PKA) and produce effects in the cardiac cell similar to beta-adrenergic stimulation. We have investigated whether the inhibitory effect of PUFAs on the Ca(2+)-release mechanism is caused by direct inhibition of the SR Ca(2+)-release channel/ryanodine receptor (RyR) or requires activation of PKA. Experiments in intact cells under voltage-clamp show that the n-3 PUFA eicosapentaenoic acid (EPA) is able to reduce the frequency of spontaneous waves of Ca(2+)-release while increasing SR Ca(2+) content even when PKA activity is inhibited with H-89. This suggests that the EPA-induced inhibition of SR Ca(2+)-release is not dependent on activation of PKA. Consistent with this, single-channel studies demonstrate that EPA (10-100 microM), but not saturated fatty acids, reduce the open probability (Po) of the cardiac RyR incorporated into phospholipid bilayers. EPA also inhibited the binding of [3H]ryanodine to isolated heavy SR. Our results indicate that direct inhibition of RyR channel gating by PUFAs play an important role in the overall antiarrhythmic properties of these compounds.

Light at the end of the Ca(2+)-release channel tunnel: structures and mechanisms involved in ion translocation in ryanodine receptor channels.

RyR and InsP3R are Ca(2+)-release channels. When induced to open by the appropriate stimulus, these channels allow Ca2+ to leave intracellular storage organelles at an astonishing rate. Investigations of the ion-handling properties of isolated RyR channels have demonstrated that, at least in comparison to voltage-gated channels of surface membranes, these channels display limited powers of discrimination between physiologically relevant cations and this relative lack of selectivity is likely to contribute to the ability of Ca(2+)-release channels to maintain high rates of cation translocation without compromising function. A range of ion-handling properties in RyR are consistent with the proposal that this channel functions as a single-ion channel and theoretical considerations indicate that the high rates of ion translocation monitored for RyR would require the pore of such a structure to be short and possess a large capture radius. Measurements of the dimensions of regions of RyR involved in ion conduction and discrimination indicate that this is likely to be the case. In each monomer of RyR/InsP3R, residues making up the last two trans-membrane spanning domains and a luminal loop linking these two helices contribute to the formation of the channel pore. The luminal loops of both RyR and InsP3R contain amino acid sequences similar to those known to form the selectivity filter of K+ channels. In addition the luminal loops of both Ca(2+)-release channels contain sequences that are likely to form helices that may be analogous to the pore helix visualised in KcsA. The correlation in structural elements of the luminal loops of RyR/InsP3R and KcsA has prompted us to speculate on the tertiary arrangement for this region of the Ca(2+)-release channels using the established structure of KcsA as a framework.

Markovian models of low and high activity levels of cardiac ryanodine receptors.

The modal gating behavior of single sheep cardiac sarcoplasmic reticulum (SR) Ca2+-release/ryanodine receptor (RyR) channels was assessed. We find that the gating of RyR channels spontaneously shifts between high (H) and low (L) levels of activity and inactive periods where no channel openings are detected (I). Moreover, we find that there is evidence for multiple gating modes within H activity, which we term H1 and H2 mode. Our results demonstrate that the underlying mechanisms regulating gating are similar in native and purified channels. Dwell-time distributions of L activity were best fitted by three open and five closed significant exponential components whereas dwell-time distributions of H1 activity were best fitted by two to three open and four closed significant exponential components. Increases in cytosolic [Ca2+] cause an increase in open probability (Po) within L activity and an increase in the probability of occurrence of H activity. Open lifetime distributions within L activity were Ca2+ independent whereas open lifetime distributions within H activity were Ca2+ dependent. This study is the first attempt to estimate RyR single-channel kinetic parameters from sequences of idealized dwell-times and to develop kinetic models of RyR gating using the criterion of maximum likelihood. We propose distinct kinetic schemes for L, H1, and H2 activity that describe the major features of sheep cardiac RyR channel gating at these levels of activity.

Evidence for Ca(2+) activation and inactivation sites on the luminal side of the cardiac ryanodine receptor complex.

We have used tryptic digestion to determine whether Ca(2+) can regulate cardiac ryanodine receptor (RyR) channel gating from within the lumen of the sarcoplasmic reticulum (SR) or whether Ca(2+) must first flow through the channel and act via cytosolically located binding sites. Cardiac RyRs were incorporated into bilayers, and trypsin was applied to the luminal side of the bilayer. We found that before exposure to luminal trypsin, the open probability of RyR was increased by raising the luminal [Ca(2+)] from 10 micromol/L to 1 mmol/L, whereas after luminal trypsin exposure, increasing the luminal [Ca(2+)] reduced the open probability. The modification in the response of RyRs to luminal Ca(2+) was not observed with heat-inactivated trypsin, indicating that digestion of luminal sites on the RyR channel complex was responsible. Our results provide strong evidence for the presence of luminally located Ca(2+) activation and inhibition sites and indicate that trypsin digestion leads to selective damage to luminal Ca(2+) activation sites without affecting luminal Ca(2+) inactivation sites. We suggest that changes in luminal [Ca(2+)] will be able to regulate RyR channel gating from within the SR lumen, therefore providing a second Ca(2+)-regulatory effect on RyR channel gating in addition to that of cytosolic Ca(2+). This luminal Ca(2+)-regulatory mechanism is likely to be an important contributing factor in the potentiation of SR Ca(2+) release that is observed in cardiac cells in response to increases in intra-SR [Ca(2+)].

Structural factors that determine the ability of adenosine and related compounds to activate the cardiac ryanodine receptor.

The effects of adenosine and adenine on the gating of native sheep cardiac ryanodine receptor (RyR) channels were investigated. By examining the mechanisms underlying channel activation and by using comparative molecular field analysis (CoMFA) we have investigated the structural features of adenine-based ligands involved in channel activation. In the presence of 10 microM cytosolic Ca(2+), adenosine and adenine both activate the channel but only to a level approximately 10 and 20% respectively of that of ATP indicating that both are partial agonists of low efficacy. Adenosine was able to antagonize the ATP-induced increase in open probability (Po) as expected for a partial agonist of low efficacy at the ATP sites on the cardiac RyR. GTP (100 microM - 10 mM) had no effect on channel gating indicating that the adenine ring structure is important for agonist activity at the ATP-sites on RyR. CoMFA revealed an extremely strong correlation between the structural features of the five ATP analogues and the ability to increase (Po). Our model indicates that the high efficacy of ATP results primarily from the large electrostatic field established by the ionized phosphate groups. Reducing the number of phosphate groups lowers the strength of this field, leading to ligands with lower efficacy. In addition, steric interactions between the alpha-phosphate and ribose moieties and the RyR are correlated with low Po.

AMP is a partial agonist at the sheep cardiac ryanodine receptor.

We have investigated the ability of AMP to modulate the native sheep cardiac ryanodine receptor (RyR) channel at various cytosolic [Ca2+]. Channels were incorporated into planar phospholipid bilayers and current fluctuations through the bilayer were monitored under voltage clamp conditions. We demonstrate that AMP only exhibits agonist activity if the cytosolic [Ca2+] is sufficiently high. Even in the presence of a high cytosolic [Ca2+] (65 microM), AMP cannot fully open the channel and the maximum open probability (Po) observed is approximately 0.3 at 2 mM AMP. Concentrations of AMP above the maximally activating level cause inactivation of the channel. Our experiments indicate that AMP is an agonist with such low efficacy at the ATP sites on the cardiac RyR that it is effectively an antagonist of ATP-induced increases in Po. Our study demonstrates that the number of phosphates attached to the 5'-carbon of the ribose ring of adenine-based compounds determines the efficacy of the ligand to increase the Po of the cardiac RyR. Substitution of groups at this position may lead to the identification of potent antagonists at ATP sites on RyR.

Evidence for novel caffeine and Ca2+ binding sites on the lobster skeletal ryanodine receptor.

1. The effects of Ca2+, ATP and caffeine on the gating of lobster skeletal muscle ryanodine receptors (RyR) was investigated after reconstitution of the channels into planar phospholipid bilayers and by using [3H]-ryanodine binding studies. 2. The single channel studies reveal that the EC50 (60 microM) for activation of the lobster skeletal RyR by Ca2+ as the sole ligand is higher than for any other isoform of RyR studied. 3. Inactivation of the channel by Ca2+ (EC50 = 1 mM) occurs at concentrations slightly higher than those required to inactivate mammalian skeletal RyR (RyR1) but lower than those required to inactivate mammalian cardiac RyR (RyR2). 4. Lifetime analysis demonstrates that cytosolic Ca2+, as the sole activating ligand, cannot fully open the lobster skeletal RyR (maximum Po approximately 0.2). The mechanism for the increase in open probability (Po) is an increase in both the frequency and the duration of the open events. 5. ATP is a very effective activator of the lobster RyR and can almost fully open the channel in the presence of activating cytosolic [Ca2+]. In the presence of 700 microM Ca2+, 1 mM ATP increased Po to approximately 0.8. 6. Caffeine, often used as a tool to identify the presence of RyR channels, is relatively ineffective and cannot increase Po above the level that can be attained with Ca2+ alone. 7. The results reveal that caffeine increases Po by a different mechanism to that of cytosolic Ca2+ demonstrating that the mechanism for channel activation by caffeine is not 'sensitization' to cytosolic Ca2+. 8. By studying the mechanisms involved in the activation of the lobster RyR we have demonstrated that the channel responds in a unique manner to Ca2+ and to caffeine. The results strongly indicate that these ligand binding sites on the channel are different to those on mammalian isoforms of RyR.

Similarities in the effects of DIDS, DBDS and suramin on cardiac ryanodine receptor function.

The mechanisms involved in 4,4'-diisothiocyanostilbene-2, 2'-disulfonic acid (DIDS)- and 4,4'-dibenzamidostilbene-2, 2'-disulfonic acid (DBDS)- modification of sheep cardiac ryanodine receptor (RyR) channel function have been investigated. DIDS (50-500 microm) exerts at least three effects on single channel function. With Ca2+ as the permeant ion, DIDS increases both channel open probability (Po) and single channel conductance in a similar manner to the effects observed with suramin. Both effects occur immediately and are fully reversible. Similar effects were observed with DBDS (10 microm-2 mm), a compound with the 4,4'-NCS groups of DIDS replaced with NHCOC6H5. DIDS (500 microm) also caused irreversible modification to the fully open channel level in 74% of the channels. This effect was not observed with suramin or DBDS (10 microm-1 mm). Competition studies with DBDS and suramin coupled with the close similarities in the effects of DIDS, DBDS and suramin on gating and conduction suggest that these ligands may all bind to the same sites on RyR. The DIDS-induced irreversible modification to the fully open state may result from the binding of the isothiocyanate groups to positively charged amino acids at or near the suramin binding sites although it is possible that this modification is unrelated to its other effects on channel function.

Glycolytic pathway intermediates activate cardiac ryanodine receptors.

During myocardial ischaemia and reperfusion, enhancement of glycolytic activity occurs and this may lead to fluctuating levels of glycolytic intermediates. We demonstrate that sugar phosphate intermediates of glycolysis, particularly fructose-1,6-diphosphate (FDP; 100 microM-10 mM), can activate sheep cardiac ryanodine receptor (RyR) channels incorporated into bilayers (open probability (Po) increases up to approximately 0.6) and stimulate [3H]ryanodine binding (> 200%) to isolated cardiac sarcoplasmic reticulum (SR) membrane vesicles. The relative effectiveness of the sugar phosphates in stimulating [3H]ryanodine binding and increasing the Po of the channels was FDP > glucose-1-phosphate (G-1-P) > fructose-6-phosphate (F-6-P) > glucose-6-phosphate (G-6-P). These novel properties of the sugar phosphate compounds indicate that changes in glycolytic flux may influence the release of SR Ca2+ by modulating RyR channel gating.

The interactions of ATP, ADP, and inorganic phosphate with the sheep cardiac ryanodine receptor.

The effects of ATP, ADP, and inorganic phosphate (Pi) on the gating of native sheep cardiac ryanodine receptor channels incorporated into planar phospholipid bilayers were investigated. We demonstrate that ATP and ADP can activate the channel by Ca2+-dependent and Ca2+-independent mechanisms. ATP and ADP appear to compete for the same site/s on the cardiac ryanodine receptor, and in the presence of cytosolic Ca2+ both agents tend to inactivate the channel at supramaximal concentrations. Our results reveal that ATP not only has a greater affinity for the adenine nucleotide site/s than ADP, but also has a greater efficacy. The EC50 value for channel activation is approximately 0.2 mM for ATP compared to 1.2 mM for ADP. Most interesting is the fact that, even in the presence of cytosolic Ca2+, ADP cannot activate the channel much above an open probability (Po) of 0.5, and therefore acts as a partial agonist at the adenine nucleotide binding site on the channel. We demonstrate that Pi also increases Po in a concentration and Ca2+-dependent manner, but unlike ATP and ADP, has no effect in the absence of activating cytosolic [Ca2+]. We demonstrate that Pi does not interact with the adenine nucleotide site/s but binds to a distinct domain on the channel to produce an increase in Po.

Modification of the conductance and gating properties of ryanodine receptors by suramin.

Suramin, a polysulfonated napthylurea, increases the open probability and the single-channel conductance of rabbit skeletal and sheep cardiac ryanodine receptor channels. The main mechanism for the increase in Po is an increase in the duration of open lifetimes. The effects on conduction and gating are completely reversible and involve an interaction with the cytosolic side of the channel. 10 mM dithiothreitol had no effect on the suramin-induced increase in conductance or Po. Therefore oxidation of sulfhydryl groups on the channels does not appear to be involved. Suramin has been used as an antagonist of ATP at P2 purinoceptors, however, we find that suramin does not antagonize the effect of ATP at skeletal or cardiac ryanodine receptor channels. The unusual gating kinetics induced by suramin suggest that it does not interact with the adenine nucleotide binding site on the ryanodine receptor but rather binds at a novel site(s). The suramin-induced changes to channel gating and conduction do not prevent the characteristic modification of single-channel properties by micromolar ryanodine.

Cyclic ADP-ribose, the ryanodine receptor and Ca2+ release.

In a variety of vertebrate and invertebrate tissues the ryanodine-sensitive Ca2+ channel is the pathway for Ca2+ release from intracellular stores. The mechanism for activation of the ryanodine receptor-channel complex appears to depend both on the ryanodine receptor isoform and the cell type. In addition, a complex combination of endogenous intracellular compounds regulates channel gating. In this article, Rebecca Sitsapesan, Stephen McGarry and Alan Williams review the mechanisms involved in cyclic ADP-ribose (cADPR)-induced Ca2+ release and discuss the likelihood that cADPR-activated Ca2+ release is mediated by one of the recognized isoforms of the ryanodine receptor-Ca2+ channel complex.

New insights into the gating mechanisms of cardiac ryanodine receptors revealed by rapid changes in ligand concentration.

We have developed a novel technique for incorporation of sheep cardiac sarcoplasmic reticulum (SR) Ca(2+)-release channels into planar phospholipid bilayers in order to investigate changes in [Ca2+] on a physiological time scale and have investigated whether the rate of change of cytosolic [Ca2+] has a direct effect on the gating of the cardiac SR Ca(2+)-release channel. Vesicles of heavy SR were incorporated into planar phospholipid bilayers painted on glass pipettes, and an established technique for rapid solution exchanges at excised membrane patches was modified to allow solution changes to be made at the bilayer within 10 ms. For a given change in [Ca2+], we demonstrate that the open probability (Po) is similar whether the cytosolic [Ca2+] is increased rapidly (10 ms) or slowly (1 s) and appears to be no different from the Po measured under steady state conditions that were recorded by using conventional bilayer techniques. We also demonstrate that no desensitization or inactivation occurs at -40 mV when the channel is activated by Ca2+ alone or in the presence of other channel activators, ATP or EMD 41000. However, at +40 mV, rapid channel activation followed by inactivation was observed. The probability of such voltage-dependent inactivation appears to depend on the mechanism of channel activation.

A novel method for incorporation of ion channels into a planar phospholipid bilayer which allows solution changes on a millisecond timescale.

We have developed a method of rapidly changing the solutions on one side of a planar phospholipid bilayer. Bilayers can be painted on glass pipettes of tip diameter > or = 50 microns. By modifying an established method for rapid exchange of solutions bathing excised membrane patches, solution changes can be made at the bilayer within 10 ms. After incorporation of channels into the bilayer, the bilayer is moved into one of two parallel streams of solution flowing from a length of double-barrelled glass theta tubing. Activation of a solenoid system rapidly moves the theta tubing so that the bilayer is in the flow of the adjacent solution. For various reasons, the single-channel gating mechanisms of many channels are studied in planar bilayer systems. The conventional bilayer technique only allows for steady-state single-channel gating to be monitored. This novel method now allows the effects of rapid changes in modulators of channels incorporated into planar phospholipid bilayers to be measured.

The gating of the sheep skeletal sarcoplasmic reticulum Ca(2+)-release channel is regulated by luminal Ca2+.

The effects of changes in luminal [Ca2+] have been investigated in sheep skeletal sarcoplasmic reticulum (SR) Ca(2+)-release channels after activation of the channels by different ligands from the cytosolic side of the channel. Native heavy SR membrane vesicles were incorporated into planar phospholipid bilayers under voltage-clamp conditions. Experiments were carried out in symmetrical 250 mM Cs+. Lifetime analysis indicates that channels activated solely by cytosolic Ca2+ exhibit at least two open and five closed states. The open events are very brief and are close to the minimum resolvable duration. When channels are activated solely by cytosolic Ca2+, luminal Ca2+ does not appear to exert any regulatory effect. The Po and duration of the open and closed lifetimes are unchanged. However, if channels are activated by ATP alone or by ATP plus cytosolic Ca2+, increases in luminal [Ca2+] produce marked increases in Po and in the duration of the open lifetimes. Our results demonstrate that maximum activation of the skeletal SR Ca(2+)-release channel by ATP cannot be obtained in the absence of millimolar luminal [Ca2+].

Cyclic ADP-ribose and related compounds activate sheep skeletal sarcoplasmic reticulum Ca2+ release channel.

It has been suggested that adenosine 5'-cyclic-diphosphoribose (cADPR) can activate only nonskeletal isoforms of the ryanodine-sensitive Ca2+ release channel. We now demonstrate that cADPR is an effective activator of sheep skeletal sarcoplasmic reticulum (SR) Ca2+ release channels incorporated into planar phospholipid bilayers in the presence of activating levels of cytosolic Ca2+. In addition, the precursor of cADPR, beta-NAD+, and the metabolite, adenosine diphosphoribose (ADP-ribose), also increase the open probability (Po) of skeletal SR Ca2+ release channels in micromolar concentrations. At low concentrations of cADPR (1 microM), the mechanism for the increase in Po is an increase in the frequency of channel openings with no increase in the duration of the open events. We also show that the effect of cADPR is dependent on luminal [Ca2+]. cADPR has no effect on Po when the luminal [Ca2+] is < 40 microM. However, at millimolar concentrations of luminal Ca2+, cADPR 1 and 10 microM) increases Po in the presence of activating cytosolic Ca2+.