A 15-step synthesis of (+)-ryanodol

(+)-Ryanodine and (+)-ryanodol are complex diterpenoids that modulate intracellular calcium-ion release at ryanodine receptors, ion channels critical for skeletal and cardiac muscle excitation-contraction coupling and synaptic transmission. Chemical derivatization of these diterpenoids has demonstrated that certain peripheral structural modifications can alter binding affinity and selectivity among ryanodine receptor isoforms. Here, we report a short chemical synthesis of (+)-ryanodol that proceeds in only 15 steps from the commercially available terpene (S)-pulegone. The efficiency of the synthesis derives from the use of a Pauson-Khand reaction to rapidly build the carbon framework and a SeO2-mediated oxidation to install three oxygen atoms in a single step. This work highlights how strategic C-O bond constructions can streamline the synthesis of polyhydroxylated terpenes by minimizing protecting group and redox adjustments.

Quantification of the effects of a ryanodine receptor channel mutation on interaction with a ryanoid

Understanding the nature of the interaction of the plant alkaloid ryanodine with its receptor channel (RyR) is important to aid interpretation of physiological studies and provide structure-function information about RyR. We present here the first quantitative description of the relative single-channel kinetic effects of a single-point mutation in RyR2. We exploit the well-characterized ryanoid 8beta-amino-9alpha-hydroxyryanodine that displays reversible kinetics with RyR2. We explicitly show that the effect of the Q4863A mutation is to increase the apparent dissociation constant by increasing the apparent dissociation rate of the ryanoid. The voltage-dependence of the interaction displays no change. We infer that Q4863 is not involved with the voltage-drop but is able to influence ryanoid-bound structural changes. We discuss structural mechanisms by which this mutation could affect ryanoid interaction.

The interaction of an impermeant cation with the sheep cardiac RyR channel alters ryanoid association

In previous studies, we have demonstrated that the interaction of ryanoids with the sarcoplasmic reticulum Ca(2+)-release channel [ryanodine receptor (RyR)] incorporated into planar lipid bilayers reduced the effectiveness of tetraethylammonium (TEA(+)) as a blocker of K(+) translocation (J Gen Physiol 117: 385-393, 2001). In the current study, we investigated both the effect of TEA(+) on [(3)H]ryanodine binding and the actions of this impermeant cation on the interaction of the reversible ryanoid 21-amino-9alpha-hydroxyryanodine with individual, voltage-clamped RyR channels. A dose-dependent inhibition of [(3)H]ryanodine binding was observed in the presence of TEA(+), suggesting that the cation and alkaloid compete for access to a common site of interaction. Single channel studies gave further insights into the mechanism of the competition between the two classes of ligands. TEA(+) decreases the association rate of 21-amino-9alpha-hydroxyryanodine with its receptor, whereas the dissociation rate of the ryanoid from the channel was unaffected. Our results demonstrate that TEA(+) inhibits both K(+) translocation through RyR, and ryanoid interaction at the high affinity ryanodine site on the channel. These actions involve binding of TEA(+) to different, but weakly interacting, sites in the RyR channel.

Localisation, function and composition of primary Ca(2+) spark discharge region in isolated smooth muscle cells from guinea-pig mesenteric arteries

Smooth muscle cells (SMCs) contain numerous calcium release domains, grouped into regions discharging as a single unit. Laser scanning confocal microscopy, voltage clamp and immunocytochemistry of single SMCs from small mesenteric arteries of guinea-pig were used to study the localisation, function and macromolecular composition of such calcium discharge regions (CDRs). Use of the Ca(2+)-sensitive fluorescent dye fluo-3 or fluo-4 with BODIPY TR-X ryanodine (BTR), a fluorescent derivative of ryanodine, showed spontaneous Ca(2+) sparks originating from regions stained by BTR, located immediately under the plasma membrane, in the arch formed by the sarcoplasmic reticulum surrounding the nucleus. Membrane depolarisation or application of noradrenaline or alpha,beta-methylene ATP, a P2X purinoceptor agonist, elicited Ca(2+) sparks from the same, spontaneous Ca(2+) spark-discharging region. The most active (primary) CDR accounted for nearly 60% of spontaneous transient outward currents at -40 mV and these were of significantly higher amplitude than the ones discharged by secondary CDRs. Immunocytochemical staining for type 1 IP(3) receptors, BK(Ca) channels, P2X(1) purinoceptors or alpha(1) adrenoceptors revealed their juxtaposition with BTR staining at the location typical of the primary CDR. These data suggest the existence of a primary calcium discharge region in SMCs; its position can be predicted from the cell's structure, it acts as a key region for the regulation of membrane potential via Ca(2+) sparks and is a potential link between the external, neurohumoral and the cell's internal, calcium signalling system.

The interaction of ryanoids with individual ryanodine receptor channels

Ryanodine binds with high affinity and specificity to a class of Ca(2+)-release channels known as ryanodine receptors (RyR). The interaction with RyR results in a dramatic alteration in function with open probability (Po) increasing markedly and rates of ion translocation modified. We have investigated the features of ryanodine that govern the interaction of the ligand with RyR and the mechanisms underlying the subsequent alterations in function by monitoring the effects of congeners and derivatives of ryanodine (ryanoids) on individual RyR2 channels. While the interaction of all tested ryanoids results in an increased Po, the amplitude of the modified conductance state depends upon the structure of the ryanoid. We propose that different rates of cation translocation observed in the various RyR-ryanoid complexes represent different conformations of the channel stabilized by specific conformers of the ligand. On the time scale of a single channel experiment ryanodine binds irreversibly to the channel. However, alterations in structure yield some ryanoids with dissociation rate constants orders of magnitude greater than ryanodine. The probability of occurrence of the RyR-ryanoid complex is sensitive to trans-membrane voltage, with the vast majority of the influence of potential arising from a voltage-driven alteration in the affinity of the ryanoid-binding site.

The Gln4863Ala mutation within a putative, pore-lining trans-membrane helix of the cardiac ryanodine receptor channel alters both the kinetics of ryanoid interaction and the subsequent fractional conductance

The specific, high-affinity interaction of the plant toxin ryanodine with its molecular target the ryanodine receptor channel (RyR) has been instrumental in RyR research. Alanine scanning of putative pore regions of mouse RyR2 has highlighted the amino acid Gln4863, predicted to lie within trans-membrane helix TM10, as an important determinant of ryanodine binding. We have investigated the effects of several ryanodine derivatives, guanidinopropionylryanodine, 21-p-nitrobenzoylamino-9alpha-hydroxyryanodine, 8beta-amino-9alpha-hydroxyryanodine, and 21-amino-9alpha-hydroxyryanodine, with the mouse Q4863A RyR2 mutant at the single-channel level. Our results demonstrate that the rate of dissociation of all ryanoids investigated is increased by the mutation. The modification of channel function after ryanoid binding is qualitatively similar for wild-type and mutant, but in several cases, single-channel conductances were increased with Q4863A. These novel findings have been interpreted within the framework of existing comparative molecular field analysis studies on ryanoids. We suggest that replacement of a glutamine by an alanine residue at position 4863 causes RyR2 to simultaneously alter interactions with both ends of the ryanoid molecule.

Voltage-sensitive equilibrium between two states within a ryanoid-modified conductance state of the ryanodine receptor channel

We have investigated the influence of transmembrane holding potential on the kinetics of interaction of a cationic ryanoid, 8beta-amino-9alpha-hydroxyryanodine, with individual ryanodine receptor (RyR) channels and on the functional consequences of this interaction. In agreement with previous studies involving cationic, neutral, and anionic ryanoids, both rates of association and dissociation of the ligand are sensitive to transmembrane potential. A voltage-sensitive equilibrium between high- and low-affinity forms of the receptor underlies alterations in rates of association and dissociation of the ryanoid. The interaction of 8beta-amino-9alpha-hydroxyryanodine with RyR influences the rate of cation translocation through the channel. With this ryanoid bound, the channel fluctuates between two clearly resolved subconductance states (alpha and beta). We interpret this observation as indicating that with 8beta-amino-9alpha-hydroxyryanodine bound, the pore of the RyR channel exists in two essentially isoenergetic conformations with differing ion-handling properties. The equilibrium between the alpha- and beta-states of the RyR-8beta-amino-9alpha-hydroxyryanodine complex is sensitive to transmembrane potential. However, the mechanisms determining this equilibrium differ from those responsible for the voltage-sensitive equilibrium between high- and low-affinity forms of the receptor.

An anionic ryanoid, 10-O-succinoylryanodol, provides insights into the mechanisms governing the interaction of ryanoids and the subsequent altered function of ryanodine-receptor channels

We have investigated the interactions of a novel anionic ryanoid, 10-O-succinoylryanodol, with individual mammalian cardiac muscle ryanodine receptor channels under voltage clamp conditions. As is the case for all ryanoids so far examined, the interaction of 10-O-succinoylryanodol with an individual RyR channel produces profound alterations in both channel gating and rates of ion translocation. In the continued presence of the ryanoid the channel fluctuates between periods of normal and modified gating, indicating a reversible interaction of the ligand with its receptor. Unlike the majority of ryanoids, we observe a range of different fractional conductance states of RyR in the presence of 10-O-succinoylryanodol. We demonstrate that 10-O-succinoylryanodol is a very flexible molecule and propose that each fractional conductance state arises from the interaction of a different conformer of the ryanoid molecule with the RyR channel. The probability of channel modification by 10-O-succinoylryanodol is dependent on the transmembrane holding potential. Comparison of the voltage dependence of channel modification by this novel anionic ryanoid with previous data obtained with cationic and neutral ryanoids reveals that the major influence of transmembrane potential on the probability of RyR channel modification by ryanoids results from an alteration in receptor affinity. These investigations also demonstrate that the charge of the ryanoid has a major influence on the rate of association of the ligand with its receptor indicating that ionic interactions are likely to be involved in this reaction.

Diketopyridylryanodine has three concentration-dependent effects on the cardiac calcium-release channel/ryanodine receptor

By interacting with more than one site, ryanoids induce multiple effects on calcium-release channels. To date, the kinetics of interaction of only one of these sites has been characterized. Using C(4),C(12)-diketopyridylryanodine in both [(3)H]ryanodine binding and single channel experiments we characterized another site on the cardiac ryanodine receptor (RyR2) with which ryanoids interact. Competitive binding of this ryanoid to RyR2 implied a minimal two-site binding model. At the single channel level, C(4),C(12)-diketopyridylryanodine induced three distinct effects. At nanomolar concentrations, it increased channel open probability severalfold without inducing a subconductance. This effect was independent of membrane holding potential. As for other ryanoids, low micromolar concentrations of C(4),C(12)-diketopyridylryanodine readily induced a subconductance state. The major subconductance had a current amplitude of 52% of fully open, it was reversible, and its time to induction and duration were voltage- and concentration-dependent, affording Hill slopes of >2. At higher micromolar concentrations C(4),C(12)-diketopyridylryanodine induced long lasting, yet reversible shut states. Using a pharmacological strategy we have discerned an additional ryanoid-binding site on RyR2 that triggers an increase in channel activity. This site likely resides outside the strict confines of the transmembrane conducting pathway.

Excess noise in modified conductance states following the interaction of ryanoids with cardiac ryanodine receptor channels

The interaction of ryanodine with the ryanodine receptor (RyR) produces profound changes in channel function. Open probability increases dramatically and conductance is reduced. In this report we describe differences in the properties of reduced conductance states produced by the interaction of ryanodine derivatives with RyR channels. Some reduced conductance states are considerably noisier than the normal open state of the RyR channel. Inspection and analysis of these events reveals that the excess noise arises from transitions between two conductance states. Following the interaction of certain ryanodine derivatives, RyR channels undergo transitions between two conformations with slightly different ion-handling properties.

A ryanodine fluorescent derivative reveals the presence of high-affinity ryanodine binding sites in the Golgi complex of rat sympathetic neurons, with possible functional roles in intracellular Ca(2+) signaling

The plant alkaloid ryanodine (Ry) is a high-affinity modulator of ryanodine receptor (RyR) Ca(2+) release channels. Although these channels are present in a variety of cell types, their functional role in nerve cells is still puzzling. Here, a monosubstituted fluorescent Ry analogue, B-FL-X Ry, was used to reveal the distribution of RyRs in cultured rat sympathetic neurons. B-FL-X Ry competitively inhibited the binding of [3H]Ry to rabbit skeletal muscle SR membranes, with an IC(50) of 150 nM, compared to 7 nM of unlabeled Ry. Binding of B-FL-X Ry to the cytoplasm of sympathetic neurons is saturable, reversible and of high affinity. The pharmacology of B-FL-X Ry showed marked differences with unlabeled Ry, which are partially explained by its lower affinity: (1) use-dependent reversible inhibition of caffeine-induced intracellular Ca(2+) release; (2) diminished voltage-gated Ca(2+) influx, due to a positive shift in the activation of voltage gated Ca(2+) currents. B-FL-X Ry-stained sympathetic neurons, viewed under confocal microscopy, showed conspicuous labeling of crescent-shaped structures pertaining to the Golgi complex, a conclusion supported by experiments showing co-localization with Golgi-specific fluorescent probes and the breaking up of crescent-shaped staining after treatment with drugs that disassemble Golgi complex. The presence of RyRs to the Golgi could be confirmed with specific anti-RyR(2) antibodies, but evidence of caffeine-induced Ca(2+) release from this organelle could not be obtained using fast confocal microscopy. Rather, an apparent decrease of the cytosolic Ca(2+) signal was detected close to this organelle. In spite of that, short-term incubation with brefeldin A (BFA) suppressed the fast component of caffeine-induced Ca(2+) release, and the Ca(2+) release process lasted longer and appeared less organized. These observations, which suggest a possible role of the Golgi complex in Ca(2+) homeostasis and signaling in nerve cells, could be relevant to reports involving derangement of the Golgi complex as a probable cause of some forms of progressive neuronal degeneration, such as Alzheimer's disease and amyotrophic lateral sclerosis.

Ryanoid modification of the cardiac muscle ryanodine receptor channel results in relocation of the tetraethylammonium binding site

The interaction of ryanodine and derivatives of ryanodine with the high affinity binding site on the ryanodine receptor (RyR) channel brings about a characteristic modification of channel function. In all cases, channel open probability increases dramatically and single-channel current amplitude is reduced. The amplitude of the ryanoid-modified conductance state is determined by structural features of the ligand. An investigation of ion handling in the ryanodine-modified conductance state has established that reduced conductance results from changes in both the affinity of the channel for permeant ions and the relative permeability of ions within the channel (Lindsay, A.R.G., A. Tinker, and A.J. Williams. 1994. J. Gen. Physiol. 104:425-447). It has been proposed that these alterations result from a reorganization of channel structure induced by the binding of the ryanoid. The experiments reported here provide direct evidence for ryanoid-induced restructuring of RyR. TEA+ is a concentration- and voltage-dependent blocker of RyR in the absence of ryanoids. We have investigated block of K+ current by TEA+ in the unmodified open state and modified conductance states of RyR induced by 21-amino-9alpha-hydroxyryanodine, 21-azido-9alpha-hydroxyryanodine, ryanodol, and 21-p-nitrobenzoylamino-9alpha-hydroxyryanodine. Analysis of the voltage dependence of block indicates that the interaction of ryanoids with RyR leads to an alteration in this parameter with an apparent relocation of the TEA+ blocking site within the voltage drop across the channel and an alteration in the affinity of the channel for the blocker. The degree of change of these parameters correlates broadly with the change in conductance of permeant cations induced by the ryanoids, indicating that modification of RyR channel structure by ryanoids is likely to underlie both phenomena.

Pseudoreceptor model for ryanodine derivatives at calcium release channels

This paper describes the generation of a pseudoreceptor model for ryanodine receptor (RyR) modulating ryanoids in rabbit skeletal muscle. For this purpose, the molecular modelling software PrGen was applied to correlate experimentally determined and calculated free energies of binding for a set of 15 ryanodine derivatives. The final model indicates a narrow cleft with hydrogen bond donor and acceptor capacities (represented by an Asn) as most crucial for binding the pyrrole carboxylate substituent at C3 of ryanodine. In addition, hydrophobic residues flank the aromatic pyrrole ring (Tyr, Phe, and Ile). Two of those residues (Tyr and Ile) interact with the 2-isopropyl moiety, which seems to contribute to binding. Opposite to the pyrrole locus, a second hydrophobic region (represented by a Leu) restricts ryanodine derivatives in their longitudinal axis and leads to the discrimination of equatorial and axial positioned methyl groups and of polar substituents at C9. Finally, a charged glutamate residue generates strong hydrogen bonding and electrostatic interactions with the hydroxyl groups at C10 and C15. For this binding-site model--composed of six amino acid residues--a correlation for the training set ligands of R = 0.99 (Q2 = 0.975) and a root mean square (rms) deviation of 0.568 kcal/mol for the prediction of the binding energies of four test set ligands was obtained. Based on this pseudoreceptor model the putative topology of the real binding site of ryanoids will be discussed.

The interaction of a neutral ryanoid with the ryanodine receptor channel provides insights into the mechanisms by which ryanoid binding is modulated by voltage

In an earlier investigation, we demonstrated that the likelihood of interaction of a positively charged ryanoid, 21-amino-9alpha-hydroxyryanodine, with the sarcoplasmic reticulum Ca(2+)-release channel (ryanodine receptor, RyR) is dependent on holding potential (Tanna, B., W. Welch, L. Ruest, J.L. Sutko, and A. J. Williams. 1998. J. Gen. Physiol. 112:55-69) and suggested that voltage dependence could result from either the translocation of the charged ligand to a site within the voltage drop across the channel or a voltage-driven alteration in receptor affinity. We now report experiments that allow us to assess the validity of these alternate mechanisms. Ryanodol is a neutral ryanoid that binds to RyR and induces modification of channel function. By determining the influence of transmembrane potential on the probability of channel modification by ryanodol and the rate constants of ryanodol association and dissociation, we demonstrate that the influence of voltage is qualitatively the same for both the neutral and positively charged ryanoids. These experiments establish that most, if not all, of the modification of ryanoid interaction with RyR by transmembrane holding potential results from a voltage-driven alteration in receptor affinity.

Interactions of a reversible ryanoid (21-amino-9alpha-hydroxy-ryanodine) with single sheep cardiac ryanodine receptor channels

The binding of ryanodine to a high affinity site on the sarcoplasmic reticulum Ca2+-release channel results in a dramatic alteration in both gating and ion handling; the channel enters a high open probability, reduced-conductance state. Once bound, ryanodine does not dissociate from its site within the time frame of a single channel experiment. In this report, we describe the interactions of a synthetic ryanoid, 21-amino-9alpha-hydroxy-ryanodine, with the high affinity ryanodine binding site on the sheep cardiac sarcoplasmic reticulum Ca2+-release channel. The interaction of 21-amino-9alpha-hydroxy-ryanodine with the channel induces the occurrence of a characteristic high open probability, reduced-conductance state; however, in contrast to ryanodine, the interaction of this ryanoid with the channel is reversible under steady state conditions, with dwell times in the modified state lasting seconds. By monitoring the reversible interaction of this ryanoid with single channels under voltage clamp conditions, we have established a number of novel features of the ryanoid binding reaction. (a) Modification of channel function occurs when a single molecule of ryanoid binds to the channel protein. (b) The ryanoid has access to its binding site only from the cytosolic side of the channel and the site is available only when the channel is open. (c) The interaction of 21-amino-9alpha-hydroxy-ryanodine with its binding site is influenced strongly by transmembrane voltage. We suggest that this voltage dependence is derived from a voltage-driven conformational alteration of the channel protein that changes the affinity of the binding site, rather than the translocation of the ryanoid into the voltage drop across the channel.

Structure-function relationships among ryanodine derivatives. Pyridyl ryanodine definitively separates activation potency from high affinity

Ryanodine derivatives are differentially effective on the two limbs of the ryanodine concentration-effect curve. This study comparing ryanodine, ryanodol, and pyridyl ryanodine and nine C10Oeq esters of them focuses on structure-function relations underlying their differential effectiveness. Ryanodol and pyridyl ryanodine had significantly lower affinities than ryanodine, but their EC50act values (concentration of ryanoid that induces one-half of full efficacy), potencies, and efficacies were not diminished in like fashion. Ryanodine and ryanodol were partial agonists, whereas pyridyl ryanodine was a full agonist, having a diminished deactivation potency. C10Oeq esterifications enhanced affinities and efficacies of the base ryanoids. The C10-Oeq ester derivatives of ryanodine and pyridyl ryanodine, but not those of ryanodol, lost their capacity to deactivate RyR1s. Thus, affinity differences among ryanoids clearly do not predicate functional differences as regards activation of Ca2+ release channels. The pyrrole carboxylate on the C3 of ryanodine is dispensable to ryanoid activation of Ca2+ release channels. Ryanodol lacks this ring, but it nevertheless effects substantial activation. Moreover, its C10-Oeq esters display full efficacy. The increased ability of all the C10-Oeq derivatives to release Ca2+ from the vesicles strengthens their role in directly impeding deactivation of RyR1, perhaps by interaction with some component within the transmembrane ionic flux pathway.

Structural components of ryanodine responsible for modulation of sarcoplasmic reticulum calcium channel function

Comparative molecular field analysis (CoMFA) was used to analyze the relationship between the structure of a group of ryanoids and the modulation of the calcium channel function of the ryanodine receptor. The conductance properties of ryanodine receptors purified from sheep heart were measured using the planar, lipid bilayer technique. The magnitude of the ryanoid-induced fractional conductance was strongly correlated to specific structural loci on the ligand. Briefly, electrostatic effects were more prominent than steric effects. The 10-position of the ryanoid had the greatest influence on fractional conductance. Different regions of the ligand have opposing effects on fractional conductance. For example, steric bulk at the 10-position is correlated with decreased fractional conductance, whereas steric bulk at the 2-position (isopropyl position) is correlated with increased fractional conductance. In contrast to fractional conductance, the 3-position (the pyrrole locus) had the greatest influence on ligand binding, whereas the 10-position had comparatively little influence on binding. Two possible models of ryanodine action, a direct (or channel plug) mechanism and an allosteric mechanism, were examined in light of the CoMFA. Taken together, the data do not appear to be consistent with direct interaction between ryanodine and the translocating ion. The data appear to be more consistent with an allosteric mechanism. It is suggested the ryanoids act by inducing or stabilizing a conformational change in the ryanodine receptor that results in the observed alterations in cation conductance.

Ryanoids change the permeability of potassium channels of locust (Schistocerca gregaria) muscle

The plasma membrane of locust skeletal muscle contains two types of K+ channel; a maxi, Ca2+-activated 170 pS channel (BK channel) and an inward rectifier of 35 pS conductance (IK channel). The effects of ryanodine, 9,21-didehydroryanodine and 9,21-didehydroryanodol on these channels have been investigated. In the concentration domain 10(-9) M to 10(-5) M, ryanodine irreversibly induced a dose-dependent reduction of the reversal potential (Vrev) of the channel currents, measured under physiologically normal K+ and Na+ gradients, i.e. from approximately 60 mV in the absence of ryanodine to approximately 15 mV for 10(-5) M ryanodine. The alteration of K+ channel selectivity was Ca2+ independent. 9,21-Didehydroryanodine and 9,21-didehydroryanodol reduced Vrev, but only to approximately 35 mV during application of 10(-5) M of these compounds. 9,21-Didehydroryanodine also diminished the conductances of the locust K+ channels. The three ryanoids reduced Vrev of a Ca2+-activated, high-conductance channel in inside-out patches excised from mouse interosseal muscle, although the changes were in each case less pronounced than those for the locust K+ channels. Also, the action of 9,21-didehydroryanodine on mouse K+ (BK) channels was restricted to a shift of Vrev. For all three ryanoids, the IC50 coefficients (i.e. the concentration of toxin that gave a 50% reduction in Vrev) for the shifts in Vrev were similar for the locust and mouse muscle K+ channels.

The pyrrole locus is the major orienting factor in ryanodine binding

Ryanodine, a natural product, is a complex modulator of a class of intracellular Ca2+ release channels commonly called the ryanodine receptors. Ryanodine analogs can cause the channel to persist in long-lived, subconductance states or, at high ligand concentrations, in closed, nonconducting states. In this paper, we further explore the relationship between structure and ryanodine binding to striated muscle. Ryanodine, 3-epiryanodine, and 10-ryanodine are three structural isomers of ryanodine. The dissociation constants of these compounds were measured using rabbit skeletal muscle ryanodine receptors. Placing the pyrrole carbonyl group at the 3-epi- and 10-positions of ryanodol largely restores the large loss of binding energy observed when ryanodine is hydrolyzed to ryanodol. Comparative molecular field analysis successfully predicts the enhanced binding and indicates that the pyrrole group controls the orientation of ligand binding. We propose that the ryanoids are reorientated in the binding site of the ryanodine receptors such that the pyrrole always occupies the same subsite. By applying this model, the binding constants of other ryanoids are predicted.

Electrophysiological effects of ryanodine derivatives on the sheep cardiac sarcoplasmic reticulum calcium-release channel

We have examined the effects of a number of derivatives of ryanodine on K+ conduction in the Ca2+ release channel purified from sheep cardiac sarcoplasmic reticulum (SR). In a fashion comparable to that of ryanodine, the addition of nanomolar to micromolar quantities to the cytoplasmic face (the exact amount depending on the derivative) causes the channel to enter a state of reduced conductance that has a high open probability. However, the amplitude of that reduced conductance state varies between the different derivatives. In symmetrical 210 mM K+, ryanodine leads to a conductance state with an amplitude of 56.8 +/- 0.5% of control, ryanodol leads to a level of 69.4 +/- 0.6%, ester A ryanodine modifies to one of 61.5 +/- 1.4%, 9,21-dehydroryanodine to one of 58.3 +/- 0.3%, 9 beta,21beta-epoxyryanodine to one of 56.8 +/- 0.8%, 9-hydroxy-21-azidoryanodine to one of 56.3 +/- 0.4%, 10-pyrroleryanodol to one of 52.2 +/- 1.0%, 3-epiryanodine to one of 42.9 +/- 0.7%, CBZ glycyl ryanodine to one of 29.4 +/- 1.0%, 21-p-nitrobenzoyl-amino-9-hydroxyryanodine to one of 26.1 +/- 0.5%, beta-alanyl ryanodine to one of 14.3 +/- 0.5%, and guanidino-propionyl ryanodine to one of 5.8 +/- 0.1% (chord conductance at +60 mV, +/- SEM). For the majority of the derivatives the effect is irreversible within the lifetime of a single-channel experiment (up to 1 h). However, for four of the derivatives, typified by ryanodol, the effect is reversible, with dwell times in the substate lasting tens of seconds to minutes. The effect caused by ryanodol is dependent on transmembrane voltage, with modification more likely to occur and lasting longer at +60 than at -60 mV holding potential. The addition of concentrations of ryanodol insufficient to cause modification does not lead to an increase in single-channel open probability, such as has been reported for ryanodine. At concentrations of > or = 500 mu M, ryanodine after initial rapid modification of the channel leads to irreversible closure, generally within a minute. In contrast, comparable concentrations of beta-alanyl ryanodine do not cause such a phenomenon after modification, even after prolonged periods of recording (>5 min). The implications of these results for the site(s) of interaction with the channel protein and mechanism of the action of ryanodine are discussed. Changes in the structure of ryanodine can lead to specific changes in the electrophysiological consequences of the interaction of the alkaloid with the sheep cardiac SR Ca2+ release channel.

Novel actions of ryanodine and analogues--perturbers of potassium channels

The effects of ryanodine, 9,21-didehydroryanodine and 9,21-didehydroryanodol on two types of K(+) channel (a maxi, Ca(2+)-activated, 170pS channel (BK channel) and an inward rectifier, stretch sensitive channel of 35 pS conductance (IK channel)found in the plasma membrane of locust skeletal muscle have been investigated. 10(-9) M-10(-5) M ryanodine irreversibly induced a dose-dependent reduction of the reversal potential (V (rev)) of the currents of both channels, i.e. from 60 mV in the absence of the alkaloid to 15 mV for 10(-5) M ryanodine, measured under physiologically normal K(+) and Na(+) gradients. In both cases the change in the ionic selectivity was Ca(2+) -independent. 9,21-didehydroryanodine and 9,21-didehyroryanodol also reduced V (rev), but only to 35 mV during application of 10(-5) M of these compounds. Additionally, 9,21-didehydroryanodine reversibly diminished the conductances of the two K(+) channels. To test the hypothesis that ryanoids increase Na permeability by enlarging the K(+) channels, the channels were probed with quaternary ammonium ions during ryanoid application. When applied to the cytoplasmic face of inside-out patches excised from locust muscle membrane, TEA blocked the K(+) channels in a voltage-dependent fashion. The dissociation constant (K (d)(0)) for TEA block of the IK channel was reduced from 44 mM to 1 mM by 10(-7) M ryanodine, but the voltage-dependence of the block was unaffected. Qualitatively similar data were obtained for the BK channel. Ryanodine had no effect on the K (d) for cytoplasmically-applied TMA. However, the voltage-dependence for TMA block was increased for both K(+) channels, from 0.47 to 0.8 with 10(-6) M ryanodine. The effects of ryanodine on TEA and TMA block support the hypothesis that ryanodine enlarges the K(+) channels so as to facilitate permeation of partially hydrated Na(+) ions.

Activation and deactivation of sarcoplasmic reticulum calcium release channels: molecular dissection of mechanisms via novel semi-synthetic ryanoids

The plant alkaloids ryanodine and dehydroryanodine are high affinity, biphasic modulators of the intracellularly located, calcium-regulated calcium release channels of a variety of cell types. To date, little is certain about the molecular basis of the interactions that prompt low concentrations of ryanodine (nanomolar to low micromolar) to activate (open) the channels and higher concentrations to deactivate (functionally close) the sarcoplasmic reticulum calcium release channel. In the present study, we approached this question using novel, semi-synthetic C10-Oeq ester derivatives of ryanodine and dehydroryanodine as molecular probes of the ryanodine binding sites on the calcium release channel. Binding affinities of these C10-Oeq ester derivatives of ryanodine and dehydroryanodine with acidic, basic and neutral side chains (Kd values > 53.9 nM, Kd values 0.3-0.7 nM and Kd values 1.3-20.4 nM, compared with 2.3 and 2.8 nM for ryanodine and dehydroryanodine, respectively) were evaluated for their ability to modulate the patency of the sarcoplasmic reticulum calcium release channel. With the exception of only two derivatives tested to date, all the semi-synthetic C10-Oeq esters selectively activate the Ca2+ release channel. That is, they produce no functional closure of the sarcoplasmic reticulum calcium release channels at the highest concentration that could be tested. Half-maximal concentrations for activation (EC50act values) ranged from 0.87-4.2 microM, compared with an EC50act of 1.3 microM for ryanodine. Using a low concentration (0.5 nM) of a high specific activity, radioiodinated derivative of ryanodine, C10-Oeq N-(4-azido-5-125iodo salicyloyl) glycyl ryanodine (1400 Ci/mmol) as the radioligand in displacement binding affinity assays, two distinct, sequential ryanodine binding isotherms were demonstrated within the normal 0-300 nM ryanodine sigmoidal displacement curve. A high affinity site had an IC50 of 0.5 nM (Kd = 0.26 +/- 0.02 nM). Above this concentration, an apparent plateau occurred between 3 and 6 nM ryanodine, and at higher concentrations a lower affinity site was revealed that demonstrated an IC50 of about 25 nM (Kd = 11.7 +/- 1.2 nM). Scatchard analysis from direct binding of C10-Oeq N-(4-azido-5-125iodo salicyloyl) glycyl ryanodine to junctional sarcoplasmic reticulum vesicles also suggests the presence of more than one class of binding sites within the nanomolar concentration range. The high affinity site demonstrated a Bmax of 3 pmol/mg protein. We were unable to saturate the lower affinity binding sites with this ligand. To evaluate the functional effects occurring among sarcoplasmic reticulum calcium release channel monomers as a consequence of ryanodine's binding, we utilized a photo-activatable derivative of ryanodine, C10-Oeq N-(4-azido salicyloyl) glycyl ryanodine that demonstrates channel modulating characteristics similar to ryanodine. Covalently labeling the sarcoplasmic reticulum calcium-release channels with this ligand, followed by measurements of rates of calcium efflux and SDS-PAGE of the labeled protein, revealed that deactivation of the sarcoplasmic reticulum calcium release channels of skeletal muscle by this ryanoid occurred at concentrations which apparently produce virtually irreversibly interactions between receptor monomers. This 'polymerization' was indicated by the progressive appearance of two higher molecular weight protein bands on SDS-PAGE, concomitant with progressive decreases in the ryanodine receptor monomer band that runs at an apparent molecular mass of 365 kDa. In summary, we have prepared and utilized novel C10-Oeq ester derivatives of ryanodine and dehydroryanodine in studies aimed at better understanding the molecular basis for the complex biphasic actions of ryanodine on the sarcoplasmic reticulum calcium release channels from rabbit skeletal muscle cells. The described studies presage correlations that may be useful in furthering our understa

Spiganthine, the cardioactive principle of Spigelia anthelmia

Spiganthine [1] was isolated as the main cardioactive principle from medicinally used extracts of Spigelia anthelmia. Its structure was established by spectroscopic methods. The biological effect of spiganthine is characterized by a delay in contraction development of the heart muscle.

High affinity C10-Oeq ester derivatives of ryanodine. Activator-selective agonists of the sarcoplasmic reticulum calcium release channel

The plant alkaloids ryanodine and dehydroryanodine are specific and potent modulators of the sarcoplasmic reticulum calcium release channel. In the present study, acidic, basic, and neutral side chains esters of these diterpene compounds were prepared and their pharmacologic activities were assessed. Binding affinities of the novel C10-Oeq ester derivatives for the sarcoplasmic reticulum Ca2+ release channel were evaluated with sarcoplasmic reticular vesicles prepared from rabbit skeletal muscle. Kd values of the derivatives varied 500-fold, ranging from 0.5 to 244 nM. In comparison, Kd values for ryanodine and dehydroryanodine were 4.4 nM and 5.4 nM, respectively. Basic substituents at the C10-Oeq side chain terminus produced the highest affinity derivatives (Kd values from 0.5 to 1.3 nM). Neutral and/or hydrophobic side chain derivatives exhibited intermediate affinities for the high affinity ryanodine receptor site (Kd values from 2.5 to 39 nM), whereas a derivative with a terminal acidic group had the lowest affinity (Kd value > 100 nM). Certain of the higher affinity C10-Oeq derivatives were evaluated more extensively for their pharmacologic activity on the sarcoplasmic reticular Ca2+ release channel. Both channel activating (opening) and deactivating (closing) actions were assessed from the ability of the ryanoids to alter Ca2+ efflux rates from skeletal junctional sarcoplasmic reticular vesicles that had been passively loaded with Ca2+. The natural Ryania secondary metabolites ryanodine, dehydroryanodine and esters E and F, all exhibit antithetical concentration-effect curves, indicating both activator and deactivator actions. In contrast, the semi-synthetic C10-Oeq esters selectively activate the Ca2+ release channel. Half-maximal concentrations for such activation (EC50 act) ranged from 0.87 microM to 4.2 microM, compared with an EC50 act of 1.3 microM for ryanodine. These derivatives were also evaluated for their ability to augment ATP-dependent CA2+ accumulation by cardiac junctional sarcoplasmic reticular vesicles, an effect that results from deactivation of the Ca2+ release channels. None of the derivatives tested was able to significantly augment Ca2+ accumulation, further substantiating their inability to deactivate the sarcoplasmic reticular Ca2+ release channel. Additionally, these derivatives functionally antagonized the action of ryanodine to close the Ca2+ release channel. The results presented demonstrate that these C10-Oeq ester derivatives of ryanodine and dehydroryanodine bind specifically to the SR Ca2+ release channel, selectively activate the channel, and, although they fail to effect channel closure, they nevertheless functionally compete with ryanodine at its low affinity (deactivator) site(s).

Ryanodine and an iodinated analog: doxorubicin effects on binding and Ca2+ accumulation in cardiac sarcoplasmic reticulum

An 125I-iodinated ryanodine analog, modified by attaching an iodo-Cbz-beta-alanyl group to the C10eq hydroxy of ryanodine (iodo-carbobenzyloxy-beta-alanyl-ryanodine), binds to cardiac sarcoplasmic reticulum Ca2+ release channels with equal affinity as [3H]ryanodine. In the present study, both iodo-Cbz-beta-alanyl-ryanodine and ryanodine bound to canine cardiac microsomal membrane preparations in a Ca2+ dependent manner. At 10 microM free Ca2+ doxorubicin increased specific binding of both ligands, with doxorubicin concentrations of 4.06 +/- 0.44 and 6.22 +/- 1.31 microM inducing 50% maximal enhancement of binding for ryanodine and iodo-Cbz-beta-alanyl-ryanodine, respectively. Effects of ryanodine and iodo-Cbz-beta-alanyl-ryanodine +/- doxorubicin in vitro on cardiac sarcoplasmic reticulum Ca2+ release were compared indirectly by determining Ca2+ accumulation in cardiac microsomal vesicles loaded with 45Ca2+. In the absence of oxalate, neither ryanodine nor iodo-Cbz-beta-alanyl-ryanodine (10 microM) decreased net Ca2+ uptake, whereas doxorubicin reduced Ca2+ accumulation 20 +/- 2%. In the presence of oxalate and 0.4 microM free Ca2+ ("low"), both ryanodine and iodo-Cbz-beta-alanyl-ryanodine modestly decreased (by 19% and 17% at 10 nM, respectively) maximum Ca2+ accumulation. Increasing concentrations of ryanodine (100 nM-100 microM) and iodo-Cbz-beta-alanyl-ryanodine (100 nM-30 microM) had no greater effect, but 100 microM iodo-Cbz-beta-alanyl- ryanodine decreased net Ca2+ uptake 57 +/- 3%. Doxorubicin (30 microM) alone reduced Ca2+ uptake 36%; its effects with 1 nM-10 microM ryanodine or 1 nM-100 microM iodo-Cbz-beta-alanyl-ryanodine were additive.(ABSTRACT TRUNCATED AT 250 WORDS)

Structural determinants of high-affinity binding of ryanoids to the vertebrate skeletal muscle ryanodine receptor: a comparative molecular field analysis

Ryanodine binds to specific membrane proteins, altering the calcium permeability of intracellular membranes. In this study 19 ryanoids were isolated or synthesized and the structures correlated to the strength of binding to vertebrate skeletal muscle ryanodine receptors. Global minima were determined by employment of molecular mechanics and dynamics augmented by systematic searching of conformational space. Overall, steric and electrostatic factors contribute about equally to the differences in the experimentally determined dissociation constants. The dominant electrostatic interaction is localized to a hydroxyl group in an apolar region of the molecule. The pyrrole and isopropyl groups located together at one pole of the molecule have the greatest effect on steric interactions between ligand and receptor. We suggest ryanodine binds to the receptor with the pyrrole and isopropyl groups buried deep inside a cleft in the protein. This arrangement places special importance on the conformation of the pyrrole and isopropyl groups. In contrast, the opposite pole appears to be positioned at the entrance of the binding pocket because bulky adducts placed in the 9 position of ryanodine alter binding minimally. For example, a fluorescent ryanodine adduct was synthesized which has a dissociation constant close to that of ryanodine. Detailed examination reveals subtle interactions between ryanoid and receptor. In many cases, the major factors altering the strength of binding were found to be conformational alterations in the molecule remote from the site of covalent modification.

Photoaffinity labeling of the ryanodine receptor/Ca2+ release channel with an azido derivative of ryanodine

Ryanodine receptors/Ca2+ release channels play an important role in regulating the intracellular free calcium concentrations in both muscle and nonmuscle cells. Ryanodine, a neutral plant alkaloid, specifically binds to and modulates these Ca2+ release channels. In the work described here, we characterize the interaction of a tritium-labeled, photoactivable derivative of ryanodine (3H-labeled 10-O-[3-(4-azidobenzamido)propionyl]ryanodine ([3H]ABRy)) with the ryanodine receptor of skeletal, cardiac, and brain membranes. Scatchard analysis demonstrates that this ligand binds to a single class of high affinity sites in skeletal muscle triads. Furthermore, competition binding assays of [3H]ryanodine with skeletal, cardiac, and brain membranes in the presence of increasing concentrations of unlabeled ABRy illustrate that this azido derivative of ryanodine is able to specifically displace [3H]ryanodine from its binding site(s). Analysis of the effects of Ca2+, ATP, and KCl on [3H]ABRy binding in triad membranes shows a similar modulation of binding to that seen in these membranes with [3H]ryanodine. Photoaffinity labeling of triads with [3H]ABRy resulted in specific and covalent incorporation of [3H]ABRy into a 565-kDa protein that was shown to be the skeletal muscle ryanodine receptor. Digestion of the labeled ryanodine receptor revealed a [3H]ABRy-labeled 76-kDa tryptic fragment that was identified with an antibody directed against the COOH-terminal of the receptor. These results demonstrate that the 76-kDa COOH-terminal tryptic fragment contains the high affinity binding site for ryanodine.

Radioimmunoassay for the calcium release channel agonist ryanodine

A novel photo-activatable derivative of ryanodine, 9-hydroxy-21-(4-azidobenzoyloxy)-9-epiryanodine, has been synthesized and conjugated to keyhole limpet hemocyanin for the production of antibodies with high affinity and specificity to ryanodine. The anti-ryanodine antibodies reacted specifically on immunoblots with the azido-ryanodine compound covalently conjugated to bovine serum albumin. A radioimmunoassay specific for ryanodine was developed using the anti-ryanodine antibodies, and a dissociation constant for ryanodine of 1 nM was determined. Half-maximal inhibition constants (IC50) for various ryanodine derivatives were found to range between 3.2 and 200 nM. These IC50 values correlated very well with the IC50 values obtained for the compounds binding to the skeletal muscle membrane receptor. These antibodies should be useful for the characterization of the ryanodine binding site on the sarcoplasmic reticulum Ca2+ release channel.

High-purity ryanodine and 9,21-dehydroryanodine for in vitro diagnosis of malignant hyperthermia in man

Susceptibility to malignant hyperthermia (MH) is currently diagnosed by the in vitro contracture test (IVCT) in skeletal muscle. However, this test does not possess absolute specificity. Thus, in addition to the established procedure, the "ryanodine contracture test" has been proposed to improve discrimination between MH-susceptible (MHS) and normal (MHN) patients. In all previous studies, the ryanodine used was a mixture consisting of high-purity ryanodine (HPR) and 9,21-dehydroryanodine (DHR). Therefore, in this study the effects of both substances were investigated in concentrations of 2, 5 and 10 mumol litre-1. With all concentrations, contractures appeared earlier in MHS than in MHN muscles, but these differences were significant at all contracture levels with HPR only. Moreover, with the smallest concentration (2 mumol litre-1), the best discrimination between MHS and MHN was observed. Classification of MH-equivocal patients (MHE) as MHS or MHN seems to be possible with the use of ryanodine-induced contractures. The contracture test with HPR should therefore be added to the established procedure of the IVCT.

Differential activating and deactivating effects of natural ryanodine congeners on the calcium release channel of sarcoplasmic reticulum: evidence for separation of effects at functionally distinct sites

Two novel natural ryanoids from extracts of the wood of Ryania speciosa Vahl were evaluated with sarcoplasmic reticulum (SR) vesicles for their binding affinities and their activating and deactivating effects on Ca2+ release channels. The new ryanoids, which are more polar than the known Ryania constituents ryanodine and didehydro-(9,21)-ryanodine, were purified using silica gel column chromatography and reverse phase high performance liquid chromatography. The new ryanoids were designated ester E and ester F, in keeping with nomenclature previously used in the literature. These compounds were identified by NMR spectroscopy and mass spectroscopy as C9ax-hydroxyryanodine and C8ax-hydroxy-C10-epi-dehydroryanodine, respectively. Binding of esters E and F to the high affinity (nanomolar Kd) site on SR Ca2+ release channels was determined from relative binding affinity assays using 6.7 nM [3H]ryanodine. Apparent Kd values of ryanodine, ester E, and ester F for binding to this domain on the skeletal muscle ryanodine receptor/SR Ca2+ release channel were 4.4 +/- 0.8, 65 +/- 10, and 257 +/- 53 nM, respectively (mean +/- standard deviation, four or more experiments). Apparent Kd values for cardiac muscle receptors were 0.51 +/- 0.01, 12 +/- 0.4, and 57 nM, respectively. As a functional indication of the effects of the ryanoids, channel-opening (activator) and channel-closing (deactivator) actions were assessed from the ability of the ryanoids to alter the rate of Ca2+ efflux from passively loaded skeletal muscle junctional sarcoplasmic reticular vesicles (JSRV). Activator actions among the ryanoids were similar, in that they exhibited apparently parallel concentration-effect curves, having a slope of 40% Ca2+ loss/decade increment in ryanoid concentration. Half-maximal values for activation (EC50 values) were 2.5, 63, and 43 microM for ryanodine, ester E, and ester F, respectively. Maximal channel opening by ester E was significantly less than that produced by the other ryanoids. The deactivator actions of the compounds on skeletal JSRV were dissimilar, in that their concentration-effect curves appeared not to be parallel. The quotient of the EC50 for deactivation and that for activation was taken as the concentration-coupling ratio (CCR). The CCR for ryanodine was 114 and that for ester F was 72, but the CCR for ester E was only 21. ATP-dependent Ca2+ accumulation by cardiac JSRV provided a second means to evaluate deactivator actions of the ryanoids. Results from cardiac JSRV assays were in general similar to those from skeletal JSRV assays.(ABSTRACT TRUNCATED AT 400 WORDS)

Amino- and guanidinoacylryanodines: basic ryanodine esters with enhanced affinity for the sarcoplasmic reticulum Ca(2+)-release channel

Amino- and guanidinoacyl esters of ryanodine were prepared to evaluate the effect of basicity on the binding affinity of these derivatives for the sarcoplasmic reticulum Ca(2+)-release channel (SR CRC). In the presence of DCC and DMAP Cbz-beta-alanine reacts with ryanodine in CH2Cl2 to give O10eq-Cbz-beta-alanylryanodine (3a), which on hydrogenolysis yields the beta-alanyl ester (4a). N,N'-bis-Cbz-S-methylthiourea reacts with 4a to yield beta-N,N'-bis-Cbz-guanidinopropionylryanodine (5a). O10eq-beta-guanidinopropionylryanodine (6a) is obtained on hydrogenolytic deprotection of 5a. The binding affinity of beta-alanine ester (4a) and its glycyl congener (4b) is 2-3-fold greater, and that of the beta-guanidinopropionyl ester (6a) and its acetyl congener (6b) 3-6-fold greater, than that of ryanodine. The effect of ryanodine on SR Ca2+ flux is of a biphasic nature: nanomolar levels open (activate) the channel, while micromolar levels close (deactivate) it. The base-substituted esters 4a and 6a both display a unidirectional effect: they only open the channel. An understanding of ryanodine's mode of action and the design of effective SR CRC activating and deactivating ryanoids for possible therapeutic application are major research objectives.

Bioactive ryanoids from nucleophilic additions to 4,12-seco-4,12-dioxoryanodine

Ryanoids are the most potent inhibitors known for the calcium-release channel (ryanodine receptor), and they are also botanical insecticides. Twenty-two new ryanoids are described in which the C-4, C-12 bond is ruptured or replaced with an oxygen bridge and in which substituents at C-4 and C-12 are modified to have a wide range of polarities. They are obtained by nucleophilic additions to the 4,12-seco-4,12-dioxo compounds or diketones prepared from ryanodine and dehydroryanodine by periodate oxidation. Structures of the new compounds are distinguished by changes in NMR chemical shifts of 13C and 1H nuclei in the regions of C-4 and C-12. The new ryanoids are compared with ryanodine as inhibitors of [3H]ryanodine binding using a rabbit muscle sarcoplasmic reticulum preparation alone or with ATP and a mouse brain receptor with ATP. They are also examined as knockdown agents for houseflies pretreated with a cytochrome P450 oxidase inhibitor to suppress detoxification and then injection with the ryanoid. The diketones have very weak binding activity in the receptor assays and very low toxicity to flies. Activity approaching that of ryanodine in both the receptor and fly assays is obtained for ketals with small groups at C-12 and polar substituents such as OH or NHOH at C-4. The oximes range from low to moderate potency. Addition of thiols to the vinyl group of dehydroryanodine gives three thioethers all of low biological activity. With most ryanoids addition of ATP to the muscle system increases its sensitivity to near that found for the brain receptor with ATP; possible exceptions are compounds with phenyl substituents. Activity at the calcium-release channel generally follows housefly toxicity although the hydrazine and hydroxyamine adducts are much weaker than expected perhaps due to dissociation under the assay conditions.

Synthesis and biochemical properties of an 125I-labelled ryanodine derivative

The synthesis of a novel radioiodinated ryanodine-O10eq-N-acylamino acylate along with biological data are reported. The affinity of the iodinated product, 7, was comparable to ryanodine, 7.97 nM and 6.47 nM, respectively. Conversion of the non-radioactive iodinated ryanodine analog to the [125I] isotope was accomplished by conversion of 7 to the trimethyltin derivative followed by [125I] exchange using chloramine-T in organic solvent. The radioiodinated ryanodine analog, 9, bound to cardiac membrane preparations in a protein dependent and saturable manner indicating that this analog may represent a useful new tool for the study of ryanodine receptors and that modifications about the C-10 hydroxy group of ryanodine may be carried out without loss in biological activity.

Effects of ryanodine and 9,21-didehydroryanodine on caffeine-induced contraction of rat and guinea pig aortae

We compared the effects of ryanodine and 9,21-didehydroryanodine (DH-ryanodine), which are present in commercial preparations of 'ryanodine', on the contractions of rat and guinea pig aortae induced by 20 mM caffeine and tested the dependence of the action of each substance on external Ca2+. With the first protocol, the aortae were incubated with ryanodine or DH-ryanodine for 20 min in Ca2(+)-containing medium, and caffeine was added at 2 min incubation in Ca2(+)-free medium. With the second protocol, each substance was added when the external medium was changed to Ca2(+)-free medium, and 20 min later, caffeine was applied. Ryanodine and DH-ryanodine inhibited the caffeine-induced contractions in a similar way; i.e., with maximal effects at 3 microM and lesser effects at 10 microM. The potencies of inhibition by both substances were similar except that the effect of ryanodine at 1.5 microM was more potent than that of DH-ryanodine with the second protocol. The response by muscles previously loaded with Ca2+ to a second application of caffeine was more greatly inhibited by both compounds (use-dependent effect). The inhibition of the contraction due to the first or second application of caffeine was greater when either agent was applied in Ca2+-containing medium than in Ca2(+)-free medium. These results indicate that ryanodine and DH-ryanodine are similar in their effects on caffeine-induced Ca2+ release in vascular smooth muscle and that cellular Ca2+ levels may affect the action of ryanodine.

Structural aspects of ryanodine action and selectivity

The topography and toxicological relevance of the Ca2+-ryanodine receptor complex are evaluated with ryanodine and two natural analogues (9,21-didehydro and the new 18-hydroxy), 13 ryanoid derivatives (prepared from ryanodine and didehydroryanodine by functionalizing the available pyrrole, olefin, and hydroxyl substituents), and four degradation products. The potency of ryanoids at the skeletal muscle sarcoplasmic reticulum specific binding site generally parallels their toxicity to mice, supporting the toxicological relevance of the Ca2+-ryanodine receptor. The optimal receptor potency of ryanodine and didehydroryanodine is reduced 3-14-fold by hydroxylation at an isopropyl methyl substituent, epimerization at C9, oxidation or acetylation of the C10-hydroxyl, or epoxidation at the 9,21-position; other ryanoids are less active. Ryanodol and didehydroryanodol, in contrast to ryanodine and didehydroryanodine, have low toxicity to mice and little activity at the mammalian receptor, yet they are potent knockdown agents for injected houseflies or cockroaches, suggesting a possible difference in the target sites of mammals and insects.