Physiology, Ryanodine Receptor


Article Author:
Jesse Raszewski


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Sandeep Sharma


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Updated:
2/17/2019 8:19:05 AM

Introduction

A ryanodine receptor is a homotetrameric channel with a molecular mass of more than 2.2 megadaltons.[1] It is the largest known ion channel and gets its name from one of its exogenous ligands, ryanodine, an alkaloid plant toxin from Ryania speciosa.[2] Ryanodine receptor ion channels are embedded in the internal side of the sarcoplasmic reticulum that stores calcium, which is fundamental to striated muscle.[3] They are high conductance, monovalent or divalent conducting channels regulated by multiple factors that include calcium, magnesium, adenosine triphosphate, calmodulin, protein kinases and phosphatases, and redox active species.[4] Ryanodine receptors are essential for excitation-contraction coupling, linking action potentials and contraction of the striated muscle, by releasing calcium ions that are required to activate the contractile proteins.[3] These proteins are studied to develop therapeutic advances in diseases associated with striated muscle.

Issues of Concern

One issue of concern when studying these proteins is the size. Ryanodine receptors are the largest known ion channels that are capable of creating a rapid and transient increase in the cytosolic calcium levels within the cell.[5] The analysis of the primary structure of these proteins demonstrate many functional motifs that are present in other proteins, but the role in ryanodine receptors has not been fully elucidated due to the size of the gene.[5] The massive size of the gene, the multitude of modulators, and the dynamic nature of the channel make the structural analysis very difficult.[5] The many advances in electron microscopy are beginning to decode many vital features of the receptor.[5]

Cellular

A ryanodine receptor is comprised of four polypeptides each consisting of around 5000 amino acids, and four FK506-binding proteins each consisting of approximately 110 amino acids.[4] Moreover, the type 1 ryanodine receptor is the major isoform expressed in skeletal muscle, and the type 2 ryanodine receptor is the major isoform expressed in cardiac muscle.[3] 

In skeletal muscle, calcium release units arrange themselves in triads, which are composed of three different elements: two terminal expansions of the sarcoplasmic reticulum on either side that form a junction with the third component the t-tubule.[3] Within each one of these junctions, the ryanodine receptors form a double row of channels that form "couplons" with the dihydropyridine receptors in the t-tubule membrane.[3] The t-tubules enter the muscle fibers via caveolae, and these align with the A and I  band and overlap on either side of the Z-line within the sarcomere, which forms a double band in each sarcomere, that repeat at spaced intervals along the length of a muscle fiber.[3]

In cardiac muscle, calcium release units arrange themselves in dyads, which contain only two elements, a single terminal sarcoplasmic reticulum expansion forming a junction with the surface of the t-tubule membrane.[3] The cardiac sarcoplasmic reticulum expansions are relatively narrow, and these dyads align with the Z-line forming a single band in each sarcomere of the cardiac muscle.[3]

Development

The functional ryanodine receptor ion channel is formed by four monomers each having more than 5000 residues that constitute the largest ion channel protein so far identified.[3] In humans, the gene that encodes the type 1 ryanodine receptor channel protein that commonly presents in skeletal muscle has its location on chromosome 19q13.2 and spans across 104 exons.[5] The gene that encodes the type 2 ryanodine receptor that is in cardiac muscle is located on the chromosome 1q43 and spans 102 exons.[5] The type 3 ryanodine receptor gene is located in chromosome 15q13.3-14 and spans 103 exons.[5] 

Organ Systems Involved

There are three different isoforms of ryanodine receptors found in mammals.[2] They each share around 65% of the gene sequence identity and have subtle functional differences.[2]

The type 1 ryanodine receptor is primarily found in skeletal muscles and is located in the junctional region of the terminal sarcoplasmic reticulum.[5] The type 1 channels may also express at very low levels in cardiac muscle, smooth muscle, stomach, kidney, thymus, cerebellum, Purkinje cells, adrenal glands, ovaries, and the testes.[5] New studies have shown that type 1 receptors may even express in B-lymphocytes.[5] The predominant form of the ryanodine receptor in cardiac muscle is the type 2 receptor.[5] The type 2 ryanodine receptor also expresses at high levels in the Purkinje cells of the cerebellum and cerebral cortex, and in low levels in the stomach, kidneys, adrenal glands, ovaries, thymus, and the lungs.[5] The type 3 ryanodine receptors get expressed in the hippocampal neurons, thalamus, Purkinje cells, corpus striatum, and in the skeletal muscles predominantly located in the diaphragm, the smooth muscle cells of the coronary vasculature, lungs, kidneys, ileum, jejunum, spleen, stomach, aorta, uterus, ureters, urinary bladder, and esophagus.[5] 

Function

The ryanodine receptor serves as a conduit for calcium to flow through to produce a contraction in striated muscle.

In skeletal muscle, the depolarization from the action potential leads to a protein to protein interaction across the junctional cleft between the dihydropyridine receptor and the ryanodine receptor type 1 to release calcium from the sarcoplasmic reticulum to produce a muscle contraction.[6]

In cardiac muscle during systole, calcium is released from the sarcoplasmic reticulum by direct activation of the type 2 ryanodine receptors by an inward current of calcium via the L-type calcium channels during excitation produced from the action potential.[7] This calcium-induced calcium release occurs at specialized microdomains where the T- tubule of the sarcolemma closely approaches the junction of the sarcoplasmic reticulum forming the dyad structure.[7] The spatiotemporal summation of this calcium-induced calcium release generates contraction within the cardiac muscle.[7]

Mechanism

Historically it has been shown that there are three properties essential for a muscle contraction: sensitivity level to ryanodine, how rapidity of calcium release from the sarcoplasmic reticulum, and the ryanodine receptor.[2] The ryanodine receptors are calcium-gated cationic ion channels that are weakly selective for calcium over other cations.[2] The mechanism via which the channel activates is excitation-coupling and is tissue specific. Excitation-contraction coupling encompasses the many complex processes linking surface membrane action potentials to shortening of the muscle fiber, which has evolved over the years to only incorporate the mechanism linking the depolarization-dependent response of the dihydropyridine receptor voltage sensor with the release of the calcium from the sarcoplasmic reticulum by the ryanodine receptors.[3] 

The skeletal muscle excitation-contraction coupling is thought to depend on the conformational change denoted through the protein to protein interactions that link dihydropyridine subunits to the type 1 ryanodine receptors.[3] The voltage sensor response to the depolarization is measured as a "charge movement" across the surface and the t-tubule membrane.[3]

In cardiac excitation-contraction coupling, calcium ions enter the dyadic junction through the dihydropyridine receptor and activate the type 2 ryanodine receptors via calcium-induced calcium release.[3] The dihydropyridine calcium influx is sufficient to activate several type 2 ryanodine receptors, and there is only one dihydropyridine receptor for every 4 to 10 type 2 receptor tetramer.[3] This cardiac mechanism is dependent upon the extracellular level of calcium.[3]

Related Testing

One area of testing that has proven beneficial has been the use of fluorescence resonance energy transfer.[8] This method allows the user to discover compounds that actually modulate an intracellular calcium concentration of the ryanodine receptor.[8] The N-terminus inter-subunit of the ryanodine receptor self-associates, and has recently emerged as a critical structure-function parameter in the regulation of the channel.[9] Empirical evidence from a combination of testing has indicated that type 2 ryanodine receptor N-terminus, which is also conserved in type 1 and type 3 ryanodine receptors, is intricately involved in the closure of the canal.[9] These methods of testing have helped develop therapeutic applications in medicine.[8]

Pathophysiology

Mutations in ryanodine receptors primarily correlate with a range of myopathies and cardiac arrhythmia disorders. The Human Gene Mutation Database contains 563 mutations in the type 1 ryanodine receptors and 287 mutations in the type 2 ryanodine receptors that are known to cause inherited disease.[2]

For example in malignant hyperthermia, findings indicate that disruption of the N-terminus and central domain interaction within the ryanodine receptor is disrupted leading to increased activity of the channel.[9] In catecholaminergic polymorphic ventricular tachycardia, findings indicate that a single amino acid substitution in the ryanodine receptor gene leads to the N-terminus and central domain unzipping that underlies the channel dysfunction and diastolic sarcoplasmic reticulum calcium leak.[9]

Clinical Significance

More than 100 type-1 ryanodine receptor channel mutations potentially present in skeletal muscle, including malignant hyperthermia, central core disease, and multi/minicore disease.[4] As for type 2 ryanodine receptors, there are more than 150 mutations that lead to inherited pathology, including catecholaminergic polymorphic ventricular tachycardia, arrhythmogenic right ventricular dysplasia type 2, and idiopathic ventricular fibrillation.[4]

Malignant hyperthermia is a hypermetabolic syndrome that appears in susceptible patients after exposure to specific pharmacologic agents, that induces abnormal regulation of the ryanodine receptors, producing a massive release of calcium from the sarcoplasmic reticulum in striated muscle.[10]. The symptoms include high fever, tachycardia and muscle rigidity. Laboratory workup will show high CK and high potassium levels. It most commonly results from the use of volatile anesthetic agents (sevoflurane, halothane, isoflurane, and enflurane) and very rarely by succinylcholine. Inheritance to the susceptibility is often autosomal dominant. Very infrequently the disease may occur as a new mutation. Dantrolene sodium is the specific therapy used to counteract malignant hyperthermia because it inhibits the release of calcium from the sarcoplasmic reticulum by antagonizing the type 1 ryanodine receptors.[10]

Catecholaminergic polymorphic ventricular tachycardia is characterized by a polymorphic ventricular tachycardia in the setting of high adrenergic tone, as in exercise.[11] The mainstay of therapy is to avoid strenuous activity, and the first-line pharmacological therapy is beta-blockers to control the heart rate.[11]


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Physiology, Ryanodine Receptor - Questions

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The ryanodine receptor is associated with which of the following?



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A patient comes into the clinic due to muscle fasciculations. After diagnostic testing, it is determined that the patient has very low levels of the ion needed to begin the contraction of the muscles. What is the ion that is stored within the sarcoplasmic reticulum that is released by the ryanodine receptor when potentiated by an action potential?



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A scientist is testing cardiac muscle using electric potential in a laboratory. One of the hearts would not release calcium when stimulated due to a receptor. Which type of ryanodine receptor is most often associated with striated cardiac muscle?



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A patient comes into the emergency department due to a stab from a sharp knife in the arm. When asked if he could contract the bicep, the patient could not. What portion of the sarcomere was most likely disrupted due to the injury, where the ryanodine receptor release calcium to induce skeletal muscle contraction?



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Physiology, Ryanodine Receptor - References

References

Efremov RG,Leitner A,Aebersold R,Raunser S, Architecture and conformational switch mechanism of the ryanodine receptor. Nature. 2015 Jan 1;     [PubMed]
Willegems K,Efremov RG, Structural Details of the Ryanodine Receptor Calcium Release Channel and Its Gating Mechanism. Advances in experimental medicine and biology. 2017;     [PubMed]
Dulhunty AF,Board PG,Beard NA,Casarotto MG, Physiology and Pharmacology of Ryanodine Receptor Calcium Release Channels. Advances in pharmacology (San Diego, Calif.). 2017;     [PubMed]
Meissner G, The structural basis of ryanodine receptor ion channel function. The Journal of general physiology. 2017 Dec 4;     [PubMed]
Lanner JT,Georgiou DK,Joshi AD,Hamilton SL, Ryanodine receptors: structure, expression, molecular details, and function in calcium release. Cold Spring Harbor perspectives in biology. 2010 Nov;     [PubMed]
Santulli G,Lewis DR,Marks AR, Physiology and pathophysiology of excitation-contraction coupling: the functional role of ryanodine receptor. Journal of muscle research and cell motility. 2017 Feb;     [PubMed]
Nikolaienko R,Bovo E,Zima AV, Redox Dependent Modifications of Ryanodine Receptor: Basic Mechanisms and Implications in Heart Diseases. Frontiers in physiology. 2018;     [PubMed]
Rebbeck RT,Essawy MM,Nitu FR,Grant BD,Gillispie GD,Thomas DD,Bers DM,Cornea RL, High-Throughput Screens to Discover Small-Molecule Modulators of Ryanodine Receptor Calcium Release Channels. SLAS discovery : advancing life sciences R     [PubMed]
Seidel M,Lai FA,Zissimopoulos S, Structural and functional interactions within ryanodine receptor. Biochemical Society transactions. 2015 Jun;     [PubMed]
Kollmann-Camaiora A,Alsina E,Domínguez A,Del Blanco B,Yepes MJ,Guerrero JL,García A, Clinical protocol for the management of malignant hyperthermia. Revista espanola de anestesiologia y reanimacion. 2017 Jan;     [PubMed]
Lieve KV,van der Werf C,Wilde AA, Catecholaminergic Polymorphic Ventricular Tachycardia. Circulation journal : official journal of the Japanese Circulation Society. 2016 May 25;     [PubMed]

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