InsP3/Ryanodine Receptors

The low calcium concentration that characterizes the cytosol of all eukaryotic cells is maintained by active calcium transport into the extracellular space and into the intracellular stores, largely the endoplasmic and sarcoplasmic reticulum. The resulting steep electrochemical gradients for calcium allow opening of calcium channels in these membranes to generate rapid increases in cytosolic calcium concentration in response to appropriate extracellular stimuli.

Two related families of calcium channels, inositol 1,4,5-trisphosphate (InsP3) and ryanodine receptors, are largely responsible for mediating calcium release from intracellular stores. Additional, less extensively characterized channels are likely to mediate the calcium mobilization evoked by such intracellular signals as β-NAADP (nicotinic acid adenine dinucleotide phosphate) and sphingosine-1-phosphate. Most of these intracellular calcium channels are regulated by several intracellular messengers and there are also important interactions between the different calcium channels. These features undoubtedly contribute to the complexity of the calcium signals observed in intact cells. Because calcium diffuses only slowly in cytoplasm, the free calcium concentration near open calcium channels can far exceed that of the rest of the cytoplasm. Such spatially restricted increases in calcium concentration allow local communication between calcium channels and intracellular targets; mitochondria, for example. These "€œcalcium synapses"€œ increase enormously the versatility of calcium as an intracellular messenger.

Ryanodine and InsP3 receptors share both structural and functional characteristics. Both receptor families are made up of subunits that are among the largest of known proteins and for each the functional channel comprises a tetramer in which six membrane-spanning helices, near the carboxy terminus of each subunit, form a calcium channel. The pore itself is formed by the final pair of transmembrane domains and the intervening loop from each of the four subunits. Whereas InsP3 receptors exist as both homotetramers and heterotetramers, only homotetrameric ryanodine receptors have so far been reported. The enormous cytosolic domains of these receptors provide sites through which diverse intracellular signals modulate their behavior. Such signals include proteins that bind directly to the receptors (e.g., calmodulin, FKBP12, CaBP, Homer, bcl-2), protein kinases that phosphorylate them, and many small second messengers. The N-terminal region of InsP3 receptors may also contact the calcium channels in the plasma membrane that mediate capacitative calcium entry. Such "conformational coupling"€ also occurs in skeletal muscle where L-type calcium channels are coupled to activation of type 1 ryanodine receptors. Perhaps the most important of the small messengers that regulate intracellular calcium channels is calcium itself, which regulates both families of receptors, and thereby allows each to mediate propagation of intracellular calcium signals by means of calcium-induced calcium release.

The ability of calcium channels in the plasma membrane selectively to allow the passage of calcium into the cell requires that they very effectively discriminate between calcium and monovalent cations. The need for such discrimination is less acute for the intracellular calcium channels, because calcium pumps concentrate calcium within the intracellular stores, and monovalent cation channels within the membrane of the endoplasmic reticulum ensure that there is no steep gradient for monovalent cations. In effect, responsibility for the selective passage of calcium through intracellular calcium channels has been delegated to the calcium pumps of the stores. It is not surprising therefore that both InsP3 and ryanodine receptors are far less calcium-selective than are plasma membrane calcium channels.

While intracellular and plasma membrane calcium channels provide access to different sources of calcium, there are important interactions between them. Calcium entering the cell across the plasma membrane can directly trigger release of calcium from intracellular stores by activating ryanodine receptors; the best example is provided by cardiac myocytes. Conversely, depletion of intracellular calcium stores in most non-excitable cells generates an unknown signal that leads to activation of "€œcapacitative"€ calcium entry across the plasma membrane. The important point is that there are dynamic interactions between intracellular and extracellular sources of calcium and the calcium channels that provide regulated access to them.

Finally, although many drugs are known to interact with InsP3 or ryanodine receptors, many, particularly those that interact with InsP3 receptors, are poorly selective and useful only under carefully controlled conditions. Xestospongin and 2-APB, for example, have each been reported to inhibit InsP3 receptors, but each appears also to have many additional effects on other calcium-signalling proteins. Likewise, many blockers of potassium channels also block InsP3 and ryanodine receptors, but such drugs have proven useful only in very carefully controlled situations.

 

The Table below contains accepted modulators and additional information. For a list of additional products, see the "Similar Products" section below.

 

Receptor Type

InsP3 receptors Ryanodine receptors
Structures Tetramer (4 x ~313 kDa) Not Known
Subtypese InsP3R1-3a,f RyR1f
Alternate Names None Skeletal (α)
Structural Information InsP3R1: 2695 aa (human)
InsP3R2: 2701 aa (human)
InsP3R3: 2671 aa (human)
5038 aa (human)
Distribution Most cells express several isoforms Skeletal muscle and elsewhere
Calcium Conductance ~50 pS
Mean open time ~4 ms
100-150 pS
Mean open time ~20 ms
Permeation Ba2+ > Sr2+ > Ca2+ > Mg2+ > Mn2+
PBa/PK=6.3
Ba2+ > Sr2+ > Ca2+ > Mg2+
PBa/Pk = 4-8
Pharmacology Agonists (Ins(1,4,5)P3 nM) (I7012, I9766) and related compounds
(e.g., Ins(2,4,5) P3, Ins(4,5)P2 (I3264), Ins(1,4,5)PS3)
Adenophostins
Ryanodine (nM-µM)
Caffeine (mM) (C0750)
Heparin (µg/ml) (H3393 (p))
4-Chloro-m-cresol (µM) (C55402)
Pharmacology Antagonists Heparin (µg/ml) (H3393 (p))
Decavanadate (µM)
Caffeine (mM) (C0750)
Xestospongin (X2628) (<µM)h
2-Aminoethoxydiphenyl borate (>µM)h
Ruthenium red (µM) (R2751)
Ryanodine (>10 µM)
Imperatoxin (nM) (I148)
Dantrolene (µM) (D9175)
Physiology Stimulation Cytosolic Ca2+ (<µM)
ATP (µM) (A2383)
Cytosolic Ca2+ (µM)
ATP (mM) (A2383)
Calmodulin (P1431)c
Cyclic ADP-ribose (C7344)b
Physiology Inhibition Cytosolic Ca2+ (>µM)
Calmodulin (InsP3R1) (P1431)g
Cytosolic Ca2+ (mM)
Calmodulin (µM) (P1431)c
Radioligands of Choice [3H]-Inositol 1,4,5-trisphosphate [3H]-Ryanodine
[125I]-Calmodulin
Physiological Function Ca2+ release mediated by many receptors that
stimulate InsP3 formation
Excitation-contraction coupling in skeletal muscle
Disease Relevance
Huntington'€™s disease Malignant hyperthermia

 

 

Receptor Type

Ryanodine receptors Ryanodine receptors
Structures Tetramer (4 x ~560 kDa) Not Known
Subtypese RyR2f RyR3
Alternate Names Cardiac (β)
Structural Information 4967 aa (human) 4870 aa (human)
Distribution Heart, brain, smooth muscle and elsewhere
Brain, smooth muscle and elsewhere
Calcium Conductance 100-150 pS
Mean open time ~20 ms
100-150 pS
Mean open time ~20 ms
Permeation Ba2+ > Sr2+ > Ca2+ > Mg2+
PBa/Pk = 4-8
Ba2+ > Sr2+ > Ca2+ > Mg2+
PBa/Pk = 4-8
Pharmacology Agonists Ryanodine (nM-µM)
Caffeine (mM) (C0750)
4-Chloro-m-cresol (µM) (C55402)
Ryanodine (nM-µM)
Caffeine (mM) (C0750)
Pharmacology Antagonists Ruthenium red (µM) (R2751)
Ryanodine (>10 µM)
8-Amino cyclic ADP ribosed
Ruthenium red (µM) (R2751)
Ryanodine (>10 µM)
Physiology Stimulation Cytosolic Ca2+ (µM)
ATP (mM) (A2383)
Calmodulin (P1431)c
Cyclic ADP-ribose (C7344)b
Cytosolic Ca2+ (µM)
ATP (mM) (A2383)
Calmodulin (P1431)c
Cyclic ADP-ribose (C7344)b
Physiology Inhibition Cytosolic Ca2+ (mM)
Calmodulin (µM) (P1431)c
Cytosolic Ca2+ (mM)
Calmodulin (µM) (P1431)c
Radioligands of Choice [3H]-Ryanodine
[3H]-Cyclic ADP-ribose
[125I]-Calmodulin
[3H]-Ryanodine
[125I]-Calmodulin
Physiological Function Excitation-contraction coupling in cardiac muscle
Ca2+-induced Ca2+ release
Ca2+-induced Ca2+ release
Disease Relevance Heart failure Not Known

 

Footnotes

Additional messengers capable of mobilizing intracellular calcium stores, which include sphingosine-1-phosphate and β-NAADP, are omitted from the chart because the calcium channels they regulate have not yet been identified.

a) Roman and Arabic numerals are presently used interchangeably to distinguish between InsP3 receptor subtypes, the latter are preferable. Although partial sequences for putative types 4 and 5 InsP3 receptors were reported, they are now thought to represent species differences between the type 2 InsP3 receptor subtype.

b) The site to which cyclic ADP-ribose binds has yet to be identified.

c) Calmodulin, both with and without bound calcium, can cause either inhibition or stimulation of ryanodine receptor function.

d) 8-Amino cyclic ADP ribose is a competitive antagonist of the cyclic ADP-ribose-binding site. 8-Bromo-cyclic-ADP ribose is an antagonist with lower affinity, but it is more membrane permeant.

e) While InsP3 receptors are known to exist as both heterotetramers and homotetramers, only homotetrameric assemblies of ryanodine receptor subunits have so far been demonstrated.

f) InsP3R1, InsP3R2, RyR1 and RyR2 are also expressed as alternative splice variants.

g) Calmodulin-mediated inhibition of InsP3 binding to InsP3R1 is calcium-independent.

h) The specificity of these antagonists, neither of which acts at the InsP3-binding site, has been challenged by work suggesting that among many additional effects they also inhibit the endoplasmic reticulum calcium pump. In addition, 2-APB directly blocks capacitative calcium entry without affecting other calcium entry pathways.

 

Abbreviations

Ins(1,4,5)P3: Inositol 1,4,5-trisphosphate
Ins(4,5)P2: Inositol 4,5-bisphosphate
Ins(2,4,5)P3: Inositol 2,4,5-trisphosphate
2-APB: 2-Aminoethoxydiphenyl borate
Ins(1,4,5)PS3: Inositol 1,4,5-trisphosphorothioate

b: bovine
p: porcine

 

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References