Structural determinants of ion permeation in CRAC channels

McNally, Beth A.; Yamashita, Megumi; Engh, Anita M.; Prakriya, Murali

doi:10.1073/pnas.0909574106

Cited by 132 publications

(184 citation statements)

References 33 publications

(43 reference statements)

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“…Also, the inner pore structures of human Orai1 and dOrai could differ, although this seems unlikely given the high degree of sequence conservation between the two species (94% identity in the M1/pore region, corresponding to residues 76-107 of human Orai1). Further, cysteine scanning of side chain accessibility in the middle to upper pore region (R91-E106 of human Orai1; McNally et al, 2009;Zhou et al, 2010) gave results consistent with the dOrai crystal structure. The dOrai structure presumably reflects a closed channel state (Hou et al, 2012), and in theory the open or inactivated states of human Orai1 could have a more open inner pore than that seen in the dOrai structure, possibly allowing CaM binding.…”

Section: Discussionsupporting

confidence: 60%

Orai1 pore residues control CRAC channel inactivation independently of calmodulin

Mullins¹,

Yen²,

Lewis³

2016

J Cell Biol

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Section: Discussionsupporting

confidence: 60%

Orai1 pore residues control CRAC channel inactivation independently of calmodulin

Mullins¹,

Yen²,

Lewis³

2016

J Cell Biol

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“…Their point of departure is the reversible block of CRAC current through R91C channels upon oxidative crosslinking of neighboring R91C residues. This recalls the partial block of the open R91C channel by Cd 2+ [6], and both findings suggest that pinning TM1 helices together at their cytoplasmic ends occludes the pore. That the channel can be occluded or pinned closed in these artificial cases does not imply that the gating movement of the wild-type channel involves widening the inner mouth of the pore.…”

mentioning

confidence: 96%

“…Na + and other monovalent ions can permeate the channel when no divalent ions are present, but the channel is selective for Ca 2+ in physiological solutions, because binding of Ca 2+ at a site in the pore prevents Na + permeation. E106 in transmembrane helix 1 (TM1) of the human ORAI1 channel was implicated in Ca 2+ binding by electrophysiology [4,5], and the physical proximity of E106 sidechains from separate ORAI1 subunits was confirmed by disulfide crosslinking of E106C monomers [6,7]. An unusual feature of the ORAI1 channel is that its constituent TM1 helices are in proximity and line the pore along its entire length (Figure 1).…”

mentioning

confidence: 99%

“…An unusual feature of the ORAI1 channel is that its constituent TM1 helices are in proximity and line the pore along its entire length (Figure 1). This was apparent from the block of currents by Cd 2+ traversing the channel and from the disulfide crosslinking of ORAI1 monomers, when cysteine residues were introduced at positions 88, 91, 95, 98, or 102 in TM1 [6,7]. Cd 2+ block at V102C is of particularly high affinity, indicating that the V102C sidechains are close together in the permeation pathway [6].…”

mentioning

confidence: 99%

“…This was apparent from the block of currents by Cd 2+ traversing the channel and from the disulfide crosslinking of ORAI1 monomers, when cysteine residues were introduced at positions 88, 91, 95, 98, or 102 in TM1 [6,7]. Cd 2+ block at V102C is of particularly high affinity, indicating that the V102C sidechains are close together in the permeation pathway [6]. The protein crosslinking experiments further point to limited flexibility of the helical backbone from F99-M104 in comparison to other parts of TM1, placing V102 in a narrow and relatively rigid part of the pore that could serve as an energy barrier to ion passage [7].…”

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confidence: 99%

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Insights into CRAC channel gating and ion permeation

Hogan

2012

Cell Res

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The ORAI1 store-operated calcium channel, also known as the CRAC channel, has provided many surprises. The latest is that channel gating and ion selectivity are closely intertwined.The calcium release-activated calcium (CRAC) channel, originally defined in T lymphocytes and mast cells, is an oligomer composed of ORAI1 subunits. Its hallmarks are exquisite selectivity for Ca 2+ in physiological solutions, a narrow pore as defined by permeation of small organic cations, and a very small single-channel current. The channel is recruited to ER-plasma membrane junctions and activated by STIM proteins in response to ER Ca 2+ store depletion. The emerging picture of the STIM-ORAI pathway is reviewed in [1,2]. There has been relatively slow progress, however, in delineating the physical basis of channel gating and ion permeation. A new paper by McNally et al. [3] reports three important advances: It locates an external gate in the ORAI1 channel, implicates the gate region in ion selectivity, and in an aspect not discussed here, shows that STIM-ORAI stoichiometry can influence the ion selectivity of the channel.Previous work has established that the ORAI channel is not intrinsically restricted to conducting Ca 2+ . Na + and other monovalent ions can permeate the channel when no divalent ions are present, but the channel is selective for Ca 2+ in physiological solutions, because binding of Ca 2+ at a site in the pore prevents Na + permeation. E106 in transmembrane helix 1 (TM1) of the human ORAI1 channel was implicated in Ca 2+ binding by electrophysiology [4,5], and the physical proximity of E106 sidechains from separate ORAI1 subunits was confirmed by disulfide crosslinking of E106C monomers [6,7]. An unusual feature of the ORAI1 channel is that its constituent TM1 helices are in proximity and line the pore along its entire length (Figure 1). This was apparent from the block of currents by Cd 2+ traversing the channel and from the disulfide crosslinking of ORAI1 monomers, when cysteine residues were introduced at positions 88, 91, 95, 98, or 102 in TM1 [6,7]. Cd 2+ block at V102C is of particularly high affinity, indicating that the V102C sidechains are close together in the permeation pathway [6]. The protein crosslinking experiments further point to limited flexibility of the helical backbone from F99-M104 in comparison to other parts of TM1, placing V102 in a narrow and relatively rigid part of the pore that could serve as an energy barrier to ion passage [7].The new paper by McNally et al.[3] first probes entry of the organic cation 2-aminoethyl methanethiosulfonate (MTSEA + ) into the E106D channel. The pairing of channel and reagent is a calculated choice. The E106D channel has a larger pore diameter than the wild-type ORAI1 channel, but is gated normally by STIM1. The MTSEA + headgroup diameter, 3.8 Å, is comparable to the diameter of methylammonium, which carries current through E106D channels. Methanethiosulfonate reagents are typically used to modify cysteine residues introduced at specific sites in a channel...

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Enlightening Allostery: Designing Switchable Proteins by Photoreceptor Fusion

Mathony

Niopek

2020

Advanced Biology

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upon photoexcitation and often reversible at similar time-scales upon withdrawal of the light trigger. [1][2][3][4] Apart from this temporal precision, light can also be supplied in a spatially confined way with single-cell or subcellular accuracy, for example by using lasers or blinds. [5][6][7] Together, these favorable characteristics render optogenetics a highly powerful method for perturbing and studying dynamic processes in living cells and explain the rapid growth of this scientific field over the past 15 years.Generally, optogenetic tools can either be categorized by the nature of the photoreceptors they employ or by their undelaying working principle. [8] Focusing on the latter classification, one can differentiate between systems that are regulated via inducible association/dissociation reactions and often involve multiple component versus single-component tools functioning via inducible allostery. [8] Association-based tools make use of photoreceptors that bind to one another or to a secondary binding partner upon light exposure. [9] The red/far-red light-responsive PhyB/PIF or blue light-responsive CRY2/CIB1 heterodimerization systems are typical examples for association-dependent optogenetic tools. One application of such optogenetic heterodimerizers is the control of protein subcellular localization. [10] To this end, one binding partner is targeted to a specific subcellular structure or location (e.g., the plasma membrane, nucleus, mitochondria), while the second partner is corecruited to this structure upon dimerization. The same principle can also be employed to reconstitute split-proteins in a light-dependent manner. [9] Optogenetic tools that function via inducible allostery, in contrast, are usually single-component systems. They consist of an engineered chimera between a photoreceptor domain and an effector protein and their light-switching behavior is mediated by steric or allosteric interactions between the two. [8,11] A particular advantage of single-component optogenetic tools as compared to dimerization-based tools is their compactness. They are small in size, since only the photosensory domain is fused to the effector domain/protein of choice and no additional proteins need to be coexpressed. Moreover, allosteric tools do not rely on the diffusion-based association of two components, the kinetics of which depends on the protein concentrations.Optogenetic switches that rely on inducible allostery have mainly been engineered on the basis of light-oxygen-voltage (LOV) domains [11] and phytochromes. [12][13][14] LOV domains belong to the Per-ARNT-Sim or PAS (period circadian protein-aryl Optogenetics harnesses natural photoreceptors to non-invasively control selected processes in cells with previously unmet spatiotemporal precision. Linking the activity of a protein of choice to the conformational state of a photosensor domain through allosteric coupling represents a powerful method for engineering light-responsive proteins. It enables the design of compact and highly potent single-componen...

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Structural determinants of ion permeation in CRAC channels

Cited by 132 publications

References 33 publications

Orai1 pore residues control CRAC channel inactivation independently of calmodulin

Orai1 pore residues control CRAC channel inactivation independently of calmodulin

Insights into CRAC channel gating and ion permeation

Enlightening Allostery: Designing Switchable Proteins by Photoreceptor Fusion

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