An examination of the secretion‐like coupling model for the activation of the Ca2+ release‐activated Ca2+ current ICRAC in RBL‐1 cells

Abstract

1 One popular model for the activation of store-operated Ca²⁺ influx is the secretion-like coupling mechanism, in which peripheral endoplasmic reticulum moves to the plasma membrane upon store depletion thereby enabling inositol 1,4,5-trisphosphate (InsP₃) receptors on the stores to bind to, and thus activate, store-operated Ca²⁺ channels. This movement is regulated by the underlying cytoskeleton. We have examined the validity of this mechanism for the activation of I_CRAC, the most widely distributed and best characterised store-operated Ca²⁺ current, in a model system, the RBL-1 rat basophilic cell line. 2 Stabilisation of the peripheral cytoskeleton, disassembly of actin microfilaments and disaggregation of microtubules all consistently failed to alter the rate or extent of activation of I_CRAC. Rhodamine-phalloidin labelling was used wherever possible, and revealed that the cytoskeleton had been significantly modified by drug treatment. 3 Interference with the cytoskeleton also failed to affect the intracellular calcium signal that occurred when external calcium was re-admitted to cells in which the calcium stores had been previously depleted by exposure to thapsigargin/ionomycin in calcium-free external solution. 4 Application of positive pressure through the patch pipette separated the plasma membrane from underlying structures (cell ballooning). However, I_CRAC was unaffected irrespective of whether cell ballooning occurred before or after depletion of stores. 5 Pre-treatment with the membrane-permeable InsP₃ receptor antagonist 2-APB blocked the activation of I_CRAC. However, intracellular dialysis with 2-APB failed to prevent I_CRAC from activating, even at higher concentrations than those used extracellularly to achieve full block. Local application of 2-APB, once I_CRAC had been activated, resulted in a rapid loss of the current at a rate similar to that seen with the rapid channel blocker La³⁺. 6 Studies with the more conventional InsP₃ receptor antagonist heparin revealed that occupation of the intracellular InsP₃-sensitive receptors was not necessary for the activation or maintenance of I_CRAC. Similarly, the InsP₃ receptor inhibitor caffeine failed to alter the rate or extent of activation of I_CRAC. Exposure to Li⁺, which reduces InsP₃ levels by interfering with inositol monophosphatase, also failed to alter I_CRAC. Caffeine and Li⁺ did not affect the size of the intracellular Ca²⁺ signal that arose when external Ca²⁺ was re-admitted to cells which had been pre-exposed to thapsigargin/ionomycin in Ca²⁺-free external solution. 7 Our findings demonstrate that the cytoskeleton does not seem to regulate calcium influx and that functional InsP₃ receptors are not required for activation of I_CRAC. If the secretion-like coupling model indeed accounts for the activation of I_CRAC in RBL-1 cells, then it needs to be revised significantly. Possible modifications to the model are discussed.