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CRAC Channels (crac + channel)

Distribution by Scientific Domains
Life Sciences100%

Selected Abstracts

Local Ca2+ influx through CRAC channels activates temporally and spatially distinct cellular responses

ACTA PHYSIOLOGICA, Issue 1 2009
A. B. Parekh
Abstract Ca2+ entry through store-operated Ca2+ release-activated Ca2+ (CRAC) channels controls a disparate array of key cellular responses. In this review, recent work will be described that shows local Ca2+ influx through CRAC channels has important spatial and temporal consequences on cell function. A localized Ca2+ rise below the plasma membrane activates, within tens of seconds, catabolic enzymes resulting in the generation of the intracellular messenger arachidonic acid and the paracrine pro-inflammatory molecule LTC4. In addition, local Ca2+ entry can activate gene expression, which develops over tens of minutes. Local Ca2+ influx through CRAC channels therefore has far-reaching consequences on intra- and intercellular communication. [source]

The molecular architecture of the arachidonate-regulated Ca2+ -selective ARC channel is a pentameric assembly of Orai1 and Orai3 subunits

THE JOURNAL OF PHYSIOLOGY, Issue 17 2009
Olivier Mignen
The activation of Ca2+ entry is a critical component of agonist-induced cytosolic Ca2+ signals in non-excitable cells. Although a variety of different channels may be involved in such entry, the recent identification of the STIM and Orai proteins has focused attention on the channels in which these proteins play a key role. To date, two distinct highly Ca2+ -selective STIM1-regulated and Orai-based channels have been identified , the store-operated CRAC channels and the store-independent arachidonic acid activated ARC channels. In contrast to the CRAC channels, where the channel pore is composed of only Orai1 subunits, both Orai1 and Orai3 subunits are essential components of the ARC channel pore. Using an approach involving the co-expression of a dominant-negative Orai1 monomer along with different preassembled concatenated Orai1 constructs, we recently demonstrated that the functional CRAC channel pore is formed by a homotetrameric assembly of Orai1 subunits. Here, we use a similar approach to demonstrate that the functional ARC channel pore is a heteropentameric assembly of three Orai1 subunits and two Orai3 subunits. Expression of concatenated pentameric constructs with this stoichiometry results in the appearance of large currents that display all the key biophysical and pharmacological features of the endogenous ARC channels. They also replicate the essential regulatory characteristics of native ARC channels including specific activation by low concentrations of arachidonic acid, complete independence of store depletion, and an absolute requirement for the pool of STIM1 that constitutively resides in the plasma membrane. [source]

TRPC channels function independently of STIM1 and Orai1

THE JOURNAL OF PHYSIOLOGY, Issue 10 2009
Wayne I. DeHaven
Recent studies have defined roles for STIM1 and Orai1 as calcium sensor and calcium channel, respectively, for Ca2+ -release activated Ca2+ (CRAC) channels, channels underlying store-operated Ca2+ entry (SOCE). In addition, these proteins have been suggested to function in signalling and constructing other channels with biophysical properties distinct from the CRAC channels. Using the human kidney cell line, HEK293, we examined the hypothesis that STIM1 can interact with and regulate members of a family of non-selective cation channels (TRPC) which have been suggested to also function in SOCE pathways under certain conditions. Our data reveal no role for either STIM1 or Orai1 in signalling of TRPC channels. Specifically, Ca2+ entry seen after carbachol treatment in cells transiently expressing TRPC1, TRPC3, TRPC5 or TRPC6 was not enhanced by the co-expression of STIM1. Further, knockdown of STIM1 in cells expressing TRPC5 did not reduce TRPC5 activity, in contrast to one published report. We previously reported in stable TRPC7 cells a Ca2+ entry which was dependent on TRPC7 and appeared store-operated. However, we show here that this TRPC7-mediated entry was also not dependent on either STIM1 or Orai1, as determined by RNA interference (RNAi) and expression of a constitutively active mutant of STIM1. Further, we determined that this entry was not actually store-operated, but instead TRPC7 activity which appears to be regulated by SERCA. Importantly, endogenous TRPC activity was also not regulated by STIM1. In vascular smooth muscle cells, arginine-vasopressin (AVP) activated non-selective cation currents associated with TRPC6 activity were not affected by RNAi knockdown of STIM1, while SOCE was largely inhibited. Finally, disruption of lipid rafts significantly attenuated TRPC3 activity, while having no effect on STIM1 localization or the development of ICRAC. Also, STIM1 punctae were found to localize in regions distinct from lipid rafts. This suggests that TRPC signalling and STIM1/Orai1 signalling occur in distinct plasma membrane domains. Thus, TRPC channels appear to be activated by mechanisms dependent on phospholipase C which do not involve the Ca2+ sensor, STIM1. [source]

Ca2+ microdomains near plasma membrane Ca2+ channels: impact on cell function

THE JOURNAL OF PHYSIOLOGY, Issue 13 2008
Anant B. Parekh
In eukaryotic cells, a rise in cytoplasmic Ca2+ can activate a plethora of responses that operate on time scales ranging from milliseconds to days. Inherent to the use of a promiscuous signal like Ca2+ is the problem of specificity: how can Ca2+ activate some responses but not others? We now know that the spatial profile of the Ca2+ signal is important Ca2+ does not simply rise uniformly throughout the cytoplasm upon stimulation but can reach very high levels locally, creating spatial gradients. The most fundamental local Ca2+ signal is the Ca2+ microdomain that develops rapidly near open plasmalemmal Ca2+ channels like voltage-gated L-type (Cav1.2) and store-operated CRAC channels. Recent work has revealed that Ca2+ microdomains arising from these channels are remarkably versatile in triggering a range of responses that differ enormously in both temporal and spatial profile. Here, I delineate basic features of Ca2+ microdomains and then describe how these highly local signals are used by Ca2+ -permeable channels to drive cellular responses. [source]

Agonist activation of arachidonate-regulated Ca2+ -selective (ARC) channels in murine parotid and pancreatic acinar cells

THE JOURNAL OF PHYSIOLOGY, Issue 3 2005
Olivier Mignen
ARC channels (arachidonate-regulated Ca2+ -selective channels) are a novel type of highly Ca2+ -selective channel that are specifically activated by low concentrations of agonist-induced arachidonic acid. This activation occurs in the absence of any depletion of internal Ca2+ stores (i.e. they are ,non-capacitative'). Previous studies in HEK293 cells have shown that these channels provide the predominant pathway for the entry of Ca2+ seen at low agonist concentrations where oscillatory [Ca2+]i signals are typically produced. In contrast, activation of the more widely studied store-operated Ca2+ channels (e.g. CRAC channels) is only seen at higher agonist concentrations where sustained ,plateau-type'[Ca2+]i responses are observed. We have now demonstrated the presence of ARC channels in both parotid and pancreatic acinar cells and shown that, again, they are specifically activated by the low concentrations of appropriate agonists (carbachol in the parotid, and both carbachol and cholecystokinin in the pancreas) that are associated with oscillatory [Ca2+]i signals in these cells. Uncoupling the receptor-mediated activation of cytosolic phospholipase A2 (cPLA2) with isotetrandrine reduces the activation of the ARC channels by carbachol and, correspondingly, markedly inhibits the [Ca2+]i signals induced by low carbachol concentrations, whilst those signals seen at high agonist concentrations are essentially unaffected. Interestingly, in the pancreatic acinar cells, activation by cholecystokinin induces a current through the ARC channels that is only approximately 60% of that seen with carbachol. This is consistent with previous reports indicating that carbachol-induced [Ca2+]i signals in these cells are much more dependent on Ca2+ entry than are the cholecystokinin-induced responses. [source]