Regulation of a Ca2+-sensitive adenylyl cyclase in an excitable cell. Role of voltage-gated versus capacitative Ca2+ entry

In nonexcitable cells, we had previously established that Ca(2+)-sensitive adenylyl cyclases, whether expressed endogenously or heterologously, were regulated exclusively by capacitative Ca(2+) entry (Fagan, K. A., Mahey, R. and Cooper, D. M. F. (1996) J. Biol. Chem. 271, 12438-12444; Fagan, K. A., Mons, N., and Cooper, D. M. F. (1998) J. Biol. Chem. 273, 9297-9305). Relatively little is known about how these enzymes are regulated by Ca(2+) in excitable cells, where they predominate. Furthermore, no effort has been made to determine whether the prominent voltage-gated Ca(2+) entry, which typifies excitable cells, overwhelms the effect of any capacitative Ca(2+) entry that may occur. In the present study, we placed the Ca(2+)-stimulable, adenylyl cyclase type VIII in an adenovirus vector to optimize its expression in the pituitary-derived GH(4)C(1) cell line. In these cells, a modest degree of capacitative Ca(2+) entry could be discerned in the face of a dramatic voltage-gated Ca(2+) entry. Nevertheless, both modes of Ca(2+) entry were equally efficacious at stimulating adenylyl cyclase. A striking release of Ca(2+) from intracellular stores, triggered either by ionophore or thyrotrophin-releasing hormone, was incapable of stimulating the adenylyl cyclase. It thus appears as though the intimate colocalization of adenylyl cyclase with capacitative Ca(2+) entry channels is an intrinsic property of these molecules, regardless of whether they are expressed in excitable or nonexcitable cells.     

Adenovirus-mediated expression of an olfactory cyclic nucleotide-gated channel regulates the endogenous Ca2+-inhibitable adenylyl cyclase in C6-2B glioma cells

Previous studies have established that Ca2+-sensitive adenylyl cyclases, whether endogenously or heterologously expressed, are preferentially regulated by capacitative Ca2+ entry, compared with other means of elevating cytosolic Ca2+ (Chiono, M., Mahey, R., Tate, G., and Cooper, D. M. F. (1995) J. Biol. Chem. 270, 1149-1155; Fagan, K. A., Mahey, R., and Cooper, D. M. F. (1996) J. Biol. Chem. 271, 12438-12444; Fagan, K. A., Mons, N., and Cooper, D. M. F. (1998) J. Biol. Chem. 273, 9297-9305). These findings led to the suggestion that adenylyl cyclases and capacitative Ca2+ entry channels were localized in the same functional domain of the plasma membrane. In the present study, we have asked whether a heterologously expressed Ca2+-permeable channel could regulate the Ca2+-inhibitable adenylyl cyclase of C6-2B glioma cells. The cDNA coding for the rat olfactory cyclic nucleotide-gated channel was inserted into an adenovirus construct to achieve high levels of expression. Electrophysiological measurements confirmed the preservation of the properties of the expressed olfactory channel. Stimulation of the channel with cGMP analogs yielded a robust elevation in cytosolic Ca2+, which was associated with an inhibition of cAMP accumulation, comparable with that elicited by capacitative Ca2+ entry. These findings not only extend the means whereby Ca2+-sensitive adenylyl cyclases may be regulated, they also suggest that in tissues where they co-exist, cyclic nucleotide-gated channels and Ca2+-sensitive adenylyl cyclases may reciprocally modulate each other's activity.     

Discriminating between capacitative and arachidonate-activated Ca(2+) entry pathways in HEK293 cells.

We have recently questioned whether the capacitative or store-operated model for receptor-activated Ca(2+) entry can account for the influx of Ca(2+) seen at low agonist concentrations, such a those typically producing [Ca(2+)](i) oscillations. Instead, we have identified an arachidonic acid-regulated, noncapacitative Ca(2+) entry mechanism that appears to be specifically responsible for the receptor-activated entry of Ca(2+) under these conditions. However, it is unclear whether these two systems reflect the activity of distinct entry pathways or simply different mechanisms of regulating a common pathway. We therefore used the known selectivity of the Ca(2+)-stimulated type VIII adenylyl cyclase for Ca(2+) entry occurring via the capacitative pathway (Fagan, K. A., Mahey, R., and Cooper, D. M. F. (1996) J. Biol. Chem. 271, 12438-12444) to attempt to discriminate between these two entry mechanisms in HEK293 cells. Consistent with the earlier reports, we found that thapsigargin induced an approximate 3-fold increase in adenylyl cyclase activity that was unrelated to global changes in [Ca(2+)](i) or to the release of Ca(2+) from internal stores but was specifically dependent on the induced capacitative entry of Ca(2+). In marked contrast, the arachidonate-induced entry of Ca(2+) completely failed to affect adenylyl cyclase activity despite producing a substantially greater rate of entry than that induced by thapsigargin. These data demonstrate that the arachidonate-activated entry of Ca(2+) occurs via an entirely distinct influx pathway.     

The cytosolic domains of Ca2+-sensitive adenylyl cyclases dictate their targeting to plasma membrane lipid rafts

Lipid rafts are specialized, cholesterol-rich domains of the plasma membrane that are enriched in certain signaling proteins, including Ca(2+)-sensitive adenylyl cyclases. This restrictive localization plays a key role in the regulation of the Ca(2+)-stimulable AC8 and the Ca(2+)-inhibitable AC6 by capacitative calcium entry. Interestingly, AC7, a Ca(2+)-insensitive AC, is found in the plasma membrane but is excluded from lipid rafts (Smith, K. E., Gu, C., Fagan, K. A., Hu, B., and Cooper, D. M. F. (2002) J. Biol. Chem. 277, 6025-6031). The mechanisms governing the specific membrane targeting of adenylyl cyclase isoforms remain unknown. To address this issue, a series of chimeras were produced between the raft-targeted AC5 and the non-raft-targeted AC7, involving switching of their major domains. The AC5-AC7 chimeras were expressed in HEK 293 cells and lipid rafts were isolated from the bulk plasma membrane by either detergent-based or non-detergent-based fractionation methods. Additionally, confocal imaging was used to investigate the precise cellular targeting of the chimeras. Surprisingly, the two tandem six-transmembrane domains of AC5 were not required for localization to lipid rafts. Rather, AC5 localization depended on the complete cytoplasmic loops (C1 and C2); constructs with mixed domains were either retained in the endoplasmic reticulum or degraded. Similar conclusions are drawn for the lipid raft localization of the Ca(2+)/calmodulin-stimulable AC8; again, the C1 and C2 domains are critical. Thus, protein-protein interactions may be more important than protein-lipid interactions in targeting these calcium-sensitive enzymes to lipid rafts.     

Residence of adenylyl cyclase type 8 in caveolae is necessary but not sufficient for regulation by capacitative Ca(2+) entry.

Ca(2+)-sensitive adenylyl cyclases (ACs) depend on capacitative Ca(2+) entry (CCE) for their regulation. Residence of the endogenous Ca(2+)-inhibitable adenylyl cyclase of C6-2B glioma cells in cholesterol-enriched caveolae is essential for its regulation by CCE (Fagan, K. A., Smith, K. E., and Cooper, D. M. F. (2000) J. Biol. Chem. 275, 26530-26537). In the present study, we established that depletion of cellular cholesterol ablated the regulation by CCE of a Ca(2+)-stimulable adenylyl cyclase, AC8, heterologously expressed in HEK293 cells. We considered the possibility that a calmodulin-binding domain in the N terminus of AC8, which is not required for in vitro regulation by Ca(2+), might play a targeting role. Deletion and mutation of the N terminus did attenuate the enzyme's sensitivity to CCE without altering its in vitro responsiveness to Ca(2+)/calmodulin. Both N terminus-deleted AC8 and wild type AC8 were expressed at the plasma membrane, as shown by imaging analysis of green fluorescence protein-tagged constructs. However, not only wild type AC8 but also the CCE-insensitive mutants occurred in caveolar fractions of the plasma membranes, even though a Ca(2+)-insensitive adenylyl cyclase, AC7, was excluded from caveolae. Finally, the AC8 mutants were no more responsive to nonphysiological elevation of Ca(2+) than the wild type. We conclude that (i) not all adenylyl cyclases reside in caveolae, (ii) the calmodulin-binding domain in the N terminus of AC8 does not play a role in caveolar targeting, (iii) the N terminus does play a role in associating AC8 with factors that confer sensitivity to CCE, and (iv) residence of Ca(2+)-sensitive adenylyl cyclases in caveolae is essential but not sufficient for regulation by CCE.     

The role of calmodulin recruitment in Ca2+ stimulation of adenylyl cyclase type 8

Ca2+ stimulation of adenylyl cyclase type 8 (AC8) is mediated by calmodulin (CaM). An earlier study identified two CaM binding sites in AC8; one that was apparently not essential for AC8 activity, located at the N terminus, and a second site that was critical for Ca2+ stimulation, found at the C terminus (Gu, C., and Cooper, D. M. F. (1999) J. Biol. Chem. 274, 8012-8021). This study explores the role of these two CaM binding domains and their interaction in regulating AC8 activity, employing binding and functional studies with mutant CaM and modified AC8 species. We report that the N-terminal CaM binding domain of AC8 has a role in recruiting CaM and that this recruitment is essential to permit stimulation by Ca2+ in vivo. Using Ca2+-insensitive mutants of CaM, we found that partially liganded CaM can bind to AC8, but only fully liganded Ca2+/CaM can stimulate AC8 activity. Moreover, partially liganded CaM inhibited AC8 activity in vivo. The results indicate that CaM pre-associates with the N terminus of AC8, and we suggest that this recruited CaM is used by the C terminus of AC8 to mediate Ca2+ stimulation.     

Ca(2+), Sr(2+), and Ba(2+) identify distinct regulatory sites on adenylyl cyclase (AC) types VI and VIII and consolidate the apposition of capacitative cation entry channels and Ca(2+)-sensitive ACs

Ca(2+)-sensitive adenylyl cyclases may act as early integrators of the two major second messenger-signaling pathways mediated by Ca(2+) and cAMP. Ca(2+) stimulation of adenylyl cyclase type I (ACI) and adenylyl cyclase type VIII (ACVIII) is mediated by calmodulin and the site on these adenylyl cyclases that interacts with calmodulin has been defined. By contrast, the mechanism whereby Ca(2+) inhibits adenylyl cyclase type V (ACV) and adenylyl cyclase type VI (ACVI) is unknown. In this study, Ca(2+), Sr(2+), and Ba(2+) were compared to probe the involvement of E-F hand-like domains in both Ca(2+) stimulation and inhibition of ACVIII and ACVI, respectively. HEK 293 cells transfected with ACVIII cDNA and C6-2B glioma cells (where the endogenous adenylyl cyclases is predominantly ACVI) were used to compare the effects of these three cations in in vitro and in vivo measurements. The in vitro data identified two Ca(2+) regulatory sites for both ACVIII and ACVI. Strikingly different potency series for these cations at mediating high affinity stimulation and inhibition of ACVIII and ACVI, respectively, effectively rule out the possibility that calmodulin or proteins utilizing similar Ca(2+)-binding motifs mediate inhibition of ACVI. On the other hand, the low affinity inhibition that is common to both ACVIII and ACVI showed virtually identical potency profiles for the IIa cation series, indicating a common site of action. Remarkably, whereas Sr(2+) was rather ineffective at regulating these cyclases (particularly ACVI) in vitro, adequate concentrations accumulated in the vicinity of these enzymes as a consequence of capacitative cation entry to partially regulate both of these activities in vivo. This latter finding consolidates earlier observations that Ca(2+)-sensitive adenylyl cyclases detect and respond to capacitative cation entry rather than global cytosolic cation concentrations.     

Coordinate regulation of membrane cAMP by Ca2+-inhibited adenylyl cyclase and phosphodiesterase activities

Activation of store-operated Ca(2+) entry inhibits type 6 adenylyl cyclase (EC; AC(6); Yoshimura M and Cooper DM. Proc Natl Acad Sci USA 89: 6712-6720, 1992) activity in pulmonary artery endothelial cells. However, in lung microvascular endothelial cells (PMVEC), which express AC(6) and turn over cAMP at a rapid rate, inhibition of global (whole cell) cAMP is not resolved after direct activation of store-operated Ca(2+) entry using thapsigargin. Present studies sought to determine whether the high constitutive phosphodiesterase activity in PMVECs rapidly hydrolyzes cAMP so that Ca(2+) inhibition of AC(6) is difficult to resolve. Direct stimulation of adenylyl cyclase using forskolin and inhibition of type 4 phosphodiesterases using rolipram increased cAMP and revealed Ca(2+) inhibition of AC(6). Enzyme activity was assessed using PMVEC membranes, where Ca(2+) and cAMP concentrations were independently controlled. Endogenous AC(6) activity exhibited high- and low-affinity Ca(2+) inhibition, similar to that observed in C6-2B cells, which predominantly express AC(6). Ca(2+) inhibition of AC(6) in PMVEC membranes was observed after enzyme activation and inhibition of phosphodiesterase activity and was independent of the free cAMP concentration. Thus, under basal conditions, the constitutive type 4 phosphodiesterase activity rapidly hydrolyzes cAMP so that Ca(2+) inhibition of AC(6) is difficult to resolve, indicating that high phosphodiesterase activity works coordinately with AC(6) to regulate membrane-delimited cAMP concentrations, which is important for control of cell-cell apposition.     

Ca(2+) entry activated by S-nitrosylation. Relationship to store-operated ca(2+) entry

The coupling between Ca(2+) pools and store-operated Ca(2+) entry channels (SOCs) remains an unresolved question. Recently, we revealed that Ca(2+) entry could be activated in response to S-nitrosylation and that this process was stimulated by Ca(2+) pool emptying (Favre, C. J., Ufret-Vincenty, C. A., Stone, M. R., Ma, H-T. , and Gill, D. L. (1998) J. Biol. Chem. 273, 30855-30858). In DDT(1)MF-2 smooth muscle cells and DC-3F fibroblasts, Ca(2+) entry activated by the lipophilic NO donor, GEA3162 (5-amino-3-(3, 4-dichlorophenyl)1,2,3,4-oxatriazolium), or the alkylator, N-ethylmaleimide, was observed to be strongly activated by transient external Ca(2+) removal, closely resembling activation of SOC activity in the same cells. The nonadditivity of SOC and NO donor-activated Ca(2+) entry suggested a single entry mechanism. Calyculin A-induced reorganization of the actin cytoskeleton prevented SOC but had no effect on GEA3162-induced Ca(2+) entry. However, a single entry mechanism could account for both SOC and NO donor-activated entry if the latter reflected direct modification of the entry channel by S-nitrosylation, bypassing the normal coupling process between channels and pools. Small differences between SOC and GEA3162-activated Ba(2+) entry and sensitivity to blockade by La(3+) were observed, and in HEK293 cells SOC activity was observed without a response to thiol modification. It is concluded that in some cells, S-nitrosylation modifies an entry mechanism closely related to SOC and/or part of the regulatory machinery for SOC-mediated Ca(2+) entry.     

Two Ca2+-dependent ATPases in rat liver plasma membrane. The previously purified (Ca2+-Mg2+)-ATPase is not a Ca2+-pump but an ecto-ATPase

We have shown that the rat liver plasma membrane has at least two (Ca2+-Mg2+)-ATPases. One of them has the properties of a plasma membrane Ca2+-pump (Lin, S.-H. (1985) J. Biol. Chem. 260, 7850-7856); the other one, which we have purified (Lin, S.-H., and Fain, J.N. (1984) J. Biol. Chem. 259, 3016-3020) and characterized (Lin, S.-H. (1985) J. Biol. Chem. 260, 10976-10980) has no established function. In this study we present evidence that the purified (Ca2+-Mg2+)-ATPase is a plasma membrane ecto-ATPase. In hepatocytes in primary culture, we can detect Ca2+-ATPase and Mg2+-ATPase activities by addition of ATP to the intact cells. The external localization of the active site of the ATPase was confirmed by the observation that the Ca2+-ATPase and Mg2+-ATPase activities were the same for intact cells, saponin-treated cells, and cell homogenates. Less than 14% of total intracellular lactate dehydrogenase, a cytosolic enzyme, was released during a 30-min incubation of the hepatocytes with 2 mM ATP. This indicates that the hepatocytes maintained cytoplasmic membrane integrity during the 30-min incubation with ATP, and the Ca2+-ATPase and Mg2+-ATPase activity measured in the intact cell preparation was due to cell surface ATPase activity. The possibility that the ecto-Ca2+-ATPase and Mg2+-ATPase may be the same protein as the previously purified (Ca2+-Mg2+)-ATPase was tested by comparing the properties of the ecto-ATPase with those of (Ca2+-Mg2+)-ATPase. Both the ecto-ATPase and the (Ca2+-Mg2+)-ATPase have broad nucleotide-hydrolyzing activity, i.e. they both hydrolyze ATP, GTP, UTP, CTP, ADP, and GDP to a similar extent. The effect of Ca2+ and Mg2+ on the ecto-ATPase activity is not additive indicating that both Ca2+- and Mg2+-ATPase activities are part of the same enzyme. The ecto-ATPase activity, like the (Ca2+-Mg2+)-ATPase, is not sensitive to oligomycin, vanadate, N-ethylmaleimide and p-chloromercuribenzoate; and both the ecto-ATPase and purified (Ca2+-Mg2+)-ATPase activities are insensitive to protease treatments. These properties indicate that the previously purified (Ca2+-Mg2+)-ATPase is an ecto-ATPase and may function in regulating the effect of ATP and ADP on hepatocyte Ca2+ mobilization (Charest, R., Blackmore, P.F., and Exton, J.H. (1985) J. Biol. Chem. 260, 15789-15794).     

CIB1, a ubiquitously expressed Ca2+-binding protein ligand of the InsP3 receptor Ca2+ release channel

A family of Ca(2+)-binding proteins (CaBPs) was shown to bind to the inositol 1,4,5-trisphosphate receptor (InsP(3)R) Ca(2+) release channel and gate it in the absence of InsP(3), establishing them as protein ligands (Yang, J., McBride, S., Mak, D.-O. D., Vardi, N., Palczewski, K., Haeseleer, F., and Foskett, J. K. (2002) Proc. Natl. Acad. Sci. U. S. A. 99, 7711-7716). However, the neuronally restricted expression of CaBP and its inhibition of InsP(3)R-mediated Ca(2+) signaling when overexpressed (Kasri, N. N., Holmes, A. M., Bultynck, G., Parys, J. B., Bootman, M. D., Rietdorf, K., Missiaen, L., McDonald, F., De Smedt, H., Conway, S. J., Holmes, A. B., Berridge, M. J., and Roderick, H. L. (2004) EMBO J. 23, 312-321; Haynes, L. P., Tepikin, A. V., and Burgoyne, R. D. (2004) J. Biol. Chem. 279, 547-555) have raised questions regarding the functional implications of this regulation. We have discovered the Ca(2+)-binding protein CIB1 (calmyrin) as a ubiquitously expressed ligand of the InsP(3)R. CIB1 binds to all mammalian InsP(3)R isoforms in a Ca(2+)-sensitive manner dependent on its two functional EF-hands and activates InsP(3)R channel gating in the absence of InsP(3). In contrast, overexpression of CIB1 or CaBP1 attenuated InsP(3)R-dependent Ca(2+) signaling, and in vitro pre-exposure to CIB1 reduced the number of channels available for subsequent stimulation by InsP(3). These results establish CIB1 as a ubiquitously expressed activating and inhibiting protein ligand of the InsP(3)R.     

Coupling between intracellular Ca2+ stores and the Ca2+ permeability of the plasma membrane. Comparison of the effects of thapsigargin, 2,5-di-(tert-butyl)-1,4-hydroquinone, and cyclopiazonic acid in rat thymic lymphocytes.

The regulation of Ca2+ uptake by receptors is incompletely understood. It has been proposed that the Ca2+ permeability of the plasma membrane increases in response to depletion of a critical intracellular Ca2+ storage compartment (Takemura, H., Hughes, A. R., Thastrup, O., and Putney, J. W. (1989) J. Biol. Chem. 264, 12266-12271). This hypothesis is based largely on the effect of thapsigargin, an inhibitor of endomembrane CA(2+)-ATPases. Due to the existence of an endogenous leak, inhibition of Ca2+ uptake by thapsigargin induces depletion of the stores. This is accompanied by increased plasmalemmal Ca2+ permeability, without change in the level of inositol phosphates. On the other hand, depletion of the intracellular stores by 2,5-di(tert-butyl)-1,4-hydroquinone (BHQ), a chemically unrelated inhibitor of the Ca(2+)-ATPases, fails to induce Ca2+ influx (Kass, G. E., Duddy, S. K., Moore, G. A., and Orrenius, S. (1989) J. Biol. Chem. 264, 15192-15198). In an attempt to reconcile these observations, we analyzed in lymphocytes the mode of action of thapsigargin and BHQ. In addition, we tested the effects of cyclopiazonic acid (CPA), a blocker of the skeletal muscle sarcoplasmic reticulum Ca(2+)-ATPase. All three compounds released Ca2+ from a common intracellular compartment. Thapsigargin and low concentrations of BHQ and CPA concomitantly elevated the plasmalemmal Ca2+ permeability. Higher concentrations of BHQ and CPA produced a secondary inhibition of the Ca2+ entry pathway, by a mechanism seemingly unrelated to their effects on the internal stores. This inhibitory side effect can account for the reported discrepancies between the effects of thapsigargin and BHQ. The data provide further support for the notion that endomembrane Ca2+ stores are functionally coupled to the plasma membrane Ca2+ permeability pathway.     

Ca2+ entry mediated by store depletion, S-nitrosylation, and TRP3 channels. Comparison of coupling and function

The mechanism for coupling between Ca(2+) stores and store-operated channels (SOCs) is an important but unresolved question. SOC-mediated Ca(2+) entry is complex and may reflect more than one type of channel and coupling mechanism. To assess such possible divergence the function and coupling of SOCs was compared with two other distinct yet related Ca(2+) entry mechanisms. SOC coupling in DDT(1)MF-2 smooth muscle cells was prevented by the permeant inositol 1,4,5-trisphosphate (InsP(3)) receptor blockers, 2-aminoethoxydiphenyl borate (2-APB) and xestospongin C. In contrast, Ca(2+) entry induced by S-nitrosylation and potentiated by store depletion (Ma, H-T., Favre, C. J., Patterson, R. L., Stone, M. R., and Gill, D. L. (1999) J. Biol. Chem. 274, 35318-35324) was unaffected by 2-APB, suggesting that this entry mechanism is independent of InsP(3) receptors. The cycloalkyl lactamimide, MDL-12, 330A (MDL), prevented SOC activation (IC(50) 10 micrometer) and similarly completely blocked S-nitrosylation-mediated Ca(2+) entry. Ca(2+) entry mediated by the TRP3 channel stably expressed in HEK293 cells was activated by phospholipase C-coupled receptors but independent of Ca(2+) store depletion (Ma, H.-T., Patterson, R. L., van Rossum, D. B., Birnbaumer, L., Mikoshiba, K., and Gill, D. L. (2000) Science 287, 1647-1651). Receptor-induced TRP3 activation was 2-APB-sensitive and fully blocked by MDL. Direct stimulation of TRP3 channels by the permeant diacylglycerol derivative, 1-oleoyl-2-acetyl-sn-glycerol, was not blocked by 2-APB, but was again prevented by MDL. The results indicate that although the activation and coupling processes for each of the three entry mechanisms are distinct, sensitivity to MDL is a feature shared by all three mechanisms, suggesting there may be a common structural feature in the channels themselves or an associated regulatory component.     

On the Ca2+ dependence of non-transferrin-bound iron uptake in PC12 cells

Non-transferrin-bound iron (NTBI) uptake has been reported to follow two pathways, Ca(2+)-dependent and Ca(2+)-independent (Wright, T. L., Brissot, P., Ma, W. L., and Weisiger, R. A. (1986) J. Biol. Chem. 261, 10909-10914; Sturrock, A., Alexander, J., Lamb, J., Craven, C. M., and Kaplan, J. (1990) J. Biol. Chem. 265, 3139-3145). Studies reporting the two pathways have ignored the weak interactions of Ca(2+) with the chelator nitrilotriacetate (NTA) and the reducing agent ascorbate. These studies used a constant ratio of total Fe(2+) to NTA with and without Ca(2+). We observed Ca(2+) activation of NTBI uptake in PC12 cells with the characteristics reported for other cells upon using 1 mm ascorbate and a constant ratio of total Fe(2+) to NTA with or without Ca(2+). However, Ca(2+) did not affect NTBI uptake in solutions without NTA. We then determined conditional stability constants for NTA binding to Ca(2+) and Fe(2+) by potentiometry under conditions of NTBI uptake experiments (pH, ionic strength, temperature, ascorbate, total Fe(2+), and total Ca(2+) concentrations). In solutions based on these constants and taking Ca(2+) chelation into account, Ca(2+) did not affect NTBI uptake over a range of free Fe(2+) concentrations. Thus, the Ca(2+) activation of NTBI uptake observed using the constant total Fe(2+) to NTA ratio was because of Ca(2+)-NTA chelation rather than an activation of the NTBI transporter itself. It is suggested that the previously reported Ca(2+) dependence of NTBI uptake be re-evaluated.     

Phosphorylated Ca2+-ATPase stable enough for structural studies

The atomic structure of sarcoplasmic reticulum Ca(2+)-ATPase, in a Ca(2+)-bound conformation, has recently been elucidated (Toyoshima, C., Nakasako, M., Nomura, H. & Ogawa, H. (2000) Nature 405, 647-655). Important steps for further understanding the mechanism of ion pumps will be the atomic structural characterization of different key conformational intermediates of the transport cycle, including phosphorylated intermediates. Following our previous report (Champeil, P., Henao, F., Lacapère, J.-J. & McIntosh, D. B. (2000) J. Biol. Chem. 276, 5795-5803), we show here that it is possible to prepare a phosphorylated form of sarcoplasmic reticulum Ca(2+)-ATPase (labeled with fluorescein isothiocyanate) with a week-long stability both in membranes and in mixed lipid-detergent micelles. We show that this phosphorylated fluorescein isothiocyanate-ATPase can form two-dimensional arrays in membranes, similar to those that were used previously to reconstruct from cryoelectron microscopy images the three-dimensional structure of Ca(2+)-free unphosphorylated ATPase. The results also provide hope that crystals of phosphorylated Ca(2+)-ATPase suitable for x-ray crystallography will be achieved.     

A Ca(2+)-independent activation of a type IV cytosolic phospholipase A(2) underlies the receptor stimulation of arachidonic acid-dependent noncapacitative calcium entry

The oscillatory [Ca(2+)](i) signals typically seen following physiologically relevant stimulation of phospholipase C-linked receptors are associated with a receptor-activated entry of Ca(2+), which plays a critical role in driving the oscillations and influencing their frequency. We have recently shown that this receptor-activated entry of Ca(2+) does not conform to the widely accepted "capacitative" model and, instead, reflects the activity of a distinct, novel Ca(2+) entry pathway regulated by arachidonic acid (Shuttleworth, T. J., and Thompson, J. L. (1998) J. Biol. Chem. 273, 32636-32643). We now show that the generation of arachidonic acid under these conditions results from the activity of a type IV cytosolic phospholipase A(2) (cPLA(2)). Although cPLA(2) activation commonly involves a Ca(2+)-dependent translocation to the membrane, at these low agonist concentrations cPLA(2) activation was independent of increases in [Ca(2+)](i), and no detectable translocation to the membrane occurs. Nevertheless, stimulation of cPLA(2) activity was confined to the membrane fraction, where an increase in phosphorylation of the enzyme was observed. We suggest that, at the low agonist concentrations associated with oscillatory [Ca(2+)](i) signals, cPLA(2) activation involves an increased phosphorylation of a discrete pool of the total cellular cPLA(2) that is already localized within the membrane fraction at resting [Ca(2+)](i).     

Relation between phosphatidylserine exposure and store-operated Ca(2+) entry in stimulated cells

A significant increase in intracellular Ca(2+) is required to trigger the remodeling of the cell plasma membrane. Scott syndrome is an extremely rare inherited disorder of the transmembrane migration of phosphatidylserine toward the exoplasmic leaflet in blood cells. We have recently reported a reduced capacitative Ca(2+) entry in Scott cells [Martínez et al. (1999) Biochemistry 38, 10092-10098]. We have investigated here the links between defective phosphatidylserine exposure and Ca(2+) signaling in Scott cells by focusing on the Ca(2+) entry following the emptying of intracellular stores. After depletion of caffeine- or thapsigargin-sensitive stores, Ca(2+) entry was lower in Scott compared to control lymphoblasts. However, the simultaneous depletion of both types of stores restored a normal Ca(2+) influx across the plasma membrane in Scott cells and phosphatidylserine externalization ability was improved concomitantly with capacitative Ca(2+) entry. These observations point to the essential role of capacitative Ca(2+) entry in the control of phosphatidylserine exposure of stimulated cells.     

Stable activation of single Ca2+ release-activated Ca2+ channels in divalent cation-free solutions

The regulation of store-operated, calcium-selective channels in the plasma membrane of rat basophilic leukemia cells (RBL-2H3 m1), an immortalized mucosal mast cell line, was studied at the single-channel level with the patch clamp technique by removing divalent cations from both sides of the membrane. The activity of the single channels in excised patches could be modulated by Ca(2+), Mg(2+), and pH. The maximal activation of these channels by divalent cation-free conditions occurred independently of depletion of intracellular Ca(2+) stores, whether in excised patches or in whole cell mode. Yet, a number of points of evidence establish these single-channel openings as amplified store-operated channel events. Specifically, (i) the single channels are exquisitely sensitive to inhibition by intracellular Ca(2+), and (ii) both the store-operated current and the single-channel openings are completely blocked by the capacitative calcium entry blocker, 2-aminoethoxydiphenyl borane. In addition, in Jurkat T cells single-channel openings with lower open probability have been observed in the whole cell mode with intracellular Mg(2+) present (Kerschbaum, H. H., and Cahalan, M. D. (1999) Science 283, 836-839), and in RBL-2H3 m1 cells a current with similar properties is activated by store depletion.     

Developmental changes in capacitative Ca(2+) entry in mouse mammary epithelial cells

Developmental changes in capacitative Ca(2+) entry and Ca(2+) release from intracellular stores were measured using fura-2 fluorescence method during the pregnancy period (day 3-;18) in mouse mammary epithelial cells. Ca(2+) release was identified with the transient intracellular Ca(2+) ([Ca(2+)](i)) increase induced by thapsigargin addition in a Ca(2+)-free solution. Capacitative Ca(2+) entry was measured by the transient [Ca(2+)](i) increase induced by re-addition of extracellular Ca(2+) after depletion of Ca(2+) stores by thapsigargin. The capacitative Ca(2+) entry was greatest at the early stage of pregnancy (i.e. day 3 of pregnancy) and decreased as pregnancy progressed, while Ca(2+) release remained unchanged throughout the developmental stages. These findings indicate that in contrast to Ca(2+) release, a close correlation exists between capacitative Ca(2+) entry and pregnancy-induced development in mammary epithelial cells.