Abstract
Orai proteins are highly selective calcium channels playing an important role in calcium entry. Orai3 channels are overexpressed in breast cancer (BC) tissues, and involved in their proliferation, cell cycle progression and survival. Herein, we sought to address the involvement of Orai3 in resistance to chemotherapeutic drugs. Using high-throughput approaches, we investigated major changes induced by Orai3 overexpression, including downstream signaling mechanisms involved in BC chemotherapy resistance. Resistance was dependent on external calcium presence and thus Orai3 functionality. This effect allowed a downregulation of the p53 tumor suppressor protein expression via the pro-survival PI3K/Sgk-1/Sek-1 pathway. We demonstrated that p53 degradation occurred not only via Mdm2, but also via another unexpected E3 ubiquitin ligase, Nedd4-2. We found supporting bioinformatic evidence linking Orai3 overexpression and chemoresistance in large human BC data sets. Altogether, our results shed light on the molecular mechanisms activated in BC cells commonly found to overexpress Orai3, allowing resistance to chemotherapeutic drugs.
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Introduction
Cancer cells have the ability to become resistant to a variety of drugs, and resistance of cancer cells is therefore a major hindrance for effective therapeutic modalities. Despite significant advances in early detection, as well as comprehension of molecular mechanisms of breast cancer (BC), about 30% of patients with early-stage BC have recurrent disease [1]. In general, systemic agents such as chemotherapeutic drugs are effective in 90% of primary BC. However, progression generally occurs over time, and if such, resistance to therapy is not only common but quite expected [1]. Residual tumor cells are detected post-treatment in most cancer patients, and these cells are thought to remain in a quiescent state for years before resuming growth, resulting in tumor recurrence. Tumor cells from recurrent tumors exhibit increased resistance to chemotherapeutic drugs [2], and become more difficult to eradicate. Deciphering molecular mechanisms of this acquired cellular resistance not only would be a major step toward comprehension and finding on how to eradicate cancer cells, but could also serve for predicting tumor resistance, allowing more personalized treatments for the patient’s benefit.
Altered expression of ion channels is now recognized as one of the hallmarks of cancer [3], and several ion channels have already been proposed as novel emerging biomarkers and targets for cancer therapy [4]. Among them, calcium channels are of particular interest, calcium being a well-known ubiquitous second messenger regulating a wide variety of physiological functions [5, 6], including cell proliferation and cell death [7]. Store-operated calcium entry (SOCE) is one of the main calcium entry in non-excitable cells, and typically allows calcium influx through the plasma membrane subsequently to endoplasmic reticulum depletion. This ubiquitous SOCE pathway is not only necessary to refill internal calcium stores, but also to activate downstream signaling cascades [8]. Apoptosis is also potentially triggered when a large and sustained rise in cytosolic calcium occurs through SOCE (mediated by store-operated channels (SOCs)) [9,10,11]. Actors of this mechanism include depletion sensors (STIM reticular proteins), as well as plasma membrane channels. Among these, Orai channels represent highly selective calcium channels, with three distinct Orai isoforms described to date (Orai1, Orai2, and Orai3). While far less studied than Orai1, Orai3 protein deserves special attention, because of (i) its exclusive presence in mammals [12], (ii) its receptivity to pharmacological modulation [13], and (iii) its recent emergence in the cancer field, especially in BC. For instance, our group recently reported that Orai3 channels are overexpressed in BC biopsies, and are involved in proliferation, cell cycle progression, and survival of BC [14]. Moreover, these effects appear to be specific to cancer cells [14], and are transduced—at least in part—via the c-myc pathway [15].
Herein, we investigated the phenotypical effects of Orai3 overexpression in ER+ BC cell, in which SOCE is Orai3-dependent [16]. In concordance with bioinformatic data from public BC cohorts, we show that Orai3 is indeed able to confer resistance to cell death, and activates a calcium-dependent mechanism modulating the expression of the tumor suppressor protein p53.
Results
Clonal selection as a model to study Orai3 overexpression
To explore the potential relationship between Orai3 expression and resistance in BC cells, we analyzed three data sets of human BC data in the public domain, characterized for Orai3 messenger RNA (mRNA) expression and chemotherapy response. In all data sets, Orai3 mRNA expression was higher in tumors from patients with poor response and/or residual disease than those from patients with partial or complete therapy response (Fig. 1D and Supplementary Information). High Orai3 mRNA expression in the tumor sample was predictive of poor patient outcome (Fig. 1D and Supplementary Information). To validate these bioinformatic analyses, stable Orai3-overexpressing (O3V) T47D BC clones were selected. Messenger RNA was overexpressed >200× in O3V-A7 clone and around 150× in O3V-E5 clone vs. empty vector (EV) clones, respectively (Fig. S1A). Overexpression was also seen at the protein level (Fig. S1B). Calcium imaging experiments using 2-APB (which activates Orai3 but inhibits Orai1 and Orai2 [16, 17]) indicated that these overexpressed channels were functional (data not shown). Resting [Ca2+]i significantly increased in O3V cells when compared to EV cells (Fig. S1C). Orai3 overexpression was also able to increase basal SOCE (Fig. S1D). Orai3 transient transfection was also performed in the Cos-7 cell line: mRNA and proteins were largely overexpressed (Fig. S1A, B), and SOCE was also increased (Fig. S1D). Overexpression levels obtained in T47D cells were compared to expression levels obtained in some tumors (Fig. S1E and Supplementary Information). To extend these observations, we also show a higher Orai3 DNA copy number and mRNA overexpression in the three aggressive subtypes of the three largest BC data sets on the Oncomine website (Supplementary Information and Fig. S1F, G, and H). These data suggest a tumor-promoting role for Orai3 in aggressive BC.
Phenotypical changes induced by Orai3 overexpression
Orai3 overexpression decreases cell mortality
Proliferation rates are not affected by Orai3 overexpression, either in 5% FCS (Fig. 2A) or in serum-depleted media (0% FCS, data not shown). Cell mortality is however reduced in O3V cells (Fig. 2B), on average to half of the mortality seen in EV cells at 24, 48, or 72 h. In the 0% FCS condition, the effect of Orai3 overexpression is even stronger, with mortality being up to 3× lower than in EV clones (Fig. S2A).
Orai3 promotes cell resistance to classical apoptosis inducers
We next wondered whether O3V cells would also be less prone to mortality under stressful conditions, using apoptosis inducers such as thapsigargin (Tg) and staurosporine (STS). With 1 µM Tg, EV cells exhibited almost 40% mortality (24 h, Fig. 2C). O3V cells, on the other hand, showed <20% mortality in the same conditions. Upon STS application (6 h), cell mortality increased up to 14% in EV clones (Fig. 2D), whereas cell mortality was <8% in O3V clones.
Orai3 promotes cell resistance to chemotherapeutic drugs
We next used chemotherapeutic drugs, such as cisplatin (a DNA alkylating-like agent), 5-fluorouracil (5-FU, a pyrimidine analog that acts through thymineless death), and paclitaxel (a taxane that interferes with the normal breakdown of microtubules during cell division). O3V cells were found to be resistant to all agents (Fig. 2E, F and G for cisplatin, 5-FU and paclitaxel, respectively). Since results obtained with both EV clones and both O3V clones were highly similar, we chose to continue with only one clone of each category: from now on, and unless otherwise stated, EV-G11-T47D and O3V-A7-T47D clones will be referred to as EV and O3V, respectively.
Orai3 overexpression leads to decreased apoptosis in BC cells
Bax was demonstrated to heterodimerize with Bcl-2 and suppress its ability to block apoptosis [18]. The Bax/Bcl-2 ratio determines thus cellular survival or apoptotic cell death [19]. In O3V-T47D cells, the Bax/Bcl-2 ratio decreased vs. EV cells. This effect was enhanced by treatments, either with the classical apoptosis inducers Tg and STS (Fig. 3A, C), or with the chemotherapeutic drugs cisplatin, 5-FU, and paclitaxel (Fig. 3B, C).
PARP (poly(ADP-ribose) polymerase) cleavage results in inactivation of the enzyme [20], and is a common feature of apoptosis. Cleaved PARP was clearly decreased in O3V-T47D cells treated with Tg, STS, cisplatin, 5-FU, and paclitaxel (Fig. 3D, E). O3V cells were also resistant to etoposide and pemetrexed (Fig. S2B). We also extended these observations to a non-tumoral cell line (Cos-7), using transient transfection. O3V-Cos-7 cells were resistant to paclitaxel (Fig. S2C), as well as cisplatin and STS (Fig. S2D). Together, these results demonstrate that Orai3 overexpression was able to confer protection against several apoptosis inducers in BC and Cos-7 cells.
p53 is a key player in Orai3-conferred resistance
Orai3-conferred resistance is p53-dependent
Using a high-throughput Affymetrix screening method, we obtained an overview of the genes regulated by Orai3 overexpression (Supplementary Table 1). Several genes linked to death resistance were found to be regulated by the tumor suppressor gene TP53. Notably, FOXO1 (Forkhead box protein O1), AREG (coding for amphiregulin), and CALB2 (coding for calbindin-2) were found downregulated in O3V cells (1.55×, 6.07× and 7.32× vs. EV cells, respectively). These results were confirmed by qRT-PCR (Fig. 4A). It clearly appeared that p53 protein expression, as well as its transcriptional target p21, were downregulated in O3V cells (Fig. 4B). p53 and p21 protein expressions, although induced by different chemotherapeutic treatments, remained lower in O3V cells (Fig. 4C). p53 downregulation was also observed in O3V-MCF7 stable clones (Fig. S3A).
Orai3-conferred resistance appeared dependent on p53 transcriptional activity
p53 is mutated in T47D cells (L194F), but retain some transcriptional activity [21]. p53 downregulation was indeed paralleled by a downregulation of p21 mRNA expression (Fig. 4D) and p21 protein expression (Fig. 4C), as well as numerous other genes (FOXO1, CALB2, and AREG for instance, see above). Treatments with pifithrin-α (an inhibitor of p53 transcriptional activity) decreased p21 expression (Fig. 4D). In wild-type wtp53 MCF7-O3V cells, p21 was also downregulated (Fig. 4D). We next wondered whether Orai3 expression in BC samples of human patients was connected to p53 mutant or wild-type activity. In two data sets (from cBioPortal) annotated for p53 and Orai3 status, Orai3 DNA copy gain and mRNA overexpression occurred mainly in tumors with wtp53 (Fig. S4). This suggests that in human BC, Orai3 depends on p53 function for its tumor-promoting activity.
p53 is not regulated at the transcriptional level
p53 protein expression was decreased up to 80% in both O3V cell lines. However, no variation of p53 mRNA was found, neither by Affymetrix screening, nor by qRT-PCR (Fig. 4E). p53 expression was restored upon treatment with the proteasome inhibitor MG-132 in O3V cells (Fig. 4F). Among the p53 regulators are E3 ubiquitin ligases, which target p53 for degradation by the proteasome. Mdm2 for instance is able to regulate both wild-type and mutated p53 [22]. When O3V cells were treated with 20 µM nutlin-3 (an inhibitor of the p53-Mdm2 interaction), p53 expression returned to levels seen in EV cells (Fig. 4G). Interestingly, Orai3-conferred resistance was abolished (Fig. 4H), suggesting that Orai3-induced p53 downregulation is indeed associated with lower mortality and increased resistance. Orai3 expression had no impact on p53 subcellular location (Fig. S3B).
Which signaling pathway(s) is (are) involved in Orai3-conferred death resistance?
Orai3-conferred resistance is dependent on calcium entry
Orai3-conferred resistance was abrogated in a “calcium-free” medium (Fig. 5A), suggesting that the resistance depended on Orai3 function. Moreover, in the calcium-free medium, it clearly appeared that Orai3 overexpression was no longer able to downregulate p53 (Fig. 5B), suggesting that calcium entry through Orai3 channels was responsible for p53 downregulation. Same results were obtained with two O3V-MCF7 stable clones (Fig. S3A, lanes four to six). An immunofluorescent staining confirmed a p53 increase after siOrai3 treatment of O3V-T47D cells, and showed that p53 remained located in the nucleus (Fig. S5).
The signaling pathway is PI3K-dependent
We first used protein arrays to evaluate apoptosis actors potentially involved in the p53 downregulation. Since no candidates were found (Fig. S6), we assessed some other potential calcium-dependent pathways. We showed that NFAT (Nuclear Factor of Activated T-cells) was not implicated, using cyclosporin A (Fig. S7A) or using a reporter luciferase assay (Fig. S7B). We next inhibited calmodulin using calmidazolium chloride (Fig. S7C), calmodulin-kinase II using KN-93 (Fig. S7D), and MAPK using PD98059 (Fig. S7E). All these actors were clearly not implicated in Orai3-mediated p53 downregulation. Conversely, the PI3K inhibitor LY294002 was able to cancel, at least partly, Orai3-conferred resistance (Fig. 5C). O3V cells treated with LY294002 expressed p53 at a higher level than EV cells (Fig. 5D). Consistent results were obtained with two other PI3K inhibitors (wortmannin and PIK93): p53 was re-expressed in O3V cells (Fig. 5D), suggesting that PI3K pathway is implicated in Orai3-mediated p53 downregulation.
The signaling pathway is Sgk-1-dependent
Although PI3K was implicated, pAkt and Akt expression were not altered in O3V cells (Fig. 5E). We next assessed the serum- and glucocorticoid-induced protein kinase 1 (Sgk-1) pathway, since Sgk-1 was found to be regulated by SOCE, and mediated cytoprotection against cell death in ER− BC cells [23]. Phosphorylation level of Ser422 is essential for Sgk-1 activation [24]. The ratio pSgk-1/Sgk-1 was increased upon Orai3 overexpression (Fig. 5F), indicating Sgk-1 activation. GSK650394 (known to be a specific Sgk-1 competitive inhibitor [25] was able to restore p53 expression in O3V cells at levels seen in control EV cells (Fig. 5G). In T47D-O3V cells, p53 level increased subsequently to Sgk-1 downregulation (Figs. 5H and S8A).
Mdm2 does not appear to be the only link between Sgk-1 and p53
p53 degradation is also mediated by an Mdm2-independent mechanism
Mdm2 is activated by a Sgk-1-dependent Ser166 phosphorylation, inducing p53 degradation and affecting cell survival [26]. Mdm2 protein expression was drastically decreased in O3V cells (by almost 90%, Fig. 6A). The ratio Ser166Mdm2/Mdm2 was increased in O3V vs. EV cells, most probably as a result of PI3K/Sgk-1 pathway activation. Orai3-mediated p53 downregulation could hardly be explained by the drastic Mdm2 decrease. This protein downregulation was paralleled by decreased mRNA levels (Fig. 6B), probably because of the p53 transcriptional regulation of Mdm2.
Is Nedd4-2 implicated in O3V-induced p53 degradation?
Nedd4-2 is another Sgk-1-activated ubiquitin ligase. We found that Nedd4-2 downregulation was able to restore p53 protein levels (Figs. 6C and S8B). A critical site for the inactivation of Nedd4-2 by Sgk-1 is the S448 [27] residue, and the phosphorylation level of this site was found to be dramatically decreased in O3V cells (Figs. 6D and S8C).
Sek-1, the missing link between Sgk-1 and Nedd4-2?
Since activated Sgk-1 resulted in a dephosphorylated Nedd4-2, we searched either for an Sgk-1-activated phosphatase, or for an Sgk-1-inactivated kinase. Sek-1 is a kinase known to be inhibited by Sgk-1. Total Sek-1 protein was drastically decreased. Sek-1 phosphorylation level decreased less importantly (Fig. 6E), and the ratio pSek-1/Sek-1 was thus increased in O3V cells (Fig. S8D). After calcium withdrawal, Sek-1 protein levels and pNedd4-2 were drastically increased, in EV as well as in O3V cells (Figs. 6e and S8E). Moreover, in O3V cells, increased levels of Sek-1 and pNedd4-2 in “zero calcium” external solution were associated to increased p53 levels (Fig. 5B). When silencing Sek-1 in T47D-EV cells (expressing activated Sek-1), protein expression levels of pNedd4-2 and p53 were decreased, but not the Nedd4-2 expression (Figs. 6F and S8F).
Discussion
The appearance of cell resistance to chemotherapies is the major cause of relapse and metastasis, by allowing cancer cells to spread and grow at distant sites from the primary tumor [28]. We hypothesized that Orai3, a calcium channel upregulated in breast tumors and involved in apoptosis [14], would be able to play a role in cell resistance. In BC cells, Orai3 upregulation increased SOCE. Interestingly, resistance of prostate cancer (PC) cells was also linked to an Orai member (Orai1), but this resistance was conferred by a reduced SOCE [9, 10, 29, 30]. The resistance found in PC cells is thought to be a consequence of newly formed heteromeric Orai1/Orai3-based channels, at the expense of homomeric Orai1 and/or Orai3-based SOCs [30]. Results obtained in PC and BC cells are however hardly comparable, because Orai1 is the main Orai isoform implicated in SOCE in PC cells [30]. In these cells, Orai3 overexpression also shifts the balance of predominant Ca2+ entry pathways from store-dependent ones to arachidonic acid (AA)-dependent ones [30]. AA-dependent calcium entry was however not modified in our BC cell lines overexpressing Orai3 (data not shown). Orai3 channels may thus preferably work in a homomeric state in ER+-BC cells, and Orai3 overexpression may only increase the proportion of active Orai3 channels. This hypothesis is supported by the increased SOCE (which could appear quite modest, but without concomitant Stim1 overexpression, the pool of endogenous Stim1 is likely to be the limiting factor of SOCE amplitude).
Both classical apoptosis inducers and chemotherapeutic drugs used in this study were limited in inducing mortality in Orai3-overexpressing cells: this finding suggests a common mechanism. Our high-throughput transcriptomic analysis suggested a p53-dependent Orai3-conferred resistance. We showed a p53 downregulation in T47D cells (harboring a mutated p53), as well as in MCF-7 cells (p53 wild type). However, we confirm that the L194Fp53 mutant in T47D cells retains some transcriptional activity, in good agreement with the literature [21], and the Orai3-conferred resistance is therefore likely dependent on p53 transcriptional activity, shown to be important for its pro-apoptotic function [31]. In line with this hypothesis, our bioinformatic results on large cohorts suggested that in human BC, Orai3 overexpression occur in BC cells that have no TP53 mutation, loss, or lower mRNA expression. Also in line with the above-mentioned hypothesis, we found that p53 was located in the nucleus, even upon Orai3 overexpression (Fig. S3B). This observation is relevant because transcription-independent mechanisms have already been demonstrated for p53, notably at the endoplasmic reticulum where p53 regulates apoptosis in a Ca2+-dependent manner [32]. Decreased nuclear p53 was therefore an important step for the development of Orai3-conferred resistance. For instance, p53 antagonizes Bcl-2 function at several levels, including the negative regulation of Bcl-2 expression at the transcriptional level [33]. Bcl-2 was found to be upregulated in BC cell lines with all treatments, and is likely to be responsible, at least in part, for the increased resistance. Importantly, Orai3 overexpression was not only able to confer resistance to apoptosis in ER+-BC cells, but also in the non-tumoral Cos-7 cell line. This result, although quite unexpected, suggests that Orai3 is apparently able to confer apoptosis resistance to virtually any other cell line.
SOCs have already been proposed as apoptosis regulators [10], and Orai3 would be one of them. External calcium was necessary for Orai3 to downregulate p53, and among all investigated pathways, we only found an implication of the PI3K. The fact that Orai3-conferred Akt-independent resistance was unexpected. Although Akt is considered to be one of the key enzymes driving resistance of cancer cells [34], PI3K is able to promote cancer by Akt-independent pathways, possibly by Sgk isoforms [35]. Sgk-1 has been recently linked to resistance [36], is regulated by SOCE, and mediates cytoprotection against cell death in ER− BC cells [23]. Our data suggest that Orai3 was able to regulate Sgk-1 in ER+ BC cells. It has been demonstrated that Sgk-1 could activate Mdm2-dependent p53 degradation, thereby affecting cell proliferation, differentiation, and survival [26]. Since Sgk-1 phosphorylates166Ser-Mdm2 [26], a higher phosphorylation level was expected in O3V cells. A higher pMdm2/Mdm2 ratio was indeed found, most likely due to Sgk-1 activation, but a dramatic Mdm2 downregulation was evidenced (and this could be a consequence of the p53 downregulation in O3V cells, since Mdm2 is transcriptionally regulated by p53 [37]). It appeared thus difficult to consider Mdm2 as the sole p53 regulator in O3V cells (Mdm2 downregulation causes, on the contrary, an increase in p53 levels in T47D cells [38]). p53 was therefore likely degraded by another mechanism. Other ubiquitin ligases interacting with Sgk-1 are part of the Nedd4 E3 ubiquitin ligases family. Nedd4-1, known to ubiquitinylate tumor suppressors [39], was an ideal candidate but is not a target of Sgk-1 [40]. Nedd4-2, known to also ubiquitinylate ion channels and membrane transporters, can be phosphorylated by Sgk-1, and is also calcium-activated [39]. The fact that a partial Nedd4-2 downregulation was able to restore, at least partially, p53 protein levels indicated that Nedd4-2 could also mediate p53 degradation, either in a direct or indirect way. Nedd4-2 can be phosphorylated by Sgk-1 at 3 relevant phosphorylation sites, including a “major” site (Ser448, corresponding to Ser444 in Xenopus Laevis) regarding to 14-3-3 protein binding [41]. 14-3-3 proteins sequester pNedd4-2, reducing for instance its interaction with the sodium channel ENaC [42]. The ratio Ser448Nedd4-2/Nedd4-2 was dramatically decreased, potentially implying a higher availability of Nedd4-2 for ubiquitination of target proteins (possibly including p53). However, Sgk-1, as a kinase, could not be implicated directly in Nedd4-2 dephosphorylation. We hypothesized that Sgk-1 was able to phosphorylate and inactivate a kinase targeting the Ser448 residue of Nedd4-2 (residue known to be phosphorylated by several kinases [43]). Sek-1, known to be inactivated by Sgk-1 [44], is part of the Sgk-1 signaling pathway leading to cell resistance [45], and is already described for regulating p53 expression [46]. Sek-1 protein content was indeed found to be phosphorylated and thus inactivated, and was also dramatically decreased in O3V cells. Sek-1 was thus a potential Nedd4-2 kinase. In good agreement with this hypothesis, Sek-1 downregulation was able to decrease Nedd4-2 phosphorylation. This was likely to result in less Nedd4-2 sequestration with 14-3-3 proteins, and more Nedd4-2-mediated p53 degradation (confirmed at the protein level). Whether p53 can be ubiquitinated by Nedd4-2 requires further work. It is noteworthy that Nedd4-2 could also be directly activated by Orai3-mediated calcium entry (with calcium releasing auto-inhibition of Nedd4-2 [39]). Further work is also needed to elucidate the Sgk-1/Sek-1/Nedd4-2/p53 relationships.
To summarize, we show here that the Orai3 calcium channel, overexpressed in most ER+ breast tumors, is able to confer resistance to cell death by modulating p53 protein expression via the PI3K/Sgk-1 signaling pathway, which signals to activate the ubiquitin ligase Nedd4-2, most probably via Sek-1 (Fig. 7). We were able to show supporting evidence for our cell line experiments using real human BC patients using public data sets. Further work is needed to elucidate whether p53 degradation is directly or indirectly mediated by Nedd4-2, and to validate Orai3 as a predictive marker for cellular resistance against chemotherapeutic treatments in human breast tumors.
Methods
Cell culture
T47D and MCF7 BC cells were grown in Eagle’s MEM supplemented with 5% FCS (Fetal Calf Serum, Lonza), 2 mM glutamax, and 0.06% HEPES. Cos-7 cells were grown in DMEM medium supplemented with 5% FCS and 2 mM glutamax. All cell lines were grown in a 5% CO2-humidified incubator at 37 °C.
Plasmid constructs
Orai3 gene was inserted into the pEF1α-IRES-DsRed plasmid. The plasmid allowed the generation of a bicistronic mRNA in transfected cells, with production of separate Orai3 and fluorescent DsRed proteins.
Stable transfection
Transfection was performed using the nucleofection technology (Amaxa), as previously described [47]. Cells were transfected either with pEF1α-IRES-DsRed vector as a control (referred in the text to as “EV”), or with pEF1α-Orai3-IRES-DsRed (referred in the text to as “O3V,” Orai3 vector).
Selection of stable clones
Transfected cells were selected for permanent integration of the plasmid in the genome with G418 (Sigma, 0.8 µg ml−1). Cells were sorted with a FACSCanto device (Beckton-Dickinson) 3 weeks after transfection. Each well of the 96-well plates (three plates for EV, three for O3V) was then examined to rule out the presence of more than one clone per well. Two weeks after selection, a new selection was made based on relative fluorescence.
Transient transfection
Transfection was performed using the nucleofection technology according to the Amaxa Biosystems protocol. Cells were transfected with siSgk-1 (5′-GTGATCGGAAAGGGCAGTT-3′, Eurogentec), a pool of siNedd4-2 (siNedd4-2#1: 5′-AACCACAACACAAAGUCACAC-3′; siNedd4-2#2: 5′- GUUGCUGGUCUGGCCGUAU -3′, Eurogentec), siSek-1 (Santa Cruz #sc-35909), or with control siRNA (duplex negative control, Eurogentec).
Chemicals and reagents
All chemicals were purchased from Sigma, unless otherwise stated. Clones were treated with cytotoxic and chemotherapeutic agents to induce cell mortality: Tg (1 μM, 24 h), STS (1 μM, 6 h), cisplatin (50 μM, 24 h), 5-FU (40 μg ml-1, 48 h), paclitaxel (100 nM, 48 h), etoposide (40 μM, 24 h), and pemetrexed (500 µM, 24 h). All these products were dissolved in DMSO (referred in the figures to as “no treatment,” “nt”). Pharmacological inhibitors used to study the signaling pathways were the following: cyclosporine A (1 µM, 24 h), PD98058 (40 µM, 24 h), LY294002 (20 µM, 24 h), wortmannin (200 nM, 24 h), PIK93 (500 nM, 24 h), pifithrin-α (40 µM, 24 h), nutlin-3 (20 µM, 24 h), MG-132 (5 µM, 24 h), calmidazolium chloride (1 µM, 24 h), and GSK650394 (200 nM, 24 h). KN-93 (1 µM, 24 h) was purchased from RBI.
Calcium imaging
Cells were grown onto glass coverslips and were loaded for 45 min at 37 °C with 3 µM Fura-2/AM (Sigma). After Fura loading, cells were washed and kept in extracellular saline solution containing 145 mM NaCl, 5 mM KCl, 2 mM CaCl2, 1 mM MgCl2, 5 mM glucose, 10 mM HEPES (pH adjusted to 7.4 with NaOH). The glass coverslip was mounted in a chamber on a Zeiss microscope equipped for fluorescence. Fura-2 fluorescence was excited at 340 and 380 nm using a monochromator (polychrome IV, TILL Photonics, Planegg, Germany), and captured by a Cool SNAPHQ camera (Princeton Instruments) after filtration through a long-pass filter (510 nm). Metafluor software (version 7.1.7.0, Molecular Devices) was used for acquisition and analysis. The [Ca2+]i concentration was derived from the ratio of the fluorescence intensities for each of the excitations wavelengths (F 340/F 380). The cells were continuously perfused with the saline solution. SOCE was monitored through Tg-stimulated Ca2+ influx. We first perfused 1 µM Tg in Ca2+-free solution for 7 min. Then, 2 mM Ca2+ was added.
Real-time quantitative PCR (qRT-PCR)
Extraction of total RNA from cell lines and real-time PCR were performed as previously described [14]. The relative amount of Orai3 mRNAs in BC cells were normalized to the endogenous control (ß-actin) using the Pfaffl method [48].
Western blot analysis
Whole-cell lysates were prepared with RIPA buffer containing a protease inhibitor cocktail (Sigma-Aldrich). The primary antibodies used were: anti-Orai3 (1:200, Sigma Prestige antibody), anti-Bcl-2 (1/500, Cell Signaling), anti-Bax (1/500, BD Pharmingen), anti-PARP (1/1000, Santa Cruz and 1/1000, AbCam), anti-p53 (1/1000, Santa Cruz), anti-Akt (1/1000, Cell signaling), anti-p-Akt (Ser473) (1/10,000, Cell signaling), anti-Sgk-1 and anti-p-Sgk-1-Ser422 (1/1000, AbCam), anti-Mdm2 (1/1000, AbCam), anti-p-Mdm2-Ser166 (1/1000, Santa Cruz), anti-Nedd4-2 and anti-p-Nedd4-2-Ser448 (1/1000, Abcam), and anti-Sek-1 and anti-p-Sek-1-Ser80 (1/1000, Abcam). Secondary antibodies were coupled to horseradish peroxidase. Actin antibody (1/2000, Santa Cruz Biotechnology) was used for loading control experiments. Bound antibodies were visualized using ECL chemiluminescent substrate (GE Healthcare) and quantified using the Bio-Rad image acquisition software (Quantity One).
Dot-blot analysis
The protein array “PathScan® stress and apoptosis signaling antibody array Kit” (Cell Signaling Technology) was analyzed with the plugin “Dot blot analyzer” for ImageJ (available at the Gilles Carpentier’s Research website).
Cell death and apoptosis
Cell viability and mortality were first measured using Trypan Blue assay. BC cells were grown in 35 mm Petri dishes at a density of 1 × 105 cells for 72 h. Cell count was assessed using the standard Malassez cell method. Cell counts were performed six times and the results were expressed as the percentage of viable or dead cells normalized to control. Cell death and apoptosis was also assessed with a biochemical method: cleaved PARP (AbCam), combined with anti-PARP-1 (Santa Cruz). Calcium-free solutions were made by addition of 150 μM EGTA. In these conditions, free calcium is <1 μM [49].
Bioinformatic analysis of public BC data sets
ORAI3 DNA copy-number aberrations and mRNA overexpression compared to normal tissue (Fig. S1F, G, and H) was determined using Oncomine (https://www.oncomine.org/). The three data sets analyzed represent the largest DNA copy-number cohort, and the two largest mRNA expression profiling studies that contained samples for all major BC clinical subtypes. DNA copy-number gains and mRNA overexpression compared to normal tissue were calculated using 2 log and 2 log median-centered analyses, respectively. Statistical analyzes were according to default website settings.
For the correlation of tumor Orai3 mRNA expression to therapy response in BC patients in Fig. 1, the public NCBI Gene Expression Omnibus (http://www.ncbi.nlm.nih.gov/geo/) was browsed for breasts cancer cohorts with genome-wide mRNA expression profiles as well as chemotherapy response annotation, resulting in three sets: Booser-508 (GSE25066), Quiles-61 (GSE28844), and Wessels-178 (GSE34138). Booser-508 and Quiles-61 are on Affymetrix HG U133, Wessels-178 on Illumina WG6v3 mRNA expression platforms. The three sets were uploaded and analyzed in R2: a genomics analysis and visualization platform developed in the Department of Oncogenomics at the Academic Medical Center—University of Amsterdam (http://r2.amc.nl). Expression data (CEL files) were analyzed as described previously [50]. Briefly, gene transcript levels were determined from data image files using GeneChip operating software (MAS5.0 and GCOS1.0, from Affymetrix). Samples were scaled by setting the average intensity of the middle 96% of all probe-set signals to a fixed value of 100 for every sample in the data set, allowing comparisons between microarrays. The TranscriptView genomic analysis and visualization tool within R2 was used to check if probe-sets uniquely mapped in an anti-sense orientation in a highly transcribed exon of the gene locus (http://r2.amc.nl > genome browser). The probe-sets selected for ORAI3 (Affymetrix 221864_at and Illumina 1736628) meet these criteria. All other details for the data sets, including their literature references, can be obtained through their GSE or E number from the NCBI GEO and EBI ArrayExpress websites, respectively. Orai3 mRNA expression correlation to therapy response was determined using the non-parametric Kruskal–Wallis test to prevent undue influence of non-normally distributed data.
The correlation of ORAI3 and TP53 DNA and mRNA aberrations in Fig. S4 was determined using the cBioPortal website (http://www.cbioportal.org/). Four data sets representing two independent studies, METABRIC and TCGA, had complete annotations for DNA mutation and copy number and mRNA expression, and were analyzed using a Fisher exact test according to default website settings.
All other details for the data sets, including their literature references, can be obtained through the cBioPortal, Oncomine, or R2 websites. All test results were considered statistically significant if p < 0.05.
Statistical analysis
Values are expressed as mean ± SEM. Statistical analysis of the data was performed using appropriate analysis of variance, Mann–Whitney or t tests. Differences were considered significant at p < 0.05 unless otherwise stated.
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Acknowledgements
This study was supported by Région Picardie, le Ministère de l’Education Nationale (France), and la Ligue Nationale Contre le Cancer (SEPTENTRION).
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H.O.-A., P.K., D.G., F.H., D.T., and J.H. designed the experiments. J.H., P.K., D.G., L.R.-D., F.H., and C.L. performed and analyzed the experiments. All authors discussed the results and commented on the manuscript. P.K., J.H., D.G., and H.O.-A. wrote the manuscript.
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Hasna, J., Hague, F., Rodat-Despoix, L. et al. Orai3 calcium channel and resistance to chemotherapy in breast cancer cells: the p53 connection. Cell Death Differ 25, 693–707 (2018). https://doi.org/10.1038/s41418-017-0007-1
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DOI: https://doi.org/10.1038/s41418-017-0007-1