Ion channnels and transporters in cancer. 5. Ion channels in control of

1 downloads 0 Views 408KB Size Report
Sep 21, 2011 - classical blockers of ion channels can influence cell death rates, ... internal compartments, has led researchers to appreciate the pivotal ... 232, Cité Scientifique, 59650 Villeneuve d'Ascq, France (e-mail: Natacha. ..... Light blue arrows indicate the flow .... Bortner CD, Gomez-Angelats M, Cidlowski JA.
Am J Physiol Cell Physiol 301: C1281–C1289, 2011. First published September 21, 2011; doi:10.1152/ajpcell.00249.2011.

Themes

Ion channnels and transporters in cancer. 5. Ion channels in control of cancer and cell apoptosis V’yacheslav Lehen’kyi, George Shapovalov, Roman Skryma, and Natalia Prevarskaya INSERM, Equipe labellisée par la Ligue Nationale contre le cancer; and Université des Sciences et Technologies de Lille, Villeneuve d’Ascq, France Submitted 19 September 2011; accepted in final form 19 September 2011

Lehen’kyi V, Shapovalov G, Skryma R, Prevarskaya N. Ion channnels and transporters in cancer. 5. Ion channels in control of cancer and cell apoptosis. Am J Physiol Cell Physiol 301: C1281–C1289, 2011. First published September 21, 2011; doi:10.1152/ajpcell.00249.2011.— Ion channels contribute to virtually all basic cellular processes, including such crucial ones for maintaining tissue homeostasis as proliferation, differentiation, and apoptosis. The involvement of ion channels in regulation of programmed cell death, or apoptosis, has been known for at least three decades based on observation that classical blockers of ion channels can influence cell death rates, prolonging or shortening cell survival. Identification of the central role of these channels in regulation of cell cycle and apoptosis as well as the recent discovery that the expression of ion channels is not limited solely to the plasma membrane, but may also include membranes of internal compartments, has led researchers to appreciate the pivotal role of ion channels plays in development of cancer. This review focuses on the aspects of programmed cell death influenced by various ion channels and how dysfunctions and misregulations of these channels may affect the development and progression of different cancers. cell cycle; programmed cell death; plasma membrane

to normal tissue homeostasis, and abnormalities in apoptotic functions underlie the pathogenesis of many diseases. In general, an excess of apoptosis can lead to tissue degeneration, whereas a deficiency can lead to cancer. The molecular machinery of apoptosis (from initiation to the final phagocytosis of cellular remnants) is complex, involving many molecular players and signaling pathways (30, 36, 66). Over the past two or three decades, a clear and seemingly comprehensive picture of the biology of apoptosis has emerged (37). Originally identified through its characteristic cytological morphology (40), this mode of death is now known to result from activation of a common mechanism relevant in both physiological and pathological circumstances (15, 37). At the heart of this mechanism lie two families of proteins, the caspases and members of the Bcl2 extended family, as illustrated by Fig. 1. The caspases form a cascade in which initiator caspases are activated by lethal stimuli arising either at the cell membrane as a result of cytokine-receptor binding, or within the cell, in relation to internally determined signals, often generated in the microenvironment of particular organelles (87). The Bcl2 family is so called because of the relationship of its members to the B-cell lymphoma oncogene whose discovery led eventually to the identification of most of the other

APOPTOSIS IS INTEGRAL

Address for reprint requests and other correspondence: N. Prevarskaya, Laboratory of Cell Physiology, INSERM U1003, Bât. SN3, 2éme étage, p. 232, Cité Scientifique, 59650 Villeneuve d’Ascq, France (e-mail: Natacha. [email protected]). http://www.ajpcell.org

family members, but at the molecular level this family is remarkably diverse (84). On the other hand, different inducers of apoptosis trigger plasma membrane potential depolarization (8), while the inhibition of apoptosis by Bcl-2 and Mcl-1 is associated with plasma membrane hyperpolarization (29, 82). Furthermore, irrespective of the inducer or whether apoptosis is a part of a physiological or pathological process, it always involves Ca2⫹ influx followed by the recruitment of three major Ca2⫹-dependent apoptotic mechanisms: mitochondrial, cytoplasmic, and endoplasmic reticulum (ER)-mediated (60, 65). Thus the ion fluxes mediated by ion channels are extremely important mechanisms of apoptosis regulation. The first important role ascribed to plasma membrane ion channels, over 60 years ago, was their participation in cellular electrogenesis and electrical excitability. However, numerous subsequent studies have firmly established the contribution of ion channels to virtually all basic cellular behaviors, including such crucial ones for maintaining tissue homeostasis as proliferation, differentiation, and apoptosis (44, 69, 72). The major mechanisms via which ion channels contribute to these crucial processes include: providing the influx of essential signaling ions, regulating cell volume, and maintaining membrane potential. Malignant transformation of cells resulting from enhanced proliferation, aberrant differentiation, and impaired ability to die is the prime reason for abnormal tissue growth, which can eventually turn into uncontrolled expansion and invasion, characteristic of cancer (11, 34). This review focuses on the aspects of programmed cell death influenced by various ion channels and how dysfunctions and/or misregulations of these channels may influence the development and progression of different cancers. Role of Potassium Channels in Apoptosis Potassium channels are involved in the maintenance of resting potential, thereby they represent an integral part of all cells. As K⫹ channels provide an efflux of K⫹, which is the dominant cation of the intracellular medium, they are also important regulators of cell volume. K⫹ channels represent one of the most diverse groups of channels, consisting of five major classes: 1) voltage-gated (Kv class), 2) Ca2⫹-activated (KCa class), 3) inwardly rectifying (Kir class), 4) ATP-sensitive (KATP class), and 5) background two-pore domain-containing (K2P class) (83). Some of them have been identified in various types of carcinomas where they are involved in the proliferation and apoptosis of tumor cells (83). This is consistent with the paradigm according to which the enhanced K⫹ efflux is associated with apoptosis promotion and, conversely, that apoptosis is attenuated if K⫹ efflux is decreased (70, 92). The mechanisms for proapoptotic effects of enhanced K⫹ efflux

0363-6143/11 Copyright © 2011 the American Physiological Society

C1281

Themes C1282

ION CHANNELS AND CANCER

Fig. 1. Principal scheme of the mechanisms of apoptosis regulation involving the caspases and members of the Bcl2 family of proteins.

include: 1) decay of the membrane potential and associated Ca2⫹ overload and 2) apoptotic cell shrinkage (apoptotic volume decrease, AVD) and activation of intracellular proapoptotic effectors (92). In particular, decreases in intracellular K⫹ appear to promote critical events during the early phases of cell death, including proteolytic cleavage of pro-caspase-3 and enhanced endonuclease activity (70). Among numerous K⫹-channel types, the blockade of the large conductance Ca2⫹-activated K⫹ channels (BK channels) in HeLa and A2780 cancer cells results in tumor cell apoptosis and cycle arrest at G1 phase, and the transduction pathway underlying the anti-proliferative effects is linked to the increased expression of apoptotic protein p53 and the decreased expression of its chaperone proteins heat shock protein (hsp) (32). The specific inhibitor of BK channels NS1619 induces apoptosis of A2780 cells in a dosage- and time-dependent manner (IC50 ⫽ 31.1 ␮M, for 48 h pretreatment), and these effects of NS1619 were associated with increased expression of p53, p21, and Bax. These results indicate that BK channels play an important role in regulating proliferation of human ovarian cancer cells and may induce apoptosis through induction of p21(Cip1) expression in a p53-dependent manner. In addition to alterations in Ca2⫹ homeostasis, apoptosis is characterized by a series of changes that lead to plasma membrane potential (Vm) decay, cell shrinkage, DNA breakdown, and finally phagocytosis. The diverse external and internal stimuli that trigger apoptosis have been shown to involve the loss of intracellular K⫹ due to enhanced K⫹ efflux, which is required for early AVD as well as for releasing inhibition by high K⫹ levels of endogenous death-executing caspases and DNA-degrading endonucleases (9). The efflux of K⫹ to an extent that overrides the capacity of Na⫹-K⫹-ATPase to sustain the transmembrane K⫹ gradient also causes the decay of Vm. Therefore, to evade apoptosis, malignant cells must prevent the loss of intracellular K⫹ by downregulating K⫹ channels (7). Consistent with this, several human cancers are characterized by higher mitochondrial membrane potential and a lower expression of the redox-sensitive K⫹ channel Kv1.5, with both factors contributing to the enhanced resistance to apoptosis of cancer cells relative to normal cells (7). The pharmacological blockade of Kv1.5 channels in SGC7901 gastric cancer cells has also been shown to enhance resistance to apoptosis-inducing chemotherapeutic drugs (adriamycin, cisplatin, vincristine, and 5-fluorouracil) (33). In addition, the lower activity of the TWIK (two-pore domain weakly inward rectifying K⫹ channel)-related acid-sensitive K⫹ channels (TASK-3) channel has been correlated with the increased AJP-Cell Physiol • VOL

survival of glioma cells (53). However, when assessing the effects of K⫹ channels it is important to consider their indirect effects on the Ca2⫹ dependence of apoptosis occurring through the control of cell Vm and the associated Ca2⫹ influx. For instance, this mechanism was implicated in the apoptosis of HepG2 human hepatoblastoma cells induced by the K⫹ channel blocker 4-aminopyridine (4-AP) (41). In addition, the involvement in the antiapoptotic effects of the expression of oncogenic TASK-3 channel (63) mentioned above cannot be excluded. The importance of augmented K⫹ efflux in apoptosis was directly confirmed in experiments with KChAP, a K⫹-channel regulatory protein that increases K⫹-channel expression in a “chaperone-like” fashion in heterologous expression systems (4). Overexpression of KChAP in LNCaP cells decreased the average cell size due to enhanced AVD and promoted spontaneous cells apoptosis (86). Moreover, repetitive overexpression of KChAP during 19 days in LNCaP and DU-145 tumor xenografts in nude mice significantly suppressed tumor growth due to the apoptosis of infected tumor cells. The mechanism of proapoptotic KChAP action consists of the direct interaction with K⫹ channels, thereby increasing their expression. Overexpression of KChAP in LNCaP cells also produced G0/G1 cell-cycle arrest via the activation of p53 (the tumor suppressor protein) acting as a transcription factor. However, the involvement of p53 in proapoptotic KChAP activity was ruled out based on the fact that KChAP was able to induce similar apoptosis in DU-145 cells expressing mutated p53, rendering it nonfunctional as a transcription factor (86). In conclusion, K⫹ channels seem to play an important role in the control of cancer cells apoptosis by regulating membrane potential and passive calcium influxes. However, further studies are needed to identify the precise role of each type of K⫹ channels in carcinogenesis and apoptosis resistance for their potential utilization as diagnostic markers or therapeutic targets. Voltage-Gated Sodium Channels and Apoptosis As compared with other channels very little is known about the involvement of voltage-dependent sodium channels. The notion that increased malignancy of cancer cells is associated with the shift to a “more excitable” phenotype of their plasma membrane is supported not only by the decrease in K⫹ conductances, as described above, but also by the appearance of inward currents characteristic of excitable cells, such as voltage-gated Na⫹ currents. Indeed, in several cancer epithelial cells, the expression of voltage-gated Na⫹ channels (VGSCs) on functional, protein and mRNA levels has been firmly established (1, 5, 18). Though the role of VGSCs for the cancer cell proliferation, migration, and invasion has already been demonstrated (4, 5, 24, 28, 58), very little is known for their role in apoptosis. The involvement of VGSCs in cell death by apoptosis has been shown in Jurkat cell line (71). The real-time PCR analysis of neoplastic mesothelial cells showed significant expression of the mRNAs encoding for Na(V)1.2, Na(V)1.6, and Na(V)1.7 [and less so for Na(V)1.3, Na(V)1.4, and Na(V)1.5] main voltage-gated sodium channel (VGSC) ␣-subunit(s). However, blockade of VGSCs with tetrodotoxin decreased mesothelioma cell migration in in vitro motility assays and failed to interfere

301 • DECEMBER 2011 •

www.ajpcell.org

Themes ION CHANNELS AND CANCER

with cell viability, proliferation, and apoptosis progression triggered by UV exposure (25). These data on the involvement of VGSC in apoptosis may be confirmed by other indirect evidence. For instance, the progression of the hormone-responsive cancer, as prostate cancer, to the androgen-insensitivity stage is accompanied by the appearance of new apoptosis-resistant cell phenotypes. The enrichment of androgen-independent tumors with malignant neuroendocrine cells should especially be noted. Fully differentiated, nonproliferating, neuron-like apoptosis-resistant neuroendocrine cells are a normal component of the prostate epithelium which, by releasing a variety of neurosecretory products, regulate the development and secretory activity of the prostate in the endocrine/paracrine manner (2, 17). Generally, prostatic neuroendocrine cells are apoptosis-resistant cells and express a variety of membrane ion channels characteristic of neurons, like TTX-resistant VGSCs, high-voltage-activated (HVA) Ca2⫹ channels of L- and N-type, and are also able to generate action potentials. An expanding population of neuroendocrine cells beyond normal proportions due to the malignant transformation of epithelial cells is a common characteristic of prostate cancer progression (2). Neuroendocrine cells lack nuclear androgen receptor (AR), thereby representing an androgen-insensitive cell phenotype in the prostate (6). They also exhibit high apoptosis resistance (22) which, according to existing evidence, is unrelated to the common antiapoptotic Bcl-2 protein (90) and is conferred instead by new survival proteins survivin (89) and clusterin (39). Further investigations are needed to precisely characterize the role of VGSCs in the cancer-related apoptosis mechanisms whether related to misregulation of membrane potential mechanisms or other not yet identified mechanisms. Cl⫺ Channels Activation of the chloride current through specialized volume-regulated anion channels (VRACs) in response to cell swelling (ICl,swell) is one of the major mechanisms by which cells tend to restore their volume following hypo-osmotic stress [a process known as regulatory volume decrease (RVD)] (26, 57). Extracellular osmotic perturbations are not the only reason for alterations in cell volume. Effectively counteracting abrupt volume changes and maintaining relative volume constancy during active solute uptake, exocytosis, proliferation, and differentiation are major prerequisites for cell survival. Indeed, there is strong evidence that disordered or altered cell volume regulation is associated with apoptosis (57). Compelling support for such an association has been provided by demonstrating the direct link between apoptotic resistance conferred by antiapoptotic Bcl-2 protein and the strengthening of RVD capability due to upregulation of ICl,swell (48, 73). The molecular nature of native ICl,swell-carrying VRACs has been identified, and several membrane proteins are considered as potential candidates (26, 57); these data are also consistent with ClC-3 protein involvement in prostate-specific VRAC, as well as with its upregulation in androgen-independent prostate cancer cell phenotypes (48). When breast tumor cells were transfected with plasmids encoding either murine calcium-sensitive chloride channels 1 or 2 (mCLCA1 or mCLCA2), colony formation was greatly reduced relative to a vector-transfected control, demonstrating AJP-Cell Physiol • VOL

C1283

that calcium-sensitive chloride channel (CLCA) expression is deleterious to tumor cell survival (19). Furthermore, mammary epithelial cells overexpressing mCLCA2 had twice the rate of apoptosis of normal cells when subjected to serum starvation and formed multinuclear giants at a high frequency in normal culture, suggesting that mCLCA2 can promote either apoptosis or senescence (19). BCL-2 overexpression enhances the capability of RVD, a cellular defensive process against hypotonic stress. In various clones of kidney cancer Madin-Darby canine kidney (MDCK) cells, hypotonic stress induced an outwardly rectified Cl⫺ current that was significantly upregulated by BCL-2 overexpression (73). Other fundamental characteristics of this channel were similar among different MDCK clones, such as sensitivity to Cl⫺ channel inhibitor, anion permeability, and time-dependent inactivation at more positive potential. Moreover, neutralization of endogenous BCL-2 by antibody blocks the normal RVD response and the activation of swelling-activated Cl⫺ channel in human cervical cancer HT-3 cells (73). mtCLIC/CLIC4 is a p53- and tumor necrosis factor-␣ (TNF␣)-regulated cytoplasmic and mitochondrial protein that belongs to the CLIC family of intracellular chloride channels. mtCLIC associates with the inner mitochondrial membrane. Dual regulation of mtCLIC by two stress response pathways suggested that this chloride channel protein might contribute to the cellular response to cytotoxic stimuli. DNA damage or overexpression of p53 upregulates mtCLIC and induces apoptosis. Overexpression of mtCLIC by transient transfection reduces mitochondrial membrane potential, releases cytochrome c into the cytoplasm, activates caspases, and induces apoptosis (20). These studies indicate that mtCLIC, like Bax, Noxa, p53AIP1, and PUMA, participates in a stress-induced death pathway converging on mitochondria. In the same way, in human osteosarcoma cell lines SaOS and U2OS, CLIC4antisense induction increased TNF-␣-mediated apoptosis without altering TNF-␣-induced nuclear factor-␬B activity (75). Also, reducing CLIC proteins in tumor grafts of SP1 cells expressing a tetracycline-regulated CLIC4-antisense substantially inhibited tumor growth and induced tumor apoptosis. It has also been shown that in KCP-4 human epidermoid cancer cell line, which serves as a model of acquired resistance to cisplatin, has virtually no volume-sensitive, outwardly rectifying (VSOR) chloride channel activity (45). It was found that treatment with trichostatin A (TSA), a histone deacetylase inhibitor, caused VSOR chloride channel function to be partially restored. Treatment of the cells with both TSA and cisplatin resulted in an increase in caspase-3 activity. These effects were blocked by simultaneous treatment of the cells with a VSOR chloride channel blocker. These results indicate that restoration of the channel’s functional expression by TSA treatment leads to a decrease in the cisplatin resistance of KCP-4 cells suggesting the involvement of VSOR chloride channel in the cisplatin resistance of KCP-4 cancer cells (45). The same data have been obtained for nonsmall cell lung cancer (54). Cisplatin treatment induced an AVD and activated a Cl⫺ current that showed properties similar to the VSOR Cl⫺ current in wild-type A549 cells. Both the AVD process and VSOR Cl⫺ current were blocked by the chloride channel blocker 4,4=-diisothiocyanostilbene-2,2= disulfonic acid. However, the A549/CDDP cells, a model of acquired cisplatin

301 • DECEMBER 2011 •

www.ajpcell.org

Themes C1284

ION CHANNELS AND CANCER

resistance cells, on the other hand, had almost no AVD process and VSOR Cl⫺ current when treated with cisplatin. Treatment of A549/CDDP cells with TSA, partially restored the VSOR Cl⫺ current and increased cisplatin-induced cell apoptosis rate. These results suggest that impaired activity of VSOR Cl⫺ channels contributes to the cisplatin resistance in lung cancer. Furthermore, cyclosporin A (CsA) induces apoptosis in a dose- and time-dependent manner in HepG2 human hepatoma cells (42). It induced also Cl⫺ efflux, which was significantly blocked by niflumic acid (NA), a specific inhibitor. CsA increased intracellular Ca2⫹ concentration, and treatment with BAPTA/AM, an intracellular Ca2⫹ chelator, significantly inhibited the CsA-induced Cl⫺ efflux, indicating that CsA induced Cl⫺ efflux through the activation of calcium-activated chloride channels. Their inhibition with niflumic acid (NA), flufenamic acid (FA), 5-nitro-2-(3-phenylpropylamino) benzoic acid (NPPB), and DIDS markedly prevented the CsAinduced apoptosis suggesting that these channels may mediate apoptosis induced by CsA in HepG2 cells (42). The transition of cancer cells to apoptosis-resistant phenotypes is associated with an increased capability for RVD, or the restoration of cell volume in response to hypoosmotic stress, because of the enhanced expression of VRACs. The latter, at least in some cell types, can involve ClC-3 (47, 48), a member of the ClC family, which is mostly known to function as endosomal Cl⫺/H⫹ exchanger but can also function as PM Cl⫺ channel. Consistent with this, the overexpression of ClC-3 in human bronchial epithelial cells (HBECs) has been reported to inhibit transforming growth factor-␤ (TGF-␤)-induced apoptosis (12). Owing to its preferential targeting to intracellular compartments and Cl⫺/H⫹ exchanger function, the excess of ClC-3 was also found to increase the acidity of intracellular vesicles in NE tumor cell lines (BON, LCC-18, and QGP-1), thereby enhancing their resistance to the chemotherapeutic drug etoposide by almost twofold (85). Because these cells seemed to be deficient in common multidrug resistance transporters, the mechanism of enhanced drug resistance to etoposide was attributed to the ClC-3-mediated vesicular acidification, which represents a facilitating factor in vesicular drug sequestration.

channels (SOC). The common physiological trigger for the activation of these channels is inositol trisphosphate-(IP3)induced Ca2⫹ release from the ER in response to the stimulation of surface receptors coupled to the phospholipase C(PLC)-catalyzed inositol phospholipid breakdown signaling pathway. This is why, when these channels have been identified for the first time by patch-clamp experiments, they were termed “Ca2⫹ release-activated channels” (CRAC) (38). To effectively avoid apoptosis, cancer cells must utilize mechanisms that substantially reduce or even prevent Ca2⫹ influx, for example by downregulating the expression of Ca2⫹permeable channels or the signaling pathways that lead to their activation. Consistent with this, hormone-refractory apoptosisresistant phenotypes of hormone refractory cancer cells are characterized by markedly reduced levels of store-operated calcium entry (67, 80, 81), which prevents Ca2⫹ overload in response to pro-apoptotic stimuli, thereby reducing the effectiveness of mitochondrial and cytoplasmic apoptotic pathways. In this respect, it is important to assess the role of STIM1 and CRACM1 (Orai1) proteins in cancer cell SOCE. The first work on Orai1 involvement in apoptosis has shown that Orai1 protein represents the major molecular component of endogenous store-operated Ca2⫹ entry in human prostate cancer cells and constitutes the principal source of Ca2⫹ influx used by the cell to trigger apoptosis (23). The downregulation of Orai1, and consequently SOCE, protects the cells from diverse apoptosisinducing pathways, such as those induced by thapsigargin (Tg), TNF-␣, and cisplatin/oxaliplatin. The transfection of Orai1 mutants such as R91W, a selectivity mutant, and L273S, a coiled-coil mutant, into the cells significantly decreased both SOCE and the rate of Tg-induced apoptosis. This suggests that the functional coupling of STIM1 to Orai1, as well as Orai1 Ca2⫹ selectivity as a channel, is required for its pro-apoptotic effects. Thus Orai1 plays a pivotal role in the triggering of apoptosis, irrespective of apoptosis-inducing stimuli, and in the establishment of an apoptosis-resistant phenotype in prostate cancer cells (23). Thus the decrease in SOCE may be responsible for the acquiring of apoptosis-resistant phenotype an important feature of all cancers.

Ca2⫹ Homeostasis and Store-Operated Ca2⫹ Entry Channels

Role of TRP Superfamily of Channels in the Control of Apoptosis

The role of Ca2⫹ in the majority of cell-signaling pathways involved in carcinogenesis is well established. Calcium homeostasis, the consequences of calcium signaling, is an equilibrium between influx, efflux, and storage of Ca2⫹. From a physiological point of view, Ca2⫹ signaling is involved in the manifestation of cell phenotype, proliferation, differentiation, apoptosis, and in cellular activities such as contraction or secretion or cell excitability. Thus each cellular phenotype, whether normal or pathological, is characterized by a particular “calcium signature” reflecting its kinetics, amplitude, and subcellular localization of the calcium signals. In cancer epithelial cells, as in other nonexcitable cell types, Ca2⫹ entry from extracellular space is mainly supported by the “capacitative calcium entry” mechanism, also known as “storeoperated calcium entry” (SOCE) (62). This mechanism is capable of monitoring ER Ca2⫹ filling, enabling influx only when ER content is essentially decreased. It is mediated via specialized plasma membrane store-operated Ca2⫹-permeable

In recent years, some members of the widely investigated family of mammalian homologs of the Drosophila transient receptor potential (TRP) channel were viewed as being involved in SOC formation (for recent reviews see Refs. 62 and 68). In the studies conducted on prostate cancer LNCaP cells the involvement of the members of the “canonical” TRP subfamily TRPC1 and TRPC4 in prostate-specific endogenous SOCs has been suggested (78, 79). However, the expression pattern of TRPC1 and TRPC4 was not modified in androgenindependent apoptosis-resistant prostate cancer cells (79). Interestingly, the endogenous expression of TRPC1, TRPC3, and TRPV6 proteins in prostate cancer cells was shown to be controlled by the ER Ca2⫹ filling: after a prolonged (24 – 48 h) depletion of the stores with Tg, a potent proapoptotic agent, their expression increased (64). Enhanced expression of apparently store-dependent TRP members after prolonged ER store depletion is difficult to reconcile with the findings that androgen-independent, apoptosis-resistant prostate cancer cell phe-

AJP-Cell Physiol • VOL

301 • DECEMBER 2011 •

www.ajpcell.org

Themes C1285

ION CHANNELS AND CANCER

notypes, for which chronic underfilling of the ER Ca2⫹ pool represents a new level of equilibrium helping them to withstand ER stress-mediated apoptosis, are characterized by reduced SOCE (80, 81). It is, therefore, likely that native SOC in cancer cells is a much more complex entity, whose functional expression cannot be directly correlated with any of the implicated TRP members. Cold/menthol-sensitive TRPM8 of the “melastatin” TRP subfamily is yet another TRP member that has recently emerged as an important player in normal and pathological development of different tissues. TRPM8 is expressed not only in the plasma membrane of prostate cells, as initially anticipated, but also in the ER membrane, where it operates as an ER Ca2⫹ release channel involved in the activation of SOCE in response to cold/menthol stimulus also known to induce apoptosis (76, 93). Moreover, whereas remaining at moderate levels in a normal prostate, TRPM8 expression strongly increases in prostate cancer, suggesting that the channel is a pro-oncogenic actor in these cells (77). Other nonprostatic primary human tumors (breast, colon, lung, and skin) are also known to become highly enriched in TRPM8, although it is virtually undetectable in corresponding normal tissues (77). Thus even this initial information strongly pointed to much broader roles of TRPM8 beyond cold sensation, especially during carcinogenesis. In another cancer model, it was shown that menthol can induce mitochondrial membrane depolarization via the TRPM8 channel in cells of the human bladder cancer cell line T24, resulting in cell death; however, the precise mechanism of action of menthol in bladder cancer remains unknown (49). The activity of a member of the “vanilloid” TRP subfamily, TRPV6, may also have some relation to the sequence of events following the ER store depletion in LNCaP cells, as its antisense knockout decreases endogenous store-operated membrane current (ISOC) (79), but the mechanisms underlying such TRPV6 activation in LNCaP cells remain elusive.In 2007 Lehen’kyi et al. (46) published the direct implication of TRPV6 channel in apoptosis resistance of hormone-sensitive

prostate cancer cells that may be mediated by activation of NFaT transcription factor. However, the precise mechanism of TRPV6 contribution to apoptosis resistance remains unknown. Another member of vanilloid family TRPV2 has also been suggested to contribute to apoptosis resistance of androgenindependent prostate cancer cell lines, likely by augmenting Ca2⫹-influx into these cells (55). Although, such its regulatory effect is not universal, since in human urothelial carcinoma cells the regulation of calcium influx through these channels leads directly to the death of these cells (91). Decreased levels of the expression of Ca2⫹-permeable channels with activation mechanisms other than store depletion also contribute to the ability of cancer cells to escape apoptosis. For instance, the antisense knockdown of TRPM2 (an endogenous ADP-ribose-sensitive, cADP-ribose-sensitive, and H2O2-sensitive TRP member) in rat insulinoma RIN-5F cells and the U937 monocyte cell line has been shown to significantly suppress Ca2⫹ influx and cell death induced by H2O2 and TNF-␣, whereas the heterologous overexpression of this channel enhanced H2O2-induced apoptosis (35). Unexpectedly, the lack of the TRPV6 channel, rather than of the capsaicin receptor TRPV1, was found to suppress apoptosis of gastric cancer cells under capsaicin treatment (13). Although in urothelial cancer cells activation of TRPV1 channel directly triggers apoptosis via Fas/CD95-mediated intrinsic and extrinsic apoptotic pathways (3). At the same time, the functional knockout of TRPM2, as well as overexpression of wild-type TRPM2, increased melanoma susceptibility to apoptosis and necrosis (59). The superfamily of TRP channels represents a relatively new division of Ca2⫹-permeable channels particularly involved in the control of calcium influx participating in apoptosis machinery. Sufficient evidence has been collected to date to definitively implicate these channels in the apoptosis control performed by cancer cell. TRP channels, therefore, represent a substantial field of study of apoptosis presenting TRP channels as prospective pharmaceutical targets.

Fig. 2. Scheme summarizing the principal interplay between the K⫹-, Ca2⫹- and Cl⫺-permeable channels and downstream mechanisms regulating cell survival or death. Light blue arrows indicate the flow of Ca2⫹ or its effect on the respective Ca2⫹-sensitive agents triggering the downstream mechanisms. Thick light green arrow indicates the flow of K⫹ and Cl⫺, triggering common modes of response in the cells. The downstream effects are indicated by black arrows and lead to eventual pro-apoptotic or proproliferative cell development.

AJP-Cell Physiol • VOL

301 • DECEMBER 2011 •

www.ajpcell.org

Themes C1286

ION CHANNELS AND CANCER

Voltage-Gated Calcium Channels The involvement of voltage-gated Ca2⫹ channels (VGCC) in regulating balance between proliferation and apoptosis in the cell has been known since at least the 1980s. Thus it was known that the percentage of epithelial rat ventral prostate cells undergoing apoptosis in response to androgen ablation is reduced by administering voltage-gated Ca2⫹ channel VGCC blockers such as nifedipine and verapamil (14, 52). These observations gave rise to the hypothesis that calcium channel blockers may increase the risk of prostate cancer by inhibiting calcium signal-mediated apoptosis (4). Despite this evidence, the presence of VGCC activity has not been detected in cancer epithelial cells by means of electrophysiology. On the other hand, evidence has been presented showing that the small proportion of undifferentiated LNCaP cells display an LVA Ca2⫹ current carried by T-type Ca2⫹ channels, as well as the significantly increased current density during the neuroendocrine differentiation of LNCaP cells induced by either long-term treatments with membranepermeable cAMP analogs or by steroid-deprived culture medium (51). RT-PCR experiments demonstrated that only

mRNA for Cav3.2 isoform of T-type Ca2⫹ channel 1 subunit is expressed in LNCaP cells and becomes highly elevated during NE differentiation (51). It was also shown that basal Ca2⫹ entry through this channel at resting membrane potential due to the presence of a prominent “window current” is likely to facilitate neurite elongation, thereby promoting neuroendocrine differentiation. It was suggested that this channel could be also involved in the stimulation of mitogenic factor secretion, thus representing an attractive potential target for future therapeutic strategies (27, 51). However, whether or not these channels contribute to the enhanced antiapoptotic potential of apoptosis-resistant cells is not yet clear. Metabotropic Channels and Cancer Cell Apoptosis In 1990, Maneckjee and Minna (50) described the presence of ␣7-nAChR (nicotinic acetylcholine receptor) on small and nonsmall lung cancer cell lines. More recently, Lam et al. (43) suggested that nAChRs play a significant role in lung cancer predisposition and natural history. Furthermore, an important study of Song et al. (74) presented data that small cell lung cancer express a cholinergic autocrine loop that can regulate

Table 1. Ion channel involved in apoptosis Family, Ion Selectivity

Subfamily

Cys-loop, cationic Ca2⫹-permeable Purinergic, cationic Ca2⫹-permeable

nAChR P2X

Voltage-gated Na⫹ (Nav)

Nav1

Voltage-gated Ca2⫹ (Cav)

Cav1 (L-type) Cav2 Cav3 (T-type)

Voltage-gated K⫹ (Kv)

K v1 Kv10 Kv11

Ca2⫹-activated K⫹ (KCa) Inwardly rectifying K⫹ (Kir) Background K⫹ (K2P) SOC, Ca2⫹-selective TRP, cationic Ca2⫹-permeable

KCa1 (BKCa) KCa2 (SKCa) KCa3 (IKCa) Kir3 (GIRK, G protein-acti-vated) Kir3 (KATP, ATP-dependent) K2P2 K2P9 Orai/STIM TRPC

TRPV TRPM

Na⫹ nonvoltage-gated, DEG-related

ENaC ASIC

Cl- channels

ClC VRAC

IUPHAR Name, Other Names

Role in Apoptosis

␣7 P2X5/11 P2X7 Nav1.5, h1, skm II, cardiac sodium channel Nav1.7, PN1, hNE-Na, Nas4 Subunits are ND Cav2.3, ␣1E, R-type Cav3.1, ␣1G Cav3.2, ␣1H Kv1.5, HpCN1, HK2, HCK1, KV1, fHK, RK3, RMK2, HuK Kv10.1, EagI, KCNH1, ether-a-go-go Kv11.1, Erg1, HERG, human ether-a-gogo-related gene KCa1.1, BK, Slo, Slo1, maxi K KCa2.3, SK3, SKCa3 KCa3.1, IK1, IKCa3, SK41 Kir3.1, GIRK1, KGA Kir6.1, uKATP-1 K2P2.1, TREK-1, KCNK2, TPKC1 K2P9.1, TASK-3, KCNK9 Orai1/STIM1 TRPC1, TRP1 TRPC3, TRP3 TRPC4, TRP1, CCE2 TRPC6, TRP1 TRPV1, VR1, OTRPC1 TRPV6, ECaC, Cat1, Cat-L TRPM1, MLSN1 TRPM2, TRPC7, LTRPC2, KNP3, EREG1 TRPM7, TRP-PLIK, LTRPC7, ChaK(1) TRPM8, Trp-p8, CMR1, LTrpC6 ENaC␣ ENaC␥ ASIC1, ASIC ASIC2, MDEG ClC-3 ClC-3 (?)

ND ND 2Apoptosis resistance 1Apoptosis resistance 1Apoptosis resistance ND ND ND 1Apoptosis resistance 2Apoptosis resistance 1Apoptosis resistance ND 1Apoptosis resistance ND 1Apoptosis resistance ND ND ND 2Increased survival 2Apoptosis resistance 1Apoptosis resistance ND ND ND 1Apoptosis resistance ND 2Apoptosis resistance ND ND ND ND ND ND 1Apoptosis resistance 1Apoptosis resistance

The table lists ion channel subunits, for which the involvement in apoptosis has been established. IUPHAR names of subunits along with other names found in the literature are underlined. Upward arrow and downward arrow indicate increase or decrease in channel expression or functional activity and the acquired specified effect, respectfully; ND, not determined. Question mark depicts controversial results. See text for additional information and definition of abbreviations. AJP-Cell Physiol • VOL

301 • DECEMBER 2011 •

www.ajpcell.org

Themes ION CHANNELS AND CANCER

cell growth and lead to the ihibition of drug-induced apoptosis. The results of other studies showed that ␣-CbT, a powerful high affinity ␣7-nAChR inhibitor, induces antitumor effects against nonsmall cell lung cancer and malignant pleural mesothelioma by triggering apoptosis (61). The probable mechanism of nAChRs-induced apoptosis resistance likely lies in the activation of PI3K/AKT that directly phosphorylates and inactivates the pro-apoptotic function of Bax (88) and upregulation of nuclear factor-␬B (16). It has also been demonstrated that the activation of purinoreceptors, such as P2X, by ATP leads to apoptosis of hormonerefractory PC3 cells (10), though the mechanisms remain obscure. The reason may be that extracellular ATP induces the activation of multiple caspases including caspase-1, -3, and -8, required for apoptotic but not necrotic alterations of ATPinduced cell death shown for myeloma (21). Another metabotropic receptor, glycine receptor (GlyR) ␣1 subunit GLRA1 contains in its gene a sequence motif for neuron-restrictive silencer factor (NRSF) binding protein within its 5=-UTR (56). While no GLRA1 transcripts were found in the majority of nonmalignant biopsies, the GLRA1 transcripts were detected in the majority of small lung cancer cells (31). The authors showed that the reconstitution of NRSF expression induced apoptosis in lung cancer cells via the inhibition of GlyR receptor suggesting its role in apoptosis resistance. Conclusions Ion channels are known to play an important role in regulation of balance between apoptosis and proliferation in the cells. Recent reports clearly show their involvement in triggering the onset of apoptosis or even progression of cancer cell toward apoptosis-resistant phenotype. The dual role that some of them play due to their permeability to both calcium and potassium is especially interesting and is often explained as a part of the particular cancer model and the triggered downstream events. Generally, the emergence of more excitable phenotype by the reexpression of voltage-gated sodium channels and decrease in potassium efflux is a characteristic feature of advanced stage of cancer. As for the calcium, its dual role strongly depends on particular calcium signature within the cell: the transit oscillations or sustained increase, the involvement of ER or mitochondria, and the constitutive or storeoperated entry. The increased expression of chloride channels is accompanied by the enhanced ability of cancer cell to regulate its volume and resist to apoptosis and even to contribute to chemoresistance of some cancers. General interplay between the ion channels and their effectors is briefly summarized in Fig. 2, and the overview of the involved ion channels can be found in Table 1. Given the obviously important role of ion channels in cancer development and progression and the growing evidences on their role therein, further investigations are still needed to better elucidate their role in apoptosis regulating mechanisms and to elaborate the ion channels as effective discriminative markers and therapeutic targets in foreseeable future. DISCLOSURES No conflicts of interest, financial or otherwise, are declared by the author(s). AJP-Cell Physiol • VOL

C1287

REFERENCES 1. Abdul M, Hoosein N. Voltage-gated sodium ion channels in prostate cancer: expression and activity. Anticancer Res 22: 1727–1730, 2002. 2. Abrahamsson PA. Neuroendocrine cells in tumour growth of the prostate. Endocrine Relat Cancer 6: 503–519, 1999. 3. Amantini C, Ballarini P, Caprodossi S, Nabissi M, Morelli MB, Lucciarini R, Cardarelli MA, Mammana G, Santoni G. Triggering of transient receptor potential vanilloid type 1 (TRPV1) by capsaicin induces Fas/CD95-mediated apoptosis of urothelial cancer cells in an ATMdependent manner. Carcinogenesis 30: 1320 –1329, 2009. 4. Anderson JD, Hansen TP, Lenkowski PW, Walls AM, Choudhury IM, Schenck HA, Friehling M, Holl GM, Patel MK, Sikes RA, Brown ML. Voltage-gated sodium channel blockers as cytostatic inhibitors of the androgen-independent prostate cancer cell line PC-3. Mol Cancer Ther 2: 1149 –1154, 2003. 5. Bennett ES, Smith BA, Harper JM. Voltage-gated Na⫹ channels confer invasive properties on human prostate cancer cells. Pflügers Arch 447: 908 –914, 2004. 6. Bonkhoff H. Neuroendocrine differentiation in human prostate cancer. Morphogenesis, proliferation and androgen receptor status. Ann Oncol 12, Suppl 2: S141–S144, 2001. 7. Bonnet S, Archer SL, Allalunis-Turner J, Haromy A, Beaulieu C, Thompson R, Lee CT, Lopaschuk GD, Puttagunta L, Bonnet S, Harry G, Hashimoto K, Porter CJ, Andrade MA, Thebaud B, Michelakis ED. A mitochondria-K⫹ channel axis is suppressed in cancer and its normalization promotes apoptosis and inhibits cancer growth. Cancer Cell 11: 37–51, 2007. 8. Bortner CD, Gomez-Angelats M, Cidlowski JA. Plasma membrane depolarization without repolarization is an early molecular event in antiFas-induced apoptosis. J Biol Chem 276: 4304 –4314, 2001. 9. Burg ED, Remillard CV, Yuan JX. K⫹ channels in apoptosis. J Membr Biol 209: 3–20, 2006. 10. Calvert RC, Shabbir M, Thompson CS, Mikhailidis DP, Morgan RJ, Burnstock G. Immunocytochemical and pharmacological characterisation of P2-purinoceptor-mediated cell growth and death in PC-3 hormone refractory prostate cancer cells. Anticancer Res 24: 2853–2859, 2004. 11. Chaffer CL, Weinberg RA. A perspective on cancer cell metastasis. Science 331: 1559 –1564. 12. Cheng G, Shao Z, Chaudhari B, Agrawal DK. Involvement of chloride channels in TGF-beta1-induced apoptosis of human bronchial epithelial cells. Am J Physiol Lung Cell Mol Physiol 293: L1339 –L1347, 2007. 13. Chow J, Norng M, Zhang J, Chai J. TRPV6 mediates capsaicin-induced apoptosis in gastric cancer cells–Mechanisms behind a possible new “hot” cancer treatment. Biochim Biophys Acta 1773: 565–576, 2007. 14. Connor J, Sawczuk IS, Benson MC, Tomashefsky P, O’Toole KM, Olsson CA, Buttyan R. Calcium channel antagonists delay regression of androgen-dependent tissues and suppress gene activity associated with cell death. Prostate 13: 119 –130, 1988. 15. Danial NN, Korsmeyer SJ. Cell death: critical control points. Cell 116: 205–219, 2004. 16. Dasgupta P, Rastogi S, Pillai S, Ordonez-Ercan D, Morris M, Haura E, Chellappan S. Nicotine induces cell proliferation by beta-arrestinmediated activation of Src and Rb-Raf-1 pathways. J Clin Invest 116: 2208 –2217, 2006. 17. di Sant’Agnese PA. Neuroendocrine differentiation in prostatic carcinoma: an update. Prostate Suppl 8: 74 –79, 1998. 18. Diss JK, Archer SN, Hirano J, Fraser SP, Djamgoz MB. Expression profiles of voltage-gated Na(⫹) channel alpha-subunit genes in rat and human prostate cancer cell lines. Prostate 48: 165–178, 2001. 19. Elble RC, Pauli BU. Tumor suppression by a proapoptotic calciumactivated chloride channel in mammary epithelium. J Biol Chem 276: 40510 –40517, 2001. 20. Fernandez-Salas E, Suh KS, Speransky VV, Bowers WL, Levy JM, Adams T, Pathak KR, Edwards LE, Hayes DD, Cheng C, Steven AC, Weinberg WC, Yuspa SH. mtCLIC/CLIC4, an organellular chloride channel protein, is increased by DNA damage and participates in the apoptotic response to p53. Mol Cell Biol 22: 3610 –3620, 2002. 21. Ferrari D, Los M, Bauer MK, Vandenabeele P, Wesselborg S, Schulze-Osthoff K. P2Z purinoreceptor ligation induces activation of caspases with distinct roles in apoptotic and necrotic alterations of cell death. FEBS Lett 447: 71–75, 1999.

301 • DECEMBER 2011 •

www.ajpcell.org

Themes C1288

ION CHANNELS AND CANCER

22. Fixemer T, Remberger K, Bonkhoff H. Apoptosis resistance of neuroendocrine phenotypes in prostatic adenocarcinoma. Prostate 53: 118 – 123, 2002. 23. Flourakis M, Lehen’kyi V, Beck B, Raphael M, Vandenberghe M, Abeele FV, Roudbaraki M, Lepage G, Mauroy B, Romanin C, Shuba Y, Skryma R, Prevarskaya N. Orai1 contributes to the establishment of an apoptosis-resistant phenotype in prostate cancer cells. Cell Death Dis 1: e75. 24. Fraser SP, Salvador V, Manning EA, Mizal J, Altun S, Raza M, Berridge RJ, Djamgoz MB. Contribution of functional voltage-gated Na⫹ channel expression to cell behaviors involved in the metastatic cascade in rat prostate cancer: I. Lateral motility. J Cell Physiol 195: 479 –487, 2003. 25. Fulgenzi G, Graciotti L, Faronato M, Soldovieri MV, Miceli F, Amoroso S, Annunziato L, Procopio A, Taglialatela M. Human neoplastic mesothelial cells express voltage-gated sodium channels involved in cell motility. Int J Biochem Cell Biol 38: 1146 –1159, 2006. 26. Furst J, Gschwentner M, Ritter M, Botta G, Jakab M, Mayer M, Garavaglia L, Bazzini C, Rodighiero S, Meyer G, Eichmuller S, Woll E, Paulmichl M. Molecular and functional aspects of anionic channels activated during regulatory volume decrease in mammalian cells. Pflügers Arch 444: 1–25, 2002. 27. Gackiere F, Bidaux G, Delcourt P, Van Coppenolle F, Katsogiannou M, Dewailly E, Bavencoffe A, Van Chuoi-Mariot MT, Mauroy B, Prevarskaya N, Mariot P. CaV3.2 T-type calcium channels are involved in calcium-dependent secretion of neuroendocrine prostate cancer cells. J Biol Chem 283: 10162–10173, 2008. 28. Gao R, Shen Y, Cai J, Lei M, Wang Z. Expression of voltage-gated sodium channel alpha subunit in human ovarian cancer. Oncol Rep 23: 1293–1299. 29. Gilbert MS, Saad AH, Rupnow BA, Knox SJ. Association of BCL-2 with membrane hyperpolarization and radioresistance. J Cell Physiol 168: 114 –122, 1996. 30. Gregory CD, Pound JD. Cell death in the neighbourhood: direct microenvironmental effects of apoptosis in normal and neoplastic tissues. J Pathol 223: 177–194, 2011. 31. Gurrola-Diaz C, Lacroix J, Dihlmann S, Becker CM, von Knebel Doeberitz M. Reduced expression of the neuron restrictive silencer factor permits transcription of glycine receptor alpha1 subunit in small-cell lung cancer cells. Oncogene 22: 5636 –5645, 2003. 32. Han X, Wang F, Yao W, Xing H, Weng D, Song X, Chen G, Xi L, Zhu T, Zhou J, Xu G, Wang S, Meng L, Iadecola C, Wang G, Ma D. Heat shock proteins and p53 play a critical role in K⫹ channel-mediated tumor cell proliferation and apoptosis. Apoptosis 12: 1837–1846, 2007. 33. Han Y, Shi Y, Han Z, Sun L, Fan D. Detection of potassium currents and regulation of multidrug resistance by potassium channels in human gastric cancer cells. Cell Biol Int 31: 741–747, 2007. 34. Hanahan D, Weinberg RA. Hallmarks of cancer: the next generation. Cell 144: 646 –674, 2011. 35. Hara Y, Wakamori M, Ishii M, Maeno E, Nishida M, Yoshida T, Yamada H, Shimizu S, Mori E, Kudoh J, Shimizu N, Kurose H, Okada Y, Imoto K, Mori Y. LTRPC2 Ca2⫹-permeable channel activated by changes in redox status confers susceptibility to cell death. Mol Cell 9: 163–173, 2002. 36. Hengartner MO. The biochemistry of apoptosis. Nature 407: 770 –776, 2000. 37. Hotchkiss RS, Strasser A, McDunn JE, Swanson PE. Cell death. N Engl J Med 361: 1570 –1583, 2009. 38. Hoth M, Penner R. Depletion of intracellular calcium stores activates a calcium current in mast cells. Nature 355: 353–356, 1992. 39. July LV, Akbari M, Zellweger T, Jones EC, Goldenberg SL, Gleave ME. Clusterin expression is significantly enhanced in prostate cancer cells following androgen withdrawal therapy. Prostate 50: 179 –188, 2002. 40. Kerr JF, Wyllie AH, Currie AR. Apoptosis: a basic biological phenomenon with wide-ranging implications in tissue kinetics. Br J Cancer 26: 239 –257, 1972. 41. Kim JA, Kang YS, Jung MW, Kang GH, Lee SH, Lee YS. Ca2⫹ influx mediates apoptosis induced by 4-aminopyridine, a K⫹ channel blocker, in HepG2 human hepatoblastoma cells. Pharmacology 60: 74 –81, 2000. 42. Kim JA, Kang YS, Lee YS. Role of Ca2⫹-activated Cl⫺ channels in the mechanism of apoptosis induced by cyclosporin A in a human hepatoma cell line. Biochem Biophys Res Commun 309: 291–297, 2003. 43. Lam DC, Girard L, Ramirez R, Chau WS, Suen WS, Sheridan S, Tin VP, Chung LP, Wong MP, Shay JW, Gazdar AF, Lam WK, Minna AJP-Cell Physiol • VOL

44.

45.

46.

47.

48.

49.

50.

51.

52. 53.

54.

55.

56.

57.

58.

59.

60. 61.

62. 63.

64.

JD. Expression of nicotinic acetylcholine receptor subunit genes in nonsmall-cell lung cancer reveals differences between smokers and nonsmokers. Cancer Res 67: 4638 –4647, 2007. Lang F, Foller M, Lang KS, Lang PA, Ritter M, Gulbins E, Vereninov A, Huber SM. Ion channels in cell proliferation and apoptotic cell death. J Membr Biol 205: 147–157, 2005. Lee EL, Shimizu T, Ise T, Numata T, Kohno K, Okada Y. Impaired activity of volume-sensitive Cl- channel is involved in cisplatin resistance of cancer cells. J Cell Physiol 211: 513–521, 2007. Lehen’kyi V, Flourakis M, Skryma R, Prevarskaya N. TRPV6 channel controls prostate cancer cell proliferation via Ca(2⫹)/NFAT-dependent pathways. Oncogene 26: 7380 –7385, 2007. Lemonnier L, Lazarenko R, Shuba Y, Thebault S, Roudbaraki M, Lepage G, Prevarskaya N, Skryma R. Alterations in the regulatory volume decrease (RVD) and swelling-activated Cl- current associated with neuroendocrine differentiation of prostate cancer epithelial cells. Endocr Relat Cancer 12: 335–349, 2005. Lemonnier L, Shuba Y, Crepin A, Roudbaraki M, Slomianny C, Mauroy B, Nilius B, Prevarskaya N, Skryma R. Bcl-2-dependent modulation of swelling-activated Cl- current and ClC-3 expression in human prostate cancer epithelial cells. Cancer Res 64: 4841–4848, 2004. Li Q, Wang X, Yang Z, Wang B, Li S. Menthol induces cell death via the TRPM8 channel in the human bladder cancer cell line T24. Oncology 77: 335–341, 2009. Maneckjee R, Minna JD. Opioid and nicotine receptors affect growth regulation of human lung cancer cell lines. Proc Natl Acad Sci USA 87: 3294 –3298, 1990. Mariot P, Vanoverberghe K, Lalevee N, Rossier MF, Prevarskaya N. Overexpression of an alpha 1H (Cav3.2) T-type calcium channel during neuroendocrine differentiation of human prostate cancer cells. J Biol Chem 277: 10824 –10833, 2002. Martikainen P, Isaacs J. Role of calcium in the programmed death of rat prostatic glandular cells. Prostate 17: 175–187, 1990. Meuth SG, Herrmann AM, Ip CW, Kanyshkova T, Bittner S, Weishaupt A, Budde T, Wiendl H. The two-pore domain potassium channel TASK3 functionally impacts glioma cell death. J Neurooncol 87: 263–270, 2008. Min XJ, Li H, Hou SC, He W, Liu J, Hu B, Wang J. Dysfunction of volume-sensitive chloride channels contributes to cisplatin resistance in human lung adenocarcinoma cells. Exp Biol Med (Maywood) 236: 483– 491, 2011. Monet M, Lehen’kyi V, Gackiere F, Firlej V, Vandenberghe M, Roudbaraki M, Gkika D, Pourtier A, Bidaux G, Slomianny C, Delcourt P, Rassendren F, Bergerat JP, Ceraline J, Cabon F, Humez S, Prevarskaya N. Role of cationic channel TRPV2 in promoting prostate cancer migration and progression to androgen resistance. Cancer Res 70: 1225–1235, 2010. Neumann SB, Seitz R, Gorzella A, Heister A, Doeberitz MK, Becker CM. Relaxation of glycine receptor and onconeural gene transcription control in NRSF deficient small cell lung cancer cell lines. Brain Res Mol Brain Res 120: 173–181, 2004. Okada Y, Shimizu T, Maeno E, Tanabe S, Wang X, Takahashi N. Volume-sensitive chloride channels involved in apoptotic volume decrease and cell death. J Membr Biol 209: 21–29, 2006. Onkal R, Djamgoz MB. Molecular pharmacology of voltage-gated sodium channel expression in metastatic disease: clinical potential of neonatal Nav1.5 in breast cancer. Eur J Pharmacol 625: 206 –219, 2009. Orfanelli U, Wenke AK, Doglioni C, Russo V, Bosserhoff AK, Lavorgna G. Identification of novel sense and antisense transcription at the TRPM2 locus in cancer. Cell Res 18: 1128 –1140, 2008. Orrenius S, Zhivotovsky B, Nicotera P. Regulation of cell death: the calcium-apoptosis link. Nat Rev Mol Cell Biol 4: 552–565, 2003. Paleari L, Negri E, Catassi A, Cilli M, Servent D, D’Angelillo R, Cesario A, Russo P, Fini M. Inhibition of nonneuronal alpha7-nicotinic receptor for lung cancer treatment. Am J Respir Crit Care Med 179: 1141–1150, 2009. Parekh AB, Putney JW Jr. Store-operated calcium channels. Physiol Rev 85: 757–810, 2005. Pei L, Wiser O, Slavin A, Mu D, Powers S, Jan LY, Hoey T. Oncogenic potential of TASK3 (Kcnk9) depends on K⫹ channel function. Proc Natl Acad Sci USA 100: 7803–7807, 2003. Pigozzi D, Ducret T, Tajeddine N, Gala JL, Tombal B, Gailly P. Calcium store contents control the expression of TRPC1, TRPC3 and

301 • DECEMBER 2011 •

www.ajpcell.org

Themes ION CHANNELS AND CANCER

65.

66. 67.

68. 69. 70.

71. 72. 73.

74.

75.

76.

77.

78.

TRPV6 proteins in LNCaP prostate cancer cell line. Cell Calcium 39: 401–415, 2006. Pinton P, Giorgi C, Siviero R, Zecchini E, Rizzuto R. Calcium and apoptosis: ER-mitochondria Ca2⫹ transfer in the control of apoptosis. Oncogene 27: 6407–6418, 2008. Plati J, Bucur O, Khosravi-Far R. Apoptotic cell signaling in cancer progression and therapy. Integr Biol (Camb) 3: 279 –296, 2011. Prevarskaya N, Skryma R, Shuba Y. Ca2⫹ homeostasis in apoptotic resistance of prostate cancer cells. Biochem Biophys Res Commun 322: 1326 –1335, 2004. Ramsey IS, Delling M, Clapham DE. An introduction to TRP channels. Annu Rev Physiol 68: 619 –647, 2006. Razik MA, Cidlowski JA. Molecular interplay between ion channels and the regulation of apoptosis. Biol Res 35: 203–207, 2002. Remillard CV, Yuan JX. Activation of K⫹ channels: an essential pathway in programmed cell death. Am J Physiol Lung Cell Mol Physiol 286: L49 –67, 2004. Roselli F, Livrea P, Jirillo E. Voltage-gated sodium channel blockers as immunomodulators. Recent Pat CNS Drug Discov 1: 83–91, 2006. Schonherr R. Clinical relevance of ion channels for diagnosis and therapy of cancer. J Membr Biol 205: 175–184, 2005. Shen MR, Yang TP, Tang MJ. A novel function of BCL-2 overexpression in regulatory volume decrease. Enhancing swelling-activated Ca(2⫹) entry and Cl(⫺) channel activity. J Biol Chem 277: 15592–15599, 2002. Song P, Sekhon HS, Jia Y, Keller JA, Blusztajn JK, Mark GP, Spindel ER. Acetylcholine is synthesized by and acts as an autocrine growth factor for small cell lung carcinoma. Cancer Res 63: 214 –221, 2003. Suh KS, Mutoh M, Gerdes M, Crutchley JM, Mutoh T, Edwards LE, Dumont RA, Sodha P, Cheng C, Glick A, Yuspa SH. Antisense suppression of the chloride intracellular channel family induces apoptosis, enhances tumor necrosis factor ␣-induced apoptosis, and inhibits tumor growth. Cancer Res 65: 562–571, 2005. Thebault S, Lemonnier L, Bidaux G, Flourakis M, Bavencoffe A, Gordienko D, Roudbaraki M, Delcourt P, Panchin Y, Shuba Y, Skryma R, Prevarskaya N. Novel role of cold/menthol-sensitive transient receptor potential melastatine family member 8 (TRPM8) in the activation of store-operated channels in LNCaP human prostate cancer epithelial cells. J Biol Chem 280: 39423–39435, 2005. Tsavaler L, Shapero MH, Morkowski S, Laus R. Trp-p8, a novel prostate-specific gene, is up-regulated in prostate cancer and other malignancies and shares high homology with transient receptor potential calcium channel proteins. Cancer Res 61: 3760 –3769, 2001. Vanden Abeele F, Lemonnier L, Thebault S, Lepage G, Parys JB, Shuba Y, Skryma R, Prevarskaya N. Two types of store-operated Ca2⫹ channels with different activation modes and molecular origin in LNCaP human prostate cancer epithelial cells. J Biol Chem 279: 30326 –30337, 2004.

AJP-Cell Physiol • VOL

C1289

79. Vanden Abeele F, Shuba Y, Roudbaraki M, Lemonnier L, Vanoverberghe K, Mariot P, Skryma R, Prevarskaya N. Store-operated Ca2⫹ channels in prostate cancer epithelial cells: function, regulation, and role in carcinogenesis. Cell Calcium 33: 357–373, 2003. 80. Vanden Abeele F, Skryma R, Shuba Y, Van Coppenolle F, Slomianny C, Roudbaraki M, Mauroy B, Wuytack F, Prevarskaya N. Bcl-2dependent modulation of Ca(2⫹) homeostasis and store-operated channels in prostate cancer cells. Cancer Cell 1: 169 –179, 2002. 81. Vanoverberghe K, Vanden Abeele F, Mariot P, Lepage G, Roudbaraki M, Bonnal JL, Mauroy B, Shuba Y, Skryma R, Prevarskaya N. Ca2⫹ homeostasis and apoptotic resistance of neuroendocrine-differentiated prostate cancer cells. Cell Death Differ 11: 321–330, 2004. 82. Wang L, Zhou P, Craig RW, Lu L. Protection from cell death by mcl-1 is mediated by membrane hyperpolarization induced by K(⫹) channel activation. J Membr Biol 172: 113–120, 1999. 83. Wang Z. Roles of K⫹ channels in regulating tumour cell proliferation and apoptosis. Pflügers Arch 448: 274 –286, 2004. 84. Weston RT, Puthalakath H. Endoplasmic reticulum stress and BCL-2 family members. Adv Exp Med Biol 687: 65–77, 2010. 85. Weylandt KH, Nebrig M, Jansen-Rosseck N, Amey JS, Carmena D, Wiedenmann B, Higgins CF, Sardini A. ClC-3 expression enhances etoposide resistance by increasing acidification of the late endocytic compartment. Mol Cancer Ther 6: 979 –986, 2007. 86. Wible BA, Wang L, Kuryshev YA, Basu A, Haldar S, Brown AM. Increased K⫹ efflux and apoptosis induced by the potassium channel modulatory protein KChAP/PIAS3beta in prostate cancer cells. J Biol Chem 277: 17852–17862, 2002. 87. Wyllie AH. “Where, O death, is thy sting?” A brief review of apoptosis biology. Mol Neurobiol 42: 4 –9, 2010. 88. Xin M, Deng X. Nicotine inactivation of the proapoptotic function of Bax through phosphorylation. J Biol Chem 280: 10781–10789, 2005. 89. Xing N, Qian J, Bostwick D, Bergstralh E, Young CY. Neuroendocrine cells in human prostate over-express the anti-apoptosis protein survivin. Prostate 48: 7–15, 2001. 90. Xue Y, Verhofstad A, Lange W, Smedts F, Debruyne F, de la Rosette J, Schalken J. Prostatic neuroendocrine cells have a unique keratin expression pattern and do not express Bcl-2: cell kinetic features of neuroendocrine cells in the human prostate. Am J Pathol 151: 1759 –1765, 1997. 91. Yamada T, Ueda T, Shibata Y, Ikegami Y, Saito M, Ishida Y, Ugawa S, Kohri K, Shimada S. TRPV2 activation induces apoptotic cell death in human T24 bladder cancer cells: a potential therapeutic target for bladder cancer. Urology 76: 509.e1–e7, 2010. 92. Yu SP. Regulation and critical role of potassium homeostasis in apoptosis. Prog Neurobiol 70: 363–386, 2003. 93. Zhang L, Barritt GJ. Evidence that TRPM8 is an androgen-dependent Ca2⫹ channel required for the survival of prostate cancer cells. Cancer Res 64: 8365–8373, 2004.

301 • DECEMBER 2011 •

www.ajpcell.org