K+ pump and mitochondrial Na+ transporters controls glucose-dependent cytosolic and mitochondrial Na+ signals

K+ pump and mitochondrial Na+ transporters controls glucose-dependent cytosolic and mitochondrial Na+ signals

G Model ARTICLE IN PRESS YCECA-1638; No. of Pages 7 Cell Calcium xxx (2014) xxx–xxx Contents lists available at ScienceDirect Cell Calcium journa...

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ARTICLE IN PRESS

YCECA-1638; No. of Pages 7

Cell Calcium xxx (2014) xxx–xxx

Contents lists available at ScienceDirect

Cell Calcium journal homepage: www.elsevier.com/locate/ceca

A crosstalk between Na+ channels, Na+ /K+ pump and mitochondrial Na+ transporters controls glucose-dependent cytosolic and mitochondrial Na+ signals Iulia I. Nita a , Michal Hershfinkel a , Eli C. Lewis b , Israel Sekler a,∗ a b

Department of Physiology and Cell Biology, Faculty of Health Sciences, Ben-Gurion University of the Negev, Beer-Sheva, Israel Department of Clinical Biochemistry and Pharmacology, Faculty of Health Sciences, Ben-Gurion University of the Negev, Beer-Sheva, Israel

a r t i c l e

i n f o

Article history: Received 22 October 2014 Received in revised form 9 December 2014 Accepted 10 December 2014 Available online xxx Keywords: TTX Mitochondrial Na+ /Ca2+ exchanger Ouabain Mitochondrial Na+ /H+ exchanger

a b s t r a c t Glucose-dependent cytosolic Na+ influx in pancreatic islet ␤ cells is mediated by TTX-sensitive Na+ channels and is propagated into the mitochondria through the mitochondrial Na+ /Ca2+ exchanger, NCLX. Mitochondrial Na+ transients are also controlled by the mitochondrial Na+ /H+ exchanger, NHE, while cytosolic Na+ changes are governed by Na+ /K+ ATPase pump. The functional interaction between the Na+ channels, Na+ /K+ ATPase pump and mitochondrial Na+ transporters, NCLX and NHE, in mediating Na+ signaling is poorly understood. Here, we combine fluorescent Na+ imaging, pharmacological inhibition by TTX, ouabain and EIPA, with molecular control of NCLX expression, so as to investigate the crosstalk between Na+ transporters on both the plasma membrane and the mitochondria. According to our results, glucose-dependent cytosolic Na+ response was enhanced by ouabain and was followed by a rise in mitochondrial Na+ signal. Silencing of NCLX expression using siNCLX, did not affect the glucoseor ouabain-dependent cytosolic rise in Na+ . In contrast, the ouabain-dependent rise in mitochondrial Na+ was strongly suppressed by siNCLX. Furthermore, mitochondrial Na+ influx rates were accelerated in cells treated with the Na+ /H+ exchanger inhibitor, EIPA or by combination of EIPA and ouabain. Similarly, TTX blocked the cytosolic and mitochondrial Na+ responses, which were enhanced by ouabain or EIPA, respectively. Our results suggest that Na+ /K+ ATPase pump controls cytosolic glucose-dependent Na+ rise, in a manner that is mediated by TTX-sensitive Na+ channels and subsequent mitochondrial Na+ uptake via NCLX. Furthermore, these results indicate that mitochondrial Na+ influx via NCLX is antagonized by Na+ efflux, which is mediated by the mitochondrial NHE; thus, the duration of mitochondrial Na+ transients is set by the interplay between these pivotal transporters. © 2014 Elsevier Ltd. All rights reserved.

1. Introduction In pancreatic ␤ cells, glucose uptake and its metabolism are followed by a rise in cytosolic ATP that subsequently binds and inactivates K+ -ATP channels, leading to cell depolarization and the opening of voltage-gated Ca2+ channels [1]; this then triggers insulin secretion. In addition to the Ca2+ and K+ -ATP channels, ␤ cells also express voltage-gated Na+ channels. Glucose-dependent Na+ currents were shown to occur in pancreatic ␤ cells [2] and to be linked to the control of duration and

∗ Corresponding author at: Department of Physiology and Cell Biology, Faculty of Health Sciences, Ben-Gurion University of the Negev, P.O.B. 653, Beer-Sheva 84105, Israel. Tel.: +972 86477328. E-mail address: [email protected] (I. Sekler).

magnitude of the action potential, leading to insulin secretion [3–5], in similarity to the release of neurotransmitters [6]. Their role in controlling cytosolic and organellar Na+ responses remain, however, elusive. While isotopic studies indicate that cytosolic Na+ transients are promoted by glucose [7], other studies, employing microfluorimetric analysis, suggest that cytosolic Na+ transients are reduced by the activity of the Na+ /K+ ATPase pump [8]. Recently, we have shown that the glucose-dependent Na+ influx through Na+ channels is followed by a change in the cytosolic and mitochondrial Na+ transients, in pancreatic ␤ cells [9]. Cytosolic Na+ transients are propagated into the mitochondria in several cell types [10]. Na+ influx in the mitochondria is primarily mediated by the mitochondrial Na+ /Ca2+ exchanger, NCLX, which is expressed in pancreatic ␤ cells [11], displaying a stoichiometry of at least 3:1 Na+ to Ca2+ ratio [12]. In addition, NCLX can sense the

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Please cite this article in press as: I.I. Nita, et al., A crosstalk between Na+ channels, Na+ /K+ pump and mitochondrial Na+ transporters controls glucose-dependent cytosolic and mitochondrial Na+ signals, Cell Calcium (2014), http://dx.doi.org/10.1016/j.ceca.2014.12.007

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glucose-dependent cytosolic rise in Na+ , due to an affinity to Na+ that is close to resting cytosolic Na+ concentrations (KM = 12 mM) [9]. Glucose-dependent cytosolic Na+ rise can be counter-balanced by the Na+ /K+ ATPase pump, the main route for cytosolic Na+ efflux, as depicted by an abrupt increase in cytosolic Na+ levels in the presence of the Na+ /K+ ATPase inhibitor, ouabain [8]. However, the role of this pump in regulating Na+ signals in the mitochondria in general, and in pancreatic ␤ cells in particular, is unresolved. Mitochondrial Na+ influx through NCLX could be potentially counter-balanced by the activity of a mitochondrial Na+ /H+ exchanger, NHE, which mediates the mitochondrial Na+ efflux by utilizing the trans-inner mitochondrial H+ gradient that is generated by the respiratory chain [13,14]. Although this activity can be blocked by amiloride derivatives, the molecular identity of the mitochondrial NHE remains elusive, and it is unknown whether there is a functional crosstalk between the Na+ /K+ ATPase pump and either of the two mitochondrial Na+ transporters, NCLX and NHE. In the present study, we aim to determine whether glucosedependent Na+ influx, mediated by the Na+ channel, is controlled by the Na+ /K+ ATPase pump. We further examine whether a crosstalk between the pump and the Na+ channel, as well as the mitochondrial Na+ transporters, shapes the profile of mitochondrial Na+ transients. We observed that Na+ /K+ ATPase counteracts the Na+ influx mediated by the TTX-sensitive Na+ channel. In addition, since the threshold for NCLX activation is determined by cytosolic Na+ , we found that the pump strongly controls mitochondrial Na+ influx through NCLX, and indirectly affects mitochondrial Na+ efflux by mitochondrial NHE. 2. Materials and methods 2.1. Mice and islet isolation Six-eight-week old female DBA/2J mice were purchased from Jackson laboratories, Bar Harbor, ME, USA. Mice were kept in a pathogen-free environment at the Ben-Gurion University of the Negev Research Animal Facility. Animal care and experiments were conducted according to the University’s Care and Use of Animals Committee guidelines. Animals were anesthetized prior to islet isolation by standard ketamine/xylazine injection, as described elsewhere [15]. Briefly, pancreata were inflated with collagenase XI (Sigma–Aldrich, Rehovot, Israel) and then incubated at 37 ◦ C for 13 min. Digested pancreata were washed with cold HBSS containing 0.5% BSA, vortexes and filtered through 500 ␮m sieves onto 100 ␮m nylon cell strainers (Falcon; BD Biosciences Discovery Labware). The sieves were turned over a Petri dish and the islets were washed with HBSS and then hand-picked under a stereomicroscope [16]. 2.2. Cell culture and transfection Isolated islets were cultured in RPMI 1640 (Biological Industries, Kibbutz Beit Haemek, Israel) for 2–3 days and MIN6 cells in DMEM (Beit Haemek); both media were supplemented with 10% fetal calf serum, 1% penicillin/streptomycin, 1% l-Glutamine (all from Beit Haemek) and 5 mM Glucose (Gerbu). Islets were dispersed into single cells using Trypsin-EDTA (Beit Haemek) [17]. Dispersed primary islet cells and MIN6 cells were seeded onto coverslips [18]. According to immunohistochemical analysis for insulin, more than 90% of islet cells in the single-cell suspension were ␤ cells, as previously described [19]. Pancreatic primary ␤ cells and MIN6 cells were then transfected with siRNA NCLX vs. siRNA Control using DharmaFECT siRNATransfection Reagents (Dharmacon, Chicago, IL). siRNA NCLX (AACGGCCACUCAACUGUCU) vs. siRNA Control (AACGCGCAUCCAACUGUCU) were diluted in

DharmaFECT siRNA transfection reagent, incubated for 20 min at room temperature and then added to antibiotic-free medium, as previously described [11]. Transfection efficiency was evaluated by the siRNA marker, siGLO Red (Dharmacon). 2.3. Fluorescent Na+ imaging The imaging system consisted of an Axiovert 100 inverted microscope (Zeiss, Oberaue, Germany), Polychrome V monochromator (TILL Photonics, Planegg, Germany) and a SensiCam cooled charge-coupled device (PCO, Kelheim, Germany). Fluorescent images were acquired with Imaging WorkBench 4.0 software (Axon Instruments, Foster City, CA). Fluorescent Na+ imaging was performed in pancreatic primary ␤ cells and MIN6 cells attached onto coverslips and superfused with Ringer’s solution containing (in mM): 126 NaCl (Frutarom), 5.4 KCl (Sigma), 0.8 MgCl2 (Gerbu), 20 HEPES (Amresco), 1.8 CaCl2 (Sigma), 15 Glucose (Gerbu), pH was adjusted to 7.4 with NaOH (Sigma). In glucose dependent experiments, the pancreatic primary ␤ cells or MIN6 cells were pre-washed for 30 min with low glucose (3 mM) followed by high glucose (20 mM) Ringer’s solution. Fluorescent imaging of Na+ in cytosol and mitochondria was performed using CoroNa Green (Invitrogen, Eugene, OR) and CoroNa Red (Invitrogen, Eugene, OR), respectively. Cytosolic Na+ response was acquired in cells loaded with CoroNa Green at excitation of 488 nm and imaged at 510 nm long pass filter [20]. Mitochondrial Na+ signals were monitored in cells loaded with CoroNa Red at excitation of 568 nm and emission at 590 nm, respectively [20]. The traces of all fluorescent imaging experiments were plotted using KaleidaGraph 4.0 (Synergy Software, Reading, PA). The fluorescent Na+ traces were normalized to the averaged baseline signal (F/F0 ), obtained at the beginning of the measurements. The influx and efflux rates were derived from a linear fit of the fluorescence change during 30 s [11,12]. Peak amplitude was established by the difference between the maximal peak heights of the signal to the baseline fluorescence, as described [21]. Averaged rates or amplitudes of the fluorescent Na+ responses, over n (indicated in the figure legends) experiments, are presented in the bar graphs. 3. Results 3.1. Role of Na+ /K+ ATPase pump vs. mitochondrial Na+ /Ca2+ exchanger in the glucose-dependent cytosolic Na+ response We initially sought to determine the role of Na+ /K+ ATPase pump and NCLX in regulating of the glucose-dependent cytosolic Na+ response. Both Na+ transporters have the potential to modulate cytosolic Na+ signals, the former by extruding Na+ out of the cells while the latter by pumping Na+ into the mitochondria. Cells were transfected with siNCLX vs. siControl, loaded with CoroNa Green and superfused with low-glucose Ringer’s solution, followed by application of high glucose. As shown in Fig. 1A, knockdown of NCLX expression does not affect glucose-dependent initial rate or amplitude of the cytosolic Na+ rise. To determine the role of the Na+ /K+ ATPase pump in pancreatic ␤ cells, glucose-dependent changes in cytosolic Na+ were compared between non-treated (Control) vs. ouabain-treated cells (Fig. 1B). As shown, application of ouabain (100 ␮M) was followed by a strong increase in rate and amplitude of the glucose dependent cytosolic Na+ rise (10 ± 1.3-fold and 7.6 ± 1-fold, respectively) (Fig. 1C and D). To determine the combined role of NCLX and Na+ /K+ ATPase pump in glucose-dependent Na+ changes, cytosolic Na+ responses were compared between pancreatic primary islet cells transfected

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Fig. 2. NCLX-mediated mitochondrial Na+ influx is enhanced by ouabain. (A) Fluorescent traces of mitochondrial Na+ responses in MIN6 cells loaded with CoroNa Red and treated with 100 ␮M ouabain. Cells superfused with low glucose followed by high glucose Ringer’s solution. (B) Fluorescent traces of mitochondrial Na+ responses in MIN6 cells loaded with CoroNa Red, transfected with siNCLX vs. siControl. Cells were superfused with low (3 mM) glucose followed by high (20 mM) glucose containing ouabain. (C) Averaged rates of mitochondrial Na+ influx presented in panels A and B, n = 7 (**P < 0.05). (D) Averaged amplitudes of mitochondrial Na+ influx presented in panels A and B, n = 7 (**P < 0.05). Fig. 1. Role of NCLX vs. Na+ /K+ pump in regulation of glucose-dependent cytosolic Na+ response. (A) Fluorescent traces of glucose-dependent cytosolic Na+ response in primary islet cells loaded with CoroNa Green and transfected with siControl vs. siNCLX. Cells were superfused with low (3 mM) glucose followed by high (20 mM) glucose. (B) Fluorescent traces of glucose-dependent cytosolic Na+ response in pancreatic primary islets loaded with CoroNa Green and treated with 100 ␮M ouabain. Cells were superfused with low (3 mM) glucose followed by high (20 mM) glucose. (C) Averaged rates of cytosolic Na+ response presented in panel B, n = 6 (**P < 0.05). (D) Averaged amplitudes of cytosolic Na+ response presented in panel B, n = 6 (**P < 0.05). (E) Fluorescent traces of glucose-dependent cytosolic Na+ response in pancreatic primary islets cells transfected with siControl vs. siNCLX and loaded with CoroNa Green, while superfused with high glucose Ringer’s solution containing ouabain.

with siNCLX vs. siControl, and treated with ouabain. As shown in Fig. 1E, ouabain triggered a robust rise in glucose-dependent cytosolic Na+ response compared to the low-glucose phase of cytosolic Na+ signal in the siControl group. Inhibition of both Na+ transporters by ouabain and siNCLX, respectively, did not affect the rate and magnitude of the glucose-dependent cytosolic Na+ rise, compared to siControl (Fig. 1E). Taken together, the results of this part indicate that the Na+ /K+ ATPase pump is the dominant transporter in controlling the glucose dependent cytosolic Na+ response and NCLX however does not participate in glucose dependent cytosolic Na+ homeostasis in pancreatic ␤ cells. 3.2. Na+ /K+ ATPase pump modulates the mitochondrial Na+ influx via NCLX To examine whether Na+ transport via Na+ /K+ ATPase pump by controlling the glucose-dependent cytosolic Na+ rise affects the mitochondrial Na+ transients, mitochondrial Na+ changes were monitored in MIN6 cells loaded with CoroNa Red and superfused with low- and high-glucose Ringer’s solution (Fig. 2). The rate and amplitude of the mitochondrial Na+ response was increased

in the presence of ouabain by 2 ± 0.5 and 3 ± 0.3-fold, respectively, compared to non-treated cells (Control). Thus, increased cytosolic Na+ triggered by the inhibition of Na+ /K+ ATPase pump is followed by enhanced influx of Na+ into the mitochondria (Fig. 2A, C and D). To determine if the mitochondrial Na+ uptake enhanced by ouabain is mediated by NCLX, MIN6 cells were transfected with either siNCLX or siControl, loaded with CoroNa Red and subjected to high-glucose solution. As shown in Fig. 2B, knockdown of NCLX expression by siNCLX was followed by a strong decrease in rate and amplitude of glucose-dependent mitochondrial Na+ uptake compared to siControl (3 ± 0.1 and 2.5 ± 0.2 folds, respectively) (Fig. 2B, C and D). Thus, the glucose-dependent cytosolic Na+ response enhanced by ouabain is propagated into the mitochondria through NCLX.

3.3. Glucose-dependent cytosolic Na+ rise, mediated by TTX-sensitive Na+ channels, is controlled by the Na+ /K+ ATPase pump To determine whether the rise in glucose-dependent cytosolic Na+ response enhanced by ouabain is mediated by TTX-sensitive Na+ channels, pancreatic primary islet cells were loaded with CoroNa Green and superfused with high-glucose Ringer’s solution containing ouabain, in the presence or absence of TTX (Fig. 3A). The glucose-dependent cytosolic Na+ response enhanced by ouabain was drastically reduced in both rate and amplitude (10 ± 2-fold) by TTX compared to cells treated only with ouabain (Fig. 3A–C). Thus, glucose-dependent cytosolic Na+ response augmented by ouabain is mediated via the TTX-sensitive Na+ channels.

Please cite this article in press as: I.I. Nita, et al., A crosstalk between Na+ channels, Na+ /K+ pump and mitochondrial Na+ transporters controls glucose-dependent cytosolic and mitochondrial Na+ signals, Cell Calcium (2014), http://dx.doi.org/10.1016/j.ceca.2014.12.007

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Fig. 3. Ouabain-dependent increase in cytosolic Na+ is preceded by cytosolic Na+ influx via TTX-sensitive Na+ channels. (A) Fluorescent traces of glucose-dependent cytosolic Na+ response in pancreatic primary islet cells loaded with CoroNa Green, superfused with low glucose followed by high glucose Ringer’s solution containing ouabain alone or ouabain and TTX. (B) Averaged rates of cytosolic Na+ response presented in panel A, n = 5 (**P < 0.05). (C) Averaged amplitudes of cytosolic Na+ response presented in panel A, n = 5 (**P < 0.05).

3.4. Glucose-dependent cytosolic Na+ response enhanced by ouabain and mediated by TTX-sensitive Na+ channels is propagated in mitochondria via NCLX

Fig. 4. TTX diminishes the glucose-dependent mitochondrial Na+ transients enhanced by ouabain. (A) Fluorescent traces of mitochondrial Na+ influx in MIN6 cells loaded with CoroNa Red while superfused with low glucose followed by high glucose Ringer’s solution containing ouabain alone or ouabain and TTX. (B) Fluorescent traces of mitochondrial Na+ influx in MIN6 cells loaded with CoroNa Red and transfected with siNCLX vs. siControl; cells were superfused with low (3 mM) glucose followed by high (20 mM) glucose. (C) Averaged rates of mitochondrial Na+ influx presented in panels A and B, n = 8 (**P < 0.05). (D) Averaged amplitudes of mitochondrial Na+ influx presented in panels A and B, n = 8 (**P < 0.05).

glucose-dependent cytosolic Na+ rise was unaffected by the presence or absence of EIPA. While glucose-dependent cytosolic Na+ response was affected by ouabain, the application of EIPA did not change the profile of the cytosolic Na+ response, confirming that plasma membrane NHE does not play a major role in cytosolic Na+

In order to identify the major mitochondrial Na+ influx pathway that is affected by pump, we compared the mitochondrial Na+ response in the presence or absence of ouabain and TTX. Mitochondrial Na+ transients were monitored in MIN6 cells loaded with CoroNa Red and superfused with ouabain alone or ouabain and TTX. In the presence of TTX (Fig. 4A, C and D), glucose-dependent mitochondrial Na+ response enhanced by ouabain was strongly reduced in rate and amplitude (3 ± 1-fold) compared to cells treated with ouabain alone. We next asked whether glucose-dependent cytosolic Na+ rise via TTX-sensitive Na+ channels is NCLX-dependent. Glucosedependent mitochondrial Na+ response was monitored in MIN6 cells transfected with siNCLX vs. siControl and treated with ouabain and TTX. Consistent with data presented in Fig. 4A, TTX reduced the mitochondrial Na+ signal in cells transfected with siControl, resulting in a weaker ouabain effect. Under these conditions, NCLX promoted the mitochondrial Na+ influx that was blocked by 1.5 ± 0.3-fold following the knockdown of NCLX (Fig. 4B, C and D). Altogether these results indicate that Na+ /K+ ATPase pump controlling the glucose dependent cytosolic Na+ influx via TTX sensitive Na+ channels modulates the mitochondrial Na+ influx via NCLX. 3.5. Mitochondrial Na+ /H+ exchanger participates in setting of glucose dependent mitochondrial Na+ responses We then sought to determine the role of mitochondrial NHE in communicating with NCLX, using EIPA. Since plasma membrane NHE is also blocked by EIPA, we first analyzed the cytosolic glucosedependent Na+ responses in the presence or absence of 50 ␮M EIPA in MIN6 cells pre-loaded with CoroNa Green. As shown in Fig. 5A,

Fig. 5. EIPA- and TTX-dependent effect on mitochondrial Na+ response. (A) Fluorescent traces of cytosolic Na+ glucose-dependent response in presence or absence of EIPA and in presence of ouabain alone or ouabain and EIPA in MIN6 cells loaded with CoroNa Green. (B) Fluorescent traces of mitochondrial Na+ influx in MIN6 cells loaded with CoroNa Red, following application of high glucose Ringer’s solution without EIPA or TTX (Control), with EIPA alone or EIPA and TTX. (C) Averaged rates of mitochondrial Na+ influx presented in panel B, n = 5 (*P < 0.05). (D) Averaged amplitudes of mitochondrial Na+ influx presented in panel B, n = 5 (*P < 0.05).

Please cite this article in press as: I.I. Nita, et al., A crosstalk between Na+ channels, Na+ /K+ pump and mitochondrial Na+ transporters controls glucose-dependent cytosolic and mitochondrial Na+ signals, Cell Calcium (2014), http://dx.doi.org/10.1016/j.ceca.2014.12.007

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Thus, blocking the Na+ /K+ ATPase pump leads to enhanced mitochondrial Na+ influx that, in turn, triggers Na+ efflux via the EIPA-sensitive mitochondrial NHE.

4. Discussion

Fig. 6. Ouabain and EIPA co-regulate glucose-dependent mitochondrial Na+ response. (A) Fluorescent traces of mitochondrial Na+ influx in MIN6 cells loaded with CoroNa Red and superfused with high glucose Ringer’s solution in absence of any inhibitor (Control), in the presence of ouabain alone or ouabain and EIPA. (B) Averaged rates of mitochondrial Na+ influx presented in panel A, n = 3(*P < 0.05). (C) Averaged amplitudes of mitochondrial Na+ influx presented in panel A, n = 3 (*P < 0.05).

regulation and is thus not expected to modulate mitochondrial Na+ transients. We then asked if mitochondrial NHE participates in mitochondrial Na+ homeostasis, we monitored the glucose-dependent mitochondrial Na+ response in MIN6 cells loaded with CoroNa Red. Application of EIPA (50 ␮M) was followed by a 1.9 ± 0.2-fold increase in the rate of mitochondrial Na+ influx, compared to cells superfused with high-glucose Ringer solution in absence of EIPA (Control) (Fig. 5B, C and D). We next sought to determine whether a crosstalk exists between the membrane Na+ channel and mitochondrial NHE. Mitochondrial Na+ response was monitored in the presence of TTX and EIPA. As shown (Fig. 5B, C and D), the EIPA effect, i.e., accelerated mitochondrial Na+ influx, was reduced by 2 ± 0.5-fold in the presence of TTX, compared to control cells that were not treated with either TTX or EIPA. This set of results indicate that Na+ influx via plasma membrane + Na channels provide the Na+ substrate for the mitochondrial NHE and the mitochondrial Na+ transporters, NCLX and NHE, are setting the rate of change in mitochondrial Na+ signal. 3.6. Glucose-dependent mitochondrial Na+ response enhanced by ouabain is controlled by NHE To determine whether Na+ /K+ ATPase pump controls the mitochondrial NHE activity, MIN6 cells were loaded with CoroNa Red and superfused with Ringer’s solution in the presence of ouabain, with or without EIPA. As shown in (Fig. 6A–C), ouabain caused an increase in the rate and amplitude of glucose-dependent mitochondrial Na+ response (1.9 ± 0.3 and 2 ± 0.5-fold, respectively) compared to mitochondrial Na+ response in absence of ouabain. Co-application of EIPA with ouabain was followed by an accelerated rate of Na+ influx into the mitochondria (1.6 ± 0.6-fold) compared to glucose-dependent mitochondrial Na+ response monitored in the presence of ouabain alone (Fig. 6A–C).

The aim of this study was to investigate the functional interplay between Na+ /K+ ATPase pump, Na+ channels and mitochondrial Na+ transporters, NCLX and NHE. Our findings indicate that Na+ /K+ ATPase pump activity governs the glucose-dependent cytosolic Na+ rise through TTX-sensitive Na+ channels. Furthermore, Na+ /K+ ATPase pump controls mitochondrial Na+ transients by suppressing the Na+ influx via NCLX in mitochondria and thus, reducing the activity of mitochondrial NHE. Mitochondrial Na+ /Ca2+ exchanger does not contribute to setting of the glucose-dependent cytosolic Na+ rise. On the other hand, NCLX is antagonized by mitochondrial NHE, and both mitochondrial Na+ transporters play a significant role in setting the duration of mitochondrial Na+ transients. Previous studies, employing either isotopic or fluorescent indicators, suggest that glucose-dependent cytosolic Na+ rise is mediated by TTX-sensitive Na+ channels [7,9]. Indeed, our results depict a strong inhibition of ouabain-dependent cytosolic Na+ rise by TTX, indicating that Na+ /K+ ATPase pump controls the cytosolic Na+ transients through TTX-sensitive Na+ channels. In addition to the role of Na+ /K+ ATPase pump, mitochondrial Na+ uptake through NCLX may also participate in controlling the cytosolic Na+ signals by transporting cytosolic Na+ into the mitochondria. Indeed, other studies indicate that the mitochondrial exchanger does play a role in controlling also cytosolic Na+ response, as in, for example, smooth muscle cells [20]. Our findings suggest, however, that silencing of the mitochondrial exchanger does not affect the rate and amplitude of the glucose-dependent cytosolic Na+ rise, arguing against a role for NCLX in controlling cytosolic Na+ response. Although the reason for the differences is not entirely clear, the total volume occupied by mitochondria in muscle cells is much higher than in ␤ cells [22]; thus, it is conceivable that in muscle cells mitochondrial Na+ transport machinery plays a more dominant role than in ␤ cells, in which the mitochondria harbor only ∼4% of total volume of the cell [23]. It may also be argued that the similar role of NCLX in controlling cytosolic Na+ is related to the small rise in glucose-dependent cytosolic Na+ concentrations. Indeed, previous studies have indicated that NCLX has a relatively low affinity to cytosolic Na+ [9,24]. We therefore also monitored the role of NCLX in cells treated with ouabain. Our results show that the ouabain-dependent cytosolic Na+ rise was unchanged in both rate and amplitude by knockdown of NCLX expression indicating that the NCLX does not control the cytosolic Na+ concentrations. While the role of NCLX in controlling cytosolic Na+ response might be small, our results demonstrate a marked difference in mitochondrial Na+ signaling induced in ouabain-treated cells, between control vs. NCLX knockdown cells, indicating that indeed it plays a dominant role in shaping the ouabain-dependent mitochondrial Na+ transients. Previous studies suggest that insulin secretion was enhanced by ouabain [25]. The effect of ouabain is primarily mediated by an increase in cytosolic Na+ , which in turn triggers the reversal of the plasma membrane Na+ /Ca2+ exchanger, NCX, mediating Ca2+ influx and thus, enhancing the secretion of insulin. Subsequent studies, however, pointed out that plasma membrane NCX plays a relative minor role in cytosolic Ca2+ homeostasis and subsequent insulin secretion, as demonstrated in rodent ␤ cells [26]. Another, more likely scenario is that the inhibition of the Na+ /K+ ATPase pump diminishes transmembrane Na+ gradient, depolarizing the cells and contributing to the activation of the

Please cite this article in press as: I.I. Nita, et al., A crosstalk between Na+ channels, Na+ /K+ pump and mitochondrial Na+ transporters controls glucose-dependent cytosolic and mitochondrial Na+ signals, Cell Calcium (2014), http://dx.doi.org/10.1016/j.ceca.2014.12.007

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voltage-gated Na+ and Ca2+ channels. The activation of this pathway is, in turn, expected to increase glucose-dependent Ca2+ signals that are required for insulin secretion. In addition, Na+ channels mediate cytosolic Na+ rise, which is propagated into mitochondria via mitochondrial Na+ /Ca2+ exchanger [27,28], thus accelerating the mitochondrial Ca2+ shuttling [29]. Our results show a strong decrease in ouabain-dependent mitochondrial Na+ response in cells treated with TTX, indicating that Na+ /K+ ATPase pump suppresses the mitochondrial Na+ uptake by lowering the cytosolic Na+ transients through TTX-sensitive Na+ channels. Mitochondrial Na+ transients are dually controlled by the activity of both NCLX and mitochondrial NHE [10,30,31]; importantly, the activity of the latter is to antagonize the Na+ influx via NCLX. Consistent with previous studies, the activity of mitochondrial NHE in astrocytes showed a similar rise in mitochondrial Na+ influx in the presence of EIPA, an inhibitor of NHE, following glutamate-dependent cytosolic Na+ responses [10]. The activity of NHE preserves Na+ gradients that are necessary for a prolonged activation of NCLX in pumping out mitochondrial Ca2+ , thus maintaining a prolonged mitochondrial Ca2+ shutteling. In addition, mitochondrial NHE, by harnessing the H+ gradients, can modulate the mitochondrial pH values. Indeed, previous studies suggest that mitochondrial matrix pH controls oxidative phosphorylation and subsequently, insulin secretion [32]. Our results further indicate that Na+ /K+ ATPase controls the activity of mitochondrial NHE by counteracting the glucosedependent cytosolic Na+ rise via TTX-sensitive Na+ channels. Because the Na+ /K+ ATPase pump is controlled by endogenous ouabain [33], such a pathway may link the Na+ /K+ ATPase pump to metabolic activities and mitochondrial Ca2+ signaling. Finally, our results indicate that mitochondrial Na+ levels are dynamically balanced by the activity of both mitochondrial NCLX and NHE; while NCLX activity promotes the influx of mitochondrial Na+ , EIPA-sensitive mitochondrial NHE activity reduces mitochondrial Na+ extrusion rate. Such fine-tuning is thought to be essential for balancing mitochondrial Na+ gradient which in turn control the duration of mitochondrial Ca2+ transients. 5. Conclusions Na+ /K+ ATPase pump controls mitochondrial Na+ signals by counterbalancing the glucose-dependent cytosolic Na+ rise mediated by the TTX-sensitive Na+ channels. By lowering cytosolic Na+ , the Na+ /K+ ATPase suppresses the activity of mitochondrial Na+ transporters, NCLX and mitochondrial NHE. While the mitochondrial Na+ transporters NCLX and mitochondrial NHE do not participate in controlling cytosolic Na+ , they appear to play a major role in mitochondrial Na+ homeostasis. Conflict of interest The authors declared that there is no conflict of interest. Acknowledgments We would like to thank Eyal Ozeri for the preparation of primary islets. The study was supported by an ISF and DIP grant to IS. References [1] S.J. Ashcroft, L.C. Weerasinghe, P.J. Randle, Interrelationship of islet metabolism, adenosine triphosphate content and insulin release, Biochem. J. 132 (1973) 223–231. [2] T.D. Plant, Na+ currents in cultured mouse pancreatic B-cells, Pflugers Arch. 411 (1988) 429–435.

[3] M. Hiriart, D.R. Matteson, Na channels and two types of Ca channels in rat pancreatic B cells identified with the reverse hemolytic plaque assay, J. Gen. Physiol. 91 (1988) 617–639. [4] R. Vidaltamayo, M.C. Sanchez-Soto, M. Hiriart, Nerve growth factor increases sodium channel expression in pancreatic beta cells: implications for insulin secretion, FASEB J. 16 (2002) 891–892. [5] M. Braun, R. Ramracheya, M. Bengtsson, Q. Zhang, J. Karanauskaite, C. Partridge, P.R. Johnson, P. Rorsman, Voltage-gated ion channels in human pancreatic beta-cells: electrophysiological characterization and role in insulin secretion, Diabetes 57 (2008) 1618–1628. [6] V. Parpura, A. Verkhratsky, Homeostatic function of astrocytes: Ca(2+) and Na(+) signalling, Transl. Neurosci. 3 (2012) 334–344. [7] S. Kawazu, A.C. Boschero, C. Delcroix, W.J. Malaisse, The stimulus-secretion coupling of glucose-induced insulin release. XXVIII. Effect of glucose on Na+ fluxes in isolated islets, Pflugers Arch. 375 (1978) 197–206. [8] E. Grapengiesser, Unmasking of a periodic Na+ entry into glucose-stimulated pancreatic beta-cells after partial inhibition of the Na/K pump, Endocrinology 139 (1998) 3227–3231. [9] Nita, M. Ii, C. Hershfinkel, G.A. Kantor, E.C. Rutter, I. Lewis, Sekler, Pancreatic beta-cell Na+ channels control global Ca2+ signaling and oxidative metabolism by inducing Na+ and Ca2+ responses that are propagated into mitochondria, FASEB J. 28 (2014) 3301–3312. [10] Y. Bernardinelli, G. Azarias, J.Y. Chatton, In situ fluorescence imaging of glutamate-evoked mitochondrial Na+ responses in astrocytes, Glia 54 (2006) 460–470. [11] I.I. Nita, M. Hershfinkel, D. Fishman, E. Ozeri, G.A. Rutter, S.L. Sensi, D. Khananshvili, E.C. Lewis, I. Sekler, The mitochondrial Na+ /Ca2+ exchanger upregulates glucose dependent Ca2+ signalling linked to insulin secretion, PLoS ONE 7 (2012) e46649. [12] R. Palty, W.F. Silverman, M. Hershfinkel, T. Caporale, S.L. Sensi, J. Parnis, C. Nolte, D. Fishman, V. Shoshan-Barmatz, S. Herrmann, D. Khananshvili, I. Sekler, NCLX is an essential component of mitochondrial Na+ /Ca2+ exchange, Proc. Natl. Acad. Sci. U.S.A. 107 (2010) 436–441. [13] P. Mitchell, J. Moyle, Translocation of some anions cations and acids in rat liver mitochondria, Eur. J. Biochem. 9 (1969) 149–155. [14] K.D. Garlid, Sodium/proton antiporters in the mitochondrial inner membrane, Adv. Exp. Med. Biol. 232 (1988) 37–46. [15] E.C. Lewis, L. Shapiro, O.J. Bowers, C.A. Dinarello, Alpha1-antitrypsin monotherapy prolongs islet allograft survival in mice, Proc. Natl. Acad. Sci. U.S.A. 102 (2005) 12153–12158. [16] P.R. Salvalaggio, S. Deng, C.E. Ariyan, I. Millet, W.S. Zawalich, G.P. Basadonna, D.M. Rothstein, Islet filtration: a simple and rapid new purification procedure that avoids ficoll and improves islet mass and function, Transplantation 74 (2002) 877–879. [17] M.A. Ravier, G.A. Rutter, Isolation and culture of mouse pancreatic islets for ex vivo imaging studies with trappable or recombinant fluorescent probes, Methods Mol. Biol. 633 (2010) 171–184. [18] F.C. Jonkers, J.C. Jonas, P. Gilon, J.C. Henquin, Influence of cell number on the characteristics and synchrony of Ca2+ oscillations in clusters of mouse pancreatic islet cells, J. Physiol. 520 (Pt 3) (1999) 839–849. [19] C. Lindskog, O. Korsgren, F. Ponten, J.W. Eriksson, L. Johansson, A. Danielsson, Novel pancreatic beta cell-specific proteins: antibody-based proteomics for identification of new biomarker candidates, J. Proteomics 75 (2012) 2611–2620. [20] D. Poburko, C.H. Liao, V.S. Lemos, E. Lin, Y. Maruyama, W.C. Cole, C. Van Breemen, Transient receptor potential channel 6-mediated, localized cytosolic [Na+ ] transients drive Na+ /Ca2+ exchanger-mediated Ca2+ entry in purinergically stimulated aorta smooth muscle cells, Circ. Res. 101 (2007) 1030–1038. [21] D. Akhmedov, M. Braun, C. Mataki, K.S. Park, T. Pozzan, K. Schoonjans, P. Rorsman, C.B. Wollheim, A. Wiederkehr, Mitochondrial matrix pH controls oxidative phosphorylation and metabolism-secretion coupling in INS-1E clonal beta cells, FASEB J. 24 (2010) 4613–4626. [22] V. Lukyanenko, A. Chikando, W.J. Lederer, Mitochondria in cardiomyocyte Ca2+ signaling, Int. J. Biochem. Cell Biol. 41 (2009) 1957–1971. [23] G.A. Rutter, J.M. Theler, M. Murgia, C.B. Wollheim, T. Pozzan, R. Rizzuto, Stimulated Ca2+ influx raises mitochondrial free Ca2+ to supramicromolar levels in a pancreatic beta-cell line. Possible role in glucose and agonist-induced insulin secretion, J. Biol. Chem. 268 (1993) 22385–22390. [24] P. Paucek, M. Jaburek, Kinetics and ion specificity of Na(+)/Ca(2+) exchange mediated by the reconstituted beef heart mitochondrial Na(+)/Ca(2+) antiporter, Biochim. Biophys. Acta 1659 (2004) 83–91. [25] E.G. Siegel, C.B. Wollheim, A.E. Renold, G.W. Sharp, Evidence for the involvement of Na/Ca exchange in glucose-induced insulin release from rat pancreatic islets, J. Clin. Invest. 66 (1980) 996–1003. [26] F. Van Eylen, O.D. Horta, A. Barez, A. Kamagate, P.R. Flatt, R. Macianskiene, K. Mubagwa, A. Herchuelz, Overexpression of the Na/Ca exchanger shapes stimulus-induced cytosolic Ca(2+) oscillations in insulin-producing BRIN-BD11 cells, Diabetes 51 (2002) 366–375. [27] M.D. Carrithers, G. Chatterjee, L.M. Carrithers, R. Offoha, U. Iheagwara, C. Rahner, M. Graham, S.G. Waxman, Regulation of podosome formation in macrophages by a splice variant of the sodium channel SCN8A, J. Biol. Chem. 284 (2009) 8114–8126. [28] F. Yang, X.P. He, J. Russell, B. Lu, Ca2+ influx-independent synaptic potentiation mediated by mitochondrial Na(+)-Ca2+ exchanger and protein kinase C, J. Cell Biol. 163 (2003) 511–523.

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[29] C. Maack, S. Cortassa, M.A. Aon, A.N. Ganesan, T. Liu, B. O’rourke, Elevated cytosolic Na+ decreases mitochondrial Ca2+ uptake during excitation-contraction coupling and impairs energetic adaptation in cardiac myocytes, Circ. Res. 99 (2006) 172–182. [30] D.M. Bers, W.H. Barry, S. Despa, Intracellular Na+ regulation in cardiac myocytes, Cardiovasc. Res. 57 (2003) 897–912. [31] E. Murphy, D.A. Eisner, Regulation of intracellular and mitochondrial sodium in health and disease, Circ. Res. 104 (2009) 292–303.

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[32] A. Wiederkehr, K.S. Park, O. Dupont, N. Demaurex, T. Pozzan, G.W. Cline, C.B. Wollheim, Matrix alkalinization: a novel mitochondrial signal for sustained pancreatic beta-cell activation, EMBO J. 28 (2009) 417–428. [33] J.M. Hamlyn, M.P. Blaustein, Salt sensitivity, endogenous ouabain and hypertension, Curr. Opin. Nephrol. Hypertens. 22 (2013) 51–58.

Please cite this article in press as: I.I. Nita, et al., A crosstalk between Na+ channels, Na+ /K+ pump and mitochondrial Na+ transporters controls glucose-dependent cytosolic and mitochondrial Na+ signals, Cell Calcium (2014), http://dx.doi.org/10.1016/j.ceca.2014.12.007