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WATER AND ELECTROLYTE HOMEOSTASIS

Functional and molecular characterization of the fluid secretion mechanism in human parotid acinar cells

¹The Center for Oral Biology in the Aab Institute of Biomedical Sciences and the ²Department of Pharmacology and Physiology, University of Rochester School of Medicine and Dentistry, Rochester, New York; and ³Facultad de Medicina and ⁴Instituto de Fisica, Universidad Autonoma de San Luis Potosi, San Luis Potosi, Mexico

Submitted 20 August 2006 ; accepted in final form 5 March 2007

	ABSTRACT

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
The strategies available for treating salivary gland hypofunction are limited because relatively little is known about the secretion process in humans. An initial microarray screen detected ion transport proteins generally accepted to be critically involved in salivation. We tested for the activity of some of these proteins, as well as for specific cell properties required to support fluid secretion. The resting membrane potential of human acinar cells was near –51 mV, while the intracellular [Cl^–] was 62 mM, about fourfold higher than expected if Cl ions were passively distributed. Active Cl^– uptake mechanisms included a bumetanide-sensitive Na⁺-K⁺-2Cl^– cotransporter and paired DIDS-sensitive Cl^–/HCO₃^– and EIPA-sensitive Na⁺/H⁺ exchangers that correlated with expression of NKCC1, AE2, and NHE1 transcripts, respectively. Intracellular Ca²⁺ stimulated a niflumic acid-sensitive Cl^– current with properties similar to the Ca²⁺-gated Cl channel BEST2. In addition, intracellular Ca²⁺ stimulated a paxilline-sensitive and voltage-dependent, large-conductance K channel and a clotrimazole-sensitive, intermediate-conductance K channel, consistent with the detection of transcripts for KCNMA1 and KCNN4, respectively. Our results demonstrate that the ion transport mechanisms in human parotid glands are equivalent to those in the mouse, confirming that animal models provide valuable systems for testing therapies to prevent salivary gland dysfunction.

salivary glands; secretion; fluid; channels; exchangers; cotransporters

In an effort toward achieving this goal, we have performed a comprehensive evaluation of the functional and molecular properties of the ion transport proteins expressed in human parotid glands and have compared these with the transporters expressed in mouse salivary glands. Salivary gland acinar cells secrete most, if not all, of the fluid component of saliva. The current secretion model predicts that the primary driving force for basal to apical, transacinar fluid and electrolyte secretion is Cl^– movement (5, 32) (see also Fig. 6). Such Cl^– trafficking involves both uptake mechanisms located in the basolateral membrane to concentrate intracellular Cl^– above its electrochemical equilibrium concentration, and apical efflux channels, which are activated by an increase in intracellular [Ca²⁺]. Other critical steps in fluid secretion include the movement of Na ions through the acinar cell tight junctions and the efflux of K⁺ from the acinar cells. Pathological defects that result in hyposalivation may occur at multiple steps in this fluid secretion process, including, for example, ion transporter activation, agonist-receptor interaction, and second messenger generation. Given the vital role of transepithelial movement of electrolytes in secretion, perturbation of ion transport function is likely to be involved in many such conditions. Here, we confirm that human parotid acinar cells employ the same repertoire of ion transport proteins found in other mammalian salivary glands. Given this high degree of similarity, animal models (especially mouse) will likely continue to provide valuable insight for understanding fluid secretion in humans and for developing strategies for averting the consequences of salivary gland dysfunction.

View larger version (33K): [in this window] [in a new window]   Fig. 6. Fluid secretion model in human parotid acinar cells. Acinar cell secretion model based on the entry of Cl– across the basolateral membrane mediated by a Na+/K+/2Cl– cotransporter and the paired Na+/H+ and Cl–/HCO3– exchangers and exit across the apical membrane via a Cl channel. The six essential ion transport mechanisms involved in fluid and electrolyte movement in Cl–-secreting acinar cells include basolateral Na+-K+-ATPase with a stoichiometry of 3 Na+:2 K+, the electroneutral NKCC1, basolateral K channels (IK1 and maxi-K), paired basolateral Na+/H+ and Cl–/HCO3– exchangers (NHE1 and AE2, respectively), and apical Cl channels (BEST2). Cl– is concentrated in acinar cells (62 mM) by the Na+-K+-2Cl– cotransporter and paired Na+/H+ and Cl–/HCO3– exchangers, well above that predicted for a cell with a hyperpolarized membrane potential (about –51 mV). K+ and Cl– exit when the K and Cl channels open in response to a receptor-mediated increase in the intracellular [Ca2+]. The accumulation of Cl– in the acinar lumen is neutralized by Na+ movement across tight junctions and water follows osmotically. Note that acinar cells are homogeneous; therefore, the different transport elements are spread out for clarity, but all occur in each cell. See DISCUSSION for details and earlier reviews (5, 32). Not shown is the possible contribution of a Na+-HCO3– cotransporter mechanism (39, 42).

	METHODS

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

BCECF-AM [2'-7'-bis-(2-carboxyethyl)-5-(and 6)-carboxyfluorescein, acetoxymethyl ester], EIPA [5-(N-ethyl-N-isopropyl)amiloride], DIDS (4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid) and SPQ [6-methoxy-N-(3-sulfopropyl)quinolinium] were purchased from Molecular Probes (Eugene, OR). Liberase was from Roche (Indianapolis, IN), paxilline was from Biomol (Plymouth Meeting, PA), and all other chemicals were purchased from Sigma Chemical (St. Louis, MO) or as described in the text.

Human and Mouse Parotid Tissue

Human parotid tissue was obtained from healthy male and female subjects (30–70 years of age) scheduled to have parotid surgery because their gland contained a pleomorphic adenoma that required removal of all or a large portion of the gland. Much of the normal tissue surrounding the tumor is not used for diagnostic evaluation of the sample. This discarded tissue was collected immediately after surgical excision and transported in ice-cold physiological saline to the laboratory where the tissue was either frozen in liquid N₂, or acinar cells were isolated for acute functional assays. Tissue was obtained as approved by the University of Rochester Institutional Review Board.

Parotid tissue was also obtained from BlackSwiss-SvJ129 hybrid mice aged between 2 and 5 mo. Mice were housed in pathogen-free, microisolator cages with free access to laboratory chow and water ad libitum with a 12:12-h light-dark cycle. Mice were rendered unconscious by exposure to CO₂ and killed by exsanguination prior to removal of the parotid glands. Animal protocols were approved by the Animal Resources Committee of the University of Rochester.

Salivary Cell Preparation

Parotid acinar cells were prepared by enzymatic digestion as previously described (3). Tissue was finely minced in Eagle's minimum essential medium (Biofluids) containing Liberase (0.3 mg/7.5 ml) and incubated at 37°C in a shaker with continuous agitation (100 cycles/min). After 20 min of incubation, the salivary gland tissue was dispersed by gentle pipetting (10 times) and centrifuged (210 g x 15 s). The cell pellet was resuspended in a further 7.5 ml of digestion medium for an additional 40 min, at the end of which time the salivary gland cells were rinsed and harvested by centrifugation. For patch- clamp studies, single acinar cells were isolated by an initial digestion for 5 min in a solution containing Liberase and 0.02% trypsin, followed by incubation in a Liberase-containing solution as described above.

RNA Isolation and Northern Blot Analysis

Total RNA was isolated from parotid gland tissues according to the manufacturer's protocol (RNeasy, Qiagen, Valencia, CA). Before Northern blot analysis, mRNA was extracted by chromatography (oligo-dT resin, Oligotex mRNA Mini Kit; Qiagen). Northern blots were prepared and hybridized using the cDNA probes described in Table 1.

Targeted cDNA Array

The expression of transcripts for ion transporter proteins in human and mouse parotid glands was examined using a custom-designed "salivary gland secretion" cDNA array slide. A detailed description of the array can be found at http://www.urmc.rochester.edu/Aab/Oralbio/labpages/microarraycob/.

Probes for target genes were designed to include key water and ion transport proteins, as well as many secretion-associated signaling molecules and representative secretory proteins. Human and mouse cDNAs representing 187 "secretion" genes were obtained from either Open Biosystems (Huntsville, AL) or the "Mouse 15K cDNA Clone Set" (National Institute of Aging). PCR primers (Integrated DNA Technologies, Coralville, IA) were designed to amplify 200–1,200 bp products from the 3' ends of highly homologous regions of the human and mouse genes. PCR products of the expected length were purified (PCR cleaning kit, Qiagen, CA), sequence verified, and dried (Eppendorf Speedvac, Hamburg, Germany). Products were resuspended at 200 ng/µl in Pronto printing buffer (Corning, Corning, NY) and printed onto UltraGap Gamma Amino Propyl Silane slides (Corning) using a Bio-Rad VersaArray arrayer and 8 SMP3B stealth pins (TeleChem International, Sunnyvale, CA). Each cDNA was printed (125 µm diameter) in duplicate at adjacent sites with spot-to-spot separation of 375 µm.

Twenty micrograms of total RNA was transcribed and labeled using the Superscript Indirect cDNA Labeling Kit (Invitrogen) with Cy3 or Cy5 dye (Amersham Biosciences). Labeled cDNA was mixed with hybridization buffer (0.5 mg/ml Cot 1 DNA, 0.2 mg/ml yeast tRNA, 4x SSC buffer, 50 mM pH 8 Tris, 0.3% SDS, 0.2 mg/ml BSA), incubated at 95°C for 5 min, and added directly to the array slide within the hybridization cassette (Corning). The cassette was submerged in a 58°C water bath for 18 h, at the end of which time, the slides were thoroughly washed (2x SSC/0.2% SDS for 5 min, 0.1x SSC/0.1% SDS for 2 min, 0.2x SSC for 30 s, 0.05x SSC for 30 s, and then H₂O for 30 s), dried by centrifugation, and immediately scanned (Scan Array Express, Perkin Elmer, Cambridge, MA).

Samples isolated from the parotid glands of four human subjects and four mice were analyzed by array. Positive (-actin and GAPDH) and negative controls, including blank spots and 10 alien genes (Array Validation Kit, Stratagene, La Jolla, CA), were arrayed in duplicate and used to normalize the sensitivity, signal linearity, and consistency of the assay. For "spot" identification and quantification of the fluorescent signal intensities, the microarray images were analyzed using Scan Array Express v2.1 software (Perkin Elmer). The fluorescence signal intensity for each DNA spot (average intensity of each pixel present within the spot) was calculated and subtracted using local background correction after normalization (52). A positive signal was accepted when the spot intensity was greater than the mean intensity + 2 SD of the negative controls (19, 50). Expression of a gene was considered "present" when at least 3 out of 4 samples were positive.

Electrophysiology

Measurements of the electrophysiological properties of human parotid acinar cells were made at room temperature (20–22°C) using the patch-clamp technique in various configurations. Data analysis was performed using pClamp (ver. 8.0, Axon Instruments, Sunnyvale, CA), Origin (version 7.0, Origin Software, Northampton, MA), or custom software.

Membrane potential measurements. Membrane potential was determined using the perforated patch technique in current-clamp mode. Electrophysiological data were acquired using an Axopatch 200B amplifier and Digidata 1320A digitizer (Axon Instruments, Foster City, CA) and filtered at 2 kHz. Pipettes (Corning 8161 patch glass, Warner Instruments, Hamden, CT) were pulled to give a final resistance of 2–3 M in the solutions described below. The pipette was filled with (in mM): 95 K-methanesulfonate, 45 KCl, 15 NaCl, 1 MgCl₂, 5 BAPTA, 10 HEPES (pH 7.2), and then the pipette tip was back-filled with the same solution supplemented with 250 µg/ml nystatin and 2 mM Lucifer yellow. The nystatin stock solution (75 mg/ml in DMSO) was prepared daily. The liquid junction potential was minimized by briefly filling the bath with the pipette solution and zeroing the voltage. Immediately after obtaining the giga-seal, the recording chamber was perfused with solution A (in mM): 110 NaCl, 25 Na-gluconate, 5.4 KCl, 0.4 KH₂PO₄, 0.33 NaH₂PO₄, 0.8 MgSO₄, 2.2 CaCl₂, 10 glucose, 20 HEPES, pH 7.4 with NaOH. After the access resistance declined to 5–15 M (less than 10 min), the membrane potential was recorded in current-clamp mode. Exclusion of Lucifer yellow fluorescence from the patched cells confirmed that the perforated patch remained intact throughout the experiment. Membrane potential was determined in resting cells and then during stimulation by superfusion with 0.3 µM carbachol. The arithmetic mean of the membrane potential was computed when sustained oscillations occurred during stimulation periods (excluding the initial "spike").

K⁺ current measurements. Whole-cell and single-channel patch- clamp recordings were done with an Axopatch 200B amplifier. Data acquisition was performed using a 12-bit analog/digital converter controlled by a personal computer. The current records were filtered at 5 kHz. Whole-cell patch pipettes were constructed from GC-150 glass (Warner Instruments) with resistance values between 4 and 6 M. The pipette (internal) solution was 135 mM K-glutamate, 10 mM HEPES (pH 7.2), 5 mM EGTA, and with CaCl₂ added to establish various Ca²⁺ concentrations (see also http://www.stanford.edu/cpatton/maxc.html). The external solution for whole cell patch recordings consisted of (in mM): 135 Na-glutamate, 5 K-glutamate, 2 CaCl₂, 2 MgCl₂, and 10 HEPES (pH 7.2). The use of glutamate instead of Cl^– effectively eliminates Cl channel currents. The measured relevant junction potential in these recordings was less than 4 mV, sufficiently small that no correction was made.

Single-channel currents were obtained from inside-out patches with electrodes constructed from quartz (Garner Glass) and coated with sticky wax. The electrode tips were about 1–2 µm in diameter, and the current records were filtered at 2 kHz. These single-channel experiments used an external (pipette) solution that consisted of (in mM) 135-K glutamate, 2 CaCl₂, 2 MgCl₂, and 10 HEPES (pH 7.2). The internal (bath) solution was the same as used for the whole cell experiments.

Cl^– current measurements. Cl^– currents were recorded in whole cell configuration using a PC-501A amplifier (Warner Instruments, Holliston, MA). Pipettes fabricated with Corning 8161 glass had a resistance of 2–4 M when filled with the internal solution. Calcium-activated Cl^– currents were recorded from cells bathed with a solution containing (in mM): 139 TEA-Cl, 20 HEPES, 0.5 CaCl₂, and 100 D-mannitol (pH 7.3). TEA was used as the monovalent cation which essentially eliminates K channel currents. To test the Cl^– dependency of the whole cell current, 139 mM bath TEA-Cl was replaced with equimolar TEA-glutamate. The intracellular solution contained (in mM): 80 NMDG-glutamate, 50 NMDG-EGTA, 30 CaCl₂, and 20 HEPES (pH 7.3). This latter solution contained an estimated free [Ca²⁺] of 250 nM (1). Currents were recorded from 2-s test pulses from –80 to +100 mV in 20-mV increments applied every 7 s. At the end of each test pulse, the voltage was repolarized to –80 mV for 700 ms. The holding potential was 0 mV. Blockade of the calcium-activated Cl^– current by niflumic acid was assessed in cells dialyzed with an intracellular solution that contained (in mM): 9.7 TEA-Cl, 30 EGTA, 21 CaCl₂, 20 HEPES (pH 7.3) and an estimated free [Ca²⁺] of 250 nM. In these experiments, currents were recorded using the voltage protocol described above except for the holding potential, which was set at –50 mV.

Intracellular [Ion] Measurements

Acinar cells were loaded with either pH- or Cl^–-sensitive fluoroprobe by incubation for 15–20 min at room temperature with 2 µM BCECF-AM (7) or 1 mM SPQ (11), respectively. The fluorescence of dye-loaded acinar cells was monitored in a superfusion chamber mounted on a Nikon Diaphot inverted epifluorescence microscope interfaced with an Imago Sensicam (TILL Photonics, Pleasanton, CA).

Intracellular pH. BCECF-loaded acinar cells were excited at 490 and 440 nm, and emitted fluorescence was measured at 530 nm. Cells were superfused with a physiological, HCO₃^– containing solution B (in mM): 110 NaCl, 25 NaHCO₃, 5.4 KCl, 0.4 KH₂PO₄, 0.33 NaH₂PO₄, 0.8 MgSO₄, 1.2 CaCl₂, 10 glucose, and 20 HEPES. When NH₄Cl was used to monitor Na⁺-K⁺-2Cl^– cotransporter activity, 30 mM NaCl was replaced with equimolar NH₄Cl. Chloride salts were replaced with equimolar gluconate in Cl^–-free solutions, and additional calcium was added to compensate for chelation. Solutions were gassed with 5% CO₂ and 95% O₂ for at least 30 min before the pH was adjusted to 7.4 with NaOH. Intracellular pH data were expressed as a fluorescence ratio F₄₉₀/F₄₄₀ (46).

Intracellular [Cl^–]. SPQ-loaded cells were superfused with solutions A or B (see Membrane potential measurements or Intracellular pH, respectively) and excited at 360 nm and emitted fluorescence was measured at 510 ± 40 nm. HCO₃^–-free solutions were gassed with 100% O₂. Intracellular [Cl^–] was estimated by in situ calibration of the fluorescence, as previously described (11). The calibration solutions contained (in mM): 80 KCl, 70 K-gluconate, 10 glucose, 0.005 nigericin, and 0.01 tributyltin (pH 7.4). The [Cl^–] was adjusted from 0 to 80 mM by replacement of KCl with K-gluconate.

Data analyses and presentation. Reported values are the means ± SE for the number of acinar cells or aggregates examined. Statistical analyses were performed using Student's t-test; P values of <0.05 were considered statistically significant. All experiments were performed with three or more separate preparations. The figures show results from a single representative experiment unless otherwise noted.

	RESULTS

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
Screening of Human and Mouse Parotid Gland RNA

As an initial step in defining the fluid secretion mechanism in human parotid glands, gene expression was screened using a targeted cDNA array slide. This custom-designed array contained probes for 187 secretion-related genes that encode for ion/water transporters (75 genes) and receptors/regulators (101 genes), proteins potentially involved in the fluid secretion mechanism, as well as 11 secretory protein genes (see METHODS). Table 2 shows representative examples of relevant genes expressed in the samples isolated from human and mouse parotid glands. Of the 75 probes on the array representing ion/water transporter proteins, 59 were detected in human parotid tissue, whereas 61 of the probes hybridized with the mouse parotid gland RNA samples. Of the 59 genes expressed in human parotid tissue, 51 were also expressed in mouse parotid glands (86%).

Intracellular [Cl^–] and Membrane Potential

The current secretion model states that fluid and electrolyte transport is driven by transacinar Cl^– movement. This process requires the intracellular [Cl^–] of acinar cells to be accumulated to a level greater than its electrochemical equilibrium. With a resting membrane voltage between –50 and –60 mV (see below) and an external Cl^– concentration of 120 mM, the expected equilibrium values for intracellular Cl^– would be 12 to 18 mM. To test whether the intracellular Cl^– level in human parotid cells is greater than the equilibrium level, as required for chloride-based fluid secretion, we used the Cl^–-sensitive dye SPQ to estimate the intracellular [Cl^–]. From experiments like the one shown in A of Fig. 1, we found that the intracellular [Cl^–] in human parotid acinar cells was 62.4 ± 2.5 mM (n = 5) in a HCO₃^–-free solution, four to five times the predicted equilibrium value for the intracellular [Cl^–]. Changing the bath solution from a HCO₃^–-free to a HCO₃^–-containing solution did not significantly change the intracellular [Cl^–] (n = 4: HCO₃^–-containing = 56.3 ± 5.5 mM Cl^–; HCO₃^–-free = 57.7 ± 3.4 mM Cl^–). Thus, as in other mammalian salivary gland cells (6, 11, 44, 54), including those from mice (8, 36), human parotid acinar cells possess mechanism(s) for concentrating the intracellular [Cl^–] well above its electrochemical equilibrium.

View larger version (16K): [in this window] [in a new window]   Fig. 1. Intracellular [Cl–] and membrane potential of human parotid acinar cells. A: intracellular [Cl–] was estimated by in situ calibration of the anion-sensitive dye SPQ. SPQ-loaded cells were excited at 360 nm, and emitted fluorescence was measured at 510 ± 40 nm. Cells were perfused with a physiological solution followed by calibration solutions where the bath [Cl–] was adjusted from 0 to 80 mM. B: nystatin, perforated-patch technique was used to monitor the membrane potential (Vm) of isolated human parotid acinar cells. The membrane potential was recorded in current-clamp mode at rest or during stimulation with 0.3 µM carbachol (CCh).

Na⁺-Dependent Cl^– Uptake Mechanisms

The observation that the intracellular [Cl^–] of human parotid acinar cells is four or fivefold greater than its electrochemical equilibrium (Fig. 1) indicates that these cells express a mechanism for concentrating Cl^– and is consistent with the prediction that fluid and electrolyte secretion is driven by transacinar Cl^– movement. The two Cl^– uptake mechanisms previously described in rodent salivary gland acinar cells, Na⁺-K⁺-2Cl^– cotransport and paired Na⁺/H⁺ and Cl^–/HCO₃^– exchange (5, 32) were detected by cDNA array analysis in human parotid tissue (Table 2). To test for the functional presence of these three electroneutral ion transport mechanisms in human acinar cells, the intracellular pH-sensitive dye BCECF was used to monitor the activity of these transporters.

Na⁺-K⁺-2Cl^– cotransporter. Na⁺-K⁺-2Cl^– cotransporter activity was examined by monitoring the transport of the K⁺ surrogate NH₄⁺ (9) in a HCO₃^–-containing solution. Fig. 2A shows that addition of NH₄Cl caused a very rapid intracellular alkalinization, as uncharged NH₃ equilibrated across the plasma membrane, consuming intracellular protons and raising the intracellular pH. Subsequently, the intracellular pH decreased more slowly as NH₄⁺ entered the acinar cell primarily via the Na⁺-K⁺-2Cl^– cotransporter. The muscarinic receptor agonist carbachol (CCh, 0.5 µM) was used to enhance cotransporter activity (9). The agonist-induced acidification was blocked greater than 90% by the specific Na⁺-K⁺-2Cl^– cotransport inhibitor bumetanide (100 µM), such that the rate of acidification was not significantly different from that observed in unstimulated acinar cells (Fig. 2, A and B). Bumetanide had no significant effect on the acidification rate of resting cells (in the absence of CCh), suggesting that during unstimulated conditions, the Na⁺-K⁺-2Cl^– cotransporter is relatively inactive (Fig. 2B). We have previously shown that the mouse salivary acinar cell Na⁺-K⁺-2Cl^– cotransporter is encoded by the Slc12a2 gene (8). Northern blot analysis (Fig. 2B, inset) detected transcripts consistent with the expected size of the human and mouse transcripts from this gene. These results confirm the array data (Table 2) and demonstrate the presence of Na⁺-K⁺-2Cl^– cotransporter NKCC1 transcripts in both human and mouse parotid glands.

View larger version (21K): [in this window] [in a new window]   Fig. 2. Bumetanide (Bumet)-sensitive Na+-K+-2Cl– cotransporter (NKCC1). Na+-K+-2Cl– cotransporter activity was examined in a physiological solution containing HCO3– by monitoring the transport of the K+ surrogate NH4+. Acinar cells were loaded with pH-sensitive dye, and the normalized change in the BCECF fluorescence ratio (490 nm/440 nm) was calculated. The average initial BCECF ratio was set to zero. A: cells were exposed to carbachol (CCh, 0.5 µM) ± bumetanide (Bumet, 100 µM) added 1 min before the addition of 30 mM NH4Cl. B: rate of the acidification that occurred following NH4Cl addition (the initial linear 30 s) was determined in cells in the absence or presence of CCh ± Bumet (resting, n = 7; resting + Bumet, n = 4; stimulated, n = 8; stimulated + Bumet, n = 7). Bumet had no significant effect on the acidification rate of unstimulated cells but blocked >90% of the stimulated initial rate of acidification (*the initial rate in the presence of CCh was significantly greater than the other three experimental conditions; P < 0.001). Inset: Northern blot analysis detected NKCC1 transcripts in human (lane H) and mouse (lane M) parotid gland RNA preparations (see METHODS for details). Arrow indicates the approximate expected size of the transcript (see Table 1).

View larger version (26K): [in this window] [in a new window]   Fig. 3. Na+/H+ and Cl–/HCO3– exchangers. Activities of the paired Na+/H+ and Cl–/HCO3– exchangers were examined by monitoring acinar cells loaded with the pH-sensitive dye BCECF in a physiological solution containing HCO3–. A: cells were acid loaded by a 1-min exposure to 30 mM NH4Cl. Left: recovery from the acid load was Na+ dependent (n = 8). Right: EIPA sensitivity (2 µM, n = 5). B: Cl– removal induced an intracellular alkalinization (left). DIDS (300 µM) blocked nearly 50% of the rate of alkalinization determined during the initial linear 20 s (n = 6). Northern blot analysis detected AE2 (middle) and NHE1 (right) transcripts in human (lane H) and mouse (lane M) parotid gland RNA preparations (see METHODS for details). Arrows indicate the approximate expected sizes of the transcripts (see Table 1).

Ca²⁺-Dependent Cl^– and K⁺ Currents

The membrane potential (V_m) of human parotid acinar cells at rest (–51 mV) and during stimulation (–63 mV) was approximately midway between the equilibrium potentials for K and Cl ions (–81 and –17 mV, respectively; Fig. 1B). These results suggest that both K⁺ and Cl^– currents contribute to the V_m during resting and stimulated conditions. Moreover, these currents are likely due to the activation of Ca²⁺-gated Cl and K channels (1, 35).

Ca²⁺-activated Cl^– currents. The current secretion model states that fluid production requires transacinar Cl^– movement and is thus associated with Cl^– efflux across the apical membrane. The model further predicts that a Ca²⁺-gated Cl channel is the source of this efflux (5, 32). In agreement with this model, electrophysiological experiments performed in human parotid acinar cells confirmed the presence of a Ca²⁺-activated Cl^– current. Fig. 4A, left, shows time-dependent, outwardly rectifying Cl^– currents in response to 2-s voltage pulses in cells dialyzed with 250 nM intracellular [Ca²⁺]. Large tail currents were seen when the V_m was changed to a potential of –80 mV at the end of the test pulse. In contrast, no current was recorded in cells dialyzed with a Ca²⁺-free solution (not shown; 20 mM EGTA and 0 Ca²⁺; n = 3), suggesting that these currents were due to activation of a Ca²⁺-dependent Cl channel and that relatively little voltage-activated Cl^– current is present in human parotid acinar cells. Moreover, the outward currents shown in Fig. 4A, left were nearly abolished and the reversal potential shifted +49 ± 26 mV (n = 3) in acinar cells bathed in 139 mM glutamate/1 mM chloride (Fig. 4A, right), indicating that the current was Cl^– selective. Further support for the presence of Ca²⁺-activated Cl channels was obtained using niflumic acid (NFA), a chloride channel antagonist, which is relatively specific for this channel type in salivary gland acinar cells (30). The Ca²⁺- and time-dependent Cl^– currents observed at positive voltages were blunted by 100 µM NFA. Fig. 4B shows current-voltage relationships obtained before (solid squares) and after (open circles) exposure to NFA (n = 4). The Ca²⁺-dependent Cl^– current measured at the end of the 2-s voltage step to +100 mV was blocked 88 ± 2% by 100 µM niflumic acid. The above properties are hallmarks of Ca²⁺-gated Cl channels (1, 16, 22, 30). Recent results indicate that the molecular identity of the channel responsible for the Ca²⁺-gated Cl^– current may be a member of the BEST gene family (16, 17). Consistent with this possibility, Northern blot analysis detected BEST2 transcripts in both human and mouse parotid tissues (Fig. 4C). However, the array probe detected BEST2 message in all mouse samples but failed to detect significant levels of BEST2 transcript in three out of the four human samples. This array probe was generated from a mouse BEST2 cDNA, which was 77% identical to the homologous human sequence; this difference in sequence likely explains the less robust BEST2 signal for human samples when using the standard array hybridization protocol. Indeed, optimization of the Northern blot analysis conditions for this BEST2 probe detected transcripts without difficulty in human parotid tissue.

View larger version (19K): [in this window] [in a new window]   Fig. 4. Ca2+-activated Cl– currents in human parotid acinar cells. Cl– currents were recorded from cells that were dialyzed with a pipette solution containing 250 nM [Ca2+] to activate Ca2+-activated Cl channels. A: representative raw Cl– current traces recorded from the same cell in 140 mM extracellular chloride (A, left) or 1 mM chloride and 139 mM glutamate (A, right). The membrane voltage was varied between –80 to +100 mV from a holding potential of –0 mV. B: summary of average current-voltage (I/V) plots obtained at the end of the test pulse from cells (n = 4) exposed to 0 (solid squares) or 100 µM niflumic acid (NFA; open circles). The membrane voltage was varied between –80 to +100 mV from a holding potential of –50 mV. The apparent reversal potential was –20 ± 1 mV. After correction for the liquid junction potential, it was –30 mV, which is reasonably close to the calculated value for the equilibrium potential for Cl– (–25 mV). C: Northern blot analysis detected BEST2 transcripts in human (lane H) and mouse (lane M) parotid gland RNA preparations (see METHODS for details). Arrow indicates the approximate expected size of the transcript (see Table 1).

View larger version (38K): [in this window] [in a new window]   Fig. 5. Maxi-K and IK1 Ca2+-dependent K currents in human parotid acinar cells. K+ currents were recorded from representative cells, as described in METHODS. A: current-voltage plots in the absence (left) and in the presence of clotrimazole (right). Insets: raw data from depolarizations to –100, –60, –20, +20, and +60 mV from a –60 mV holding potential. Note that control currents have both IK1 and maxi-K. Main figures are currents at the end of test pulse to the indicated potential in the absence (left) and presence (right) of 300 nM clotrimazole. Dashed lines represent the time- and voltage-independent IK1 current. Clotrimazole blocks most of the IK1 activity (about 75%) [and increases maxi-K; see (47)]. Cell was patched with 250 nM Ca2+. B: another cell (also patched with 250 nM Ca2+) already treated with 300 nM clotrimazole (left) followed by clotrimazole + 1 µM paxilline. Paxilline blocks all the time- and voltage-dependent maxi-K. C: raw single-channel records (right) and single-channel I-Vs (left). Pairs of single-channel records from each of three excised inside/out patches exposed to 1 µM, 160 nM, and 250 nM Ca2+ (top to bottom). The top patch showed only maxi-K channels, the middle showed only IK1, and the bottom had both. The main figure contains individual single-channel current amplitudes at the indicated potentials. Each type of symbol represents a patch from different cells—when both channels were recorded, the same symbol for each was used. Note that the human IK1 conductance (22 pS) is exactly the same as for mouse, and the human 162 pS value is relatively close to the 140 pS value found in mouse (35). D: Northern blot analysis detected IK1 (left) and maxi-K (right) transcripts in human (lane H) and mouse (lane M) parotid gland RNA preparations (see METHODS for details). Arrows indicate the approximate expected size of the transcripts (see Table 1).

	DISCUSSION

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A fluid secretion model is proposed in Fig. 6 on the basis of the results of our molecular and functional analyses of the human parotid gland and from other model systems (5, 32). This model predicts that transepithelial Cl^– movement acts as the driving force for fluid secretion in human parotid acinar cells. Transepithelial Cl^– movement requires that the intracellular [Cl^–] is elevated above its electrochemical equilibrium and that the membrane potential remains more hyperpolarized than the Cl^– equilibrium potential during stimulation to maintain the driving force for apical Cl^– efflux. Indeed, the intracellular [Cl^–] of human parotid acinar cells was 62 mM, more than fourfold higher than predicted from the Cl^– electrochemical equilibrium (62 mM vs. the predicted 15 mM if passive diffusion were operative), and the membrane potential remained hyperpolarized during muscarinic receptor activation (–63 ± 2 mV). These functional measurements are similar to those previously made in other mammalian model systems (11, 41, 54), suggesting that human acinar cells rely on the same ion transport mechanisms to generate saliva by transepithelial Cl^– movement. Although not shown in the secretion model (Fig. 6), numerous aquaporin (AQP) water channels are expressed in human salivary glands (14, 15, 33). For example, AQP5 has been localized to the apical surface of human and rat salivary gland acinar cells (15, 18, 28), where it has been demonstrated to play an important part in stimulated transcellular water movement in mouse salivary glands (21, 26). The importance of water permeability to salivary gland function is reflected in the number of aquaporin isoforms detected in human and mouse parotid tissues, including AQP5 (see Table 2; also positive by Northern blot analysis, not shown).

The model shown in Fig. 6 includes basolateral Na⁺-K⁺-ATPase (51), which pumps Na⁺ out of the cell at the expense of ATP hydrolysis and consequently creates a large inward-directed Na⁺ chemical gradient (see Table 2). Na⁺-dependent Cl^– uptake mechanisms would necessarily be located in the basolateral membrane of acinar cells, where they exploit the Na⁺ gradient to elevate intracellular Cl^– above its electrochemical equilibrium. Consistent with this model, we detected bumetanide-sensitive Na⁺-K⁺-2Cl^– cotransporter activity and NKCC1 gene expression in human parotid acinar cells (Fig. 2). We previously found that a null mutation in Nkcc1 (SLC12A2) eliminated cotransporter activity in mice and reduced in vivo stimulated secretion greater than 60%, thus demonstrating that this gene encodes for the basolateral Na⁺-K⁺-2Cl^– cotransporter in mouse salivary gland acinar cells (8). The residual saliva produced in Nkcc1 null mice has been associated with NaCl uptake (in exchange for HCO₃^– and H⁺) that is mediated by the paired Cl^–/HCO₃^– and Na⁺/H⁺ antiporters. In agreement with this possibility, molecular and functional evidence in the current as well as prior studies in rodents (8, 36) suggests that the DIDS-sensitive anion exchanger AE2 (SLC4A2) is most likely responsible for much of this basolateral exchanger activity in acinar cells (Fig. 3). However, the anion exchanger activity was only modestly DIDS-sensitive in human parotid acinar cells; thus there is the distinct possibility that AE2 is not the exclusive anion exchanger in this tissue. In fact, transcripts for AE4 and several members of the SLC26A gene family, some of which can carry out anion exchange (45), were detected by microarray. The Na⁺/H⁺ exchanger NHE1 is the primary regulator of acinar cell intracellular pH, as verified in Nhe1-3 (Slc9a1, Slc9a2, and Slc9a3) null mice (7). NHE1 is likely to be functionally coupled to the anion exchanger activity. Indeed, Nhe1^–/– mice secrete significantly less saliva (38), demonstrating the importance of the Na⁺/H⁺ exchanger Nhe1 in salivary gland function. Consistent with the functional significance of this Na⁺/H⁺ exchanger in human salivary acinar cells as well, Na⁺/H⁺ exchanger activity with an NHE1-like sensitivity to the amiloride-derivative EIPA (53), and NHE1 messenger RNA, were detected in human parotid glands.

Iwatsuki et al. (20) first demonstrated the presence of Ca²⁺-dependent K⁺ and Cl^– conductances in rat and mouse salivary gland acinar cells, but this study did not determine the nature of these currents. Both muscarinic and P-type nucleotide receptors are coupled to an increase in [Ca²⁺]_i in human parotid acini (4). This increase in [Ca²⁺]_i is thought to trigger the activation of both K and Cl channels involved in fluid secretion. In agreement with this premise, we found in human parotid acinar cells that intracellular Ca²⁺ stimulated a paxilline-sensitive and voltage-dependent, large-conductance K channel and a clotrimazole-sensitive, intermediate-conductance K channel, consistent with the detection of transcripts for KCNMA1 (maxi-K) and KCNN4 (IK1), respectively (Fig. 5). Similar to our results, a Ca²⁺- and voltage-activated K channel with a large-unit conductance of 160–165 pS (27, 37) and a Ca²⁺-activated intermediate K⁺ conductance (37) were previously detected in human salivary cells. However, in the present study, we did not detect a Na⁺-permeable current (27). In addition, an increase in the intracellular Ca²⁺ also stimulated a niflumic acid-sensitive Cl^– current, and transcripts were identified by Northern blot analysis for the BEST2 Ca²⁺-gated Cl channel (Fig. 4). On the basis of the current literature, the BEST2 gene most likely encodes the Ca²⁺-dependent Cl channel expressed in salivary gland acinar cells (16, 17); however, there are other candidate Ca²⁺-gated Cl channel genes. Indeed, our microarray screen of the human and mouse salivary glands detected the expression of other BEST genes, as well as several members of the CLCA family of putative Ca²⁺-gated Cl channel genes (24).

In summary, the present study provides a comprehensive evaluation and confirmation of the ion transport proteins thought to be involved in the fluid secretion process in salivary gland acinar cells. Our results demonstrate that the ion transport mechanisms in human parotid glands are equivalent to those detected in mouse and most other mammalian salivary glands, and thus, confirm that animal models provide valuable systems for developing and testing clinical therapies to alleviate salivary gland dysfunction.

	GRANTS

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
This work was supported in part by National Institutes of Health Grants DE09692, DE08921 (J. E. Melvin), and DE016960 (to T. Begenisich).

	ACKNOWLEDGMENTS

 
The authors thank Jill Thompson, Laurie Koek, Jennifer Scantlin, Mark Wagner and Pam McPherson for expert technical assistance. We also thank Dr. John Coniglio for his assistance in obtaining human parotid tissue.

	FOOTNOTES

 

Address for reprint requests and other correspondence: J. E. Melvin, Center for Oral Biology, Medical Center Box 611, Univ. of Rochester, 601 Elmwood Ave., Rochester, NY 14642 (e-mail: james_melvin{at}urmc.rochester.edu)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

^* T. Nakamoto, A. Srivastava, and V. G. Romanenko contributed equally to this article.

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