Journal of Histochemistry and Cytochemistry, Vol. 49, 1045-1054, August 2001, Copyright © 2001, The Histochemical Society, Inc.


ARTICLE

Carbonic Anhydrase II Associated with Plasma Membrane in a Human Pancreatic Duct Cell Line (CAPAN-1)

Laetitia Alvarezb, Marjorie Fanjulb, Nicholas Carterc, and Etienne Hollandeb
a Laboratoire de Biologie Cellulaire et Moléculaire des Epithéliums
b Université Paul Sabatier, Toulouse, France
c Department of Child Health, St George's Hospital, Medical School, University of London, London, United Kingdom

Correspondence to: Etienne Hollande, Laboratoire de Biologie Cellulaire et Moléculaire des Epithéliums, Université Paul Sabatier, 38 rue des 36 Ponts, 31400 Toulouse, France. E-mail: hollande@lmtg.ups-tlse.fr


  Summary
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Materials and Methods
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The subcellular distribution of carbonic anhydrase II, either throughout the cytosol or in the cytoplasm close to the apical plasma membrane or vesicular compartments, suggests that this enzyme may have different roles in the regulation of pH in intra- or extracellular compartments. To throw more light on the role of pancreatic carbonic anhydrase II, we examined its expression and subcellular distribution in Capan-1 cells. Immunocytochemical analysis by light, confocal, and electron microscopy, as well as immunoblotting of cell homogenates or purified plasma membranes, was performed. A carbonic anhydrase II of 29 kD associated by weak bonds to the inner leaflet of apical plasma membranes of polarized cells was detected. This enzyme was co-localized with markers of Golgi compartments. Moreover, the defect of its targeting to apical plasma membranes in cells treated with brefeldin A was indicative of its transport by the Golgi apparatus. We show here that a carbonic anhydrase II is associated with the inner leaflet of apical plasma membranes and with the cytosolic side of the endomembranes of human cancerous pancreatic duct cells (Capan-1). These observations point to a role for this enzyme in the regulation of intra- and extracellular pH. (J Histochem Cytochem 49:1045–1053, 2001)

Key Words: carbonic anhydrase II, HCO3- secretion, Golgi apparatus, intracellular trafficking, pancreatic duct cells, cell culture


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THE FAMILY OF CARBONIC ANHYDRASES (CA, EC 4.2.1.1) comprises 14 isoforms characterized by tissue-specific expression and different subcellular localizations. These enzymes catalyze the reversible hydration reaction of carbon dioxide and regulate acid–base balance in various organs (Carter 1972 ). CA II is one of the better characterized isoforms. In the digestive tract, it is present in epithelia such as those of the parotid and submandibular glands (Parkkila et al. 1994 ), esophagus (Christie et al. 1997 ), stomach (Parkkila et al. 1994), liver (Carter et al. 1989 ), gallbladder (Juvonen et al. 1994 ), and intestine (Lonnerholm et al. 1988 ). In the pancreas, CA II has been detected only in duct cells (Kumpulainen and Jalovaara 1981 ). Pancreatic duct cells secrete a bicarbonate (HCO3-)-rich fluid. This secretin-dependent secretion is believed to be regulated by the CFTR (cystic fibrosis transmembrane conductance regulator) (Gray et al. 1993 ). It has been suggested that CA II is responsible for the production of HCO3- ions secreted at the apical poles of duct cells via a Cl-/HCO3- exchanger (Novak and Greger 1988 ) and in some species likely by an additional HCO3- channel (Mahieu et al. 1994 ; Ishiguro et al. 1996 ). Various subcellular distributions of CA II have been described. In primary cultures of mouse pancreatic duct cells (Githens et al. 1992 ), this enzyme was observed in the cytosol and along basolateral membranes, whereas in human pancreatic duct cells of the Capan-1 cell line, CA II has been observed in cytoplasm underneath apical plasma membranes (Mahieu et al. 1994 ). In narrow cells of the initial or intermediate segments of epididymal cells, Hermo et al. 2000 have described the presence of CA II in the cytosol in the neighborhood of vesicles, whose membranes are rich in vacuolar H+ ATPase. These authors suggested that the H+ produced by the CA II and secreted by the vacuolar H+ ATPase acidify the epididymal lumen after fusion of the vesicles with the apical plasma membrane. In red blood cells, a membrane CA II associated with a Cl-/HCO3- band 3 exchanger has been described (Parkes and Coleman 1989 ; Kifor et al. 1993 ). These observations suggest that CA II could have specific roles in relation to its subcellular distribution. To attempt to elucidate the roles of CA II in human pancreatic duct cells, we examined the expression of this enzyme, its subcellular distribution, and its association with organelles in cultured Capan-1 cells. This cell line represents a good model of pancreatic duct cells because, despite their neoplastic transformation, Capan-1 cells have retained the ability of healthy duct cells to secrete ions (Levrat et al. 1988 ; Cheng et al. 1998 ). They polarize spontaneously during growth in vitro and at confluence form domes, an indicator of transepithelial exchange of water and electrolytes (Levrat et al. 1988 ). They express various anionic channels (Becq et al. 1992 ; Mahieu et al. 1994 ), including the CFTR channel (Becq et al. 1993 ), as well as membrane-bound CA IV (Mahieu et al. 1994 ; Mairal et al. 1996 ) and cytoplasmic CA II (Mahieu et al. 1994 ). In this study we show the presence of a CA II associated with apical plasma membranes and with Golgi compartments in polarized Capan-1 cells.


  Materials and Methods
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Materials and Methods
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Cell Culture
Cells of the Capan-1 cell line, isolated (Fogh et al. 1977 ) from a hepatic metastasis in a patient with a pancreatic adenocarcinoma, were used. The cells were maintained in culture as described elsewhere (Mahieu et al. 1994 ; Mairal et al. 1996 ).

Detection of CA II
Cytoenzymological Detection of CA. The enzymatic activity of CA was demonstrated according to the Hansson's method by both light and electron microscopic examination of cells fixed in situ with 2.5% glutaraldehyde (15 min, 4C) (Mahieu et al. 1994 ).

Immunocytochemistry on Fixed Cells. CA II was detected by immunoperoxidase and immunofluorescence. Reactions were performed on 1- to 6-day-old cells cultivated on glass slides in Leighton tubes, fixed in situ with paraformaldehyde (PFA 3%), then permeabilized or not with ethanol. Cells were incubated successively with polyclonal sheep immunserum directed against human CA II (Serotec, Oxford, UK; 1:100, 1 hr) containing 0.1% bovine serum albumin (BSA) followed by a serum of rabbit anti-sheep IgGs coupled to peroxidase (Pierce, Rockford, IL; 1:400, Tris–BSA, pH 7.6, 45 min). Antigen–antibody complexes were revealed using 3'-amino-9-ethyl carbazole (AEC) (Sigma Chemical; St Louis, MO) in the presence of hydrogen peroxide. Some immunoperoxidase reactions were carried out on cells fixed with paraformaldehyde and embedded in paraplast. For immunofluorescence, antigen–antibody complexes were revealed using anti-sheep IgG coupled to fluorescein isothiocyanate (FITC) (Nordic Immunological Laboratories; Tilburg, The Netherlands). In this case, preparations were observed with a confocal laser scanning microscope (LSM410; Carl Zeiss, Oberkochen, Germany). Fluorescence excitation was produced by an argon laser at a wavelength of 488 nm.

Immunocytochemistry on Living Cells. To detect CA II on the surface of Capan-1 cells, immunofluorescence reactions were carried out on living cells. Under these conditions, the cells were not permeabilized and only the extracellular epitopes of CA are revealed. Briefly, after blocking of nonspecific sites, cells were incubated with anti-CA II antibodies (1:50 in culture medium with fetal calf serum 10%, 2 hr, 4C), then rinsed and incubated with anti-sheep IgG antibodies coupled to FITC (1:400, 4C, 2 hr), and fixed with a mixture of methanol (95%)–acetic acid (5%) (-20C, 7 min). Similar reactions were performed to compare the membrane distribution of CA II and CA IV. In this case, polyclonal antibodies directed against a peptide sequence (residues 1–18) of human GPI-anchored CA IV were used (Wistrand et al. 1999 ). Antigen–antibody complexes were revealed using rabbit anti-sheep IgG coupled to FITC (Nordic Immunological). The preparations were observed by confocal microscopy.

Controls were carried out on both living and fixed cells. Cells were incubated (a) with primary antibody previously fully bound to purified bovine CA II (10 µg/ml, 3 hr; Sigma), or (b) with only secondary antibody coupled to peroxidase or FITC.

Immunoblotting
Cell Homogenates. To estimate the expression of CA II during growth of Capan-1 cells, immunoblots were made on cell homogenates of 1–6-day-old cultures. Cells were rinsed in PBS, then scraped off. After centrifugation (5 min, 2000 x g), the pellet was solubilized for 20 min at 4C in 1 ml of lysis buffer [HEPES 20 mM, NaCl 150 mM, EDTA 1 mM, Nonidet P-40 1%, aprotinin 25 µg/ml, leupeptin 10 µg/ml, pepstatin 15 µg/ml, phenylmethylsulfone (PMSF) 1 mM, DNase 2 µg/ml]. The lysate was centrifuged (5 min, 14,000 x g) and the supernatant collected. The supernatant was stored at -80C or used directly for immunoblotting. Proteins were assayed according to Lowry et al. 1951 . The cell homogenates equivalent to 50 µg of protein were loaded onto 10% SDS-PAGE, then electroblotted onto nitrocellulose membranes. After saturation [Tris buffer solution (TBS)–Tween 20 (0.1%)–skimmed milk (5%)], CA II was detected by incubating membranes successively with anti-CA II antibodies (Serotec) (1:2000 in TBS–Tween–milk overnight at 4C), then with anti-sheep IgG coupled with peroxidase (Pierce) (1:10,000). The antigen-antibody complexes were revealed by chemoluminescence (ECL; Amersham, Poole, UK). Immunoreactivity was quantified by densitometry (Biocom; Ulis, France).

Plasma Membranes. Plasma membranes were isolated on a continuous Percoll gradient according to the method of Record et al. 1982 . Experiments were performed at different ionic strengths. Briefly, 8 x 107 washed cells, placed in Tris buffer 25 mM, pH 9.6, KCl 100 mM, MgCl2 5 mM, ATP 1 mM, were sonicated and centrifuged (1000 x g, 10 min). Under conditions of low ionic strength, the supernatant was adjusted to pH 7.4 and taken up in 18 ml of a mixture of 11 ml Percoll, 2.2 ml H2O, 4.8 ml Tris (40 mM), pH 7.4, KCl (40 mM), MgCl2 (2 mM). The membrane fraction was recovered after centrifugation at 160,000 x g for 10 min (60Ti rotor; Beckman). The Percoll was eliminated by two successive centrifugations (130,000 x g, 30 min). Similar experiments under conditions of high ionic strength were also conducted. The pH of the supernatant was adjusted to 9.6. The Percoll was mixed with Tris buffer 100 mM, pH 9.6, KCl 400 mM, MgCl2 20 mM, and the pH of the mixture after addition of supernatant was adjusted to 9.6. All buffers contained leupeptin (10 µg/ml), aprotinin (25 µg/ml), pepstatin (15 µg/ml), and PMSF (1 mM). The membrane proteins (15 µg) were immunoblotted as described above for the cell homogenates.

Intracellular Traffic of CA II
Two types of experiments were carried out to analyze the intracellular traffic of CA II. First, immunocytochemical reactions for co-labeling CA II and Golgi compartments using anti-CA II antibodies (1:100) and anti-Golgi zone antibodies (1:80) (Valbiotech; Paris, France) were performed on fixed and permeabilized 3-day-old cells. Antigen–antibody complexes were revealed with anti-IgG coupled to FITC (1:400) for CA II and anti-IgG coupled with tetramethyl-rhodamine isothiocyanate (TRITC; Nordic Immunological) (1:200) for the Golgi marker. Preparations were observed by confocal microscopy. Second, CA II was examined on cells treated with brefeldin A (BFA). Six-day-old cells were treated for 2, 5, 9, 14, or 16 hr with BFA (5 µg/ml; Sigma) solubilized in ethanol. CA II was then detected by immunoperoxidase reactions. The percentage of CA II-immunoreactive cells was then determined. The following controls were carried out: (a) Immunocytochemical reactions were performed on the cultures to estimate the distribution and intensity of CA II immunolabeling before treatment with BFA or ethanol; (b) cells were cultured in the presence of ethanol (1 µl/ml), the solvent of BFA for each duration of treatment (2, 5, 9, 14, or 16 hr) followed by immunocytochemistry for detection of CA II; (c) check of reversibility of the action of BFA: cells treated with BFA for 2, 5, 9, 14, or 16 hr were then maintained in a complete medium without ethanol or BFA. At 48 hr later the cultures were fixed for immunoperoxidase staining.


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Expression of CA II in Capan-1 Cells
The immunoblots of the cell homogenates of 1–6- day-old Capan-1 cells revealed the presence of a single CA II-immunoreactive protein of 29 kD irrespective of the age of the culture (Fig 1a1, Lanes 1–6). Densitometric analysis showed that the expression of this protein increased gradually during growth in culture; it was threefold higher in post-confluent cells (Day 6) than in the cells at the start of growth (Day 2) (Fig 1a2). The co-migration with the purified bovine CA II (Fig 1a1, Lane 0) demonstrated that this protein was a CA II. The absence of crossreaction of the anti-CA II antibody with the human CA IV, another isoform of CA expressed in Capan-1 cells, was also verified by immunoblotting. In Fig 1b1 it can be seen that the anti-CA II antibody that recognized the purified bovine CA II (Fig 1b1, Lane 2) and the CA II expressed by Capan-1 cells (Fig 1b1, Lane 1) did not recognize the purified human 35-kD CA IV (Fig 1b1, Lane 3). Conversely, the anti-CA IV antibody did not recognize the 29-kD CA II expressed by Capan-1 cells nor the purified CA II (Fig 1b2, Lanes 1 and 3). This antibody revealed the purified human 35-kD CA IV (Fig 1b2, Lane 2) and two 35-kD and 55-kD proteins in the Capan-1 cell homogenates (Fig 1b2, Lane 1).



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Figure 1. Expression of CA II during growth of Capan-1 cells in culture. (a1) Immunoblotting after migration on SDS-PAGE, revealing a CA II of 29 kD. Lane 0, purified bovine CA II. Lanes 1 to 6, cell homogenates of 1- to 6-day-old cells. (a2) Densitometric analysis of the immunoblotting shown in a1. Demonstration of the specificity of the anti-CA II and anti-CA IV antibodies. (b1) Immunoblotting with anti-CA II antibody. Lane 1, cell homogenate; Lane 2, purified bovine CA II; Lane 3, purified human CA IV. (b2) Immunoblotting with anti-CA IV antibody. Lane 1, cell homogenate; Lane 2, purified human CA IV; Lane 3, purified bovine CA II.

Distribution of CA II in Capan-1 Cells
The localizations of CA II were determined from immunocytochemical reactions on fixed and permeabilized cells. At confluence, some cells exhibited strong intracytoplasmic immunoreactivity. This was mostly throughout the cytoplasm (Fig 2a) and especially in the neighborhood of the nucleus (Fig 2a, arrows). Other cells presented small immunofluorescent spots in their periphery (Fig 2a, arrowheads). In young cultures (1–3 days), most of the cells were non-polarized and exhibited intracytoplasmic immunoreactivity. This immunoreactivity was seen in the nuclear envelope (Fig 2b and Fig 2c, arrows) and in the cytoplasm around the nuclei, either in a horseshoe or circular pattern (Fig 2c, small arrows) surrounded by many small CA II-immunoreactive granules. After Day 3, most of the cells were weakly labeled on the nuclear envelope but presented immunoreactivity in the form of granulations throughout the cytoplasm. On the other hand, in post-confluent cultures most cells had become polarized, in which the immunoreactivity was noted mainly in cytoplasmic digitations and microvilli (Fig 2d and Fig 2e, arrows). In cross-sections of the cell layer, the immunoreactivity was seen at the apical poles of polarized cells (Fig 2f, arrows). In some cases, labeling was also observed along basolateral membranes (Fig 2f, arrowheads). Electron microscopic examination of immunoperoxidase reactions demonstrated strong immunoreactivity on the plasma membranes of the microvilli on polarized cells (Fig 3a). CA activity was also revealed on apical plasma membranes after the Hansson's reaction. Precipitates from the enzyme reaction were noted on both the outer and the inner leaflets of the plasma membrane (Fig 3b and Fig 3c, arrows) as well as in the cytosol. Immunofluorescence studies were conducted on living cells in an attempt to determine whether the CA II lay on the inner or the outer side of the membrane. No CA II immunoreactivity was observed on the surface of Capan-1 cells (Fig 3d). On the other hand, strong CA IV immunoreactivity was detected at the cell surface (Fig 3e). Superimposition of the CA IV fluorescence image on the same field observed by interference microscopy (Fig 3f, small arrows) provided further support for this localization.



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Figure 2. (a) General appearance of the distribution of CA II immunofluorescence in a 3-day-old culture. Note the cytoplasmic immunofluorescence with a higher intensity in perinuclear regions (arrows), and the peripheral immunofluorescence as small spots (arrowheads). Confocal microscopic image in the plane of the nucleus (N). Bar = 6 µm. (b) Immunoperoxidase reaction on non-polarized Capan-1 cells at low magnification. Note the presence of strong CA II immunoreactivity on the nuclear envelope (arrows) and the granular staining in perinuclear cytoplasm. Bar = 20 µm. (c–f) Details of the distribution of CA II immunoreactivity in the nuclear envelope (c, arrow), the many secretory granules in perinuclear regions (c, small arrows), the apices of cells in a polar view (d and e, arrows) and in cross-section (f, arrows) basolateral membranes of some cells (f, arrowheads) Bars = 10 µm. BP, basolateral pole; AP, apical pole. b and c, 3-day-old cultures; d–f, 6-day-old cultures.



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Figure 3. Distribution of CA II in plasma membranes of polarized cells. (a) Electron microscopic image of CA II immunoreactivity in membranes of microvilli (Mv) after immunoperoxidase reaction. Bar = 0.1 µm. (b,c) Subcellular distribution of CA after Hansson's reaction. (b) Localization of CA reactivity at the apical pole (AP) of a polarized cell. Note the strong reactivity on apical membranes and microvilli (Mv) and in the cytosol and mitochondria (Mi). Bar = 10 µm. (c) Detail of the distribution of precipitates after Hansson's reaction, showing CA activity on either side of the plasma membrane (arrows). Bar = 0.2 µm. (d–f) Localization of CA II (d) and CA IV (e,f) after immunofluorescence reactions on living cells. Note the absence of immunoreactivity in d and the CA IV immunoreactivity on the cell surface as shown by superimposition of the fluorescence image on that from interference microscopy (f). Bars = 10 µm.

The controls designed to check the specificity of the immunocytochemical reactions were all negative.

Demonstration of the Association of CA II with Plasma Membranes
As further support for the presence of CA II associated with the plasma membranes of polarized cells, immunoblots were made on fractions of plasma membranes prepared under conditions of different ionic strength. Fig 4 shows the presence of a 29-kD CA II-immunoreactive protein from plasma membranes purified under conditions of low ionic strength (Fig 4, Lane 3). This protein migrated in the same way as the CA II found in the cell homogenates (Fig 4, Lane 1) or the purified bovine CA II (Fig 4, Lane 2). On the other hand, in fractions of plasma membranes purified under conditions of high ionic strength, no CA II-immunoreactive protein was detected (Fig 4, Lane 4).



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Figure 4. Demonstration of CA II associated with plasma membranes. Immunoblotting of plasma membranes purified on a Percoll gradient. Lane 1, purified bovine CA II; Lane 2, cell homogenate; Lanes 3 and 4, fraction of plasma membranes purified under conditions of low (Lane 3) and high ionic strength (Lane 4).

CA II Traffic
Treatment of 6-day-old cultures with BFA led to a marked reduction in the number of cells showing membrane CA II immunoreactivity. In the untreated cultures (Fig 5a) or those treated with ethanol alone (1–14 hr) or in cells treated with BFA for short periods (1–4 hr), 48% of cells presented CA II immunoreactivity on their surface, whereas only 30% of cells presented such immunoreactivity after 9 hr of treatment with BFA (Fig 5b) and only 2.1% in cultures treated for 14 hr (Fig 5c). After 14 hr of treatment, immunoreactivity was observed in filamentous or elongated intracytoplasmic structures but not on plasma membranes (Fig 5c, arrows). Treatment at a concentration of 5 µg/ml BFA for more than 14 hr was found to be cytotoxic. To check the absence of toxicity of BFA, cells treated for 14 hr were maintained in a medium without ethanol and BFA. Immunocytochemistry showed the reappearance of CA II on apical plasma membranes.



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Figure 5. Progressive decrease in CA II immunoreactivity on the surface of polarized cells after treatment with BFA. (a) Control: note the strong labeling on the surface of cells. (b) Cells treated with BFA for 9 hr. Note the dramatic decrease in labeling with respect to untreated cells (a). (c) Cells treated with BFA for 14 hr. Note absence of immunoreactivity on the surface of cells. Arrows indicate CA II-immunoreactive filamentous structures localized in the perinuclear region. Bars = 10 µm.

To find out whether CA II was associated with Golgi compartments, double-labeling experiments were conducted on 3-day-old cells using antibodies against CA II and Golgi compartments. Confocal microscopic study by merging the image of CA II immunofluorescence (Fig 6a, arrows) with that of the immunofluorescence from Golgi compartments (Fig 6b, arrows) showed that the two were largely co-localized (Fig 6c).



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Figure 6. Demonstration by confocal microscopy of co-localization of CA II and Golgi compartments. (a) CA II immunoreactivity (arrow). (b) Golgi immunoreactivity (arrow). (c) Co-localization seen by merging immunoreactivity a and b (arrow). Bars = 20 µm.


  Discussion
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In this study, we demonstrated an association of CA II with apical plasma membranes of polarized cells and with membranes of Golgi compartments in human cancerous pancreatic duct cells of the Capan-1 cell line.

Capan-1 cells expressed a CA II-immunoreactive protein whose molecular weight of 29 kD corresponds to that of the human CA II described in various cell types (Sly and Hu 1995 ). This CA II was expressed in a continuous manner, although its level of expression increased gradually during cell growth in culture. This increase was concomitant with the spontaneous and progressive acquisition of a differentiated cell stage. The existence of a relationship between the expression of CA II and differentiated cell status has also been demonstrated in other human pancreatic duct cell lines (Frazier et al. 1990 ) and for enzyme systems such as alkaline phosphatases (Fanjul et al. 1991 ) or CA IV (Mahieu et al. 1994 ; Mairal et al. 1996 ) in this same cell model. In the same way, CA II in vivo is considered to be a marker for the tissue differentiation of excretory ducts in the developing rat parotid gland (Peagler et al. 1998 ). In polarized Capan-1 cells, our immunocytochemical studies revealed CA II immunoreactivity on the microvilli. On electron microscopic analysis, this immunoreactivity was localized essentially in apical plasma membranes. CA IV has also been found to be confined to these membrane domains (Mahieu et al. 1994 ; Mairal et al. 1996 ). Western blotting confirmed the specificity of the immunocytochemical reactions and provided further support for the presence of CA II associated with apical plasma membranes. Immunocytochemical analysis on living cells also pointed out different distributions of CA II and CA IV on either side of the plasma membrane. Under our experimental conditions, no CA II labeling was observed, whereas the majority of cells exhibited CA IV immunoreactivity. These results suggest that the CA II associated with apical plasma membranes of Capan-1 cells is bound to the inner leaflet. CA IV has been shown to be situated on the outer leaflet in many cell types, in line with the description of this enzyme as a GPI-anchored protein (Zhu and Sly 1990 ; Ghandour et al. 1992 ; Okuyama et al. 1992 ; Mairal et al. 1996 ). On electron microscopic examination, the CA activity after the Hansson's reaction on both inner and outer leaflets of apical plasma membranes of Capan-1 cells was thought to indicate sites of activity of CA II and CA IV, respectively. In epithelial cells, CA II has been localized in apical cytoplasm underlying the plasma membranes (Wistrand et al. 1986 ; Holthofer et al. 1987 ; Lonnerholm et al. 1988 ; Mahieu et al. 1994 ), but there is doubt about the presence of membrane CA II in cells of the surface epithelium of cecum (Lonnerholm et al. 1988 ) and pancreatic duct cells in primoculture (Githens et al. 1992 ), where the location has been described as basolateral. In erythrocytes, CA II has been demonstrated in plasma membranes associated with the carboxyl terminal of the Cl-/HCO3- exchanger (band 3) (Vince and Reithmeier 1998 ). In Capan-1 cells, experiments on preparations of plasma membranes purified under conditions of high or low ionic strength showed that CA II was associated with the membrane by weak interactions. This association poses the problem of the intracellular traffic of this enzyme. Two possibilities can be suggested: (a) the cytosolic CA II underlying apical plasma membranes may associate directly with the inner leaflet under certain physiological conditions, or (b) CA II may be associated with membranes of the organelles involved in the transport of membrane proteins and may therefore be targeted to apical plasma membranes by transport vesicles. The cytoplasmic CA II immunoreactivity observed on the nuclear envelope or on granular structures distributed in perinuclear or supranuclear regions, depending on the stage of polarization of the cells, suggests that the CA II is associated early with endomembranes. The demonstration of a co-localization of CA II with a marker for the Golgi apparatus indicated that CA II was in fact associated with Golgi compartments. Furthermore, the disappearance of the CA II immunoreactivity on apical plasma membranes of cells treated with BFA, a drug that disrupts the Golgi apparatus (Fujiwara et al. 1988 ) and thereby blocks the traffic of membrane proteins or those secreted by the merocrine pathway, indicates that CA II in Capan-1 cells may be transported to apical plasma membranes by virtue of its association with Golgi apparatus membranes. These results differ from those found in the coagulating gland of the rat, in which the isoform CA II, although secreted, was not seen to be associated with endomembranes (Wilhem et al. 1998 ). In Capan-1 cells, we suggest that the CA II, which does not possess a peptide signal, is synthesized in free polyribosomes, then binds to the cytosolic leaflet of membranes of endoplasmic reticulum or Golgi compartments, which in turn become vesicles and so transport it to the apical plasma membrane. The physiological significance of a CA II linked to the endomembranes and the plasma membrane was assumed to involve synthesis of HCO3- ions or protons regulating extra- and intracellular pH. In enterocytes, CA II is believed to be involved in the dissipation of intracellular pH gradients stemming from H+-coupled peptide transport, although the enzyme was not described to be associated with cell organelles (Stewart et al. 1999 ). In epididymal narrow cells, CA II was localized near vesicles and was believed to play a role in the acidification of the epididymal lumen by producing H+ ions that are expelled into the matrix of the vesicle by a vacuolar H+ ATPase (Hermo et al. 2000 ). In Capan-1 cells, CA II could well be associated with a transmembrane protein, as has been demonstrated in the erythrocyte (Kifor et al. 1993 ; Vince and Reithmeier 1998 ). This would enable transfer of HCO3- ions or H+ either to the extracellular medium or to the matrix of membrane organelles. In conclusion, in Capan-1 cells, CA II associated with the cytosolic leaflets of membranes (of both the cells and their organelles) point to a role for this enzyme in the regulation of intra- and extracellular pH.


  Acknowledgments

Supported by the Association Française de Lutte contre la Mucoviscidose (AFLM) and by the Ministère de l'Enseignement Supérieur et de la Recherche (MESR).

We would like to thank Dr Esclassan for his fruitful discussion and assistance, and Mr F. Stefani and Mr C. Baritaud for their technical assistance.

Received for publication October 13, 2000; accepted February 21, 2001.


  Literature Cited
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Becq F, Fanjul M, Mahieu I, Berger Z, Gola M, Hollande E (1992) Anion channels in a human pancreatic cancer cell line (Capan-1) of ductal origin. Pflugers Arch 420:46-53[Medline]

Becq F, Fanjul M, Merten M, Figarella C, Hollande E, Gola M (1993) Possible regulation of CFTR-chloride channels by membrane-bound phosphatases in pancreatic duct cells. FEBS Lett 327:337-342[Medline]

Carter MJ (1972) Carbonic anhydrase: isoenzymes, properties, distribution and functional significance. Biol Rev 47:465-513[Medline]

Carter N, Wistrand PJ, Lönnerholm G (1989) Carbonic anhydrase localization to perivenous hepatocytes. Acta Physiol Scand 135:163-167[Medline]

Cheng HS, Leung PY, Cheng Chew SB, Leung PS, Lam SY, Wong WS, Wang ZD, Chan HC (1998) Concurrent and independent HCO3- and Cl- secretion in a human pancreatic duct cell line (Capan-1). J Membr Biol 164:155-167[Medline]

Christie KN, Thomson C, Xue L, Lucocq JM, Hopwood D (1997) Carbonic anhydrase isoenzymes I, II, III, and IV are present in human esophageal epithelium. J Histochem Cytochem 45:35-40[Abstract/Free Full Text]

Fanjul M, Theveniau M, Palévody C, Rougon G, Hollande E (1991) Expression and characterization of alkaline phosphatases during differentiation of human pancreatic cancer (Capan-1) cells in culture. Biol Cell 73:15-25[Medline]

Fögh J, Fögh JM, Orfeo T (1977) One hundred and twenty-seven cultured human tumor cell lines producing tumors in nude mice. J Natl Cancer Inst 59:221-226[Medline]

Frazier ML, Lilly BJ, Wu EF, Ota T, Hewett–Emmett D (1990) Carbonic anhydrase II gene expression in cell lines from human pancreatic adenocarcinoma. Pancreas 5:507-514[Medline]

Fujiwara T, Oda K, Yokota S, Takatsuki A, Ikehara Y (1988) Brefeldin A causes disassembly of the Golgi complex and accumulation of secretory proteins in the endoplasmic reticulum. J Biol Chem 263:18545-18552[Abstract/Free Full Text]

Ghandour MS, Langley OK, Zhu XL, Waheed A, Sly WS (1992) Carbonic anhydrase IV on brain capillary endothelial cells: a marker associated with the blood-brain barrier. Proc Natl Acad Sci USA 89:6823-6827[Abstract]

Githens S, Schexnayder JA, Frazier ML (1992) Carbonic anhydrase II gene expression in mouse pancreatic duct cells. Pancreas 7:556-561[Medline]

Gray MA, Plant S, Argent BE (1993) cAMP-regulated whole cell chloride currents in pancreatic duct cells. Am J Physiol 264:C591-602[Abstract/Free Full Text]

Hermo L, Adamali HI, Andonian S (2000) Immunolocalization of CA II and H+ V-ATPase in epithelial cells of the mouse and rat epididymis. J Androl 21:376-391[Abstract/Free Full Text]

Holthöfer H, Schulte BA, Pasternack G, Siegel GJ, Spicer SS (1987) Immunocytochemical characterization of carbonic anhydrase-rich cells in the rat kidney collecting duct. Lab Invest 57:150-156[Medline]

Ishiguro H, Steward MC, Wilson RW, Case RM (1996) Bicarbonate secretion in interlobular ducts from guinea-pig pancreas. J Physiol 495:179-191[Abstract]

Juvonen T, Parkkila S, Parkkila AK, Niemelä O, Lajunen LHJ, Kairaluoma MI, Perämäki P, Rajaniemi H (1994) High-activity carbonic anhydrase isoenzyme (CA II) in human gallbladder epithelium. J Histochem Cytochem 42:1393-1397[Abstract/Free Full Text]

Kifor G, Toon MR, Janoshazi A, Solomon AK (1993) Interaction between red cell membrane band 3 and cytosolic carbonic anhydrase. J Membr Biol 134:169-179[Medline]

Kumpulainen T, Jalovaara P (1981) Immunohistochemical localization of carbonic anhydrase isoenzymes in the human pancreas. Gastroenterology 80:796-799[Medline]

Levrat JH, Palevody C, Daumas M, Ratovo G, Hollande E (1988) Differentiation of the human pancreatic adenocarcinoma cell line (Capan-1) in culture and coculture with fibroblasts dome formation. Int J Cancer 42:615-621[Medline]

Lönnerholm G, Midtved T, Schenholm M, Wistrand PJ (1988) Carbonic anhydrase isoenzymes in the caecum and colon of normal and germ-free rats. Acta Physiol Scand 132:159-166[Medline]

Lowry OH, Rosebrough NJ, Lewis–Farr A, Randall RJ (1951) Protein measurement with the Folin phenol reagent. J Biol Chem 193:265-275[Free Full Text]

Mahieu I, Becq F, Wolfensberger T, Gola M, Carter N, Hollande E (1994) The expression of carbonic anhydrases II and IV in the human pancreatic cancer cell line (Capan-1) is associated with bicarbonate ion channels. Biol Cell 81:131-141[Medline]

Mairal A, Fanjul M, Hollande E (1996) Targeting of carbonic anhydrase IV is linked to the polarization of human pancreatic duct cells (Capan-1) in culture. Gastroenterol Clin Biol 20:581-590[Medline]

Novak I, Greger R (1988) Properties of the luminal membrane of isolated perfused rat pancreatic ducts. Effect of cyclic AMP and blockers of chloride transport. Pflugers Arch 411:546-553[Medline]

Okuyama T, Sato S, Zhu XL, Waheed A, Sly WS (1992) Human carbonic anhydrase IV: cDNA cloning, sequence comparison, and expression in COS cell membranes. Proc Natl Acad Sci USA 89:1315-1319[Abstract]

Parkes JL, Coleman PS (1989) Enhancement of carbonic anhydrase activity by erythrocyte membranes. Arch Biochem Biophys 275:459-468[Medline]

Parkkila S, Parkkila AK, Juvonen T, Rajaniemi H (1994) Distribution of the carbonic anhydrase isoenzymes I, II, and VI in the human alimentary tract. Gut 35:646-650[Abstract]

Peagler FD, Redman RS, McNutt RL, Kruse DH, Johansson I (1998) Enzyme histochemical and immunohistochemical localization of carbonic anhydrase as a marker of ductal differentiation in the developing rat parotid gland. Anat Rec 250:190-198[Medline]

Record M, Bes JC, Chap H, Douste–Blazy L (1982) Isolation and characterization of plasma membranes from Krebs II ascite cells using Percoll gradient. Biochim Biophys Acta 688:57-65[Medline]

Sly WS, Hu PY (1995) Human carbonic anhydrases and carbonic anhydrase deficiencies. Annu Rev Biochem 64:375-401[Medline]

Stewart AK, Boyd CAR, Vaughan–Jones RD (1999) A novel role for carbonic anhydrase: cytoplasmic pH gradient dissipation in mouse small intestinal enterocytes. J Physiol 516:209-217[Abstract/Free Full Text]

Vince JW, Reithmeier RAF (1998) Carbonic anhydrase II binds to the carboxyl terminus of human band 3, the erythrocyte Cl-/HCO3- exchanger. J Biol Chem 273:28430-28437[Abstract/Free Full Text]

Wilhem B, Keppler C, Hoffbauer G, Lottspeich F, Linder D, Meinhart A, Aumüller G, Seitz J (1998) Cytoplasmic carbonic anhydrase II of rat coagulating gland is secreted via the apocrine export mode. J Histochem Cytochem 46:505-511[Abstract/Free Full Text]

Wistrand PJ, Carter ND, Conroy CW, Mahieu I (1999) Carbonic anhydrase IV activity is localized on the exterior surface of human erythrocytes. Acta Physiol Scand 165:211-218[Medline]

Wistrand PJ, Schenholm M, Lönnerholm G (1986) Carbonic anhydrase isoenzymes CA I and CA II in the human eye. Invest Ophthalmol Vis Sci 27:419-428[Abstract]

Zhu XL, Sly WS (1990) Carbonic anhydrase IV from human lung. Purification, characterization, and comparison with membrane carbonic anhydrase from human kidney. J Biol Chem 265:8795-8801[Abstract/Free Full Text]