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From the * Department of Pharmacology and Toxicology, Dartmouth Medical School, Hanover, New Hampshire 03755; and Department of Medicine, § Department of Cell Biology, and || Sarah W. Stedman Nutrition Center, Duke University Medical Center, Durham,
North Carolina 27710
Plasma membrane Ca2+-ATPase (PMCA) and the Na+/Ca2+ exchanger participate in regulating cell function by maintaining proper intracellular Ca2+ concentrations ([Ca2+]i). In renal epithelial cells these proteins have been additionally implicated in cellular calcium absorption. The purpose of the present studies was to determine the Ca2+ extrusion mechanisms in cells derived from the proximal tubule. Homology-based RT-PCR was used to amplify PMCA transcripts from RNA isolated from mouse cell lines originating from the S1, S2, and S3 proximal tubule segments. S1, S2, and S3 cells exhibited only PMCA1 and PMCA4 products. PCR product identity was confirmed by sequence analysis. Northern analysis of proximal tubule cell RNAs revealed appropriate transcripts of 7.5 and 5.5 kb for PMCA1 and 8.5 and 7.5 kb for PMCA4, but were negative for PMCA2 and PMCA3. Western analysis with a monoclonal antibody to PMCA showed that all proximal cell lines expressed a reacting plasma membrane protein of 140 kD, the reported PMCA molecular mass. Na+/Ca2+ exchanger (NCX1) mRNA expression, analyzed by RT-PCR, protein expression by Western analysis, and functional exchange activity were uniformly absent from all proximal tubule cell lines. These observations support the idea that immortalized cells derived from the proximal tubule express PMCA1 and PMCA4, which may serve as the primary mechanism of cellular Ca2+ efflux.
Key words: calcium transport; kidney; PMCA; Na/Ca exchange; Ca-ATPaseCytoplasmic ionized calcium is tightly regulated by intracellular homeostatic mechanisms that quickly sequester calcium and, over the longer term, extrude calcium from the cell. Calcium efflux across plasma membranes is an energy-dependent process that may be
mediated by Ca2+-ATPase and by various exchanger
proteins including the Na+/Ca2+ exchanger (Philipson
and Nicoll, 1992), Na+/Ca2+, K+ exchanger (Cervetto
et al., 1989
), and H+/Ca2+ exchanger (Tsukamoto et
al., 1991
). In polarized epithelial cells, such as those
found in the intestine and the kidney, the situation is
more complicated since these cells must regulate cytoplasmic calcium when challenged by rapid and large
changes in the rate of transcellular calcium transport.
Calcium absorption by epithelial cells is a two-step process wherein calcium entry is followed by efflux. The
membrane-delimited proteins responsible for admitting calcium from the lumen are located in apical plasma
membranes, whereas those responsible for calcium efflux are located in basolateral plasma membranes.
Calcium absorption occurs throughout the nephron.
The majority of calcium is absorbed by proximal tubules, with smaller fractions recovered at more distal
sites. In proximal tubules, most calcium is transported
by a passive mechanism that is thought to proceed through the paracellular pathway, driven by osmotic
solvent flow. A smaller fraction, 15-20 percent, occurs
through a cellular pathway (Ullrich et al., 1976; Rouse
et al., 1980
; Bomsztyk et al., 1984
). Although small by
comparison with the paracellular flow, active cellular
absorption by proximal tubules amounts to some 20 µmol/min, which is approximately twice that of the distal nephron, where calcium absorption is entirely cellular. The mammalian proximal tubule consists of three
different segments: S1, S2, and S3. Calcium entry may involve voltage-dependent calcium channels (Almeida et
al., 1992
; Rose et al., 1994
; Tanaka et al., 1995
). Efflux is thought to be mediated by a Ca2+-ATPase or by Na+/
Ca2+ exchange, though the presence of these transport
mechanisms in proximal tubules cells is controversial.
The first objective of the present studies was to identify
the potential macromolecules responsible for calcium
efflux in proximal tubule cells. Studies were performed
on immortalized lines of mouse proximal tubule cells
that were derived from S1, S2, or S3 proximal tubules
(Nesbitt et al., 1995
, 1996
).
The Ca2+-ATPase is a primary active transport mechanism. Plasma membrane Ca2+-ATPases (PMCAs)1 are
P-type ATPases (Pedersen and Carafoli, 1987), encoded by four discrete genes, PMCA1-PMCA4. PMCA
gene products are homologous isoforms of ~140 kD
(Stauffer et al., 1995
) that vary in expression levels in a
tissue-dependent manner. In humans and in the rat, PMCA1 and PMCA4 mRNA and protein are the dominant isoforms in virtually all tissues, including kidney
(Stauffer et al., 1995
), whereas PMCA2 and PMCA3 are
expressed primarily in nervous tissue (Stauffer et al.,
1993
). In the kidney, PMCA2 transcripts are expressed
in most cortical nephron segments (Magocsi et al.,
1992
). The glomerulus exhibits PMCA1 mRNA (Magocsi et al., 1992
). These results apparently contrast
with the aforementioned evidence that PMCA1 and
PMCA4 are the primary renal isoforms.
Plasma membrane Na+/Ca2+ exchange is a secondary active transport mechanism, also capable of mediating cellular calcium efflux. The NCX1 Na+/Ca2+ exchanger has a wide tissue distribution, with transcripts
expressed in heart (Nicoll et al., 1990), brain (Furman
et al., 1993
), kidney (Reilly and Shugrue, 1992
), as well
as in other tissues (Smith and Smith, 1995
). NCX1 encodes a protein that is ~125 kD in size and is highly
conserved across species (Reilly et al., 1993
). In renal
epithelial cells the exchanger is localized to basolateral membranes (Reilly et al., 1993
), where it couples the
dissipative energy of Na+ entry to Ca2+ efflux with a 3:1
stoichiometry (Talor and Arruda, 1985
). Attempts to
localize the NCX1 Na+/Ca2+ exchanger to specific
nephron segments have resulted in contradictory or
ambiguous findings. The functional implications of differential expression of the PMCA isoforms and the
Na+/Ca2+ exchanger in a single cell is unclear. A second aim of these studies was to determine whether expression of specific isoforms was related to the segmental origin of S1, S2, and S3 cells and if single cell types
express multiple isoforms of particular proteins responsible for calcium efflux.
Cell Culture
Immortalized mouse proximal (S1, S2, or S3) and distal convoluted tubule (DCT) cell lines were established as detailed previously (Friedman et al., 1991; Nesbitt et al., 1995
, 1996
). The
proximal tubule cells exhibit the phenotype of S1, S2, or S3 portions of the proximal tubule including: (a) functional Na:Pi
cotransport; (b) formation of cAMP in response to parathyroid
hormone or calcitonin; and, (c) alkaline phosphatase activity, appropriate for the segmental origin of each cell type (Nesbitt et
al., 1995
, 1996
). DCT cells exhibit a distal convoluted tubule phenotype, as described elsewhere (Gesek and Friedman, 1992
;
Friedman et al., 1996
). Distal tubule (DT) cells2 were isolated by
a double-antibody immunodissection procedure described previously (Pizzonia et al., 1991
) and maintained in primary culture.
DCT and proximal tubule cell lines were grown on 100-mm
dishes (Corning Glass Works, Corning, NY) in DMEM/Ham's F12 media (Sigma Chemical Co., St. Louis, MO) supplemented
with 5% heat-inactivated (56°C for 20 min) FCS (Sigma) and PSN
antibiotic mixture (50 µg penicillin, 50 µg streptomycin, 100 µg
neomycin/100 ml media; Gibco BRL, Gaithersburg, MD) in a humidified atmosphere of 95% O2/5% CO2 at 37°C. Primary cultures of distal tubule cells were grown under the same conditions
using 10% FCS. Cells were placed in serum-free DMEM/Ham's
F12 media 16 h before use.
RNA Isolation
Culture dishes (100-mm diameter) of proximal tubule cells were washed twice with 5 ml 1× Ca2+/Mg2+-free Hank's balanced salt solution. Cells were solubilized and scraped in the presence of 1.0 ml 1 M GITC, layered onto a 1.5 ml CsCl gradient in 3 ml TL-100 centrifuge tubes (Beckman Instruments, Inc., Fullerton, CA) and overlaid with 0.15 ml of 20% sarkosyl. Gradients were centrifuged for 2 h at room temperature, pellets were washed with 70% ethanol, and resuspended in 100 µl sterile water. Quantitation of yield was determined by absorbance at 260 and 280 nm.
Reverse Transcriptase (RT)-PCR
One microgram of total RNA from proximal tubule cells or 250 ng of mRNA was reverse transcribed using MuMLV reverse transcriptase and random hexamers (GeneAmp RNA-PCR Kit; Perkin-Elmer, Foster City, CA) for 10 min at room temperature, then 15 min at 42°C, in the presence of 5 mM MgCl2. As a control for genomic DNA contamination of the RNA preparations, parallel samples were treated similarly but not reverse transcribed. The cDNA was then amplified with Taq polymerase. Mouse kidney mRNA (Clontech, Palo Alto, CA) was used as a positive control for appropriately-sized PCR products. Primer sequences and PCR annealing temperatures for each PMCA isoform-specific primer pair are given in Table I. PCR was performed at 94°C for 1 min, annealed at the specific temperature for each primer set (Table I) for 1 min, and extended for 2 min at 70°C for 35 cycles, with a final extension of 7 min. The products were electrophoresed on a 1% low-melting agarose gel (FMC Bioproducts, Rockland, ME) and stained with ethidium bromide.
Table I. Primers Used for Amplification of Transcripts By RT-PCR |
-Actin primers were designed from the human
-actin genomic sequence (Nakajima-Iijima et al., 1985
). The primers span
an intron, thereby differentiating between PCR products from
mRNA and those from genomic DNA. RT-PCR was performed as
described above. cDNA products arising from mRNA have a size
of 372 bp, whereas products from genomic DNA have a size of
790 bp. The sequences for the forward and reverse primers and
annealing temperature are given in Table I.
NCX1 Na+/Ca2+ exchanger primers were designed to conserved portions of the exchanger transcript spanning an alternatively spliced region (Kofuji et al., 1994) known to amplify a
product of ~600 bp from mouse kidney mRNA (White et al.,
1996a
). RT-PCR was performed as above. The primer sequences
are shown in Table I.
Resulting PCR products were cut from the gel and the cDNA eluted (Wizard Prep Kit; Promega Corp., Madison, WI). Products were subcloned into the blunt end SrfI site of Bluescript SK(+) with the PCRScript Kit (Stratagene Inc., La Jolla, CA). Plasmids were isolated by the Qiagen Mini-20 Plasmid Purification Kit (Qiagen Inc., Chatsworth, CA). 1 µg of purified plasmid was digested with the restriction enzymes BamHI and NotI (Gibco-BRL) and electrophoresed on a 1% agarose gel to confirm proper insert size.
DNA Sequencing
DNA sequencing was performed with the PRISM DyeDeoxy Sequencing Kit (Applied Biosystems, Inc., Foster City, CA) as described by the manufacturer. The cDNA products were sequenced on the Applied Biosystems Model 373A DNA Sequencing System using the T3 and T7 primer sites in pBluescript. Alternatively, products were cut from a low-melt agarose gel, the cDNA eluted as above, then 100 ng of each product was directly sequenced with 3.2 pmol of the forward or reverse PCR primers using the Prism Sequencing Kit and the Applied Biosystems Sequence Sequencing System. To control for nucleotide incorporation errors introduced by Taq polymerase, multiple RT-PCR reactions were performed and products from different reactions were sequenced. The cDNAs from at least two independent reactions were sequenced in both forward and reverse directions. The sequencing results for individual isoforms were the same, except for occasional indeterminate nucleotides. These templates were resequenced in both directions to identify the ambiguous nucleotide. Comparisons between subcloned cDNA products and previously identified PMCA sequences were carried out with GCG (Genetics Computer Group, Madison, WI) and GeneWorks (IntelliGenetics, Mountain View, CA) software.
Northern Analysis
2 µg of mouse kidney mRNA (Clontech) and 10 µg of total RNA
from each proximal tubule cell line RNA were electrophoresed
on a 1% agarose/formaldehyde gel and electrophoretically transferred overnight to GeneScreen Plus Membrane (Dupont NEN,
Wilmington, DE). The blots were prehybridized in a solution of 1 M
NaCl, 1% SDS, and 10% dextran sulfate for 60 min at 60°C, then
probed with 2 × 106 cpm/ml of the randomly primed (Prime-it II
Kit; Stratagene), [32P]dCTP-labeled (ICN Pharmaceuticals, Inc.,
Costa Mesa, CA) mouse PMCA1, 2, 3, or 4 PCR cDNA product.
The blots were washed at high stringency with 50 ml 2× SSC (sodium chloride/sodium citrate), 0.1% SDS three times at room
temperature, then with 0.1× SSC, 0.1% SDS three times at 60°C
and exposed to X-AR film (Eastman Kodak Co., Rochester, NY)
for 1-4 d at 70°C.
Free Intracellular Ca2+
Single S1, S2, S3, or DCT cells were analyzed for changes of free
intracellular Ca2+ concentration, [Ca2+]i, with the Ca2+-sensitive
dye, fura-2 AM as described previously (Bacskai and Friedman,
1990; White et al., 1996a
). The cell assay buffer consisted of: 140 mM Na+, 148 mM Cl
, 5 mM K+, 1 mM Ca2+, 1 mM Mg2+, 28 mM
HEPES, 18 mM Tris, with 10 mM glucose at pH 7.4 and adjusted to 295 mosmol/kg H2O. The Na+-free assay buffer was prepared
similarly except Na+ was replaced isosmotically by tetramethyl-ammonium (TMA). Proximal tubule cells on glass cover slips
were incubated for 60 min at 37°C with 10 µM fura-2 AM (Molecular Probes, Inc., Eugene, OR). The cells were rinsed several
times and placed in a temperature-controlled chamber set at
37°C and mounted on the stage of an inverted microscope (Nikon Diaphot; Nikon, Inc., Melville, NY). Emitted fluorescence was measured with a Nikon Photoscan-2. The experimental protocol consisted of an initial 2-min baseline period, 15-min incubation with the cell assay buffer, 5 min with Na+-free assay buffer,
10 min wash with control buffer, and finally 5 min in Na+-free,
Ca2+-free assay buffer, followed by calibration as previously described (Gesek and Friedman, 1992
). All experimental solutions
contained ouabain (10
3 M) to inhibit the Na+/K+ ATPase and
nifedipine (10
5 M) to block Ca2+ entry through Ca2+ channels.
Membrane Preparation and Western Analysis
Plasma membranes were isolated as follows: Six million proximal tubule cells or primary cultures of distal tubule cells were washed three times with 1× Hank's balanced salt solution in the presence of the protease inhibitors PMSF, EDTA, leupeptin, and pepstatin A (Sigma Chemical Co.). The cells were then sonicated for 10 s at 60% maximum output (Sonifier cell disrupter 450; Branson Ultrasonics Corp., Danbury, CT). The suspensions were transferred to 1.5 ml Eppendorf tubes and centrifuged at 500 g for 10 min. The supernatant was transferred to fresh tubes and centrifuged at 10,000 g for 20 min. The pellets were resuspended in 50 µl of 1× PBS buffer. A Lowry protein assay was performed on the resulting membranes using BSA as a standard.
50 µg of membranes from the mouse proximal tubule cell lines and primary cultures of distal tubule cells were electrophoresed at 20 mA (Hoefer Scientific, San Francisco, CA) on a 7.5% polyacrylamide gel (SDS-PAGE). Prestained markers (Bio-Rad Laboratories, Richmond, CA) were electrophoresed in parallel and used for protein mass determination. The protein was transferred to nitrocellulose (Bio-Rad Laboratories) in a transfer apparatus (Hoefer Scientific) for 1.5 h at 400 mA.
After blocking for 18 h in 5% BLOTTO (Carnation Instant
Non-Fat Dry Milk in 1× Tris-buffered saline, pH 7.4) at 4°C, the
blot was probed with a 1:1,000 dilution of an mAb raised to purified human PMCA, Clone 5F10 (Borke et al., 1989) (Affinity
Bioreagents, Inc., Golden, CO) or a polyclonal antibody specific
for the Na+/Ca2+ exchanger (Reilly et al., 1993
), kindly provided
by Dr. Robert Reilly (Yale University, New Haven, CT), in 1%
BLOTTO for 90 min at room temperature. The PMCA blots were
then incubated with a 1:3000 dilution of a horseradish peroxidase (HRP)-labeled goat anti-mouse IgG (Bio-Rad Laboratories). For the NCX1, the blots were incubated in a 1:500 dilution
of HRP-labeled goat anti-guinea pig IgG in 1% BLOTTO for 60 min at room temperature. Blots were developed by enhanced
chemiluminescence according to the manufacturer's (Amersham Corp., Arlington Heights, IL) instructions using Kodak X-OMAT (Eastman Kodak, Co.) film.
Analysis of PMCA Transcripts in Proximal Tubule Cells
RNA isolated from the proximal tubule S1, S2, and S3
cell lines was reverse-transcribed and the resulting
cDNA was amplified by PCR in separate experiments
using oligodeoxynucleotide primers specific (Meszaros
and Karin, 1993; Stauffer et al., 1993
; Abramowitz et al.,
1995
) for the four PMCA isoforms (sequences given in
Table I). RT-PCR was performed on at least two RNA
samples for each primer set and yielded identical results. PMCA1 primers resulted in a product of ~550 bp
from S1, S2, and S3 cells and from mouse kidney, which
served as a positive control (Fig. 1 A, +). Using the
same RNA samples, different results were obtained with
primers for PMCA2 and 3. The primers specific for
PMCA2 (Fig. 1 B) and PMCA3 (Fig. 1 C) were uniformly negative for S1, S2, and S3 cells but the positive
control revealed appropriately sized products from kidney of 427 and 392 bp, respectively. The primers specific for PMCA4 revealed an appropriately sized product of 563 bp in all proximal tubule cells, as well as in
mouse kidney (Fig. 1 D). For all primer sets and RNAs,
samples analyzed in the absence of RT showed no products (Fig. 1, A-D,
). These results support the view
that cell lines derived from S1, S2, and S3 proximal tubule segments express transcripts encoding PMCA1
and PMCA4.
Sequence Analysis of Proximal Tubule PMCA PCR Products
To confirm the identity of the proximal tubule PMCA
PCR products amplified by each primer pair, the cDNAs
from at least two independent reactions (see MATERIALS AND METHODS) were sequenced. The mouse partial
clones were found to have high similarity to rat PMCAs
in their respective regions, consistent with reports of
high conservation of PMCA isoforms across species
(Keeton and Shull, 1995). The amino acid sequence
alignments for each mouse PCR product and its corresponding rat homologue is shown in Fig. 2. The mouse
proximal tubule PMCA1 product was identical to the published (Shull and Greeb, 1988
) rat PMCA1 sequence (Fig. 2 A). PMCA2 and PMCA3 products were
98 and 100% identical to rat PMCA2 and PMCA3 (Fig.
2, B and C) sequences, respectively, in their corresponding regions. In addition, the PMCA4 PCR product shares 92% similarity to the cloned rat PMCA4
cDNA sequence (Fig. 2 D). Therefore, sequence analysis confirms that the mouse PMCA isoforms are highly
homologous to the rat isoforms within the amplified regions, and also demonstrates that the primers used for
RT-PCR are specific for each isoform.
Northern Analysis of Proximal Tubule PMCA
Northern analysis was performed to determine the sizes
of the PMCA mRNAs in proximal tubule cells. The
mouse PMCA1, 2, 3, and 4 PCR products were randomly primed, [32P]dCTP-labeled, and used as cDNA
probes for the analysis of separate blots. The PMCA1
probe strongly hybridized with two distinct transcripts of 7.5 and 5.5 kb in mouse kidney mRNA (Fig. 3 A,
Mouse Kidney) and with RNA from S1, S2, and S3 cell
lines (Fig. 3 A, lanes S1 -S3). The probe specific for
PMCA4 hybridized with 8.5 and 7.5 kb transcripts from
both mouse kidney and the proximal cells (Fig. 3 D).
Although the origin of multiple bands on the Northern
blots is not known, these transcripts show doublets similar to those previously reported for PMCA1 and
PMCA4 in other tissues (Kumar et al., 1993; Keeton and Shull, 1995
). Neither PMCA2 nor PMCA3 was observed in the proximal tubule cell lines (Fig. 3, B and
C). Mouse kidney mRNA exhibited PMCA2 transcripts
of 7.1 and 4 kb (Fig. 3 B). PMCA3 was faintly detected
in mouse kidney (Fig. 3 C). To assure that the PMCA3
cDNA probe was capable of hybridizing with PMCA3
transcripts, mouse brain mRNA was used as a positive
control and revealed the presence of appropriately
sized mRNAs of 7.5 and 5.1 kb (Fig. 3 C, lane 5), consistent with reported mRNA transcript sizes for rat skeletal muscle and brain (Burk et al., 1995
). Therefore, molecular evidence provided by RT-PCR and Northern
analysis support the idea that the dominant mRNAs in
proximal tubule cells are PMCA1 and PMCA4.
Analysis of NCX1 Na+/Ca2+ Exchanger Transcripts in Proximal Tubule Cells
RT-PCR was performed on RNA isolated from the S1,
S2, and S3 cell lines to determine if proximal tubule
cells express transcripts encoding the NCX1 Na+/Ca2+
exchanger. The NCX1 primers target conserved portions of the rat exchanger transcript and are known to
amplify a region of alternative splicing from mouse kidney mRNA (Kofuji et al., 1994; White et al., 1996a
). A
band of the predicted size, 600 bp, was obtained from
mouse kidney RNA analyzed in the presence of RT (Fig. 4, Mouse Kidney +). Mouse kidney RNA samples
analyzed in the absence of RT (Fig. 4,
) failed to generate products indicating that the observed product
arose from amplification of mRNA and not genomic
DNA. All three proximal cell lines were negative for NCX1 (Fig. 4, S1 -S3).
-actin mRNA was amplified by
RT-PCR as a control to verify that the RNA samples
were intact. All proximal tubule RNA samples yielded
an appropriately sized product of 372 bp (Fig. 4). Since
the
-actin primers span an intron, the product was derived from RNA because genomic DNA would yield an
expected product of 790 bp (Nakajima-Iijima et al.,
1985
). These results demonstrate that, within experimental error, the proximal tubule cell lines do not express the NCX1 transcript.
Analysis of PMCA and Na+/Ca2+ Exchanger Protein Expression in Proximal Tubule Cells
To assess protein expression of PMCA and Na+/Ca2+
exchanger Western analysis was performed on membrane preparations from the S1, S2, and S3 proximal tubule cell lines and primary cultures of mouse kidney
distal tubule cells. PMCA was examined using an mAb
that recognizes the highly conserved hinge region the
enzyme (Borke et al., 1989), whereas the exchanger
was assessed with an NCX1-specific polyclonal antibody, raised against the large intracellular loop of the
rabbit kidney exchanger (Reilly et al., 1993
). In agreement with the reported PMCA protein molecular mass (Borke et al., 1989
), membrane preparations from the
three mouse proximal tubule cell lines (Fig. 5 A, S1-S3)
and primary cultures of mouse kidney distal tubule
cells (Fig. 5 A, DT) show a single, strongly reacting
band of 140 kD.
The same membrane preparations used for PMCA
analysis were probed in parallel with an anti-Na+/Ca2+
exchanger antibody. The anti-exchanger antibody detected no reacting proteins in proximal tubule S1, S2 or
S3 membrane preparations at 125 kD, the molecular
mass of the mature form of the exchanger (Nicoll et
al., 1990). A lower band of ~85 kD was observed (Fig. 5
B, S1-S3). Membranes isolated from primary cultures of
distal tubule cells, which are known to express the exchanger (White et al., 1996a
), were used as positive
control. A strongly reacting protein was observed at
~125 kD, the reported size of the mature exchanger
protein (Reilly et al., 1993
) (Fig. 5 B, DT), along with a
lower band at 85 kD. The 85 kD band is hypothesized
to be a proteolytic fragment of the mature exchanger
protein (Nicoll et al., 1990
) but its exact identity has yet
to be determined. Anti-Na+/Ca2+ exchange pre-immune
controls were shown previously to be negative for distal
tubule cell membrane preparations (White et al., 1996a
). Because NCX1 transcripts were not detected in S1, S2,
or S3 cells, it is unlikely that the lower weight band is a
breakdown product of the NCX1 exchanger. Therefore,
PMCA protein is expressed in plasma membranes of
proximal tubule cells. However, within experimental error, proximal tubule cells do not express detectable levels of the mature NCX1 Na+/Ca2+ exchanger protein.
Functional Na+/Ca2+ Exchange Activity in Proximal Tubule Cells
Although analysis of NCX1 protein in proximal tubule
cell plasma membranes, as described above, was negative for the mature form of the exchanger, functional
Na+/Ca2+ exchange activity below the level of detection by Western blotting cannot be ruled out. Therefore we used an approach to analyze Na+/Ca2+ exchange in S1, S2, and S3 proximal tubule cells in a manner similar to that described elsewhere (Dai et al.,
1996; White et al., 1996a
).
Under prevailing conditions of [Ca2+]i and membrane voltage basolateral Na+/Ca2+ exchange operates
in the forward mode, coupling the influx of Na+ ions
down their electrochemical gradient to the efflux of
Ca2+ ions against a steep electrochemical barrier
(Friedman and Gesek, 1995). The exchanger is reversible and can operate in the opposite mode, wherein sodium efflux energizes calcium uptake. This can be
achieved experimentally by loading cells with Na+ and
then isosmotically replacing extracellular Na+ (Goldman et al., 1994
; Dai et al., 1996
; White et al., 1996a
). Changes of [Ca2+]i in the presence and absence of extracellular Ca2+ were measured in paired experiments
in single cells with the Ca2+-sensitive dye, fura-2. Representative traces from each cell type are shown in Fig. 6
A, and the results are summarized in Table II. Resting
[Ca2+]i was ~110 nM in all cell types. After a 15-min incubation with ouabain, to inhibit the Na+/K+ ATPase
and thereby increase intracellular Na+, reversal of the
Na+ gradient in the presence of extracellular Ca2+
caused 70-75 nM increases of [Ca2+]i in S1, S2, and S3
cells. In the absence of external Ca2+, [Ca2+]i increased
by 50-58 nM. The elevation of [Ca2+]i was not significantly different in the presence or absence of external
Ca2+ (Fig. 6 B). Thus, it is unlikely that the majority of
the rise of [Ca2+]i in proximal cells was due to the entry
of Ca2+ and presumably resulted from the release of
calcium from cytoplasmic organelles (White et al.,
1996a
). In contrast, DCT cells exhibited average rises
of [Ca2+]i of 369 nM in the presence of extracellular
Ca2+ and 54 nM in the absence of extracellular Ca2+
(Table II), as reported previously (White et al., 1996a
).
These latter findings are consistent with the view that
the majority of the rise of [Ca2+]i in DCT cells is due to
Ca2+ entry from the extracellular buffer.
Table II. Na+-dependent increases of [Ca2+]i in the Presence and Absence of Extracellular Calcium |
In this report experimental evidence is provided for the presence of multiple isoforms of the plasma membrane Ca2+-ATPases (PMCA1 and PMCA4) in S1, S2, and S3 proximal tubule cells. By contrast, we were unable to detect NCX1 Na+/Ca2+ exchanger transcripts, protein, or Na+/Ca2+ exchange activity in these proximal tubule cell lines.
PMCA in Proximal Tubule Cells
Proximal tubule cells express mRNA for multiple isoforms of PMCA. Using RT-PCR, we show that clonally
expanded S1, S2, and S3 proximal tubule cell lines express transcripts encoding PMCA1 and PMCA4 (Fig. 1,
A and D). Northern analysis performed on RNA isolated from the proximal cells using specific cDNA
probes provides further evidence that multiple isoforms are present in these cells (Fig. 3). Appropriately
sized transcripts for PMCA1 and PMCA4 were detected
in all proximal tubule cell lines, however PMCA2 and
PMCA3 were not detected in the same RNA samples,
consistent with the RT-PCR experiments targeting individual PMCA isoforms (Fig. 3). The positive control,
mouse kidney RNA, strongly hybridized with all cDNA
probes except PMCA3, confirmed by mouse brain RNA (Fig. 3 C), indicating that the probes were capable of
detecting specific transcripts. Therefore, molecular evidence provided by RT-PCR and Northern analysis support
the idea that the dominant mRNAs in proximal tubule
cells are PMCA1 and PMCA4. UMR-106 osteosarcoma cells, which express PMCA1, 2, and 4 (Abramowitz et
al., 1995), and cultured pancreatic
cells, which contain PMCA1, 2, and 4 transcripts (Varadi et al., 1996
),
have also been demonstrated to exhibit multiple PMCA
isoforms. The consequence of expressing multiple
PMCA isoforms in a single cell type is not known. However by varying isoform structure in modifying domains,
and thus varying sensitivities to calmodulin and phospholipids, the PMCA isoforms could be differentially
regulated (Strehler, 1991
), thereby affecting cellular
calcium homeostasis or transcellular calcium transport.
Studies of PMCA mRNA levels in human and rat kidney reveal that PMCA1 and PMCA4 are the dominant
renal transcripts, whereas PMCA2 mRNA represents
<2% of the total PMCA mRNA in the kidney; PMCA3
was virtually undetectable (Stauffer et al., 1993). Subsequent work substantiated these findings at the protein
level using Western analysis with PMCA isoform-specific antibodies (Stauffer et al., 1995
). The present findings are consistent with these earlier results (Stauffer et
al., 1993
). However, an analysis of microdissected rat
nephron segments by RT-PCR concluded that PMCA2
was the dominant isoform in proximal convoluted tubules, cortical thick ascending limbs, distal convoluted
tubules, and cortical collecting ducts (Magocsi et al.,
1992
). The mRNA for PMCA1 was present in glomeruli but absent in tubular segments; PMCA3 was not found.
In the present study PMCA2 was undetectable in S1, S2,
or S3 proximal tubule cells by RT-PCR or by Northern
analysis (Figs. 1 and 3). Several reasons can be envisioned for the discrepancies regarding localization of
PMCA isoform transcripts in proximal tubule cells between the present work and previous studies. These differences may stem, in part, from the experimental procedures employed. To localize PMCA isoforms in cortical nephron segments, Magocsi et al.(1992) performed
RT-PCR with isoform specific primers on microdissected nephron segments. Since PMCAs are expressed
ubiquitously in both tubular epithelial cells and in nonepithelial cells, the source of the specific mRNA amplified is critical. Contamination of excised tubule segments by adjoining nephron segments, nervous tissue, fibroblasts, and connective tissue may occur, thereby
confounding interpretation. This is of particular concern with a procedure such as RT-PCR. Moreover, the
cDNA products resulting from the RT-PCR reactions
were not sequenced, thereby precluding verification of
their identity. Instead, product specificity was based
upon predicted sizes of PCR products and PCR Southern analysis. Because of the high degree of homology
between PMCA isoforms, however, PCR products may
be of similar sizes regardless of the isoforms amplified.
Also, Southern analysis with cDNA probes may cross-hybridize between isoforms. This possibility was not
ruled out by testing individual probes against cloned
PMCA cDNAs as controls. Finally, the PMCA4 cDNA sequence was not identified at the time of the Magocsi
publication, therefore confirmation of cross-reaction with this transcript could not be established. In the
present work these problems were circumvented by: using primers known to be specific for individual PMCA
isoforms; isolating RNA from characterized, clonal cell
lines to avoid contamination; sequencing cDNA reaction products to provide absolute confirmation of their identity; and including appropriate control RNAs in
Northern analysis to verify proper PMCA transcript presence and size. Thus, the absence of PMCA2 transcripts
in proximal tubule cells is unlikely to involve failure of
the PMCA2 primers to amplify the transcript because
whole mouse kidney mRNA gave a product of the appropriate size (Fig. 1 B) and its identity was confirmed
by sequence analysis (Fig. 2 B). In addition, mouse kidney was positive by Northern analysis for PMCA2, but
negative in the cell lines (Fig. 2 B). The possibility exists, of course, that PMCA2 and PMCA3 transcripts may
be expressed at levels in proximal cells below the limits of resolution by RT-PCR and Northern analysis. Furthermore, the absence of PMCA2 and PMCA3 transcripts by RT-PCR or Northern analysis is not attributable to compromised RNA integrity since
-actin mRNA
was amplified from all samples and PMCA1 and PMCA4
were amplified from the same samples that were negative for PMCA2 and PMCA3. Selective downregulation
of the PMCA2 transcript in cultured proximal tubule
cell lines as a consequence of the transformation with SV40 cannot be excluded and could potentially contribute to or account for its apparent absence. Also,
species-specific expression of the PMCA isoforms may
account for the failure to find PMCA2 in mouse proximal tubule cells.
In addition to the molecular evidence supporting the
presence of PMCA mRNA in proximal tubule cell lines,
protein expression of PMCA was analyzed. Application
of an mAb directed against the hinge region of the human PMCA (Borke et al., 1989) confirmed the presence of PMCA protein in plasma membranes of proximal tubule cells (Fig. 5). Membrane preparations from
primary cultures of distal tubule cells, derived from
nephron regions known to express PMCA (Borke et al.,
1987
), revealed a band of similar mass when analyzed
in parallel with proximal cell lines (Fig. 5 A). This finding supports the view that the reacting protein is a
PMCA. The antibody used in Western analysis in this
report does not distinguish between the four PMCA
isoforms (Borke et al., 1989
). Although transcripts encoding two isoforms, PMCA1 and PMCA4 were detected, the appearance of a single band upon Western
analysis is most likely due to the similar mass and migration of PMCA isoforms when separated by SDS-PAGE (Stauffer et al., 1995
). The presence of PMCA
protein in proximal tubule cells is not entirely consistent with other reports, where PMCA was immunolocalized only to distal portions of the human (Borke et al.,
1987
) and the rat (Borke et al., 1989
) nephron. This
apparent discrepancy may result from lower abundance of proximal tubule PMCA, below the level of detection by immunocytochemical methods. This possibility is supported by evidence showing reduced PMCA
activity in proximal tubules compared to distal tubule
segments in both rat and rabbit nephrons (Doucet and
Katz, 1982
; Ramachandran and Brunette, 1989
; Ramachandran et al., 1991
). Moreover, associated proteins
that mask the antigenic epitope of PMCA in vivo may
be present in proximal tubule cells, since intracellular
proteins are known to interact with the enzymes (Enyedi et al., 1989
). During SDS-PAGE the plasma
membranes are denatured, and the antibody recognition sites could be revealed. Therefore, readily detectable amounts of PMCA protein are present in membrane preparations from the S1, S2, and S3 cell lines regardless of segment origin, supporting the molecular
identification of PMCA transcripts in these cells.
Na+/Ca2+ Exchange in Proximal Tubule Cells
The presence of Na+/Ca2+ exchange in proximal tubules is uncertain and controversial. Evidence supporting the presence of Na+/Ca2+ exchange derives primarily, though not entirely, from functional studies (Ullrich et al., 1976; Gmaj et al., 1979
; Lee et al., 1980
;
Friedman et al., 1981
; Lorenzen et al., 1984
; Yang et al., 1988
; Dominguez et al., 1991
, 1992
), whereas molecular structural experiments (Ramachandran and Brunette, 1989
; Yu et al., 1992
; Bourdeau et al., 1993
; Reilly
et al., 1993
) have generally failed to confirm its presence. In the present studies we applied both a structural and functional strategy to evaluate the presence of Na+/Ca2+ exchange in proximal tubule cells.
Examination of primary cultures of distal tubule cells
using a characterized NCX1 exchanger polyclonal antibody (Reilly et al., 1993) revealed a protein of 125 kD,
consistent with the molecular mass of the processed,
mature exchanger protein (Nicoll et al., 1990
; Reilly et
al., 1993
). In contrast, all three proximal tubule cell
lines were negative for the mature exchanger (Fig. 5
B). The membrane preparations analyzed however, revealed a reacting protein of 85 kD (Fig. 5 B), similar in
size to a reported proteolytic fragment (Philipson et al.,
1988
; Vemuri et al., 1990
). Since proximal tubule S1, S2,
and S3 cells apparently do not express NCX1 (Figs. 4-6),
the smaller band is unlikely to be a breakdown product
of the mature exchanger. By virtue of the fact that the anti-exchanger antibody is polyclonal, the 85 kD band
could be a protein with a similar antigenic epitope to
that present in the NCX1 exchanger since the protein
does not appear to react with preimmune sera (White
et al., 1996a
). Further analysis of the 85 kD protein will
be required to make a definitive statement as to its
identity. The results of the studies described herein support the idea that NCX1 is absent from mouse proximal tubule cells. These results (Fig. 5 B) and conclusion
differ from studies where the protein was reported in
proximal tubule preparations (Dominguez et al.,
1992
). The present results do not rule out the possibility of species-specific expression of NCX1 in proximal tubule cells.
Independent functional assessment of Na+/Ca2+ exchange using experimental protocols that definitively
revealed Na+-dependent calcium transport in DCT
cells (Fig. 6 and White et al., 1996a) and UMR-106 osteoblast cells (White et al., 1996b
) failed to uncover significant exchange activity in S1, S2, or S3 cells (Fig. 6,
Table II). Nonetheless, the rise of [Ca2+]i in the presence of external Ca2+ in proximal cells was slightly
greater (~15-20 nM) than in the absence of Ca2+ (Table II). This modest difference could be due to a
slightly greater release of intracellular Ca2+ stores in
the presence of external Ca2+. Alternatively, modest exchange activity may be present in proximal tubule cells
but not readily demonstrable under the imposed experimental conditions. Nonetheless, the majority of the
increase clearly was not due to calcium entry, consistent with the interpretation that the residual rise of
[Ca2+]i is due to release from subcellular organelles
and does not result from Na+/Ca2+ exchange.
Summary and Conclusion
Although an appreciable portion of proximal calcium
absorption involves a cellular transport pathway, little is
known of the mechanisms by which calcium enters or
exits these cells. The present work focused on transport
mechanisms in basolateral plasma membranes. In principle, either or both a PMCA and Na+/Ca2+ exchanger
might mediate efflux. We provide evidence for the
presence of two PMCA isoforms (PMCA1 and PMCA 4)
in S1, S2, and S3 cells. Data showing that PMCA protein
is expressed by these cells is also provided. Conversely,
we were unable to find evidence for Na+/Ca2+ exchange, NCX1 exchanger transcripts or protein in
proximal tubule cells. Apparent Kms for calcium for
PMCA in kidney are 0.1-0.4 µM (Doucet and Katz,
1982; van Heeswijk et al., 1984
; Ramachandran et al.,
1991
) and indistinguishable in proximal and distal tubule basolateral membranes (Doucet and Katz, 1982
;
Ramachandran et al., 1991
). The Na+/Ca2+ exchanger
has apparent Kms for calcium of 15-40 µM and of 1-2 µM (Philipson, 1985
). In the kidney, the Km has been
reported to be 0.1 µM (van Heeswijk et al., 1984
).
These findings would suggest that basal [Ca2+]i may be
controlled, in part, by efflux mediated by PMCA1 or PMCA4, which exhibit Kms similar to the resting [Ca2+]i
(Friedman and Gesek, 1995
). Possible roles of Na+/
Ca2+ exchange in proximal tubule cells are more difficult to assign on the basis of the present work, which
within experimental error, failed to adduce evidence
for the expression of NCX1 transcripts or functional
exchange activity in three proximal tubule cell lines. It
could be argued that proximal tubules express Na+/
Ca2+ exchangers, but such expression and activity is
downregulated in the immortalized cells studied
herein. Although some evidence supporting functional
Na+/Ca2+ exchange in proximal cells is compelling
(Lee et al., 1980
; Lorenzen et al., 1984
), rigorous tests
involving collapse of the Na+ gradient to determine if
Ca2+ efflux was coupled directly to Na+ entry through
the Na+/Ca2+ exchanger were not performed. Furthermore, the kinetic measurements would suggest that
even if present in proximal tubules, Na+/Ca2+ exchange is unlikely to play a vital role in regulating resting or stimulated levels of [Ca2+]i. The present results,
however, do not definitively rule out the possibility that
basolateral Ca2+ efflux pathways are differentially expressed along the proximal nephron or that they may
differ between species. Furthermore, cell transformation may affect the pattern of expression and might theoretically explain the failure to detect the NCX1 exchanger. These arguments notwithstanding, it is possible that proximal tubules express an alternate NCX
gene product or a different form of exchanger, such as
the Na+/Ca2+, K+ exchanger. Although to our knowledge this hypothesis has not been explicitly tested,
Windhager (Milovanovic et al., 1991
) noted that, when
expressed in Xenopus oocytes, Ca2+ uptake mediated by
the renal Na+/Ca2+ exchange was stimulated by K+.
Original version received 28 August 1996 and accepted version received 14 November 1996.
Address correspondence to Peter A. Friedman, Ph.D., Dartmouth Medical School, Department of Pharmacology and Toxicology, Hanover, NH 03755-3835. Fax: 603-650-1129; E-mail: PAF{at}Dartmouth.edu
This work was submitted in partial fulfillment of the requirements for a Ph.D. by Kenneth E. White, who was a predoctoral Fellow of the Albert J. Ryan Foundation during the performance of these studies.These studies were supported by National Institutes of Health grants R01 GM-34399, R01 ES-05860 (P.A. Friedman), T32 DK-07301 (K.E. White), and R01 AR-27032 (M.K. Drezner).