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J. Biol. Chem., Vol. 276, Issue 37, 34359-34362, September 14, 2001
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From the Department of Cellular and Molecular Physiology, Yale
University, New Haven, Connecticut 06510 and The Mount Desert Island
Biological Laboratory, Salsbury Cove, Maine 04672
Received for publication, July 1, 2001, and in revised form, July 16, 2001
The specificity of major protein
phosphatases is conferred via targeting subunits, each of which binds
specifically to the phosphatase and targets it to the vicinity of
substrate proteins. In the case of protein phosphatase 1 (PP1), an
RVXFXD motif on a targeting subunit
binds to a cleft in PP1c, the catalytic subunit. Here we report that a
substrate of PP1, the Na-K-Cl cotransporter (NKCC1), bears this motif
in its N terminus near sites of regulatory phosphorylation and that
direct binding of PP1 to NKCC1 is functionally important in determining
the set point for intracellular chloride regulation. NKCC1 mutants in
which the motif is destroyed or improved exhibit dramatically shifted
activation curves because of a change in the rate of cotransporter
dephosphorylation. Furthermore, direct interaction of NKCC1 and PP1c
observed by coprecipitation of the two proteins is not seen in a mutant
lacking the site. This establishes a new paradigm of phosphatase
specificity, one in which a substrate protein containing an
RVXFXD motif binds directly to PP1c; we propose
that this may be a quite general mechanism.
A small number of protein phosphatases is responsible for
dephosphorylation of the majority of cellular phosphoproteins (1, 2).
The specificity of these otherwise promiscuous enzymes is conferred by
targeting subunits, each of which binds specifically to the phosphatase
and targets it to the vicinity of substrate proteins. For protein
phosphatase 1 (PP1),1 a cleft
in the catalytic subunit (PP1c) binds proteins that contain the
consensus motif, RVXFXD, illustrated both in a
direct examination of the molecular structure (3) and by the results of
peptide panning experiments (4). The present study began with the
observation that the N terminus of the Na-K-Cl cotransporter (NKCC1)
contains a highly conserved region with the sequence RVNFVD (residues
140-145 in human NKCC1, 107-112 in shark NKCC1), posing the
possibility that the cotransporter is directly targeted as a
phosphatase substrate.
The Na-K-Cl cotransporter is an integral membrane protein constituting
a major regulated pathway for coupled inward movement of
Na+, K+, and Cl In this study we directly examine the hypothesis that the RVNFVD
sequence in the N terminus of NKCC1 forms a functionally important
binding site for PP1c. It is found that mutations at this locus
dramatically alter the activation curve for Na-K-Cl cotransport,
consistent with a 10-fold decrease in the rate of cotransporter
dephosphorylation. On the other hand a change that "improves" the
putative PP1 binding site exhibits the converse behavior, consistent
with a 4-fold increase in the rate of NKCC1 dephosphorylation. In
transfected HEK cells the functional consequence of removing the PP1
binding site is that the intracellular chloride concentration is
maintained at a level 35% above that with wild type NKCC1, supporting
the idea that a major role of the Na-K-Cl cotransporter is the
regulation of [Cl]i. Finally, it is demonstrated through
coprecipitation experiments that PP1 does indeed bind to the NKCC1
protein. Because the RVXFXD motif is found in a
large number of cytosolic and membrane proteins, we propose that this new paradigm of phosphatase targeting may be of very broad importance in cellular regulation.
NKCC1 in HEK Cells--
Mutants of shark NKCC1 were prepared by
the Kunkel method of single-stranded mutagenesis, as described
previously (15); details are available on request. Stable transfectants
were prepared in HEK-293 cells by calcium phosphate
precipitation and positive selection with G418 (15). All lines were
maintained in culture in 100 µM furosemide, a rapidly
reversible NKCC inhibitor (16). NKCC1 activation was achieved in
these cells by 1 h of incubation in hypotonic medium containing
1.5 mM chloride (17) or in the experiments represented by
Fig. 2, by preincubation in media containing various [Cl] (18)
and furosemide. Intracellular [Cl] and cell volume were determined as
described previously (18) using 36Cl (0.1 µCi/ml) and
[14C]urea (0.5 µCi/ml) equilibrated in a 45-min
incubation in regular flux medium in 6-well plates (see Fig. 3) or
preincubation media in 96-well plates (see Fig. 2). Data were
statistically analyzed by analysis of variance with Bonferroni
correction for multiple measurements.
Rectal Gland Tubule Cells--
Suspensions of epithelial tubules
from the salt-secreting rectal gland of the dogfish shark were used in
the experiments represented by Fig. 1. The rectal gland is a rich
source of NKCC1 and has been utilized extensively as a model
chloride-secreting epithelium (7, 19-21). As described previously
(21), tubules were liberated from thin slices of the gland by
incubation in collagenase and mechanical agitation and isolated by low
speed differential centrifugation. NKCC1 was activated in these cells
by 10 min of incubation in 50 µM forskolin, which causes
the opening of chloride channels and rapid loss of cellular chloride
(20).
Dephosphorylation of NKCC1--
Solubilized activated NKCC1 was
obtained from transfected HEK cells (or rectal gland tubule cells; see
parentheses) by addition of 0.1% Triton, 20 mM Tris-Cl (or
2% Triton, 20 mM Na-HEPES), pH 7.5, at ~2% (or 4%)
cytocrit, and agitation for 30 s (and centrifugation in a
microfuge to remove debris). This solution was further diluted 11-fold
(or 50-fold) in 20 mM Tris-Cl (or Na-HEPES); aliquots were
incubated at 20 °C with (see Fig. 1) or without (see Fig. 3)
appropriate concentrations of phosphatase inhibitors for 0-40 min,
during which period dephosphorylation of NKCC1 occurred. Dephosphorylation was terminated at appropriate time points by addition
of one-half volume of 1 M H3PO4 (or
SDS transfer buffer containing 0.5 µM calyculin A), and
40-µl aliquots were dot-blotted (Milliblot-D; Millipore) in 300 µl
of transfer buffer. The level of cotransporter phosphorylation at
Thr184/Thr189 was determined on these
blots using the anti-P-NKCC1 antibody (22) and standard Western
blotting techniques using chemiluminescence detected with a cooled CCD camera.
Transport Assays--
86Rb influxes were performed
as described previously (15, 17). Transfected HEK cells were
preincubated in media of various external [Cl] (with gluconate
replacement) for 1 h to activate the cotransporter. Furosemide (50 µM) was included in most conditions to prevent the
cotransporter from affecting cellular electrolyte composition. Maximal
activation was obtained by including 0.5 µM calyculin A
in the low chloride medium for the last 10 min of the preincubation.
Minimal activation was obtained by pre-incubating in 15 mM
potassium in the absence of furosemide to cause cell depolarization and
elevation of intracellular chloride (20). Prior to the influx
measurement, cells were rapidly washed twice in low chloride medium to
remove furosemide. 86Rb influx was determined in a 1-min
period in 135 mM NaCl, 5 mM RbCl (2 µCi
86Rb/ml), 1 mM CaCl2, 1 mM MgCl2, 1 mM
Na2HPO4, 1 mM
Na2SO4, 0.1 mM ouabain, 15 mM Na-HEPES, pH 7.4. Cells were washed three times, and
86Rb content was determined by imaging of the 96-well plate
on a PhosphorImager screen (Molecular Dynamics). As shown previously (15, 17, 18) and confirmed in control experiments, >90% of the
86Rb influxes reported here are due to NKCC1 and are
inhibitable by bumetanide.
Modeling Phosphorylation and Dephosphorylation--
To compare
mutants and wild type NKCC1 (see Fig. 2), we assume the following
simple model of phosphorylation and dephosphorylation in the
steady state: A · kdephos = (1 Precipitation with Microcystin Beads--
The microcystin LR
(Calbiochem) affinity matrix was prepared using the method of Moorhead
et al. (23). Coprecipitation experiments were performed by
incubating solubilized activated NKCC1 from HEK cells (see above) with
microcystin beads (typically 0.2 mg of cell protein in 300 µl of 1%
Triton, 100 mM Tris-Cl with 5 µl of packed beads) for 15 min at 20 °C with and without preincubation with 4 µM
microcystin. The beads were washed rapidly twice each with 0.35 M NaCl in phosphate-buffered saline and with that solution diluted 10-fold, and proteins were eluted in boiling SDS sample buffer
with 40 mM DTT. In some experiments the cross-linking
agent, dithiobis(succinimidyl propionate, 0.2 mM;
Pierce), was added for the last 10 min before lysis, potential
complexes being dissociated with DTT during bead elution. As seen in
Fig. 5, the cross-linking procedure had no detectable effect on the
outcome of the experiments.
Antibodies and Blotting--
Shark NKCC1 was detected with J4
and J7 antibodies (24); J4 recognizes an epitope in the N terminus, and
J7 recognizes an epitope in the C terminus of NKCC1. Incidentally,
these studies demonstrated that the RVXFXD
sequence comprises part or all of the epitope for the J3 monoclonal
antibody (24); none of the mutants in this region were positive with
J3. Cotransporter phosphorylation was determined with anti-P-NKCC, a
polyclonal antibody raised to a peptide containing phosphorylated
Thr184 and Thr189; this antibody recognizes
phosphorylated versus non-phosphorylated NKCC1 with greater
than 25:1 discrimination; it is linear in response compared with
32P incorporation (22). PP1c was detected with a commercial
monoclonal antibody (P35220; Transduction Laboratories).
Shark and human NKCC1 are 74% identical in overall amino acid
sequence, and the regions containing the regulatory phosphoacceptors (shark 172-202) and the putative PP1 binding site (shark 107-112) are
almost fully conserved between the two species (95 and 100% identity,
respectively). In addition the properties of regulation of shark
and human NKCC1s by [Cl]i appear virtually identical in
transfected HEK cells (14).2
We have chosen to study shark NKCC1 because of the availability of
superior antibody probes for this species and because of the ability to
conduct studies in both the cell culture model and in the intact organ,
the salt-secreting rectal gland of the shark.
That PP1 is responsible for regulatory dephosphorylation is suggested
by previous studies of the relative effects of calyculin A and okadaic
acid on Na-K-Cl cotransport (25) and NKCC1 activation (20). To further
examine this relationship, we have followed the dephosphorylation of
the Na-K-Cl cotransporter in solubilized cell extracts and compared the
effectiveness of a number of inhibitors of PP1 and PP2A (Fig.
1). In each case inhibition of NKCC1
dephosphorylation has a K0.5 consistent with the
action of PP1, but for most inhibitors the results are well outside the
reported range for PP2A. Together these results are very strongly
supportive of PP1 as the phosphatase involved in NKCC1 regulation.
To study the regulatory importance of the putative PP1 binding site in
NKCC1, we prepared mutations of NKCC1 including alanine substitution
throughout the RVXFVD motif (RANF, RVNA, AANA) the replacement of the NKCC1 sequence with the homologous sequence from
NKCC2, deletion of the N terminus before G153, and
replacement of the NKCC1 sequence with the sequence of a known PP1c
binding peptide. Activation of the stably transfected NKCC1 mutants was accomplished by preincubation in media with a range of
extracellular Cl concentrations, because activity of NKCC1 is
controlled via phosphorylation in response to changes in cell volume
and [Cl]i (18, 20). The rapidly reversible cotransporter
inhibitor furosemide was included during the preincubation period to
eliminate any effects of NKCC1 on cellular electrolyte balance. Fig.
2c illustrates the changes in
intracellular [Cl] and volume that are brought about by these
experimental preincubations. As illustrated in Fig. 2, a and
b, the results of these 86Rb influx experiments
demonstrated a striking shift in the activation curve of NKCC1 in each
of the alanine-substituted mutants and in the N-terminal deletion. The
shift is in the direction of higher NKCC activity at all Cl
concentrations, consistent with a higher level of phosphorylation. The
change is well fit by assuming a 10-fold decrease in the rate of
dephosphorylation in a simple phosphorylation-dephosphorylation
model (Fig. 2b, lines).
ACCELERATED PUBLICATION
Modulation of Ion Transport by Direct Targeting of
Protein Phosphatase Type 1 to the Na-K-Cl Cotransporter*
,
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
in many cell
types. The transporter is a central element in electrolyte movement by
secretory epithelia, where it functions in concert with cystic fibrosis
transmembrane conductance regulator, potassium channels, and the
sodium pump to bring about transcellular chloride transport (5, 6).
Cotransport activity is fully controlled by direct phosphorylation of
the NKCC1 protein (7-9) in response to decreases in cell volume or
intracellular [Cl]. Phosphorylation of NKCC1 is mediated by a kinase
whose identity is still unknown, but dephosphorylation appears to occur
through the action of protein phosphatase 1 (10). The phosphoregulatory
region, including three identified threonine phosphoacceptors, is in
the cytoplasmic N terminus of the NKCC1 (7, 11-13). Functional
characteristics of cotransporter regulation are highly conserved among
vertebrates from shark to human (14), consistent with conservation of
the identified phosphoacceptor residues and of the
RVXFXD motif, which we examine here.
EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
A) · kphos, where A is the fraction of
active transporter, kphos is the rate constant of phosphorylation, and kdephos is the rate
constant of dephosphorylation. We further assume that under any given
experimental condition, kphos is the same for
each of our NKCC1 constructs but that kdephos varies among them. Then by combining these relationships for mutant and
wild types and rearranging, we have Amutant = Awt/(Awt + 
· (1 Awt)) where Amutant and
Awt are fractional activities, and is the
ratio of kdephos for mutant to wild type.
RESULTS AND DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
View larger version (19K):
[in a new window]
Fig. 1.
Inhibition of NKCC1 dephosphorylation by
phosphatase inhibitors. Indicated phosphatase inhibitors
were added during dephosphorylation of shark rectal gland NKCC1. Rate
constants were obtained by monoexponential least squares fit of the
dephosphorylation curves, and K0.5 was obtained
from the dependence of the rate constant on [inhibitor] at six
different appropriate concentrations. Values presented as filled
circles are averages and standard errors from three to five
experiments with each inhibitor. For comparison, the range of values
reported in the literature (cf. Refs. 35-37) for PP1
and PP2A are plotted.
View larger version (37K):
[in a new window]
Fig. 2.
Regulation of NKCC1 function by [Cl]
depends on the RVXFXD site. HEK
cells transfected with various NKCC1 constructs accumulated
86Rb in a 1-min flux assay after preincubation at different
Cl concentrations. a, phosphorimage of 86Rb
influx experiments on 96-well plates, illustrating raw data from one
experiment. Each line was assayed in triplicate lanes, as
indicated. b, 86Rb influx evaluated in a
series of experiments similar to that in a. Values are the
means ± standard errors (n = 4, except
n = 3 for trunc153), obtained after normalization of
each line to its maximal flux in an experiment. The line
through the points for wild type NKCC1 is drawn by eye;
the upper line is calculated from the first line assuming a
10-fold lower dephosphorylation rate (see "Experimental
Procedures"; = 0.1); the lower line is calculated
assuming a 4-fold higher rate compared with wild type. c,
cell [Cl] and cell volume after preincubation in the media containing
various Cl concentrations. Points show means of triplicates in one
experiment; four other experiments gave similar results.
Lines are drawn by eye.
Clearly, destruction of the RVXFXD motif produces
an activating shift in cotransporter regulation, consistent with a
decrease in the ability of PP1 to dephosphorylate the target protein.
Noting that the NKCC sequence might be "improved" relative to other
RVXFXD peptides, we tested the sequence KRVRFED
of a known PP1c binding peptide (4). This sequence has additional basic
residues at 2 and +1 and an additional acidic residue at +3
(numbering relative to valine), each of which is expected to improve
the binding. Indeed this mutant proved to be extremely difficult to
activate, maximum flux being attained only in the presence of the
phosphatase inhibitor calyculin A. This is consistent with an increased
rate of dephosphorylation, and the data can be modeled by a 4-fold higher rate compared with control (Fig. 2b, lower
line).
The RVXFXD site is 100% conserved in NKCC1 among various vertebrate species from shark to human, but the corresponding region of the renal form, NKCC2, (RISFRP) has RP instead of a favorable downstream acidic residue. Indeed, when the NKCC1 site was replaced with the NKCC2 sequence, we found that this mutant behaved similarly to others in which the RVXFXD site was destroyed; regulation was shifted in favor of activation at all Cl concentrations (Fig. 2). This result must explain, at least in part, the fact that NKCC2 is constitutively more active than NKCC1 both in its native location in the renal tubule (26) and when it is expressed in Xenopus oocytes (27).
An interesting aspect of the RVXFXD mutations is
that they do not have all or none functional consequences. We expected
that our mutants might be fully active under all conditions, but
instead loss of the motif resulted in a cotransporter that is 10-fold more readily activated compared with controls. Thus the interaction appears to have evolved to fine tune the volume and Cli
regulatory system, effectively adjusting the set point to a lower cell
volume and lower [Cl]i. The physiological consequence of
this change is illustrated in Fig. 3,
where resting [Cl]i in transfected HEK cells is seen to
be strongly determined by the nature of the NKCC1 regulatory domain.
The effect on cell volume is smaller (not significant in these
experiments) consistent with the idea that NKCC1 plays a larger role in
[Cl]i regulation than in volume regulation (18).
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The behavior of our mutants is consistent with changes in regulatory
phosphorylation of NKCC. Above we modeled this as a change in the
dephosphorylation rate. An alternative possibility is that a change in
the phosphorylation rate is most affected by the mutations. To address
this question, we examined the decrease in the level of phosphorylation
of NKCC1 as a function of time in extracts of transfected HEK cells. As
illustrated in Fig. 4, each of the alanine mutations results in a ~5-fold decrease in the rate of cell-free dephosphorylation compared with that of wild type NKCC1 (we
have no explanation for the small rapid phase of dephosphorylation that
is similar in each sample). This strongly supports the proposal that
impaired interaction with PP1c is the outcome of mutations of the
RVXFXD site.
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To look directly for interaction between PP1c and NKCC1 we utilized a
microcystin affinity matrix to pull down PP1c (23). Microcystin binds
to PP1 with high affinity at a site distinct from the one that binds
the RVXFXD sequence (3, 28). Fig. 5a illustrates the efficiency
of the microcystin beads in precipitating PP1c and demonstrates that
pre-incubation with excess microcystin blocks the precipitation. As
shown in Fig. 5b, wild type NKCC1 is specifically
coprecipitated with PP1c on the microcystin beads, as detected by NKCC1
antibodies. In an alanine mutant lacking the
RVXFXD consensus site, there was no detectable
coprecipitation of cotransporter, but in the "improved"
KRVRFED mutant, greatly increased coprecipitation of NKCC1 with PP1c
was consistently observed. These results demonstrate direct binding of
PP1c to NKCC1, and they show that the RVXFXD
consensus motif is responsible for the physical interaction.
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Previous utilization of microcystin affinity methods led to the coprecipitation of numerous proteins with PP1c (29). Specific interactions have been noted between PP1 or PP2 and various potential target proteins (30-34), but a functional interaction has been demonstrated only in the case of the Bad protein (30). Our results suggest that in addition to the targeting proteins identified in earlier studies, many PP1c-associating proteins may actually be substrate proteins specifically recognized through an RVXFXD motif. Similarly it appears likely that among the estimated 10% of data base proteins containing the motif (3), many more than previously suspected may have functional interactions with PP1c.
The results presented here establish a new paradigm for recognition of
substrate proteins by PP1-specific interaction between PP1c and an
RVXFXD motif on the final target protein. This
contrasts with the conventional model in which interactions between
PP1c and substrate proteins are mediated by a set of targeting
proteins. To our knowledge, the present result is the first time a
phosphatase-specific binding site has been identified on a substrate
protein and demonstrated to be of functional significance. It seems
likely that this paradigm will be found to be widely applicable to the
problem of substrate recognition by protein phosphatases.
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ACKNOWLEDGEMENTS |
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We thank Grace Jones, Frederique Dewaersegger, and Jocelyn Forbush for excellent technical assistance, Angus Nairn for helpful discussions, and Ignacio Giménez, Daniel Bowles, and Brian Dowd for comments on the manuscript.
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FOOTNOTES |
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* This work was supported by National Institutes of Health Grant DK47661.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.
Present address: Dept. of Medicine, Molecular Medicine and Renal
Unit, Beth Israel Deaconess Medical Center, Harvard Medical School, 330 Brookline Ave., RW763, Boston, MA 02215. Tel.: 617-667-2923; E-mail:
rdarman@caregroup.harvard.edu.
§ Dept. of Neonatology, University Children's Hospital of Munich, Lindwurmstr. 4, Munich, Bavaria D-80337, Germany. Tel.: 49-89-5160-2811; E-mail: andreas.flemmer@kk-i.med.uni-muenchen.de.
¶ To whom correspondence should be addressed: Dept. of Cellular and Molecular Physiology, Yale University School of Medicine, 333 Cedar St., New Haven, CT 06520-8026. Tel.: 203-785-4068; Fax: 203-785-6834; E-mail: biff.forbush@yale.edu.
Published, JBC Papers in Press, July 20, 2001, DOI 10.1074/jbc.C100368200
2 Unpublished results.
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ABBREVIATIONS |
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The abbreviations used are: PP1 and PP2, protein phosphatases type 1 and 2; PP1c, catalytic subunit of protein 1; NKCC1 and NKCC2, isoforms of the Na-K-Cl cotransporter; DTT, dithiothreitol; HEK, human embryonic kidney.
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ABSTRACT
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B. Benziane, S. Demaretz, N. Defontaine, N. Zaarour, L. Cheval, S. Bourgeois, C. Klein, M. Froissart, A. Blanchard, M. Paillard, et al. NKCC2 Surface Expression in Mammalian Cells: DOWN-REGULATION BY NOVEL INTERACTION WITH ALDOLASE B J. Biol. Chem., November 16, 2007; 282(46): 33817 - 33830. [Abstract] [Full Text] [PDF]
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K. B. E. Gagnon, R. England, L. Diehl, and E. Delpire Apoptosis-associated tyrosine kinase scaffolding of protein phosphatase 1 and SPAK reveals a novel pathway for Na-K-2C1 cotransporter regulation Am J Physiol Cell Physiol, May 1, 2007; 292(5): C1809 - C1815. [Abstract] [Full Text] [PDF]
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I. Gimenez and B. Forbush The Residues Determining Differences in Ion Affinities among the Alternative Splice Variants F, A, and B of the Mammalian Renal Na-K-Cl Cotransporter (NKCC2) J. Biol. Chem., March 2, 2007; 282(9): 6540 - 6547. [Abstract] [Full Text] [PDF]
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D. Pacheco-Alvarez, P. S. Cristobal, P. Meade, E. Moreno, N. Vazquez, E. Munoz, A. Diaz, M. E. Juarez, I. Gimenez, and G. Gamba The Na+:Cl- Cotransporter Is Activated and Phosphorylated at the Amino-terminal Domain upon Intracellular Chloride Depletion J. Biol. Chem., September 29, 2006; 281(39): 28755 - 28763. [Abstract] [Full Text] [PDF]
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A. N. Anselmo, S. Earnest, W. Chen, Y.-C. Juang, S. C. Kim, Y. Zhao, and M. H. Cobb WNK1 and OSR1 regulate the Na+, K+, 2Cl- cotransporter in HeLa cells PNAS, July 18, 2006; 103(29): 10883 - 10888. [Abstract] [Full Text] [PDF]
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P. de los Heros, K. T. Kahle, J. Rinehart, N. A. Bobadilla, N. Vázquez, P. San Cristobal, D. B. Mount, R. P. Lifton, S. C. Hebert, and G. Gamba WNK3 bypasses the tonicity requirement for K-Cl cotransporter activation via a phosphatase-dependent pathway PNAS, February 7, 2006; 103(6): 1976 - 1981. [Abstract] [Full Text] [PDF]
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A. Mercado, V. Broumand, K. Zandi-Nejad, A. H. Enck, and D. B. Mount A C-terminal Domain in KCC2 Confers Constitutive K+-Cl- Cotransport J. Biol. Chem., January 13, 2006; 281(2): 1016 - 1026. [Abstract] [Full Text] [PDF]
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K. B. E. Gagnon, R. England, and E. Delpire Volume sensitivity of cation-Cl- cotransporters is modulated by the interaction of two kinases: Ste20-related proline-alanine-rich kinase and WNK4 Am J Physiol Cell Physiol, January 1, 2006; 290(1): C134 - C142. [Abstract] [Full Text] [PDF]
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I. C. Del Castillo, M. Fedor-Chaiken, J. C. Song, V. Starlinger, J. Yoo, K. S. Matlin, and J. B. Matthews Dynamic regulation of Na+-K+-2Cl- cotransporter surface expression by PKC-{epsilon} in Cl--secretory epithelia Am J Physiol Cell Physiol, November 1, 2005; 289(5): C1332 - C1343. [Abstract] [Full Text] [PDF]
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H. S. Kocinsky, A. C. C. Girardi, D. Biemesderfer, T. Nguyen, S. Mentone, J. Orlowski, and P. S. Aronson Use of phospho-specific antibodies to determine the phosphorylation of endogenous Na+/H+ exchanger NHE3 at PKA consensus sites Am J Physiol Renal Physiol, August 1, 2005; 289(2): F249 - F258. [Abstract] [Full Text] [PDF]
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C. M. Liedtke, X. Wang, and N. D. Smallwood Role for Protein Phosphatase 2A in the Regulation of Calu-3 Epithelial Na+-K+-2Cl-, Type 1 Co-transport Function J. Biol. Chem., July 8, 2005; 280(27): 25491 - 25498. [Abstract] [Full Text] [PDF]
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N. D. Smallwood, B. S. Hausman, X. Wang, and C. M. Liedtke Involvement of NH2 terminus of PKC-{delta} in binding to F-actin during activation of Calu-3 airway epithelial NKCC1 Am J Physiol Cell Physiol, April 1, 2005; 288(4): C906 - C912. [Abstract] [Full Text] [PDF]
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C. F. Simard, G. M. Brunet, N. D. Daigle, V. Montminy, L. Caron, and P. Isenring Self-interacting Domains in the C Terminus of a Cation-Cl- Cotransporter Described for the First Time J. Biol. Chem., September 24, 2004; 279(39): 40769 - 40777. [Abstract] [Full Text] [PDF]
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H. CEULEMANS and M. BOLLEN Functional Diversity of Protein Phosphatase-1, a Cellular Economizer and Reset Button Physiol Rev, January 1, 2004; 84(1): 1 - 39. [Abstract] [Full Text] [PDF]
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K. Piechotta, N. Garbarini, R. England, and E. Delpire Characterization of the Interaction of the Stress Kinase SPAK with the Na+-K+-2Cl- Cotransporter in the Nervous System: EVIDENCE FOR A SCAFFOLDING ROLE OF THE KINASE J. Biol. Chem., December 26, 2003; 278(52): 52848 - 52856. [Abstract] [Full Text] [PDF]
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Y. A. Mahmmoud, G. Cramb, A. B Maunsbach, C. P. Cutler, L. Meischke, and F. Cornelius Regulation of Na,K-ATPase by PLMS, the Phospholemman-like Protein from Shark: MOLECULAR CLONING, SEQUENCE, EXPRESSION, CELLULAR DISTRIBUTION, AND FUNCTIONAL EFFECTS OF PLMS J. Biol. Chem., September 26, 2003; 278(39): 37427 - 37438. [Abstract] [Full Text] [PDF]
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