From the Department of Biochemistry and Molecular
Biology, Mayo Foundation, Rochester, Minnesota 55905 and
¶ National Institute of Haematology and Immunology,
1113 Budapest, Hungary
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ABSTRACT |
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Phosphorylation by protein kinase C of isoform 4a
of the human plasma membrane Ca2+ pump (hPMCA4a) was
studied using the COS cell expression system. Phosphorylation of
several truncated mutants of hPMCA4a indicated that a single
phosphorylation site lies in a region between residues 1113 and 1125. This region is within the calmodulin binding domain and contains a
single phosphorylatable residue, serine 1115. Converting this serine to
an alanine diminished phosphorylation greatly. Phosphorylation, done in
the absence of calmodulin, did not affect subsequent calmodulin
binding, but previous binding of calmodulin did inhibit
phosphorylation. Moreover, no significant shift in the calmodulin
response curve of hPMCA4a was observed when phosphorylation was
mimicked by converting serine 1115 to an acidic residue. The calmodulin
binding domain of hPMCA4a is much longer than other calmodulin binding
domains and has been suggested to consist of two binding lobes
interrupted by a short nonbinding region. The findings of this study
indicate that serine 1115 is the residue phosphorylated by protein
kinase C, and that it lies within the nonbinding region of the
calmodulin binding domain.
The plasma membrane Ca2+ pump, with its high
Ca2+ affinity, appears to be responsible for maintaining
the low resting level of Ca2+ in the unstimulated cell. The
activity of this pump is controlled by several different means: by
calmodulin, acidic phospholipids, phosphorylation with protein kinases,
proteolysis, and dimerization. Most of the regulatory determinants of
the enzyme are located at its carboxyl terminus. This region contains
the high affinity calmodulin binding site, an autoinhibitory region,
sites for phosphorylation with protein kinases C and A, and cleavage
sites for proteolysis (1, 2). It is a highly variable region displaying
great diversity between the different
PMCA1 isoforms.
The pump is encoded by four different genes, and an additional
variability is produced by alternative RNA splicing so that the number
of possible transcripts of the pump is >20 (3). The alternative
splices at site C alone create ~10 protein variants. This site is
located in the middle of the region coding for the calmodulin binding
domain, and the splices involve a frameshift that changes all of the
downstream residues. Because these splices are in the regulatory
region, the different pump variants are expected to have different
regulatory properties. In hPMCA4 such a variation has been shown to
have a striking effect on the calmodulin binding and basal activity
(4). These structural changes also cause a major change in the sites
available for phosphorylation by protein kinases. Although all isoforms
show a great proportion of serine and threonine residues at the
carboxyl terminus, the locations of consensus sequences for
phosphorylation are quite different from one isoform to the other (1).
The alternate splice, especially, has a profound effect on the location
of the phosphorylatable residues in this region.
The regulatory region of hPMCA4b begins with a 28-residue calmodulin
binding domain and continues with a downstream inhibitory region, which
does not contribute to calmodulin binding (5). This downstream
inhibitory region contains the sites for phosphorylation with protein
kinase C. Phosphorylation of these sites releases the inhibition caused
by the inhibitory region but does not affect the inhibition caused by
the calmodulin binding domain. Thus, phosphorylation stimulates the
pump only partially, and binding of calmodulin is needed to achieve
full activity of the enzyme. Because these phosphorylation sites are
located downstream of the calmodulin-binding domain, phosphorylation of
hPMCA4b at these sites does not affect calmodulin binding (6).
The structure of the regulatory region of hPMCA4a, the other splice
variant of isoform 4, is quite different. It has a much longer
calmodulin binding domain of 49 residues, which overlaps completely
with the inhibitory region. We have suggested that the long calmodulin
binding sequence of hPMCA4a actually consists of two binding lobes
separated by a short nonbinding region (7). Because of this difference
in the structure of the regulatory region, isoform 4a has a much lower
affinity for calmodulin and a higher basal activity than isoform 4b
(4).
The great variability between the isoforms at the carboxyl terminus has
suggested that they would have different protein kinase C
phosphorylation sites, and phosphorylation at these sites would have a
different effect on their activity. A recent study has shown that
isoforms 2b and 3b were not phosphorylated significantly by protein
kinase C, whereas isoforms 2a and 3a were phosphorylated (8).
Phosphorylation of 2a and 3a with the kinase reduced calmodulin binding
of these forms drastically but did not affect their basal activity.
Here we show that phosphorylation of hPMCA4a with protein kinase C
occurs within the calmodulin binding domain but does not affect
substantially either the calmodulin affinity or the basal activity of
the enzyme. Using site-directed mutagenesis we have identified a unique
phosphorylation site in hPMCA4a and determined that this site lies
within the folded out nonbinding region of the calmodulin binding domain.
45Ca and [ Construction of the hPMCA4a Mutants--
4a-ct56 and 4a-ct44
were constructed as described before (4, 7). Mutations of serine 1115 of the full-length hPMCA4a were done by double PCR (9). In this method,
the first PCR product was made by amplification of an hPMCA4a sequence
using a primer containing the desired mutation and a primer including a
unique restriction site (KpnI) already present in the
sequence. The product of this PCR was then used as a primer for a
second round of PCR, with the other primer including the second unique restriction site (NsiI). The PCR products were cloned using
the blunt PCR cloning kit from Invitrogen and sequenced by the Mayo Molecular Biology Core Facility. The NsiI-KpnI
piece was cut out and placed into the wild-type hPMCA4a in the vector
psp72. The full-length SalI-KpnI piece was then
cut out of psp72 and ligated into the expression vector pMM2.
Transfection--
Transfection was carried out using
LipofectAMINE based on the protocol as described by the manufacturer
and by Enyedi et al. (8). Briefly, transfection was
initiated when the cells were 70-80% confluent in 150-cm2
flasks. The cells were incubated at 37 °C with the DNA-LipofectAMINE complex (formed by incubating 8 µg of DNA and 100 µl of
LipofectAMINE in 3.6 ml of serum-free Optimem medium) in 14.5 ml of
serum-free Optimem medium. After 5 h of incubation, the cells were
supplemented with serum, and incubation continued for a total of
24 h. The medium containing DNA-LipofectAMINE complex was then
replaced with fresh tissue culture medium with 10% serum, and the
cells were cultured for an additional 24 h.
Isolation of Microsomes from COS Cells--
Crude microsomal
membranes from COS cells were prepared as described by Enyedi et
al. (6).
Ca2+ Transport Assay--
Ca2+ uptake by
microsomal vesicles was carried out in a 200-µl reaction mixture and
assayed by rapid filtration through Millipore membrane filters (0.45 µm pore size, type HA) as described (6, 8). The reaction mixture
contained 100 mM KCl, 25 mM
TES-triethanolamine, pH 7.2, 40 mM
KH2PO4/K2HPO4, pH 7.2, 200 nM thapsigargin, 5 mM NaN3, 4 µg/ml oligomycin, 7 mM MgCl2, 100 µM CaCl2 (labeled with 45Ca;
specific activity, 100,000-150,000 cpm/nmol), and enough EGTA to
obtain 1.2 µM free Ca2+ concentration.
Microsomes at a 10-20 µg/ml concentration were preincubated in the
presence of the appropriate calmodulin concentration for 2 min at
37 °C, and Ca2+ uptake by the vesicles was started by
the addition of 6 mM ATP. When the effect of protein kinase
C on the calmodulin-activity was studied, Ca2+ uptake by
the vesicles was started in the presence of 20 milliunits (0.0857 µg/ml) of PKC and 100 nM phorbol 12-myristate 13-acetate in the absence of calmodulin. 250 nM calmodulin was added
where appropriate, and the reaction was continued for an additional 5 min. The reaction was terminated by separating the microsomes with
filtration through the Millipore membrane filters.
Phosphorylation of Microsomal Membrane Proteins with Protein
Kinase C--
10 µg of microsomal membranes isolated from COS-1
cells transfected with the appropriate construct were phosphorylated
with rat brain protein kinase C basically as described (6, 8). A
200-µl reaction mixture contained 100 mM KCl, 25 mM TES-triethanolamine, pH 7.2, 1 mM
MgCl2, 5 mM dithiothreitol, 0.1 mM
sodium orthovanadate, 100 µM CaCl2, and 90 µM EGTA. This mixture was preincubated for 3 min with 20 milliunits (0.0875 µg/ml) of protein kinase C and 100 nM
phorbol 12-myristate 13-acetate, and the reaction was started by the
addition of 20 µM [ Binding of the Phosphorylated hPMCA4a Constructs to
Calmodulin-Sepharose--
This was done as described previously (6,
8). Briefly, the phosphorylation reaction described above was
terminated by putting the samples on ice, and subsequently, 40 µl of
extraction solution containing 5 mM MgCl2, 5 mM CaCl2, 2% Triton X-100, 1.5 M
sucrose, 0.8 M NaCl, and 50 mM
TES-triethanolamine, pH 7.2, were added. The mixture was incubated on
ice for 15 min. Then, 50 µl of a suspension of calmodulin-Sepharose
beads was added to each sample, and binding was allowed to proceed on
ice for 90 min. The unbound proteins were removed by washing the beads four times with 200 µl of 5 × diluted extraction buffer. The
proteins bound to the calmodulin-Sepharose were removed by incubating
the beads with the electrophoresis sample buffer described above, which
contained SDS-urea. The beads were separated from the samples by
centrifugation, and an aliquot of each sample was applied to an
SDS-polyacrylamide gel.
Gel Electrophoresis, Electrotransfer, and
Autoradiography--
The radioactive samples were electrophoresed on
4-15% gradient acrylamide gel following Laemmli's procedure (13).
The samples were subsequently electroblotted, and the blots were
immunostained with monoclonal antibody 5F10 (10) before autoradiography
for 2-3 days. The amount of phosphorylation was quantitated using the
Bio-Rad GS-363 Molecular Imager System and related to the amount of
pump protein of the same immunoblot. The amount of the constructs was
determined by antibody binding using the enhanced chemiluminescence
Western blot detection system and was quantitated using the Bio-Rad
Molecular Imager System.
We studied the phosphorylation of hPMCA4a expressed in the COS
cell system with protein kinase C. To determine the region where
phosphorylation occurs, we followed the same strategy as we had
previously used for hPMCA4b (6); i.e. we used truncated mutants of hPMCA4a called 4a-ct44 and 4a-ct56 expressed in COS cells.
Fig. 1 shows the sequence of the
calmodulin binding domain at the carboxyl terminus of hPMCA4a, and the
arrows show where the truncates end. Using these constructs,
we have been able to determine the boundaries of the calmodulin binding
domain and the autoinhibitory region (7). Phosphorylation of the
membranes containing the expressed constructs was performed in the
presence of protein kinase C and [
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
REFERENCES
MATERIALS AND METHODS
-32P]ATP were purchased
from NEN Life Science Products. Calmodulin and calmodulin-Sepharose
were obtained from Sigma. phorbol 12-myristate 13-acetate and rat brain
protein kinase C (containing isoforms
,
1,
2, and
) were
purchased from Calbiochem. The specific activity of the protein kinase
C preparation was 1130 units/mg protein. LipofectAMINE and Optimem
media were obtained from Life Technologies, Inc. All other chemicals
used for this study were of reagent grade.
-32P]ATP. After 5 min
of incubation the reaction was terminated by the addition of 1 ml of
ice-cold 6% trichloroacetic acid containing 1 mM ATP and
10 mM inorganic phosphate. The precipitate was supplemented with 50 µg of bovine serum albumin, washed three times with the same
trichloroacetic acid solution, and then dissolved in the electrophoresis sample buffer containing 62.5 mM Tris-HCl,
pH 6.8, 2% SDS, 10% glycerol, 5 mM EDTA, 125 mg/ml urea,
and 100 mM dithiothreitol. An aliquot of this solution
containing 2 µg of membrane protein was applied to each track of an
SDS-polyacrylamide gel.
RESULTS
-32P]ATP. Fig.
2A shows an immunoblot of the
phosphorylated membrane samples stained with monoclonal antibody 5F10,
whereas Fig. 2B is an autoradiogram of the same immunoblot.
Fig. 2A shows that hPMCA4a and the truncates were expressed
in the COS cell membrane equally well. On the autoradiogram shown in
Fig. 2B strong phosphorylated bands could be seen at the
position of full-length hPMCA4a and 4a-ct44, whereas the
phosphorylation was much weaker at the position of 4a-ct56.
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Fig. 1.
Sequence of the calmodulin binding
(C) and inhibitory (I) domain of hPMCA4a.
The arrows show the residues where the truncated mutants
end. Phosphorylatable residues are in bold type; basic
residues are underlined; and acidic residues are
boxed.
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Fig. 2.
Phosphorylation with protein kinase C of
hPMCA4a and its truncated mutants, 4a-ct44 and 4a-ct56. 10 µg of
microsomal membrane proteins isolated from COS cells transfected with
the appropriate constructs were phosphorylated with protein kinase C as
described under "Materials and Methods." 2 µg of the samples were
separated on an SDS-polyacrylamide gel and immunoblotted. A,
5F10 staining. B, autoradiogram of the same paper. The
phosphorylation pattern seen is typical of three different
experiments.
To analyze binding of the phosphorylated proteins to calmodulin, the samples were loaded onto calmodulin-Sepharose in the presence of calcium followed by extensive washings to remove the loosely bound proteins. The protein bound to the Sepharose beads was analyzed by gel electrophoresis and immunoblotting (Fig. 3). It is evident from Fig. 3 that all constructs bound to the calmodulin-Sepharose and that strong phosphorylation of hPMCA4a and 4a-ct44 could be seen. This experiment allowed us to see more clearly the lack of labeling of 4a-ct56. This was evident because only the pump bound to the column with high affinity, greatly improving the labeling/background ratio in the phosphorylation experiment. Because 4a-ct56 was not labeled, our data suggested that the phosphorylatable site in hPMCA4a resides between residues 1113 and 1125, within a region that is common to both hPMCA4a and 4a-ct44 but missing in 4a-ct56. The only residue that could become phosphorylated within this region is the serine at position 1115. Although this region lies within the calmodulin binding domain of hPMCA4a, phosphorylation did not affect calmodulin binding drastically; i.e. the phosphorylated samples bound to calmodulin-Sepharose. On the other hand, including excess calmodulin in the phosphorylation medium effectively inhibited the labeling of the pump (Fig. 4).
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To verify that phosphorylation was indeed occurring at position 1115, this residue was modified. Fig. 4 shows that converting serine 1115 to an alanine or an aspartate in the full-length hPMCA4a blocked phosphorylation completely, in good accordance with the results obtained with the truncates. These experiments confirmed that serine 1115 is indeed a potential phosphorylation site in hPMCA4a and that this site lies within a region that is involved in calmodulin binding.
Then we tested the effect of phosphorylation with protein kinase C on the Ca2+ transport activity of hPMCA4a. Microsomal membrane vesicles were preincubated with protein kinase C and phorbol 12-myristate 13-acetate in the presence of ATP, and Ca2+ uptake was initiated by the addition of labeled Ca2+. Phosphorylation did not affect either the basal or the calmodulin-stimulated activity of the enzyme (data not shown). Moreover, the activity of the mutant in which phosphorylation was mimicked by adding a fixed negative charge by replacing serine 1115 with an aspartate was equal to that of the wild type or to the mutant in which the serine was replaced by an alanine.
Although phosphorylation did not abolish calmodulin binding, a shift in the calmodulin affinity would be expected because of the introduction of a negative charge within the calmodulin binding domain. Thus, we examined whether the negative charge added by phosphorylation of serine 1115 affected the calmodulin affinity of hPMCA4a. When calcium transport by membrane vesicles expressing the wild-type hPMCA4a was tested, we were unable to detect any effect of phosphorylation on the calmodulin concentration required for half-maximal stimulation of the enzyme (not shown). Because calmodulin may interfere with the phosphorylation reaction, in Fig. 5 we compared the calmodulin response curves of the mutants in which serine 1115 was replaced by an aspartate or by an alanine. These mutants mimic the totally phosphorylated and nonphosphorylated forms of the pump, respectively. No substantial shift in the calmodulin response curves of the mutants compared with that of the wild type could be detected, indicating that phosphorylation of hPMCA4a at serine 1115 does not affect the calmodulin affinity of the enzyme.
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DISCUSSION |
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Protein kinase C is a key element of intracellular signaling, which phosphorylates and regulates a wide variety of intracellular targets. Many of these targets are calmodulin-binding proteins in which phosphorylation occurs in or near the calmodulin binding domain; therefore, phosphorylation of these proteins affects (usually decreases) calmodulin binding (11, 12). It has been accepted that one of these targets is the plasma membrane Ca2+ pump and that the phosphorylation sites of the enzyme also lie near its calmodulin binding domain. The isoform diversity of this pump has caused us to ask whether the different isoforms are all regulated in the same way, or whether the regulation also shows diversity among the isoforms.
Close inspection of the sequences of the isoforms has indicated that they should have different phosphorylation sites. Indeed, our recent experiments have demonstrated that among five different isoforms (rPMCA2b, rPMCA3b, hPMCA4b, rPMCA2a, and rPMCA3a) expressed in the COS cell system, only three are potential targets for protein kinase C phosphorylation (hPMCA4b, rPMCA2a, and rPMCA3a), and that phosphorylation affects their activities differently. In the case of hPMCA4b, protein kinase C partially increases the basal activity and does not affect calmodulin binding (6). In the cases of the other two isoforms phosphorylation does not affect the basal activity, but, rather, by diminishing calmodulin binding, it inhibits the calmodulin-stimulated activity of the enzymes (8).
Although the sequences of the regulatory regions of rPMCA2a and 3a resemble each other rather closely, the sequence of the same region of the other "a" forms is different. In the case of hPMCA4a the serine and threonine residues of this region are much less abundant than in the case of rPMCA2a and 3a, with fewer putative phosphorylation sites. The regulatory sequence and the location of the putative phosphorylation sites of hPMCA4a shows even less resemblance to hPMCA4b.
In this study we demonstrated that hPMCA4a is also a potential target for protein kinase C phosphorylation. Determination of the site of phosphorylation was obtained by analyzing several carboxyl-terminally truncated mutants of hPMCA4a and by point mutation of the full-length enzyme expressed in the COS cell system. Using this strategy, we identified serine 1115 as a single phosphorylation site in the consensus sequence SFKG. The phosphorylation was blocked when calmodulin was bound to the enzyme, in good accordance with previous findings that this sequence is part of the calmodulin binding domain.
Although binding of calmodulin inhibited phosphorylation, the phosphorylated pump still bound to calmodulin-Sepharose and was activated by calmodulin. Moreover, the mutant in which phosphorylation was mimicked by converting serine 1115 to an aspartic acid also was activated by calmodulin. We were unable to detect an effect by introducing a negative charge either by phosphorylation or by mutation on the concentration of calmodulin required for half-maximal activation of hPMCA4a. These results show that serine 1115 is not involved directly in calmodulin binding but is hidden from protein kinase C phosphorylation when calmodulin is bound before phosphorylation. Recently, we have suggested that the calmodulin binding domain of hPMCA4a consists of two separate binding regions, which are interrupted by a short nonbinding loop (7). The present findings support this idea and indicate that serine 1115 is part of the loop that is folded out of the calmodulin-enzyme interaction surface. Thus, the nonbinding loop may start with the aspartic acid at position 1105 and end with the sequence surrounding serine 1115, as shown in Fig. 6.
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Phosphorylation of hPMCA4b at its downstream inhibitory region caused partial activation of the enzyme. On the contrary, phosphorylation of hPMCA4a within its calmodulin binding domain (which also serves as an inhibitor) did not affect the basal activity. This suggests that the loop that is folded out from the calmodulin-enzyme interaction is not in contact with the catalytic core of the pump and therefore is not involved in self-inhibition.
In conclusion, here we have provided additional evidence for the
differential regulation of the plasma membrane calcium pump isoforms
with protein kinase C. It is clear that each isoform has a unique mode
of regulation by protein kinase C phosphorylation, which is presumably
suited to its function in the cell. Of the six isoforms studied so far,
four (4b, 4a, 3a, and 2a) are phosphorylated by protein kinase C, but
only one (4b) is activated by this phosphorylation. The phosphorylation
of 2a and 3a prevented calmodulin binding, whereas phosphorylation of
4a and 4b had little effect on calmodulin binding. The relationship of
these properties to the functions of these isoforms in the living cell
remains to be determined. All of these findings are based on studies
using the overexpressed pump isoforms in COS cell membranes. We cannot
exclude the possibility that in other kinds of membranes unknown
factors may modify the locus and the effect of protein kinase C
phosphorylation, but this is the only system currently available for
studying the characteristics of the individual pump isoforms.
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FOOTNOTES |
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* This work was supported in part by National Institutes of Health Grants GM28835 and GM55514 (to J. T. P.), by Hungarian Academy of Sciences Grant OTKA T023659 (to A. E.), and by an international research scholarship from the Howard Hughes Medical Institute (to A. E. and J. T. P.).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.
§ These authors contributed equally to this work.
To whom correspondence should be addressed: Dept. of
Biochemistry and Molecular Biology, Mayo Foundation, 200 First St.
S. W., Rochester, MN 55905. Tel.: 507-284-2295; Fax:
507-284-9759.
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ABBREVIATIONS |
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The abbreviations used are: PMCA, plasma membrane Ca2+ pump; r, rat; h, human; PCR, polymerase chain reaction; TES, 2-{[2-hydroxy-1,1-bishydroxymethyl)ethyl]amino}-ethanesulfonic acid..
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REFERENCES |
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