(Received for publication, October 3, 1996, and in revised form, January 31, 1997)
From the Research Division, Joslin Diabetes Center, and Department of Medicine, Harvard Medical School, Boston, Massachusetts 02215
Members of the Rad family of GTPases (including Rad, Gem, and Kir) possess several unique features of unknown function in comparison to other Ras-like proteins, with major N-terminal and C-terminal extensions, a lack of typical prenylation motifs, and several non-conservative changes in the sequence of the GTP binding domain. Here we show that Rad and Gem bind to calmodulin (CaM)-Sepharose in vitro in a calcium-dependent manner and that Rad can be co-immunoprecipitated with CaM in C2C12 cells. The interaction is influenced by the guanine nucleotide binding state of Rad with the GDP-bound form exhibiting 5-fold better binding to CaM than the GTP-bound protein. In addition, the dominant negative mutant of Rad (S105N) which binds GDP, but not GTP, exhibits enhanced binding to CaM in vivo when expressed in C2C12 cells. Peptide competition studies and expression of deletion mutants of Rad localize the binding site for CaM to residues 278-297 at the C terminus of Rad. This domain contains a motif characteristic of a calmodulin-binding region, consisting of numerous basic and hydrophobic residues. In addition, we have identified a second potential regulatory domain in the extended N terminus of Rad which, when removed, decreases Rad protein expression but increases the binding of Rad to CaM. The ability of Rad mutants to bind CaM correlates with their localization in cytoskeletal fractions of C2C12 cells. Immunoprecipitates of calmodulin-dependent protein kinase II, the cellular effector of Ca2+-calmodulin, also contain Rad, and in vitro both Rad and Gem can serve as substrates for this kinase. Thus, the Rad family of GTP-binding proteins possess unique characteristics of binding CaM and calmodulin-dependent protein kinase II, suggesting a role for Rad-like GTPases in calcium activation of serine/threonine kinase cascades.
Rad is the prototypic member of a new class of Ras-like
GTP-binding proteins that includes Gem and Kir (1-3). In humans, Rad
is most highly expressed in the heart, lung, and skeletal muscle and
expression is increased in the skeletal muscle of some type II diabetic
humans (1). Rad exhibits a unique magnesium dependence for guanine
nucleotide binding and is regulated by a Rad-specific GTPase-activating
protein (GAP)1 (4). In cultured muscle and
fat cells, Rad overexpression attenuates insulin-stimulated glucose
uptake without altering expression or insulin-stimulated translocation
of the Glut4 glucose transporter (5). By expression library screening,
Rad has been shown to interact with skeletal muscle -tropomyosin,
suggesting that Rad may participate in regulation of the cytoskeleton
(6). The Gem gene product is expressed in the G1 phase in
mitogen-activated T lymphocytes and shares approximately 60% amino
acid identity with Rad (2), whereas kir was isolated from a
pre-B-cell library and is overexpressed in cells expressing
BCR/ABL or v-abl (3). Murine kir and
gem are 98.4% identical in nucleotide sequence and encode
the same or very highly related proteins, referred to here as Kir/Gem
(3). When expressed in Saccharomyces cerevisiae, kir induces invasive pseudohyphal growth and may function
upstream of the STE20 kinase (7).
rad and kir/gem encode GTP-binding proteins with several structural features that are distinct from other GTPases (1-3). The N terminus of Rad is extended by 88 amino acids, and Kir/Gem is extended by 72 amino acids in comparison to Ras, and the C terminus of each is extended by 31 amino acids. Although Rad and Kir/Gem share 100% identity in the final 11 amino acids, they lack a CAAX-like prenylation site present in other Ras-like molecules (8, 9). Rad and Kir/Gem differ from each other and from other Ras-like proteins in the putative effector (G2) domain, suggesting that they interact with distinct GAPs or effector molecules. They also contain residues in the G3 consensus sequence for guanine nucleotide binding which are divergent from Ras (1-3).
Members of the Ras family of GTP-binding proteins participate in a number of cellular functions including proliferation (10), vesicular transport (11, 12), and cytoskeletal arrangement (13, 14). Rac and cdc42 have been shown to interact with phosphatidylinositol 3-kinase and to participate in signaling leading to activation of the Jun kinases (15, 16). While the exact function of Rad and Kir/Gem is unknown, it has recently been reported in abstract that peptides based on the C terminus of Rad and Kir/Gem can bind to calmodulin (CaM) in vitro (17). In this study, we show that the full-length Rad protein binds CaM in vitro and in vivo in a Ca2+-dependent manner and that the C-terminal residues 278-297 of human Rad are critical for this interaction. The binding of Rad and CaM is influenced by the guanine nucleotide bound state of Rad. We also demonstrate that Rad is present in complex with the cellular target of CaM, calmodulin-dependent protein kinase II (CaMKII), which can phosphorylate both Rad and Gem in vitro. These findings suggest that the Rad family of Ras-like proteins may participate in Ca2+-triggered signaling events involving CaM and the CaMKII serine/threonine kinase cascade.
C2C12 murine myocytes transfected with puromycin resistance
vector only (Puro), or expressing full-length human wild-type (WT)
rad cDNA, the potential dominant negative mutant, S105N, or the putative activated mutant, P61V/Q109H (PVQH), were produced by
transfection using the pBabe-Puro retroviral vector (6). C-terminal
deletion mutants were constructed by polymerase chain reaction using WT
Rad cDNA as a template. 5 primers spanned an internal PflM1 site
within the rad coding region. 3
primers contained an
EcoRI restriction site and an in-frame stop codon to
terminate translation at residues 249, 278, or 297 of Rad. Reaction
products were cloned into the PflM1-EcoRI sites of the
pBABE-WT Rad vector to replace the C-terminal sequences of the WT
construct. Deletion of the N-terminal 88 amino acids of Rad was
achieved using 5
primers containing a BamHI restriction
site and sequences homologous to rad beginning at codon 88 following an initiating methionine. 3
primers flanked the Rad
termination codon and contained an EcoRI restriction site.
Reaction products were cloned into the BamHI-EcoRI sites of the pBabe-Puro vector. All
constructs were confirmed by sequence analysis. Stable
puromycin-resistant cell lines expressing Rad mutants were established
as described previously (6).
C2C12 murine myocytes were maintained in Dulbecco's modified Eagle's medium containing 10% fetal bovine serum in a 5% CO2 environment. Two days post-confluence, cells were fed with Dulbecco's modified Eagle's medium containing 1% calf serum and allowed to differentiate into mature myotubes for 5-7 days. Cells on a 100-mm dish were washed twice with ice-cold phosphate-buffered saline and scraped into 500 µl of lysis buffer containing 1% Triton X-100, 25 mM Tris, pH 7.4, 150 mM NaCl, 1 mM DTT, 1 mM MgCl2, 1 mM phenylmethylsulfonyl fluoride, 10 µg/ml aprotinin, and 10 µg/ml leupeptin. Cells were rotated at 4 °C for 1 h prior to centrifugation at 10,000 × g for 10 min to remove insoluble material. Protein concentrations were determined using the BCA protein assay (Pierce).
Preparation of GST-fusion Proteins and PeptidesThe pGEX-2T vector encoding full-length Gem was a generous gift from K. Kelly, National Institutes of Health. Purified recombinant GST-Rad and GST-Gem were prepared as described previously for Rad (4). Peptides corresponding to the C-terminal residues 279-308 of human Rad (KRFLGRIVARNSRKMAFRAKSKSCHDLSVL) and to the Rad effector domain residues 115-127 (DGPEAEAAGHTYD) were generated by the peptide core of the Joslin Diabetes Center DERC.
CaM-Sepharose Binding, Immunoprecipitation, and ImmunoblottingFor binding to CaM-Sepharose, GST-Sepharose, or Sepharose 4B, lysates (0.5 or 1.0 mg) or purified Gem (0.5 µg) were incubated in lysis buffer with 10-20 µl of a 50% slurry of CaM-Sepharose (Pharmacia Biotech Inc., final concentration 3-6 µM), GST-Sepharose, or Sepharose 4B (Pharmacia) which was previously washed three times in lysis buffer. When noted, incubations contained 1 mM CaCl2 or 2 mM EGTA. Following rotation for 4 h at 4 °C, beads were washed three times in lysis buffer with or without CaCl2 or EGTA. For immunoprecipitations, extracts were incubated with 5 µg of anti-CaM monoclonal antibody (Upstate Biotechnology, Inc., UBI), 5 µg of anti-CaMKII polyclonal antibody (UBI), or anti-Rad polyclonal antiserum JD68 (6) for 4 h at 4 °C. Immune complexes were precipitated using protein G-Sepharose (Pharmacia) for CaM or protein A-Sepharose (Pharmacia) for CaMKII and Rad. For Western immunoblotting 1:1000 dilutions of anti-CaM and anti-Rad antibodies were used. Anti-Gem monoclonal antibody, 2D10, was a gift from K. Kelly and was used at a 1:500 dilution. Blots were subsequently incubated with horseradish peroxidase-conjugated goat anti-mouse antibody (Jackson ImmunoResearch) for CaM and Gem or 125I-labeled protein A (DuPont NEN) for Rad. Purified CaM was purchased from Boehringer Mannheim.
GTPase Activity1 µg of GST-Rad bound to
glutathione-Sepharose beads was incubated with or without 5 µg of
purified CaM at 4 °C for 1 h. Beads were washed four times in
ice-cold loading buffer (50 mM Tris-HCl, pH 7.4, 1 mM MgCl2, 1 mM DTT, and 1 mg/ml
bovine serum albumin) prior to loading with [-32P]GTP
(3 µCi) for 5 min at room temperature. GTP hydrolysis was carried out
as described using Rad-GAP partially purified by Mono S chromatography
(4). Equal counts of reaction products were subjected to thin layer
chromatography and analyzed using a Molecular Dynamics
PhosphorImager.
GTP and GDP binding to Rad was determined using a nitrocellulose filtration assay as described (4). 20 pmol/sample of GST-Rad was incubated in exchange buffer (50 mM Tris-HCl, pH 7.4, 1 mM DTT, 1 mM MgCl2, and 1 mg/ml bovine serum albumin) with or without 100 pmol/sample of CaM (Boehringer Mannheim) and 3 µCi/sample [3H]GDP or [3H]GTP (specific activity 25-50 Ci/mmol; DuPont NEN) at room temperature. At each time point 40-µl aliquots were filtered in duplicate through BA 85 nitrocellulose (Schleicher & Schuell) followed by washing with 10 ml of ice-cold filtration buffer (50 mM Tris-HCl, pH 7.4, 0.1 mM DTT, and 1 mM MgCl2). The radioactivity remaining on the filters was determined by scintillation counting.
In Vitro PhosphorylationFor phosphorylation by CaMKII,
approximately 0.5 µg of Rad and Gem recombinant proteins, purified by
thrombin cleavage from GST-fusion proteins or 0.5 µg of MBP (Sigma),
were incubated in a total volume of 30 µl in kinase buffer (50 mM HEPES, pH 7.5, 1 mM DTT, 2 mM
CaCl2, 2 mM CaM) in the presence of 1 unit of
CaMKII (Sigma) and 10 µCi of [-32P]ATP at 30 °C
for 45 min. Reactions were terminated by the addition of SDS sample
buffer and analyzed by SDS-PAGE followed by autoradiography. For time
course determinations 0.4 µg of GST-Rad or GST were incubated in
kinase buffer containing 10 µCi of [
-32P]ATP (100 µM) and 100 units of CaMKII (truncated version, New England Biolabs) at 30 °C for the indicated times. For dose
determinations, 0.4 µg of GST-Rad was incubated in kinase buffer with
10 µCi of [
-32P]ATP (100 µM) and
0-500 units CaMKII (truncated version, New England Biolabs) at
30 °C for 45 min.
C2C12 myotubes expressing WT or mutant Rad were subjected to subcellular fractionation based on the method of Torti et al. (18). Cells from two 150-mm dishes were harvested by scraping into ice-cold buffer (20 mM HEPES, pH 7.4, 255 mM sucrose, 1 mM EDTA, 10 µg/ml leupeptin, 10 µg/ml aprotinin, and 1 mM phenylmethylsulfonyl fluoride). Cells were homogenized with a Teflon pestle in a Wheaton glass homogenizer. The post-nuclear supernatants were centrifuged at 200,000 × g for 60 min. The supernatant containing cytosolic proteins was collected. The total membrane pellet was rehomogenized in buffer containing 10 mM HEPES, 137 mM NaCl, 2.9 mM KCl, 12 mM NaHCO3, pH 7.4, and 1% Triton X-100 and incubated for 30 min at 4 °C. The Triton X-100 insoluble cytoskeleton was collected by centrifugation for 6 min at 12,000 × g. The supernatant was centrifuged for 60 min at 200,000 × g to obtain the membrane skeleton pellet and supernatant containing total soluble membranes. 50 µg of each fraction was analyzed by Western immunoblotting with anti-Rad antibodies.
To determine
whether Rad binds CaM, lysates from C2C12 myoblasts overexpressing Rad
were incubated with calmodulin-Sepharose in the presence of 1 mM CaCl2 or 2 mM EGTA as described
under "Experimental Procedures." In the presence of
Ca2+, but not EGTA, Rad bound CaM-Sepharose, but not the
control GST-Sepharose (Fig. 1A).
Immunoprecipitation of the supernatant from the CaM-Sepharose experiment with anti-Rad antibody revealed that nearly all of the Rad
protein was depleted by prior binding to CaM-Sepharose in the presence
of Ca2+, while the immunoprecipitation of Rad from control
samples was unaffected by CaCl2 or EGTA treatment (Fig.
1B). Similar experiments were performed with purified Gem
incubated with CaM-Sepharose. Like Rad, Gem associated with CaM in the
presence of 1 mM CaCl2 (Fig. 1C, lane
2), and this could be disrupted by treatment with 2 mM
EGTA (Fig. 1C, lane 3). No detectable protein was associated with the control Sepharose 4B beads in the presence of 1 mM
CaCl2 (Fig. 1C, lane 1). Western immunoblotting
revealed that equal quantities of Gem were detected in the starting
material in the presence of CaCl2 or EGTA (Fig.
1D).
Co-immunoprecipitation of Rad and Calmodulin
To determine if
Rad and CaM interact in intact cells, C2C12 cells overexpressing WT Rad
were lysed with Triton X-100 buffer and immunoprecipitated with
anti-Rad or anti-CaM antibodies. Western immunoblotting indicated the
presence of Rad in CaM immunoprecipitates (Fig.
2A, lanes 1 and 2) which varied
between 1 and 10% of the total cellular Rad protein, as determined by
comparison of blots of whole cell lysates. Treatment of cells with 5 µM ionomyocin prior to lysis did not appear to affect the
amount of Rad bound to CaM; however, it is likely that endogenous
stores of Ca2+ released upon lysis might have already
induced the binding of these proteins in the absence of added
Ca2+. Consistent with this, lysis of cells in the presence
of 2 mM EGTA disrupts Rad and CaM interaction (not shown).
In addition, when CaM immune complexes were washed with 2 mM EGTA, Rad was completely dissociated (Fig. 2A,
lane 3), whereas the quantity of Rad in anti-Rad immune complexes
was unaffected by this treatment (Fig. 2A, lane 6 versus lanes
4 and 5), suggesting Ca2+ dependence of the
Rad-CaM interaction in vivo.
Immunoprecipitation with anti-Rad antibody followed by Western immunoblotting for CaM revealed the presence of CaM in anti-Rad immune complexes (Fig. 2B, lanes 4 and 5) and the dissociation of this complex by EGTA treatment (Fig. 2B, lane 6). In the presence of EGTA, CaM exhibited the expected altered migration pattern (Fig. 2B, lane 3) (19). Thus, Rad and CaM co-precipitate in immune complexes in a Ca2+-dependent manner.
CaM Binds the C Terminus of RadCaM-binding sites are rich in
hydrophobic and basic residues with the potential to form a basic
amphipathic -helix, often with charged and hydrophobic residues
residing on opposite sides of the helix (20). When modeled as a helical
wheel, Rad C-terminal residues 274-291 form an almost ideal
CaM-binding domain with a structure composed of opposing surfaces rich
in charged residues or long chain hydrophobic amino acids (Fig.
3).
To determine whether Rad binds CaM via C-terminal residues, we assessed
the ability of a peptide corresponding to the final 30 amino acids of
Rad to compete for Rad binding to CaM-Sepharose. As shown in Fig.
4A, increasing concentrations of a peptide
corresponding to residues 278-308 of human Rad competitively inhibited
the interaction of Rad and CaM, whereas the same concentrations of a
peptide corresponding to the effector region of Rad (residues 115-127)
did not. Quantitation of these results revealed an IC50 of
5 µM for incubation in this assay when the concentration
of CaM was approximately 3 µM (Fig. 4B),
suggesting an approximate 1:1 stoichiometry of Rad-CaM interaction.
To further analyze the CaM-binding region of Rad, several deletion mutants of Rad were constructed and expressed in C2C12 cells. The Rad C297 construct terminates at residue 297, deleting the final 11 amino acids of Rad which share 100% identity with Kir/Gem (1-3). The Rad C278 construct deletes the final 30 amino acids, corresponding to the presumed CaM-binding domain, and the Rad C249 construct deletes the final 59 amino acids of Rad. As in previous experiments, incubation of lysates of C2C12 cells overexpressing WT Rad with CaM-Sepharose followed by Western blotting revealed Ca2+-dependent binding of Rad to the CaM-Sepharose (Fig. 4C, lane 3), which was disrupted by EGTA treatment (Fig. 4C, lane 4). Endogenous Rad in control cells (Fig. 4C, lanes 1 and 2) also bound in a Ca2+-dependent manner and was visible upon longer exposure of the blots (not shown). Deletion of the C-terminal residues 297-308 (C297 mutant) did not significantly affect the ability of Rad to bind CaM (Fig. 4C, lanes 5 and 6). In contrast, deletion of C-terminal residues 278-308 (C278 mutant) abolished Rad binding to CaM (Fig. 4C, lanes 7 and 8), as did a larger deletion of residues 249-308 (C249 mutant, Fig. 4C, lanes 9 and 10), which creates a molecule of identical length to Ras at the C terminus.
As noted above, in addition to the C-terminal extension, Rad also contains 88 additional amino acids on the N terminus as compared with Ras. To identify whether the N terminus of Rad contributes to the binding to CaM, a deletion was made that removes the unique N terminus of Rad. This mutant (N88) exhibited much lower levels of expression than the other mutants (Fig. 4D, lanes 11 and 12), but an appropriate length protein could still be detected by Western blotting of lysates following longer exposure (not shown). Upon incubation of cell lysates with CaM-Sepharose, Rad-88 exhibited a striking enhancement in Ca2+-dependent binding relative to WT Rad (Fig. 4C, lane 11). Quantitation of Rad protein bound to CaM relative to the levels of expression revealed that CaM binding was decreased by >90% with the Rad C278 and C249 C-terminal deletion mutants, whereas the Rad N88 N-terminal mutant exhibited an approximate 24-fold enhancement in CaM binding relative to the wild type protein (Fig. 4E). Thus, the residues of Rad critical for CaM binding are contained within the region encompassing the C-terminal residues 278-297, whereas the N terminus of Rad appears to encode a region that may affect antibody recognition, protein expression or stability, as well as a potential negative regulatory region for CaM binding.
GDP-Rad Preferentially Binds CaMTo determine whether the
interaction of Rad and CaM is influenced by the guanine
nucleotide-bound state of Rad, the binding of GST-Rad to CaM- Sepharose
was assessed following preloading of Rad with GDP or GTPS. In
vitro GDP-bound Rad preferentially bound CaM as compared with
GTP
S-bound Rad with an approximate 8-fold increase in the quantity
of Rad protein bound (Fig. 5A). Removal of
Ca2+ by EGTA treatment disrupted binding of CaM, regardless
of guanine nucleotide association. Similar results were obtained when
Rad protein was cleaved from GST by thrombin treatment prior to the assay (not shown).
To further assess the influence of guanine nucleotide binding on Rad and CaM interaction in vivo, C2C12 cells were used that overexpress wild type Rad (WT), Rad with a mutation (S105N) that abolishes GTP-binding activity and favors GDP binding, and is thus a potential dominant-negative molecule, or Rad with a double mutation (P61V/Q109H, PVQH) that results in a molecule with high intrinsic GTP binding and GTPase activities in vitro (4). Lysates of these cells were assayed by Western immunoblotting for Rad binding to CaM-Sepharose (Fig. 5B) and for expression levels of the Rad proteins (Fig. 5C). The binding to CaM relative to the expression level of WT, S105N, and PVQH Rad was quantitated in Fig. 5D. Results from three independent experiments revealed that the Rad S105N mutant exhibited an approximate 5-fold enhanced CaM binding relative to the WT and PVQH proteins, despite lower relative expression of this mutant. The binding of all three proteins was disrupted by EGTA treatment (Fig. 5B). These results, together with those in which GDP incubation enhanced binding, suggest that the GDP-bound form of Rad preferentially associates with CaM.
CaM Does Not Affect Rad GTPase ActivityA possible role of
CaM binding might be to alter the GTPase activity of Rad. To test this
hypothesis Rad and Rad bound to CaM were subjected to a GTP hydrolysis
assay in the presence or absence of a preparation of partially purified
Rad-GAP (4). GTP hydrolysis by Rad was stimulated approximately
2.5-fold in the presence of partially purified Rad-GAP (Fig.
6A). Rad bound to CaM exhibited a slight
elevation in Rad-GAP-stimulated GTP hydrolysis; however, this was not
significantly different from controls. In addition, CaM had no effect
on intrinsic Rad GTPase activity in the absence of Rad-GAP. Since CaM
preferentially binds the GDP form of Rad, we speculated that CaM might
affect the ability of Rad to bind GTP. However, binding studies
performed in the presence or absence of 5-fold molar excess of CaM did
not show an affect of CaM binding on the ability of Rad to bind either [3H]GTP (Fig. 6B) or [3H]GDP
(Fig. 6C), suggesting that CaM binding may not regulate guanine nucleotide binding of Rad.
Rad Is Present in Complex with CaMKII
A major cellular
effector of Ca2+-CaM signaling is the serine/threonine
kinase CaMKII (20, 21). To determine whether Rad exists in complex with
CaMKII, lysates from control cells, cells expressing WT Rad, and cells
expressing Rad mutants that exhibited altered binding to CaM (C278,
N88, and S105N) were subjected to immunoprecipitation with anti-CaMKII
antibody followed by Western immunoblotting to detect Rad (Fig.
7A). WT Rad overexpressed in C2C12 cells was
detected in anti-CaMKII immunoprecipitates; endogenous Rad was
detectable in these immunoprecipitates upon longer exposure (not
shown). Comparison of blots of whole cell lysates indicated that
approximately 2% of the total cellular Rad protein was present in
anti-CaMKII immunoprecipitates. Quantitation of Rad protein bound to
anti-CaMKII immune complexes relative to the levels of expression is
shown in Fig. 7C. In contrast to what was observed with the
CaM binding experiments, the C-terminal Rad mutant, C278, truncated at
residue 278 exhibited similar binding to CaMKII immune complexes as
compared with the WT and endogenous Rad (Fig. 7, A and
C). The N-terminal truncation, N88 (Fig. 7A, lane
4) exhibited an approximate 4-fold enhancement in binding relative
to WT Rad despite very low levels of expression of this mutant (Fig.
7B, lane 4). A longer exposure of this lane is shown, and
the migration of the 88 mutant is indicated in Fig. 7B, lane
6. Similar to the results for CaM binding, the S105N mutant (Fig.
7A, lane 5) exhibited an approximate 8-fold enhanced binding
to CaMKII, suggesting that this interaction may also be favored by the
GDP-bound form of Rad. Since the Rad truncated at residue 278 (C278)
retained the ability to bind CaMKII but was unable to bind CaM, further
experiments were performed to confirm that Rad binding to CaMKII is
independent of its interaction with CaM. Thus, lysates from cells
expressing WT Rad were subjected to immunoprecipitation with
anti-CaMKII antibodies followed by EGTA washing of the immune
complexes, a treatment which results in dissociation of Rad and CaM. As
shown in Fig. 7D, the presence of 1 mM
CaCl2 or 2 mM EGTA did not affect the
Rad·CaMKII complexes (compare lanes 2 and 3 versus
lane 1). Likewise, addition of a peptide corresponding to residues
278-308 of Rad at concentrations that disrupt Rad-CaM interaction did not disrupt Rad-CaMKII binding (Fig. 7, lanes 4 and
5). Thus, Rad is present in complex with CaMKII under
conditions in which Rad and CaM do not appear to interact.
Rad and Gem Are In Vitro Substrates for CaMKII
Rad and
Kir/Gem possess several potential sites for CaMKII phosphorylation
based on the presence of the consensus sequence RXX(S/T)
(21). To determine whether these GTP-binding proteins can, in fact,
serve as a substrates for CaMKII, purified recombinant Rad and Gem were
incubated in a kinase reaction containing CaMKII, CaM, and
CaCl2, as described under "Experimental Procedures." Both Rad and Gem were phosphorylated by CaMKII as was the control substrate, MBP (Fig. 8A). Thrombin, which was
present in the protein preparations as a result of protein
purification, was not phosphorylated by CaMKII. For a time course
determination of Rad phosphorylation, GST-Rad or GST were incubated in
a kinase reaction with 100 units of a 33-kDa truncated version of
CaMKII for various times as described under "Experimental
Procedures." Phosphorylation of GST-Rad was apparent within 1 min and
peaked within 45 min at 30 °C (Fig. 8B). Phosphorylation
of GST control (29 kDa) was not observed under these conditions.
Quantitation of the counts incorporated into Rad at 45 min of
incubation revealed that Rad was phosphorylated with a stoichiometry of
0.6 ± 0.17 mol of ATP/mol of protein. For dose determinations of
the kinase, GST-Rad was incubated with 0-500 units of truncated CaMKII
for 45 min at 30 °C. GST-Rad was phosphorylated by CaMKII in a
dose-dependent manner with phosphorylation being apparent
with 10 units of CaMKII.
Correlation of CaM Binding with Cellular Localization
Rad
lacks the prenylation motifs found in most Ras-like molecules and is
located in both the cytoplasm and membrane of the cell (5). A portion
of Rad, however, is associated with the cytoskeleton and membrane
skeleton components by as yet undetermined mechanisms.2 To determine whether the
CaM-binding site of Rad influences localization, C2C12 myotubes
expressing WT and mutant Rad were subjected to fractionation into
cytosolic and membrane components. Western immunoblot analysis revealed
that endogenous Rad in control cells, WT Rad in overexpressing cells,
and the C297 C-terminal deletion mutant were distributed similarly
among cytoskeleton, membrane skeleton, total soluble membrane, and
cytosolic fractions (Fig. 9, lanes 1-12). In
contrast, Rad with a deletion of the CaM-binding domain, residues
278-308, was localized almost completely in the cytosolic fraction
(Fig. 9, lanes 13-16). Similarly, deletion of residues
249-308 yielded a cytosolic mutant (lanes 17-20), although
detection of this mutant was complicated by the presence of a
nonspecific protein band at 32 kDa present in the membrane skeleton
fraction of each cell type. Interestingly, the molecule with deletion
of the N-terminal 1-88 amino acids, which exhibited enhanced CaM
binding, was localized exclusively to the membrane skeleton,
cytoskeleton, and soluble membrane fractions (Fig. 9, lanes
21-24). Thus, the low level of detection of this mutant in
Western immunoblots of Triton X-100-soluble lysates (Fig. 4B, lanes 11 and 12) may be due in large part to the
relative absence of this protein from the cytosol and the insolubility
of the majority of the expressed protein. We were unable to detect
differences in the localization of CaM and CaMKII in fractions of these
cells obtained in the presence or absence of 2 mM EGTA (not
shown).
Rad and Kir/Gem are members of a novel class of Ras-related
GTP-binding proteins that contain unique and extended N and C termini
as compared with other Ras-like proteins (1-3). In this study we have
shown that these extended domains are involved in binding of CaM. Thus,
Rad and Gem bind CaM-Sepharose in a
Ca2+-dependent manner, and in cells, Rad
co-immunoprecipitates with CaM in a manner that is disrupted by EGTA
treatment. Therefore, the Rad family of proteins joins the growing list
of CaM-binding proteins, including CaMKII, myosin light chain kinase,
phosphofructokinase, plasma membrane Ca2+-ATPase,
neuromodulin, and, more recently, IQGAP1 and Ras-guanine nucleotide
releasing factor (22-26). Berchtold and Fischer (17) have shown that a
peptide corresponding to the final C-terminal 30 amino acids of Kir/Gem
binds to CaM in vitro, and in the current study we find that
a synthetic peptide based on the final 30 amino acids of Rad (residues
278-308) competes for Rad binding to CaM-Sepharose. Further evidence
that the CaM-binding domain of Rad is indeed located in the C-terminal
extended region involved deletion mutants. Thus, while deletion of
residues 297-308 from full-length Rad did not disrupt CaM binding,
deletion of residues 278-308 abolished CaM binding completely. Based
on these mutants, the specific residues critical for the CaM
interaction lie in the 19-amino acid region encompassing residues
278-297 of human Rad. Modeling of this region as a helical wheel
confirms the distribution of charged and hydrophobic residues typical
of CaM-binding protein. It is likely that the corresponding region of
Gem, which shares 79% homology to Rad and is also rich in charged and
hydrophobic residues, mediates its binding to CaM. We have shown
previously that in C2C12 cells, GDP-bound Rad binds skeletal muscle
-tropomyosin following Ca2+ ionophore treatment (6).
Although the region of Rad that mediates this interaction has not been
determined, addition of a 5-fold molar excess of purified tropomyosin
did not affect the interaction of Rad and CaM, suggesting that the
binding regions reside in different locations in Rad (not shown).
The Rad-CaM interaction appears to be dependent on the guanine
nucleotide-bound state of Rad since GDP-loaded purified Rad and the Rad
dominant negative mutant (S105N) expressed in cells exhibit increased
binding to CaM in comparison to GTPS-loaded Rad and WT Rad in cells.
We speculated that CaM may thus serve to sequester Rad in its inactive
GDP-bound form, serving as a "switching off" mechanism; however, we
failed to show an affect of CaM binding on the guanine nucleotide
binding state of Rad, suggesting that this may not be the case.
Alternatively, in the presence of Ca2+, Rad may serve to
sequester CaM. Additionally, we have previously shown that treatment of
C2C12 cells with Ca2+ ionophore, A23187, results in a rapid
degradation of Rad protein (6). It is possible that
Ca2+-CaM serves a role in the switching off of Rad by
facilitating the degradation of Rad by Ca2+-activated
proteases. CaM does not catalyze the inactivation of Rad by GTP
hydrolysis, since CaM alone does not significantly affect Rad intrinsic
GTPase activity nor Rad-GAP-stimulated GTP hydrolysis.
In addition to binding CaM, Rad exists in complex with CaMKII, the serine/threonine kinase which is a cellular target of CaM. Deletion of the CaM-binding domain of Rad, treatment of immune complexes with EGTA, and competition studies with the CaM-binding domain peptide indicate that Rad interacts with CaMKII independent of its association with Ca2+-CaM and that different domains of Rad are involved in these interactions. In addition, Rad and Gem serve as in vitro substrates for CaMKII. Although the significance of this phosphorylation is not yet known, it is possible that CaMKII modulates the function of Rad or its binding to CaM in a feedback mechanism. Two consensus sites for CaMKII phosphorylation (serines 273 and 299) reside near the region of CaM binding (1) and could potentially modulate the Rad-CaM interaction by introducing a negative charge in the binding region.
It has been noted that several CaM-binding proteins, including CaMKII and myosin light chain kinase, contain a "CaM-like binding site" within the sequence of the molecule (i.e. rich in hydrophobic/anionic residues) which is proposed to act as an internal inhibitor of CaM binding by interacting with the hydrophobic/cationic CaM-binding site within the protein (22). Our mutagenesis studies suggest that Rad may have such a region in that deletion of the N-terminal 88 amino acids of Rad resulted in a molecule that exhibits enhanced binding to CaM-Sepharose. The region of Rad spanning residues 68-88 contains a number of hydrophobic and negatively charged residues, making it a potential auto-inhibitory domain (22). Thus, the unique N- and C-terminal regions of Rad may co-regulate CaM interaction. It is possible, of course, that deletion of the N terminus results in a more generalized alteration in conformation, exposing the CaM-binding site or altering the guanine nucleotide binding characteristics of this protein. In addition, accurate quantitation of the CaM binding efficiency of the N-terminal deletion mutant (Rad N88) is difficult since so little of the protein is detectable in the soluble lysate samples.
Unlike Ras, which is localized to the plasma membrane via prenylation of its C-terminal CAAX-like motif, Rad is localized mainly to the cytoplasm, with portions of the protein associated with cytoskeletal2 and membrane fractions (5). Although Rad lacks a CAAX-like C-terminal motif, deletion of the C-terminal residues 278-308 displaced Rad from the cytoskeleton, membrane skeleton, and soluble membrane fractions to the cytosol, whereas deletion of residues 297-308 did not. Thus, the critical residues for Rad localization to membrane and cytoskeletal components correspond to the CaM-binding domain of Rad, residues 278-297. It is also possible that CaM binding serves to localize Rad. Consistent with this, deletion of the N terminus of Rad, which enhances CaM binding, correlates with displacement of Rad from the cytosol to the cytoskeleton, membrane skeleton, and soluble membranes. Alternatively, in addition to an intact N terminus, Rad localization may require residues near, but distinct from, those C-terminal residues required for CaM interaction.
In summary, we have shown that the Ras-like GTPases, Rad and Gem, possess the unique quality of binding Ca2+-CaM and have localized the site of CaM binding to the C-terminal residues 278-297 of human Rad. The interaction of Rad and CaM is dependent on the guanine nucleotide bound state of Rad, and deletion mutations that affect binding result in redistribution of Rad in the cell. In addition, Rad is found in complex with CaMKII, and Rad and Gem serve as in vitro substrates for this kinase, suggesting that the Rad-like GTPases participate in Ca2+-activated signaling cascades leading to the activation of serine kinases.
We thank Dr. Renee Emkey for valuable discussions on this work. We also thank Dr. Kathleen Kelly of National Institutes of Health for the gifts of the GST-Gem construct and the anti-Gem antibodies.