Originally published In Press as doi:10.1074/jbc.M111466200 on March 1, 2002
J. Biol. Chem., Vol. 277, Issue 19, 17248-17254, May 10, 2002
The Circadian Regulatory Proteins BMAL1 and Cryptochromes Are
Substrates of Casein Kinase I
*
Erik J.
Eide
,
Erica L.
Vielhaber,
William A.
Hinz, and
David M.
Virshup§¶
From the Department of Oncological Sciences,
§ Huntsman Cancer Institute Center for Children, and
¶ Department of Pediatrics, University of Utah School of Medicine,
Salt Lake City, Utah 84112
Received for publication, November 30, 2001, and in revised form, February 21, 2002
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ABSTRACT |
The serine/threonine protein kinase casein kinase
I 
(CKI) is a key regulator of metazoan circadian rhythm. Genetic
and biochemical data suggest that CKI binds to and phosphorylates the PERIOD proteins. However, the PERIOD proteins interact with a variety of circadian regulators, suggesting the possibility that
CKI may interact with and phosphorylate additional clock components
as well. We find that CRY1 and BMAL1 are phosphoproteins in cultured
cells. Mammalian PERIOD proteins act as a scaffold with distinct
domains that simultaneously bind CKI and mCRY1 and mCRY2 (mCRY).
mCRY is phosphorylated by CKI only when both proteins are bound to
mammalian PERIOD proteins. BMAL1 is also a substrate for CKI
in vitro, and CKI kinase activity positively regulates
BMAL1-dependent transcription from circadian promoters in
reporter assays. We conclude that CKI phosphorylates multiple circadian substrates and may exert its effects on circadian rhythm in
part by a direct effect on BMAL1-dependent transcription.
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INTRODUCTION |
Circadian rhythms allow organisms to optimize their metabolic and
physiologic behavior in response to the 24 h day. The rhythm is
generated by cell-autonomous transcription-translation feedback loops
highly conserved in outline if not in detail in most eukaryotes studied
to date (recently reviewed in Refs. 1-4). Extensive genetic investigation coupled with molecular studies has uncovered many of the
essential elements of the metazoan clock. The central feature of the
clock is transcription, regulated by a heterodimeric transcription factor that drives expression of genes whose protein products are
negative regulators of their own transcription. This negative feedback
loop establishes stable molecular oscillations with a period of ~24
h. In mammals, the transcription factors are the PAS
domain-containing proteins CLK1 and BMAL1, whereas the
negative factors include the PERIOD proteins PER1 and PER2 and the
cryptochromes CRY1 and CRY2. The
stability and period of the circadian oscillations are likely to be
dependent on multiple factors, including the rate at which these
regulators accumulate in the cell (i.e. the sum of their
synthesis and degradation rates) and the rate at which they accumulate
in the nucleus. Finally, the activities of circadian regulators are
modified by post-translational modifications.
Analysis of animals and humans with altered circadian rhythms
demonstrates the importance of phosphorylation in the regulation of the
molecular clock. Mutations in the casein kinase I (CKI) homolog
double-time (dbt) in Drosophila
markedly lengthen or shorten the circadian period, depending on the
allele (5-8). In hamsters, a point mutation in CKI that decreases
kinase activity causes the semidominant short period tau
phenotype (9). The functional role of CKI within the circadian clock
has not been fully elucidated (1, 10). A number of studies indicate the
PER proteins are critical targets of CKI. dbt-mutant
flies have altered patterns of PER phosphorylation and accumulation (6,
8, 11). Mutations in a CKI phosphorylation site in human PER2 have
been identified in a family with advanced sleep phase syndrome (FASPS),
a dominantly inherited short circadian period disorder (12).
Overexpression of CKI leads to decreased mPER1 protein half-life and
alters the nucleocytoplasmic localization of the proteins (13-15).
Whether CKI can phosphorylate other circadian regulatory proteins
has not yet been explored.
One central feature of the circadian regulatory machinery is the
multiple interactions between the clock proteins. CKI forms stable
complexes with PER proteins. PER proteins heterodimerize with each
other and interact with CRY1 and CRY2 (16-18). CRY1 and CRY2 also
interact with the heterodimeric transcription factor CLK/BMAL1 both
functionally and in yeast two-hybrid assays (19, 20). Hence, the
potential for higher order complexes exists. Given the changing
abundance of these factors over time, different complexes are likely to
form at different times of day.
In the present study, we examined the ability of CKI to
interact with and phosphorylate other clock proteins in
vitro and in cell culture, both directly and when in multiprotein
complexes. We find that mCRY1 and mCRY2 are substrates of CKI but
only when both CRY and kinase are bound to PER1 or PER2. Furthermore,
mCRY1 can overcome the CKI-dependent cytoplasmic
retention of mPER1 seen in human embryonic kidney 293 (HEK 293) cells
and relocalize the entire multimeric complex to the nucleus. The
ability of CKI to phosphorylate CLK and BMAL1 was examined as well.
BMAL1 but not CLK is a substrate of CKI in vitro. BMAL1
phosphorylation by CKI is neither dependent on nor stimulated by the
presence of PER or CRY proteins. BMAL1 is also a phosphoprotein when
expressed in HEK 293 cells, and co-expression of a dominant-negative
CKI inhibits BMAL1 phosphorylation. Inhibition of CKI activity
using dominant-negative CKI or dsRNA-mediated interference also led to decreased CLK/BMAL1-dependent transcription. The data
suggest CKI has multiple functional substrates in the circadian
rhythm regulatory apparatus.
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MATERIALS AND METHODS |
Cell Line Maintenance and Transfection--
HEK 293 cells were
maintained in Dulbecco's modified Eagle's medium with 10% fetal calf
serum in a humidified incubator at 37 °C and 5% CO2.
Cells were transfected using LipofectAMINE PLUS (Invitrogen) with
between 0.3 and 0.7 µg of expression constructs, as indicated in the
figures, with the total amount of transfected DNA brought up to 1 µg
with the addition of empty vector.
Immunoprecipitations and Immunofluorescence--
HEK 293 cells
were transfected with the indicated expression constructs and harvested
18 h later in HTS buffer (10 mM HEPES, pH 7.5, 0.1%
Triton X-100, 100 mM NaCl, 2 mM EDTA, 2 mM EGTA, and 2 mM DTT, supplemented with
CompleteTM (Roche Molecular Biochemicals) protease
inhibitors). Myc epitope-tagged proteins were immunoprecipitated with 1 µg of 9E10 anti-Myc monoclonal antibodies and protein A-agarose
beads. The beads were then washed three times in HTS buffer, and
proteins were eluted with SDS-PAGE loading buffer. After SDS-PAGE, the
proteins were transferred to a nitrocellulose membrane (Hybond-C extra,
Amersham Biosciences) and further analyzed by immunoblotting using the
indicated antibodies. For immunofluorescence, HEK 293 cells were
transiently transfected as indicated in Fig. 3. 18 h after
transfection, the cells were fixed in 4% paraformaldehyde and
permeabilized with 0.1% Triton X-100. Anti-Myc (9E10) and
anti-influenza hemagglutinin epitope (12CA5) monoclonal antibodies were
directly conjugated to Alexa 488 (green) or Alexa 594 (red) according to the manufacturer's directions (Molecular
Probes). The antibodies and 4,6-diamidino-2-phenylindole nuclear stain
were incubated with the cells for 1 h at room temperature. The
epitope-tagged proteins were then visualized using an Olympus BX50
fluorescence microscope equipped with a cooled charge-coupled device
camera (Photometrics Ltd.) at 60× magnification. Images were acquired
using the mFISH (Vysis, Inc) software package and further analyzed with
PhotoShop 5.0 (Adobe).
Kinase Assays--
HEK 293 cells were transiently transfected
with expression constructs as indicated in the figures. Eighteen hours
after transfection, Myc epitope-tagged proteins were immunoprecipitated
from 300 µg of soluble cell free extract with 1 µg of 9E10 anti-Myc
monoclonal antibodies as was done above. Beads were kept on ice and
washed several times with HMB buffer (30 mM HEPES, pH 8, 7 mM MgCl2, 100 µg/ml bovine serum albumin, and
25 µM ATP). After washing, the beads were split three
ways. To one bead fraction, HMB, [
-32P]ATP, and 50 ng
of recombinant CKI
C320 was added to a final volume of 20 µl.
This truncated form of CKI was used to avoid the auto-inhibition
seen with full-length CKI in vitro (21). Another bead
fraction was treated identically except for the omission of recombinant
kinase as a negative control. The beads were then incubated at 37°
for 15 min. The reactions were stopped by washing the beads three times
with HM buffer (30 mM HEPES, pH 8, 7 mM MgCl2). Proteins were eluted from the beads with Laemmli
sample buffer and separated by SDS-PAGE, and dried gels were analyzed by PhosphorImager (Amersham Biosciences). To confirm the
presence of proteins in the immunoprecipitate, the third bead fraction was also run out on SDS-PAGE and analyzed by immunoblotting as above.
For in vitro kinase assays (Fig. 5A), V5
epitope-tagged CLK and BMAL1 were synthesized in rabbit reticulocyte
lysate using the TNT Coupled Reticulocyte System (Promega). The
proteins were immunoprecipitated from 90 µl of each synthesis
reaction with 3 µg of anti-V5 antibodies. Bead washes, in
vitro kinase assays, and Western blotting were performed as
described above.
Metabolic Labeling of Cells--
HEK 293 cells were transiently
transfected as indicated in Fig. 4, A and B.
Eighteen hours after transfection, cells were labeled for 3 h with
[32P]orthophosphoric acid (2 mCi/ml) in phosphate-free
Dulbecco's modified Eagle's medium. After labeling, cells were washed
and then lysed in radioimmune precipitation buffer (1% Nonidet P-40, 0.5% deoxycholic acid, 0.1% sodium dodecyl sulfate, 150 mM NaCl, 150 mM Tris, pH 8.0) supplemented with
2 mM dithiothreitol, 10 mM sodium fluoride, 10 mM 
-glycerol phosphate, 200 nM okadaic acid,
and CompleteTM (Roche Molecular Biochemicals) protease
inhibitors). Myc epitope-tagged CRY or BMAL1 was immunoprecipitated
from 1 mg of soluble lysate with 8 µg of 9E10 anti-Myc antibodies and
protein A-agarose beads. After washing, bound proteins were eluted with
Laemmli sample buffer and examined by SDS-PAGE and phosphorimaging analysis.
Transcription Assays and RNA Interference--
HEK 293 cells
seeded in a single well of a six-well dish were transiently transfected
with between 25 and 250 ng of luciferase reporter plasmid using
LipofectAMINE Plus (Invitrogen) according to the manufacturer's
directions. Where indicated, 250 ng each of CLK and BMAL1 and 100 ng of
CKI or CKI(K38A) expression constructs were also co-transfected.
In all cases 25 ng of a plasmid encoding -galactosidase was added,
and the total amount of DNA transfected was brought up to 1 µg with
the addition of empty vector. After 24 h, cell-free extracts were
made by the addition of lysis buffer (100 mM potassium
phosphate, pH 7.8, 0.2% Triton X-100, and 0.5 mM DTT).
Luciferase activity was detected using the Tropix Dual-Light assay
system (PE Biosystems) and measured using a microtiter plate luminometer and the Revelation MLX software package (Dynex
Technologies). -Galactosidase activity was measured as a
transfection efficiency control and was used to normalize the
luciferase data.
Endogenous CKI and CKI
mRNA was targeted in HEK 293 cells by
the addition of a 21-nucleotide duplex small interfering RNA (siRNA).
This duplex RNA targets nucleotides 520-538 of the CKI-coding sequence and was constructed using the ribooligonucleotide (r) pair
with the sequences 5'-rCUGGGGAAGAAGGGCAACCdTT-3' and
5'-rGGUUGCCCUUCUUCCCCAGdTT-3'. The identical nucleotide sequence is
present in CKI as well. As a control for the specificity of this
duplex, a ribooligonucleotide pair with the inverse sequence was
used with the sequences 5'-rCCAACGGGAAGAAGGGGUCdTT-3' and
5'-rGACCCCUUCUUCCCGUUGGdTT. The oligonucleotides were annealed essentially as described in Elbashir et al. (22). 4.5 µg
of each duplex was then introduced into 6-well tissue culture plate using Oligofectamine according to the manufacturer's directions (Invitrogen). After 48 h, the transfection mixture was removed, and the cells were transfected with mPer1-luc reporter, CLK,
and BMAL1 expression constructs as described above. Twenty-four hours after transfection, luciferase activity was detected and normalized to
-galactosidase activity. CKI and CKI abundance was assessed by
immunoblot using UT31, a rabbit polyclonal antibody that recognizes a
shared amino-terminal epitope on CKI and CKI (23).
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RESULTS |
mCRY Binds a Conserved Domain in the Carboxyl Terminus of
PER--
Genetic, biochemical, and immunofluorescence data suggest
there is a physical interaction between mCRY and mPER (17, 18, 20). To
map the region of mPER1 and mPER2 that bind mCRY1 and mCRY2, amino- and
carboxyl-terminal truncations of mPER1 and mPER2 were co-expressed with
full-length mCRY1 or mCRY2, and the mPER protein was
immunoprecipitated. As expected, mPER1 efficiently immunoprecipitated
full-length mCRY1 (Fig. 1A,
lane 1'). mCRY1 also binds mPER11219, a truncation of
mPER1 lacking the carboxyl-terminal 72 residues (Fig. 1A,
lane 5'). However, when mPER1 was further truncated by an
additional 100 residues (mPER11118), all detectable mCRY binding was
lost (Fig. 1A, lane 6'). These results indicate that mCRY1 binds to mPER1 in its carboxyl-terminal region bound by
amino acids 1117 and 1219, outside the CKI binding domain. Supporting this, a fragment of mPER1 encompassing amino acids 1027 and
1291, mPER1(1027-1291), also binds mCRY1 (Fig. 1A,
lane 4'). The efficiency of the mCRY1 interaction with
mPER1(1027-1291) and mPER11219 is less than that seen with
full-length mPER1, suggesting that additional contacts between CRY and
PER proteins may occur in the full-length protein (Fig. 1A,
lanes 4' and 5'). As reported by others, mCRY
does not require the PAS domains of mPER for stable interaction (Fig.
1A, lane 2') (20). The mCRY1 binding domain of
mPER2 similarly maps to between residues 1127 and 1225 (Fig.
1B). mCRY2 interacts with mPER1 and mPER2 in the same domain
as does mCRY1 (data not shown). This CRY binding region of mPER1 and
mPER2 is conserved among vertebrate PER proteins but is absent in
insect PER and other proteins in GenBankTM (data not
shown).
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Fig. 1.
mCRY interacts with a conserved domain in the
carboxyl terminus of mPER1 and mPER2. A, HEK 293 cells
were transiently transfected with plasmids expressing full-length V5
epitope-tagged mCRY1 and the indicated truncations of Myc
epitope-tagged mPER1 or mPER2. mPER was immunoprecipitated
(IP) with anti-Myc antibodies and the presence of mCRY in
the immunoprecipitate was assessed by immunoblotting with anti-V5
antibodies. B, schematic representation of mCRY·mPER
binding results, with selected domains on mPER indicated.
Boxes labeled A and B indicate PAS
domains, whereas CKI indicates the CKI/ binding site,
and N indicates one of the nuclear localization signals.
FL, full length.
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mPER Is a Scaffold That Brings mCRY1 and CKI into a Multimeric
Complex--
mPER1 and mPER2 bind to both endogenous and overexpressed
CKI using a conserved domain in the approximate center of PER
(e.g. mPER1 amino acids 496-815) (12, 13). We therefore
tested whether CKI and CRY could simultaneously bind to PER, forming
a ternary complex in intact cells. Full-length mCRY1 was expressed with mPER1 or mPER2 as indicated in Fig. 2.
mCRY was immunoprecipitated, and the presence of mPER in the pellet was
probed by Western blotting. mCRY1 efficiently interacted with both
full-length mPER1 and mPER2 (Fig. 2, lanes 2' and
4') but not mPER11118 or mPER2905 (Fig. 2, lanes
3' and 5'), confirming that the carboxyl terminus of mPER is required for interaction. Immunoprecipitation of mCRY1 alone in
the absence of mPER1 did not pull down endogenous CKI (Fig. 2,
lane 1'). However, when either mPER1 or mPER2 was
co-expressed, mCRY1 consistently co-immunoprecipitated both mPER and
CKI (Fig. 2, lanes 2' and 4' and data not
shown). Consistent with this result, when mPER11118 (deficient in
mCRY binding) was co-expressed with mCRY1, neither truncated
mPER11118 nor CKI co-immunoprecipitated with mCRY1 (Fig. 2,
lane 3'). CKI also failed to immunoprecipitate with mCRY1
when mPER2905 was expressed (Fig. 2, lane 5'). Taken together, these results indicate that CKI and mCRY1 are able to
interact with each other only indirectly and that they require the
presence of mPER to bring them into a trimeric complex. Thus, the mPER
protein acts as a scaffold that allows formation of a mCRY1·CKI·mPER multimeric complex.
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Fig. 2.
CKI interaction with
mCRY1 requires intact PER protein. Endogenous CKI
co-immunoprecipitates (IP) with mCRY1 only in the presence
of full-length mPER proteins. Myc epitope-tagged mCRY1 and FLAG
epitope-tagged mPER were transiently expressed in HEK 293 cells as
indicated. mCRY was immunoprecipitated with anti-Myc antibodies, and
the presence of co-precipitating mPER was assessed by SDS-PAGE and
immunoblotting with anti FLAG antibodies. The blot was sequentially
stripped and reprobed with an anti-CKI polyclonal antibody to detect
the presence of co-immunoprecipitating endogenous CKI and with an
anti-Myc antibody to confirm the presence of mCRY1 in the
immunoprecipitate pellet. An equal amount of input cell lysates is
shown on the left (lanes 1-5), whereas the
proteins present in the immunoprecipitate are shown on the right
(lanes 1'-5').
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mCRY1 Brings the Cytoplasmic mPER1·CKI Complex into the
Nucleus--
PER subcellular localization is a dynamic process
regulated by at least two nuclear localization signals, a nuclear
export signal, protein-protein interactions, and protein
phosphorylation (11, 15, 24). CKI kinase activity can influence
mPER1 subcellular localization by either sequestering it in the
cytoplasm in HEK 293 cells (13) or driving it to the nuclear
compartment in COS7 cells (15). mCRY1 protein is predominately
localized to the nuclear compartment in transfected cells, where it
inhibits CLK/BMAL1-dependent transcription (18). mCRY1 also
binds and promotes nuclear translocation of mPER1 and mPER2 proteins
(18). These observations, when taken together with the fact that mCRY1,
mPER1, and CKI form a multiprotein complex suggest at least two
possibilities with respect to subcellular localization. One, mCRY1 may
translocate the CKI·mPER1 complex to the nucleus, overcoming the
CKI-dependent mPER1 cytoplasmic localization seen in HEK
293 cells. Conversely, CKI may promote mCRY1 cytoplasmic
localization that is dependent on its interaction with mPER1.
To distinguish between these two possibilities, epitope-tagged CKI
and mCRY1 were transiently expressed in HEK 293 cells with empty vector
and either full-length or truncated mPER1 (Fig. 3), and their intracellular localization
was examined by direct immunofluorescence microscopy. In the absence of
mPER1, mCRY1 was nuclear in 97% of cells examined, whereas in the same
cells, CKI was predominantly cytoplasmic (only nuclear in 3% of
cells) (Fig. 3, panels a, d, and g).
However, when mPER1 was co-expressed with CKI and mCRY1, CKI
localization changed from predominantly cytoplasmic to nuclear (Fig. 3,
panels b, e, and h). Thus, mPER1 allows mCRY1 to bring CKI to the nucleus despite the CKI kinase activity that otherwise promotes mPER1 cytoplasmic localization in HEK
293 cells (13). Consistent with this model, when the mCRY1
binding-deficient form of mPER1 (mPER11118) was co-expressed, CKI
remained predominantly in the cytoplasm (Fig. 3, panels c, f, and i).
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Fig. 3.
mCRY1 promotes nuclear localization of the
mPER1/CKI complex. CKI is localized to
the nucleus through interaction with the PER·CRY complex. Myc-tagged
mCRY1 and hemagglutinin epitope-tagged CKI were transiently
expressed in HEK 293 cells in the presence of vector (a,
d, and g), full-length mPER1 (b,
e, and h), or truncated mPER1 (1118, lacking
the CRY interaction domain) (c, f, and
i) as indicated. Protein localization was visualized by
staining the cells with anti-Myc antibodies conjugated to Alexa 488 (green) and anti-hemagglutinin antibodies conjugated to
Alexa 594 (red). The percent of transfected cells exhibiting
nuclear localization of the indicated protein is shown in each
panel.
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These results, when taken together with the immunoprecipitation data
(Fig. 2), suggest that mPER1 must interact with both CKI and mCRY1
in order for mCRY1 to bring CKI into the nucleus. We note that there
was some accumulation of CKI in the nucleus when mPER11118 was
expressed (compare Fig. 3, panels d-f), again suggesting
there is some additional interaction between mPER11118 and mCRY1
(Fig. 2).
mCRY1 Requires mPER1 or mPER2 to Be Phosphorylated by CKI in
Vitro--
The ability of CKI to phosphorylate PER1 requires that
the kinase first bind to the substrate, presumably ensuring a high local concentration and/or appropriate positioning of the kinase (Ref.
13 and data not shown). Because mCRY1 can be found in a multimeric
complex with PER and CKI, mCRY1 present in this complex might
similarly be phosphorylated by CKI. We first assessed whether mCRY1
was in fact a phosphoprotein in intact cells. Epitope-tagged mCRY1 was
transiently expressed in 32P-metabolically labeled HEK 293 cells, immunoprecipitated, and analyzed by autoradiography (Fig.
4A). mCRY1 incorporated
significant amounts of 32P during a 3-h labeling,
indicating it is in fact phosphorylated in cultured cells.
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Fig. 4.
mPER-dependent mCRY1
phosphorylation. A, mCRY1 is a phosphoprotein in intact
cells. HEK 293 cells were transiently transfected with either empty
vector ( ) or with a plasmid encoding Myc-tagged mCRY1 (+). 18 h
after transfection, cells were metabolically labeled with
[32P]orthophosphoric acid for 3 h, at which time
cell free lysates were prepared and subjected to immunoprecipitation
with anti-Myc antibody. 32P incorporation into mCRY1 was
assessed by SDS-PAGE and phosphorimaging analysis. B, mCRY1
is phosphorylated by CKI in a CKI·PER·mCRY1 complex in
vitro. HEK 293 cells were transiently transfected with mCRY1 and
PER expression plasmids as indicated. mCRY1 protein was then
immunoprecipitated (IP) with anti-Myc antibodies, and the
immunoprecipitates were split three ways. Two of the three fractions
were subjected to an in vitro kinase assay in the presence
of [-32P]ATP and without () or with (+) added
recombinant CKI(C320). mCRY1 phosphorylation was then visualized
by SDS-PAGE and phosphorimaging. C, the third bead fraction
was subjected to immunoblotting after SDS-PAGE to confirm the presence
of CRY and PER proteins in the immunoprecipitates as indicated in the
figure.
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To test whether CKI could phosphorylate mCRY1, mCRY1 alone and
mCRY1·mPER complexes were assembled by co-expression in HEK 293 cells, and the proteins were recovered by immunoprecipitation of mCRY1
(Fig. 4C). When mCRY1, expressed alone, was
immunoprecipitated and incubated with recombinant CKI, there was
minimal phosphorylation of mCRY1 (Fig. 4B, lane
2). However, when full-length mPER1 or mPER2 was co-expressed with
mCRY1, mCRY1 was efficiently phosphorylated by CKI (Fig.
4B, lanes 4 and 8). Phosphorylation of
mCRY1 seen without added CKI may be due to endogenous CKI and/or
CKI co-precipitating with PER1 and PER2 (Fig. 4B,
lanes 3 and 7). The interaction of CRY with mPER
was required for CRY phosphorylation by CKI, since mCRY1
phosphorylation fell back to background levels when truncated mPER
proteins that do not interact with mCRY1 were co-expressed with mCRY1
(Fig. 4B, lanes 6 and 10). mCRY2 was similarly
phosphorylated by CKI only in the presence of PER containing both
CKI and CRY binding sites (data not shown). These results suggest
that PER acts as a scaffold that brings mCRY and CKI into close
proximity with each other. This effectively raises the local
concentration of CKI around mCRY, allowing for efficient
phosphorylation of mCRY by CKI.
To test the potential biological function of mCRY phosphorylation by
CKI, we tested the effect of CKI co-expression on the ability of
CRY1 and CRY2 to repress transcription from the mPer1 promoter (18). No consistent effect of active or dominant-negative CKI on CRY activity was found (data not shown). Similarly, no effect
of dominant-negative CKI (K38A) on the level of CRY1 phosphorylation in transfected cells was detectable. Thus, although CKI can clearly phosphorylate mCRY in a multimeric complex in vitro, the
physiological significance of this phosphorylation remains to be determined.
BMAL1 Phosphorylation Is Regulated by CKI--
CKI is found
both in the nucleus and cytoplasm depending on cell and tissue type
(13, 15, 25). Depending on its subcellular localization CKI may
phosphorylate distinct sets of substrates. Because CKI forms
intermolecular complexes with and phosphorylates clock proteins such as
mPER1, mPER2, and mCRY1, we next asked if CKI could phosphorylate
other circadian regulators. CKI was able to phosphorylate BMAL1
immunoprecipitated from programmed reticulocyte lysates and from
transfected cells (Fig. 5, A
and B). Immunoprecipitated CLK was not phosphorylated by
CKI (Fig. 5A). We did not observe a reproducible, robust
interaction between CKI and BMAL1 by co-immunoprecipitation assays.
Unlike the stimulation of mCRY phosphorylation seen in the presence of
mPER, BMAL1 phosphorylation by CKI was not appreciably altered by
the formation of a BMAL1·mPER2 complex (Fig. 5B and data
not shown).
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Fig. 5.
BMAL1 phosphorylation is regulated by
CKI in vitro and in intact
cells. A, BMAL1 but not CLK is a substrate of CKI. V5
epitope-tagged CLK (lanes 1, 3, and 4)
and BMAL1 (lanes 2, 5, and 6) were
expressed in rabbit reticulocyte lysates and immunoprecipitated, and
the beads were split three ways. One fraction was probed with anti-V5
antibodies to verify the presence of protein in the pellet (lanes
1 and 2), and the remaining fractions were subjected to
an in vitro kinase reaction in the absence (lanes
3 and 5) or presence (lanes 4 and
6) of added recombinant CKI(C320) as indicated.
B, BMAL1 was phosphorylated by CKI in vitro
independent of mPER2. HEK 293 cells were transiently transfected with
plasmids encoding Myc-tagged BMAL1 along with FLAG-tagged mPER2 or
empty vector. The Myc-tagged BMAL1 was immunoprecipitated and incubated
with [-32P]ATP and without () or with (+)
recombinant CKI(C320). Co-immunoprecipitation of mPER2 with BMAL1
was confirmed by immunoblotting a fraction of the immunoprecipitates
with anti-FLAG antibodies (lanes 5 and 6). The
presence of co-immunoprecipitating mPER2 did not stimulate
phosphorylation of BMAL1. C, BMAL phosphorylation in intact
cells is reduced by co-expression of dominant-negative CKI. HEK 293 cells were transiently transfected with plasmids encoding Myc
epitope-tagged BMAL1 and either vector () or a kinase-inactive form
of CKI(K38A) (+). At 18 h post-transfection, cells were labeled
with [32P]orthophosphoric acid for 3 h, and then the
BMAL1 protein was immunoprecipitated (IP) from lysates with
anti-Myc monoclonal antibodies. 32P incorporation into
BMAL1 was assessed by SDS-PAGE and phosphorimaging analysis. BMAL1
protein expression was determined by immunoblot of cell free lysate.
The data shown is a representative result of three separate
experiments. D, Quantitation of BMAL1 phosphorylation
without (-) or with (+) co-expression of CKI(K38A). The results
shown are the average of three independent experiments.
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BMAL1 was found by metabolic labeling to be a phosphoprotein in cells
(Fig. 5C). Because CKI was able to directly phosphorylate BMAL1 in vitro, the effect of overexpression of a
dominant-negative form of CKI on BMAL1 phosphorylation in intact
cells was also examined. CKI(K38A) co-expression reduced BMAL1
phosphorylation by about 40% (Fig. 5, C and D).
The decrease in BMAL1 phosphorylation was not due to a decrease in
BMAL1 protein levels, which were unchanged regardless of the presence
or absence of CKI(K38A) (Fig. 5C, lower
panel). The partial reduction in BMAL1 phosphorylation could be
due to complete inhibition of phosphorylation of a subset of sites or a
partial reduction in CKI activity. Phosphopeptide mapping of BMAL1
expressed without and with CKI(K38A) demonstrated that there was a
global decrease in BMAL1 phosphorylation (data not shown), consistent
with CKI(K38A) partially blocking the endogenous kinases
phosphorylating BMAL1.
CKI Regulates BMAL1-dependent
Transcription--
Phosphorylation regulates the activity of
multiple transcription factors (26, 27). Because BMAL1 is
phosphorylated by CKI in vitro, and expression of a
dominant-negative form of CKI decreases BMAL1 phosphorylation in
intact cells, we examined whether CKI regulated the activity of a
CLK/BMAL1-dependent promoter. Transcriptional activity was
assessed by the CLK/BMAL1-dependent expression of
luciferase from the mPer1 promoter (Fig.
6A). Co-expression of active
CKI had no effect on luciferase expression, whereas expression of
dominant-negative CKI, CKI(K38A), caused a 40% decrease in
luciferase activity. This change in luciferase expression is similar in
magnitude to the decrease in BMAL1 phosphorylation seen with
CKI(K38A) co-expression. CKI may regulate the expression of
multiple genes, as it has been implicated in processes as diverse as
Wnt/-catenin signaling and NFAT (nuclear factor of activated T
cells) nuclear localization (28, 29). However, CKI(K38A) is not a
global transcriptional repressor, as it had no effect on luciferase
expression from actin and cdc2 promoters (Fig. 6, B and C).
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|
Fig. 6.
CKI regulates BMAL1
driven transcription. A, overexpression of
dominant-negative CKI leads to decreased BMAL1-driven transcription.
HEK 293 cells were transiently transfected with a
CLK·BMAL1-responsive promoter (mPer1:luc) and CLK, BMAL1,
and CKI expression constructs or empty vector as indicated. After
18 h, cell free extracts were prepared, and the luciferase
activity was analyzed. B and C, CKI(K38A) has
minimal effect on other promoters. HEK 293 cells were transiently
transfected with plasmids encoding either CKI or dominant-negative
CKI(K38A) and a reporter with the actin promoter
(B) or the cdc2 promoter (C) driving
luciferase expression. 18 h after transfection, luciferase
activity was analyzed as in A. D, dsRNA-mediated
interference leads to depletion of CKI/ and inhibition of
CLK/BMAL1-driven gene expression. Endogenous CKI/ was partially
eliminated in HEK 293 cells by transfection of a 21-nucleotide RNA
duplex (siRNA) directed against the CKI/ sequence. As
a control, the sequence was introduced in the inverted orientation
(Inv). After 48 h, the transfection mixture was
removed, and plasmids encoding both CLK and BMAL1 (where indicated)
along with a reporter containing luciferase behind the mPer1
promoter (18) were introduced. After an additional 24 h, whole
cell lysates were prepared, and luciferase activity analyzed as
described in A. The lower panel shows a
representative immunoblot of CKI. The relative amount of endogenous
CKI was analyzed using NIH Image software and the quantitation shown
beneath.
|
|
To further assess the role of CKI in regulation of circadian E
box-containing promoters, we attempted to eliminate CKI and CKI
expression using siRNA (22). A 21-base pair RNA duplex (CKI
nucleotides 520-538, a sequence conserved in CKI) was transiently transfected into HEK 293 cells. A dsRNA with the same sequence but in
reverse order (denoted Inv) was similarly transfected in control experiments. The effect of siRNA on protein expression was
assessed by immunoblot of cell extracts (Fig. 6D). Under
these conditions, the dsRNA targeting CKI and CKI reduced their
abundance by almost 50%. As Fig. 6D illustrates, treatment
of cells with the CKI/ dsRNA led to a 40% decrease in luciferase
expression driven by the mPer1 promoter compared with
mock-treated and control-treated cells. Hence, both dominant-negative
CKI and siRNA-mediated inhibition of CKI activity led to similar
decreases in BMAL1-dependent transcriptional activity.
| |
DISCUSSION |
CKI is firmly established as a critical component of the
circadian clock. Studies in flies and mammals suggest that the
stability and localization of the PERIOD proteins are regulated by
CKI-dependent phosphorylation. In this study, we present
evidence that CKI acts on additional circadian substrates, including
a PER-dependent phosphorylation of CRY and direct
phosphorylation of BMAL1. Inhibition of CKI activity by either
expression of dominant-negative CKI or use of small interfering RNAs
reduced expression from the mPer1 but not the
cdc2 nor actin promoters. Although the data
cannot exclude the possibility that additional CKI substrates may
influence transcription from the mPer1 promoter, they are
consistent with a model in which direct phosphorylation of BMAL1 by
CKI positively regulates the activity of BMAL1 in transcription.
The PER protein acts as a scaffold, bringing CKI and CRY proteins
into close proximity. Both CRY proteins interact with the carboxyl
termini of mPER1 and mPER2 in a region of high sequence homology
between the two proteins and distant from the previously defined PAS
domain and CKI binding site. Identification of a similar CRY binding
site on PER has been reported recently by others (30). Notably, the CRY
binding domain has no homologous region in insect PER, consistent with
a distinct role for cryptochromes as light-sensing proteins in
non-vertebrates. The presence of distinct CRY and CKI binding sites
on PER allows formation of a ternary complex between CKI, CRY, and
PER proteins. Formation of this complex appears to have at least two
consequences. First, CRY can overcome the CKI-mediated PER1
cytoplasmic localization. This is consistent with immunolocalization
studies showing nuclear CKI in neurons within the suprachiasmatic
nucleus (25, 31) and positions CKI to phosphorylate nuclear
circadian regulators. This conclusion is supported by the recent report
of Lee et al. (32), who found CKI and CKI in a complex
with both PER and CRY in rat and hamster liver and additionally found
circadian regulation of CKI nuclear localization. Second, CRY present
in this complex can be efficiently phosphorylated by CKI in
vitro. The functional consequence of CKI-dependent
CRY phosphorylation is the subject of ongoing investigation, but it
does not appear to modify the inhibitory effect of CRY upon circadian
promoters (data not shown).
We also examined whether or not BMAL1 was a substrate for CKI. Given
that CRY requires the formation of a CRY·PER·CKI multimeric complex for its phosphorylation by CKI, it was unexpected that CKI can in fact directly phosphorylate BMAL1. This phosphorylation appears to be physiologically relevant, since overexpression of dominant-negative CKI led to both a decrease in BMAL1
phosphorylation and a decrease in BMAL1-dependent
transcription from E-box-containing promoters. Similarly, a
dsRNA-mediated decrease in CKI protein in intact cells led to a
decrease in BMAL1 transcriptional activation function. That the CKI
with the R178C mutation found in the tau hamster is likely
to exhibit a dominant-negative phenotype (i.e. bind to
substrates and block access of active kinases) (1, 9) suggests that
decreased phosphorylation of BMAL1 may contribute to the tau
short period phenotype. An alternative hypothesis not excluded here is
that in the cell CKI may regulate a pathway that then regulates
BMAL1 phosphorylation and activity. Although in these studies we used
CKI, the closely related CKI that can similarly bind to and
phosphorylate PER proteins is likely to similarly phosphorylate BMAL1
(13, 25). Recent work from two groups suggests both BMAL1 and CLK are
phosphorylated in intact animals. Both proteins have
phosphorylation-dependent electrophoretic mobility shifts
that change through the circadian day (32). Finally, we note that
Sanada and co-workers (33) recently show that mitogen-activated protein
kinase phosphorylates BMAL1 on several sites and modestly inhibits the
activity of BMAL1 in transcription assays. Mitogen-activated protein
kinase and CKI are likely to phosphorylate distinct sites on BMAL1.
BMAL1 may therefore be the target of several distinct signaling
pathways, with divergent effects on its activity.
Immunolocalization studies of CKI have produced conflicted results,
dependent on cell type and co-expression of additional circadian
proteins. The finding of a multimeric CKI·PER·CRY complex that
can relocalize CKI from cytoplasm to nucleus implies that some of
the variability in CKI localization seen in cultured cells is due to
co-expression of circadian regulators. For example, PER and CRY levels
may be higher in COS7 than in HEK 293 cells and, hence, target CKI
to the nucleus more readily in those cells. These results also suggest
that one function of the PER·CRY complex in vivo may be to
relocalize CKI to the nucleus during periods of CRY abundance,
facilitating phosphorylation of BMAL1 and perhaps additional nuclear
circadian regulators. What remains to be resolved is how the
stimulatory effect of CKI phosphorylation and the inhibitory effect
of CRY on BMAL1 activity are coordinated to produce stable oscillations
in expression from circadian promoters.
| |
ACKNOWLEDGEMENTS |
We thank R. Schackmann for oligonucleotide
synthesis, M. Morgan for assistance with immunofluorescence microscopy,
and S. Reppert and A. Schönthal for plasmids.
| |
FOOTNOTES |
*
These studies were funded in part by National Institutes of
Health Grants R01CA71074 and P30CA42014 and by the Huntsman Cancer Foundation.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.
To whom correspondence should be addressed: Huntsman Cancer
Institute, 2000 Circle of Hope, Salt Lake City, UT 84112-5550. Tel.:
801-585-3408; Fax: 801-587-9415; E-mail:
david.virshup@hci.utah.edu.
Published, JBC Papers in Press, March 1, 2002, DOI 10.1074/jbc.M111466200
| |
ABBREVIATIONS |
The abbreviations used are:
CLK, CLOCK;
mCRY1
and mCRY2, murine cryptochrome 1 and 2, respectively;
mCRY, both mCRY1
and mCRY2;
CKI, casein kinase I epsilon;
PER, mammalian PERIOD
proteins;
HEK 293 cells, human embryonic kidney 293;
DTT, dithiothreitol;
siRNA, small interfering RNA;
dsDNA, double-stranded
DNA.
| |
REFERENCES |
| 1.
|
Eide, E. J.,
and Virshup, D. M.
(2001)
Chronobiol. Int.
18,
389-398[CrossRef][Medline]
[Order article via Infotrieve]
|
| 2.
|
Reppert, S. M.,
and Weaver, D. R.
(2001)
Annu. Rev. Physiol.
63,
647-676[CrossRef][Medline]
[Order article via Infotrieve]
|
| 3.
|
Lowrey, P. L.,
and Takahashi, J. S.
(2000)
Annu. Rev. Genet.
34,
533-562[CrossRef][Medline]
[Order article via Infotrieve]
|
| 4.
|
Allada, R.,
Emery, P.,
Takahashi, J. S.,
and Rosbash, M.
(2001)
Annu. Rev. Neurosci.
24,
1091-1119[CrossRef][Medline]
[Order article via Infotrieve]
|
| 5.
|
Kloss, B.,
Price, J. L.,
Saez, L.,
Blau, J.,
Rothenfluh, A.,
Wesley, C. S.,
and Young, M. W.
(1998)
Cell
94,
97-107[CrossRef][Medline]
[Order article via Infotrieve]
|
| 6.
|
Price, J. L.,
Blau, J.,
Rothenfluh, A.,
Abodeely, M.,
Kloss, B.,
and Young, M. W.
(1998)
Cell
94,
83-95[CrossRef][Medline]
[Order article via Infotrieve]
|
| 7.
|
Rothenfluh, A.,
Abodeely, M.,
and Young, M. W.
(2000)
Curr. Biol.
10,
1399-1402[CrossRef][Medline]
[Order article via Infotrieve]
|
| 8.
|
Suri, V.,
Hall, J. C.,
and Rosbash, M.
(2000)
J. Neurosci.
20,
7547-7555[Abstract/Free Full Text]
|
| 9.
|
Lowrey, P. L.,
Shimomura, K.,
Antoch, M. P.,
Yamazaki, S.,
Zemenides, P. D.,
Ralph, M. R.,
Menaker, M.,
and Takahashi, J. S.
(2000)
Science
288,
483-492[Abstract/Free Full Text]
|
| 10.
|
Vielhaber, E. L.,
and Virshup, D. M.
(2001)
Int. Union Biochem. Mol. Biol. Life
51,
273-278
|
| 11.
|
Kloss, B.,
Rothenfluh, A.,
Young, M. W.,
and Saez, L.
(2001)
Neuron
30,
699-706[CrossRef][Medline]
[Order article via Infotrieve]
|
| 12.
|
Toh, K. L.,
Jones, C. R., He, Y.,
Eide, E. J.,
Hinz, W. A.,
Virshup, D. M.,
Ptacek, L. J.,
and Fu, Y. H.
(2001)
Science
291,
1040-1043[Abstract/Free Full Text]
|
| 13.
|
Vielhaber, E.,
Eide, E.,
Rivers, A.,
Gao, Z.-H.,
and Virshup, D. M.
(2000)
Mol. Cell. Biol.
20,
4888-4899[Abstract/Free Full Text]
|
| 14.
|
Keesler, G. A.,
Camacho, F.,
Guo, Y.,
Virshup, D.,
Mondadori, C.,
and Yao, Z.
(2000)
Neuroreport
11,
951-955[Medline]
[Order article via Infotrieve]
|
| 15.
|
Takano, A.,
Shimizu, K.,
Kani, S.,
Buijs, R. M.,
Okada, M.,
and Nagai, K.
(2000)
FEBS Lett.
477,
106-112[CrossRef][Medline]
[Order article via Infotrieve]
|
| 16.
|
Yagita, K.,
Yamaguchi, S.,
Tamanini, F.,
van Der Horst, G. T.,
Hoeijmakers, J. H.,
Yasui, A.,
Loros, J. J.,
Dunlap, J. C.,
and Okamura, H.
(2000)
Genes Dev.
14,
1353-1363[Abstract/Free Full Text]
|
| 17.
|
Field, M. D.,
Maywood, E. S.,
O'Brien, J. A.,
Weaver, D. R.,
Reppert, S. M.,
and Hastings, M. H.
(2000)
Neuron
25,
437-447[CrossRef][Medline]
[Order article via Infotrieve]
|
| 18.
|
Kume, K.,
Zylka, M. J.,
Sriram, S.,
Shearman, L. P.,
Weaver, D. R.,
Jin, X.,
Maywood, E. S.,
Hastings, M. H.,
and Reppert, S. M.
(1999)
Cell
98,
193-205[CrossRef][Medline]
[Order article via Infotrieve]
|
| 19.
|
Griffin, E. A., Jr.,
Staknis, D.,
and Weitz, C. J.
(1999)
Science
286,
768-771[Abstract/Free Full Text]
|
| 20.
|
Shearman, L. P.,
Sriram, S.,
Weaver, D. R.,
Maywood, E. S.,
Chaves, I.,
Zheng, B.,
Kume, K.,
Lee, C. C.,
van der Horst, G. T.,
Hastings, M. H.,
and Reppert, S. M.
(2000)
Science
288,
1013-1019[Abstract/Free Full Text]
|
| 21.
|
Cegielska, A.,
Gietzen, K. F.,
Rivers, A.,
and Virshup, D. M.
(1998)
J. Biol. Chem.
273,
1357-1364[Abstract/Free Full Text]
|
| 22.
|
Elbashir, S. M.,
Harborth, J.,
Lendeckel, W.,
Yalcin, A.,
Weber, K.,
and Tuschl, T.
(2001)
Nature
411,
494-498[CrossRef][Medline]
[Order article via Infotrieve]
|
| 23.
|
Fish, K.,
Cegielska, A.,
Getman, M.,
Landes, G.,
and Virshup, D. M.
(1995)
J. Biol. Chem.
270,
14875-14883[Abstract/Free Full Text]
|
| 24.
|
Vielhaber, E. L.,
Duricka, D.,
Ullman, K. S.,
and Virshup, D. M.
(2001)
J. Biol. Chem.
276,
45921-45927[Abstract/Free Full Text]
|
| 25.
|
Camacho, F.,
Cilio, M.,
Guo, Y.,
Virshup, D.,
Patel, K.,
Khorkova, O.,
Styren, S.,
Morse, B.,
Yao, Z.,
and Keesler, G. A.
(2001)
FEBS Lett.
489,
159-165[CrossRef][Medline]
[Order article via Infotrieve]
|
| 26.
|
Hunter, T.,
and Karin, M.
(1992)
Cell
70,
375-387[CrossRef][Medline]
[Order article via Infotrieve]
|
| 27.
|
Karin, M.,
and Hunter, T.
(1995)
Curr. Biol.
5,
747-757[CrossRef][Medline]
[Order article via Infotrieve]
|
| 28.
|
Peters, J. M.,
McKay, R. M.,
McKay, J. P.,
and Graff, J. M.
(1999)
Nature
401,
345-350[CrossRef][Medline]
[Order article via Infotrieve]
|
| 29.
|
Sakanaka, C.,
Leong, P., Xu, L.,
Harrison, S. D.,
and Williams, L. T.
(1999)
Proc. Natl. Acad. Sci. U. S. A.
96,
12548-12552[Abstract/Free Full Text]
|
| 30.
|
Miyazaki, K.,
Mesaki, M.,
and Ishida, N.
(2001)
Mol. Cell. Biol.
21,
6651-6659[Abstract/Free Full Text]
|
| 31.
|
Ishida, Y.,
Yagita, K.,
Fukuyama, T.,
Nishimura, M.,
Nagano, M.,
Shigeyoshi, Y.,
Yamaguchi, S.,
Komori, T.,
and Okamura, H.
(2001)
J. Neurosci. Res.
64,
612-616[CrossRef][Medline]
[Order article via Infotrieve]
|
| 32.
|
Lee, C.,
Etchegaray, J. P.,
Cagampang, F. R.,
Loudon, A. S.,
and Reppert, S. M.
(2001)
Cell
107,
855-867[CrossRef][Medline]
[Order article via Infotrieve]
|
| 33.
|
Sanada, K.,
Okano, T.,
and Fukada, Y.
(2002)
J. Biol. Chem.
277,
267-271[Abstract/Free Full Text]
|
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ABSTRACT
INTRODUCTION
