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Molecular and Cellular Biology, November 2001, p. 7287-7294, Vol. 21, No. 21
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.21.7287-7294.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Photic Signaling by Cryptochrome in the Drosophila
Circadian System
Fang-Ju
Lin,
Wei
Song,
Elizabeth
Meyer-Bernstein,
Nirinjini
Naidoo, and
Amita
Sehgal*
Department of Neuroscience, Howard Hughes
Medical Institute, University of Pennsylvania Medical School,
Philadelphia, Pennsylvania 19104
Received 25 January 2001/Returned for modification 5 March
2001/Accepted 7 August 2001
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ABSTRACT |
Oscillations of the period (per) and
timeless (tim) gene products are an integral
part of the feedback loop that underlies circadian behavioral rhythms
in Drosophila melanogaster. Resetting this loop in
response to light requires the putative circadian photoreceptor
cryptochrome (CRY). We dissected the early events in photic resetting
by determining the mechanisms underlying the CRY response to light and
by investigating the relationship between CRY and the
light-induced ubiquitination of the TIM protein. In response to light,
CRY is degraded by the proteasome through a mechanism that requires
electron transport. Various CRY mutant proteins are not degraded,
and this suggests that an intramolecular conversion is required for
this light response. Light-induced TIM ubiquitination precedes CRY
degradation and is increased when electron transport is blocked. Thus,
inhibition of electron transport may "lock" CRY in an active state
by preventing signaling required either to degrade CRY or to convert it
to an inactive form. High levels of CRY block TIM ubiquitination,
suggesting a mechanism by which light-driven changes in CRY could
control TIM ubiquitination.
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INTRODUCTION |
In all organisms examined thus far,
a feedback loop comprising cycling gene products that negatively
regulate their own synthesis lies at the heart of the circadian clock
(7). In Drosophila melanogaster, two of the
genes that autoregulate in this fashion are period
(per) and timeless (tim). The
per and tim mRNA levels cycle with a circadian
rhythm, such that RNA levels are high at the end of the day (or
beginning of the night) and low at the end of the night (13, 36,
37). The two encoded proteins (PER and TIM) also cycle, with
protein accumulation starting in the early evening and peaking in the
middle of the night (8, 15, 26, 47). As they accumulate in
the cytoplasm PER and TIM associate to form heterodimers (20,
47). This association stabilizes PER and permits nuclear entry
of both proteins (30, 31, 34). Thus, while TIM does not
require PER for stability, it is dependent on PER for nuclear
transport. In the nucleus, either one or both proteins repress the
synthesis of the per and tim mRNAs. Turnover of
the two proteins, TIM in the late night and PER in the early morning,
allows RNA levels to rise once again and the cycle continues.
Light acts as the primary zeitgeber, or timegiver, to synchronize an
organism to its environment. At a molecular level the effect of light
is to reduce levels of the TIM protein, an effect that appears to
mediate entrainment of the molecular loop and thereby that of
behavioral rhythms (15, 20, 26, 47). In fact, in all
organisms examined (Neurospora crassa,
Drosophila, and mammals), light changes levels of a clock
component, indicating that this is a conserved general mechanism
(7, 32, 41). The photoreceptors used by the circadian
clock are still a subject of considerable debate, but in
Drosophila it is clear that the visual system is not
required although it is a redundant pathway that can mediate
entrainment (14, 40, 46). The dedicated circadian
photoreceptor in Drosophila as well as in
Arabidopsis thaliana is the flavin-binding
photoreceptor, cryptochrome (CRY) (1, 9-11, 39). In
Drosophila, levels of cry RNA and protein cycle
such that RNA levels peak at the end of the day and protein levels are
high at night (9). Flies containing a mutant
cry gene (cryb) display free-running
behavioral rhythms but show deficits in entrainment that are especially
pronounced when cryb is coupled with a
visual-system mutation (14, 39). In addition, cryb mutant flies are rhythmic in constant light
while wild-type flies are arrhythmic under such conditions, further
demonstrating that their circadian system is defective in its ability
to perceive light (10).
We recently found that TIM degradation in response to light is mediated
by the proteasome and that TIM is phosphorylated and ubiquitinated
prior to its degradation (27). Ubiquitination of TIM in
response to light can be observed in cultured Drosophila S2
cells. To analyze the upstream events in the photic input pathway, we
investigated the response of CRY to light and the effect of CRY
signaling on TIM ubiquitination in the S2 cell culture system. Our data
support a model in which CRY undergoes a light-induced conformation
change which leads to its degradation by the proteasome. Blocking the
transport of electrons from reduced flavin inhibits CRY degradation and
increases TIM ubiquitination, indicating a causal relationship between
the two events. However, overexpression of CRY attenuates TIM
ubiquitination. Based on these data we propose a model according to
which CRY controls TIM ubiquitination by actively blocking it in the
dark and promoting it in the presence of light.
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MATERIALS AND METHODS |
Plasmid construction.
The pIZ-cry expression
plasmid was constructed by ligating the entire coding region of
dcry (nucleotides 1 to 1629; GenBank accession no. AB018050)
into expression vector pIZ/His-V5 (Invitrogen), which uses the OpIE2
promoter. The design inserted the V5 epitope at the carboxy terminus of
CRY. CRY mutants CRY-N (amino acids 1 to 423 of CRY), CRY-C
(amino acids 244 to 542), and CRYb (39) were
also subcloned into pIZ/His-V5. Expression plasmids hs-tim, hs-cry and hs-Ub were constructed by
cloning full-length cDNAs for tim (28),
cry, and an hemagglutinin (HA)-tagged ubiquitin octamer
(42), respectively, into hsp70 promoter-driven
expression vector pCasPer-hs (27). All constructs were
verified by restriction enzyme digestion and sequencing.
Fly genetics.
The UAS-cry transgenic line,
P{UAS-dcry}, was generously provided by T. Tanimura
(Kyushu University, Ropponmatsu, Japan) (16). To
obtain CRY-overexpressing flies, the P{UAS-dcry}
line was crossed with the act5C-GAL4 effector line.
Cell transfections and pharmacological treatment.
All
plasmids, hs-tim (1 µg/well), hs-Ub (1 µg/well),
hs-cry, and wild-type and mutant pIZ-cry (amounts
specified in each figure legend) were transfected using the calcium
phosphate coprecipitation method. The calcium phosphate precipitate was
mixed with 5 × 106 cells, and the mixture was
incubated for 16 h. The cells were grown for an additional 24 h in fresh media. To induce the expression of transfected genes in the
pCasPer-hs vector, cells were incubated for 30 min at 37°C and
allowed to recover at room temperature for the times indicated
in the figure legends. For light treatment (at the bench top, ~600
lx) the cells were exposed to a 10-min or 2- or 5-h light pulse after
recovery from heat shock (see figure legends for details). For
transfections where no heat shock was involved, light treatment was
initiated 40 to 48 h after transfection. Diphenylene iodonium
(DPI; Sigma) and MG115 (Z-Leu-Leu-Nva-H; Peptides International)
dissolved in dimethyl sulfoxide and lactacystin (BIOMOL) dissolved in
water were used at a final concentration of 20 µM. After the
treatments required for each experiment, cells were harvested and lysed
as described below.
Coimmunoprecipitations.
S2 cells were washed once with
phosphate-buffered saline (PBS) and lysed in Triton immunoprecipitation
buffer (150 mM NaCl, 50 mM Tris [pH 7.5], 10 mM EDTA [pH 8.0],
0.2% Triton X-100, 10 mM dithiothreitol, protease inhibitor
cocktail; Boehringer Mannheim). Cell extracts were clarified by
centrifugation (16,181 × g, 20 min at 4°C), and
protein concentrations were determined using the Bio-Rad DC protein
assay. One milligram of total protein from each clarified supernatant
was incubated with 1 µl of an antibody to TIM (UPR8) overnight at
4°C. The immune complex was bound to protein G beads by incubation at
4°C for 1 h. Beads were then washed three times with PBS, mixed
with sodium dodecyl sulfate (SDS) gel loading buffer (40 µl), and
boiled, and the supernatant was loaded onto SDS-polyacrylamide gel
electrophoresis gels. To assay ubiquitination, Western blots of the
precipitates were probed with an anti-HA antibody as described below
(the transfected ubiquitin is tagged with HA).
Western blots.
Fly head extracts were obtained as follows.
Heads from frozen flies were homogenized in the Triton
immunoprecipitation buffer described above. Extracts were clarified by
centrifugation (16,181 × g, 20 min at 4°C), and
the protein concentration was determined. One hundred to 150 µg of
protein from the clarified supernatant was loaded onto
SDS-polyacrylamide gel electrophoresis gels and transferred to a
nitrocellulose membrane. For S2 cell Western blots, equivalent amounts
of protein from S2 cells were loaded (amount used in each experiment is
indicated in the figure legends). After being blocked in 1% bovine
serum albumin and 3% nonfat dry milk in PBS, the blot was incubated
with either a 1:1,000 dilution of rabbit anti-HA antibody (Clontech;
see Fig. 5 and 7A), a 1:300 dilution of mouse anti-HA antibody
(provided by Jeffrey Field; see Fig. 6) (12), a 1:1,000
dilution of rat anti-TIM antibody UPR8 (15), a 1:1,000
dilution of mouse anti-V5 antibody (Invitrogen), a 1:200 dilution of
rat anti-CRY (raised to a full-length glutathione S-transferase-CRY fusion protein; see Fig. 7A), or a
1:5,000 dilution of rabbit anti-MAPK (mitogen-activated protein kinase;
Sigma) in blocking solution for 1 h at room temperature.
Subsequently, the blot was washed three times for 10 min each in PBS
and then incubated with horseradish peroxidase-conjugated secondary
antibody (1:1,000; Amersham). The signal was visualized with the ECL
kit (Amersham). To ensure equal loading on each lane, the blot was stripped in stripping buffer (62.5 mM Tris-HCl [pH 7.6], 100 mM 2-mercaptoethanol, 5% SDS) at 55°C for 30 min, rinsed in PBS, blocked, and processed for detecting other bound proteins. In CRY
experiments, overall levels of MAPK were quantitated to control for
protein concentration and loading (see Fig. 1 and 3), whereas immunoprecipitated TIM levels were used as a control in TIM
ubiquitination experiments (see Fig. 6 and 7). The Western blotting
data were quantified on a densitometer (Molecular Dynamics), and the
relative optical density (ROD) of the protein of interest was then
determined. The means ± standard errors of the means (SEM) of the
experiments were plotted, and Student's t test was used to
make comparisons between control and experimental groups.
Reverse transcription-PCR.
mRNA from S2 cells
was isolated using the MicroPoly(A)Pure kit and transcribed to
first-strand cDNA with an oligo(dT) primer using the Superscript
preamplification system (Life Technologies). To ensure that the PCR
product was derived from mRNA and not genomic DNA, a negative control
in which reverse transcriptase was omitted was included. Subsequent PCR
amplification was carried out with a primer pair that amplifies
nucleotides 654 to 1089 of cry.
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RESULTS |
CRY is degraded by the proteasome in response to light.
The
profile of CRY protein expression in light-dark (LD) cycles suggested
that the protein is unstable in the presence of light (9).
Light-induced instability of CRY was supported by experiments in which
CRY was expressed in S2 cells (4). We transfected cells
with a pIZ-cry construct, in which CRY is tagged with a V5
epitope, and noticed that levels of the protein were reduced by light
treatment. To identify the mechanisms that degrade CRY, we treated CRY
-transfected cells with light in the presence of proteasome inhibitors
MG115 and lactacystin. Both these agents were effective in blocking CRY
degradation (Fig. 1). This effect of
light on both TIM (27) and CRY suggests that the action of a ubiquitin/proteasome degradation pathway may be one of the first events in photic resetting in Drosophila.
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FIG. 1.
CRY is degraded by the proteasome in response to light.
S2 cells were transfected with pIZ-cry (2 µg/well) and
then left in the dark for 40 h. A proteasome inhibitor, either
MG115 (A) or lactacystin (lacta) (B), was added to the culture media at
20 µM. The cells were subsequently kept in light (L) or dark (D) for
5 h prior to Western blot analysis. (Left) Western blots (150 µg/lane) were probed first with an anti-V5 antibody to detect
pIZ-cry and then with an anti-MAPK antibody to control for
loading. (Right) For each proteasome inhibitor, data from three
independent experiments were quantified on a densitometer (Molecular
Dynamics). The ROD of the CRY signal was normalized to that of
MAPK, and the means ± SEM are graphed. *,
significantly different from the light-treated control assayed in
the absence of the proteasome inhibitor (t =  3.05 and P < 0.04 for MG115, and t = 3.22 and P = 0.03 for lactacystin). MG115 and
lactacystin did not produce significant changes in CRY expression in
the samples that were maintained in the dark (t = 2.66 and P = 0.056, and t = 0.32 and P = 0.77, respectively).
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CRY mutants are not degraded by light.
We previously reported
light-induced ubiquitination of TIM in S2 cells (further discussed
below). The photoreceptor that transduced photic signals to TIM was not
known, but, based on data implying a role for CRY in circadian
photoreception (11, 39) together with the reported
light-activated direct interaction of TIM and CRY (4), we
suspected that S2 cells expressed endogenous cry. As shown
in Fig. 2A, we confirmed the presence of
cry RNA in S2 cells. Consistent with the presence of
endogenous CRY in our S2 cells, we found that light-dependent
inhibition of PER-TIM feedback activity, which is known to be CRY
dependent (4), occurred to a significant extent in the
absence of transfected CRY (S. Sathyanarayanan, F. Lin, and A. Sehgal,
unpublished data). The presence of endogenous photic signaling
mechanisms in S2 cells provided us with a system in which we could
assay the degradation of transfected CRY regardless of its ability to
transduce a photic signal.
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FIG. 2.
Effect of light on CRY mutants. (A) Expression of
endogenous cry in S2 cells. A 435-bp band corresponding to
dcry (bp 654 to 1089) was detected through reverse
transcription-PCR with S2 mRNA (lane 1). There was no band when
reverse transcriptase was eliminated from the reaction, indicating that
the product is derived from RNA (lane 2). Lane M, molecular weight
markers (Life Technologies). (B) (Top) Schematic representation of CRY
mutants. The CRYb mutant carries a missense mutation
(asterisk) that substitutes an asparagine (N) for an aspartic acid (D)
in the flavin-binding site. Both CRY-N and CRY-C contain the 14 highly
conserved residues required for flavin binding but lack sequences at
the C and N termini, respectively. (Middle) Western analysis of S2
cells transfected with the mutant cry DNA (2 µg/well).
Light-treated cells were exposed to a 2-h light pulse. Equal amounts of
light-treated (L) and dark control (D) lysates (150 µg/lane)
were loaded onto the gel, and the blot was probed with an
anti-V5 antibody. (Bottom) The Western blotting data from
this experiment and from several others were quantified on a
densitometer (Molecular Dynamics). The ROD of the signal obtained
under different conditions was normalized to that of wild-type CRY
in the dark, and the means ± SEM were plotted. The numbers
of independent experiments are in parentheses.
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To determine whether a specific region of CRY mediates its degradation,
we transfected different CRY mutants and assayed their
response to
light. As shown in Fig.
2B, CRY-N (amino acids 1 to
423) has
the C-terminal 119 amino acids deleted and CRY-C (amino
acids 244 to
542) has the N-terminal 243 amino acids deleted.
The
cryb mutation is a missense mutation within the
sequence that encodes
the highly conserved flavin-binding region of
Drosophila CRY.
It corresponds to the original
cry mutation isolated through a
genetic screen of
Drosophila (
39). Treatment with light did
not
reduce the levels of any of these mutant CRY proteins (Fig.
2B). For
CRY-N the levels were consistently low with and without
light
treatment, indicating a general instability of the protein.
CRY-C was
expressed at high levels, and levels of CRY
b were
equivalent to those of the wild type. However, none of these
proteins
showed a response to light. Since there is no common
sequence that is
deleted in all these constructs, this indicates
either that CRY
degradation requires more than one part of the
molecule or that the
overall conformation of the molecule is important
for its
recognition by the degradation system. The large deletions
in CRY-N and
CRY-C may prevent such a conformation change. For
CRY
b, the
mutation is thought to prevent association with flavin,
which may be
required for a redox-mediated conformation change
(see
below).
CRY degradation requires redox activity.
CRY signaling in
plants requires redox activity and is mediated, at least in part, by
the flavin moiety bound to CRY (23, 45). This is based on
the finding that DPI, which inhibits the transport of electrons from
reduced flavin, was effective in blocking CRY-mediated photic signaling
in Arabidopsis (23). In addition, flavins
participate in electron transport in other systems, the most relevant
system being that of the photolyases, which are homologous to CRYs and
which are known to repair DNA through an electron transfer mechanism
(2, 6).
Based on the data implicating electron transport in
Arabidopsis CRY signaling, we determined the effect of
electron transport
inhibitors on degradation of
Drosophila
CRY. As shown in Fig.
3, DPI attenuated
CRY degradation. Thus, photic signaling by
Drosophila CRY
involves redox activity, most likely mediated by the flavin.
Note that
the doses of DPI used here have not been associated
with any toxic
effects in cell culture systems (
5,
35). Ferricyanide,
which blocks electron transport in the membrane, attenuated CRY
degradation to a limited extent (data not shown).
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FIG. 3.
CRY degradation requires electron transport. The CRY
response to light was tested in transfected S2 cells in the presence of
electron transport inhibitor DPI. Cells were transfected with
pIZ-cry (2 µg/well), and DPI was added to the culture
media immediately before a 5-h light pulse. (Top) CRY expression was
assayed through Western blots using an anti-V5 antibody. The blots were
then stripped and reprobed with an anti-MAPK antibody. Three
independent experiments were performed and analyzed. (Bottom) The ROD
of the CRY signal was determined and normalized to that of MAPK. *,
significantly different from the light-treated sample assayed in the
absence of DPI (t = 3.65, P < 0.03).
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Relationship between light responses of CRY and TIM.
The
presence of endogenous CRY in our S2 cells supported the idea that the
light-dependent TIM ubiquitination we reported previously
(27) was mediated by CRY. As mentioned above, the data of
Ceriani et al., demonstrating a light-dependent interaction between TIM
and CRY, also suggested that CRY regulates TIM (4). To
determine if the TIM response to light requires CRY, we assayed TIM
levels in light-pulsed and unpulsed cryb flies.
As shown in Fig. 4, while wild-type flies
showed the characteristic decrease in TIM levels with light treatment,
this response was lacking in cryb flies. Using a
histochemistry assay, Ivachenko et al. also recently reported that TIM
does not respond to light in larval lateral neurons and adult
Malpighian tubules of cryb flies
(17).
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FIG. 4.
TIM is not degraded by light in
cryb flies. Wild-type (Canton S) and
cryb flies were treated with a 1-h light pulse
at zeitgeber time 20 (ZT20; ZT0, lights on; ZT12, lights off
[12-h-12-h LD cycle]). (Top) At the end of 1 h, light-pulsed
flies (LP) and unpulsed controls (NP) were harvested and head extracts
(100 µg/lane) were assayed for TIM expression. The Western
blots were stripped and reprobed with an anti-MAPK antibody to control
for loading (in other experiments we determined that levels of MAPK do
not cycle in adult fly heads [J. Williams and A. Sehgal, unpublished
data]). (Bottom) The data were quantified on a densitometer, and TIM
levels were normalized relative to those of MAPK. The means ± SEM
of three experiments are shown for both genotypes in light and dark.
TIM levels were significantly reduced by light in wild-type flies
(t = 3.78; P = 0.019) but not in the
cryb mutant (t = 1.31;
P = 0.26).
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We used the S2 cell system to determine the relationship between
light-induced CRY degradation and TIM ubiquitination and
degradation.
One possibility we considered was that CRY was required
for TIM
stability. In this model, light-induced CRY degradation
would lead to
TIM degradation, perhaps by exposing relevant sites
on TIM to
phosphorylation and ubiquitination events. Although
TIM and CRY do not
bind each other in the dark in the yeast two-hybrid
system, they
can be coimmunoprecipitated from S2 cells, suggesting
that they are
present in the same complex (
4). Thus, removal
of CRY in
response to light could affect TIM processing. Alternatively,
light
exposure may lead to some conformational and/or redox changes
in
CRY which trigger downstream events including TIM ubiquitination
and
CRY degradation. To distinguish between these two possibilities,
we
examined the time course of TIM ubiquitination and that of
CRY
degradation in S2 cells. We detected an increase in TIM ubiquitination
within 5 min of light exposure (Fig.
5A),
while CRY levels in
the same extracts remained unchanged up to the end
of a 30-min
light pulse (Fig.
5B). Thus, overall degradation of CRY
does not
appear to be required for TIM ubiquitination. Although we
cannot
exclude the possibility that CRY is removed from a complex with
TIM, it is more likely that in response to light CRY transmits
a signal
that leads to TIM ubiquitination.
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FIG. 5.
TIM ubiquitination precedes CRY degradation. We
determined the time course of light-induced TIM ubiquitination and of
CRY degradation in S2 cells. Cells were cotransfected with
hs-tim, hs-Ub (this expresses an HA-tagged ubiquitin
octamer), and pIZ-cry (2 µg/well). (A) Expression of TIM
and HA-tagged ubiquitin was induced through heat shock treatment (see
Materials and Methods). After recovery from heat shock, cells were
exposed to light for the indicated times and harvested immediately. TIM
ubiquitination was assayed by probing TIM immunoprecipitates with an
anti-HA antibody. Similar results were obtained in two independent
experiments. (B) Samples from panel A were run on a separate gel and
probed with anti-V5 to determine the level of CRY after light
treatment.
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We failed to detect significant degradation of TIM in S2 cells in
response to light. This may be due, in part, to the HA tag
on the
ubiquitin, which could interfere with proteasomal digestion.
However,
other researchers have also noted that TIM is not turned
over upon
light exposure in S2 cells (
4). Extended incubation
(up to
6 h post-TIM induction) of transfected cells resulted in
TIM
degradation in both dark- and light-treated cells (data not
shown).
We next examined TIM ubiquitination in the presence of electron
transport inhibitor DPI. TIM ubiquitination was increased
by DPI (Fig.
6), although CRY degradation was blocked,
which is
consistent with the idea that TIM ubiquitination does not
require
degradation of CRY (Fig.
5). In fact, the increased TIM
ubiquitination
is most likely due to the accumulation of activated CRY,
effected
through a block either in degradation or in the reconversion
of
CRY to an inactive form.
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FIG. 6.
TIM ubiquitination is increased by blocking electron
transport. Cells were transfected with hs-tim (T), hs-Ub
(U), and pIZ-cry (C) (0.2 µg/well). After a 30-min
heat shock, the cells were maintained in the dark for 2 h. DPI (20 µM) was added to the cultures 10, 20, or 30 min prior to the
initiation of a 10-min light pulse (L). Controls were maintained in the
dark (D) during this time. (Top) TIM ubiquitination was assayed as
described for Fig. 5. (Middle) The blot was reprobed with an anti-TIM
antibody to visualize overall TIM levels. TIM ubiquitination was
increased in the DPI-treated groups. (Bottom) Quantitation of data from
three independent experiments. In all cases, the ROD of the
ubiquitinated TIM species in DPI-treated groups was quantified on a
densitometer and normalized to the ROD of ubiquitinated TIM in
untreated cells. The duration of DPI treatment prior to the light pulse
is indicated within each bar. The numbers of times an experimental
condition was repeated are in parentheses.
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Effect of CRY overexpression on the TIM light response.
As
noted above, we believe that light-induced TIM ubiquitination in S2
cells is mediated by endogenous CRY. To test the effects of increasing
CRY levels on light-induced TIM ubiquitination, we cotransfected S2
cells with hs-tim, hs-Ub (27), and different concentrations of either pIZ-cry or hs-cry and
assayed TIM ubiquitination 2 h after light exposure.
High concentrations of both hs-
cry and pIZ-
cry
decreased TIM ubiquitination (Fig.
7A and
data not shown). However, ubiquitination
of TIM was enhanced when <0.2
µg of hs-
cry/well was transfected
(Fig.
7A).
pIZ-
cry did not increase TIM ubiquitination when transfected
at low concentrations, most likely because this plasmid yielded
higher
levels of CRY expression. Taken together these observations
indicate
that small increases in CRY promote TIM ubiquitination
after 2 h
of light exposure but that high levels attenuate it.
However, even in
the presence of high levels of CRY, TIM ubiquitination
increased during
the first 10 to 15 min of light treatment (Fig.
5A). The block at later
time points in CRY-overexpressing cells
(Fig.
7A) is indicative of a
deficit in the maintenance of TIM
ubiquitination, which may be due to
enhanced deactivation of CRY
(see Discussion).
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FIG. 7.
Effect of CRY overexpression on light-induced TIM
ubiquitination and TIM expression. (A) hs-tim, hs-Ub,
and different amounts of the hs-cry plasmid were transfected
into S2 cells where indicated. (Top) To analyze ubiquitination,
TIM immunoprecipitates were probed with an anti-HA antibody. (Middle)
The blots were reprobed with an anti-TIM antibody to evaluate overall
levels of TIM. (Bottom) CRY levels were verified by probing the same
lysates (100 µg) with an anti-CRY antibody. The differential effects
of low and high concentrations of CRY were observed in two independent
experiments with the hs-cry plasmid. Blocking by high
concentrations of CRY was also seen in multiple experiments with the
pIZ-cry plasmid (see text). (B) Light-induced degradation of
TIM protein is delayed in flies that overexpress CRY. Flies were
collected at the indicated zeitgeber times (ZT) during the third day of
a 12-h-12-h LD cycle. (Top) Western blots of yw and
Act5C-GAL4/UAS-cry adult head extracts (100 µg/lane) were
probed with an anti-TIM antibody. (Bottom) Data from two or three
independent experiments (the data for all the yw time points
and UAS-cry ZT23 are based on two experiments; data for
UAS-cry time points other than ZT23 are based on
three) were quantified on a densitometer. Means ± SEM are
plotted. A more detailed comparison of early day time points (ZT1, -2, and -4 to -6) between the two genotypes confirmed that TIM levels
were higher in UAS-cry flies in the early part of the day
(data not shown).
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Our data on the differential effects of low and high CRY concentrations
are supported by results of CRY overexpression in
transgenic flies.
Flies that overexpress CRY under control of
the
tim promoter
show enhanced resetting, while those that express
CRY under the actin
5c promoter show a reduction of light-induced
phase delays
(
16). The difference in the phenotypes of these
two
overexpression strains may lie in the level of overexpression.
To
determine whether the reduced resetting in the actin 5c line
correlated
with reduced TIM degradation in response to light,
we crossed flies
carrying a UAS-
cry construct to others carrying
an actin 5c
promoter-GAL4 transgene and assayed the resulting
progeny for TIM
expression. TIM expression was examined at different
times of day by
Western blotting of adult fly head extracts (Fig.
7B). In CRY
overexpression flies TIM levels were considerably
higher than wild-type
levels at time points 1 and 4 but equivalent
to wild-type levels at all
other time points. Thus, the effect
was specific for the early part of
the day, when TIM is normally
turned over in response to
light.
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DISCUSSION |
Degradation of CRY by light invokes analogies with the plant
photoreceptors, phytochrome (PHY) and CRY, both of which are degraded
in response to light (22, 38). Thus, it may be a common
mechanism to control levels of the photoreceptor and thereby the
strength of the photic response. Moreover, as noted here for CRY, PHY
is known to be degraded by the proteasome (38).
The role of the proteasome in degradation of both CRY and TIM also
underscores similarities with the cell cycle. The cell cycle is
characterized by cycling proteins that undergo phosphorylation and
subsequent degradation, in many cases by the proteasome
(18). We now know that both PER and TIM are cyclically
phosphorylated and that phosphorylation plays a role in turnover of
both proteins (27, 30). For TIM, light-induced degradation
is effected through an increase in phosphorylation and ubiquitination
(27). Thus, as for the cell cycle, multiple proteins in
the circadian cycle are turned over by the ubiquitin-proteasome
pathway. However, PER turnover may utilize a different pathway since
ubiquitination of PER has not been observed (27).
The mechanisms that lead to CRY degradation in response to light are
not clear, but we hypothesize that a conformation change in CRY
is required. A light-induced conformation change is supported by the
following lines of evidence. (i) In the yeast two-hybrid system CRY
interacts with full-length TIM in the presence of light but not in the
dark (4). (ii) Sequences that mediate CRY degradation do
not appear to map to a unique part of the molecule, suggesting that
the tertiary structure is important (Fig. 2). (iii) The
CRYb protein is not degraded by light (Fig. 2). All these
mutants were tested in the presence of endogenous CRY, and so their
ability to signal was dissociated from their degradation. Although the single amino acid mutated in the flavin-binding region in
CRYb could play a direct role in the degradation process,
it is far more likely that it affects a flavin-mediated conformation
change. The fact that CRYb does not associate with TIM in
the yeast two-hybrid system (4) is consistent with an
inability to undergo a conformation change.
Ceriani et al. showed recently that CRY blocks PER and TIM
autoregulation of their own RNA synthesis in a light-dependent manner
in S2 cells (4). As TIM degradation is not detectable in
S2 cells, they suggested that the inhibition of TIM activity, rather
than its degradation, by CRY is the primary response to light. We
believe that this block in PER-TIM activity may be the immediate
response of the clock to light. Presumably this block persists as long
as the photic signals are present and CRY is not degraded. However, a
phase change of several hours, which can be produced with a pulse of
<1 min of light, must require an irreversible change in a clock
component. We show that TIM is ubiquitinated in S2 cells within 5 min
of light treatment. In flies, TIM degradation (which presumably follows
ubiquitination) occurs within 30 to 60 min of light treatment
(15) and is apparently critical for resetting the clock
(40, 46). As shown in Fig. 4 and as reported by Ivachenko
et al., a CRY molecule with a functional flavin-binding domain is
required for this response (17).
Signaling by flavins frequently involves a redox change (2, 23,
24). In fact, we show here that a reagent that blocks the
transfer of electrons from reduced flavin prevents CRY degradation by
light. At the same time, it increases TIM ubiquitination. Based on the
recently proposed models for Arabidopsis CRY
(45), DPI may block either intramolecular electron
transport required for a change in CRY conformation or
intermolecular transport to a signaling pathway that effects
degradation. Assuming that active CRY, which promotes TIM
ubiquitination, is produced by a conformation change, we suggest that
the DPI-sensitive step occurs after the conformation change. It should
be noted that DPI can also block the activity of other flavoproteins,
such as NADPH oxidase and nitric oxide synthase, that play a role in
redox processes (21, 44).
We show here that high levels of CRY block TIM ubiquitination. Our data
on the effects of CRY in S2 cells are supported by in vivo fly data.
Transgenic flies that overexpressed CRY under control of the
tim promoter showed enhanced resetting, indicating that
within a certain range increasing levels of the photoreceptor amplify
the photic signal (9). Likewise, at very low
concentrations in cultured cells we observed increased TIM
ubiquitination (Fig. 7A). However, when CRY was overexpressed by the
actin 5c promoter in flies (16) and also in the cultured
cells when it increased beyond a certain level (Fig. 7A), the photic
signal is reduced. The transgenic lines that expressed CRY under the
control of the actin 5c promoter showed smaller phase shifts than the
wild type, perhaps because the actin promoter drives a high level of
expression at all times of day, as distinct from the tim
promoter, which is rhythmically transcribed. In addition, the actin 5c
line that expressed the highest levels of CRY showed decreased
sensitivity to light such that a higher intensity of light was required
to produce shifts equivalent to that for the wild type. Our data demonstrate that in these flies levels of TIM in the early part of the
day are increased. This could be due to the effect of CRY overexpression on the feedback mechanism; since CRY is known to attenuate negative feedback by PER and TIM in a light-dependent manner
(4), CRY overexpression could result in reduced feedback and thereby increased tim RNA expression. However, one would
expect the increased RNA to also result in high levels of TIM at night, which was not observed here (Fig. 7B). Given that daytime levels are
preferentially affected, together with the behavioral phenotype of
these flies, we favor the alternative explanation that the TIM response
to light is reduced due to attenuation of photic signaling by
overexpressed CRY.
We infer that, in the actin 5c-CRY flies as well as in the S2 cells,
less CRY is present in an active (light-induced) conformation. Overexpression may result in rapid deactivation of CRY in continuous light, which would account for the decrease in TIM ubiquitination observed at later time points (compare Fig. 5 and 7). We note that
photoreceptors are known to be deactivated in the presence of
continuous light (25), a process that may be augmented by overexpression. An attractive possibility is that the inactive form of
CRY prevents TIM ubiquitination while the light-induced form, which
binds TIM directly, promotes TIM ubiquitination (Fig. 8). In the CRY overexpression situation
the high levels of inactive CRY during both the light and the dark
attenuate TIM ubiquitination. Since the inactive form is normally found
in the dark, this would be indicative of a role for CRY in blocking TIM
ubiquitination in the dark (Fig. 8). It may be possible to test this
model by generating mutations that lock CRY in a particular
conformation. It would also be interesting to determine the effects of
acute CRY induction on overall TIM levels and on light-induced TIM
degradation in flies. A function for CRY in stabilizing TIM may also
have relevance for its mechanism of action within the clock. To date, there is no evidence to suggest that CRY is involved in generating free-running behavioral rhythms in Drosophila, but it
apparently participates in clock function in peripheral tissues
(17, 19). Interestingly, in Malpighian tubules, where CRY
appears to be part of the clock, TIM levels are low in
cryb flies (17). In addition,
mammalian CRY is part of the clock that controls behavioral rhythms and
is thought to stabilize mPER2 (33). It is conceivable
that, as a clock component, CRY controls free-running degradation of
clock proteins, thereby promoting molecular oscillations.
View larger version (12K):
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|
FIG. 8.
Model for the effect of CRY on TIM. The light-induced
conformation of CRY promotes TIM ubiquitination, perhaps through direct
interaction with TIM. This conformation of CRY also signals to a
degradation pathway through a DPI-sensitive electron transport
mechanism. As a result, both CRY and TIM are degraded (although TIM
degradation is not observed in S2 cells, light-induced TIM degradation
in flies is CRY dependent [17] [Fig. 4]). We assume
that, like other photoreceptors, CRY is eventually deactivated.
Overexpression of CRY may favor its deactivation, resulting in
decreased TIM ubiquitination in S2 cells and decreased degradation in
flies (Fig. 7). We suggest that the inactive CRY actively inhibits TIM
ubiquitination, a mechanism by which CRY could also control TIM
ubiquitination in the dark (see Discussion). FADH, reduced flavin
adenine dinucleotide.
|
|
The lack of TIM degradation in S2 cells suggests that some components
of the pathway are absent or expressed at low levels in these cells.
Nevertheless, it is clear that S2 cells are capable of circadian
photoreception and support all the events that lead up to the first
response of a clock protein. Given that the S2 cell line is an
embryonic line that has not differentiated completely, this suggests
that photoreceptors, and in some cases perhaps even circadian
oscillators, are found in undifferentiated embryonic cells,
which give rise to specific organs. In this context, note that some
mammalian cells display cyclic expression of clock genes when serum
shocked (3). In addition, circadian oscillators that can
be entrained by light have been described in isolated organs from both
vertebrates and invertebrates (29, 43).
| |
ACKNOWLEDGMENTS |
The first two authors contributed equally to this work.
We thank Yifeng Chen for raising the CRY antibody used here, Teiichi
Tanimura for flies carrying the UAS-cry construct, J. D. Alvarez and J. Field for comments on the manuscript, Tony Cashmore and Peter Schotland for comments on a previous version, and other members of the laboratory for useful discussions.
The work was supported in part by grants from the NIH and NSF.
A.S. is an Associate Investigator in the HHMI.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Howard Hughes
Medical Institute, Department of Neuroscience, University of
Pennsylvania Medical School, Philadelphia, PA 19104. Phone: (215)
573-2985. Fax: (215) 573-2015. E-mail:
amita{at}mail.med.upenn.edu.
| |
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Molecular and Cellular Biology, November 2001, p. 7287-7294, Vol. 21, No. 21
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.21.7287-7294.2001
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Abstract
Introduction
