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Molecular Cell
Article
CRL4Cdt2-Mediated Destruction
of the Histone Methyltransferase Set8 Prevents
Premature Chromatin Compaction in S Phase
Richard C. Centore,1 Courtney G. Havens,3 Amity L. Manning,1 Ju-Mei Li,4 Rachel Litman Flynn,1 Alice Tse,1 Jianping Jin,4
Nicholas J. Dyson,1 Johannes C. Walter,3 and Lee Zou1,2,*
1Massachusetts General Hospital Cancer Center, Harvard Medical School, Charlestown, MA 02129, USA
2Department of Pathology
3Department of Biological Chemistry and Molecular Pharmacology
Harvard Medical School, Boston, MA 02115, USA
4Department of Biochemistry and Molecular Biology, The University of Texas Health Science Center at Houston, Houston, TX 77030, USA
*Correspondence: zou.lee@mgh.harvard.edu
DOI 10.1016/j.molcel.2010.09.015
SUMMARY
The proper coordination between DNA replication
and mitosis during cell-cycle progression is crucial
for genomic stability. During G2 and mitosis, Set8
catalyzes monomethylation of histone H4 on lysine
20 (H4K20me1), which promotes chromatin compaction. Set8 levels decline in S phase, but why and how
this occurs is unclear. Here, we show that Set8 is
targeted for proteolysis in S phase and in response
to DNA damage by the E3 ubiquitin ligase, CRL4Cdt2.
Set8 ubiquitylation occurs on chromatin and is
coupled to DNA replication via a specific degron in
Set8 that binds PCNA. Inactivation of CRL4Cdt2 leads
to Set8 stabilization and aberrant H4K20me1 accumulation in replicating cells. Transient S phase
expression of a Set8 mutant lacking the degron
promotes premature H4K20me1 accumulation and
chromatin compaction, and triggers a checkpointmediated G2 arrest. Thus, CRL4Cdt2-dependent
destruction of Set8 in S phase preserves genome
stability by preventing aberrant chromatin compaction during DNA synthesis.
INTRODUCTION
DNA replication and other cell-cycle events, such as replication
origin licensing in G1 and chromatin condensation in mitosis, are
carefully coordinated to maintain genomic stability. The process
of DNA replication is coupled with several other events, including
chromatin assembly, sister-chromatid cohesion, ubiquitylation
of specific cell-cycle regulators, activation of the DNA replication
checkpoint, and DNA repair. Recent studies showed that the
CRL4Cdt2 E3 ubiquitin ligase, which functions in a replicationcoupled manner through binding to PCNA, plays a critical role
in coordinating origin licensing in G1 and DNA replication in S
phase (Jin et al., 2006; Kim et al., 2008; Lovejoy et al., 2006;
22 Molecular Cell 40, 22–33, October 8, 2010 ª2010 Elsevier Inc.
Sansam et al., 2006; Zhong et al., 2003). To understand whether
CRL4Cdt2 has additional roles in coordinating DNA replication
with other cell-cycle events, we sought to identify additional
CRL4Cdt2 substrates.
The CRL4Cdt2 E3 ligase complex is comprised of the scaffold
protein Cul4, the adaptor protein Ddb1, and the putative
substrate receptor protein Cdt2 (Angers et al., 2006; Higa
et al., 2006; Jin et al., 2006; Sansam et al., 2006). The best-characterized substrate of CRL4Cdt2 is the ‘‘licensing’’ factor Cdt1,
which is required to recruit the MCM2-7 complex to replication
origins in G1. During DNA replication, Cdt1 binds to PCNA
through a PCNA-interacting protein motif (PIP box), and is
degraded on chromatin in a PCNA- and CRL4Cdt2-dependent
manner (Arias and Walter, 2005, 2006; Jin et al., 2006; Nishitani
et al., 2006; Sansam et al., 2006; Senga et al., 2006). This replication-coupled mechanism for Cdt1 degradation ensures that
fired replication origins cannot be relicensed in the same
S phase. The CRL4Cdt2-mediated degradation of Cdt1 occurs
not only in S phase, but also after DNA damage (Higa et al.,
2003, 2006; Hu et al., 2004; Hu and Xiong, 2006; Jin et al.,
2006; Sansam et al., 2006; Senga et al., 2006). When it is bound
to PCNA on chromatin, the PIP box of Cdt1 is presented as
a degron and recognized by CRL4Cdt2. Our analysis of the PIP
degron of Cdt1 has identified three sequence elements critical
for binding to PCNA and Cdt2, which are conserved among
known CRL4Cdt2 substrates (Havens and Walter, 2009).
In a genome-wide search for PIP degron-containing proteins,
we identified Set8 (KMT5A/PR-Set7/SETD8) as a potential
substrate of CRL4Cdt2. Set8 is the methyltransferase that monomethylates histone H4 on lysine 20 (H4K20me1) (Fang et al.,
2002; Nishioka et al., 2002). Loss of Set8 in human, mouse, or
Drosophila cells results in massive DNA damage during S phase
and improper chromosome condensation in mitosis (Houston
et al., 2008; Huen et al., 2008; Jorgensen et al., 2007; Karachentsev et al., 2005; Oda et al., 2009; Paulsen et al., 2009; Sakaguchi
and Steward, 2007; Tardat et al., 2007). During the cell cycle,
Set8 is most abundant during G2 and mitosis, and low during
S phase (Huen et al., 2008; Oda et al., 2009; Yin et al., 2008).
Concomitant with the elevation of its abundance in the G2
and M phases, Set8 promotes a transient accumulation of
�Molecular Cell
CRL4Cdt2 E3 Ligase Targets Set8 for Degradation
A
Figure 1. Set8 Is Degraded by CRL4Cdt2 in
Response to DNA Damage
B
(A) Sequence alignment of the PIP degrons of
human Cdt1, p21, and Set8 from different species.
J is any moderately hydrophobic amino acid L, V,
I, or M. w is an aromatic residue, Y or F. B is a positively charged residue, R or K. Red residues are
conserved in the PIP boxes, and the blue residues
are only conserved in the PIP degrons.
(B) UV-induced Set8 degradation is 26S proteaD
some dependent. U2OS cells were treated with
50 J/m2 UV, and the levels of endogenous Set8,
Cdt1, and tubulin were monitored at the indicated
C
times by western blotting. Where indicated, 10 mM
Mock
UCN-01
Wortmannin
MG132 was added to cells 5 hr prior to irradiation.
0 0.5 1 2 0 0.5 1 2 0 0.5 1 2 hr post UV
(C) UV-induced Set8 degradation is independent
of ATM, ATR, and Chk1. U2OS cells were treated
Set8
with 1 mM UCN-01 (Chk1 inhibitor) or 100 mM wortE
mannin (PI3KK inhibitor) for 1 hr prior to UV irradi*
Cdt1
ation. Inhibition of Chk1 phosphorylation serves as
a positive control for wortmannin activity. Note that
Chk1 S345p
UCN-01 does not inhibit the phosphorylation of
Chk1 by ATR, but prevents the mobility change
PCNA
of Chk1 indicative of Chk1 autophosphorylation.
(D) CRL4Cdt2 downregulates Set8 protein levels.
U2OS cells were transfected with control siRNA
or siRNAs targeting Ddb1, Cdt2, and Cul4A. The
levels of the indicated proteins were monitored
by western blotting.
(E) UV-induced Set8 degradation is Cdt2 dependent. U2OS cells transfected with Cdt2 siRNA or control siRNA were treated with UV followed by 100 mg/ml
cycloheximide. The levels of the indicated proteins were analyzed in a time course. In all panels, asterisk labels nonspecific bands recognized by the indicated
antibodies.
H4K20me1 (Houston et al., 2008; Huen et al., 2008; Oda et al.,
2009; Rice et al., 2002). H4K20me1, which promotes chromatin
compaction, may contribute to proper mitosis and impact the
subsequent S phase (Houston et al., 2008; Oda et al., 2009;
Sakaguchi and Steward, 2007; Trojer et al., 2007). While Set8
has a clear role in methylating H4K20 during mitosis, why and
how it is downregulated during S phase is not clear. Interestingly,
in the presence of proteasome inhibitors, Set8 is readily detected
in S phase cells, and it colocalizes with the DNA replication
protein PCNA (Huen et al., 2008; Jorgensen et al., 2007; Tardat
et al., 2007). Furthermore, Set8 contains two PIP boxes that
contribute to its binding to PCNA (Huen et al., 2008; Jorgensen
et al., 2007).
In this study, we show that Set8 is degraded by a CRL4Cdt2mediated mechanism during S phase and in response to DNA
damage. The degradation of Set8 relies on its PIP degron and
its interactions with both PCNA and Cdt2. This mechanism of
Set8 degradation is observed not only in human cells but also
in Xenopus egg extracts. In the cell-free Xenopus system, Set8
is ubiquitylated on chromatin and destroyed in a PCNA-, Cdt2-,
and PIP degron-dependent manner. Ablation of CRL4Cdt2 in
human cells leads to stabilization of endogenous Set8 and aberrant accumulation of H4K20me1 in S phase cells. When a stabilized PIP box mutant of Set8 is expressed in S phase cells, it
induces premature H4K20me1 accumulation and chromatin
compaction, and triggers a checkpoint-mediated G2 arrest.
We propose that CRL4Cdt2-mediated degradation of Set8
prevents H4K20me1 accumulation during S phase, thereby preventing premature chromatin compaction that interferes with
genome duplication. The replication-coupled downregulation
of Set8 is a critical mechanism that defines the functional
window of Set8 during the cell cycle, contributing to the orderly
execution of DNA replication and mitosis.
RESULTS
Set8 Is Downregulated by CRL4Cdt2 in Cycling Cells
and in Response to DNA Damage
Our recent studies revealed three sequence elements that are
conserved in known CRL4Cdt2 substrates and together comprise
a ‘‘PIP degron’’ (Figure 1A): one is a canonical PIP box that is
essential for PCNA binding, another is a TD motif at positions
5 and 6 of the PIP box that confers high-affinity binding to
PCNA, and the third is a basic residue located four amino acids
downstream of the PIP box that is important for Cdt2 recruitment to the substrate-PCNA complex on chromatin (Havens
and Walter, 2009). To identify additional substrates of the
CRL4Cdt2 E3 ligase, we searched the Swiss-Prot database using
ExPASy ScanProsite with the PIP degron consensus motif (Q/Nx-x-L/V/I/M-T-D-F/Y-F/Y-x-x-x-K/R). Like Cdt1 and p21, two
known CRL4Cdt2 substrates (Abbas et al., 2008; Kim et al.,
2008; Nishitani et al., 2008), Set8 was identified in this screen.
Notably, the PIP degron sequence in Set8 was perfectly
conserved across a wide range of metazoan organisms (Figure 1A). This finding prompted us to investigate whether the
stabilities of Set8 and Cdt1 were similarly regulated in cells.
Both Set8 and Cdt1 are downregulated during S phase, and
Cdt1 is degraded in response to DNA damage (Higa et al.,
Molecular Cell 40, 22–33, October 8, 2010 ª2010 Elsevier Inc. 23
�Molecular Cell
CRL4
A
Cdt2
Figure 2. UV-Induced Set8 Degradation Is
Dependent on Its PIP Degron
D
Set8-Ub
B
E
C
-
+
+
-
His/Biotin-Ubiquitin
+
UV
kDa
Set8-Ub
170
130
*
95
*
2003; Hu et al., 2004). A previous study showed that Set8 levels
were reduced after DNA damage due to transcription repression
(Shi et al., 2007). We found that in U2OS cells treated with 50
J/m2 UV, the level of endogenous Set8 rapidly declined within
1 hr (Figure 1B, lanes 1–3). Furthermore, the UV-induced reduction of Set8 was prevented by MG132, suggesting that Set8 is
degraded by the proteasome in response to DNA damage
(Figure 1B). The DNA damage-induced degradation of Cdt1 is
independent of the checkpoint kinases ATM and ATR (Higa
et al., 2003). Analogously, wortmannin, an inhibitor of ATM and
ATR, and UCN-01, an inhibitor of the ATR effector kinase
Chk1, had no effect on the UV-induced degradation of Set8
(Figure 1C). These results show that Set8, like Cdt1, is degraded
in a DNA damage-induced manner independently of ATM
and ATR.
To address whether Set8 is a substrate of the CRL4Cdt2, we
used siRNA to knock down the components of this E3 ubiquitin
ligase. Compared to cells treated with control siRNA, cells
treated with siRNAs targeting Cdt2, Ddb1, or Cul4A exhibited
elevated levels of Set8 (Figures 1D and see Figure S1A available online). In contrast, knockdown of Ddb2, a substrate
receptor of the distinct CRL4Ddb2 E3 ligase, did not affect
Set8 levels (Figure S1B). Cdt2 siRNA did not affect the level
of Set8 mRNA (Figure S1C), excluding the possibility that the
increase in Set8 protein is due to transcriptional changes. In
cells treated with Cdt2 or Ddb1 siRNA, the UV-induced degradation of Set8 was significantly reduced as compared to that in
control cells (Figures 1E and Figure S1D). Taken together, these
results suggest that the CRL4Cdt2 E3 ligase downregulates the
24 Molecular Cell 40, 22–33, October 8, 2010 ª2010 Elsevier Inc.
E3 Ligase Targets Set8 for Degradation
(A) The Set8DPIP mutant lacks the two conserved
aromatic residues in the putative PIP degron.
(B) The Set8DPIP mutant is defective in binding to
PCNA and Cdt2. Flag-tagged Set8WT and Set8DPIP
were transiently expressed in U2OS cells and
immunoprecipitated with anti-Flag antibody. The
Set8, PCNA, and Cdt2 proteins in the immunoprecipitates and input extracts (2%) were analyzed by
western blotting.
(C) Set8 ubiquitylation is induced by UV. HeLa cells
stably expressing His/biotin-tagged ubiquitin and
control HeLa cells were treated with UV or left
untreated. Ubiquitylated proteins were captured
with streptavidin beads under denaturing condition. Ubiquitylated Set8 was detected with Set8
antibody. Asterisk indicates nonspecific proteins
bound to streptavidin beads and cross-reacted
with Set8 antibody.
(D) UV-induced Set8 ubiquitylation requires the
PIP degron. Cells expressing Flag-tagged Set8WT
or Set8DPIP were synchronized in G1, pretreated
with MG132 for 3 hr, and irradiated with UV. The
Set8 proteins were analyzed with anti-Flag antibody 2 hr post-UV treatment.
(E) The Set8DPIP mutant is more stable than Set8WT
after UV damage. U2OS cells with induced Flagtagged Set8WT or Set8DPIP were treated with UV,
and cultured in cycloheximide-containing media
for the indicated times. The levels of Flag-Set8
and tubulin were analyzed by western blotting.
overall level of Set8 in an asynchronous cell population and
mediates its degradation in response to DNA damage.
UV-Induced Set8 Degradation Is PIP Degron Dependent
To assess whether the putative PIP degron of Set8 is required
for its degradation, we disrupted the degron using point mutations. The two conserved aromatic residues in the PIP degron
of Cdt1 are essential for its binding to PCNA (Arias and Walter,
2006; Havens and Walter, 2009). To determine whether the
corresponding residues in the PIP degron of Set8 are functionally
important, we generated a Set8 point mutant lacking these residues (F184A, Y185A; referred to as Set8DPIP) (Figure 2A).
We first tested whether wild-type and mutant Set8 proteins
are able to associate with PCNA and Cdt2. Immunoprecipitation
of Flag-tagged Set8WT captured both PCNA and Cdt2, showing
that Set8 can interact with these proteins (Figure 2B). Consistent with a previous report (Jorgensen et al., 2007), Set8DPIP
failed to associate with PCNA (Figure 2B), confirming that this
PIP box of Set8 is critical for PCNA binding. Moreover, Cdt2
did not coprecipitate with Set8DPIP, suggesting that the PIP
box is also needed for Cdt2 binding. These results suggest
that the PIP degron of Set8, like that of Cdt1, is required for
its interactions with both PCNA and Cdt2. It should be noted
that Cdt1 interacts with Cdt2 only in the presence of DNAbound PCNA (Havens and Walter, 2009). Thus, the interaction
between Flag-Set8 and Cdt2 reported here might also be mediated by PCNA and DNA.
We next asked if the PIP degron of Set8 is required for
its degradation in response to DNA damage. In cells
�Molecular Cell
CRL4Cdt2 E3 Ligase Targets Set8 for Degradation
A
D
-
MMS damaged
DNA
PIP
WT
0 8 20 0 8 20
0 8 20
MG-132
0 15 30 0 15 30 0 15 30 0 15 30 min
*
*
GST-Flag-Set8
min
Cdt1
GST-Flag-Set8
GST-Flag-Set8
Cdt1
PCNA
E
F
B
GST-Flag-Set8
Mock
PCNA
-
0
8 20
PCNA
0 8 20
0
8
- +
+ +
rec. protein
20
Mock
Flag IP
from Chrom.
GST-Flag-Set8
Myc-Ub
Cdt2
no undamaged
DNA
DNA
90-
*
=Cdt2
min
GST-Flag-Set8
Myc
1701309572-
Set8-Ub
90-
Set8-Ub
72-
*
-Set8
-PCNA
32-
C
Mock
Cdt2
-
0
8 20
Cdt2
0
8 20
0
8
Ub
1701309572-
Set8
1701309572-
rec. protein
20
Set8-Ub
G
*
Flag IP
- WT P GST-Flag-Set8
min
Set8-Ub
GST-Flag-Set8
Set8-Ub
-Set8
=Cdt2
-Set8
-PCNA
*
Figure 3. CRL4Cdt2-Dependent and DNA Damage-Induced Set8 Degradation in Xenopus Egg Extracts
(A) DNA damage and proteasome-dependent destruction of Set8 in Xenopus egg extract. HSS was supplemented with human 50 nM GST-FLAG-Set8, as well as
buffer (no DNA), undamaged plasmid, MMS-damaged plasmid, and MG132, as indicated, and at different times, samples were blotted for GST (top panel) or Cdt1
(bottom panel).
(B) Recombinant GST-FLAG-tagged human Set8 (50 nM) was added to mock-depleted or PCNA-depleted HSS that was optionally supplemented with 5 mM
recombinant human PCNA. At the different times, samples were blotted for GST.
(C) Recombinant GST-Flag-tagged human Set8 (50 nM) was added to mock-depleted or Cdt2-depleted HSS that was optionally supplemented with 25 nM
recombinant human Cdt2, as indicated. At different times, samples were blotted for GST.
(D) HSS was supplemented with MMS-treated plasmid, as well as buffer, 50 nM GST-Flag-tagged Set8WT, or Set8DPIP. At different times, samples were blotted
for the indicated proteins.
(E) HSS was supplemented with 1 mg/ml Myc-Ubiquitin and MG132, as well as buffer or 50 nM GST-Flag-tagged Set8WT, as indicated. Immobilized, 1 kb MMS
DNA was added and after 10 min, chromatin was recovered from the extract. Chromatin-bound proteins were denatured to release them from chromatin then
diluted and immunoprecipitated with Flag antibody. The isolated material was blotted for Set8 (bottom panel), Ubiquitin (middle panel), or Myc (top panel).
(F) Immobilized, 1 kb MMS DNA was isolated from mock-depleted or Cdt2-depleted HSS, each of which was supplemented with 2 mg/ml methyl ubiquitin and
50 nM GST-Flag-tagged Set8 and incubated for 10 min. Samples were blotted for Cdt2, Set8, and PCNA.
(G) Methyl ubiquitin, GST-Flag-tagged Set8WT or Set8DPIP, and 5 ng/ml MMS plasmid DNA were added to HSS. Set8WT, Set8DPIP, and their associating proteins
were immunoprecipitated from total extract with Flag antibody, and the indicated proteins were analyzed by western blotting. Asterisk indicates a protein nonspecifically recognized by PCNA antibody.
expressing His/biotin-tagged ubiquitin, endogenous Set8 was
ubiquitylated and captured by streptavidin beads in a UVinduced manner (Figure 2C). Furthermore, Flag-tagged Set8WT,
but not Set8DPIP, underwent enhanced ubiquitylation after UV
treatment (Figure 2D). When transiently expressed in cells,
Set8WT was less stable than Set8DPIP after UV irradiation
(Figure S2). To more precisely measure the effects of PIP box
mutations on Set8 stability, we generated inducible cell lines
that express Flag-tagged Set8WT or Set8DPIP. We induced the
Set8 proteins to similar levels, treated cells with UV and cycloheximide, and monitored the stabilities of the Set8 proteins in
a time course. Set8DPIP was more stable than Set8WT after UV
irradiation (Figure 2E). These data suggest that UV-induced
Set8 ubiquitylation and degradation require the PIP degron of
Set8.
CRL4Cdt2 Mediates Set8 Degradation in Xenopus Egg
Extracts
To examine Set8 destruction in a biochemically tractable
system, we turned to Xenopus egg extracts, which recapitulate
the DNA replication and damage-dependent degradation of
Cdt1 by CRL4Cdt2 (Jin et al., 2006). As shown in Figure 3A,
Cdt1 was rapidly destroyed in a high-speed supernatant (HSS)
of Xenopus egg cytoplasm supplemented with plasmid DNA
that had been damaged with methyl methanesulfonate (MMS)
(Figure 3A, bottom panel) (Jin et al., 2006). Under the same
experimental conditions, GST-Flag-tagged human Set8 was
also rapidly degraded (Figure 3A, top panel). As seen for Cdt1,
Set8 degradation was induced by MMS-treated DNA, but not
by undamaged DNA or in the absence of DNA (Figure 3A),
showing that this is a DNA damage-dependent process.
Molecular Cell 40, 22–33, October 8, 2010 ª2010 Elsevier Inc. 25
�Molecular Cell
CRL4
Depletion of PCNA or Cdt2 efficiently prevented DNA damageinduced destruction of Set8 (Figures 3B and 3C and
Figure S3A). In each case, Set8 degradation was rescued by
reconstitution of the extracts with the corresponding recombinant protein (Figures 3B and 3C). Furthermore, Set8DPIP was
completely stable in egg extracts (Figure 3D, middle panel).
Therefore, human Set8 is degraded in Xenopus egg extracts in
a manner that depends on its PIP degron, PCNA, Cdt2, and
DNA damage.
When Set8WT was added to HSS, it bound to chromatin and
recruited CRL4Cdt2 (Figure S3B). Moreover, Set8 was ubiquitylated on the chromatin (Figures 3E), but this was reduced when
Cdt2 was depleted from HSS (Figure 3F). In contrast to Set8WT,
Set8DPIP did not bind chromatin efficiently (Figure S3B), failed to
recruit Cdt2 or Ddb1 to chromatin above background levels
(Figures S3C), and was not efficiently ubiquitylated (Figure 3G
and Figure S3C). Together, these results indicate that, like
Cdt1, Set8 docks onto chromatin-bound PCNA, recruits
CRL4Cdt2, and then undergoes ubiquitylation. Interestingly, addition of Set8WT but not Set8DPIP to HSS resulted in decreased
ubiquitylation of Cdt1 (Figure S3C), suggesting a competition
between the two CRL4Cdt2 substrates.
Set8 Is Degraded during S Phase
in a CRL4Cdt2-Dependent Manner
Having established that Set8 is a substrate of CRL4Cdt2 following
DNA damage, we next investigated whether Set8 is targeted for
destruction by CRL4Cdt2 during DNA replication, as suggested
by the elevated Set8 levels observed after silencing of CRL4Cdt2
components in unperturbed populations of asynchronous cells
(Figure 1D). We first synchronized cells in S phase with hydroxyurea (HU), and then briefly induced expression of Flag-Set8WT.
Once Flag-Set8WT became readily detectable, we stopped
Set8 induction and released cells from HU. As cells resumed
DNA replication after the release from HU, the levels of FlagSet8WT rapidly declined (Figure 4A; FACS profiles shown in
Figure S4A). This decline of Set8WT was inhibited by MG132
(Figure 4A), suggesting that Set8 is actively degraded by the proteasome in replicating cells. Consistently, endogenous Set8 was
rapidly degraded in S phase cells synchronously released from
a thymindine block (Figure 4B). Furthermore, Set8WT was also
rapidly degraded during chromosomal DNA replication in Xenopus egg extracts (Figure 4C). Geminin, which blocks replication
initiation via inhibition of Cdt1 function, prevented Set8WT
destruction in this setting, demonstrating that Set8 is degraded
in a replication-dependent manner in Xenopus egg extracts.
To test if the degradation of Set8 during DNA replication was
mediated by CRL4Cdt2, we monitored the effect of Cdt2 knockdown on the stability of endogenous Set8. Knockdown of Cdt2
but not Ddb2 significantly stabilized Set8 in replicating cells
(Figure 4B). To determine whether the PIP degron of Set8 is
needed for its degradation in S phase, we compared the stabilities of Set8WT and Set8DPIP during DNA replication. In Xenopus
egg extracts, the degradation of Set8 during DNA replication
was dramatically inhibited by mutations in the PIP degron
(Figure 4C). In human cells synchronously released from HU,
Set8DPIP was more stable than Set8WT (Figure S4B). Nonetheless, we noted that in replicating human cells, Set8DPIP was still
26 Molecular Cell 40, 22–33, October 8, 2010 ª2010 Elsevier Inc.
Cdt2
E3 Ligase Targets Set8 for Degradation
-
A
+
0 10 20 30 60 0 10 20 30 60
MG132
min post HU release
Flag-Set8
Tubulin
B
siRNA
Mock
0 30 60 90 120
Cdt2
0 30 60 90 120 min post thym release
endo Set8
Tubulin
siRNA
Mock
0 30 60 90 120
Ddb2
0 30 60 90 120 min post thym release
endo Set8
Tubulin
C
WT
PIP
GST-Flag-Set8
Geminin
0 40 90 0 40 90 0 40 90
min
GST-Flag-Set8
* Cdt1
*
Figure 4. PIP Degron-Mediated Set8 Degradation during DNA Replication
(A) Set8 is actively degraded by the proteasome in replicating cells. Cells
harboring inducible Flag-Set8 were synchronized in S phase with 1 mM HU
for 24 hr. During the last 4 hr of HU treatment, Flag-Set8 was induced, and
10 mM MG132 was added when indicated. Subsequently, cells were released
into HU-free and cycloheximide-containing media with or without MG132.
Set8 levels were analyzed in a time course by western blotting.
(B) Endogenous Set8 is stabilized by knockdown of Cdt2, but not Ddb2. Cells
transfected with siRNAs targeting Cdt2 or Ddb2 and cells mock transfected
were synchronized with thymidine and released into cycloheximide-containing
media. The levels of endogenous Set8 were analyzed at the indicated time
points by western blotting.
(C) Set8 is degraded in Xenopus egg extracts in a replication- and PIP degrondependent manner. Sperm chromatin was incubated with HSS for 30 min to
promote replication licensing. Subsequently, a highly concentrated nucleoplasmic extract (Walter et al., 1998) containing GST-Flag-tagged Set8WT or
Set8DPIP was added, which stimulated efficient replication initiation (data not
shown). At different times after NPE addition, the reactions were stopped
and samples were blotted for GST and Cdt1. In lanes 1–3, HSS was incubated
with 200 nM Geminin before addition of sperm chromatin.
degraded at a slow rate even when Cdt2 was knocked down
(Figures S4B and S4C), suggesting that a PIP degron- and
Cdt2-independent mechanism also contributes to Set8
�Molecular Cell
CRL4Cdt2 E3 Ligase Targets Set8 for Degradation
Figure 5. Forced Expression of Set8 Interferes with the Cell Cycle
(A) Forced Set8 expression slows cell proliferation. U2OS cells harboring inducible Flag-tagged Set8WT, Set8DPIP, Set8DPIP,CD, or the parental cell line were
cultured in the absence or presence of 0.1 mg/ml tetracycline (Tet). The total cell numbers at the indicated time points were plotted. Error bars indicate the standard deviation of three independent experiments.
(B) Constitutive Set8 expression leads to reduced DNA synthesis and accumulation of cells in G2/M. Cells were cultured for 48 hr with or without Set8 induction.
Cell-cycle profiles (left panel) and BrdU incorporation (right panel) were analyzed by FACS. Error bars indicate the standard deviation of three independent experiments.
(C) Constitutive expression of Set8 elicits the ATR checkpoint. Cells were cultured for 48 hr with or without Set8 induction. The levels of Set8, phospho-Chk1
(Ser345), Chk1, and phospho-H3 (Ser10) were analyzed by western blotting.
(D and E) Overexpression of Set8 prior to S phase inhibits mitotic entry. Cells were synchronized in mitosis with 100 ng/ml nocodazole and then released into
media containing 2 mM thymidine. Where indicated, Set8 was induced after the release from nocodazole. Cells synchronized at G1/S were then released
from thymidine in the absence of Tet. Cell-cycle profiles are shown in (D), and protein levels of Flag-Set8, phospho-H3, and tubulin were analyzed by western
blotting in (E).
destruction (see the Discussion). Taken together, these results
suggest that CRL4Cdt2 plays an important role in repressing
Set8 levels during S phase.
Forced Expression of Set8 Induces Replication Stress
To understand why Set8 is downregulated during S phase, we
sought to override this mechanism. When Set8WT was constitutively expressed at high levels, cell proliferation gradually slowed
down (Figure 5A). FACS analysis of cells expressing Set8WT
revealed an increase in the population of S and G2/M phase cells
(Figure 5B, left panel). BrdU labeling confirmed that the population of replicating cells was increased upon Set8WT induction
(Figure 5B, right panel). Moreover, for cells that were in S phase
based on DNA content, the incorporation of BrdU was clearly
less efficient when Set8WT was induced relative to control cells
(Figure 5B, right panel). These results suggest that constitutive
Set8 expression interferes with DNA synthesis, leading to accumulation of cells in S phase and G2/M.
The reduction in DNA synthesis and accumulation of cells in S
and G2/M prompted us to investigate whether the ATR-mediated replication checkpoint was activated by forced Set8WT
expression. Indeed, when Set8WT was induced for 48 hr in asynchronous cells, the level of phospho-Chk1 (Ser345), a marker of
ATR activation, was significantly increased (Figure 5C). Furthermore, consistent with compromised DNA replication and/or
checkpoint-mediated cell-cycle arrest prior to mitosis, the levels
of phospho-H3 were reduced (Figure 5C). These results provide
further evidence that aberrant expression of Set8 interferes with
proper DNA replication and activates the ATR checkpoint.
Since Set8 is known to function in mitosis, overexpression
of Set8 may affect M phase and indirectly impact the subsequent S phase. To rule out this possibility, we synchronously
released cells from a nocodazole block in mitosis, transiently
induced Set8 expression, and arrested cells at the G1/S
transition with thymidine. When cells were released into S phase
with high levels of Set8, they progressed through S phase more
slowly, as shown by FACS analysis (Figures 5D). Furthermore,
cells with induced Set8 did not accumulate phospho-H3
(Ser10), indicating a failure to enter mitosis (Figure 5E). These
results suggest that forced expression of Set8 prior to S phase
interferes with DNA replication and prevents timely entry into
mitosis.
Molecular Cell 40, 22–33, October 8, 2010 ª2010 Elsevier Inc. 27
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A
B
HU
-/+Tet
-Tet
Time points
Cdt2
E3 Ligase Targets Set8 for Degradation
Figure 6. Expression of the Set8DPIP Mutant
Induces Premature H4K20me1 Accumulation
Acid Fraction
(A) Constitutive expression of the Set8DPIP mutant
leads to a dramatic loss of S phase cells and accumulation of G2/M cells. Shown are cell-cycle
profiles and BrdU incorporation of cells expressing Set8WT or Set8DPIP for 48 hr. Error bars indicate
the standard deviation of three independent
experiments.
(B–D) Expression of the DPIP mutant prevents
mitotic entry after release from HU arrest. In (B),
cells harboring inducible Set8WT or Set8DPIP were
synchronized in S phase with HU for 24 hr. During
the last 4 hr in HU, expression of Set8WT or
C
D
WT PIP Flag-Set8
Set8DPIP was induced. Subsequently, cells were
released from HU in the absence of Tet, and the
H3S10p
levels of the indicated proteins in whole-cell
H3
extracts were analyzed by western blotting. In
(C), Set8DPIP,CD cells were included. Experiment
H4K20me1
was performed as in (B), except that cells were
H4K20me2
released into media containing nocodazole to
trap mitotic cells. Where indicated, caffeine was
H4K20me3
added at 5 mM to bypass ATM/ATR-mediated
H4
checkpoint response. Twenty-four hours after
HU release, phospho-H3-positive mitotic cells
were scored by FACS. Error bars indicate standard deviation, and asterisk indicates p < 0.005 by Student’s t test. In (D), experiment was performed as in (B),
except that 4 hr after HU release, chromatin-bound histones were extracted with acid and analyzed by western blotting.
The Set8DPIP Mutant Is a Potent Inhibitor of the Cell
Cycle
Although induction of wild-type Set8 interferes with the cell
cycle, this approach may not fully capture the effects of Set8
stabilization because even the induced Set8WT is rapidly
degraded (Figure 4). To more specifically address the role of
CRL4Cdt2-mediated Set8 degradation, we induced expression
of Set8WT and Set8DPIP and compared their effects on the cell
cycle. Compared to Set8WT, Set8DPIP induced a much more
prominent increase in G2/M cells (Figure 6A). Furthermore,
expression of Set8DPIP dramatically reduced the BrdU-positive
cells, suggesting that cells were trapped outside of S phase
(Figure 6A and Figure S5A). Consistent with its effects on the
cell cycle, Set8DPIP reduced cell proliferation even more dramatically than Set8WT (Figure 5A). Thus, Set8 is a potent inhibitor of
the cell cycle when the PIP degron is disrupted.
To determine whether the effects of Set8DPIP on the cell cycle
are dependent upon its catalytic activity, we generated a catalytically ‘‘dead’’ Set8DPIP, CD double mutant (Nishioka et al., 2002).
In marked contrast to Set8DPIP, Set8DPIP, CD did not induce
a G2/M arrest (Figure 6C), nor did it inhibit cell proliferation (Figure 5A). These results show that Set8DPIP remains catalytically
active in cells, and that its activity is necessary for the induction
of cell-cycle arrest.
and released the cells. As cells resumed DNA replication, the
levels of phospho-Chk1 gradually declined (Figure 6B and
Figure S5B). In cells with Set8DPIP, Chk1 was phosphorylated
to higher levels in thymidine and HU, and phospho-Chk1 persisted for longer after cells resumed replication (Figure 6B and
Figure S5B). Despite the persistent Chk1 phosphorylation, cells
with Set8DPIP progressed through S phase without obvious delay
(data not shown). However, both FACS and western blotting
analyses showed that while cells with Set8WT gradually entered
mitosis and accumulated phospho-H3 over time, cells with
Set8DPIP failed to accumulate significant levels of this mitotic
mark (Figure 6B and Figures S5B and S5C). Thus, when briefly
expressed in S phase cells, Set8DPIP does not arrest replication
but leads to a robust G2 arrest.
The modest but persistent Chk1 phosphorylation induced by
Set8DPIP during S phase suggests that although DNA replication
can proceed, the process is not normal. Although the effects of
Set8DPIP are not sufficient to halt replication, they may contribute
to the subsequent G2 arrest. Indeed, in the presence of caffeine,
an inhibitor of ATM and ATR, the G2 arrest induced by Set8DPIP
was significantly bypassed (Figure 6C). Importantly, the catalytically inactive Set8DPIP,CD mutant did not induce a G2 arrest
(Figure 6C), showing that the catalytic activity of Set8DPIP is
needed to trigger the checkpoint.
The Set8DPIP Mutant Triggers a Checkpoint-Mediated
G2 Arrest
The loss of cells in S phase and accumulation of cells in G2/M
indicates that Set8DPIP may interfere with DNA replication and/
or the G2/M transition. To assess this possibility, we synchronized cells in S phase with double-thymidine block or HU, briefly
induced Set8WT or Set8DPIP, and then terminated the induction
The Set8DPIP Mutant Leads to Aberrant H4K20me1
Accumulation during DNA Replication
As cells resumed DNA replication after the release from HU or
thymidine, H4K20me1 accumulated significantly faster in cells
expressing Set8DPIP than in cells expressing Set8WT (Figures
6B and 6D and Figures S5B and S5C). In cells expressing
Set8WT, the levels of H4K20me1 rose shortly before mitosis,
28 Molecular Cell 40, 22–33, October 8, 2010 ª2010 Elsevier Inc.
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CRL4Cdt2 E3 Ligase Targets Set8 for Degradation
PCNA
H4K20me1
merge
Figure 7. The Set8DPIP Mutant Induces
Aberrant Chromatin Compaction in Replicating Cells
DAPI
PIP,CD
PIP
WT
A
C
B
K20me1
D
PCNA
WT
Tet:
-
merge
PIP
+
-
DAPI
PIP,CD
+
-
+
F
E
chromatin
WT
PIP
Flag-Set8
CAP-D3
CAP-G2
Set8
PCNA
and the levels of H4K20me2/me3 increased modestly following
H4K20me1 accumulation (Figures S5B and S5C). In cells
expressing Set8DPIP, the levels of H4K20me1 rose in S phase,
whereas the levels of H4K20me2/me3 did not change significantly even after cells were arrested in G2 (Figure 6D and Figures
S5B and S5C). These results suggest that H4K20me1 is the
primary, if not the only, form of H4K20 methylation that is rapidly
induced by Set8DPIP during S phase.
We also examined the accumulation of H4K20me1 by immunostaining in cells expressing Set8WT or Set8DPIP. In cells
expressing Set8WT, PCNA staining and H4K20me1 staining
were mutually exclusive (Figure 7A and Figure S6A), consistent
with the degradation of Set8 in replicating cells and its accumulation in G2/M. In marked contrast, a significant fraction of S
phase cells expressing Set8DPIP were positive for both PCNA
and H4K20me1 (Figure 7A and Figure S6A). In addition, a fraction
of the Set8DPIP cells labeled with EdU were positive for
(A) Transient expression of the DPIP mutant in
S phase cells leads to aberrant costaining of
PCNA and H4K20me1. Cells were arrested in
S phase with HU for 24 hr, and Set8WT or Set8DPIP
was transiently induced during the last 4 hr. Cells
were subsequently released from HU and were
stained with antibodies to PCNA and H4K20me1
4 hr after HU release.
(B) Colocalization of PCNA and H4K20me1 in the
replicating cells that express Set8DPIP.
(C) Knockdown of Cdt2, but not Ddb2, leads to
accumulation of H4K20me1 in PCNA-positive
cells. Cells were transfected with siRNAs targeting
Cdt2 and Ddb2, or mock treated. The levels of
H4K20me1 and PCNA were analyzed by immunostaining. The averages of at least two independent experiments are plotted and error bars
indicate standard deviation.
(D and E) The Set8DPIP mutant reduces the
distance between two loci on chromosome 16
in replicating cells. Cells were synchronized
and induced to express Set8WT, Set8DPIP, or
Set8DPIP,CD as in (A), and released for 6 hr. Dual
colored FISH probes were used to visualize 16q22
and 16p13. Representative images of the two loci
are shown in (D). The distances between the two
loci in the indicated cell populations were measured
using confocal microscopy (see the Experimental
Procedures). Distances were normalized to the
uninduced population of the same cell line, and
the average of three independent experiments is
plotted in (E). Error bars indicate standard deviation. *p < 0.05 and **p < 0.001 by Student’s t test.
(F) The Set8DPIP mutant promotes premature
binding of condensin II to chromatin in S phase.
Cells expressing Set8WT or Set8DPIP were synchronized and released as in (A), and were subjected to
chromatin fractionation 6 hr after HU release. The
levels of CAP-D3, CAP-G2, Set8, and PCNA in
chromatin fractions were analyzed by western
blotting.
H4K20me1, showing that this histone mark is aberrantly
established in cells undergoing replication (Figure S6B). Furthermore, PCNA and H4K20me1 significantly colocalized with each
other in cells containing Set8DPIP (Figure 7B), indicating that
H4K20me1 prematurely accumulated at or around replication
forks. In contrast to Set8DPIP, Set8DPIP,CD did not promote
H4K20me1 accumulation in PCNA-positive cells (Figure 7A
and Figure S6A), indicating that the ability of Set8DPIP to induce
H4K20me1 in replicating cells is dependent upon its catalytic
activity.
To determine whether stabilization of endogenous Set8 in S
phase promotes premature H4K20me1 accumulation, we monitored the effects of Cdt2 knockdown on the levels of H4K20me1
in PCNA-positive cells. Knockdown of Cdt2 led to a significant
increase in the PCNA-positive cells with high levels of
H4K20me1 (Figure 7C and Figure S6C), suggesting that stabilization of endogenous Set8 is sufficient to promote H4K20me1
Molecular Cell 40, 22–33, October 8, 2010 ª2010 Elsevier Inc. 29
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Cdt2
E3 Ligase Targets Set8 for Degradation
accumulation in otherwise unperturbed, replicating cells. Similar
premature H4K20me1 accumulation was induced by Ddb1
knockdown, but not by Ddb2 knockdown (Figure 7C and
Figure S6C). In addition, a significant fraction of the Cdt2 knockdown cells with high H4K20me1 displayed phospho-RPA32 foci,
indicating a link between aberrant H4K20me1 accumulation and
activation of the ATM and/or ATR checkpoint kinases (Figures
S6D and S6E).
nents of condensin II, to chromatin in replicating cells (Figure 7F),
consistent with a recent report that CAP-D3 binds H4K20me1
(Liu et al., 2010).
Together, the experiments above present four independent
lines of evidence that Set8 stabilization during S phase leads
to premature chromatin compaction.
Set8DPIP Induces Premature Chromatin Compaction
in Replicating Cells
H4K20me1 is a histone mark important for chromatin compaction, and its accumulation in mitosis is associated with chromatin
condensation (Oda et al., 2009; Rice et al., 2002; Trojer et al.,
2007). The premature accumulation of H4K20me1 in cells
expressing Set8DPIP suggested that chromatin may be aberrantly compacted during S phase. To assess this possibility,
we first used dual color FISH and confocal microscopy to
measure the distance between two loci on chromosome 16
(16q22 and 16p13). In synchronously replicating cells, the
average distance between the two loci was significantly reduced
by Set8DPIP (Figures 7D and 7E). Compared to Set8DPIP, Set8WT
reduced the distance to a lesser extent, and Set8DPIP,CD did not
affect the distance at all (Figures 7D and 7E). These results
suggest that the presence of Set8 activity during S phase
promotes chromatin compaction.
In a second approach to monitor the effects of Set8 stabilization on chromatin compaction, we analyzed the association of
linker histone H1 with chromatin by salt extraction. Coincident
with the premature accumulation of H4K20me1 in Set8DPIP cells
6 hr after the release from HU (Figure 6B), H1 was less extractable in Set8DPIP cells than in Set8WT cells (Figure S6F, left panel,
lanes 4 and 5, 9 and 10), indicating that H1 is more tightly bound
to chromatin in the replicating cells with Set8DPIP.
To further confirm the effects of Set8 stabilization on chromatin compaction, we analyzed chromatin using micrococcal
nuclease (MNase). When Set8DPIP was induced in S phase cells,
it reduced the levels of mononucleosomes generated by partial
MNase digestion (Figure S6G, left panel, compare mononucleosomes in lanes 2 and 3 versus lanes 6 and 7). The ratio of monoto dinucleosomes was lower in Set8DPIP-expressing cells than in
control cells after 15 min of MNase digestion (Figure S6G, left
panel, lanes 2 and 6, and lower panel). Furthermore, after a longer
MNase digestion, more nucleosomes remained in the di- and trinucleosome states in Set8DPIP-expressing cells (Figure S6G, left
panel, lanes 4 and 8). These results suggest that Set8DPIP
renders chromatin more compacted than Set8WT. In contrast
to Set8DPIP, Set8DPIP,CD had no effect on MNase cleavage
(Figure S6G, right panel), suggesting that the ability of Set8DPIP
to promote chromatin compaction is dependent on its catalytic
activity.
To understand how Set8 stabilization promotes aberrant chromatin compaction in S phase cells, we tested the possibility that
condensin was prematurely recruited to chromatin during replication. The binding of condensin II to chromatin in prophase is
the initial event that triggers normal mitotic chromatin condensation (Hirota et al., 2004). Expression of Set8DPIP in S phase led to
increased binding of CAP-D3 and CAP-G2, two specific compo-
Role of CRL4Cdt2 as a Coordinator of DNA Replication
and Chromatin Compaction
The CRL4Cdt2 complex is a unique E3 ubiquitin ligase that specifically recognizes targets bound to PCNA on chromatin. This
unique property of CRL4Cdt2 confers upon it the ability to ubiquitylate substrates and target them for degradation in a replicationcoupled manner, suppressing cell-cycle events that are
incompatible with ongoing DNA synthesis. During S phase,
CRL4Cdt2 degrades the licensing factor Cdt1, and promotes
the nuclear export of another licensing factor Cdc6 by degrading
the CDK inhibitor p21 (Abbas et al., 2008; Arias and Walter, 2006;
Jin et al., 2006; Kim et al., 2007, 2008; Nishitani et al., 2006, 2008;
Sansam et al., 2006; Zhong et al., 2003). Thus, by restricting
origin licensing to G1, CRL4Cdt2 plays a key role in coordinating
G1 and S phases. Our results suggest that CRL4Cdt2 has another
important role in coordinating S phase and mitosis. By suppressing Set8 function during S phase, CRL4Cdt2 ensures the orderly
execution of DNA replication and H4K20me1-mediated chromatin compaction (Figure S6H). Failure to degrade Set8 in S
phase leads to premature chromatin compaction in replicating
cells, which appears to interfere with DNA synthesis and
prevents proper entry into mitosis. Together with the previous
studies on CRL4Cdt2, our findings suggest that CRL4Cdt2 is
a key factor that coordinates DNA replication with other cellcycle events before and after S phase.
30 Molecular Cell 40, 22–33, October 8, 2010 ª2010 Elsevier Inc.
DISCUSSION
CRL4Cdt2- and PCNA-Mediated Degradation of Set8
The mechanism by which Set8 is ubiquitylated is remarkably
similar to that of Cdt1. In S phase and after DNA damage,
destruction of both Set8 and Cdt1 is promoted by CRL4Cdt2.
Moreover, the PIP degron of Set8 closely resembles that of
Cdt1. Finally, as seen for the interaction between Cdt1 and
CRL4Cdt2, Set8 and CRL4Cdt2 appear to assemble into a complex
only in the context of chromatin-bound PCNA. In support of this
model, we find that in egg extracts, the addition of Set8 leads to
PIP box-dependent recruitment of CRL4Cdt2 onto chromatin. In
addition, in mammalian cells, coimmunoprecipitation of Cdt2
and Set8 is dependent on the Set8 PIP box, and in egg extracts,
the interaction between Set8 and Cdt2 requires the presence of
DNA (data not shown). In summary, both Cdt1 and Set8 are
degraded via a mechanism that involves docking of their PIP
degrons onto chromatin-bound PCNA, followed by degrondependent recruitment of CRL4Cdt2 and ubiquitylation.
Although Set8DPIP is significantly stabilized after DNA damage,
its degradation in S phase cells is delayed but not abolished.
These features of Set8 degradation in human cells also resemble
those of Cdt1 (Nishitani et al., 2006; Senga et al., 2006), and they
suggest that during S phase, Set8 can be degraded by a PIP
degron-independent mechanism. In addition to CRL4Cdt2, the
�Molecular Cell
CRL4Cdt2 E3 Ligase Targets Set8 for Degradation
CRL1Skp2 is implicated in the downregulation of Cdt1 (Kondo
et al., 2004; Li et al., 2003), and it may play a secondary role in
suppressing Cdt1 during S phase (Nishitani et al., 2006; Senga
et al., 2006; Takeda et al., 2005). Interestingly, knockdown of
Skp2 leads to cell-cycle arrest at the G1/S transition and
elevated levels of Set8 (Yin et al., 2008). In our immunostaining
analysis of unperturbed cycling cells, we noticed that a fraction
of the PCNA-negative cells contained low levels of H4K20me1
(data not shown), suggesting that a PCNA-independent mechanism may suppress Set8 function outside of S phase. Since both
Set8 and H4K20me1 accumulate during G2 and M phases, it is
possible that Set8 is suppressed in G1. Consistent with this
possibility, the levels of Set8 start to decline in G1 following
nocodazole release (Huen et al., 2008; Yin et al., 2008). Our
results suggest that while the CRL4Cdt2-mediated degradation
of Set8 is a critical mechanism that defines the functional
window of Set8 during the cell cycle, additional mechanisms
may exist.
The Need for Set8 Degradation during S Phase
Set8 promotes the accumulation of H4K20me1 during G2 and
mitosis and is important for proper chromatin condensation
(Houston et al., 2008; Oda et al., 2009; Sakaguchi and Steward,
2007). As cells exit from mitosis, the level of H4K20me1 rapidly
declines and reaches its lowest point in early S phase (Huen
et al., 2008; Oda et al., 2009). We found several lines of evidence
that Set8 activity is incompatible with DNA replication. First,
constitutive expression of Set8WT reduces DNA synthesis and
triggers the ATR checkpoint response. Second, prolonged
expression of the stabilized Set8DPIP mutant leads to a dramatic
loss of replicating cells. Third, even when transiently expressed
in S phase cells, the Set8DPIP mutant induces premature
H4K20me1 accumulation near DNA replication forks and triggers
a checkpoint-mediated G2 arrest. Importantly, the ability of
Set8DPIP to induce aberrant H4K20me1 accumulation and to
activate the checkpoint is dependent upon its catalytic activity.
Thus, if Set8 is not degraded by CRL4Cdt2 during S phase, it
interferes with DNA replication by monomethylating H4K20 in
a PIP box-independent manner. Set8 has affinity for the
N terminal tail of H4 with acetylated K5, K8, and K12 (Yin et al.,
2008). Because newly synthesized H4 is hyperacetylated at K5
and K12, Set8, if not degraded during ongoing DNA synthesis,
could be recruited to the newly assembled chromatin at replication forks. Consistent with the idea that aberrant H4K20me1
accumulation compromises DNA replication, loss of Suv420h1/2, the methyltransferases that convert H4K20me1 to
H4K20me2/3, leads to genomic instability and defects in
S phase (Schotta et al., 2008). Similarly, ablation of PHF8, an
H4K20me1 demethylase, leads to a reduction of cells in S phase
and accumulation of cells at G2/M (Liu et al., 2010).
Why is aberrant H4K20me1 accumulation in S phase
a problem for the cell cycle? H4K20me1 is specifically recognized by the chromatin compaction factor L3MBTL1 and condensin II component CAP-D3 (Liu et al., 2010; Trojer et al.,
2007). The aberrant H4K20me1 accumulation around replication
forks may lead to local chromatin compaction that interferes with
fork progression and/or other replication-coupled cellular
events. Consistent with this possibility, we found multiple lines
of evidence of premature chromatin compaction in S phase cells
expressing the stabilized Set8DPIP mutant. Coincident with
premature chromatin compaction, Set8DPIP elicited Chk1 phosphorylation during S phase and triggered a checkpoint-mediated
G2 arrest. Furthermore, phospho-RPA foci were detected in
Cdt2 knockdown cells with high H4K20me1, indicating that
RPA-coated single-stranded DNA, a key structure for ATR
activation, was induced by aberrant chromatin compaction
(Zou and Elledge, 2003). These findings suggest that aberrant
H4K20me1 accumulation not only compromises genome
duplication but also impedes mitotic entry. In addition to its
immediate impact on S phase and mitotic entry, aberrant
H4K20me1 accumulation may have additional effects on the
cell cycle through transcription repression (Congdon et al.,
2010; Liu et al., 2010; Trojer et al., 2007). It remains possible
that Set8 has substrates other than H4K20, whose aberrant
methylation during S phase contributes to the faulty mitotic
entry.
To ensure orderly cell-cycle progression, mitotic events must
not occur prematurely during the cell cycle. Thus, the key mitotic
regulator Cdk1-Cyclin B is fully activated only after S phase is
completed (O’Farrell, 2001). In addition, the ATR-mediated
checkpoint pathway monitors DNA replication and prevents
premature chromatin condensation (Brown and Baltimore,
2000; Nghiem et al., 2001). This study shows that the process
of DNA replication itself, via the PCNA and CRL4Cdt2-mediated
degradation of Set8, plays an active role in delaying chromatin
compaction until S phase is completed. We expect that in the
future, other substrates of CRL4Cdt2 will emerge whose presence
in S phase is incompatible with the proper execution of DNA
replication.
EXPERIMENTAL PROCEDURES
Cell Culture, Cell Synchronization, and Drug Treatments
U2OS, HeLa, and 293T cells were cultured in Dulbecco’s modified Eagle’s
medium (DMEM) with 10% fetal bovine serum. U2OS-TR, RCZ11, RCZ23,
and RCZ29 cells were cultured in DMEM with 10% serum and 50 mg/mL
hygromycin (Invitrogen). Protein expression from stable cell lines was induced
with 0.1 mg/mL tetracycline (Sigma). Zeocin (Invitrogen) was used for clonal
selection at 100 mg/mL. To synchronize cells in S phase, 1 mM HU (Sigma)
was added for 20–24 hr. For G1/S synchronization, cells were arrested in
mitosis with 100 ng/mL nocodazole (Sigma), washed thoroughly with PBS,
and released into media containing 2 mM thymidine (Sigma). Alternatively,
cells were synchronized by standard double thymidine block. To measure
protein stability, cycloheximide and MG132 (Sigma) were used at 100 mg/mL
and 10 mM, respectively. Kinase inhibitors UCN-01 and wortmannin (Sigma)
were used at 1 and 100 mM, respectively. For all experiments involving ultraviolet radiation exposure, 50 J/m2 UV was used.
Antibodies and Immunological Techniques
Antibodies used for western blotting were from Millipore (Set8), Upstate (phospho-H3), Abcam (H4K20me1, H3, CAP-D3, CAP-G2), Active Motif (H1, H4,
H4K20me2, H4K20me3), Cell Signaling Technologies (Cul4A, Tubulin, phospho-Chk1), Santa Cruz (Chk1), Bethyl (Cdt1, DDB1, Cdt2), Novus (Cdt2),
Sigma (Flag), Chemicon (PCNA). Horseraddish peroxidease-conjugated
secondary antibodies were from Jackson ImmunoResearch. For immunofluorescence studies, antibodies used were from Abcam (PCNA), Bethyl (phospho-RPA32), and Active Motif (H4K20me1). Flag immunoprecipitations were
performed with Flag M2-conjugated agarose beads (Sigma) in NETN buffer
Molecular Cell 40, 22–33, October 8, 2010 ª2010 Elsevier Inc. 31
�Molecular Cell
CRL4
containing 20 mM Tris-HCl (pH 8.0), 120 mM NaCl, 1 mM EDTA, 0.5% NP-40,
and protease inhibitor cocktail (Sigma).
Dual Color FISH
Cells were harvested and incubated in hypotonic buffer (0.59% KC1) for 30 min
at 37� C, fixed in ice-cold 3:1 MeOH:acetic acid, and spread on glass slides.
Slides were prepared for FISH using fluorescently labeled probes specific
for the arms of chromosome 16 (16q22, red; 16p13, green) according to the
manufacturer’s instructions (Cytocell; Cat# LPH 022). Coverslips were
mounted and DNA was detected with 0.2 mg/ml DAPI/antifade solution (Cytocell). Fluorescent images were captured with a Hamamatsu Orca AG cooled
CCD camera mounted on a Nikon TI/Yokagawa CSU-10 spinning disk
confocal microscope with a 1003, 1.4 NA objective. A series of 0.25 mm optical
sections were collected in the z axis for each channel (DAPI, fluorescein, and
Texas red). Inter- and intrachromosome distances under each condition were
measured with Slidebook analysis software. Approximately 25–40 intrachromosome distances were measured for each condition for each of three biological replicates.
Additional information can be found in the Supplemental Experimental
Procedures.
SUPPLEMENTAL INFORMATION
Supplemental Information includes Supplemental Experimental Procedures,
Supplemental References, and six figures and can be found with this article
online at doi:10.1016/j.molcel.2010.09.015.
ACKNOWLEDGMENTS
We thank Drs. Michelle Longworth, James Rocco, William Michaud, Ronald
Lebofsky, and Puck Knipscheer for reagents; Dr. Marie Classon and members
of the Zou lab for helpful discussions; and Dr. Anindya Dutta for communicating unpublished results. This work is supported by National Institutes of
Health (NIH) grants GM076388 (to L.Z.), GM080676 (to J.C.W.), and
GM081607 (to N.J.D.). J.J. is a Pew Scholar and supported by a grant
(AU-1711) from the Welch Foundation. R.C.C. and C.G.H. are supported by
the NIH fellowships F32-GM089150 and F32-GM082014, respectively.
A.L.M. and R.L.F. are supported by postdoctoral fellowships from the American Cancer Society.
Received: July 29, 2010
Revised: August 13, 2010
Accepted: September 16, 2010
Published: October 7, 2010
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