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Molecular and Cellular Biology, November 2000, p. 7922-7932, Vol. 20, No. 21
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Schizosaccharomyces pombe Hsk1p Is a
Potential Cds1p Target Required for Genome Integrity
Hilary A.
Snaith,1,
Grant W.
Brown,2 and
Susan L.
Forsburg1,*
Molecular Biology and Virology Laboratory,
The Salk Institute for Biological Studies, La Jolla, California
92037-1099,1 and Department of
Biochemistry, University of Toronto, Toronto, Ontario, Canada M5S
1A82
Received 15 May 2000/Returned for modification 11 July
2000/Accepted 15 August 2000
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ABSTRACT |
The fission yeast Hsk1p kinase is an essential activator of DNA
replication. Here we report the isolation and characterization of a
novel mutant allele of the gene. Consistent with its role in the
initiation of DNA synthesis, hsk1ts genetically
interacts with several S-phase mutants. At the restrictive temperature,
hsk1ts cells suffer abnormal S phase and loss
of nuclear integrity and are sensitive to both DNA-damaging agents and
replication arrest. Interestingly, hsk1ts
mutants released to the restrictive temperature after early S-phase arrest in hydroxyurea (HU) are able to complete bulk DNA synthesis but
they nevertheless undergo an abnormal mitosis. These findings indicate
a second role for hsk1 subsequent to HU arrest. Consistent with a later S-phase role, hsk1ts is
synthetically lethal with 
rqh1 (RecQ helicase) or
rad21ts (cohesin) mutants and suppressed by
cds1 (RAD53 kinase) mutants. We demonstrate that Hsk1p
undergoes Cds1p-dependent phosphorylation in response to HU and that it
is a direct substrate of purified Cds1p kinase in vitro. These results
indicate that the Hsk1p kinase is a potential target of Cds1p
regulation and that its activity is required after replication
initiation for normal mitosis.
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INTRODUCTION |
Eukaryotic cells have developed
elaborate regulatory mechanisms to ensure that DNA replication is
restricted to S phase and occurs just once per cell cycle. An important
component of this regulation is the coordination of multiple origins of
replication. Data from many systems have provided a model of the
initiation of DNA synthesis in which several multiprotein complexes
interact with discrete replication origins in a specific temporal
pattern to regulate entry into S phase (24, 26, 32). Two
protein kinase complexes are required to activate the replication
origins: cyclin-cyclin-dependent kinase (CDK), which acts both
positively and negatively to control origin function (21,
22), and the product of the hsk1+ (also
called CDC7) gene complex.
Schizosaccharomyces pombe hsk1+ is a member of
the conserved family of CDC7 protein kinases (23, 37). The
hsk1+ gene was originally cloned by its sequence
homology to budding yeast CDC7 and is essential for
viability (36). Spores with hsk1+
deleted are able to germinate but fail to undergo DNA replication, demonstrating that Hsk1p is required for cell cycle progression. Hsk1p
is dependent on the transient expression of a regulatory subunit, Dfp1p
(also called Him1p), for activity towards its substrates (6,
56). Similar to Hsk1p, Dfp1p is also part of a multimember family, founded by the Saccharomyces cerevisiae DBF4 gene,
and homologues have now been identified in many other species,
including Drosophila melanogaster and humans (23,
31). Dfp1p (homologous to Dbf4) is expressed only during late
G1 phase until mitosis, thereby restricting Hsk1p activity
to S phase and subsequent stages of the cell cycle. Genetic and
biochemical evidence indicates that the conserved MCM proteins are
important Hsk1p substrates. S. pombe, S. cerevisiae, Xenopus laevis, and human CDC7 kinases phosphorylate Mcm2 in vitro (23, 48). Also, a recessive
mutation in S. cerevisiae mcm5 (also called
cdc46) bypasses the requirement for CDC7 entirely
(20) and there are synthetic interactions between a strain
with a mutation in the Cdc7 regulatory subunit, encoded by
DBF4, or mcm2 mutants (33).
In addition to having a role in replication initiation, the fission
yeast hsk1 mutant also has phenotypes suggesting a role in checkpoint responses. While most hsk1 spores arrest
with a predominantly 1C DNA content and fail to progress into the cell cycle, approximately 25% of these germinated cells go on to attempt an
aberrant mitosis, generating "cut" cells (36). This
phenotype is typical of mutants that fail to initiate any DNA
replication; once replication is initiated, the checkpoint is activated
to prevent inappropriate mitosis (28).
The DNA replication and damage checkpoint responses in fission yeast
require two kinases acting downstream of the Rad3p kinase: Cds1p (the
S. pombe homologue of S. cerevisiae Rad53) and
Chk1p (8, 44). rad3+ encodes the
homologue of the metazoan ATM and ATR genes and
is activated by a range of cellular insults, including UV irradiation and nucleotide depletion (8). The Cds1p and Chk1p kinases
then act to inhibit cyclin-CDK activity, thereby preventing mitotic progression.
The replication checkpoint has been extensively investigated using
hydroxyurea (HU), an inhibitor of ribonucleotide reductase, which halts
replication due to lack of nucleotides (3). Cds1p appears to
respond to early replication defects such as those induced by HU and is
required for cells to recover from S-phase arrest (35, 39).
Cells lacking cds1 arrest in early S phase upon HU treatment
but do not enter mitosis. However, they are defective in return to
growth, indicating that Cds1p has a role specifically in recovery from
S-phase arrest, rather than in prevention of mitosis. Studies suggest
that Dfp1p is directly involved in the Cds1p-mediated response to
replication arrest. Dfp1p is phosphorylated in vivo upon incubation of
the cells with HU, and this phosphorylation depends on active Cds1p
(6, 56). In addition, dfp1 mutants that lack a
conserved motif in the amino terminus have a mild HU sensitivity and
display a cut phenotype after prolonged incubation in HU
(56). In budding yeast, Rad53 is required for the
phosphorylation of Dbf4 in response to HU (11, 62) and may
influence Cdc7 activity at late origins (46, 51).
Interestingly, cds1+ is not an essential gene in
fission yeast, in contrast to RAD53, which is required for
viability in budding yeast (29, 39, 59), suggesting that
there may be differences between the two yeasts in the response to
replication arrest.
To further examine the role of hsk1+ in fission
yeast S phase, we isolated a novel temperature-sensitive allele of the
gene. We show that the mutant strain exhibits defects in both DNA
replication and checkpoint responses. Consistent with a role in the
initiation of DNA synthesis, hsk1ts cells
exhibit delayed entry into S phase at the restrictive temperature. However, the cells also have an unusual phenotype for a initiation mutant: rather than showing evidence of premature mitosis, many cells
are elongated with fragmented nuclei. Upon release from HU arrest,
hsk1ts cells complete bulk DNA synthesis but
undergo an abnormal mitosis. This suggests a role for Hsk1p kinase
after replication origin firing. In addition,
hsk1ts cells show pronounced sensitivity to
agents which trigger both the DNA replication and damage checkpoints.
Upon HU treatment, Hsk1p is phosphorylated in vivo in a Cds1p-dependent
manner and Cds1p directly phosphorylates Hsk1p in vitro. Our data
indicate that Hsk1p itself is a target of the checkpoint response and
plays a role in S phase after origin firing.
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MATERIALS AND METHODS |
General yeast manipulation and molecular biology.
All
S. pombe strains (Table 1)
were maintained on yeast extract plus supplement (YES) agar plates or
under selection on Edinburgh minimal media (EMM) with appropriate
supplements using standard techniques (38). Double mutant
strains were constructed by standard tetrad analysis. Yeast cells were
transformed by electroporation as described previously (54).
Standard molecular biology techniques were used (45). A
hsk1::ura4+/hsk1+
diploid and hsk1+ genomic and cDNA clones were
gifts of H. Masai. Pulsed-field gel electrophoresis was performed as
described previously (54). pSLF272-cds1KD contains a kinase-inactive
version of cds1 with a D312E mutation (35).
Isolation of an hsk1-1312 temperature-sensitive
strain.
pREP1-hsk1* plasmids were mutagenized in 1 M
hydroxylamine solution, pH 6.7, for 20 h at 37°C
(43). The mutant library was transformed into a
hsk1::ura4+/hsk1+
diploid (FY818), and leu+ transformants were
recovered (Fig. 1Ai). Each diploid
transformant (3,000 in total) was picked and sporulated, and
hsk1/p(nmt-hsk1) haploids were isolated on
selective minimal media (Fig. 1Aii). Each haploid was replica plated
onto YES agar containing phloxin B, and temperature-sensitive strains
were identified. Plasmids from temperature-sensitive strains were
recovered (16 in total), and the entire mutagenized hsk1
sequence was integrated into FY818 at the hsk1 locus
(Fig. 1Aiii). leu1+ diploids were sporulated,
and temperature-sensitive
hsk1::p(hsk1ts-leu1+)::ura4+
haploids were identified. Counterselection on 5-fluoro-orotic acid was
used to isolate strains containing the restored genomic locus, now with
a mutant copy of hsk1 (Fig. 1Aiv). hsk1-1312 is mutated at codon 314 from TCT to ATT, resulting in a
serine-to-isoleucine substitution.
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FIG. 1.
Isolation of a temperature-sensitive allele of
hsk1. (A) hsk1-1312 was constructed as described
in Materials and Methods. (B) Wild-type (WT) (FY254) and
hsk1-1312 (FY945) cells were streaked onto YES agar and
incubated at 25, 29, and 32°C for 4 days. (C) Hsk1p structure showing
the location of the temperature-sensitive lesion. The kinase domains
are shown in light-gray boxes, and the kinase insert domains are shown
in dark-gray boxes. (D) Alignment of the amino acid sequences in kinase
subdomain IX in the CDC7 family of hsk1-1312, showing the
temperature-sensitive S314I lesion, and wild-type S. pombe
(S.p., GenBank accession no. D50493), S. cerevisiae (S.c., accession no. M12624), Homo
sapiens (H.s., accession no. AF015592), X. laevis (X.l., accession no. AB003699), and M. musculus (M.m., accession no. AB018574)
hsk1+/CDC7 homologues. Residues
conserved among all the kinases are shown in black boxes, and residues
conserved between most of the proteins are shown in gray boxes.
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Construction of hemagglutinin (HA) and myc-tagged Hsk1p and
Hsk1tsp.
The 1,707-bp hsk1+
sequence was amplified by PCR from FY254 wild-type or FY945
hsk1ts genomic DNA and cloned into pSLF172
(15), generating pHS60 (wild type) and pHS69 (temperature
sensitive). A version of this plasmid with a LEU2 marker was
constructed, generating pHS139. The 3' hsk13HA sequence was
cloned into pJK210 (25) and used to integrate Hsk1pHA or
Hsk1tspHA into the genome as a partial tandem duplication
(FY982 or FY1035, respectively). C-terminally tagged
hsk1-myc (pHS136) was generated by subcloning
hsk1 alone from pHS60 into pDS672, which contains two myc
tags (D. A. Sherman, S. G. Pasion, and S. L. Forsburg,
unpublished data).
HU, bleomycin, and UV treatment.
Cells were treated with 20 mM HU for 4 h at either 25 or 32°C in minimal media or grown on
EMM agar plus 5 mM HU. For block and release experiments, 10 to 15 mM
HU was added for 4 h, the cells were washed extensively in HU-free
EMM, and the cells were reinoculated into EMM. Cells were treated with
5 mU of bleomycin sulfate (Sigma-Aldrich, St. Louis, Mo.) per ml in
minimal media as described previously (16). Cultures of
strains to be tested for UV sensitivity were grown to mid-exponential
phase in minimal media. One thousand cells of each strain were plated
onto two YES agar plates and exposed to a range of UV doses in a
Stratalinker (Stratagene, La Jolla, Calif.). Viability was calculated
as a percentage of cells surviving to form colonies. Viability was determined by serial dilutions, plating on YES agar at 25°C, and comparing the efficiencies of colony formation of treated and untreated cells.
Cell biology.
Immunofluorescence and DAPI
(4',6'-diamidino-2-phenylindole) staining were performed as described
previously (10, 54). For all immunofluorescence experiments,
Hsk1pHA and Hsk1tsp were integrated into the chromosome
under the native promoter (see tagging of Hsk1p and Hsk1tsp
above). Cells were examined using a Leitz Laborlux S microscope, and
images were acquired directly by Adobe Photoshop for Macintosh using a
Spot II change-coupled-device digital camera (Diagnostic Instruments,
Inc., Sterling Heights, Mich.). Samples for flow cytometry were
prepared as described previously (54). Chromosome loss rates
were determined as described previously (34).
Immunoblotting and immunoprecipitation.
Protein lysates were
prepared by glass bead lysis, and immunoprecipitation was carried out
essentially as described previously (50, 54). The
phosphatase inhibitors 50 mM sodium fluoride, 50 mM
-glycerophosphate, and 20 µM sodium vanadate were included as
necessary. Enhanced resolution of the phosphorylated forms of Hsk1p and
Chk1p was obtained using a 50:1 ratio of acrylamide-piperazine diacrylamide. Western blotting was performed as described previously (54), and the blots were digitally scanned using a
Hewlett-Packard ScanJet IIcx scanner and analyzed using Canvas 6 software for Macintosh (Deneba, Miami, Fla.). Hsk1pHA and Dfp1p-myc
were specifically immunoprecipitated using anti-HA 12CA5 (gift of Tony
Hunter) and anti-myc 9E10 (BABCO) antibodies as described previously
(54).
phosphatase assays.
Immunoprecipitates of Hsk1pHA from
lysates treated in the presence or absence of HU were washed into phosphatase buffer (New England Biolabs, Beverley, Mass.) plus 2 mM
manganese chloride. The pellets were resuspended in 50 µl of assay
buffer, 400 U of phosphatase (New England Biolabs) was added to
each sample, and the reaction mixture was incubated at 30°C for 30 min. The reaction was halted by the addition of sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) sample buffer and
boiling for 3 min. Proteins were separated by SDS-PAGE and analyzed by
immunoblotting as described above.
Kinase assays.
For Hsk1p autokinase assays, Hsk1pHA or
Hsk1tspHA was immunoprecipitated from protein lysates as
described above. The immunoprecipitates were resuspended in 40 µl of
assay buffer (25 mM MOPS [morpholinepropanesulfonic acid, pH 7.2], 15 mM MgCl2, 15 mM EGTA, 1% Triton X-100, 1 mM dithiotreitol,
60 mM -glycerophosphate, 15 mM 
-nitrophenol phosphate, 0.1 mM
sodium vanadate, 1 mM phenylmethylsulfonyl fluoride, 20 µg of
leupeptin per ml, 40 µg of aprotinin per ml). Twenty microliters of
this slurry was incubated with 200 µM [
-32P]ATP
(NEN, Boston, Mass.) for 30 min at 32°C. The reaction was halted by
boiling the slurry in SDS-PAGE sample buffer. Immunoprecipitates were
separated on SDS-10% PAGE gels, the gels were exposed to a
PhosphorImager screen, and the images were analyzed using ImageQuant software (Molecular Dynamics, Sunnyvale, Calif.). Cds1p was purified from extracts of 2 g of GBY438 following growth for 20 h in
the absence of thiamine, with 15 mM HU being added during the last 4 h of growth. Purification to apparent homogeneity was achieved in two steps, using Talon-Sepharose and anti-HA monoclonal antibody 12CA5-protein A-Sepharose, as described previously (7).
Cds1p kinase assays were performed as previously described
(6) except that 100 µM ATP was used and bovine serum
albumin was omitted. Assay mixtures contained the Hsk1pHA
immunoprecipitate from approximately 4 mg of extract and 50 ng of Cds1p.
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RESULTS |
Isolation of a novel temperature-sensitive allele of
hsk1.
To allow genetic analysis of the fission yeast
hsk1+, we isolated the first conditional allele
of this gene, using a plasmid shuffle screen (Fig. 1A) (52).
From a total of 3,000 plasmids initially screened, we isolated a single
integrated allele, hsk1-1312. hsk1-1312 supports growth at
25°C, is semipermissive for growth at 29°C, but is insufficient for
growth at 32°C and above (Fig. 1B). This phenotype can be completely
complemented by expression of hsk1+ from a
plasmid (data not shown). The temperature-sensitive lesion in
hsk1-1312 is a 2-bp mutation that changes serine 314 in
kinase subdomain IX to isoleucine (Fig. 1C). This serine residue, which is completely conserved in S. cerevisiae Cdc7 and other
metazoan CDC7 homologues, is located 3 residues from a similarly
conserved aspartate residue that stabilizes the catalytic loop in
kinase subdomain VIB (Fig. 1D) (19).
We constructed a panel of double mutant strains with
hsk1-1312, hereinafter denoted
hsk1ts, and other components involved in the
early stages of DNA replication
(Table
2).
hsk1ts
interacts genetically with two of the
mcm mutants, the
mcm2 and
mcm6 mutants, but not with the third,
the
mcm4 mutant. The double
mutant
hsk1ts strains with the
rad4
initiator protein or the
MCM10 homologue
cdc23
also have a lower maximum permissive temperature than that
of either of
the single mutants alone. These genetic interactions
with putative
initiators are consistent with the expected role
of
hsk1+ in replication initiation.
Effects of hsk1ts on protein function.
We investigated the effect of the hsk1ts
mutation on the stability and protein interactions of the
Hsk1ts protein. The temperature-sensitive Hsk1 protein
(Hsk1tsp) is slightly less abundant than the wild-type
version in asynchronously growing cells (data not shown). To determine
if this reduction in protein level is due to increased protein
turnover, we compared the stabilities of Hsk1p and Hsk1tsp
at the restrictive temperature. Hsk1p and Hsk1tsp were
expressed from the thiamine-repressible nmt1 promoter. Following repression of expression, Hsk1p was degraded within 8 h,
whereas temperature-sensitive Hsk1tsp was undetectable
after only 4 h at 36°C (Fig. 2A),
demonstrating that Hsk1tsp is indeed less stable than the
wild-type protein. It has recently been reported that Cdc7 in S. cerevisiae is able to homo-oligomerize (49). We found
that this interaction is conserved with Hsk1p in S. pombe
and that Hsk1tsp is still capable of multimerizing with the
wild-type Hsk1 protein (data not shown).
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FIG. 2.
Hsk1p protein analysis. (A) Hsk1tsp has
lower stability at 36°C than Hsk1p. Wild-type cells (FY254) were
transformed with plasmids bearing genes expressing either Hsk1pHA
(nmt-hsk1+, pHS60) or Hsk1tspHA
(nmt-hsk1ts, pHS69). Hsk1pHA expression was
induced for 16 h at 25°C, 15 µM thiamine was added back to the
media, and the cultures were shifted to 36°C for 8 h. Aliquots
were removed at  16 h (before induction, lanes 1 and 7), at 0 h
(after induction, lanes 2 and 8), and at 2 h (lanes 3 and 9),
4 h (lanes 4 and 10), 6 h (lanes 5 and 11), and 8 h
(lanes 6 and 12) after the addition of thiamine. Each lysate (10 µg)
was immunoblotted for Hsk1pHA (lanes 1 to 6), Hsk1tspHA
(lanes 7 to 12), and tubulin (lanes 1 to 12). (B) Hsk1tsp
fails to interact with Dfp1p. Expression of Dfp1p-myc (pSLF272-dfp1+myc
[6, 15]) was induced in wild-type (WT) (FY982) or
hsk1ts (FY1035) cells. The culture of
hsk1ts was split, with half being kept at 25°C
and the other half being incubated at 36°C for 6 h. Proteins
were immunoprecipitated from each lysate with either anti-HA (H),
anti-myc (M), or anti-tubulin (T) antibodies, and the
immunoprecipitates (IP) were immunoblotted with anti-HA antibodies.
Lanes 1 to 3, wild type; lanes 4 to 6, hsk1ts
cells at 25°C; lanes 7 to 9, hsk1ts cells at
36°C. The lower gel indicates the loading control. Crude extracts
used for immunoprecipitation were blotted for Hsk1-HA and Dfp1-myc.
Lane 10, wild type; lane 11, hsk1ts cells at 25°C; lane
12, hsk1ts cells at 36°C. (C) Kinase activity
is abrogated in hsk1ts cells. Kinase assays were
carried out as described in Materials and Methods. HA-tagged Hsk1p
(lanes 1 and 3) or Hsk1tsp (lanes 2 and 4) was
immunoprecipitated with an anti-HA antibody ( -HA). Half the
immunoprecipitate was subjected to kinase assay (lanes 1 and 2), and
the other half was subjected to immunoblotting (lanes 3 and 4).
autorad, autoradiograph.
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However, other aspects of Hsk1
tsp activity are aberrant.
Hsk1p requires its regulatory subunit Dfp1p for activity against the
Mcm2p substrate (
6). We found that even at the permissive
temperature,
Hsk1
tsp displays a much lower affinity for
Dfp1p than that observed
with wild-type Hsk1p (Fig.
2B). Furthermore,
Hsk1
tsp has severely reduced autophosphorylation activity
at the restrictive
temperature (Fig.
2C). It has been observed that
certain
cdc7 mutants of
S. cerevisiae can be
complemented by overexpression
of the Dfp1p homologue Dbf4
(
30). However, we did not observe
a similar rescue of
hsk1ts by high levels of Dpf1p (data not shown).
Thus, the temperature-sensitive
lesion in Hsk1
tsp clearly
disrupts several features which are necessary for the
proper activity
of the
protein.
Hsk1tsp disrupts nuclear localization.
We next
examined the localization of Hsk1p in wild-type cells and in mutants
blocked at different stages of the cell cycle by indirect
immunofluorescence. In wild-type cells, Hsk1p exhibits punctate nuclear
staining throughout the cell cycle (Fig. 3A and B). In mitotic cells just undergoing
nuclear division, the localization of Hsk1p is less well defined (Fig.
3A and B), although the protein clearly remains in the nucleus even in
cells arrested in mitosis by various cell cycle mutants (data not
shown). Since Dfp1p is quite unstable and present only during S and
G2 phases (6, 56), this indicates that Hsk1p
nuclear localization is independent of Dfp1p.
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FIG. 3.
Localization of Hsk1p. Hsk1pHA or Hsk1tspHA
was expressed from the endogenous promoter in the genome. Cells were
prepared for indirect immunofluorescence as described in Materials and
Methods and stained with DAPI to detect the DNA (A, C, E, and G) or
with the anti-HA antibody 16B12 to visualize Hsk1p (B, D, F, and H).
Wild-type cells were grown at 32°C in minimal media prior to being
stained. Temperature-sensitive strains were grown to mid-log phase at
25°C and then shifted to 36°C for 4 h prior to being stained.
In all cases, HA-tagged hsk1+ was integrated
into the genome. (A to D) Hsk1pHA localizes to discrete spots in the
nucleus independently of MCM proteins. Shown are the localizations of
Hsk1p in wild-type cells (FY982) (A and B) and in cdc21-M38
cells (FY1002) (C and D). The arrows in panels A and B indicate mitotic
cells. (E to H) Hsk1tsp is redistributed from the nucleus
at 36°C. hsk1ts cells (FY1035) were grown in
minimal media to mid-log phase at 25°C (E and F) or shifted to 36°C
for 6 h (G and H). In all cases, the scale bar represents 10 µm.
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Although the Hsk1p substrate Mcm2 (also called Cdc19p) is located in
the nucleus throughout the cell cycle (
41), in
mcm mutant strains MCM proteins are redistributed to the
cytoplasm
(
42). However, these same mutations have no effect
on the localization
of Hsk1p, which remains nuclear (Fig.
3C to D and
data not shown),
demonstrating that proper localization of Hsk1p is
independent
of its substrate. Hsk1p localization was also unaffected by
mutation
in a subunit of the origin recognition complex,
orp1, or treatment
with HU (data not
shown).
In contrast, Hsk1
tsp is redistributed to the cytoplasm at
the restrictive temperature (Fig.
3E to H). Even at 25°C, there is
an
increase in cytoplasmic background staining in comparison with
that of
wild-type cells (Fig.
3A and B). At the restrictive temperature,
specific nuclear localization of Hsk1
tsp is all but lost
and staining is seen throughout the cell body
(Fig.
3H), suggesting
that the protein is either being specifically
exported from the nucleus
or failing to localize
correctly.
hsk1ts causes G1 phase delay
and defects in nuclear integrity.
We examined the phenotype of the
hsk1ts mutant. Upon a shift to the restrictive
temperature for 4 h, hsk1ts cells displayed
a transient G1 delay (Fig.
4A).
Most cells finally arrested with an
approximately 2C DNA content, but there were increasing numbers of cut
cells containing less than 1C DNA (data not shown). Furthermore, cells
with fragmented nuclei were also apparent when the culture was examined
microscopically (Fig. 4B). This fragmentation suggests a defective
checkpoint and is similar to the phenotype reported for the
hsk1 allele (36). Several initiation mutants
undergo premature mitosis in the absence of replication. However, in
contrast to those mutants with typical initiation checkpoint defects,
hsk1ts cells were noticeably elongated,
indicating a cell cycle delay, and cells with <1C DNA content appeared
only 4 h following the shift to the nonpermissive temperature.
This timing and morphology strongly argue against premature entry into
mitosis.
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FIG. 4.
hsk1ts exhibits a G1
delay and loss of nuclear integrity at the restrictive temperature. (A)
hsk1ts exhibits G1 delay. The DNA
profiles of wild-type (FY254) (WT) and hsk1ts
(FY945) cells were examined by flow cytometry. Cells were grown at
25°C in minimal media to mid-log phase before being shifted to 36°C
for 4 h. Aliquots were removed at 0 and 4 h and prepared for
flow cytometry as described in Materials and Methods. The positions of
1C and 2C DNA contents are indicated. (B) hsk1ts
has abnormal chromosomes. Shown is DAPI staining to visualize nuclei of
wild-type (FY254) (top) and hsk1ts (FY945)
(bottom) cells after 6 h at 36°C. Arrows indicate chromosome
fragments. (C) Both wild-type and hsk1ts cells
complete DNA synthesis after HU arrest and release to 36°C. Wild-type
(FY254) and hsk1ts (FY945) cells were arrested
in HU at 25°C and released to 36°C. Aliquots were removed for
analysis by flow cytometry prior to the addition of HU and at 0, 10, 20, and 30 min after release from HU. Fewer than 5% of the cells
showed a cut phenotype (data not shown). (D) Timing of mitosis and fragmentation in hsk1ts
cdc10 and cdc10 cells. Cells were arrested in HU for
4 h and released to 36°C without HU. Cell morphology was
determined by DAPI staining and examination by fluorescence microscopy.
The percentages of cells displaying the indicated phenotypes were
plotted against time. Open symbols, normal mitotic cells in
cdc10 ( ) or cdc10 hsk1 ( ) cells; closed
symbols, fragmented nuclei in cdc10 ( ) or cdc10
hsk1 ( ) cells. (E) Fragmentation in hsk1 strains
requires entry into mitosis. Samples from the experiment whose results
are shown in panel D were photographed after 4 h at the
restrictive temperature. Left, cdc10 cells; middle,
hsk1ts cdc10 cells (arrows indicate fragmented
nuclei); right, hsk1ts cdc25 cells.
hsk1ts cdc10 and hsk1ts
cells have identical phenotypes (data not shown).
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We determined the
hsk1ts execution point for
both the replication and DNA fragmentation phenotypes by using an HU
block and
release experiment (Fig.
4C).
hsk1ts
and wild-type cells were arrested in early S phase by treatment
with HU
at the permissive temperature of 25°C and then shifted
to 36°C to
inactivate Hsk1
tsp.
hsk1ts cells in
HU became elongated with single nuclei, as did wild-type
cells (data
not shown). After HU was removed, both wild-type and
hsk1ts cells completed DNA synthesis in about 30 min, indicating that
hsk1ts was not required for
DNA replication after the HU arrest point.
However, the flow cytometry
profile of
hsk1ts revealed kinetics of DNA
accumulation different from those of
the wild type. This finding is
consistent with the failure of
late origins to fire in
hsk1ts cells at the restrictive temperature, as
seen in analogous experiments
with
S. cerevisiae cdc7
mutants (
12).
Strikingly, the nuclear structure of
hsk1ts
cells released from HU to the restrictive temperature became highly
disordered after
the completion of DNA replication (Fig.
4E and data
not shown).
A large fraction of the
hsk1ts cells
were elongated, and the DNA fragmented into several visible
pieces of
DAPI-stained material. This suggests that the Hsk1p
kinase has a second
execution point, after replication initiation,
which is required to
maintain chromosome integrity. Significantly,
this phenotype resembled
that observed in many of the cells following
the shift of the
hsk1ts strain to the restrictive temperature
(Fig.
4A).
Therefore, the nuclear fragmentation phenotype is not
simply a
consequence of HU arrest but indicates a role for Hsk1p
after the
initiation of bulk DNA synthesis in order to maintain
chromosome
integrity during mitosis. This function is apparently
separable from
its role in replication initiation, which has an
execution point prior
to the HU
arrest.
Establishment of chromosome cohesion depends upon successful passage
through S phase (
53,
58). In fission yeast, a
temperature-sensitive
mutant in the
rad21 cohesin exhibits
abnormal mitosis at the restrictive
temperature, with aberrantly
condensed chromosomes and unequally
divided nuclei (
57).
These phenotypes are similar to those we
observed in
hsk1ts cells (Fig.
4B). We found that the
rad21ts cohesin mutant is synthetically lethal
with
hsk1ts (Table
2), which may indicate a role
for Hsk1p in ensuring correct
chromosome cohesion as S phase
progresses.
Despite the fragmentation phenotypes we observed,
hsk1
mutant cells maintained high viability following 4 h at the
restrictive
temperature or after 4 h in HU, although colony size
was heterogeneous
(data not shown). This result suggests that the cells
can recover
from the damage if exposure to restrictive conditions is
not
prolonged.
To determine whether DNA fragmentation in the
hsk1ts cells depends upon passage through
mitosis, we repeated the HU block and
release experiment with
cdc10,
hsk1ts cdc10, and
hsk1ts cdc25 mutant strains. First, we monitored
the appearance of normal
mitotic cells and cells with fragmented nuclei
in the two
cdc10 strains. Following HU release, the
cdc10 mutant arrested in the
G
1 phase of the
following cell cycle, ensuring that we were observing
events in a
single mitosis. As seen in Fig.
4D, the
cdc10 mutant
underwent mitosis, with a peak at 2.5 h. The
hsk1ts cdc10 strain accumulated cells with
fragmented nuclei with similar
timing, which suggests that
fragmentation occurs as a consequence
of mitotic entry. This result
also demonstrates that entry into
mitosis in the double mutant strain
occurs with normal timing;
this phenotype was identical to that
observed in the
hsk1ts mutant alone. When the
hsk1ts cdc25 cells were released to 36°C, they
completed S phase and
arrested at the G
2/M phase transition
due to the lack of active
Cdc25p (data not shown). As shown in Fig.
4E,
no chromosome fragmentation
was detected in the
hsk1ts cdc25 strain. Thus, the abnormal
morphology in the
hsk1ts strain reflects passage
through mitosis of cells with apparently
replicated DNA but does not
reflect premature mitosis, since timing
of entry appeared
normal.
Since the
hsk1ts mutant showed abnormal,
fragmented nuclei and Hsk1
tsp was lost from the nucleus, we
next asked whether other nuclear
proteins were also redistributed. As
shown in Fig.
5A to D, the
typical
nuclear localization of Mcm2p or Mcm5p was unaffected
by the
relocalization of Hsk1
tsp, suggesting that MCM protein
localization is independent of
Hsk1p function and showing that overall
nuclear integrity is maintained
in
hsk1ts cells.
In cells where chromosomal fragmentation was observed,
there was little
association of the MCM proteins with the smaller
DAPI staining
material.
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FIG. 5.
hsk1ts has increased genome
instability. (A to D) MCM proteins remain nuclear in
hsk1ts cells. The hsk1ts
allele was combined with a strain carrying an integrated HA-tagged copy
of either Mcm2p (FY981) (A and B) or Mcm5p (FY980) (C and D). The
strains were grown in minimal media for 6 h at 36°C. The arrows
in panels A and B indicate cells with highly abnormal chromosomes which
have reduced MCM protein localization. The scale bar represents 10 µm. (E) hsk1ts cells have structurally
abnormal chromosomes as determined by pulsed-field gel electrophoresis.
Wild-type (FY254) (WT) and hsk1ts (FY945) cells
were grown at either 25 or 36°C for 6 h. Whole chromosomes were
prepared in agarose plugs and run in a 0.6% agarose gel as described
in the text. The positions of chromosomes 1 to 3 are indicated. (F)
hsk1ts homozygous diploids display elevated
rates of chromosome loss. Wild-type (HSY1) or
hsk1ts (HSY2) diploids were scored for
chromosome loss as described in the text. Results of an experiment
representative of three separate experiments which gave similar results
are shown.
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We examined the chromosome structure in the
hsk1ts mutant strain using pulsed-field gel
electrophoresis, which allows resolution
of the three individual
chromosomes of
S. pombe. Chromosomes that
are undergoing DNA
replication or have aberrant structures fail
to enter the gel (
27,
34). As seen in Fig.
5E, the three chromosomes
from
hsk1ts cells did not enter the gel very
efficiently compared to the
wild type, even at the permissive
temperature, and this effect
was exacerbated in chromosomes isolated
from
hsk1ts cells at the restrictive
temperature. We also observed that the
mobility of chromosome 3 in the
mutant was higher than in the
wild type, suggesting that this
chromosome may be smaller than
normal. A similar effect has been
reported for
mcm2 mutants (
34).
There is no
obvious smear of chromosomal fragments, such as that
observed in
cdc24 mutants (
17); thus, if
hsk1ts chromosomes are fragmented, they must
have sufficient structural
abnormalities to prevent migration into the
gel.
Finally, we investigated the genome stability of
hsk1ts cells by comparing rates of
chromosome loss as assessed by haploidization.
Diploid fission yeast
cells that lose one chromosome rapidly are
reduced to the haploid
state. Hence, the rate of chromosome loss
can be inferred by
haploidization of nonsporulating diploids (
4).
As shown in
Fig.
5F,
hsk1ts/
hsk1ts
diploids display a much higher rate of chromosome loss than that
of the
wild type, even at the permissive temperature, and this
is further
elevated by shifting the culture to the restrictive
temperature. These
results clearly demonstrate that
hsk1ts causes a
significant decrease in genome stability at all
temperatures.
Hsk1p is a target of the replication checkpoint kinase Cds1p.
Strains with defects in genome stability are often sensitive to agents
that challenge chromosomal integrity. We examined the HU response of
the hsk1ts mutant more closely. Arrest in HU
triggers the so-called replication checkpoint, and recovery from HU
arrest requires the activities of the Cds1 and Rqh1 proteins
(3). cds1+ encodes a nonessential
checkpoint kinase (39), and rqh1+,
also known as rad12+ or
hus2+, encodes a RecQ-type helicase (9, 40,
55). Mutation of these proteins does not cause premature mitosis
but rather affects the ability of arrested cells to recover and reenter
the cell cycle after HU is removed. We analyzed the genetic
interactions between hsk1ts, cds1,
and rqh1 mutants. Strikingly
hsk1ts and rqh1 mutants were
synthetically lethal, since it was not possible to recover an
hsk1ts rqh1 double mutant (Table
2; data not shown). In contrast, deletion of
cds1+ appeared to partially suppress
hsk1ts, since the double mutant formed small
colonies at 32°C, a temperature restrictive for
hsk1ts growth (Table 2; Fig.
6A). Moreover
hsk1ts was hypersensitive to overexpression of
active, but not kinase-inactive, Cds1p (Fig. 6B). However, the
fluorescence-activated cell sorter profiles were not significantly
different (data not shown).
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FIG. 6.
hsk1ts is required for recovery
from replication arrest. (A) hsk1ts can be
partially suppressed by deletion of cds1.
hsk1ts (FY945) or hsk1ts
cds1 (FY999) double mutant cells were streaked onto YES
agar at 25 or 32°C. (B) Moderate overexpression of Cds1p is toxic in
hsk1ts cells. Wild-type (WT) and
hsk1ts cells were transformed with either pREP4X
(V), pSLF272-cds1+
(cds1+), or
pSLF272-cds1KD (cds1KD),
and expression was induced at 25°C. (C) hsk1ts
is sensitive to HU. Wild-type (FY254), cds1 (FY866),
hsk1ts (FY945), rqh1 (FY1163), and
hsk1ts cds1 (FY999) cells were
grown on minimal media or minimal media plus 5 mM HU at 25°C. (D)
Abnormal cell morphologies were scored after treatment with HU.
Wild-type, hsk1ts, rqh1,
cds1, and hsk1ts
cds1 cells were treated with 10 mM HU for 11 h at
25°C (left), or 4 h at 25°C followed by release to HU-free
media at 36°C for 4 h (right). Cells were stained with DAPI and
examined microscopically. Abnormal cells were classified as those
displaying a cut morphology (black), unequal segregation (white), or
fragmented or irregular nuclei (gray). Two hundred cells were counted
for each strain.
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If Hsk1p activity is required for cells to recover from replication
arrest, we would expect
hsk1ts strains to
display phenotypes similar to those of
cds1 and
rqh1 mutants following prolonged exposure to sublethal
doses of HU.
We compared the responses of wild-type,
hsk1ts,
cds1,
rqh1,
and
hsk1ts cds1 cells to low
levels of HU at the permissive temperature
(Fig.
6C). Although the
wild-type strain formed colonies efficiently
in the presence of 5 mM
HU,
hsk1ts,
cds1,
rqh1, and
hsk1ts
cds1 cells were unable to grow. Since
hsk1ts cells arrested normally in response to HU
treatment, as did
cds1 and
rqh1 cells (Fig.
4C and data not shown), we conclude from
this assay that
hsk1ts cells are similarly defective in the
recovery from S-phase arrest.
Microscopic examination of
hsk1ts,
cds1,
rqh1,
and
hsk1ts cds1 cells following
prolonged incubation in HU at the permissive
temperature revealed that
all strains developed increasing numbers
of cut cells and other
aberrant nuclear morphologies (Fig.
6D)
(
55). In particular,
both
hsk1ts and
rqh1 cells
exhibited fragmentation similar to that seen
in the
hsk1ts mutant at the restrictive temperature
(Fig.
4A and data not shown)
(
55). Interestingly, in the
hsk1ts cds1 mutant, the fraction
of abnormal cells was higher than
that observed in either single mutant
(Fig.
6D, left graph). Upon
examination of
hsk1ts and
rqh1 cells after
release from HU arrest to the restrictive
temperature for
hsk1ts, we found that both strains accumulated
large numbers of cells
with aberrant chromosome structures and that
both were more severely
affected than the
cds1 mutant
alone (Fig.
6D, right graph). Thus,
the chromosome integrity of all
these mutants appeared to be affected
upon prolonged arrest in HU.
However, the double mutant phenotypes
and complex genetic interactions
suggest that these effects are
mediated through separable pathways,
indicating that recovery
from HU requires multiple components of the
replication and repair
machinery.
The genetic suppression of
hsk1ts by deletion of
cds1+ and its sensitivity to Cds1p
overproduction suggest that Cds1p antagonizes
some aspect of Hsk1p
activity. To determine whether Hsk1p is itself
a target of Cds1p, we
examined Hsk1p from cell extracts grown
in the presence or absence of
HU by gel electrophoresis (Fig.
7A).
Hsk1p from HU-treated cells migrated with a reduced mobility
compared
to that from untreated cells. This modest mobility shift
could be
reversed by treatment with
phosphatase, indicating
that the
modification reflects phosphorylation. The same modification
of Hsk1p
is seen in a strain with a mutation in the catalytic
subunit of the
ribonucleotide reductase
cdc22 (Fig.
7B), which
phenocopies
HU treatment (
47). Since the
hsk1ts
strain is sensitive to HU, we speculated that the mutant protein
might
not respond to HU treatment. Indeed, we found that
temperature-sensitive
Hsk1
tsp does not display a detectable
phosphorylated form following
treatment with HU at either the
permissive or restrictive temperature
(Fig.
7B).
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FIG. 7.
Hsk1p is phosphorylated by Cds1p in response to HU. (A)
Hsk1p is phosphorylated in the presence of HU. Wild-type cells were or
were not treated with HU. Lysates were prepared from wild-type cells
(FY982) in the presence of phosphatase inhibitors, and HA-tagged Hsk1p
was immunoprecipitated from the lysates using an anti-HA antibody.
Samples were run on 6% acrylamide-piperazine diacrylamide gels, as
described in Materials and Methods. Lanes: 1, Hsk1p minus HU; 2, Hsk1p
plus HU; 3, Hsk1p plus HU treated with phosphatase ( p'ase) as
described in Materials and Methods. (P), phosphorylated. (B) Hsk1p is
modified in cdc22 cells, but Hsk1tsp is not
phosphorylated in the presence of HU at any temperature. Lysates were
prepared from wild-type (FY982) (WT), hsk1ts
(FY1035), and cdc22 (FY1011) strains carrying HA-tagged
integrated Hsk1p, grown in the presence (H) or absence () of 20 mM
HU. Protein lysate (10 µg) was analyzed by immunoblotting following
electrophoresis as described for panel A above. Lanes: 1, wild type,
32°C; 2, wild type plus HU for 4 h at 32°C; 3, hsk1ts cells at 25°C; 4, hsk1ts cells plus HU at 25°C; 5, hsk1ts cells for 4 h at 36°C; 6, hsk1ts cells plus HU for 4 h at 36°C; 7, cdc22 cells for 4 h at 36°C; 8, cdc22
cells plus HU for 4 h at 36°C. (C) Hsk1p phosphorylation
requires Cds1p. Whole-cell lysates were prepared from wild-type
(FY982), cds1 (FY1082), and chk1 (FY1085)
cells, and cells expressing Hsk1pHA were grown in the absence () or
presence of HU (H) or bleomycin (B). Protein lysate (10 µg) was
analyzed by immunoblotting following electrophoresis as described for
panel A above. Lanes: 1, wild-type untreated cells; 2, wild type cells
plus HU; 3, wild-type cells plus bleomycin; 4, cds1
untreated cells; 5, cds1 cells plus HU; 6, cds1 cells plus bleomycin; 7, chk1
untreated cells; 8, chk1 cells plus HU; 9, chk1 cells plus bleomycin. (D) Hsk1p and
Hsk1tsp are Cds1p kinase substrates in vitro. (Upper gel)
Hsk1p was immunoprecipitated from extracts of fission yeast strains
containing pHS60 (Materials and Methods). The Hsk1p immunoprecipitates
were preincubated (pre-inc) with cold ATP (lanes 3 and 4) or heat
inactivated at 70°C (lanes 5 and 6) (6) and incubated with
Cds1p kinase and [-32P]ATP. Reaction products were
fractionated by SDS-PAGE and exposed to a PhosphorImager screen. Lanes:
1, no protein; 2, Cds1p only; 3, Hsk1p preincubated with cold ATP; 4, Hsk1p preincubated with cold ATP plus Cds1p; 5, Hsk1p preincubated at
70°C; 6, Hsk1p preincubated at 70°C plus Cds1p. (Lower gel) Hsk1p
and Hsk1tsp were immunoprecipitated from extracts of
fission yeast strains containing pHS60 and pHS69, respectively. The
immunoprecipitates were heat inactivated at 70°C and incubated in the
absence or presence of Cds1p. The relative levels of incorporation of
32P into Hsk1p and Hsk1tsp were determined
using ImageQuant software and are given in arbitrary units. Lanes: 7, Hsk1p only; 8, Hsk1p plus Cds1p; 9, Hsk1tsp only; 10, Hsk1tsp plus Cds1p.
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We investigated which checkpoint kinases were required for the observed
Hsk1p phosphorylation. We treated wild-type,
cds1,
and
chk1 cells with HU and examined Hsk1p modification.
HU-induced
phosphorylation of Hsk1p was not detected in
cds1 cells (Fig.
7C) but did occur in
chk1
mutants. We also treated cells with
the radiation mimetic drug
bleomycin, which activates the damage
response pathway (
16),
but we observed no alteration in the
mobility of Hsk1p (Fig.
7C). Thus,
these data suggest that Hsk1p
is a specific target of the DNA
replication checkpoint rather
than the DNA damage response
pathway.
To determine whether Hsk1p is a direct target of Cds1p, we examined the
ability of the purified Cds1p kinase to phosphorylate
immunoprecipitated Hsk1p (Fig.
7D). In order to eliminate any
background due to autophosphorylation, we used heat-inactivated
Hsk1p
immunoprecipitated from appropriate strains as a substrate
(Fig.
7D)
(
6). Both Hsk1p and Hsk1
tsp were phosphorylated
by Cds1p in vitro (Fig.
7D). This result
provides the first evidence
that the catalytic subunit of the
Hsk1p kinase itself can be
phosphorylated by Cds1p
kinase.
hsk1ts requires the damage checkpoint for
viability.
hsk1ts is sensitive to several agents
that induce DNA damage. As can be seen in Fig.
8A, hsk1ts cells
were considerably more sensitive to UV light than wild-type cells but
were not as severely affected as rad3 cells. We also tested the sensitivity of hsk1ts to the drug
methyl methane sulfonate (MMS) and found that
hsk1ts cells are much more sensitive to MMS than
wild-type and rad4 cells (Fig. 8B). Interestingly, we were
unable to construct double mutants with hsk1ts
and the chk1 or rad3 checkpoint kinases
(Table 2). This inability of cells to grow in the absence of
chk1 or rad3 when there were mutations in
hsk1 suggests that hsk1ts may cause
chromosomal lesions even at the permissive temperature which require
the presence of a fully functional DNA damage checkpoint pathway to
delay mitosis for adequate repair. This requirement would be consistent
with either defects in initiation or defects in overall chromosome
stability. We tested this theory by examining the phosphorylation state
of the Chk1 protein, since it has previously been shown that the
phosphorylation of Chk1p correlates with activation of the DNA damage
checkpoint (60). In wild-type cells, Chk1p was activated
only upon treatment with bleomycin. In contrast, Chk1p phosphorylation
was observed in hsk1ts cells even in the absence
of bleomycin, at both 25 and 36°C, indicating partial activation of
the DNA damage checkpoint in these mutant cells (Fig. 8C).
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FIG. 8.
hsk1ts is sensitive to
DNA-damaging agents. (A) hsk1ts cells are
sensitive to UV irradiation. Wild-type (FY254) (WT),
hsk1ts (FY945), and rad3 (FY1105)
cells were treated with UV irradiation as described in Materials and
Methods. The graph represents relative levels of viability following
treatment with the indicated doses. The results of one representative
experiment are presented. The experiment was repeated three times with
similar results. (B) hsk1ts cells are sensitive
to MMS. Wild-type (FY254), hsk1ts (FY945),
rad4 (FY440), and hsk1ts rad4
(FY1124) cells were streaked onto YES agar plates with or without
0.025% MMS at 25°C. (C) The DNA damage checkpoint is activated in
hsk1ts cells. Wild-type (FY1176) or
hsk1ts (FY1181) cells were grown at 25 or 36°C
for 6 h in the presence or absence of 5 mU of bleomycin per ml.
Lysates were prepared, and 20 µg of total protein was separated on
8% acrylamide-piperazine diacrylamide gels, as described in Materials
and Methods. The mobility of Chk1p was determined by Western blotting
with anti-HA antibodies. Lanes: 1, wild type at 25°C; 2, wild type at
25°C plus bleomycin; 3, wild type at 36°C; 4, wild type at 36°C
plus bleomycin; 5, hsk1ts cells at 25°C; 6, hsk1ts cells at 25°C plus bleomycin; 7, hsk1ts cells at 36°C. (P), phosphorylated.
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DISCUSSION |
In this report we have described the isolation and
characterization of the first temperature-sensitive allele of S. pombe hsk1+. The mutant allele, hsk1-1312,
changes serine 314 in kinase subdomain IX, which is conserved in all
CDC7 family members, into an isoleucine. This mutation causes a
decrease in the stability of Hsk1tsp, as well as reduced
autophosphorylation activity and decreased association with the Dfp1p
subunit. The wild-type protein is found constitutively in the nucleus,
and its localization is unaffected by treatment with HU or the absence
of its substrate Mcm2p. In contrast, the mutant protein fails to
localize appropriately, with reduced nuclear localization even under
permissive conditions. This redistribution of Hsk1tsp may
reflect abnormal protein structure or the inability of the protein to
interact with a factor required for nuclear retention. However, it is
unlikely that the redistribution of Hsk1tsp reflects its
failure to interact correctly with Dfp1p, since wild-type Hsk1p remains
nuclear throughout the cell cycle even though Dfp1p is present only
transiently (this work and references 6 and
56).
A postinitiation role for Hsk1p.
Under restrictive conditions,
hsk1ts mutant cells are severely delayed in
S-phase progression and some cells show abnormal entry into mitosis,
suggesting that they suffer a defect in the checkpoint that monitors
DNA replication. At first glance, this possibility is consistent with
observations of other mutants that block the cells prior to initiation
of DNA synthesis, including rad4 (also called
cut5) (14), orp1 (18),
cdc18 (27), and pol1 (13) mutants. The failure of these mutants to restrain M phase is thought to
indicate defects in assembly of replication structures that signal to
the checkpoint apparatus, causing the cells to enter mitosis
prematurely, without entering S phase (28). However, in
contrast to these other mutants, some hsk1ts
cells at the restrictive temperature show a single elongated cell body,
with multiple DAPI-stained dots. This phenotype is distinct from the
small, aneuploid cells of a typical cut mutant. Importantly, cellular
elongation suggests that a cell cycle delay occurs prior to abnormal mitosis.
To probe the role of Hsk1p in later stages of DNA replication, we
blocked
hsk1ts cells in HU and then released
them to the restrictive temperature.
The cells completed DNA synthesis
and underwent mitosis with apparently
normal timing. This was expected;
data from budding yeast show
that replication forks originating from
early-firing replication
origins are sufficient to complete genome
duplication in
cdc7 mutants, even if late origins do not
fire (
5,
12). This result
indicates that the initiation
function of Hsk1p at early origins
occurs prior to the HU block.
However, although
hsk1ts cells released from HU
to the restrictive temperature completed
DNA synthesis and entered
mitosis with normal timing, that mitosis
was severely disrupted, with a
high fraction of cells exhibiting
fragmented nuclei. Thus, when Hsk1p
activity is lost during replication
elongation, it affects mitotic
progression, a phenotype not observed
in budding yeast (
5,
12). The execution point for this effect
is subsequent to the HU
block, which suggests two possibilities:
either there is a second role
for Hsk1p during normal S phase
or there is a role for Hsk1p in
recovery from the DNA replication
block caused by HU treatment. These
possibilities are not mutually
exclusive.
Importantly, the phenotype upon HU treatment is similar to that
observed in a fraction of cells when they were shifted to
the
restrictive temperature without a prior HU block. This result
implies
that the mitotic defect observed following HU treatment
is not solely
an effect of S-phase arrest but rather that it is
enhanced due to the
synchrony imposed by the HU
block.
We posit that the nuclear fragmentation may reflect a defect in
chromosome cohesion, which is established during S phase (
53,
58). In support of this, we observed synthetic lethality between
hsk1ts and the mitotic
rad21ts cohesin. If the
hsk1ts cells are unable to establish correct
cohesion during S phase,
this might prevent proper chromosome
segregation at mitosis, resulting
in the observed loss in nuclear
integrity. Intriguingly, the cohesin
is phosphorylated during S phase
(
2). Very recently, a novel
DNA polymerase was shown to be
required for both replication and
cohesion in budding yeast, indicating
a further connection between
DNA replication and sister chromatid
cohesion (
61). Hsk1p may
contribute directly to the
establishment of cohesion, or it may
carry out a more general function
during DNA synthesis that affects
chromosome
segregation.
This evidence indicates a role for Hsk1p in maintaining genome
integrity that may be separate from its role in replication
initiation.
Interestingly, we found that Chk1p checkpoint kinase
is phosphorylated
in
hsk1ts cells even at the permissive
temperature, indicating that the
damage checkpoint is chronically
activated in this strain. This
chronic activation further suggests that
defects in
hsk1 cause
genome damage even when the cells are
able to divide and explains
why the
hsk1ts
mutant requires the checkpoint kinases Rad3p and Chk1p for
viability.
Hsk1p is a potential target of Cds1p.
The phenotypes that we
observed in hsk1ts cells following prolonged
exposure to HU are similar to the recovery defects observed for
cds1 and rqh1 cells upon treatment with HU,
which reflect the inability of the cells to restart S phase and
complete a normal cell cycle after replication arrest. Moreover, the
synthetic lethality between hsk1ts and
rqh1 mutants indicates that Hsk1p is required for
recovery from replication arrest in a pathway that is at least
partially separate from that requiring Rqh1p.
Our experiments reveal interactions between Hsk1p and Cds1p both during
a normal cell cycle and during replication arrest.
We found that the
temperature sensitivity of
hsk1ts is partially
suppressed by
cds1 cells and, conversely, that
hsk1ts cells are hypersensitive to
overexpression of active, but not
kinase-dead, Cds1p. Several
replication mutants, such as DNA polymerase
, require
cds1+ for viability (
1), which makes
the suppression of
hsk1ts particularly unusual.
This observation might indicate that Cds1p
is modestly activated in the
hsk1ts mutant because of its replication
initiation defect, resulting
in negative feedback which then further
down-regulates Hsk1p activity.
Alternatively, there may be a
nonessential role for Cds1p in normal
S phase in which it negatively
regulates Hsk1p. Relief of Hsk1p
ts inhibition by the
deletion of Cds1p would be permissive for growth
at higher
temperatures.
The
cds1 hsk1 double mutant has noticeably more abnormal
cells following HU treatment than those of either single mutant,
indicating that while both genes operate in the response to HU,
they
are likely to affect at least partially separate pathways.
We suggest
that the defect in HU in the double mutant is due to
two overlapping
effects: the absence of a proper Cds1p response
and the inability of
the
hsk1 mutant cells to carry out their
late-S-phase
function. These possibilities suggest that release
from HU elicits
multiple responses required to restart replication
and maintain genome
integrity.
The Hsk1p subunit in HU-treated wild-type cells undergoes
phosphorylation that requires Cds1p. Using purified proteins, we
determined that both wild-type and mutant Hsk1 proteins are direct
substrates of Cds1p in vitro, even if the Hsk1p proteins are heat
inactivated. However, the mutant Hsk1
tsp is not detectably
phosphorylated in vivo. The reason for this
discrepancy remains
unclear, although a number of mechanisms,
such as defects in mutant
Hsk1p localization or defective interactions
with other proteins, may
account for the inability of Cds1p to
mediate phosphorylation of
Hsk1
tsp in vivo. It is also formally possible that both
Cds1p phosphorylation
and Hsk1p autophosphorylation are required in
order to detect
a shift in Hsk1p mobility. Previous studies have shown
that the
Hsk1p regulatory subunit Dfp1p is also phosphorylated in a
Cds1p-dependent
manner in response to HU treatment (
6,
56).
Mutations in
dfp1 confer sensitivity to HU and cause
aberrant mitoses upon
prolonged exposure to HU (
56).
Therefore, both subunits of the
Hsk1 kinase may be direct substrates of
Cds1 kinase and are elements
of the response to S-phase arrest. These
observations are consistent
with models of budding yeast suggesting
that RAD53 kinases prevent
activation of late origins by regulating
CDC7 and DBF4 kinases
(
29,
46,
51,
62).
Our investigation provides the first evidence that Hsk1p kinase is
itself a potential Cds1p substrate, indicating that there
are levels of
regulation of Hsk1p not necessarily mediated by
its association with
Dfp1p. The requirement for Hsk1p activity
after HU arrest and genetic
interactions with
rqh1 and
rad21ts
mutants in the absence of HU suggest that Hsk1p may function
during S
phase subsequent to origin firing. This second function
may occur
normally during replication and is required for successful
recovery
from replication arrest. Our data also provide evidence
for the
functional separation of the checkpoint kinases Chk1p
and Cds1p, since
deletion of each gene has opposite effects in
hsk1ts cells. Additional genetic analysis under
way should allow us
to forge further ties between
hsk1 and
other components of the
replication and repair pathways in fission
yeast and to determine
the role of
hsk1 in the maintenance
of genome
integrity.
| |
ACKNOWLEDGMENTS |
We are grateful to Hisao Masai for strains and plasmids and
discussion of unpublished work. We thank Tamar Enoch, Greg Freyer, Hisao Ikeda, Paul Russell, Shelley Sazer, Nancy Walworth, and Mitsuhiro
Yanagida for strains and plasmids; Sally Pasion and Dan Sherman for
plasmids; Tony Hunter for antibodies; and Jeff Hodson, John Marlett,
and Andrew Waight for excellent technical assistance. We are also much
indebted to Magdalena Bezanilla, Mike Catlett, Eliana Gomez, Joel
Leverson, Debbie Liang, and Sally Pasion for their critical readings of
the manuscript.
This work was supported by American Cancer Society grant
RPG-00-132-01-CCG (S.L.F.) and Medical Research Council of Canada grant
MOP-36360 (G.W.B.). H.A.S. was partly supported by The Salk Institute
President's Club and the Ralph M. Parsons Foundation. We acknowledge
the Dreyfus Foundation for their support. S.L.F. is a scholar of the
Leukemia and Lymphoma Society. G.W.B. is a special fellow of the
Leukemia and Lymphoma Society.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Molecular
Biology and Virology Laboratory, The Salk Institute for Biological
Studies, 10010 North Torrey Pines Rd., La Jolla, CA 92037-1099. Phone: (858) 453-4100, ext. 1341. Fax: (858) 457-4765. E-mail:
forsburg{at}salk.edu.
Present address: Institute for Cell and Molecular Biology,
Edinburgh EH9 3JR, United Kingdom.
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Abstract
Introduction
