(Received for publication, October 3, 1996, and in revised form, January 19, 1997)
From the Department of Biological Chemistry, University of Michigan, Ann Arbor, Michigan 48109-0606
We report the identification of the
PPS1 gene of Saccharomyces cerevisiae. The
deduced amino acid sequence of PPS1p shows similarity with
protein-tyrosine phosphatases (PTPases) and is most closely related to
a subfamily of PTPases that are capable of dephosphorylating
phosphoseryl and phosphothreonyl residues as well as phosphotyrosyl
residues. Analysis of the predicted amino acid sequence suggests that
the protein consists of an active phosphatase domain, an inactive
phosphatase-like domain, and an NH2-terminal extension.
Mutation of the catalytic cysteinyl residue in the active phosphatase
domain reduced the in vitro activity of the mutant protein
to less than 0.5% of wild type activity, while mutation of the
corresponding cysteinyl residue of the inactive phosphatase-like domain
had no effect on in vitro activity. The PPS1 protein was
expressed in Escherichia coli, and the protein was shown to
catalyze the hydrolysis of p-nitrophenyl phosphate, dephosphorylate phosphotyrosyl, and phosphothreonyl residues in synthetic diphosphorylated peptides and to inactivate the human ERK1
protein. PPS1 transcript abundance is coregulated with that of the divergently transcribed DPB3 gene, which codes for a
subunit of DNA polymerase II, with both transcripts showing peak
abundance in S phase. pps1 mutant strains did not differ
from PPS1 strains under any of the conditions tested, but
overexpression of the PPS1 protein in S. cerevisiae led to
synchronous growth arrest and to aberrant DNA synthesis. A screen for
suppressors of this growth arrest identified the RAS2 gene
as a multicopy suppressor of the PPS1p overexpression arrest. The
arrest was not suppressed by the presence of multicopy
RAS1, TPK2, or TPK3 genes or by the presence of 5 mM cAMP in the growth medium, suggesting that
PPS1 functions in a pathway involving RAS2, but not TPK
kinases or adenylate cyclase.
Protein-tyrosine phosphorylation is a key regulator of a number of cellular processes. Substrate proteins may be phosphorylated by protein kinases and dephosphorylated by protein phosphatases. These reactions are regulated in response to environmental conditions, with the phosphorylation state of substrate proteins serving as an indicator of the appropriate response. The level of phosphorylation of target proteins, and thus the level of response, depends on three factors: the rate of enzymatic phosphorylation, the intrinsic stability of the phosphorylated amino acid, and the rate of enzymatic dephosphorylation. Since phosphotyrosyl residues are quite stable, the level of target phosphorylation depends on the interplay between kinases and phosphatases. In yeast, the response to mating pheromones (1) and medium osmolarity (2) as well as cell cycle events including control of initiation of mitosis (3) have been shown to involve phosphorylation and dephosphorylation of critical protein tyrosyl residues.
In the mating reaction, peptide pheromones are secreted by haploid
cells according to their mating type (a or ). These pheromones bind to specific receptors on cells of the opposite mating
type and initiate a signaling pathway that leads to arrest of the cell
cycle in G1 and to altered gene expression and cell morphology (4). The kinases FUS3p and KSS1p, members of the MAP1 kinase family, are activated as part
of this cascade. Another MAP kinase family member, HOG1p, is involved
in the regulation of the S. cerevisiae response to changes
in medium osmolarity (5, 6). The activity of CDC28p
cyclin-dependent kinase homologs is also modulated by
tyrosine phosphorylation (for a review, see Ref. 7). In S. pombe, the CDC28 homolog CDC2 is inactivated by a specific
tyrosine phosphorylation catalyzed by the Wee1 kinase. Dephosphorylation of this tyrosyl residue by the phosphatase CDC25 results in active CDC2 and allows entry into M phase (8, 9).
Five protein-tyrosine phosphatases have been identified in S. cerevisiae. The PTP1 (10) and PTP2 (11) genes were identified using degenerate PCR primers based on conserved regions of protein-tyrosine phosphatases (PTPases). Conserved residues at the PTPase active site include the sequence HCXXGXXR(S/T), the "signature sequence" of PTPase active sites. The cysteine in this sequence is invariant in PTPases, and mutation of this residue to serine or alanine abolishes PTPase activity (12). These active site residues are contained in a larger sequence of approximately 250 amino acids that define the PTPase domain. Selection for synthetic lethal mutations in PTP2 mutant strains demonstrated that PTP2 has functional overlap with the protein serine/threonine phosphatase PTC1 (13) and that these phosphatases are important for the inactivation of the HOG1 kinase (2). The observation that either a protein-tyrosine phosphatase or a serine/threonine phosphatase is sufficient to regulate a MAP kinase kinase-MAP kinase pair suggests that other PTPases may cooperate with protein serine/threonine phosphatases in this way. A third PTPase gene, YVH1, which also shares the PTPase signature sequence, was identified by analysis of a partially sequenced open reading frame. YVH1 mRNA levels are increased when cells are grown under nitrogen-limiting conditions, and genetic deletion of YVH1 results in a decrease in growth rate (14). Another PTPase, the CDC14 gene product, has been shown to be required for viability. CDC14 was initially characterized as a temperature-sensitive mutation (cdc14ts) that caused cells to arrest at the late nuclear division stage of the cell cycle when incubated at the nonpermissive temperature (15). Cloning and analysis of the CDC14 sequence showed that CDC14p contains the PTPase signature sequence (16). Recently, a fifth PTPase, MSG5, was isolated as a suppressor of a conditional lethal mutation in the GPA1 gene. MSG5 transcription is induced upon exposure to mating pheromone, and deletion of this gene reduces the ability of cells to adapt to the presence of pheromone. Together, these results suggest a role for MSG5 in recovery from G1 arrest following exposure to mating pheromone and suggest that the kinase FUS3p, which must be dephosphorylated for recovery from G1 arrest, is a substrate for MSG5p (17).
Continuing progress in determining the sequence of the S. cerevisiae genome allows us to identify open reading frames that are likely to encode PTPase activity. In this work, we report the isolation and initial characterization of a sixth S. cerevisiae protein-tyrosine phosphatase. The PPS1 gene was identified in a search of DNA sequence data bases with the PTPase signature sequence. Analysis of the deduced amino acid sequence of PPS1p suggests that the protein contains an active phosphatase domain as well as an inactive phosphatase-like domain. Activity assays of wild type protein and site-directed catalytic mutant proteins confirm that the phosphatase activity of the wild type protein resides in the most C-terminal phosphatase domain. We have shown that PPS1p is capable of dephosphorylating phosphotyrosyl and phosphothreonyl residues in synthetic peptides. Although PPS1 is not an essential gene, we have shown that overexpression of the PPS1 protein leads to synchronous growth arrest and to aberrant DNA synthesis. This overexpression arrest is suppressed by the presence of the RAS2 gene on a multicopy plasmid. PPS1 transcript abundance fluctuates during the cell cycle, with peak abundance in S phase. We have named the novel phosphatase PPS1 for rotein hosphatase phase.
Yeast strains (Table I)
were grown in rich medium (YEPD; 1% yeast extract, 2% bacto-peptone,
with 2% dextrose as carbon source) or synthetic medium (SC; 0.67%
yeast nitrogen base without amino acids, supplemented with nutrients as
described (18), with 2% dextrose, galactose, acetate, or glycerol as
carbon source.) All cultures were grown aerobically in rotary action
shakers at 30 °C. Cell growth was monitored spectrophotometrically
at 600 nm. For -factor synchronization experiments, cells were grown
in SC, 2% dextrose to an A600 of 0.5. S. cerevisiae
-factor (Sigma) was added to a
final concentration of 5 µg/ml, and the culture was incubated at
30 °C with shaking for 2 h. Cell morphology was monitored
microscopically to confirm growth arrest. Cells were collected by
centrifugation at room temperature and resuspended in prewarmed SC, 2%
dextrose medium in the absence of
-factor, allowing synchronized
growth to begin. The culture was incubated at 30 °C, and samples
(100 ml) were removed at 15-min intervals. For PPS1 overexpression
experiments, cells were grown in SC
Ura, 2% glucose medium overnight
at 30 °C. Cells were then diluted 1:500 into SC
Ura, 2% galactose
to induce expression of PPS1p from the pGAL1 promoter. When
a larger inoculum was necessary, cells from the overnight culture were
collected by centrifugation, washed, and inoculated into prewarmed SC
Ura, 2% galactose medium. Standard procedures were used for
transformation, mating, sporulation, and tetrad analysis (18). Light
and fluorescence microscopy were carried out using a Zeiss Axioskop
microscope and either a × 40 or × 100 objective lens.
|
Escherichia
coli strain DH5F
was used for routine transformation and
plasmid DNA preparation. Strain BL21/DE3 (Novagen) was used as a host
strain for protein expression. E. coli cultures were grown
aerobically at 37 °C in rich (2 × YT; 1.6% Bacto-peptone, 1%
yeast extract, 0.5% NaCl) medium. Where plasmids carrying the ampicillin resistance gene were present, media contained ampicillin at
a final concentration of 100 µg/ml.
Primers containing
PPS1 sequence (5-CCGACAACCTCCATTTCTCAAC-3
, and
5
-AGGATTTTGTGCATGATCCAGG-3
, for the upstream and downstream primers,
respectively) were used to amplify a 678-bp product from S. cerevisiae chromosomal DNA. The polymerase chain reaction was carried out with denaturation at 94 °C for 1 min, annealing at 55 °C for 1 min, and extension at 72 °C for 1 min. This product was cleaved with BglII and HindIII and ligated
into the BamHI and HindIII sites of plasmid
pGEM3Z (Promega) to produce plasmid pBE20. The PPS1 sequence
from pBE20 was then used as a probe to screen a S. cerevisiae chromosomal library (CENA library; ATCC). Bacterial
colonies containing library plasmids were grown on selective medium and
transferred to nitrocellulose filters. Colonies with plasmids
containing PPS1 sequence were detected by colony
hybridization. The DNA probe was labeled with
[
-32P]dCTP (NEN) in a random primed labeling reaction
(Boehringer Mannheim). Hybridization was carried out in 50% formamide,
5 × Denhardt's solution, 5 × SSPE, 0.1% SDS, and 100 µg/ml salmon sperm DNA at 42 °C for 18 h. Filters were washed
in 1 × SSC, 0.1% SDS at 65 °C prior to autoradiography.
Hybridization-positive colonies were isolated, grown on selective
medium, and rescreened to confirm the presence of PPS1
sequence. Plasmid DNA was isolated from these colonies, and a 3561-base
pair EcoRI-NheI fragment containing the
PPS1 open reading frame was ligated into the
EcoRI and PstI sites of plasmid pUC119 to produce
plasmid pBE22.
A plasmid carrying a disrupted pps1 gene (Fig. 1) was
constructed by cutting pBE22 with BglII. This digestion
removes PPS1 sequence from nucleotides 718-2192, relative
to the presumptive ATG initiator codon, and results in the deletion of
PTPase active site signature sequences from the PPS1 gene.
In place of this sequence, a 3.8-kb insert derived from a
BglII BamHI PvuII digest of plasmid
pNKY51 (19) was inserted, producing plasmid pBE24. pBE24 contains a
URA3 selectable marker, flanked by PPS1 and
adjacent sequence, and was used in the gene disruption procedure.
To express the PPS1 protein in E. coli, plasmid pBE22 was cut with NcoI and SalI. The resulting 3131-bp fragment containing the PPS1 open reading frame was inserted into the NcoI and SalI sites of plasmid pGEX-KG (20). The resulting plasmid, pBE25, contains the PPS1 coding sequence fused in frame to glutathione S-transferase (GST), with the two polypeptides separated by a thrombin cleavage site and a polyglycine kinker. Cleavage of the fusion protein yields glutathione S-transferase and PPS1p products. The PPS1 product of this reaction contains an additional 15 amino acids specified by codons in the linker region NH2-terminal to the initiator methionine of the PPS1 reading frame.
Plasmid pBE29 contains a 937-bp BglII fragment of PPS1 coding sequence (Fig. 1) inserted into the BamHI site of plasmid pBSII KS(+) (Stratagene). This vector was used for the production of single-stranded RNA probes (riboprobes) for northern hybridization experiments. pBE29 was first linearized by digestion with EcoRI, and a single-stranded probe complementary to the PPS1 mRNA was transcribed using T7 RNA polymerase under standard conditions (4).
A vector capable of overexpressing PPS1p in S. cerevisiae was constructed using an EcoRI XhoI fragment of pBE25. This fragment, containing the PPS1 coding sequence, was gel-isolated and ligated into the EcoRI XhoI sites of plasmid pYES2AT, a derivative of pYES2 (Invitrogen). The resulting vector, plasmid pBE33, contains the URA3 and AmpR selectable markers for use in S. cerevisiae and E. coli, respectively. Transcription of PPS1 mRNA is driven by the pGAL1 promoter. Transcription from this promoter is low during growth on dextrose as carbon source and is induced upon a shift to galactose as carbon source (21). Since the PPS1 sequence used to construct plasmid pBE33 includes only the PPS1 coding sequence, translation initiation is driven by the ADE1 translational initiation sequence (22) present in the pYES2AT vector. Vectors directing the expression of site-directed mutant proteins C478S and C725S were similarly constructed.
Disruption of PPS1A 5.9-kb fragment of plasmid pBE24
containing the pps1 allele along with flanking sequence
(Fig. 1B) was gel-isolated after EcoRI
SalI digest of this plasmid. This fragment was transformed into strain GYC86, with transformants selected for uracil prototrophy. Ura+ transformants were sporulated, and the resulting
haploid strains were scored for mating type and markers known to be
present in the parent strain.
Yeast DNA was prepared by the method of Guan et al. (11). 6 µg of DNA was digested with HindIII, separated on a 0.9% agarose gel, and transferred to Nytran membrane (Schleicher and Schuell). Southern hybridization was carried out with random primed NH2-terminal probe (Fig. 1C). Hybridization conditions were the same as those used for the library screen, except that the filter was washed in 0.25 × SSC, 0.1% SDS at 65 °C prior to autoradiography.
Site-directed Mutagenesis and DNA SequencingPlasmid pBE22
was used as the substrate for primer-directed mutagenesis using the
Bio-Rad phagemid mutagenesis system. The following primers were used:
5-TTGACGTTCATGTATTCTGAGGACGGATAT (C478S) and
5
-AAAGTTCTGGTGCATTCTATGGTCGGAGTCTCC (C725S). Both mutations were
sequenced using the dideoxy method (Sequenase kit; U.S. Biochemical
Corp.). The sequence of the entire PPS1 open reading frame
was determined using automated dye terminator sequencing (Applied
Biosystems).
Plasmid pBE25, which contains wild type PPS1
sequence, was transformed into E. coli strain BL21/DE3.
GST-PPS1 fusion protein was purified using a modification of the method
of Guan and Dixon (20). Overnight cultures (60 ml) were grown at
30 °C. These cultures were diluted 1:100 into 6 liters of fresh
medium and grown at room temperature for a further 6 h, until an
A600 of 1 was reached. Expression of the
GST-PPS1 fusion protein was induced by the addition of isopropyl
-D-thiogalactopyranoside to a final concentration of 200 µM. The culture was incubated aerobically for a further
15 h (overnight).
Cells were harvested by centrifugation and washed with 600 ml of
phosphate-buffered saline (PBS; 150 mM NaCl, 16 mM Na2HPO4, 4 mM
NaH2PO4, pH 7.3). After the wash step, cells
were resuspended in 80 ml of PBST (PBS plus 0.1% Triton X-100)
containing 2 mM EDTA, 5 mM dithiothreitol, 0.2 mM phenylmethylsulfonyl fluoride, and 0.2 mM
L-1-chloro-3-[4-tosylamido]-4-phenyl-2-butanone. Cells were lysed by three passages through a French pressure cell at 4 °C,
1200 p.s.i. The resulting lysate was centrifuged at 15,000 × g for 15 min to remove the insoluble fraction. 50 ml of
supernatant was incubated with 30 ml of 50% (v/v) glutathione-agarose
beads at 4 °C for 1 h with gentle shaking. The beads were
washed five times with 30 ml of PBST at 4 °C. The fusion protein was
then eluted from the beads with two washes (20 ml each) of 50 mM Tris, pH 8.0, containing 10 mM glutathione.
The eluate was supplemented to a final concentration of 150 mM NaCl, 2.5 mM CaCl2, 0.1%
-mercaptoethanol. This solution was incubated with 10 µg of
thrombin (Sigma) at room temperature for 20 min. The
thrombin-cleaved mixture was dialyzed twice against 500 ml of 25 mM Tris, pH 7.5, 4 °C for 2 h and loaded on a
Bio-scale Q20 column (Bio-Rad). Protein on the column was washed
isocratically with 60 ml of 25 mM Tris, pH 7.5, 5 mM dithiothreitol and eluted with a linear gradient of
0-600 mM NaCl in this buffer. p-Nitrophenyl
phosphate was used as a substrate to assay the phosphatase activity of
the PPS1 protein during purification (23). Protein fractions were
monitored by polyacrylamide gel electrophoresis, and protein
concentration was determined using a BCA assay system (Bio-Rad).
Mutant proteins C478S and C725S were expressed and purified using the same methods described for the wild type PPS1 protein. Wild type and mutant proteins were assayed for MAP kinase inactivation using the method of Zheng and Guan (24). Assays employing the synthetic diphosphorylated polypeptide DHTGFLpTEpYVATR were carried out using the methods described by Denu et al. (25). Wild type and mutant proteins were incubated at 30 °C in 0.05 M Tris, 0.05 M bis-Tris, 0.1 M acetate, pH 7.5, in the presence of 1.25 mM peptide. At various times, samples were removed and stopped by the addition of an equal volume of 1.5 M acetic acid. Samples were analyzed on a Vydac C18 column attached to an Applied Biosystems high pressure liquid chromatography system. Peptides were eluted with a linear gradient of 15-35% buffer B (80% acetonitrile, 20% water, 0.1% trifluoroacetic acid). Buffer A was 0.1% trifluoroacetic acid in water. This method allows for the resolution of all possible phosphorylation states of the peptide substrate.
RNA AnalysisTotal yeast RNA was prepared using the method
of Schmitt et al. (26). Poly(A)+ mRNA was
purified from samples of total RNA by oligo(dT) chromatography (PolyAtract system; Promega). RNA was separated on a 1%
formaldehyde-agarose gel, transferred to Nytran membrane, and probed
with either random primer-labeled PPS1 probe or PPS1 riboprobe
transcribed from plasmid pBE29 (Fig. 1C). For
experiments using random primer labeled probes, hybridization
conditions were those described for Southern hybridization, except that
100 µg/ml E. coli tRNA (Sigma) was used
as a nonspecific competitor. For experiments with riboprobes,
hybridization was carried out in 50% formamide, 1 mg/ml bovine serum
albumin, 400 mM sodium phosphate buffer, pH 7.1, 5% SDS,
and 100 µg/ml E. coli tRNA at 42 °C. Double-stranded
probes complementary to DBP3 and ACT1 messages
were generated by random-primed labeling of restriction digests of
plasmids pBE22 and pGEMact (27), respectively. Band intensities,
representing the relative abundance of each transcript, were measured
using a Molecular Dynamics PhosphorImager.
Yeast strains were grown as described above. 1-ml samples were harvested by centrifugation, washed with 1 ml of PBS, and fixed in 70% ethanol overnight. After fixation, the cells were collected and resuspended in 0.5 ml of sodium citrate, pH 7.0, and sonicated briefly to disperse clumps. RNase A was added to a final concentration of 1 mg/ml, and the samples were incubated at 50 °C for 1 h. Cells were washed again with PBS and stained with propidium iodide (50 µg/ml) for 1 h at room temperature. Cell clumps were again dispersed by brief sonication immediately prior to flow cytometry analysis. Flow cytometry was carried out in a Coulter Epics Elite flow cytometer.
Multicopy Suppressor ScreenA strain carrying the PPS1
overexpression plasmid (pBE33) was transformed with a YEp13-based
S. cerevisiae genomic library (28). Transformants were
selected on SC medium lacking uracil and leucine (SC Ura,
Leu) with
dextrose as carbon source. A total of 65,000 colonies were screened for
suppression of the PPS1p overexpression arrest by replica plating on SC
Ura,
Leu medium that contained galactose as the carbon source.
Under these conditions, cells carrying the pBE33 do not grow. Sixty
colonies that grew under these conditions (MSP+;
ulticopy uppressor of PS1
overexpression arrest) were selected for further study. Plasmids from
these colonies were amplified in E. coli and subjected to
another multicopy suppressor screen. Twenty-six colonies contained
plasmids that were MSP+ for two successive screens. Single
library plasmids were isolated from these colonies, confirmed as
MSP+, and sequenced to determine the identity of the
insert.
A search of S. cerevisiae sequence in the GenBankTM data base (29) with the PTPase active site signature sequence (HCXXGXXR(S/T); Ref. 30) resulted in the identification of a putative PTPase open reading frame. This sequence, named PPS1, is present in GenBankTM accession X76053[GenBank], a 32,420 base pair segment located on the right arm of S. cerevisiae chromosome II (31). Open reading frames for the DPB3, RIF1, YML27, and SNF5 genes are also present on this segment of chromosome II sequence. The PPS1 open reading frame is 2421 base pairs in length, and is predicted to code for a protein of 807 amino acids, including the active site sequence HCMVGVSRS.
DNA sequence from GenBankTM accession X76053[GenBank] was used to construct a predicted amino acid sequence of the PPS1 protein. Alignment of the PPS1p amino acid sequence with other S. cerevisiae protein-tyrosine phosphatases revealed that the putative PPS1 protein consists of two domains with amino acid sequence similarity to the active site region of PTPases and an amino-terminal extension (Fig. 2, A and B). Both of the PTPase domains of the PPS1p molecule show greater sequence similarity to the dual specific family of protein phosphatases than to the family of tyrosine-specific protein phosphatases. This sequence similarity suggests that the PPS1 protein is capable of dephosphorylation of substrate phosphoseryl and phosphothreonyl residues as well as phosphotyrosyl residues. The presence of two regions of PTPase sequence similarity in PPS1p is unique among the known S. cerevisiae PTPases. The most C-terminal PTPase domain contains a good match to the PTPase active site signature, including all aminoacyl residues invariant across known PTPases. This domain includes the sequence identified in our original GenBankTM search. The active site region of the upstream PTPase-like domain, on the other hand, is a poor match to the PTPase consensus. This active site region lacks the histidyl and arginyl residues shown to be invariant across PTPases (32) and is predicted to lack PTPase activity. Nonetheless, the upstream PTPase-like domain shows convincing sequence similarity to other PTPase domains across its entire length (Fig. 2C) and, when used to query sequence data bases, produces PTPases among the search results. The amino-terminal extension of PPS1p consists of about 300 amino acids and does not show significant sequence similarity to any other known DNA or protein sequence.
Isolation and Initial Characterization of the PPS1 Gene
The PPS1 gene was isolated using colony filter hybridization to identify a plasmid containing PPS1 sequence from a S. cerevisiae chromosomal library. The clone contained a 12,500-bp insert that included the complete sequence of the PPS1 and DPB3 genes. A 3561-base pair fragment of this library clone containing the entire PPS1 coding sequence, along with 433 bp preceding the presumptive ATG initiator codon and 709 bp downstream of the terminator codon, was ligated into plasmid pUC119. This subclone, pBE22, was used as the substrate for subsequent manipulations of PPS1 sequence. Sequence of the PPS1 open reading frame was determined using automated dye terminator sequencing. The sequence determined in this work was identical to that reported in GenBank accession X76053[GenBank] (Fig. 2A).
To determine if the PPS1 is an essential gene, we conducted
gene replacement experiments with pps1 alleles.
pps1
alleles were constructed by replacement of
nucleotides 718-2192 of the PPS1 coding sequence, including
both the upstream and downstream active sites, with the
hisG::URA3::hisG cassette from plasmid pNKY51 (Ref. 19; Fig. 1B). These pps1
alleles
were introduced into diploid strain GYC86 by linear transformation.
Twelve Ura+ transformants were selected for analysis. These
transformants were sporulated, and the resulting tetrads dissected.
Each of two dissections of the 12 transformants yielded four viable
spores per tetrad, indicating that the PPS1 gene is not
essential. Spores from each tetrad were scored for markers known to
exist in the parent strain as well as for mating type and uracil
prototrophy. All markers scored segregated as expected, with
Ura+:Ura
segregating 2:2. Two transformants
(strains BE229 and BE230; Table I) were subjected to
Southern blot analysis using a probe complementary to the undeleted 5
sequence of PPS1. The results of this analysis indicate that
one copy of the PPS1 gene has been disrupted in each of these strains.
Confirmation of this result was provided by Southern analysis of
haploid sporulation products of strain BE229 (PPS1/pps1
;
Table I) in which the 2.9-kb band representing the
pps1::URA3 allele segregates with uracil
prototrophy (data not shown). A Northern hybridization using a
single-stranded probe complementary to the PPS1 mRNA was
carried out to confirm the absence of PPS1 transcript in
haploid strains carrying the pps1
allele. We used a
single-stranded probe complementary to the PPS1 mRNA in
this experiment to rule out hybridization signals that might arise from
the noncomplementary strand of a double-stranded probe.
Poly(A)+ mRNA was prepared from strains GYC86, GYC121,
BE231, BE232, BE233, and BE234 (Table I). The results of this
hybridization show that, as expected, a 2.7-kb transcript complementary
to the PPS1 probe is present in PPS1 strains but
not in pps1
strains (data not shown). Taken together,
these results show that we have succeeded in deleting the
PPS1 gene and that pps1
mutant strains are
able to grow normally, at least under the conditions used in the tetrad dissection and marker analyses.
The observation that PPS1 is dispensable was not surprising.
Genetic deletion of S. cerevisiae protein-tyrosine and
dual-specificity phosphatases PTP1, PTP2, and
YVH1 results in relatively subtle growth defects
(YVH1; Ref. 14) or no detectable phenotype (PTP1, PTP2; Refs. 10 and 11). Several other putative
protein-tyrosine phosphatase genes have been deleted without phenotypic
consequence.2 We characterized the growth
of haploid strains carrying the pps1 allele under various
conditions. Doubling time in liquid culture of the pps1
strains was not significantly different from the doubling time of the
otherwise isogenic PPS1 strain under any of the conditions
tested, including growth at 25, 30, and 37 °C, growth in minimal
medium, and growth on a variety of fermentable and nonfermentable
carbon sources. PPS1 and pps1
strains were also grown on solid medium under these conditions, and no differences in colony morphology between wild type and mutant strains were noted.
Because S. cerevisiae responds both to altered medium
osmolarity and to the presence of pheromone by regulated changes in protein-tyrosine phosphorylation, we tested the response of
PPS1 and pps1 strains to changes in medium
osmolarity and to pheromone. We found no significant differences in the
doubling times or in colony or cell morphology between PPS1
and pps1
strains grown in medium of high osmolarity (YPD
plus 0.9 M NaCl). We tested the ability of cells carrying
the pps1
allele to produce pheromone and to respond to
the presence of pheromone in the medium. Both MATa
pps1
and MAT
pps1
strains were found to
produce pheromone normally, as judged by the diameter of the zone of
growth inhibition of a lawn of pheromone-hypersensitive tester stains (34, 35). The sensitivity of MATa PPS1 and MATa pps1
strains to the presence of
-factor was also
investigated. No difference in the diameter of the zone of growth
inhibition by
-factor of a lawn of cells was noted when the wild
type and the mutant strains were compared. An analysis of the abundance of the PPS1 transcript before and after exposure to mating
pheromone or increased osmolarity was also undertaken.
Poly(A)+ mRNA was isolated from liquid cultures before
and at several time points after the addition of either 0.9 M NaCl or
-factor. The mRNA was separated on an
agarose gel, blotted, and hybridized to a double-stranded PPS1 probe.
Like the single-stranded probe, the double-stranded probe hybridized to
a band of approximately 2.7 kb. No significant change in the abundance
of the PPS1 transcript was noted between cells grown in rich
and minimal medium or in response to the addition of 0.9 M
NaCl or
-factor (data not shown). These experiments indicate that
the signaling pathways controlling the mating response and the response
to medium osmolarity are intact in strains lacking PPS1p function. The
apparently normal responses of pps1
strains to pheromone
and osmolarity suggest that PPS1p does not act to dephosphorylate the
MAP kinase family members FUS3p or HOG1p, activated as part of the
mating and osmolarity responses, respectively (4, 5), but it remains
possible that PPS1p is a redundant regulator of one or both of these
pathways or indeed of another MAP kinase signaling pathway.
Plasmid pBE25
contains glutathione S-transferase coding sequence fused to
the PPS1 open reading frame, with transcription driven by
the E. coli Ptac promoter. E. coli
cells containing this plasmid were grown at room temperature, and
protein expression was induced over a relatively long period (15 h)
with low levels of isopropyl -D-thiogalactopyranoside.
We found that other conditions, such as growth at 37 °C, higher
levels of isopropyl
-D-thiogalactopyranoside, and
shorter induction times led to the production of insoluble or inactive
protein. GST-PPS1 fusion protein produced was purified by glutathione
affinity batch methods, and the GST domain was cleaved with thrombin.
This step yielded a mixture of polypeptides, including PPS1p (predicted
molecular mass, 91.7 kDa), thrombin, the GST domain of the fusion
protein, and several other polypeptides, as determined by
SDS-polyacrylamide gel electrophoresis (Fig. 3,
lane L). This mixture was further purified using an anion
exchange step with a 0-600 mM NaCl gradient. The PPS1
protein was eluted from the column at approximately 275 mM
NaCl (Fig. 3, lanes 47 and 48). Fractions
containing homogenous PPS1p were pooled and assayed for phosphatase
activity using p-NPP as a substrate. p-NPP activity was present only in fractions 46-51, with peak activity in
fraction 47, in good agreement with the relative abundance of the PPS1
protein band in these fractions.
Purified PPS1 protein was assayed at various pH values, ranging from
5.5 to 9.5. The pH optimum for the PPS1-catalyzed hydrolysis of
p-NPP was determined to be 7.5. At pH 7.5, the
Km of PPS1p for p-NPP was measured at
13.4 mM. When assayed at this pH, using saturating
concentrations of p-NPP, the turnover number was calculated
at 0.24 s1. This activity was inhibited by the presence
of 1 mM sodium vanadate in the assay buffer. PPS1 protein
was also able to inactivate human MAP kinase (ERK1p; Ref. 24), although
a 1:1 mixture of MAP kinase and PPS1 protein resulted in only a 50%
reduction in MAP kinase activity against myelin basic protein. The
presence of 1 mM sodium vanadate in the MAP kinase
inactivation assay buffer resulted in no inactivation of MAP kinase by
the PPS1 protein. Three truncated glutathione S-transferase
fusions of PPS1p were also expressed and partially purified. These
truncations contained 1) the carboxyl-terminal 776 amino acids (both
phosphatase domains and most of the NH2-terminal
extension), 2) the carboxyl-terminal 493 amino acids (both phosphatase
domains), and 3) the carboxyl-terminal 249 amino acids (downstream
phosphatase domain only). Glutathione-eluted fusion proteins of each of
these three constructs catalyzed the hydrolysis of p-NPP at
similar rates, suggesting that the pNPP activity of PPS1 resides in the
most C-terminal phosphatase domain.
Experiments with truncated PPS1 proteins
indicated that phosphatase activity is contributed by the most
C-terminal phosphatase domain. To confirm this result, the putative
catalytic cysteinyl residue (12) in each domain was changed a seryl
residue. Mutant proteins were purified using the methods developed for
purification of the wild type protein and were assayed for
p-NPP hydrolysis and MAP kinase inactivation. The results of
these experiments support the hypothesis that the downstream
phosphatase domain is active while the upstream phosphatase-like domain
is largely inactive. The C478S mutant protein, which contains an
undisrupted downstream phosphatase domain, showed a pH optimum,
Km for p-NPP, and turnover number
indistinguishable from that of the wild type protein. In contrast, the
C725S mutant protein had a turnover number of approximately 0.001 s1, less than 0.5% of that of the wild type protein.
Furthermore, while the wild type and C478S mutant proteins were able to
inactivate human MAP kinase as described above, the C725S mutant
protein showed no activity in this assay.
Denu and co-workers (25) have shown that the human dual specificity
phosphatase VHR is capable of dephosphorylating both phosphothreonyl
and phosphotyrosyl residues in a diphosphorylated synthetic peptide
containing human MAP kinase sequence. In these studies, VHR rapidly
dephosphorylated the phosphotyrosyl residue and subsequently
dephosphorylated the phosphothreonyl residue at a much slower rate. We
carried out similar assays to measure the rates of dephosphorylation of
the same diphosphorylated peptide catalyzed by the PPS1 protein. As
shown in Fig. 4, wild type PPS1p catalyzes
dephosphorylation of both phosphotyrosyl and phosphothreonyl residues.
Like VHR, PPS1p shows a preference for phosphotyrosyl over
phosphothreonyl residues. Unlike VHR, where these rates differ by about
2000-fold, PPS1 acts to dephosphorylate phosphothreonyl residues at a
rate about 50-100-fold lower than the rate of phosphotyrosyl dephosphorylation. The PPS1p C478S mutant protein showed a time course
of dephosphorylation similar to that of the wild type enzyme, while the
PPS1p C725S showed a rate of phosphotyrosyl dephosphorylation less than
1% of that of the wild type enzyme.
PPS1 Transcript Abundance Fluctuates during the Cell Cycle
The PPS1 open reading frame lies adjacent to the
open reading frame of the DPB3 gene, a subunit of DNA
polymerase II (Ref. 36; Fig. 1A). DBP3 was
isolated by Araki et al. (36) using an antibody screen of a
S. cerevisiae expression library. dpb3 mutants
are viable but show a mutator phenotype. Strains carrying the
dpb3
allele show a 2-6-fold increase in the reversion
rate of point mutations, suggesting that the DPB3p subunit may be
involved in maintaining fidelity of DNA replication. These workers also showed that the DPB3 transcript abundance fluctuates during
the cell cycle, in a pattern similar to that shown by other transcripts whose products are involved in DNA replication (36). The divergent arrangement and proximity of the DPB3 and PPS1
open reading frames are consistent with possible coordinated regulation
of expression of these genes.
Poly(A)+ RNA was purified from synchronized cultures of
strain GYC121 (PPS1). Cultures were grown to an
A600 of approximately 0.5. At this time,
-factor was added, and the culture was allowed to enter growth
arrest. Cells were viewed microscopically to confirm that the culture
consisted of at least 90% unbudded cells, indicating that
-factor
arrest had occurred. Cells were pelleted and resuspended in prewarmed
medium in the absence of
-factor, allowing synchronized growth to
begin. The culture was sampled at 15-min intervals, and
poly(A)+ RNA was isolated from each sample. The doubling
time of the synchronized culture was measured at 78 min. Northern
transfers of these samples were probed with random primer-labeled
probes specific for DPB3, PPS1, and actin.
DPB3 and PPS1 transcript levels were normalized to the intensity of the actin transcript, which did not fluctuate during the cell cycle.
The results of this experiment are shown in Fig. 5. The
relative abundance of the PPS1 transcript during the cell
cycle is very similar to that of DBP3. Since DPB3
is known to be cell cycle-regulated, with transcript abundance peaking
in early S phase (36), the PPS1 transcript also peaks in
early S phase. This pattern of expression supports the hypothesis that
DPB3 and PPS1 are coregulated and suggests a role
for PPS1p in the regulation of some aspect of DNA synthesis, the major
process of the S phase cell. Alternatively, the PPS1 protein might be
involved in the regulation of passage into or out of S phase. Since
genetic deletion of PPS1 did not lead to a detectable
phenotype, we could not use these pps1 mutants to help
elucidate the role of PPS1. In a complementary approach designed to help distinguish the role of PPS1, we
overexpressed the PPS1 protein in S. cerevisiae.
Overexpression of PPS1p Is Deleterious and Leads to Abnormal DNA Synthesis
Plasmid pBE33, a plasmid designed to overexpress the
PPS1 protein in S. cerevisiae, contains a 2µ origin of
replication, a URA3 selectable marker, the PPS1
gene under the control of the pGAL1 promoter, and translation initiator
sequences from the ADE1 gene. Strains GYC86, GYC121, BE240
(GYC121/pBE33), and BE239 (GYC121/pYES2AT (no insert)) were grown in
liquid culture with dextrose as the carbon source overnight and diluted
1:500 into fresh medium in the presence of galactose to activate
transcription from the pGAL1 promoter. After 8 h of growth on
galactose, strains GYC86, GYC121, and BE239 were growing normally, with
doubling times of approximately 100-110 min, while strain BE240 was
not detectably growing (doubling time >1000 min). Microscopic
examination of these cultures (Fig. 6) revealed that
strains GYC121 and BE239 were 70-75% budded, the normal state for a
growing culture of S. cerevisiae. Strain BE240, the
PPS1p-overexpressing strain, on the other hand showed only 11% budded,
consistent with a synchronized arrest of this culture.
To confirm that this arrest was a specific consequence of the overexpression of PPS1p, we examined the growth rate and percentage of budded cells in several control cultures. Strain BE240 showed no abnormalities in growth rate or the percentage of budded cells when grown on dextrose, where transcription from the pGAL1 promoter is not activated. Furthermore, expression of catalytically inactive PPS1p (C725S) or of a related dual specificity protein phosphatase (YVH1p) from the same expression vector did not lead to noticeable changes in the growth rate or morphology of the overexpressing strain, supporting the specific nature of the effects of the overexpression of PPS1p. Finally, similar phenotypes were seen with three independent isolates of strain BE240, indicating that the synchronous arrest phenotype is not a result of a mutation occurring in the vector construction or transformation procedures.
The level of PPS1p overexpression in strain BE240 was examined using
antibody methods. Total soluble protein from various strains was
separated on denaturing acrylamide gels and transferred, and the
resulting blots were probed with PPS1 antisera. PPS1p was detectable at
wild type levels of expression and was absent in pps1
mutant strains. Three independent experiments indicated that PPS1p
levels in strain BE240 were increased 15-30-fold after 2 h of
growth in the presence of galactose and 8-10-fold after 8 h. This
moderate level of PPS1p overexpression is compatible with the observed
arrest occurring as a consequence of specific interaction between
overexpressed PPS1p and its physiological substrate.
To further characterize the phenotype of PPS1p-overexpressing strains,
the above strains, GYC86, GYC121, BE240 (GYC121/pBE33), and BE239
(GYC121/pYES2AT (no insert)), were grown overnight in medium containing
dextrose and diluted 1:500 into medium containing galactose, as
described. After the growth arrest, phenotypes were confirmed, and the
cells were fixed and stained with propidium iodide. The cells were
mononucleate when viewed under a fluorescence microscope. The cells
were then subjected to flow cytometry analysis (Fig. 7).
Haploid strain GYC121 showed the expected fluorescence peaks at 1n and
2n DNA content; diploid strain GYC86 showed peaks at 2n and 4n. Strain
BE239, like the parent strain GYC121, showed peaks at 1n and 2n (data
not shown). Strain BE240, the induced PPS1p overexpressor, showed a
markedly different fluorescence intensity pattern. This strain showed a
broad peak of cells with DNA content approaching 2n. Some cells
contained amounts of DNA greater than 2n, indicating that these cells
may have undergone more than a single round of DNA replication. These
results, along with the expression pattern of the PPS1 transcript, are
consistent with a role for PPS1 in maintaining S phase. In normal
cells, the transcript is most abundant during S phase and decreases
2-3-fold as the synchronized culture enters G2 phase. When
PPS1p is overexpressed, the cells exhibit an inability to exit S phase,
as indicated by the high concentration of DNA in each cell.
Multicopy Suppression of the PPS1p Overexpression Arrest
The growth arrest of PPS1p overexpressors allowed us to select for genes that, when present on multicopy vectors, overcome the defect that leads to this arrest. We would expect that kinases and their regulators would be among the genes identified with this screen, since increased expression of this class of molecules might counteract the effects of increased levels of phosphatase expression. Library plasmids were transformed into a strain carrying the PPS1p overexpression vector and screened for a multicopy suppression of PPS1p overexpression (MSP+) phenotype. MSP+ plasmids were then sequenced to identify the inserted DNA. Of the 26 plasmids that were found to confer an MSP+ phenotype in two successive rounds of screening, 11 contained inserts that included the open reading frame for the RAS2 gene. In S. cerevisiae, RAS2p is a well known regulator of adenylate cyclase (37), with increased RAS2 activity leading to increased intracellular cAMP levels, activation of the cAMP-dependent protein kinases TPK1p, TPK2p, and TPK3p, and ultimately to the breakdown of storage carbohydrate (38). We tested the ability of other molecules involved in this pathway to suppress the PPS1p overexpression defect. Neither the addition of 5 mM cAMP to the growth medium nor the presence of RAS1, TPK2, or TPK3 on a high copy vector restored the ability of PPS1p-overexpressing strains to grow on galactose. Taken together, these results suggest a role for PPS1p in regulation of a pathway involving RAS2p but not RAS1p, adenylate cyclase, or the cAMP-dependent protein kinases. To confirm that addition of cAMP to the growth medium had the expected effect on the accumulation of storage carbohydrates in these strains, we carried out iodine staining of cells grown in the presence or absence of cAMP (Table II). The results of these experiments show that exogenous cAMP has the expected effect on the accumulation of storage carbohydrates. No strain showed dark iodine staining when grown in the presence of 5 mM exogenous cAMP. In contrast, cells carrying empty vector or RAS2 in multicopy showed dark iodine staining, while cells carrying TPK1 or TPK2 in multicopy did not stain. These observations confirm that the presence of the TPK genes has the expected effect on the accumulation of storage carbohydrates and show that the presence of RAS2 in multicopy does not lead to decreased levels of carbohydrate in this strain.
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The structure of the PPS1-DPB3 region of chromosome II suggested possible coregulation of these genes, and this was confirmed by measurement of transcript abundance. Coregulation of other divergently transcribed genes has been shown to occur in S. cerevisiae. The best studied example of this type of regulation is the promoter region that directs the expression of the GAL1 and GAL10 genes (39). This promoter region contains both positive and negative regulatory elements that allow coordinated activation or repression of GAL1 and GAL10. Since both of these genes specify proteins involved in the catabolism of galactose, it is reasonable that their regulation would be coordinated. Similarly, the sporulation-specific genes SPS18 and SPS19 are divergently transcribed and coregulated. These genes were isolated independently and subsequently shown to share promoter elements (40). Although these two genes are coregulated, the SPS18 gene is transcribed at about four times the rate of transcription of the SPS19 gene. We see a similar pattern of expression of DPB3 and PPS1. Although the abundance of these transcripts fluctuates in concert during the cell cycle, the DPB3 transcript is more abundant than the PPS1 transcript at all stages of the cell cycle.
Nature of Defects Caused by PPS1 OverexpressionHaving
carried out an analysis of the phenotype of pps1 mutants
without discovering any set of conditions where the pps1
allele is deleterious, we investigated the effects of overexpression of
PPS1p. As noted, PPS1p overexpression leads to two major defects; cells
overexpressing PPS1p arrest in a synchronous fashion that is
morphologically similar to a G1 arrest, and these cells
contain a G2 amount of DNA, as determined by flow cytometry
analysis. These consequences of PPS1p overexpression appear to be
contradictory. Cells that are arrested in G1 would be
expected to be unbudded and to have a G1 amount of DNA.
Conversely, cells that contain a G2 amount of DNA would not
be expected to be in an unbudded state. The trivial explanation of
these two defects postulates that they are unrelated. It is possible
that either the apparent G1 arrest or the G2
amount of DNA per cell represents the consequence of an event normally
mediated by PPS1p, while the other is an overexpression artifact. It
should be noted, however, that overexpression of the related YVH1p
phosphatase in otherwise isogenic strains did not lead to any
detectable phenotype and that a relatively modest 15-fold
overexpression of PPS1p is sufficient to induce cells to arrest.
Another possibility is that the PPS1p phosphatase has multiple
functions during the cell cycle and that overexpression causes defects
at each point of action. These phenotypes of PPS1p overexpressors are
similar to those shown by S. cerevisiae cells expressing
Cdi1, a human protein phosphatase isolated on the basis of its
interaction with human cyclin-dependent kinases (41). Gyuris and co-workers (41) report that expression of this PTPase from
the pGAL1 promoter results in a morphology similar to G1 arrest as well as nuclear abnormalities. In HeLa cells, Cdi1 transcript abundance was shown to peak in early S phase. Although Cdi1p and PPS1p
do not share outstanding sequence similarity, we suggest that these
enzymes may have similar roles in regulating progression through the
cell cycle in yeast (PPS1p) and humans (Cdi1p).
Taken together, the pattern of PPS1 expression (peak transcript abundance correlated with other transcripts involved in DNA synthesis) and the fact that some cells in the PPS1p-overexpressing culture appeared to have undergone more than one round of DNA replication suggest a role for the PPS1p phosphatase in maintenance of the DNA synthesis phase of the cell cycle. In this model, PPS1p activity maintains in the dephosphorylated state some substrate that, when phosphorylated, promotes exit from the synthesis phase of the cell cycle. Under conditions where PPS1p is overexpressed, this substrate remains in the dephosphorylated state, and exit from S phase is delayed. This model is supported by the observation that the deleterious effects of PPS1p overexpression require a catalytically active phosphatase.
Suppression of PPS1p Overexpression Defects by RAS2The
results of a multicopy suppressor screen indicate that RAS2,
but not RAS1, cAMP, TPK2, or TPK3, is
able to suppress the PPS1p overexpression defect. Our results point
toward a role for PPS1p in a pathway involving RAS2p but not adenylate
cyclase. This conclusion is strengthened by the observation that the
RAS2 multicopy suppression plasmid, while sufficient to
overcome the PPS1p overexpression arrest, does not lead to decreased
levels of storage carbohydrate, indicating that the adenylate
cyclase-TPK pathway is not activated under these conditions. Morishita
and co-workers (33) have reported genetic interactions between
RAS2 and several genes, including the protein kinase genes
DBF2, CDC5, and CDC15, that function
during the mitosis phase of the cell cycle. We predict that the PPS1
protein phosphatase acts to down-regulate these kinases, their
regulators, or their substrates during the DNA synthesis phase of the
cell cycle. A summary of these predictions is shown in Fig.
8. In this scheme, PPS1 acts during S phase to dephosphorylate a substrate protein, which, when phosphorylated by cell
cycle kinases, allows M phase to proceed. Overexpression of PPS1 leads
to hypophosphorylation of the substrate protein and to an inability to
exit S phase. The presence of RAS2 in multicopy does not activate the
cAMP-TPK pathway but allows cell cycle kinases to phosphorylate the
substrate protein and promotes normal cell cycle progression.
Alternative models of PPS1p-RAS2p interaction are also possible. The point of action of PPS1p has not been elucidated in this work, and future experiments will be directed at the identification of PPS1p substrates. In addition to the RAS2 gene, the multicopy suppressor screen identified the protein phosphatase gene PPH22 as a common multicopy suppressor of the PPS1p overexpression arrest. We are currently investigating the possibility that PPH22p is a regulator of PPS1p activity.
We thank John Denu, Robert Fuller, Kun Liang Guan, Quinn Vega, and Beverly Yashar for helpful discussions and critical reading of the manuscript.