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Previous Article | Next Article 
Molecular and Cellular Biology, June 2000, p. 4199-4209, Vol. 20, No. 12
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Two Regulators of Ste12p Inhibit
Pheromone-Responsive Transcription by Separate Mechanisms
K. Amy
Olson,
Chris
Nelson,
Georgia
Tai,
Wesley
Hung,
Carl
Yong,
Caroline
Astell, and
Ivan
Sadowski*
Department of Biochemistry and Molecular
Biology, University of British Columbia, Vancouver, British
Columbia, Canada
Received 25 October 1999/Returned for modification 22 December
1999/Accepted 13 March 2000
 |
ABSTRACT |
The yeast Saccharomyces cerevisiae transcription factor
Ste12p is responsible for activating genes in response to MAP kinase cascades controlling mating and filamentous growth. Ste12p is negatively regulated by two inhibitor proteins, Dig1p (also called Rst1p) and Dig2p (also called Rst2p). The expression of a C-terminal Ste12p fragment (residues 216 to 688) [Ste12p(216-688)] from a GAL promoter causes FUS1 induction in a strain
expressing wild-type STE12, suggesting that this region can
cause the activation of endogenous Ste12p. Residues 262 to 594 are
sufficient to cause STE12-dependent FUS1
induction when overexpressed, and this region of Ste12p was found to
bind Dig1p but not Dig2p in yeast extracts. In contrast, recombinant
glutathione S-transferase-Dig2p binds to the Ste12p
DNA-binding domain (DBD). Expression of DIG2, but not
DIG1, from a GAL promoter inhibits
transcriptional activation by an Ste12p DBD-VP16 fusion. Furthermore,
disruption of dig1, but not dig2, causes
elevated transcriptional activation by a LexA-Ste12p(216-688) fusion.
Ste12p has multiple regions within the C terminus (flanking residue
474) that can promote multimerization in vitro, and we demonstrate that
these interactions can contribute to the activation of endogenous
Ste12p by overproduced C-terminal fragments. These results demonstrate
that Dig1p and Dig2p do not function by redundant mechanisms but rather
inhibit pheromone-responsive transcription through interactions with
separate regions of Ste12p.
| |
INTRODUCTION |
Ste12p activates signal-responsive
transcription in Saccharomyces cerevisiae. In haploid
yeasts, Ste12p is required for the response to mating pheromone
produced by the opposite mating type and for invasive growth, possibly
in response to limiting nutrients (13). In diploids, Ste12p
regulates pseudohyphal development in response to nitrogen starvation
(13). In each case, Ste12p induces the transcription of
genes necessary to produce the appropriate cell cycle progression and
morphological alterations. Since Ste12p is necessary for responses to
separate signals that cause substantial changes in the organism, its
activity must be tightly regulated. Part of the differential function
of Ste12p in regulating separate classes of genes is mediated through
interactions with different DNA-binding partners. Ste12p binds
cooperatively with itself, Mcm1p, and 
1p to regulate
pheromone-responsive genes (36, 37, 42, 43) and with Tec1p
to activate genes required for filamentous growth (22).
Regulation of Ste12p's function in pheromone and filamentous responses
appears to involve overlapping signaling mechanisms that control the
MAP kinases Fus3p and Kss1p, respectively (23). In response
to mating pheromone, Fus3p is thought to phosphorylate substrates that
mediate the activation of pheromone-responsive transcription and cause
the transient G1 cell cycle arrest required for mating.
Downstream targets of Fus3p may include Ste12p (9, 16, 38),
the two inhibitors of Ste12p encoded by DIG1 (also called
RST1) and DIG2 (also called RST2)
(3, 40), and Far1p, which inhibits Cdc28-G1
cyclin complexes and promotes pheromone-responsive cell cycle arrest
(9, 26, 41). The unactivated form of Fus3p has also been
shown to inhibit inappropriate activation of Kss1p by the pheromone
response pathway (23). Similarly, the unactivated form of
Kss1p inhibits filamentous response element-dependent transcription,
while active Kss1p is required for the expression of filamentous
response genes (2, 23). Like Fus3p, Kss1p is known to
phosphorylate Dig1p and Dig2p (5), but the functional significance of these phosphorylations has not been determined.
Two inhibitors of Ste12p encoded by DIG1 and DIG2
were identified in two-hybrid screens with Kss1p (5) and
Cln1p and Cln2p (40) and have been shown to be present in
complexes that also contain Ste12p and Kss1p and/or Fus3p (5,
40). Dig1p and Dig2p appear to negatively regulate the function
of Ste12p in both filamentous growth and pheromone response (3, 5,
40). Pheromone treatment causes phosphorylation of Dig1p and
Dig2p (40), and it has been suggested that the activation of
Ste12p may be mediated through inhibition of the function of these
negative regulators (40). Consistent with this model, a
minimal pheromone-responsive segment of Ste12p was shown to interact
with Dig1p and Dig2p in a two-hybrid analysis (27). Dig1p
and Dig2p are 22% identical over their entire sequences and share a
60-amino-acid segment with 64% similarity. Disruption of
DIG1 or DIG2 individually has no apparent effect
on cell morphology or pheromone response, but yeasts bearing
disruptions of both dig1 and dig2 form extensive filaments and show elevated expression of pheromone-responsive genes
(5, 30, 40). Because of their sequence similarity and
apparent phenotypic redundancy, these two inhibitors have generally
been considered to have similar, if not identical, functions (3,
5, 40). However, DIG1 is expressed constitutively, whereas DIG2 has a cluster of upstream pheromone response
elements and is induced approximately twofold in response to pheromone (5, 30).
Because an understanding of Ste12p regulation is complicated by its
interaction with multiple regulatory proteins and DNA-binding partners,
we have sought to simplify analysis of the functions of Dig1p and Dig2p
by examining their effects on the pheromone-responsive gene
FUS1, which Ste12p can activate on its own (14).
We have found that Dig1p and Dig2p bind to separate regions of Ste12p; Dig1p interacts directly with the Ste12p central region (residues 309 to 547), while Dig2p interacts with the DNA-binding domain (DBD)
(residues 21 to 195). These interactions are necessary to inhibit
pheromone-responsive transcription by Ste12p in vivo. These results
demonstrate that Dig1p and Dig2p are not mechanistically redundant but
rather must inhibit Ste12p function through independent mechanisms.
| |
MATERIALS AND METHODS |
Plasmids, yeast strains, and yeast techniques.
The yeast
strains used for these experiments are listed in Table
1. WHY4 is an SY2585 derivative in which
ste12 was disrupted by use of plasmid pSUL16
(11). The dig1
173 disruption was produced with
pIS173, which is a URA3 two-step disruption plasmid that removes DIG1 nucleotides 
125 to +1050. The
ste1212 disruption was generated similarly with plasmid
pAO012, which deletes nucleotides 493 to +640. Disruptions were
confirmed by PCR and Southern blotting. Plasmids pJL1 and
pYe/STE12Xba, which express GAL-inducible wild-type (WT)
Ste12p and Ste12p without the DBD (Ste12pDBD) (residues 216 to 688),
respectively, have been described previously (16). Ste12p
deletion mutants (see Fig. 2A) were produced by amplification in vitro
using the oligonucleotides listed in Table
2 and cloned into pYeDP8-1/2
(7) as KpnI/EcoRI fragments. Plasmids
p10, p11, and p12 were constructed by subcloning BamHI
deletion fragments from p2 into p5, p1 into p5, and p3 into p6,
respectively. The LEU2 GAL-STE12 deletion plasmids pIS222
(residues 216 to 688), pIS224 (356 to 688), and pIS225 (216 to 500)
contain a LEU2 BglII fragment (made blunt) inserted into the
EcoRV site of URA3 in their respective parents
described above. His6-Ste12p DBD expression plasmids were
produced by cloning EcoRI/BamHI fragments
produced by amplification with combinations of the oligonucleotides
indicated in Table 2 into pRSET-A. pAO003, which expresses Ste12p DBD
from a GAL promoter, contains an
EcoRI/BamHI fragment from pRSET-A (residues 1 to
215) subcloned into pYeDP8-1/2. The Ste12p DBD-VP16 fusion was created
by cloning a DBD-encoding fragment from pSTE12-7 (16) into
the EcoRI site of pM3VP16 (31). An Ste12p
DBD-VP16 XhoI/HindIII fragment was then made
blunt with PolIK and cloned into the BamHI (made
blunt) site of pYeDP8-1/2 to produce pSTVP/235. pG4-DBD, for expression
of His6-Gal4p DBD (residues 1 to 147) in Escherichia
coli, contains a HindIII/EcoRI fragment
from pMA241 (21) in pRSET-B. Plasmids for the expression of
Dig1p and Dig2p from GAL promoters in yeasts (pG1T and pG2T,
respectively) and as glutathione S-transferase (GST) fusions
in E. coli (pT580 and pT581, respectively) were as described
previously (40). GST-Ste12p E. coli expression
plasmids pGT11 (residues 216 to 594), pGT12 (216 to 500), pGT16 (262 to
688), pGT14 (356 to 688), and pGT15 (450 to 688) contain
KpnI/EcoRI fragments as described above cloned into pGT10, which is pGEX4-T3 with a KpnI linker inserted
into the BamHI (made blunt) site. pMHLex and pIS181 are
TRP1 ARS-CEN plasmids expressing LexA from the
ADH1 promoter, followed by multiple cloning sites
(39). LexA-Ste12p yeast expression plasmids pIS196 (residues
1 to 688) and pIS182 (215 to 688) contain an EcoRI fragment and pIS183 (215 to 473) contains an EcoRI/BamHI
fragment from corresponding Gal4 fusion plasmids (38) cloned
into pMHLex. LexA-Ste12p expression plasmids pIS184 (residues 216 to
500), pIS187 (262 to 688), pIS188 (356 to 688), pIS189 (403 to 688), and pIS194 (450 to 688) contain KpnI/EcoRI
fragments as described above in pIS181. His6-Gal4p
(residues 1 to 93) fusions were expressed in E. coli using
pRJR1 (29).
Unless indicated otherwise, cells were grown in minimal selective
medium to an optical density at 600 nm of 0.8 and induced with 2%
galactose or 2 µg of -factor (Sigma) per ml. 
-Galactosidase activity in permeabilized cells was determined as described previously (1). RNA was extracted by the phenol-freeze technique
(35), and specific transcripts were measured by Northern
blotting (1).
Recombinant proteins and antibodies.
GST and
His6 fusion proteins were expressed in E. coli
and batch purified with glutathione-agarose (Sigma) and Ni-agarose, respectively (1). Extracts from E. coli RR1
expressing TRPE-Ste12p from plasmid pTES216 (16) were
prepared as described previously (34). A recombinant
baculovirus for expressing native WT Ste12p was produced by
cotransfection of Autographa californica nuclear polyhedrosis virus (AcMNPV) DNA into SF9 cells with pBVS12,
which contains the STE12 open reading frame cloned into the
EcoRV/BamHI sites of pACYM1 (25).
Extracts from infected cells were produced by Dounce homogenization in
SF9 lysis buffer (20 mM Tris-HCl [pH 8], 150 mM NaCl, 1 mM EDTA, 1%
Nonidet P-40, 0.5% sodium deoxycholate, 1 mM phenylmethylsulfonyl
fluoride [PMSF], 3 mM dithiothreitol [DTT], 0.7 mM leupeptin, 2 µM pepstatin, 2 mM benzamidine, 2 µg of chymostatin per ml, 100 µg of tolylsulfonyl phenylalanyl chloromethyl ketone [TPCK] per ml)
and clarified by centrifugation at 12,000 × g for 20 min. For measuring interactions between recombinant proteins, 5 µg of
GST-Gal4 or His6-Gal4 fusion protein was mixed in GST lysis
buffer (1 mM DTT, 0.1% Nonidet P-40, 250 mM NaCl, 50 mM NaF, 5 mM
EDTA, 50 mM Tris [pH 7.5], 1 mM PMSF, 1 µg of pepstatin per ml, 1 µg of leupeptin per ml, 10 µg of soybean trypsin inhibitor per ml,
10 µg of TPCK per ml, 0.6 mM dimethylaminopurine) with
His6-Ste12p DBD, His6-Gal4p DBD, or 100 µg of
E. coli lysates containing TRPE-Ste12p or was mixed in GST
lysis buffer supplemented with 1 mg of bovine serum albumin per ml and
100 µg of total protein from infected SF9 extracts expressing WT
Ste12p. Recombinant GST fusions and associated proteins were recovered
with glutathione-agarose as described below and analyzed by sodium
dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) and
Western blotting. Rabbit anti-histidine tag antibodies were purchased
from Santa Cruz. Rabbit anti-Gal4p and anti-Ste12p (residues 216 to 688) [Ste12p(216-688)] antibodies have been described previously
(33). Rabbit anti-Ste12p DBD antibodies were produced
against His6-Ste12p(1-215) using standard techniques
(15).
Metabolic labeling, immunoprecipitation, and protein affinity
precipitation.
Cells bearing GAL1-STE12 expression
plasmids were starved for 20 min in Met-negative medium prior to
labeling at 30°C with 1.2 mCi of [35S]methionine per ml
in the presence of 2% galactose for 2 h. Immunoprecipitation with
anti-Ste12p polyclonal antibody was done as described previously (16). Labeled lysates used to assay interactions with
recombinant fusion proteins were prepared in GST lysis buffer as for
immunoprecipitation. The lysates were precleared by incubation with 20 µg of GST and 50 µl of glutathione-agarose per ml for 1 h at
4°C, followed by microcentrifugation at 2,000 × g for 2 min. Clarified lysates were incubated with 5 µg of recombinant GST,
GST-Dig1p, or GST-Dig2p for 1 h on ice. Following the addition of
25 µl of glutathione-agarose, the samples were incubated for an
additional 1 h at 4°C with gentle agitation. The beads were
washed three times with GST lysis buffer, and bound proteins were
eluted by incubation for 30 min in GST lysis buffer plus 5 mM
glutathione. Labeled proteins were resolved by SDS-10% PAGE and
detected by autofluorography.
| |
RESULTS |
Overexpression of Ste12p C-terminal fragments causes the induction
of a pheromone-responsive gene in the absence of pheromone.
The
ability of Ste12p to activate transcription is inhibited in the absence
of pheromone by at least two negative regulators, Dig1p and Dig2p
(5, 40). To identify the region(s) of Ste12p that is
necessary for inhibition by these proteins, we initiated a strategy
similar to that used to examine the regulation of Gal4p by the
inhibitor Gal80p. The overproduction of Gal4p C-terminal fragments
containing the major region of interaction with Gal80p causes the
induction of GAL transcription in the absence of galactose by competing for the binding of Gal80p with endogenous WT Gal4p (17, 20). Consistent with previous results (38),
we found that the overexpression of WT Ste12p from a
galactose-inducible promoter in either WT or ste12 yeast
caused elevated transcription from a pheromone-responsive promoter
(FUS1-LacZ) in the absence of pheromone (Fig.
1). Also, similar to the results obtained
with Gal4p, we found that FUS1-LacZ transcription could be
induced in the absence of pheromone by overexpression of a truncated
Ste12p derivative [Ste12p(216 to 688)] lacking the DBD in yeast cells expressing endogenous WT STE12 (Fig. 1A) but not in cells
bearing an ste12 disruption (Fig. 1B). This result
demonstrates that endogenous Ste12p can be activated in the absence of
pheromone by overproduction of the Ste12p C terminus (residues 216 to
688). In view of our original rationale, one interpretation of this
result is that the Ste12p C terminus might bind one or more inhibitors
and that its overproduction causes induction by competing for the
binding of inhibitors with endogenous Ste12p. However, we demonstrate below that the Ste12p C terminus has several segments that can promote
multimerization. Therefore, overexpression of residues 216 to 688 likely causes activation by a mechanism involving a direct interaction
with endogenous Ste12p, in addition to competition for the binding of
negative regulatory proteins.
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FIG. 1.
Overexpression of Ste12p residues 216 to 688 causes
STE12-dependent activation of FUS1-LacZ
transcription. Yeast strains SY2585 (STE12) (A) and WHY4
(ste12) (B) bearing plasmids pYeDP8-1/2 (vector), pJL1 (WT
Ste12p), and pYe/STE12Xba (Ste12pDBD) were induced with
galactose, and FUS1-LacZ expression was determined by
measurement of -galactosidase (-gal) activity at the indicated
times.
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To identify the region of Ste12p necessary for causing the induction of
FUS1-LacZ expression when overproduced, we expressed a set
of C-terminal deletions from the GAL1 promoter (Fig.
2A). We found that sequences C terminal
to residue 594 or N terminal to residue 262 could be deleted from
overexpressed Ste12p without preventing the elevation of
FUS1-LacZ reporter gene expression (Fig. 2B). In contrast,
overexpression of Ste12p fragments bearing C-terminal truncations to
residues 547 and N-terminal truncations to 309 did not cause a
significant elevation of FUS1-LacZ transcription (Fig. 2B).
Consistent with these results, expression of a fragment spanning
residues 262 to 594 (Fig. 2B, p10) caused the activation of
FUS1-LacZ expression, whereas a smaller fragment spanning
residues 309 to 547 had no effect (Fig. 2B, p12). These observations
indicate that endogenous Ste12p can be activated in the absence of
pheromone by overproduction of a C-terminal Ste12p fragment spanning
residues 262 to 594.
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FIG. 2.
Ste12p residues 262 to 594 cause elevated
FUS1 transcription when overexpressed in STE12
yeast. (A) Strain SY2585 (STE12) bearing plasmids expressing
Ste12p fragments from a GAL promoter or pYEDP8-1/2 (vector)
were grown to mid-log phase and induced with galactose for 2 h.
(B) Relative FUS1-LacZ transcription was measured by
assaying -galactosidase activity.
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Dig1p and Dig2p interact with separate regions of Ste12p.
Dig1p and Dig2p are present in complexes with Ste12p and Kss1p or Fus3p
in vivo (5, 40). Since overexpression of Ste12p residues 262 to 594 causes activation of endogenous Ste12p, we determined whether
Dig1p or Dig2p interacts directly with this region. We examined whether
Ste12p deletion fragments (Fig. 2A) could be recovered from labeled
total yeast extracts by protein affinity precipitation with recombinant
GST-Dig1p and GST-Dig2p. As shown previously (16), WT
Ste12p and Ste12pDBD are readily detected by immunoprecipitation
with polyclonal anti-Ste12p antibodies when expressed from a
galactose-inducible promoter in [35S]methionine-labeled
cells (Fig. 3A, lanes A). Recombinant
GST-Dig1p mixed with [35S]methionine-labeled extracts
prepared from ste12 cells and recovered with
glutathione-agarose bound a single labeled protein of approximately 80 kDa (Fig. 3A, vector, lane 1), while similarly treated GST-Dig2p bound
two labeled proteins of approximately 80 and 92 kDa (Fig. 3A, vector,
lane 2). The identities of these 80- and 92-kDa proteins are unknown.
Using this technique, we found that WT Ste12p could be recovered from
labeled extracts by affinity precipitation with both GST-Dig1p and
GST-Dig2p (Fig. 3A, WT Ste12p, lanes 1 and 2, respectively). In
contrast, we found that the Ste12pDBD derivative could be recovered
from extracts with GST-Dig1p but not GST-Dig2p (Fig. 3A, Ste12pDBD,
compare lanes 1 and 2). These results demonstrate that recombinant
Dig1p and Dig2p specifically interact with Ste12p plus several
additional proteins in labeled yeast extracts. Furthermore, we found
that both Dig1p and Dig2p bound WT Ste12p but that only Dig1p was
capable of interacting with the Ste12pDBD derivative. This result
indicates that these inhibitors must bind to different regions of
Ste12p. Dig2p requires the DBD (residues 1 to 215) for interaction with
Ste12p, whereas Dig1p can interact with residues 216 to 688.
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FIG. 3.
Dig1p and Dig2p interact with different regions of
Ste12p in yeast extracts. Strain WHY4 (ste12) bearing Ste12p
expression plasmids pJL1 (A, WT Ste12p), pYe/STE12Xba (A,
Ste12pDBD), and control pYeDP8-1/2 (A, vector) or plasmids
expressing Ste12p deletions p1 (B), p2 (C), p3 (D), p4 (E), p5 (F), p6
(G), and p7 (H) was labeled with [35S]methionine in the
presence of galactose. Labeled extracts were immunoprecipitated with
Ste12p(216-688) polyclonal antibodies (lanes A) or analyzed by protein
affinity precipitation with recombinant GST-Dig1p (lanes 1) or GST-Dig2
(lanes 2). Recovered proteins were resolved by SDS-PAGE and visualized
by autofluorography. Migration of WT Ste12p and Ste12pDBD is
indicated by arrowheads labeled A and B, respectively, in panel A. Migration of the Ste12p C-terminal fragments in panels B to H is
indicated by an arrowhead. MW, molecular weight (in thousands).
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To identify the region of Ste12p that binds GST-Dig1p, we examined
interactions with the Ste12p C-terminal deletion fragments (Fig. 2A) by
protein affinity precipitation from labeled yeast extracts. We found
that Ste12p C-terminal truncations p1 (215 to 641) and p2 (215 to 594)
were efficiently recovered from labeled yeast extracts with GST-Dig1p
but not GST-Dig2p, while p3 (215 to 547) was recovered slightly less
efficiently with GST-Dig1p (Fig. 2B, C, and D). In contrast, the
C-terminal truncation p4 (215 to 500) did not interact with GST-Dig1p
or Dig2p (Fig. 3E). Similarly, the Ste12p N-terminal truncations p5
(262 to 688) and p6 (309 to 688) were also recovered by GST-Dig1p (Fig.
3F and G), but the smaller N-terminal truncations p7 (356 to 688) (Fig. 3H) and p8 (403 to 688) and p9 (450 to 688) (data not shown) did not
interact with either GST-Dig1p or GST-Dig2p. These results indicate
that residues 309 to 547 of Ste12p are required for the most efficient
interaction with recombinant Dig1p. Furthermore, the fact that none of
the truncated Ste12p C-terminal fragments interacted with Dig2p
supports the conclusion that the two inhibitors interact with separate
regions of Ste12p.
Ste12p is known to interact with other proteins in addition to Dig1p
and Dig2p, including the transcription factors Mcm1p (10),
1p (43), and Tec1p (22) and the MAP kinases
Kss1p and Fus3p (2, 3, 5, 40). We also observed at least two
additional proteins, of 80 and 92 kDa, interacting with GST-Dig2p and
one protein, of 80 kDa, interacting with GST-Dig1p in protein affinity
precipitations of labeled yeast extracts (Fig. 3A). Therefore, it was
necessary to determine whether Dig1p and Dig2p were capable of direct
interactions with separate regions of recombinant Ste12p in the absence
of additional yeast proteins. To examine whether GST-Dig2p interacts
directly with the Ste12p DBD, we expressed this fragment (residues 1 to
215) in E. coli as a His6-tagged fusion (Fig.
4A, lane 4). We found that
His6-Ste12p DBD is bound efficiently by GST-Dig2p (Fig. 4A,
lane 1) but not significantly by GST-Dig1p (lane 2). Neither GST fusion
protein interacted with His6-Gal4p DBD (Fig. 4A, lanes 5 to
8). Further deletion analysis demonstrated that residues 21 to 195 of
Ste12p comprise the minimal Dig2p-binding region. GST-Dig2p interacted
with His6-Ste12p(21-195) (Fig. 4B, lane 6) but not smaller
fragments containing residues 21 to 170 or 45 to 195 of Ste12p (Fig.
4B, lanes 9 and 12). This result indicates that Dig2p binds to Ste12p
at the same region required for DNA binding (42) (data not
shown). GST-Dig1p did not interact with any of the Ste12p DBD deletion
constructs (data not shown).
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FIG. 4.
Dig1p and Dig2p interact with separate parts of
recombinant Ste12p in vitro. (A) Recombinant His6-Ste12p
DBD (lanes 1 to 4) and His6-Gal4p DBD (lanes 5 to 8) were
mixed with GST-Dig2p (lanes 1 and 5), GST-Dig1p (lanes 2 and 6), or GST
(lanes 3 and 7). Bound proteins were recovered with
glutathione-agarose, resolved by SDS-PAGE, and detected by
immunoblotting with anti-His6 tag antibodies. One-twelfth
the input amount of His6-Ste12p DBD and
His6-Gal4p DBD was analyzed directly by SDS-PAGE (lanes 4 and 8), and their migration is indicated as A and B, respectively. (B)
Recombinant His6-Ste12p (DBD) fragments spanning residues 1 to 215 (lanes 1 to 3), 21 to 195 (lanes 4 to 6), 21 to 170 (lanes 7 to
9), or 45 to 195 (lanes 10 to 12) were assayed for interaction with GST
(lanes 2, 5, 8, and 11) or GST-Dig2p (lanes 3, 6, 9, and 12). An
equivalent amount of input Ste12p DBD was loaded in lanes 1, 4, 7, and
10. (C) Extracts from SF9 cells infected with WT Ste12p-expressing
baculovirus (+, odd lanes), or control AcMNPV (, even
lanes) were analyzed directly by SDS-PAGE (lanes 7 and 8) or mixed with
GST-Dig1p (lanes 1 and 2), GST-Dig2p (lanes 3 and 4), or GST (lanes 5 and 6). Bound proteins were recovered with glutathione-agarose and
analyzed by SDS-PAGE and immunoblotting with Ste12p(216-688)
antibodies. (D) E. coli lysates containing
TRPE-Ste12p(216-688) (input, lane 1) were mixed with GST (lane 2),
GST-Dig1p (lane 3), or GST-Dig2p (lane 4), and bound proteins were
analyzed by SDS-PAGE and immunoblotting with Ste12p(216-688)
antibodies. MW, molecular weight (in thousands).
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Full-length recombinant WT Ste12p was also produced by expression in
insect cells using a baculovirus vector (Fig. 4C, lane 7). Consistent
with the results shown above (Fig. 3A), we found that recombinant WT
Ste12p could be recovered from infected insect cell extracts with both
GST-Dig1p (Fig. 4C, lane 1) and GST-Dig2p (lane 3). These results
demonstrate that Dig1p and Dig2p are able to interact with Ste12p in
the absence of other yeast proteins. However, since the unactivated
form of Kss1p has been shown to bind and inhibit Ste12p (2),
an effect that appears to require Dig1p or Dig2p (3),
interpretation of the latter result may be complicated by the fact that
insect cells express MAP kinases. To determine whether Dig1p interacts
directly with the Ste12p central region, we used a recombinant
TRPE-Ste12p(216-688) fusion produced in E. coli
(16) (Fig. 4D, lane 1). Consistent with the results shown
above, we found that TRPE-Ste12p(216-688) was bound by GST-Dig1p
(Fig. 4D, lane 2) but not by GST-Dig2p (lane 4). These results
demonstrate that Dig1p and Dig2p interact directly with separate
regions of Ste12p. Dig2p binds to the Ste12p DBD (residues 1 to 215),
while the strongest interaction of Dig1p with Ste12p requires a region
spanning residues 309 to 547 (Fig. 3).
Dig1p and Dig2p inhibit Ste12p by separate interactions in
vivo.
Since Dig1p and Dig2p interact with separate segments of
Ste12p in vitro, we examined whether we could dissociate their
inhibitory effects on Ste12p in vivo. We expressed the Ste12p DBD on
its own (residues 1 to 215) and as a fusion to the strong
transcriptional activation domain of herpes simplex virus type 1 VP16
(32) (Ste12p DBD-VP16) from GAL promoters. Ste12p
DBD produced on its own caused a slight elevation of
FUS1-LacZ transcription relative to the vector control (Fig.
5A), suggesting that the DBD might
possess a weak transcriptional activation function. However, the Ste12p DBD-VP16 fusion activated FUS1-LacZ expression approximately
25-fold more than Ste12p DBD (Fig. 5A). We found that simultaneous
expression of Dig2p but not Dig1p from a GAL promoter
inhibited the activation of FUS1-LacZ expression by the
Ste12p DBD-VP16 fusion (Fig. 5A). We also examined the effect of Ste12p
DBD and Ste12p DBD-VP16 on the expression of the endogenous
FUS1 gene by Northern blotting. Consistent with the results
of Fig. 5A, we found that Ste12p DBD-VP16 strongly activated
FUS1 transcription and that this effect could be inhibited
by simultaneous overexpression of DIG2 but not
DIG1 (data not shown). These results demonstrate that Dig2p
inhibits Ste12p in vivo by its direct interaction with the DBD.
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FIG. 5.
Dig1p and Dig2p inhibit Ste12p through interactions with
different regions in vivo. (A) Strain WHY4 bearing plasmids pYeDP8-1/2
(vector), pAO003 (Ste12p DBD), and pSTVP/235 (Ste12p DBD-VP16) was
cotransformed with YEplac112 (control), pG1T (GAL-DIG1), and
pG2T (GAL-DIG2). Cells were grown to mid-log phase, and
FUS1-LacZ expression was measured by assaying
-galactosidase (-gal) activity 2 h after galactose addition.
(B) Yeast strains W303-1A (WT), ISY37 (dig1), and MT1147
(dig2) bearing plasmid pSH18-34 (LexA ops-LacZ)
were cotransformed with pMHLex (LexA), pIS196 [LexA-Ste12p(1-688)],
or pIS182 [LexA-Ste12p(216-688)]. Transcriptional activation by LexA
fusions was assayed by measuring -galactosidase activity in cells
grown to mid-log phase.
|
|
To examine whether Dig1p inhibits Ste12p by interaction with the
central region, we examined activation by LexA-Ste12p fusions in
dig1 and dig2 yeast strains (Fig. 5B). Consistent
with previous observations (38), we found that
LexA-Ste12p(1-688) and LexA-Ste12p(216-688) fusions were weak
activators in the absence of pheromone (Fig. 5B), but activation could
be stimulated by pheromone treatment in WT cells (data not shown).
However, we found that activation by LexA-Ste12p(216-688) in the
absence of pheromone was elevated in dig1 yeast cells
relative to WT cells but not in dig2 yeast cells (Fig. 5B).
In contrast, activation by the LexA-full-length Ste12p fusion
[LexA-Ste12p(1-688)] was unaffected by disruption of either
dig1 or dig2 in unstimulated cells (Fig. 5B).
These results indicate that in the absence of pheromone,
LexA-Ste12p(1-688) must be negatively regulated by both Dig1p and
Dig2p, whereas LexA-Ste12p(216-688) is only inhibited by Dig1p.
Together with the above results, these observations support the view
that Dig1p and Dig2p inhibit Ste12p through interactions with separate regions.
Overexpression of Ste12p(216-688) does not cause the activation of
endogenous Ste12p solely by competing for the binding of Dig1p.
As
indicated above, we initially examined the effect of overexpressed
Ste12p C-terminal fragments with the rationale that they should cause
the activation of endogenous Ste12p by competing for binding of the
inhibitor proteins. However, several observations indicate that
overexpressed Ste12p(216-688) cannot cause activation merely by
competition for Dig1p. First, as shown above, overproduction of
Ste12p(262-594) is required to cause the activation of FUS1 transcription by endogenous Ste12p (Fig. 2); in contrast, a smaller segment (residues 309 to 547) seems to be necessary for efficient interaction with Dig1p (Fig. 3). Second, Ste12p(216-688) does not
interact directly with Dig2p (Fig. 3 and 4), yet overexpression of this
region can activate endogenous Ste12p in a WT (DIG2) strain (Fig. 1). Furthermore, simultaneous overexpression of DIG2
inhibited transcriptional activation by both WT Ste12p and Ste12pDBD
as efficiently as overexpression of DIG1 (Fig.
6A). We also directly examined whether
Dig1p was required for the activation of FUS1 transcription
by overexpressed Ste12p(216-688) (Fig. 6B). We found that
overexpression of residues 216 to 688 caused much more extensive induction of FUS1 transcription in both dig1 and
dig2 yeast cells than in WT cells (Fig. 6B, compare lanes 6 and 9 with lane 3). In contrast, overexpression of the Ste12p DBD
(residues 1 to 215) on its own caused approximately equivalent levels
of activation of FUS1 transcription in mutant cells and in
WT cells (Fig. 6B, lanes 2, 5, and 8). This result demonstrates that
overexpression of Ste12p(216-688) cannot cause FUS1
induction simply by competing with endogenous Ste12p for Dig1p.
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FIG. 6.
Activation of endogenous Ste12p by the overexpressed C
terminus does not require DIG1. (A) Strain SY2585
(STE12) bearing Ste12p expression plasmid pJL1 (WT Ste12p),
pYe/STE12Xba (Ste12pDBD), or control pYeDP8-1/2 (vector) was
cotransformed with pG1T (GAL-DIG1), pG2T
(GAL-DIG2), or Yeplac181 (control) (12). Cells
were grown to mid-log phase, and FUS1-LacZ expression was
measured by assaying -galactosidase (-gal) activity 2 h
after galactose addition. (B) W303-1A (WT, lanes 1 to 3), MT1147
(dig2, lanes 4 to 6), and MT1154 (dig1, lanes 7 to 9) were transformed with pYeDP8-1/2 (vector, lanes 1, 4, and 7),
pAO003 [GAL-Ste12p(1-215), lanes 2, 5, and 8], or
pYe/STE12Xba [GAL-Ste12p(216-288), lanes 3, 6, and 9].
Cells were grown to mid-log phase and induced with galactose. RNA was
extracted 2 h postinduction and analyzed by Northern blotting with
FUS1 (top) and ACT1 (bottom) probes.
|
|
The overproduced Ste12p C terminus causes transcriptional
activation through an interaction with endogenous Ste12p.
Since
the activation of FUS1 transcription by overproduced
residues 216 to 688 requires endogenous Ste12p (Fig. 1), we imagined that this effect might be mediated by direct interaction of this fragment with WT Ste12p. To examine this possibility, we determined whether a region(s) in the Ste12p C terminus could promote
multimerization in vitro (Fig. 7). We
found that recombinant WT Ste12p can interact in vitro with the Ste12p
C terminus (residues 216 to 688) fused to the Gal4p DBD (Fig. 7A, lane
1) in coimmunoprecipitation experiments. Smaller Ste12p fragments,
spanning residues 216 to 473 (Fig. 7A, lane 2) and 474 to 688 (lane 4),
fused to Gal4p also interacted with WT Ste12p in vitro, indicating that
multiple sites flanking residue 473 must be able to promote
multimerization. We also examined the interaction of recombinant WT
Ste12p with GST-Ste12p fusion proteins in vitro (Fig. 7B). Consistent
with the results of Fig. 7A, we found that WT Ste12p interacted with
GST fused to various Ste12p C-terminal fragments (Fig. 7B, lanes 3 to
7) but not with GST alone (lane 2). GST fused to Ste12p C-terminal
fragments containing residues 216 to 500 (Fig. 7B, lane 4) or residues
450 to 688 (lane 7) interacted efficiently with WT Ste12p. Combined
with the results of Fig. 7A, these results indicate that multiple
segments within the Ste12p C terminus must promote multimerization.
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FIG. 7.
Ste12p C-terminal regions cause multimerization in
vitro. (A) WT Ste12p SF9 extracts (input, lane 5) were incubated with
extracts from E. coli expressing His6-tagged
Gal4p DBD (6H-G4, lane 4) or 6H-G4 fused to Ste12p residues 216 to 688 (lane 1), 216 to 473 (lane 2), or 474 to 688 (lane 3). Gal4p fusions
were recovered by immunoprecipitation with GAL4 DBD monoclonal
antibody, and the interacting Ste12 protein was detected by Western
blotting with Ste12p(1-215) antibodies (top). Input 6H-G4 fusion
protein was detected by Western blotting with Gal4p DBD antibodies
(bottom). (B) WT Ste12p-containing extracts (input, lane 1) were
incubated with recombinant GST (lane 2) or GST fused to residues 216 to
594 (lane 3), 216 to 500 (lane 4), 262 to 688 (lane 5), 356 to 688 (lane 6), or 450 to 688 (lane 7) of Ste12p. Bound WT Ste12p recovered
with glutathione-agarose was analyzed by SDS-PAGE and immunoblotting
with Ste12p DBD antibodies. (C) Extracts from E. coli
expressing His6-Gal4p fused to Ste12p(216-473) (input,
lane 1) were incubated with recombinant GST (lane 2), GST-Dig1p (lane
3), or GST-Dig2p (lane 4). Bound 6H-G4-Ste12p recovered with
glutathione-agarose was detected by immunoblotting with Gal4p DBD
antibodies.
|
|
We examined whether overexpression of the Ste12p C terminus could cause
activation by multimerization with WT Ste12p in vivo by using a
modified two-hybrid system. For this purpose, we first needed to
identify Ste12p C-terminal fragments that are incapable of activating
transcription for use as bait fusions. We found that Ste12p(216-688)
fused to LexA caused strong activation of transcription of a
LexA-responsive reporter gene in untreated ste12 dig1 dig2
yeast cells (Fig. 8A, 216 to 688).
Deletion of residues C terminal to Ste12p amino acid 474 did not
prevent activation by LexA fusions (Fig. 8A, 216 to 474). However,
deletion of residues N terminal to amino acid 356 prevented activation
by LexA-Ste12p (Fig. 8A, 356 to 688). These results are consistent with
previous observations (38) and indicate that the major
activating segment of Ste12p resides between amino acids 216 and 356.
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FIG. 8.
The Ste12p C terminus can cause activation by
multimerization in vivo. (A) Yeast strain YCN7 (ste12 dig1
dig2) bearing pSH18-34 (LexA ops-LacZ) was transformed
with pMHLex expressing LexA (vector) or the LexA-Ste12p expression
plasmids pIS182 (216 to 688), pIS184 (216 to 500), pIS183 (216 to 474),
pIS187 (262 to 688), pIS188 (356 to 688), pIS189 (403 to 688), and
pIS194 (450 to 688). Transcriptional activation by LexA fusions was
assayed by measuring -galactosidase (-Gal) activity in cells
grown to mid-log phase. (B) Yeast strain YCN7 bearing pSH18-34 and the
LexA-Ste12p bait plasmids (as in panel A; LexA-Ste12p Bait) was
cotransformed with vectors producing residues 216 to 288, 356 to 688, or 216 to 500 of Ste12p from a GAL promoter (Ste12p Prey).
Cells were grown to mid-log phase, and expression from the
LexA-responsive reporter was measured by assaying -galactosidase
activity 2 h after galactose addition.
|
|
We next determined whether Ste12p(216-688) could cause the activation
of reporter gene expression in the presence of LexA-Ste12p fusions
which are incapable of activating transcription on their own but which
contain segments that can promote Ste12p multimerization. For this
purpose, we used LexA fused to Ste12p(356-688) and Ste12p(450-688), two fragments that can interact with WT Ste12p in vitro as GST fusions
(Fig. 7B, lanes 6 and 7). Consistent with the above results, coexpression of Ste12pDBD caused the activation of reporter gene expression in the presence of both LexA-Ste12p C-terminal fusions but
not with LexA produced on its own (Fig. 8B, Ste12p Prey 216-688). In
contrast, Ste12p(356-688) did not cause the activation of
transcription when coexpressed with the LexA-Ste12p fusions (Fig. 8B,
Ste12p Prey 356-688), indicating that the Ste12p activating region
(Fig. 8A) is necessary for activation by overexpressed Ste12p
C-terminal fragments. Additionally, coexpression of Ste12p(216-500)
also caused much weaker activation in the presence of the LexA-Ste12p fusions (Fig. 8B, Ste12p Prey 216-500), a result which might reflect less efficient multimerization of this derivative in vivo. Note that
Ste12p(216-500) can activate transcription efficiently when fused
directly to LexA (Fig. 8A) but not when coexpressed with the
LexA-Ste12p fusions in Fig. 8B or when produced in cells expressing WT
Ste12p (Fig. 2, p4). These observations indicate that overexpression of
Ste12p C-terminal fragments likely causes the activation of FUS1 transcription (Fig. 1 and 2) by forming complexes with
endogenous Ste12p. In this view, the "activating" fragment must
contain both the transcriptional activation region (residues 262 to
356) and sufficient C-terminal sequences to promote multimerization
with endogenous WT Ste12p (residues 356 to 594).
Our observation that residues 309 to 547 of Ste12p are required for
interaction with Dig1p (Fig. 3) are at odds with previous results
indicating that a much smaller segment (residues 301 to 335) is
sufficient for interaction with Dig1p in two-hybrid experiments (27). Because Ste12p appears to have C-terminal segments
that can promote multimerization (Figs. 7 and 8), we wondered whether this discrepancy results from the fact that the Gal4p DBD forms a
stable dimer (4, 24). If Dig1p interacts most efficiently with Ste12p multimers, then interactions in our experiments (Fig. 3)
would require segments that can promote efficient multimerization in
addition to the region of direct contact between these proteins. In
contrast, since the Gal4p DBD itself forms a dimer, interactions of
Ste12p fragments with Dig1p in a two-hybrid experiment should require
only the region necessary for direct interaction. Consistent with this
possibility, we found that GST-Dig1p could bind recombinant Gal4-Ste12p(216-473) in vitro (Fig. 8C, lane 3); in contrast, GST-Dig2p was unable to interact with recombinant Gal4-Ste12p(216-473) (lane 4). Considering that GST-Dig1p is unable to interact with Ste12p
fragments lacking residues C terminal of residue 547 when produced as
native fragments in yeast cells (Fig. 3), these observations suggest
that Dig1p prefers to bind Ste12p multimers under the conditions of our
experiments and previous two-hybrid analyses (27).
| |
DISCUSSION |
Ste12p is a transcriptional activator whose function involves
interactions with multiple DNA-binding partners and that is negatively
regulated by several inhibitory proteins (Fig.
9). In this work, we have examined the
relationship between the regulators Dig1p and Dig2p and Ste12p's
function in activating transcription of the pheromone-responsive gene
FUS1. Although Dig1p and Dig2p have generally been
considered to have overlapping, if not redundant, functions (2, 3,
5, 40), we demonstrate that they must regulate Ste12p by separate
mechanisms. Dig1p binds directly to a central region of Ste12p
(residues 309 to 547), while Dig2p binds to the Ste12p DBD (residues 1 to 215) (Fig. 9). These different interactions can account for their
inhibitory effect on Ste12p in vivo. Overproduction of Dig2p but not
Dig1p inhibits activation by an Ste12p DBD-VP16 fusion protein. In
contrast, deletion of dig1 but not dig2 causes
constitutive activation by a LexA-Ste12p(216-688) fusion. These
observations demonstrate that Ste12p activity is regulated by two
inhibitory proteins that function separately. Like Dig1p and Dig2p, the
MAP kinases Kss1p and Fus3p were also initially thought to have
redundant functions in the pheromone response (8) until it
was recognized that these enzymes have inhibitory effects in their
unactivated state (2, 23) and that Kss1p is preferentially
required for regulation of the filamentous growth response
(19).
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FIG. 9.
Ste12p interacts with multiple transcription factors and
regulatory proteins. Regions of Ste12p required for binding the
pheromone response element (DNA binding) and for transcriptional
activation are indicated by black bars. Several separate segments
flanking residue 473 can promote multimerization (dashed grey bar).
Regions required for interactions with Mcm1p, Kss1p, Dig2p, and Dig1p
are indicated by black bars. An additional segment contributes to an
interaction with Dig1p by causing Ste12p multimerization (dashed grey
bar).
|
|
Dig1p and Dig2p inhibit Ste12p through interactions with separate
regions.
A previous report indicated that both Dig1p and Dig2p
interact with residues 301 to 335 of Ste12p, termed the pheromone
induction domain (27). This region was shown to confer
pheromone inducibility to Gal4p DBD fusions and to interact with Dig1p
and Dig2p in two-hybrid assays. We found that a larger region of
Ste12p, spanning residues 309 to 547, was required for an efficient
interaction with GST-Dig1p. Furthermore, this region of Ste12p did not
interact directly with Dig2p in our experiments (Fig. 3 and 8C). These
discrepancies are likely related to the fact that Ste12p C-terminal
segments can promote multimerization (Fig. 7 and 8). For example, the
apparent interaction of Dig2p with the pheromone-responsive domain in
previous two-hybrid analyses might be mediated through an interaction
with endogenous Ste12p, since these experiments were performed with WT
cells (27). Additionally, we found that GST-Dig1p could
interact efficiently with Ste12p(216-474) fused to the Gal4p DBD in
vitro (Fig. 8C) but not to Ste12p216-547 expressed on its own in yeast cells (Fig. 3). Considering that several regions in the Ste12p C
terminus can cause multimerization (Fig. 7 and 8), this difference may
be a consequence of the fact that the Gal4p DBD forms stable dimers
(4, 24). One implication of this hypothesis is that Dig1p
must preferentially interact with Ste12p multimers. However, since the
stoichiometry of Ste12p and Dig1p-Ste12p complexes in uninduced and
induced conditions has not been established, it is difficult to predict
whether this apparent requirement for Dig1p interaction has any
significance for the regulation of Ste12p. Nevertheless, in combination
with the previous two-hybrid analyses (27), our results
suggest that Dig1p directly interacts with residues 301 to 335 but that
further C-terminal sequences to 547 contribute to the interaction,
perhaps because they are necessary for multimerization (Fig. 9).
Our finding that Dig1p and Dig2p interact with separate regions of
Ste12p (Fig. 9) suggests that they inhibit transcription through
independent mechanisms. Because Dig2p binds to the DBD and inhibits
activation by an Ste12p DBD-VP16 fusion, the simplest model is that
this inhibitor modulates the ability of Ste12p to bind to the pheromone
response element. In support of this hypothesis, we found that binding
of the Ste12p DBD (residues 1 to 215) to a pheromone response element
is inhibited by equimolar amounts of recombinant GST-Dig2p but not
GST-Dig1p in vitro (data not shown). Furthermore, in vivo footprinting
analysis suggests that pheromone treatment causes filling of pheromone
response elements on a multicopy FUS1 reporter template (not
shown). These results suggest that some Ste12p may be sequestered in a
complex with Dig2p prior to pheromone treatment, although we found that
Dig2p was produced at considerably lower levels than Dig1p in
unstimulated cells (not shown). It is also possible that Dig2p inhibits
through a mechanism other than or in addition to prevention of Ste12p DNA binding. Dig1p, in contrast, interacts with a region spanning residues 309 to 547 of Ste12p (Fig. 8). This region also overlaps sequences that are necessary for transcriptional activation
(38) (Fig. 8A). Therefore, one possibility is that Dig1p
functions in a manner similar to that of Gal80p, which binds directly
to the major activation domain of Gal4p and inhibits transcriptional activation in the absence of galactose (20). In this model, we would expect Dig1p to interact with DNA-bound Ste12p to prevent transcriptional activation in the absence of pheromone. However, the
precise mechanism by which Dig1p inhibits Ste12p remains to be
elucidated and, like that for Dig2p, may require an understanding of
the involvement of Kss1p and Fus3p.
The MAP kinase gene KSS1 was initially identified in a
multicopy suppressor screen for its ability to promote recovery from pheromone-induced growth arrest (6). It was discovered more recently that the unactivated form of Kss1p functions as a negative regulator of Ste12p's function in the filamentous response (5, 23). The inhibitory effect on filamentous response
element-dependent transcription was shown to involve the direct binding
of Kss1p to Ste12p (2). Unactivated Kss1p also inhibits the
transcription of pheromone-responsive genes, in a manner which appears
to be more dependent on Dig1p and Dig2p than on the inhibition of
filamentous response element-dependent transcription (3).
These observations suggest that the full inhibitory effect of Dig1p and
Dig2p on pheromone-responsive transcription might require interactions with the unactivated MAP kinases Kss1p and Fus3p. Perhaps the interactions that we observed between Dig1p, Dig2p, and Ste12p are
stabilized in vivo by the MAP kinases (3).
Regulation of Ste12p activity by pheromone-stimulated
signaling.
Of the transcription factors that have been
characterized to date, Ste12p may be unique in being negatively
regulated by two proteins that inhibit through separate mechanisms. Our
finding that Dig1p and Dig2p inhibit by nonredundant mechanisms is not surprising, considering the central role that Ste12p plays in coordinating cell fate in response to physiological signaling. Ste12p
activity may be induced in response to pheromone through Fus3p-mediated
phosphorylation of the inhibitors and/or Ste12p (5, 9, 16, 38,
40). However, since Dig1p and Dig2p inhibit Ste12p by interacting
with different regions, it is likely that the full activation of Ste12p
involves multiple mechanisms. It should also be noted that the
induction of Ste12p activity may not necessarily require dissociation
of these inhibitors. Most recent experiments investigating Gal4p
indicate that GAL induction may occur without dissociation
of the negative regulator Gal80p (18, 28). Therefore,
elucidation of the mechanisms regulating pheromone-responsive
transcription will require a better understanding of the interactions
between Dig1p, Dig2p, and Ste12p as well as the MAP kinases.
| |
ACKNOWLEDGMENTS |
This work was supported by a grant to I.S. from the N.C.I.C.,
with funds from the Canadian Cancer Society. K.A.O. was supported by an
N.S.E.R.C. postgraduate studentship.
We thank Mike Tyers, Stanley Fields, H. Ronne, and Malcolm Whiteway for
plasmids and yeast strains. Karen Lund, Susan Goto, Martin Hirst, and
several attentive anonymous reviewers provided helpful comments on the manuscript.
K. Amy Olson, Chris Nelson, and Ivan Sadowski contributed equally to
the design and implementation of these experiments.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Biochemistry and
Molecular Biology, 2146 Health Sciences Mall, Vancouver, British
Columbia V6T 1Z3, Canada. Phone: (604) 822-4524. Fax: (604) 822-5227. E-mail: sadowski{at}interchange.ubc.ca.
| |
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Molecular and Cellular Biology, June 2000, p. 4199-4209, Vol. 20, No. 12
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
