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Molecular and Cellular Biology, December 2000, p. 8709-8719, Vol. 20, No. 23
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
In Vivo Requirement of Activator-Specific
Binding Targets of Mediator
Jin Mo
Park,
Hye-Suk
Kim,
Sang Jun
Han,
Moon-Sun
Hwang,
Young Chul
Lee, and
Young-Joon
Kim*
Genome Regulation Center, Creative Research
Initiative, Samsung Biomedical Research Institute, Sungkyunkwan
University School of Medicine, Suwon 440-746, Korea
Received 17 July 2000/Returned for modification 17 August
2000/Accepted 24 August 2000
 |
ABSTRACT |
There has been no unequivocal demonstration that the activator
binding targets identified in vitro play a key role in transcriptional activation in vivo. To examine whether activator-Mediator interactions are required for gene transcription under physiological conditions, we
performed functional analyses with Mediator components that interact
specifically with natural yeast activators. Different activators
interact with Mediator via distinct binding targets. Deletion of a
distinct activator binding region of Mediator completely compromised
gene activation in vivo by some, but not all, transcriptional activators. These demonstrate that the activator-specific targets in
Mediator are essential for transcriptional activation in living cells,
but their requirement was affected by the nature of the activator-DNA interaction and the existence of a postrecruitment activation process.
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INTRODUCTION |
A set of proteins required for
accurate initiation of RNA polymerase II (Pol II) transcription have
been isolated, and their mode of action has been studied extensively
(30). In addition to these so-called basal transcription
factors, another group of proteins (collectively termed coactivators)
have been shown to stimulate Pol II transcription in response to
gene-specific enhancer DNA-bound activator proteins. Certain
coactivators, such as histone acetyltransferases and ATP-dependent
nucleosome-remodeling factors, function in the context of chromatin by
covalently modifying or repositioning nucleosomes (3, 43).
Others transduce activation signals from enhancer-bound activators to
the basal transcription machinery. TATA-binding protein-associated
factors (TAFs) and Mediator complexes are two representative members of
this class of coactivators (2, 10).
TAFs were identified initially in Drosophila and human cells
as integral components of TFIID and shown to possess coactivator activity in vitro (5, 42). However, depletion of various TFIID-specific TAFs does not have a significant effect on
transcriptional activation of most genes in Saccharomyces
cerevisiae (15, 25, 45). More importantly,
TAF-independent transcriptional activation has been reported in several
in vitro systems (19, 21, 29, 46), suggesting the existence
of another activator target that plays a more dominant role in
transcriptional activation.
Mediator, a multiprotein complex containing Srb/Med and several other
transcriptional regulatory proteins, is tightly associated with the Pol
II holoenzyme (designated hpol II) in the yeast S. cerevisiae (19, 21) and plays a pivotal role in
transcriptional regulation. Even though the Mediator complex as a whole
is required in general for Pol II transcription, some of its subunits
function in an activator-specific manner to modulate the expression of a distinct subset of genes (13, 15, 23). In addition,
genetic evidence suggests that a subset of the Mediator proteins are
involved in transcriptional repression (4, 8, 17, 35).
Differential dissociation of the Mediator components by high-urea
treatment (22) and compositional analysis of mutant hpol II
complexes (23, 24, 26) revealed that Mediator subunits with
similar genetic properties form distinct modular subassemblies.
Because purified hpol II in conjunction with basal transcription
factors can support activated transcription in a well-defined yeast
transcription system (19, 21), it was conceived that gene-specific activators communicate either directly or indirectly with
Mediator to recruit Pol II to the promoter. This idea was substantiated
by findings that hpol II interacts with the functional activation
domain of VP16 and Gcn4 (6, 14, 23). Furthermore, so-called
artificial recruitment experiments demonstrated that transcriptional
activation can occur independently of an activation domain when hpol II
is recruited to promoters either by physically tethering a Mediator
component to an enhancer-bound protein or by introducing into a
Mediator protein a gain-of-function mutation that endows the protein
with synthetic activator-binding capability (1, 7).
Using the model activator VP16, we demonstrated previously that a
distinct module of Mediator is required for activator binding (23). However, it remains to be determined whether natural
yeast activators, including Gal4 and Gcn4, also utilize the same
Mediator module for their interaction with hpol II. Moreover, there has been no unequivocal demonstration to date that the physical interaction between transcriptional coactivators and activator proteins identified in vitro does in fact play a critical role in activated transcription in living cells.
In order to decipher more precisely the in vivo function of the
activator-binding target(s) in the Mediator complex, we have determined
systematically the Mediator subunits that serve as direct binding
targets for VP16, Gal4, and Gcn4 and localized the binding domain in
each of the target subunits. Next, we generated mutant Mediator
proteins from which the activator-binding region was removed and tested
their ability to support activated transcription under physiological
conditions. Our results show that Mediator has distinct interacting
surfaces for each activator protein and these surfaces are required for
gene activation in vivo. In addition, we find that hpol II recruitment
to promoters in yeast cells requires the interaction of gene-specific
transcriptional activators with their target-binding domains in the
Mediator complex. However, with some activators this interaction does
not necessarily result in activated transcription. Hence, each
transcriptional activator may utilize diverse but distinct activation
mechanisms, including chromatin remodeling and hpol II recruitment, to
achieve higher transcriptional efficiency.
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MATERIALS AND METHODS |
Yeast strains.
The hrs1 null strain JMP9
(MAT
ade2 his3 leu2 trp1 ura3
hrs1::LEU2) was constructed by crossing
SSAB-2CF (37) to YPH499 (38). Diploids were
sporulated, and a segregant containing the correct set of markers was selected.
Plasmid constructs.
In order to construct pGEX-mini-Gal4 and
pET-mini-Gal4, the XhoI-BamHI fragment from
pRJR113 (blunted for pGEX-mini-Gal4) that encodes a part of the Gal4
activation domain (32) was inserted into XhoI-
and NotI (blunted)-digested pGEX-4T2 (Amersham Pharmacia Biotech) and XhoI- and BamHI-digested
pEh-Gal4VP16, respectively. Glutathione-S-transferase (GST)
fusion plasmid vectors that encode a fragment of Gal11 and Hrs1 were
constructed by inserting a PCR-amplified or restriction enzyme-digested
protein-coding DNA fragment into the appropriate pGEX vectors. The
parental plasmids that contain the GAL11 gene and some of
the GST-Gal11 fusion plasmids were provided by Hiroshi Sakurai and have
been described previously (36).
Low-copy-number plasmids that encode GAL11 and its internal
deletion mutants were constructed by excising the entire Gal11 protein-coding sequences (by KpnI and PstI
digestion) from high-copy-number plasmids containing the
GAL11 derivatives (36) and cloning them into the
TRP1-marked plasmid pRS314 (38). A plasmid
encoding the gal11
(176-262) mutation was
provided by Masafumi Nishizawa and has been described previously
(28).
The low-copy-number plasmids encoding
HRS1 were prepared in
a sequential manner. The
KpnI-
NotI fragment from
pRS316-
HRS1 (
37)
that encodes the promoter region
and an amino-terminal part of
HRS1 was inserted into
KpnI- and
NotI-digested pRS314 to construct
pRS314-HRS1N. The
NotI fragment from pGEX-Hrs1(83-432),
which
carries the rest of the Hrs1 coding sequence, was subsequently
cloned at the
NotI site of pRS314-HRS1N.
pRS314-
hrs1(
180-343)
was constructed by
cloning a PCR-amplified sequence encoding amino
acids 344 to 432 of
Hrs1 into the
NotI site of pRS314-HRS1N. In
order to
construct pRS314-
hrs1(
2-82), the
XhoI (blunted)-
EcoRI
fragment from
pGEX-Hrs1(83-432), which encodes the Hrs1 coding
sequence lacking the
amino-terminal 82 amino acids, was inserted
into
SmaI- and
EcoRI-digested pRS314 to construct pRS314-HRS1C.
PCR-amplified sequence encoding the
HRS1 promoter was then
digested
with
KpnI and
SmaI and inserted into
KpnI- and
EcoRI (blunted)-digested
pRS314-HRS1C.
The
lacZ reporter plasmid
2XGCN4-CYC1-lacZ was
constructed by inserting the
PvuII fragment from pSPGCN4CG
(
9), which contained
two consecutive Gcn4 binding sites,
into
SmaI- and
XhoI (blunted)-digested
pLGSD5
(
12). pRS313-Gal4DBD-Gcn4 was constructed by inserting
the
EcoRI fragment from pLY235 (
47) into the
EcoRI site of pRS313-Gal4VP16.
pRS313-Gal4VP16 was prepared
by inserting the
ScaI-
XbaI fragment
with the
Gal4VP16 expression cassette from pMA540 (
34) into
the
EcoRV and
XbaI sites of the
HIS3-based
low-copy-number plasmid
pRS313.
Analysis of activator-Mediator interactions.
GST pulldown
assays and far-Western blot analyses were carried out as described
previously (23). The GST and hexahistidine fusion proteins
used in the in vitro binding assays were expressed in and purified from
Escherichia coli BL21(DE3) using glutathione-Sepharose (Amersham-Pharmacia Biotech) and Ni-nitrilotriacetic acid-agarose (Qiagen), respectively. Hemagglutinin (HA) fusion proteins were purified from Sf9 insect cells infected with recombinant FASTBAC baculovirus (Gibco-BRL) with anti-HA monoclonal antibody (BAbCo) and HA
peptide (Roche) according to the manufacturer's recommendations. The
wild-type and hrs1 hpol II used in the experiments shown in Fig. 1A were purified from yeast cells using Bio-Rex 70, DEAE-Sephacel, Bio-gel HTP, and Mono Q chromatography as described
(19). The hpol II used in compositional analyses (Fig. 3B,
4D, and 6C) was immunoprecipitated from Bio-Rex 70 fractions with
anti-Rgr1 antibody.
Transcriptional analysis.
Reconstituted in vitro
transcription reactions were performed as described (19).
For the analysis of reporter gene expression in yeast cells, episomal
reporter plasmids were introduced into yeast cells by transformation,
and the transformed cells were grown in selective synthetic complete
medium to the mid-log phase. Galactose induction and amino acid
starvation were conducted as described (13).
-Galactosidase activity in cells was measured in triplicate by the
permeabilized-cell method (12).
Chromatin immunoprecipitation.
Yeast cells were subjected to
formaldehyde cross-linking, and the soluble chromatin was fragmented by
sonication and immunoprecipitated with anti-Rgr1 antibody as described
previously (39). PCR primers were used to amplify the
following regions (coordinates relative to the ATG at +1): the
160/13 region of GAL1; the 357/79 region of
HIS4; and the 298/38 region of the actin gene.
| |
RESULTS |
Gal11 module of yeast hpol II serves as an activator-specific
binding target.
We showed previously that the VP16 activation
domain (amino acids 412 to 490) interacts directly with yeast hpol II
in an in vitro assay (23). One or more of the Mediator
subunits in the Gal11 module of hpol II (Gal11, Hrs1, and Med2)
function in this interaction, as gal11 and hrs1
null versions of hpol II (which lack all three constituents of the
Gal11 module) are severely defective for VP16 activator binding. In
order to test whether the natural yeast activator proteins Gcn4 and
Gal4 also interact with the Gal11 module of Mediator, we measured the
affinity of wild-type and mutant (hrs1) hpol II binding
to each activator protein with a GST pulldown assay. For convenience,
we used a minimized Gal4 protein that contained the Gal4 DNA-binding
domain (Gal4DBD; amino acids 1 to 93) fused to the carboxyl-terminal activation domain (amino acids 768 to 881) (designated mini-Gal4 in
this study). Wild-type hpol II bound specifically to GST-activator fusion proteins, whereas hrs1 hpol II, which lacks the
Gal11 module, did not bind to any of the activator proteins tested
(Fig. 1A). Therefore, Gal4, Gcn4, and
VP16 all contact hpol II via the Gal11 module proteins.
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FIG. 1.
Gal11 module of Mediator is required for activator
binding and transcriptional activation. (A) GST pulldown assay of
wild-type hpol II (lanes 1 to 6) and hrs1 hpol II (lanes
7 to 12). Purified hpol II in the Mono-Q fraction (19) was
incubated with GST beads containing the GST-activator fusion proteins
indicated at the top of each lane. As controls, GST alone (lanes 2 and
8) and GST fused to an activation-defective version of VP16
(VP16 456FP442; lanes 3 and 9) were used. Bead-bound
proteins, along with the proteins used in the binding reactions (input;
lanes 1 and 7), were analyzed by sodium dodecyl sulfate-polyacrylamide
gel electrophoresis (SDS-PAGE) and subsequent immunoblotting with the
Mediator antibodies indicated at the left of the panel. (B) The
transcriptional activity of wild-type and hrs1 null
(hrs1) hpol II were analyzed in an in vitro transcription
system reconstituted with purified transcription factors. The presence
(+) or absence () of activator proteins is indicated at the top of
the panel. The transcripts from the G-less templates containing either
the Gal4 (Gal4:G) or Gcn4 (Gcn4:G) DNA-binding sites are indicated
by arrows at the right of the panel. The fold activation of hpol II by
each activator is shown at the bottom of the panel. (C) Far-Western
blot analysis of activator-binding targets. Affinity-purified hpol II
blotted on nitrocellulose membrane after resolution by SDS-PAGE was
probed with radiolabeled VP16 (V) or Gcn4 (C) protein (left panel). The
labeled protein bands were visualized by reprobing the same blot with
anti-Gal11 and anti-Hrs1 antibodies (right panel). The apparent
molecular sizes (in kilodaltons) are shown in the middle. (D) GST
pulldown assay of Gal11 module proteins. Purified HA-Gal11 (G), HA-Med2
(M), and HA-Hrs1 (H) proteins were incubated with the bead-bound
GST-activator fusion proteins indicated at the top of the panel. After
washing away the unbound proteins, the proteins that remained bound to
the beads were visualized by immunoblotting with anti-HA antibody. The
protein bands are indicated with arrows at the left of the panel. The
largest band in the G lanes is the full-length HA-Gal11 fusion protein,
and the smaller bands are degradation products of the parent protein.
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To evaluate the requirement of the activator-Gal11 module interaction
for transcriptional activation, we measured the transcriptional
activity of the
hrs1 hpol II in a reconstituted
transcription
system. The lack of the Gal11 module in
hrs1 hpol II did not
affect basal transcription activity
(Fig.
1B). However, transcriptional
activation of
hrs1
hpol II by Gal4-VP16, mini-Gal4, and Gcn4
was either completely
defective or partially compromised (Fig.
1B). These results suggest
that the direct interactions between
the activator proteins and the
Gal11 module play an important
role in transcriptional activation in
vitro. However, it was still
unclear which of the components of the
Gal11 module is a direct
binding target for the activator proteins.
Therefore, we aimed
to identify the Mediator subunit(s) that interacts
directly with
each activator
protein.
When a membrane blotted with purified wild-type hpol II was probed with
radiolabeled VP16 protein using a far-Western analysis,
only the Gal11
polypeptide gave a strong binding signal (Fig.
1C) (
23).
However, when the same blot was probed with radiolabeled
Gcn4, the Hrs1
polypeptide gave a strong signal (Fig.
1C). This
result hinted at the
presence of activator-specific binding targets
within the Mediator. To
confirm this result, we used a GST pulldown
assay to examine the direct
interactions between each of the purified
Gal11 module proteins
(HA-tagged proteins HA-Gal11, HA-Hrs1 and
HA-Med2) and GST-activator
fusion proteins GST-VP16, GST-mini-Gal4,
and GST-Gcn4. All of the
activator proteins tested bound tightly
to Gal11, whereas none bound to
Med2. In addition, Gcn4 interacted
with both Hrs1 and Gal11 (Fig.
1D).
The discrepancy between the
results of the far-Western and GST pulldown
assays may have resulted
from the differential sensitivities of the two
assays in detecting
protein binding affinity. Nevertheless, Gal11
appears to be a
common activator binding target, whereas Hrs1 acts as a
Gcn4-specific
target. Med2, on the other hand, may function as an
auxiliary
factor rather than as a direct activator-binding target, or
could
serve as a binding site for a different type of activator
protein.
VP16-interacting domain of Gal11 Is essential for transcriptional
activation in vivo.
Although the in vitro binding analysis
identified Gal11 as a common binding target of the activator proteins
tested, the role of this interacting domain under physiological
conditions remains to be determined. In order to address this question,
we sought to examine the function of a version of yeast hpol II that
lacked only the specific activator-binding region of the Mediator. To this end, we first mapped more precisely the VP16-binding region within
Gal11. We prepared a series of GST fusion proteins, each containing a
fragment that spans a different region of Gal11 (Fig. 2). The various GST-Gal11 fusion proteins
were incubated individually with 35S-labeled VP16, and
their physical interactions were monitored by GST pulldown assays. This
analysis identified residues 116 to 255 (G11-A in Fig. 2A) of Gal11 as
the sole VP16-binding region (Fig. 2, lane 4). The interaction required
a functional VP16 activation domain, as no such physical interaction
was observed with the activation-defective VP16 mutant protein
456FP442 (Fig. 2A). A Gal11 protein derivative [1-864(176-262)]
from which only a portion of G11-A was deleted did not interact with
VP16 (Fig. 2B, lane 3), although it was able to interact with Gal4 and
Gcn4. These findings suggest that G11-A is both necessary and
sufficient for VP16 binding.
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FIG. 2.
GST-Gal11 pulldown assay with activator proteins Gal4,
Gcn4, and VP16. (A) Radiolabeled activators indicated at the left-hand
side of the panel were incubated with GST beads containing the Gal11
fragments indicated at the top of each lane. Fragments of Gal11
polypeptide fused to GST are represented as solid bars, and the Gal11
amino acid residues contained in each fragment are indicated. The
proteins bound to the beads were visualized by SDS-PAGE and
autoradiography. The regions identified to interact with activator
proteins are labeled G11-A to G11-D. (B) GST pulldown assays with GST
beads fused to a series of Gal11 derivatives that contained various
internal deletions or with GST beads fused to the Gal11 fragments
indicated at the top of each lane as in panel A. The parts of the amino
acid residues deleted from the Gal11(1-864) fragment (lanes 3 to 6) are
indicated by numbers in parentheses following the .
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In order to examine the in vivo requirement of G11-A for
transcriptional activation by VP16, we constructed the
gal11(
176-262)
mutant strain and tested
its ability to support reporter gene
activation by LexA-VP16 in vivo.
The
GAL11 wild-type strain supported
activation of reporter
gene expression by LexA-VP16, but deletion
of G11-A completely
abolished this expression (Fig.
3A). To
confirm
that the transcriptional defect results solely from the
deletion
of G11-A rather than from a loss of other Mediator subunits,
the
gal11(
176-262) mutant hpol II was
purified, and its composition
was analyzed by immunoblot. The protein
composition of
gal11(
176-262)
mutant hpol II
was indistinguishable from that of the wild type,
and both Med2 and
Hrs1 were tightly associated with the hpol II
(Fig.
3B). Besides, all
of the deletion mutants used in this study
retained the other
activities of Mediator, such as stimulation
of basal transcription and
phosphorylation of the largest subunit
of Pol II (data not shown).
These results suggest that the transcriptional
defects of the Gal11
module mutants did not result from a conformational
distortion of the
Mediator complex by the deletions. Therefore,
G11-A plays a specific
role in transcriptional activation via
direct interaction with VP16 in
yeast cells.
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FIG. 3.
Requirement for the VP16-interacting region of Gal11 for
transcriptional activation in vivo. (A) In vivo analysis of
gal11 mutants for VP16 activation. The GAL11
derivatives introduced into the gal11 null strain are
labeled [wild type, null, and (176-262)]. Transcriptional
activation of the lacZ reporter gene containing LexA-binding
sites by LexA-VP16 in each strain is shown at the right of each allele.
In this and the other figures in this paper, reporter gene expression
level is given in units of -galactosidase activity. The percent
transcriptional activation in mutants compared to that in the wild type
is shown in parentheses. (B) Composition of hpol II purified from the
gal11(176-262) mutant. Shown are the
immunoblot analyses of hpol II immunopurified from wild-type and
gal11(176-262) mutant cells with the
antibodies indicated at the left.
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Gal4 activator requires an additional region of Gal11 for its
binding and transcriptional activation in vivo.
The observed
requirement for a specific interaction between VP16 and Gal11 for
transcriptional activation in S. cerevisiae raises the
possibility that G11-A may serve as a general binding site for natural
yeast activators such as Gal4. In order to test this idea,
35S-labeled mini-Gal4 protein was incubated with the series
of GST-Gal11 fusion proteins that were used in the above experiments.
Mini-Gal4 bound G11-A as did VP16, but in addition it interacted
strongly with G11-C (amino acids 565 to 618; Fig. 2A, lanes 4 and 7).
The presence of two binding sites for mini-Gal4 in Gal11 was confirmed with GST pulldown assays using in-frame, internal deletion mutant versions of Gal11. A Gal11 protein derivative that harbored a deletion
of a portion of G11-A [1-866(176-262)] completely lost its
affinity for VP16, but was still able to bind mini-Gal4 protein (Fig.
2B, lane 3). Only when both of the binding regions for mini-Gal4 (G11-A
and G11-C) were deleted [1-866(48-618)] was the protein unable to
bind mini-Gal4 (lane 5). These binding specificities were also
confirmed by using a series of deletion mutants in which terminal amino
acid residues in Gal11 from 256 to 864 are removed to various extents
(lanes 7 to 18).
In order to assess the physiological requirement for these Gal4-binding
sites for transcriptional activation, we examined
the growth of the
gal11 internal-deletion mutant strains on galactose
medium.
Although G11-A was essential for VP16 activation in vivo,
the
gal11(
176-262) mutant grew well on galactose
medium (Fig.
4A). However, when both of
the Gal4-interacting regions (G11-A
and G11-C) were deleted, the
gal11(
48-618) mutant, like the
gal11 null mutant, was not able to grow on galactose medium
(Fig.
4A).
In order to confirm that the growth defect of the mutants
resulted
from a Gal11 transcriptional defect, we examined the effect of
the
gal11 mutations on the expression in yeast cells of a
lacZ reporter gene bearing the
gal4 enhancer.
Consistent with the above
results, the
gal11(
176-262) strain was capable of
responding
to galactose induction efficiently (Fig.
4B). However, in
the
gal11(
48-618) strain, Gal4 activation was
reduced to 20% of that
in the wild-type strain under the same
conditions (Fig.
4B). In
particular, the transcriptional activity of
the
GAL11 internal
deletion mutants was in proportion with
their relative activator
binding strength (Fig.
4C), which demonstrates
the direct relationship
between the two properties of Mediator.
Immunoblot analysis of
gal11(
48-618) hpol II,
which showed the association of all the
Mediator components (Fig.
4D
and data not shown), confirmed that
the transcriptional defect was
caused by deletion of Gal4-binding
sites within Gal11 rather than from
the dissociation of other
Mediator subunits. Therefore, the multiple
activator-binding sites
of Gal11 appear to have an essential function
in the mediation
of the Gal4 activation signal in vivo.
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FIG. 4.
Requirement for the Gal4-interacting regions of Gal11
for transcriptional activation in vivo. (A) Growth of wild-type and
gal11 mutant yeast strains on galactose medium. Wild-type
(GAL11), gal11 null (gal11), and
two internal deletion [(48-618) and (176-262)] mutant yeast
strains grown on YP-galactose at 30°C for 72 h are shown. (B)
Transcriptional activity of gal11 mutants under Gal4
induction conditions. The GAL11 derivatives introduced into
the gal11 null strain are labeled, and the transcriptional
activation of the lacZ reporter gene containing Gal4 binding
sites in each strain is shown as in Fig. 3A. (C) Comparison of the
transcriptional activation abilities and activator-binding efficiencies
of wild-type GAL11 (1 to 1081) and a series of internal
deletion mutants [(176-262), (48-326), and (48-618)]. (D)
Composition of wild-type hpol II and hpol II purified from the
gal11(48-618) mutant yeast strains. hpol II
was immunopurified from wild-type and
gal11(48-618) mutant yeast strains, and their
compositions were compared by immunoblot analysis with the antibodies
indicated at the left. The internal deletion mutant of gal11
produced a smaller Gal11 protein derivative than did wild-type
GAL11. Sizes are shown in kilodaltons.
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Different transcriptional activator proteins utilize distinct
subunits of Mediator as their binding targets.
The in vitro
binding assays shown in Fig. 1 demonstrated that different activators
have different requirements for interaction with Mediator, and at least
for VP16 and Gal4, these interactions are essential for transcriptional
activation in vivo. Even though the effect was not as complete as with
VP16 and Gal4, transcriptional activation by Gcn4 was also reduced more
than threefold in an in vitro transcription system when all of the
Gcn4-interacting Mediator subunits were absent from hpol II (Fig. 1B).
Therefore, to examine further the generality of activator-Mediator
interactions in transcriptional regulation in yeast cells, we
deciphered the protein domains required for Gcn4 binding to Mediator
and evaluated their physiological function.
Because Gcn4 binds to both Gal11 and Hrs1, we narrowed down the binding
regions in each protein using the GST pulldown assay.
Gcn4 bound to
G11-A, as did VP16 and mini-Gal4 (Fig.
2A, lane
4). However, two
additional regions of Gal11 (G11-B and G11-D),
which were distinct from
mini-Gal4-binding region G11-C, interacted
strongly with Gcn4 (lanes 5 and 9). We next examined the Gcn4-binding
regions within Hrs1 by
creating a series of GST fusion proteins
that contained various
fragments of Hrs1 and tested them in GST
pulldown experiments (Fig.
5A). The GST pulldown assays revealed
that Gcn4 bound to an N-terminal fragment (amino acids 1 to 82;
H1-A)
and a central region (amino acids 146 to 315; H1-B) of Hrs1
(lanes 2, 4, 5, and 6). However, the mini-Gal4 protein, which
has a similar
acidic activation domain, did not interact with
any of the GST-Hrs1
fusion proteins (Fig.
5A). These results demonstrate
that Gcn4, Gal4,
and VP16 each utilize distinct regions of Mediator
as their hpol II
binding targets.
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FIG. 5.
Mediator-binding specificity of Gcn4. (A) Mapping of
Gcn4-binding regions within Hrs1. Radiolabeled Gcn4 or Gal4 proteins
were incubated with GST beads containing the GST-Hrs1 fragments
indicated at the top of each lane. Fragments of Hrs1 polypeptide fused
to GST are represented as solid bars, and the Hrs1 amino acid residues
contained in each fragment are indicated. The proteins bound to the
beads were visualized by SDS-PAGE and autoradiography. The regions
identified to interact with the transcriptional activator proteins Gcn4
and Gal4 are labeled H1-A and H1-B. (B) Correlation between Mediator
binding affinity and transcriptional activation potency of Gcn4
derivatives. Purified hpol II or recombinant HA-Gal11 or HA-Hrs1
proteins were analyzed by GST pulldown assays with GST beads fused to a
series of Gcn4 mutant protein derivatives that contained single (lanes
3 to 5), double (lanes 6 to 8), or triple (lane 9) mutations in the
hydrophobic clusters (HC) (16). Immunoblot analysis of the
bound proteins with the antibodies indicated at the right of the panel
is shown.
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In order to assess the specificity of the Gcn4-Hrs1 interactions, we
made use of a series of Gcn4 mutants that manifest differential
transcriptional activation potency. The Gcn4 activation domain
contains
multiple clusters of hydrophobic residues that make redundant
contributions to transcriptional activation (
16). When amino
acid substitutions are introduced into these clusters, their effects
on
transcriptional activation by Gcn4 are cumulative, with a reduction
of
activation potency in vivo that is proportional to the number
of
mutated clusters. Therefore, we used GST pulldown assays to
examine
whether the additive effects of these mutations on transcriptional
activation correlated with their effects on the binding of Gcn4
to
Gal11 and Hrs1. Purified hpol II was incubated with GST-Gcn4
beads that
retained either wild-type GST-Gcn4 or mutant GST-Gcn4
proteins with
single, double, or triple hydrophobic cluster substitutions.
The
single-cluster mutations had little effect on hpol II binding
(Fig. B,
lanes 3 to 5), while double-cluster substitutions resulted
in a
moderate reduction in hpol II binding (lanes 6 to 8). With
the
triple-cluster substitutions, virtually no bound hpol II was
detected
(lane 9). Therefore, the additive effects of Gcn4 mutations
on
transcriptional activation correlated with their effects on
binding to
Mediator. A similar correlation was observed when the
same experiments
were repeated with recombinant Gal11 or Hrs1
polypeptides (Fig.
5B). We
thus conclude that the interaction
between Gcn4 and hpol II depends on
a functional Gcn4 activation
domain and the Gal11 module in which Gal11
and Hrs1 make independent
contributions to Gcn4
binding.
Recruitment of hpol II through direct interaction with Gcn4 does
not limit the level of gene activation in vivo.
In order to test
the effect of the Gcn4-interacting domains within Gal11 and Hrs1 on
transcriptional activation under physiological conditions, various
gal11 and hrs1 mutants were checked for growth on
minimal medium containing 30 mM 3-aminotriazole (this growth condition
is required for activation of the HIS3 gene by Gcn4). Contrary to our previous observations, where the activator-interacting domains of Mediator were strictly required for transcriptional activation by VP16 and Gal4 in vivo, the physical interactions of Gcn4
with Gal11 and Hrs1 did not show any notable physiological relevance.
In fact, the gal11 and hrs1 null mutants also
grew as well as the wild-type yeast strain in the presence of
3-aminotriazole (data not shown). Therefore, the Gal11 module of the
Mediator is dispensable for growth under conditions that require
induction of Gcn4-regulated genes, or at least the HIS3
gene. Likewise, the expression of Gcn4-responsive reporter genes in the
gal11 and hrs1 mutant strains was equivalent to
that of the wild-type yeast strain. The transcriptional activation of
HIS4-lacZ (which contains the natural HIS4
promoter; assayed for gal11 mutants) or
2XGCN4-CYC1-lacZ (which contains a synthetic promoter with two Gcn4-binding sites; assayed for hrs1 mutants) under
amino acid starvation conditions was not reduced in any of the mutants tested compared to a wild-type yeast strain (Fig.
6A and B).
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FIG. 6.
Requirement for Gcn4-interacting regions of Mediator for
transcriptional activation in vivo. (A) In vivo analysis of the
gal11 mutants for Gcn4 activation. Transcriptional
activation of the lacZ reporter gene controlled by a natural
HIS4 promoter or a synthetic promoter containing Gal4
binding sites under the respective activation conditions is shown;
amino acid starvation or expression of exogenous Gcn4 protein fused to
a Gal4 DNA-binding domain (Gal4DBD-Gcn4) is used for transcriptional
activation of each reporter gene. The percent transcriptional
activation in mutants compared to the wild type is shown in
parentheses. (B) In vivo analysis of the effects of hrs1
mutations on transcriptional activation by Gcn4. The HRS1
derivatives and their transcriptional activities are shown as described
for panel A except that a synthetic promoter containing Gcn4-binding
sites was used instead of the natural HIS4 promoter. (C)
Composition of hpol II purified from hrs1 deletion mutants.
Immunoblot analysis of hpol II purified from wild-type, hrs1
null mutant (hrs1), hrs1(2-82)
(deletion of H1-A), and hrs1(180-343)
(deletion of H1-B) strains was carried out with antibodies against the
hpol II subunits indicated at the left.
|
|
The lack of an effect of mutations in the activator-binding target for
Gcn4 transcriptional activation appears to be related
to the distinct
mode of DNA binding of Gcn4 rather than to the
uniqueness of the Gcn4
activation domain. When the Gcn4 protein
was fused to the Gal4 DBD
(Gal4DBD-Gcn4) and assayed for its ability
to activate the reporter
gene
5xGal4-CYC1-lacZ (synthetic promoter
containing five
Gal4 binding sites), transcriptional activation
was rendered dependent
on Gcn4-Mediator interaction (Fig.
6A and
B). The deletion of
Gcn4-interacting domains in Gal11 or Hrs1
caused a two- to fourfold
reduction in reporter gene expression.
Although the transcriptional
defect observed with
hrs1(
2-82)
hpol II may be
attributed to the concurrent loss of the Gal11
module proteins (Fig.
6C, lane 2), the reduced level of activation
in response to
Gal4DBD-Gcn4 by the
hrs1(
180-343) hpol II is
not
related to the loss of other Gal11 module components (lane 3).
These results indicate that H1-B indeed acts as a functional
Gcn4-binding
target in vivo under certain conditions (see
Discussion).
Gal11 module is required for hpol II recruitment to promoters in
vivo.
In order to examine whether the interaction between
activators and the Gal11 module is indeed required for hpol II
recruitment to promoters in vivo, we performed a chromatin
immunoprecipitation using a Mediator (Rgr1)-specific antibody.
Occupancy of hpol II at the HIS4, GAL1, and
Actin promoters was analyzed in wild-type and
gal11 null mutant strains under the specified growth
conditions (Fig. 7). In wild-type cells,
hpol II was recruited to the GAL1 and HIS4
promoters only under Gal4-inducing (growth on galactose) or
Gcn4-inducing (amino acid starvation) conditions, respectively (lanes 3 and 7). In gal11 null cells, hpol II occupancy at the GAL1 promoter was reduced below a detectable level under
galactose induction conditions (lane 4). However, we observed only a
threefold reduction in hpol II occupancy at the HIS4
promoter under amino acid starvation conditions (lane 8). This shows
that the Gcn4-Mediator interaction contributes to some extent to hpol
II recruitment in vivo, but its requirement is not as absolute as it is
in the case of Gal4-Mediator activation. In conclusion, hpol II
recruitment to the promoter is the main transcriptional activation
mechanism for the Gal4 activator, whereas it is only partially required for transcriptional activation by Gcn4.
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|
FIG. 7.
Chromatin immunoprecipitation analysis of the Gal11
module-deficient mutant. The occupancy of wild-type (wt) and Gal11
module-deficient () hpol II at active or inactive promoters is shown
by assay with antibodies to Rgr1. Growth of cells on rich medium
containing galactose (YPGal) induces GAL1 transcription but
represses the HIS4 promoter. On the other hand, growth of
yeast cells on synthetic medium containing dextrose and limited amino
acids (SDex) activates HIS4 transcription but represses the
GAL1 promoter. As a control, hpol II occupancy at the
constitutively active actin promoter was analyzed in parallel. PCR
amplification of the promoter regions before (Total; lanes 1, 3, 5, and
7) and after (Precipitate; lanes 2, 4, 6, and 8) the
immunoprecipitation is shown.
|
|
| |
DISCUSSION |
In eukaryotes, several basal transcription factors and
coactivators have been reported to interact with gene-specific
transcriptional activator proteins in vitro. However, efforts to
delineate the molecular mechanisms of transcriptional activation from
the observed activator-target interactions have been hampered primarily
by the lack of experimental analyses that evaluate the physiological relevance of the in vitro interaction. Here we report on complementary biochemical and genetic analyses that show the essential requirement for the yeast Mediator Gal11 module for activator-specific
transcriptional activation in vivo.
Activator-specific binding targets in the Mediator.
We first
determined which Mediator subunit(s) interacts directly with VP16 and
the natural yeast activators Gal4 and Gcn4. All three activators
interact with hpol II in a manner that absolutely requires the Gal11
module. Srb4 was reported previously to bind to Gal4 (20).
However, hrs1 hpol II, which contains stoichiometric amounts of Srb4 (Fig. 6C), did not display the ability to interact with
Gal4 (Fig. 1A). Therefore, Srb4 is likely to contribute to Gal4-Mediator interaction to a lesser extent than the Gal11 module proteins. Nonetheless, it may serve as an alternative Gal4-binding target, especially when it is taken into account that, in the gal11(48-618) strain, Gal4 activation still
occurs, even at a much reduced level (Fig. 4B).
Analysis of the interaction between each activator with individual
constituents of the Gal11 module revealed that all three
activators
bind to Gal11, and in the case of Gcn4, additional
contacts are made
with Hrs1. These interactions involve activator-specific
regions of the
Gal11 and Hrs1 polypeptides. Our results show that
deletion of the
VP16- and Gal4-binding regions within Gal11 blocks
transcriptional
activation by VP16 and Gal4 in vivo, illustrating
the prime importance
of Gal11 in VP16 and Gal4 transcriptional
activation in vivo. Others
have reported that Gal4 activation
is also impaired in
hrs1
and
med2 yeast strains (
26,
31),
but such defects
might result from the concurrent loss of the
Gal11 protein from the
mutant hpol II complex (
23,
26).
A mutation in Gal11 protein that potentiates the activities of certain
weak Gal4 derivatives (designated Gal11P) maps to a
distinct location
(position 342) from the G11-A and G11-C regions
that interact with the
Gal4 activation domain (
1). As Gal11P
was shown to gain the
ability to interact with a portion of the
Gal4 protein (amino acids 58 to 97) distinct from the activation
domain, transcriptional activation
in Gal11P cells appears to
depend on the Gal4-Gal11 interaction in an
alternative manner
that requires a nonnatural binding
interface.
With respect to Gcn4, which interacts with both Gal11 and Hrs1, several
mutations in other Mediator proteins have been identified
that affect
transcription of Gcn4-responsive genes. These include
the
sin4 null mutation (
18), transposon insertion at
MED2 (
27),
and the temperature-sensitive
med10 mutation (
13). Parts of
the effects of the
sin4 and
med2 mutations on Gcn4 activation
may be
contributed by the loss of Gal11 module proteins, as both
Sin4 and Med2
are necessary for the stable association of Hrs1
and Gal11 with the
Mediator complex (
23,
24,
26). Depletion
of functional Med10
almost completely blocks
HIS4 induction by
Gcn4 without
affecting
GAL1 induction by Gal4 (
13). Given that
Med10 is retained in the
hrs1 hpol II (
23) and
that hpol II
recruitment to the
HIS4 promoter is not
impaired in a temperature-sensitive
med10 mutant at the
nonpermissive temperature (S. J. Han and Y.-J.
Kim, unpublished
data), Med10 does not appear to function as a
direct Gcn4-binding
target for hpol II recruitment. Med10 may,
however, play a critical
role in the postrecruitment step of transcriptional
activation by Gcn4.
Besides Med10, Srb5 was shown to act at a
step subsequent to or at
least different from that of the recruitment
of Pol II holoenzyme.
Artificial recruitment of the Pol II holoenzyme
to a reporter gene
promoter in
srb5 null yeast cells does not
lead to
transcriptional activation, whereas in
gal11 null cells
it
results in activated transcription at a level comparable to
that
observed in wild-type cells (
23). Based on these findings,
it is suggested that facilitated recruitment of hpol II via activator
binding cannot entirely account for the requirement for Mediator
proteins in gene
transcription.
Multiple and redundant mechanisms for Gcn4 transcriptional
activation.
The partial defects of Gal11 module-deficient hpol II
in the transcription reaction (Fig. 1B) and promoter binding (Fig. 7) suggest the involvement of the Gal11 module in HIS4
transcription. However, Gcn4-mediated hpol II recruitment itself does
not appear to be a major determinant of Gcn4 transcriptional activation
in vivo (Fig. 6). hpol II could be recruited to the HIS4
promoter through interaction with other activators, such as Bas1, Bas2, and Rap1. These activators may interact with hpol II via a different module of Mediator. In fact, activation by Bas2 was shown to require Med9 (13), which belongs to a different module of the Mediator.
In
HIS4 transcription, recruitment of hpol II via
interaction with an alternative activator could be one way of
overcoming
defects in the Gal11 module. However, expression of a
reporter
gene controlled exclusively by Gcn4 still remains insensitive
to the
hrs1 null mutation (Fig.
6). Only when Gcn4 is
brought
to the promoter by a heterologous DNA-binding domain does it
require
the Gal11 module for reporter gene activation. These results
raise
the possibility that Gcn4 bound to the promoter via its own
DNA-binding
domain may be able to utilize an alternative activation
pathway
that bypasses the requirement for the Gal11 module. In this
regard,
several proteins, such as MBF1 (
40) and BEF/ALY
(
44), interact
directly with Gcn4 through its bZIP domain
and can act as coactivators
for Gcn4 or other members of the bZIP
family activators. Such
proteins have the potential to constitute
alternative Gcn4 activation
pathways that circumvent the mechanism
whereby the Gcn4 activation
domain interacts directly with the Gal11
module
proteins.
It is noteworthy that Gcn4 activation has a differential requirement
for Ada2 (a component of the Spt-Ada-Gcn5 acetyltransferase
[SAGA]
complex) that is dependent on the DNA target sequence (
41).
This implies that a coactivator requirement can be influenced
by the
composition of target DNA sequences that bind Gcn4. In
this regard, the
Gcn4 bound to the enhancer element of
HIS4 promoter
and the
reporter gene promoters that we utilized may depend on
other, more
determinant regulatory pathways that do not require
interactions with
Gal11 module proteins. Nucleosome remodeling
by the SAGA complex may
play a more predominant role in
HIS4 expression
than does
Mediator
recruitment.
| |
ACKNOWLEDGMENTS |
We thank Alan Hinnebusch, Randall Morse, Toshio Fukasawa, Hiroshi
Sakurai, Masafumi Nishizawa, Richard Reese, Richard Young, Andrés
Aguilera, and Roger Kornberg for yeast strains, plasmids, and
antibodies; Kelly LaMarco for careful reading of the manuscript; and
our colleagues in the Kim lab for helpful discussion.
This work was supported by the Creative Research Initiatives Program
and the Molecular Medicine Research Group Program (98-J03-01-01-A-05) from the Korean Ministry of Science and Technology to Y.-J.K.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Sungkyunkwan
University School of Medicine, Chunchun-dong 300, Jangan-ku, Suwon-si, Kyunggi-do 440-746, Korea. Phone: 82-31-299-6439. Fax: 82-31-299-6435. E-mail: yjkim{at}medical.skku.ac.kr.
| |
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Molecular and Cellular Biology, December 2000, p. 8709-8719, Vol. 20, No. 23
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
