From the Laboratory of Gene Regulation, The Picower Institute for Medical Research, Manhasset, New York 11030
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ABSTRACT |
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The ubiquitous transcription factor, NF-Y, plays
a pivotal role in the cell cycle regulation of the mammalian cyclin A,
cdc25C, and cdc2 genes, in the S-phase
activation of the ribonucleotide reductase R2 gene, in addition to its
critical role as a key proximal promoter factor in the transcriptional
regulation of the albumin, collagen, lipoprotein lipase, major
histocompatibility complex class II, and a variety of other eukaryotic
and viral genes. In this report, the NF-Y complex has been shown to
possess histone acetyltransferase activity through physical association
with the related histone acetyltransferase enzymes, human GCN5 and
P/CAF in vivo. The assembled NF-YA:B:C complex, and the
NF-YB:YC, NF-YB:YC (DNA binding-subunit interaction domain), and
NF-YC:YB (DNA binding-subunit interaction domain) heterodimers were
sufficient to support stable interaction with human GCN5 in
vitro, suggesting that these histone acetyltransferases interact
with a unique surface in the ancient YB:YC histone-fold motif. Deletion
of either N- or C-terminal regions in human GCN5 disrupted interaction
with NF-Y in vitro. In addition, human GCN5 was observed to
activate NF-Y in transient transfections in vivo using a
natural 2(I) collagen promoter. These results suggest that these
associated histone acetyltransferases may serve to modulate NF-Y
transactivation potential by aiding disruption of local chromatin
structure thereby facilitating NF-Y access to its CCAAT box DNA binding
sites.
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INTRODUCTION |
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Chromatin structure plays a vital role in the control and regulation of eukaryotic gene transcription, as nucleosomes are now known to be remodeled during transcription in a dynamic process that involves a number of multicomponent complexes that participate in enzymatic modification of chromatin structures (1). Recent characterization of several ATP-dependent remodeling activities (2-4), and the enzymes that acetylate or deacetylate specific N-terminal lysines in the core histones proteins, provide convincing evidence that chromatin structure is significantly involved in transcriptional regulation (5, 6). In addition, a growing subset of known transcriptional cofactors have been shown to possess intrinsic histone acetyltransferase (HAT)1 activity, as well as established activation domains, and physical links to known DNA binding transcription factors (7-9). The overall importance of HAT activity in transcriptional control mechanisms has recently been underscored by the observation that the DNA binding activity of the tumor suppressor protein, p53, can be regulated through acetylation of specific C-terminal lysine residues by p300/CBP (10).
Nuclear Factor-Y (NF-Y) (11), also known as the CCAAT-binding factor
(12) together with its Saccharomyces cerevisiae homolog, HAP2/3/5 (13), is the only known transcription factor whose DNA binding
domain is created through the interaction of three heterologous
subunits (13-15). Biochemical analyses of the NF-Y complex have
demonstrated that the NF-YB:YC subunits associate through a subdomain
in the DNA binding-subunit interaction domain (DBD) (16) referred to as
the histone-fold "handshake" motif (17, 18), which resembles an
-helical structure first identified in the core histone proteins as
primarily responsible for dimerization of the H2A/H2B and H3/H4 histone
pairs. The NF-YB:YC histone-fold is most related to histones H2B/H2A,
respectively (18), and similarly contains a number of hydrophobic amino
acids which project along one face of an
-helix. Both NF-YB:YC and
these core histone pairs require strong denaturants to effect their
biochemical separation. The NF-YB:YC histone-fold plays a crucial role
in creation of a functional NF-Y CCAAT box DNA binding complex as the
NF-YA subunit associates only with the YB:YC heterodimer (15).
The yeast protein GCN5 (yGCN5) has long been known to collaborate with yeast GCN4 in the transcriptional regulation of a large number of genes involved in yeast amino acid biosynthesis and to be involved in maximally increasing the transcriptional activity of several respiratory genes which depend on the yeast HAP2/3/4/5 complex (13, 19, 20). yGCN5 is now known to possess intrinsic HAT activity (5) and is thought to acetylate specific N-terminal histone lysine resides as a consequence of its association with additional adaptor proteins in two large multicomponent complexes, referred to as the SAGA complexes (21). In these complexes, additional protein components are thought to modulate yGCN5 substrate specificity, and together these large adaptor structures serve to link upstream activators with the basic RNA polymerase II machinery. Recent cloning and characterization of the human equivalents of these yeast adaptor components (7, 22, 23) has suggested that human GCN5 (hGCN5) is likewise associated with additional protein components and is highly related to another HAT enzyme, P/CAF (7), which has been shown to physically associate with the general transcriptional coactivator, p300/CBP (7), and the hormone receptor cofactor, ACTR (24).
In this report the NF-Y complex has been shown to possess HAT activity in vivo through physical association with the known HAT enzymes, hGCN5 and P/CAF. hGCN5 activates an NF-Y CCAAT box reporter in vivo and associates with the NF-YB:YC histone-fold motif, in vitro. This report further identifies the first transcription factor target for hGCN5, suggests that yGCN5 likewise is associated with the yeast HAP2/3/5 complex through the HAP3/5 histone-fold, and thereby suggests a direct functional role for yGCN5 in global yeast respiratory gene regulation.
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EXPERIMENTAL PROCEDURES |
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Cell Culture and Transfections--
HeLa and 293 cells were
maintained in 10-cm dishes in Dulbecco's modified Eagle's medium
(Life Technologies, Inc.) supplemented with 10% fetal bovine serum
(HyClone) and grown at 37 °C, 5% CO2. Full-length human
GCN5 (provided by X.-J. Yang and Y. Nakatani) (7) was cloned into
pcDNA3 (Invitrogen) using PCR. pH6 (25) was used to generate a
site-directed mutation of the proximal CCAAT box site contained in the
2(I) collagen promoter. Both the wild-type and NF-Y mutant promoters
were cloned into the pGL3 luciferase vector (Promega) to generate pH6
GL3 and pH6m GL3, respectively, and verified using standard procedures
(26). HeLa cells were transfected using the calcium phosphate
coprecipitation method and assayed for both luciferase and
-galactosidase activities using the Dual-Light assay system
(Tropix).
Recombinant Proteins--
Human GCN5 was cloned into pRSETA
(Invitrogen) and pGEX2TK (Pharmacia Biotech Inc.) vectors using PCR.
The C-terminal deletion mutant of hGCN5 was prepared from GST-hGCN5 by
restriction enzyme digestion and contains amino acids 1-332; the
"bromodomain" (27) containing N-terminal deletion of hGCN5 was
cloned into pGEX2TK using PCR and contains amino acids 337-476 (7).
His-hGCN5 was purified from the soluble fraction of Escherichia
coli BL21(DE3) lysates following induction with 0.1 mM
isopropyl--D-thiogalactopyranoside for 1 h at
37 °C using Ni2+ chelating resin (Novagen). GST fusion
proteins were expressed and purified as described (28). YA (DBD), YB
(DBD), and YC (DBD) were cloned into pGEX2TK using PCR and contain
amino acids 234-303, 53-143, and 1-143, respectively (15, 29). The
cloning expression and purification of full-length GST- and His-NF-YABC
subunits has been described previously (30). GST-HMG-Y (20-56)
(provided by M. Wegner) (31), GST-Dr1 (provided by D. Reinberg) (32), and GST-PC4 (provided by R. Roeder) (33) have been described.
IP-HAT Assays-- HeLa cell nuclear extracts were prepared according to Dignam et al. (34). 293 cells were collected by scraping into 1 ml of ice-cold PBS and pelleted by gentle centrifugation. PBS was removed, and the cells were resuspended in 750 µl of lysis buffer (50 mM Tris-HCl, pH 8.0, 150 mM NaCl, 5 mM EDTA, 0.5% (v/v) Nonidet P-40, 0.1 mM phenylmethylsulfonyl fluoride). The lysis mixture was incubated on ice for 20 min, then cleared by centrifugation at 12,000 × g for 10 min at 4 °C.
Antibodies were added to 100 µl of either HeLa nuclear extract or 293 whole cell extract at 4 °C for 2 h. Protein A-Sepharose:protein G-Sepharose (15 µl; 1:1) (Pharmacia) was added, and the mixture was rotated overnight at 4 °C. Immune complexes were pelleted by gentle centrifugation and washed six times at 4 °C with 1.5 ml of lysis buffer, followed by two washes with 1 × PBS (1 mM DTT), and two washes with 1 × HAT reaction buffer (50 mM Tris-HCl, pH 8.0, 10% (v/v) glycerol, 1 mM DTT, 1 mM phenylmethylsulfonyl fluoride, 0.1 mM EDTA) and assayed as described (34). Acetylation reactions were performed for 20 min at 30 °C, and products were resolved with 12% SDS-PAGE gels and fluorography (Amplify; Amersham Corp.). Affinity-purified polyclonal antibodies directed against the NF-YB and NF-YA subunits were prepared as described (36). Affinity-purifiedWestern Blot Analyses--
Proteins bound to -YB affinity
beads following washing with IP lysis buffer were eluted using SDS-PAGE
buffer with no reducing agents at room temperature. Immunoprecipitates
in all cases were then heated to 95 °C under reducing conditions,
electrophoresed through 12% SDS-PAGE gels, transferred to
nitrocellulose membranes, and incubated with a 1:2000 dilution of
primary affinity-purified antibodies overnight at 4 °C. Bound
antibodies were detected using
-rabbit horseradish
peroxidase-conjugated secondary antibodies (1:5000) and ECL
(Amersham).
In Vitro Protein-Protein Interaction Assays-- Purified GST fusion proteins were incubated with glutathione-agarose beads (Sigma) (20 µl packed bead volume) with gentle mixing for 20 min at room temperature in 100 µl of 1 × PBS (1 mM DTT), then washed with 2 ml of PBS. In specific cases beads were further incubated with additional NF-Y subunits, then washed with PBS. Recombinant His-hGCN5 was added, and the incubation continued at 4 °C for 1 h with gentle mixing. Beads were washed and processed for HAT activity as described for immunoprecipitates above. YA (DBD) was cleaved from GST-YA (DBD) using thrombin and 32P-labeled using heart muscle creatine kinase (Sigma). GST fusion proteins were bound to glutatione-agarose beads then incubated with the assembled 32P-NF-Y complex or the 32P-YA (DBD) subunit alone. Beads were washed as described above for immunoprecipitations, and retained 32P-YA (DBD) was eluted and analyzed using SDS-PAGE gels.
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RESULTS |
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During study of accessory protein cofactor interactions with the
NF-Y complex (39), a CCAAT box DNA affinity-purified NF-Y fraction was
observed to possess histone acetyltransferase activity. To address
whether this HAT activity was copurifying or physically associated with
NF-Y in vivo, affinity-purified -NF-YB and
-NF-YA antibodies were used to immunoprecipitate NF-Y derived from HeLa nuclear and 293 whole cell extracts and tested using the IP-HAT assay
(8, 35) (Fig. 1, A and
B). IP-HAT analysis of the NF-Y complex using either of
these subunit directed antibodies resulted in acetylation of the core
histone proteins, H3, H2B, H2A, and to a lesser extent, histone H4.
Control
-p300 antibodies brought down HAT activity in both cell
types in a manner similar to
-NF-Y antibodies, whereas
-E1A
antibodies precipitated HAT activity only in 293 extracts and not HeLa
extracts as predicted (7, 8, 35). Preincubation of affinity-purified
-YB antibodies with the purified immunogen, GST-YB, effectively
blocked specific NF-Y-associated IP-HAT activity (Fig. 1C).
Recombinant human GCN5 (hGCN5) acetylated histone H3 predominantly in
this liquid HAT assay as has been observed previously with both yeast
and human GCN5 (7, 35). Deletion of histone substrates or substitution with bovine serum albumin in the IP-HAT assay resulted in no
acetylation, whereas both the
-YA and
-YB immunoprecipitates
retained specific CCAAT box DNA binding activity, a property of the
heterotrimeric NF-Y complex (data not shown).
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To identify the protein(s) responsible for the observed NF-Y-associated
HAT activity, -YB immunoprecipitates derived from HeLa extracts were
analyzed for the presence of known HAT proteins using Western blot
analysis (Fig. 1D). Both hGCN5 and P/CAF HAT proteins were
detected in
-YB affinity bead immunoprecipitates using
-hGCN5
affinity-purified antibodies, which were raised against full-length
hGCN5 and cross-react with P/CAF (7) (lane 2). P/CAF and
NF-YB were also detected in HeLa
-YB immunoprecipitates using
affinity-purified
-P/CAF antibodies, which were raised against the
unique N-terminal region of P/CAF and do not cross-react with hGCN5 (7)
(lane 4) and affinity-purified
-YB antibodies (lane
6), respectively. These results suggested that hGCN5 and P/CAF
were associated with NF-Y in vivo and responsible for the observed HAT activity. P/CAF has been shown to associate with the
coactivator, p300/CBP (7), which itself has intrinsic HAT activity,
however p300/CBP was not detected in HeLa
-YB immunoprecipitates using Western analysis (data not shown). To examine the possible functional role of hGCN5 in modulating NF-Y transcriptional activity in vivo, HeLa cells were transfected with hGCN5 and an NF-Y
CCAAT box containing promoter reporter derived from the murine collagen
2(I) gene (25) (Fig. 2). The observed
~4-fold activation of this reporter by hGCN5 was dependent on an
intact proximal CCAAT box element, suggesting that hGCN5 functionally
interacts and regulates NF-Y transactivation potential on a natural
CCAAT box-containing promoter.
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To examine the possibility that the NF-Y complex possesses intrinsic HAT activity, individual and specific combinations of recombinant NF-Y subunits were tested for HAT activity using the liquid assay. Neither the complete functional NF-YA:B:C complex, the NF-YB:C heterodimer, nor any individual NF-Y subunit was observed to possess HAT activity (data not shown). An in vitro GST fusion protein "pull-down" assay was developed to determine the specific NF-Y subunit requirements for physical association with hGCN5 (Fig. 3). Recombinant hGCN5 was incubated with the assembled NF-Y complex, the NF-YB:C heterodimer, and individual NF-Y subunits that were tethered to glutathione-agarose beads, then assayed for HAT activity. Using this approach hGCN5 was shown to stably associate with the complete NF-Y complex and the NF-YB:C heterodimer. hGCN5 did not associate with any individual NF-Y subunit, whereas hGCN5 was observed to associate with the full-length YB:YC complex (data not shown) and in heterodimers composed of a full-length subunit and its complementing YB (DBD) or YC (DBD) partner (Fig. 3, lanes 6 and 8, respectively). Recombinant hGCN5 (7, 35), P/CAF (7), and yGCN5 (37) are known to acetylate histone H3 predominantly in the liquid HAT assay when presented with the core histone proteins, whereas acetylation of any of the core histone proteins in nucleosomes by yeast GCN5 requires additional protein components assembed in the large molecular mass SAGA complexes (21, 38). Predominant acetylation of histone H3 by hGCN5 tethered to recombinant NF-Y or NF-YB:YC complexes (Fig. 3) suggests that the histone specificity of hGCN5, and possibly P/CAF, is altered when associated in the native NF-Y complex, since histones H2A and H2B were additionally acetylated by immunoprecipitated NF-Y in the IP-HAT assay (Fig. 1).
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In an attempt to map relevant functional domains in hGCN5 that are required for stable interaction with NF-Y, several GST-hGCN5 deletion mutants were tested using an in vitro GST pull-down assay (Fig. 4). NF-YA (DBD) has been used previously to assemble a functional heterotrimeric NF-Y complex and as an individual NF-YA subunit derivative to demonstrate that each stably interacts with a single AT-hook motif present in the non-histone chromosomal proteins, HMG-I(Y) (39) (Fig. 4, A and B, lane 6). Interaction of hGCN5 with NF-Y was dependent on an intact NF-Y complex (Fig. 4A, lane 3), since no specific interaction with YA (DBD) alone was observed (Fig. 4B, lane 3). Deletion of either the N- or C-terminal regions of hGCN5 severely inhibited its stable interaction with the assembled NF-Y complex (Fig. 4A, lanes 4 and 5, respectively). The hGCN5 C-terminal bromodomain (5, 27) contained in the N-terminal deletion mutant is not itself sufficient to support stable interaction between NF-Y and hGCN5 (Fig. 4A, lane 5). These results suggest that interaction with NF-Y requires specific domains in both the N- and C-terminal regions or that the primary interaction site maps to a region close to the deletion site.
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DISCUSSION |
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Both single nucleosomes and higher order chromatin structure are
generally thought to represent structural impediments to gene
transcription (1). Recent isolation of chromatin remodeling activities
has provided new insights into the mechanisms responsible for altering
chromatin structure during transcription and the means to begin
approaching questions regarding the targeting of specific activities to
specific promoters (2-6). Further refinement in the crystal structure
of the core nucleosome particle (40) has now supported earlier results
(41), which together suggest the N-terminal histone tails are involved
in nucleosome-nucleosome interactions and are involved in maintaining
higher order chromatin structure. Together these observations now
suggest that acetylation of the N-terminal histone lysines residues is
involved in disrupting the structure between nucleosomes in local
regions in chromatin thereby facilitating access of transcription
factors to specific promoters. In addition, recent reports have
demonstrated that p53 is a substrate for p300 (10), and the HAT
enzymes, p300, P/CAF, and TAFII250, are capable of
acetylating components of the general RNA polymerase II machinery
(i.e. TFIIE and TFIIF) (42). These results suggest that
HAT enzymes play additional roles in modulating the DNA binding
activity of an important tumor suppressor protein, and the functional
activity of general initiation factors, and further suggest important
implications for their role as cofactors in modulating upstream
transcription factor transactivation potential.
This report identifies the NF-Y complex as the first mammalian
transcription factor target for the human acetyltransferase, GCN5, the
first DNA-binding transcription factor associated with P/CAF, in
vivo, and maps the site of interaction of hGCN5 to the highly
conserved DBD elements of the NF-YB:C heterodimer. Anti-YB immunoprecipitates, which contain the NF-Y complex, were observed to be
associated with the two highly related HAT enzymes, GCN5 and P/CAF. The
C-terminal region of P/CAF is 86% identical on the amino acid level to
hGCN5 (7), which includes both the region responsible for HAT activity
and the bromodomain, a motif thought to be involved in additional
protein-protein interactions (5, 27). The N-terminal region of P/CAF is
unique, and -P/CAF antibodies (7) that recognize both N- and
C-terminal regions were observed to detect P/CAF in
-YB
immunoprecipitates (Fig. 1D). P/CAF has been shown to be
associated with two cofactors, p/300/CBP (7) and ACTR (24); however,
the site(s) of physical interaction in either case has not been
identified. While P/CAF is known to interact with p300/CBP, hGCN5 does
not (7), and presently no mammalian transcription factor has been shown
to interact with both hGCN5 and P/CAF. NF-Y is the first DNA-binding transcription factor shown to be associated with P/CAF and hGCN5. In vitro binding studies between NF-Y and hGCN5 strongly
suggest that P/CAF interacts with NF-Y likewise through its C-terminal region, which is highly related to hGCN5. Presently it is not known if
these NF-Y: HAT complexes exhibit differential activities with regard
to specific NF-Y-responsive promoters in vivo, and if the
composition of NF-Y:HAT complexes differ with regard to additional
protein components.
Comparison of immunoprecipitated NF-Y-associated HAT activity with
in vitro reconstituted NF-Y:hGCN5 HAT activity showed an altered histone substrate specificity. Both histone H2A and H2B were
observed to be acetylated when presented to NF-Y immunoprecipitates in
addition to the predominant product, H3, while in vitro
reconstituted complexes acetylated histone H3 exclusively. These
results suggest that native NF-Y may be associated with additional
protein components in vivo, in a manner possibly analogous
to the yeast SAGA complexes that contain yGCN5, in addition to the
characterized components, Spt 3/7/20, ADA2, ADA3, and other unknown
components (21). hGCN5, yGCN5, and P/CAF are known to acetylate histone
H3 predominantly when presented with the core histone proteins and to
be unable to acetylate histones in isolated nucleosomes in the absence
of additional protein components (7, 37). Recent isolation of hADA2,
the human homolog to the yeast adaptor protein, yADA2 (22), suggests
that some fraction of both hGCN5 and P/CAF may be associated in
vivo with hADA2 and mammalian equivalents of the SAGA complexes. Further analysis of -NF-Y immunoprecipitates will determine if hADA2
is present and the identity of additional protein components that may
play a role in regulating both hGCN5 and P/CAF histone substrate
specificity.
Mutational analysis of the NF-YB subunit has established that the YC interaction domain and the region required for DNA binding activity largely overlap in the ~90-amino acid YB (DBD) (16). In contrast, the NF-YA (DBD) element is more clearly defined and contains separable subdomains used for DNA binding and interaction with the YB:YC heterodimer. The YB:YC histone-fold motifs appear to play crucial roles in subunit interactions through creation of unique surfaces for interaction with the YA (DBD) and with the HAT enzymes, hGCN5 and P/CAF. The YB:YC histone-fold may make additional nonspecific contacts with DNA sequences flanking the CCAAT box, in a manner analogous to the H2B:H2A histone pair, whereas the YA (DBD) may make the majority of sequence-specific DNA contact in the CCAAT box, in addition to providing binding surfaces for HMG-I(Y) and PC4/p15 (39). Clearly, x-ray crystallographic analyses of the NF-Y (DBD) regions in association with CCAAT box DNA and these newly identified HAT enzymes in the future will further our understanding of how these proteins are structurally organized and provide additional insights into how they function in vivo.
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ACKNOWLEDGEMENTS |
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I am grateful to X.-J. Yang and Y. Nakatani for kindly providing their hGCN5 and P/CAF reagents and to Drs. D. McNabb, L. Guarante, X.-Y. Yang, and Y. Nakatani for their comments and suggestions.
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FOOTNOTES |
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* This work was supported by United States Public Health Service Grant AI37686 from the NIAID, National Institutes of Health.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
To whom correspondence should be addressed.
1 The abbreviations used are: HAT, histone acetyltransferase; IP, immunoprecipitation; CBP, CREB-binding protein; CMV, cytomegalovirus; DBD, DNA binding-subunit interaction domain; DTT, dithiothreitol; GST, glutathione S-transferase; yeast GCN5, yGCN5; hGCN5, human GCN5; NF-Y, nuclear factor-Y; PAGE, polyacrylamide gel electrophoresis; P/CAF, p300/CBP-associated factor; PCR, polymerase chain reaction; PBS, phosphate-buffered saline.
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REFERENCES |
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