From the Department of Biochemistry and Cell Biology,
Stony Brook University, Stony Brook, New York 11794-5215, the
§ Howard Hughes Medical Institute, Department of
Biochemistry and Molecular Biology, Pennsylvania State University,
University Park, Pennsylvania 16802-4500, the ¶ Lawrence Berkeley
National Laboratory and Department of Molecular and Cellular Biology,
University of California, Berkeley, Berkeley, California 94720, and the
Laboratory of Environmental Biochemistry, Graduate School of
Pharmaceutical Sciences, Osaka University, Suita, Osaka 565-0871, Japan
Received for publication, October 18, 2002, and in revised form, March 6, 2003
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ABSTRACT |
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The SAS2 gene is involved in
transcriptional silencing in Saccharomyces cerevisiae.
Based on its primary sequence, the Sas2 protein is predicted to be a
member of the MYST family of histone acetyltransferases (HATs). Sas2
forms a complex with Sas4 and Sas5, which are required for its
silencing function. Here we show that recombinant Sas2 has HAT activity
that absolutely requires Sas4 and is stimulated by Sas5. The
recombinant SAS complex acetylates H4 lysine 16 and H3 lysine 14. Furthermore, a purified SAS complex from yeast shows similar activity
and specificity. In contrast to other MYST HATs, neither the
recombinant nor the native SAS complex acetylated nucleosomal histones
under conditions that were optimum for acetylating free histones.
Finally, although the SAS subunits interact genetically and physically
with Asf1, a histone deposition factor, association of H3 and H4
with Asf1 blocks their acetylation by the SAS complex, raising the
possibility that the SAS HAT complex may acetylate free histones prior
to their deposition onto DNA by Asf1 or CAF-I.
In the yeast Saccharomyces cerevisiae, as in higher
eukaryotes, transcriptional silencing results from the formation of
highly condensed chromatin called heterochromatin. Many factors have been identified that influence the formation and maintenance of heterochromatin. Some of these proteins either physically interact with
or modify the histone N termini, while others are required for
deposition of histones onto DNA (1). In S. cerevisiae, silenced chromatin regions are found at the two silent mating loci, HML and HMR, at telomeres, and at rDNA
(2).
The SAS2 gene was identified in two screens for genes
involved in transcriptional silencing (3, 4). sas2 mutants
are defective in silencing at telomeres, and at HML in a
The SAS complex has also been functionally linked to the histone
deposition proteins Cac1 and Asf1. Sas4 was isolated in a two-hybrid
screen with Asf1 as bait (11), and Cac1 was isolated in a two-hybrid
screen with Sas2 as bait (5). Co-immunoprecitation analyses further
showed that the SAS complex associates with both Asf1 (7) and Cac1 in
yeast (5). Cac1 is a subunit of the yeast CAF-I complex (12). Both Asf1
and CAF-I bind to histones H3 and H4 and are suggested to function in
non-overlapping pathways for histone deposition and chromatin assembly
(13-18). asf1 mutants display the same effects on silencing
at HML and HMR as sas2, 4, or
5 mutants (5, 7), but unlike sas mutants,
asf1 mutants have little or no defect in telomeric silencing
(19). cac mutants, like sas mutants, have defects
in telomeric and HM silencing although the magnitudes of
these defects differ (12, 20). Furthermore, cac mutations
cause silencing defects at HML and HMR that are only partially epistatic with sas mutations (5). Together, these data suggest that the interactions among the SAS complex, CAF-I,
and Asf1 may be complex and locus-specific.
In this study we show that co-expression of Sas2, Sas4, and Sas5 in
Escherichia coli leads to formation of a stable SAS complex that acetylates histones. Sas4 is essential for the acetyltransferase activity of Sas2, and Sas5 is important. The preferred in
vitro substrates for the recombinant SAS complex are lysine 16 of
histone H4 and lysine 14 of histone H3. In contrast to the
Sas3-containing NuA3 and the Esa1-containing NuA4 complexes, the SAS
complex shows no activity toward nucleosomes or (H3·H4)2
tetramers deposited onto DNA under conditions of our assays. We have
also purified enzymatically active SAS complex from yeast, which
contains Sas2, Sas4, and Sas5. This native enzyme shows the same
substrate specificity as the recombinant enzyme, including the
preference for free histones.
Yeast Strains--
Yeast strains used in this study were derived
from YJW228 (SAS4-13Myc:kanMX6) described previously (7).
Strains YJL458 and YJW459 were constructed by integration into YJW228
of the sequences encoding the tandem affinity purification (TAP) tag immediately before the stop codon of the SAS2 and
SAS5 genes, respectively, as described elsewhere (21).
Standard yeast manipulations were performed as described (22).
Plasmids--
Plasmids for expression of Sas proteins in
E. coli were created as follows. pAS131
(Sas2-His6) was made by PCR amplification of the
SAS2 open reading frame (ORF) from yeast genomic DNA. The primers were designed so that the SAS2 sequence contained a
5' NcoI site and a 3' EcoRI site. The PCR product
was cloned into pET28b (Novagen) so that SAS2 was under
control of an inducible T7 promoter and was in-frame with sequences for
a C-terminal His6 tag. pDB16
(sas2M1-His6) was made exactly as described for
pAS131 except that pS139 was used for the template for the PCR
reaction. pS139 was previously described (7) and encodes a mutated
version of Sas2 in which amino acids 219-221 are changed to alanines.
pDB5 (Sas4) was made by cloning a PCR fragment containing the
SAS4 gene with a 5'NcoI site and a
3'BamHI site into pET28b. pDB6 (Sas5) was made by cloning a
PCR fragment containing the SAS5 ORF with a
5'NcoI site and a 3'BamHI site into pET28b. pDB7
(Sas4,Sas5) was made by cloning a BglII-BamHI
fragment containing SAS4 from pDB5 into the BglII site of pDB6. Both SAS4 and SAS5 are transcribed
in the same direction, each under control of a separate T7 promoter.
PCR was used to amplify a fragment from pAS131, which contained
SAS2-His6, the T7 promoter and terminator, and
SphI restriction sites on each end. The fragment was cloned
into the SphI site of pDB7 to make pAS132
(Sas2-His6,Sas4,Sas5), into pDB5 to make pDB18
(Sas2-His6,Sas4), and into pDB6 to make pDB17
(Sas2-His6,Sas5). A similar SphI fragment was
made using pDB16 as template and cloned into pDB7 to make pAS134
(sas2M1-His6,Sas4,Sas5). All coding regions
were sequenced to check for PCR errors.
Protein Expression and Purification in E. coli--
Sas proteins
were expressed in E. coli strain BL21 (DE3) codon plus by a
3-h induction with 0.4 mM IPTG. The proteins were purified
from 100-ml cultures using Novagen His Bind Affinity Resin according to
the manufacturer's instructions. Purified proteins were dialyzed
against 50 mM Tris, pH 8 and frozen at Protein Expression and Purification in Yeast--
Whole cell
extracts were prepared from a 12-liter culture as previously described
(26). The native SAS complex was purified by the tandem affinity
purification method (21). After purification, 20% of the purified SAS
complex was separated on a polyacrylamide gel and silver stained.
HAT Assays--
HAT assays using recombinant SAS were done in 25 µl with 37.5 mM Tris, pH 8.5, 0.1 mM EDTA, 1 mM dithiothreitol, 3.2 µM
[3H]acetyl coenzyme A (Amersham Biosciences, 5.6 Ci/mmol). Substrates for HAT assays were as follows: 0.16 mg/ml chicken
erythrocyte histones (27), 0.12 mg/ml HeLa nucleosomes and HeLa core
histones, and 40 µM H3 or H4 N-terminal peptides.
Approximately 12 ng of Sas2 and 120 ng of Esa1 were used. The amount of
enzyme used in each assay was estimated by comparing Coomassie Blue
staining of samples with bovine serum albumin standards, analyzed by
SDS-PAGE. HAT assays for the yeast SAS complex were done as above
except that the reaction volume was 15 µl, and the substrates
were as follows: 0.5 µg of HeLa nucleosomes, HeLa core histones, and
recombinant yeast core histones and 40 µM H4 N-terminal
peptides. The amount of enzyme used was 1% of that obtained from a
12-liter preparation (5.0% of that shown on the silver-stained gel in
Fig. 6A). Reactions were incubated at 30 °C for 45 min
and then spotted onto Whatman p81 cation exchange paper and air-dried.
The dried papers were washed three times for 5 min each with 50 mM sodium carbonate, pH 9.0 and once with acetone.
Radioactivity was quantitated in a liquid scintillation counter.
SDS-PAGE of Acetylated Histones--
For the experiment in Fig.
3A, chicken histones were acetylated with SAS complexes or
Esa1 as described above except that the final concentration of histones
was 0.4 mg/ml. For the experiment in Fig. 6B, reactions were
carried out exactly as described above for the native SAS enzyme.
Reactions were terminated by addition of 5 µl of 5× protein loading
dye. Samples were heated to 100 °C for 5 min, centrifuged at
16,000 × g for 2 min, and resolved on 15%
SDS-polyacrylamide gels. Proteins were stained with Coomassie Blue,
destained, saturated with EN3HANCE (PerkinElmer Life
Sciences), dried under vacuum, and exposed to film.
For Fig. 5, reactions were performed with 150 nCi of
[14C]acetyl coenzyme A (57 mCi/mmol). Reactions were
performed in a 20-µl reaction volume in the same buffer described
above, plus 10 mM sodium butyrate and 1 mM
phenylmethylsulfonyl fluoride. Reactions were assembled on ice,
incubated at 30 °C for 30 min, and stopped with the addition of 5 µl of 5× SDS-PAGE loading buffer. Reactions were heated at 100 °C
for 1 min and loaded onto 15% SDS-PAGE gels, which were
silver-stained, photographed, treated with 1 M sodium salicylate/30% MeOH, dried, and subjected to fluorography.
Amino Acid Sequence Analysis--
HAT assays were done as
described above using the recombinant SAS complex and either the H3 or
H4 peptide. Four reactions were pooled, applied to ProSorb membranes
(PerkinElmer Life Sciences) and processed for sequencing according to
instructions from the manufacturer. The samples were subjected to Edman
degradation. Eluates from each cycle were collected, dried, resuspended
in 50 mM sodium acetate, pH 5.2, and counted in a liquid
scintillation counter.
Recombinant preparations of most MYST family proteins identified
to date function as HATs in vitro in the absence of other factors (8). Although Sas2 displays a high degree of homology to MYST
family proteins, we and others (5) have been unable to detect HAT
activity using recombinant Sas2. Because Sas2 is part of a complex with
Sas4 and Sas5 in vivo, and because mutation of
SAS4 or SAS5 causes the same phenotypes as
mutation of SAS2, we reasoned that Sas2 might require these
additional subunits for activity. Furthermore, Sas2 expressed in
E. coli is to a large extent insoluble (data not shown). It
has been shown that, in some cases, co-expression of several subunits
of a multiprotein complex can increase the solubility of the individual
proteins (28, 29). Therefore, we designed a plasmid for co-expression of SAS2, SAS4, and SAS5 in E. coli. Plasmid pAS132 contains SAS2 (including sequences
for a C-terminal His6 tag), SAS4 and
SAS5, with each gene under control of an inducible T7
promoter. Upon induction, all three proteins were expressed, although
only a small fraction of Sas2-His6 and Sas5 was soluble
(data not shown). When the soluble fraction was purified using
nickel-affinity chromatography by virtue of the His tag on Sas2,
substantial amounts of Sas4 and Sas5 coeluted with Sas2, indicating
that the proteins formed a complex in E. coli (Fig.
1B). Remarkably, this complex
had robust HAT activity using chicken histones as substrate (Fig.
1A). In contrast, equivalent amounts of recombinant
Sas2-His6 expressed and purified in the same manner in the
absence of Sas4 and 5 displayed no activity (Fig. 1, A and
B).
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
sir1 background, but display improved silencing at a
mutated HMR locus (3, 4) and at rDNA (5). Genetic evidence
suggested that SAS2 functions in a pathway with two other
genes, SAS4 and SAS5 (6) and recent biochemical
evidence demonstrated that the three proteins exist as a complex in
yeast termed SAS (5, 7). SAS2 encodes a putative member of
the MYST family of histone acetyltransferases (HATs),1 which also includes
human MOZ, MORF, TIP60, and HBO1; Drosophila MOF and Chm;
and S. cerevisiae Sas3 and Esa1. Although many of these
proteins have been shown to possess HAT activity (8), no enzymatic
activity had previously been detected for Sas2. However, recent work
suggests that acetyltransferase activity may be important for Sas2
function. We and others (5, 7) have shown that the conserved acetyl-CoA
binding domain of Sas2 is required for HML and telomeric
silencing, as mutations in this motif cause the same silencing defects
as does deletion of SAS2 (5, 7). Furthermore, a point
mutation (K16R) in the histone H4 N-terminal tail phenocopies the
effects of sas2 mutants on silencing (5). The H4-K16R
mutation causes complete loss of telomeric silencing and improves
silencing at a mutated HMR to the same extent as deletion of
SAS2. Combination of a SAS2 gene deletion with
the H4-K16R mutation leads to no additional increase in HMR
silencing (5). Very recently, two groups (9, 10) have demonstrated that
lysine 16 of histone H4 is hypoacetylated in sas2 mutants. Together, these data are consistent with the possibility that histone
H4 lysine 16 is a direct substrate for acetylation by Sas2.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
80 °C in 50 mM Tris, pH 8, 10% glycerol. Esa1 was induced from plasmid pLP831 (His6-Esa1) in strain BL21 (DE3) with 1.0 mM IPTG. Protein was purified as described above for the
SAS complex. (H3·H4)2 tetramers were prepared as
described (23). Asf1 and Asf1(H3·H4)2 complexes were
purified as described (12). HeLa histones for Fig. 5 were purified as
described (24). (H3·H4)2 tetramers were assembled onto
plasmid DNA as described (25). The tetramer-DNA complexes were further
purified by collecting them in the void fraction of a S200 gel
filtration column to ensure that no free histones remained.
RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
The recombinant SAS complex has HAT
activity. A, in vitro HAT assay using
purified recombinant proteins from E. coli expressing either
Sas2-His6 or Sas2-His6, Sas4, and Sas5 with
chicken histones as substrate. The bar graph represents the
amount of [3H]acetyl groups (cpm) transferred from
[3H]acetyl-CoA to chicken histones for each enzyme.
B, Coomassie Blue-stained SDS-PAGE gel of the purified
proteins used in A showing positions of
Sas2-His6, Sas4, and Sas5. Lane 1 has ~150 ng
of purified protein from E. coli expressing only
Sas2-His6; lane 2 is from E. coli in
which Sas2-His6, Sas4, and Sas5 are co-expressed from the
same plasmid. C, HAT assays as in A with either
chicken histones or a synthetic peptide corresponding to the first 28 amino acids of histone H4 as substrate. Sas2-His6 and
associated proteins were purified from E. coli cells
containing a plasmid co-expressing Sas2-His6 and Sas4, or
Sas2-His6 and Sas5, or all three proteins. D,
Coomassie Blue-stained SDS-PAGE gel of the purified proteins used in
C. Lane 1, Sas2-His6, Sas4;
lane 2, Sas2-His6, Sas5; lane 3,
Sas2-His6, Sas4, Sas5.
To determine whether all three Sas proteins were required for HAT activity, or whether the activity resulted from either Sas2,4 or Sas2,5 subcomplexes, additional expression plasmids were constructed that encoded Sas2-His6 and either Sas4 or Sas5. In both cases, equivalent amounts of the Sas4 or Sas5 proteins copurified with Sas2-His6 as when all three proteins were expressed in the same cell (Fig. 1D). These data demonstrate that both Sas4 and Sas5 can bind directly to Sas2. When these complexes were tested in a HAT assay using chicken histones as substrate, the Sas2,4 complex had activity but the Sas2,5 complex did not (Fig. 1C). However, the specific activity of the Sas2,4 complex was consistently 2-3 fold lower than that of the Sas2,4,5 complex, even though these complexes contained comparable amounts of Sas2 and Sas4 proteins (Fig. 1, C and D). Both the Sas2,4,5 complex and the Sas2,4 complex were also able to acetylate a peptide that corresponds to the first 28 amino acids of histone H4. We conclude that the N terminus of H4 is a substrate for acetylation by the SAS complex. For this peptide as well, the specific activity of the Sas2,4 complex was lower than that of the Sas2,4,5 complex, and the Sas2,5 complex had no activity (Fig. 1C). These results demonstrate that Sas2 is a HAT in vitro, but that its HAT activity requires additional subunits. While the Sas2,4 complex has activity, optimal HAT activity requires the Sas2,4,5 complex.
We had previously shown that the acetyl-CoA binding motif of Sas2 is
essential for function in vivo. Specifically, a mutant form
of Sas2 termed sas2M1 in which amino acids 219-221 (GLG)
were changed to alanines abolished the silencing activity of Sas2, but
did not affect formation of the SAS complex (7). When we coexpressed a
His6-tagged version of the sas2M1 protein
together with Sas4 and Sas5, we observed that sas2M1 formed
a SAS complex in vitro with subunit stoichiometry similar to
that observed for the wild-type complex (Fig.
2B). However, the
sas2M1,4,5 complex displayed no HAT activity against either
chicken histones or a H4 peptide (Fig. 2A). Thus, the
silencing phenotypes caused by the sas2-M1 mutation
correlate with the loss of HAT activity.
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To further characterize the substrates of the SAS complex, we separated
the products of a HAT reaction on a polyacrylamide gel to resolve the
individual histones. Fluorography revealed that histone H4 is the major
substrate for the SAS complex. However, histone H3 is also acetylated
by this enzyme (Fig. 3A). This
acetylation pattern is quite similar to that of Esa1, another member of
the MYST family of acetyltransferases (Fig. 3A). The Sas2,4
complex showed a similar substrate specificity but had lower specific activity (data not shown). We conclude that the Sas5 subunit does not
alter which histone polypeptides are acetylated by Sas2.
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To determine which residues within the histone H3 and H4 tails are acetylated by the SAS complex, we used as substrates synthetic peptides corresponding to the first 28 amino acids of H4 or the first 21 amino acids of H3. Both peptides were efficiently acetylated when incubated with the SAS complex, but not with Sas2 alone (Figs. 1 and 2 and data not shown). In vitro 3H-acetylated peptides were subjected to N-terminal sequencing, and the amount of radioactivity in each residue was determined. We observed that the primary site of acetylation on histone H4 was lysine 16 and that the primary site of acetylation on the H3 peptide was lysine 14 (Fig. 3B).
Interestingly, when the products of the HAT assays using the wild-type SAS complex were analyzed on a protein gel, Sas2, as well as histones H3 and H4, was radioactively labeled (Fig. 3A). Because the labeling of Sas2 survived SDS-PAGE and because no radioactivity was incorporated into the sas2M1 mutant protein (Fig. 3A), the labeling most likely resulted from autoacetylation of Sas2 rather than non-covalent trapping of acetyl-CoA. Similar autoacetylation was observed for Esa1 (Fig. 3A), but not for Hat1, a histone acetyltransferase that is not a member of the MYST family (data not shown). Interestingly, the autoacetylation of Sas2 was dependent upon the presence of histones; when histones were omitted from the reaction, very little radioactivity was incorporated into Sas2 (data not shown). Whether this autoacetylation is intermolecular or intramolecular, and whether it is important for the function of the enzyme, is not known.
Most MYST family members studied to date exist in multiprotein complexes and interact with chromatin in order to acetylate histones (8). In S. cerevisiae, these include Sas3, a component of the NuA3 complex (30), and Esa1, the HAT for the NuA4 complex (31). Both the NuA3 and NuA4 complexes acetylate histones in a nucleosomal context. Therefore, we hypothesized that SAS would display a similar activity. Consistent with this idea, a Gal4-Sas2 fusion protein, when tethered via Gal4 binding sites placed at HMR, functioned as an effective barrier to the spread of silencing (32). This was proposed to result from Sas2-mediated histone acetylation counteracting Sir2-mediated histone deacetylation. These data suggested that when artificially tethered, Sas2 can acetylate histones in nucleosomes.
To test whether the SAS complex acetylates nucleosomal histones,
nucleosomes and core histones derived from human HeLa cells were
compared as substrates of the SAS complex. Strikingly, we detected no
acetylation of nucleosomes using assay conditions that were optimum for
acetylating free histones (Fig. 4).
However, the SAS complex did acetylate free histones derived from these nucleosomes (Fig. 4), demonstrating that these HeLa histones were not
already fully acetylated on histone H3 lysine 14 and H4 lysine 16. Furthermore, the Sas3-containing NuA3 complex, which acetylates H3
lysine 14 on nucleosomes, had robust activity using the HeLa nucleosomes as substrate (Fig. 4). We also purified nucleosomes from
wild-type and sas2 yeast strains and tested those
nucleosomes as substrates for the SAS complex. The assays were done
using several different buffer conditions that are optimal for other HATs, with a salt range from 0-150 mM. The SAS complex
showed no activity on nucleosomes from either strain (data not shown). In contrast, the Esa1-containing NuA4 complex was active on both (data
not shown). We also tested whether SAS could acetylate histones H3 and
H4 in the form of (H3·H4)2 tetramers deposited onto DNA, in the absence of H2A/H2B dimers. Again, no modification of the histones was observed, although the same preparation of histones used
to form the tetramer-DNA complexes was efficiently acetylated (Fig.
5). Thus, under our reaction conditions,
free histones H3 and H4, but not those deposited onto DNA, are
substrates of the recombinant SAS complex in vitro.
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Neither Esa1 nor Gcn5 acetylate nucleosomes in vitro unless
they are part of a multiprotein complex (NuA4 for Esa1, Ref. 31 and
SAGA or ADA for Gcn5, Ref. 33). Therefore, the inability of the
recombinant SAS complex to acetylate nucleosomes may result because a
targeting subunit is missing. To address this, we purified active SAS
complex from yeast. We created strains in which either Sas2 or Sas5
contained at their C terminus a tag for TAP (21). This tag enabled us
to purify native SAS complex consisting of Sas2, Sas4, and Sas5 (Fig.
6A). We tested these purified
complexes for HAT activity using HeLa nucleosomes, HeLa
core histones and recombinant yeast histones. Just as for the
recombinant SAS complex, the native yeast complex could acetylate free
histones, but not the same histones when incorporated into nucleosomes
(Fig. 6B). The native complex, like the recombinant SAS
complex, acetylated histones H3 and H4, with a stronger preference for
H4 than for H3 (Fig. 6B).
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To further characterize the specificity of the yeast enzyme, we used as
substrates a series of peptides corresponding to amino acids 1-20 of
the histone H4 N terminus. These peptides were either unacetylated or
tri-or tetra-acetylated at lysines 5, 8, 12, and 16. Only peptides in
which lysine 16 was not acetylated were substrates for the native SAS
complex (Fig. 7). Therefore, under our
reaction conditions the recombinant and native SAS complexes show
similar substrate specificities; both acetylate free histone H4 at
lysine 16, and to a lesser extent histone H3, and neither acetylates histones that are packaged into nucleosomes.
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Because of the phenotypic similarity of asf1 and
sas2 mutants for HM silencing and the physical
interactions between Asf1 and SAS subunits (5, 7), we tested the
hypothesis that SAS acetylates histones that are bound to Asf1. In this
experiment, Asf1/H3/H4 complexes were purified (14) and then used as
substrate for recombinant SAS in a HAT assay. Surprisingly, we observed that association of histones with Asf1 efficiently blocked their acetylation by SAS (Fig. 5).
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DISCUSSION |
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Sas2 was predicted to be a histone acetyltransferase because of its sequence similarity to members of the MYST family. However, until this report, no in vitro activity was detected either from recombinant Sas2 or from Sas2 purified from yeast. In this analysis, we show that recombinant Sas2 can acetylate histones, but only when associated with the Sas4 subunit. Although the in vitro specificity of other HATs is altered by associated proteins (8), this is the first case in which enzymatic activity of a histone acetyltransferase absolutely depends upon additional subunits. Furthermore, maximal activity of Sas2,4 required the Sas5 subunit. Sas5 may be required to help stabilize the complex, or to help in substrate recognition. Sas5 has homology to tf2f domain-containing proteins including yeast TAFII30, which is a component of a number of transcription/chromatin remodeling complexes (34-36). Perhaps the tf2f domain of Sas5 is involved in histone binding. Because sas5 mutants are as defective in silencing as sas2 mutants, Sas5 may be crucial for HAT activity in cells in a manner not reflected in our in vitro assays.
Previous attempts by this group and others (5, 7) to purify enzymatically active SAS complex from yeast were unsuccessful, although the complexes that were purified contained Sas2, Sas4, and Sas5. In this report, we show that using the tandem affinity purification method (21) to isolate the SAS complex results in active enzyme. Perhaps the previously isolated complexes co-purified with an inhibitor, or the purification schemes used inactivated the enzyme. For all substrates tested, the recombinant enzyme and yeast native enzyme show similar substrate specificities. Both enzymes acetylate histone H4 and to a lesser extent, histone H3. Furthermore, both enzymes acetylate free histones, but not those in nucleosomes.
We showed that both the recombinant and native enzymes acetylate lysine
16 of histone H4. Previous genetic data showed that mutating histone H4
lysine 16 to a nonacetylatable residue (K16R) confers silencing defects
similar to those of sas2 null cells (5) and that H4 lysine
16 is underacetylated in sas2 mutants (9, 10). Our data
strongly suggest that these genetic effects are a direct consequence of
acetylation of histone H4 lysine 16 by the SAS complex. Both the
recombinant and native enzyme complexes also acetylate histone H3
in vitro, and we determined using the recombinant enzyme
that the target was lysine 14. It has not been determined whether
histone H3 lysine 14 is also an in vivo substrate for the
SAS complex. Acetylation of H3 lysine 14 is reduced in a
sas2 mutant, but this effect may be indirect (10). Since the histone H4 K16R mutation causes the same reduction in silencing as
deletion of SAS2 at telomeres and at HML (in a
sir1 strain) (5), it may be that acetylation of histone
H3 lysine 14 by Sas2 either does not occur in vivo or is not
important for silencing.
Almost all HAT enzyme complexes studied to date except for Hat1
acetylate both free and nucleosomal histones. However, neither the
recombinant nor native SAS complex could acetylate histones in HeLa
nucleosomes; whereas using the same assay conditions, both enzymes
could acetylate free histones derived from these nucleosomes.
Furthermore, the recombinant enzyme had no activity on nucleosomes
purified from wild-type and sas2 mutant cells. We considered
four possible explanations for these results. First, it is possible
that a subunit required to target SAS to nucleosomal histones was lost
during the purification of the enzyme from yeast. Second, SAS may only
work on histones that have been previously modified in some way, and
these modified histones are not present in the HeLa or yeast
nucleosomes we used. If true, then this modification must only be
required when histones are part of nucleosomes, since once released
from the HeLa nucleosomes the HeLa histones were good substrates for
the SAS enzyme. Third, acetylation of nucleosomes by SAS may require
assay conditions different from those that we used. A fourth
explanation is that in vivo SAS does acetylate only free
histones and not those in nucleosomes. Sas proteins physically interact
with subunits of the Asf1 and CAF-I histone deposition factors.
Furthermore, asf1 mutations and sas mutations cause similar effects on silencing at the HM loci, and
cac mutants and sas mutants both display reduced
telomeric silencing. Asf1 and CAF-I bind to free histone H3 and H4, and
are believed to function in histone deposition. SAS may function in
these two pathways to participate in the deposition process. However,
we have demonstrated that recombinant SAS does not acetylate H3 or H4
when they are bound to DNA as tetramers or associated with Asf1. A
model to explain the biochemical data and genetic interactions between
SAS and Asf1 (and CAF-I) would be that SAS acetylates newly synthesized
H3 and H4 and then passes these histones on to Asf1 (or CAF-I) for
deposition onto chromatin. SAS has been implicated in formation of a
barrier between silenced and unsilenced regions of the chromosome (32,
9, 10). Perhaps Asf1 and CAF-I function downstream of SAS in the
formation of these barriers by depositing acetylated histones adjacent
to regions of silent chromatin.
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ACKNOWLEDGEMENTS |
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We thank L. Pillus for the Esa1 expression plasmid, T. Fisher at the CASM facility at Stony Brook for peptide sequencing, and M. Horikoshi for peptides used in Fig. 7.
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FOOTNOTES |
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* This work was supported by grants from the National Institutes of Health (to R. S. and J. L. W.) and from the National Science Foundation (to P. D. K.).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: Dept. of Biochemistry and Cell Biology, Stony Brook University, Stony Brook, NY 11794-5215. Tel.: 631-632-8565; Fax: 631-632-8575; E-mail: rolf@life.bio.sunysb.edu.
Published, JBC Papers in Press, March 6, 2003, DOI 10.1074/jbc.M210709200
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ABBREVIATIONS |
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The abbreviations used are:
HAT, histone
acetyltransferase;
IPTG, isopropyl -D-thiogalactoside;
TAP, tandem affinity purification;
CBP, calmodulin binding
protein.
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