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Molecular and Cellular Biology, December 1999, p. 8591-8603, Vol. 19, No. 12
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
NF-Y Associates with H3-H4 Tetramers and Octamers
by Multiple Mechanisms
Giuseppina
Caretti,1
Maria Carla
Motta,1,
and
Roberto
Mantovani1,2,*
Dipartimento di Genetica e Biologia dei
Microrganismi, Università di Milano, 20133 Milan,1 and Dipartimento di Biologia
Animale, Università di Modena e Reggio, 41100 Modena,2 Italy
Received 12 May 1999/Returned for modification 23 June
1999/Accepted 16 August 1999
 |
ABSTRACT |
NF-Y is a CCAAT-binding trimer with two histonic subunits, NF-YB
and NF-YC, resembling H2A-H2B. We previously showed that the short
conserved domains of NF-Y efficiently bind to the major histocompatibility complex class II Ea Y box in DNA nucleosomized with
purified chicken histones. Using wild-type NF-Y and recombinant histones, we find that NF-Y associates with H3-H4 early during nucleosome assembly, under conditions in which binding to naked DNA is
not observed. In such assays, the NF-YB-NF-YC dimer forms complexes
with H3-H4, for whose formation the CCAAT box is not required. We
investigated whether they represent octamer-like structures, using
DNase I, micrococcal nuclease, and exonuclease III, and found a highly
positioned nucleosome on Ea, whose boundaries were mapped; addition of
NF-YB-NF-YC does not lead to the formation of octameric structures,
but changes in the digestion patterns are observed. NF-YA can bind to
such preformed DNA complexes in a CCAAT-dependent way. In the absence
of DNA, NF-YB-NF-YC subunits bind to H3-H4, but not to H2A-H2B,
through the NF-YB histone fold. These results indicate that (i) the
NF-Y histone fold dimer can efficiently associate DNA during nucleosome
formation; (ii) it has an intrinsic affinity for H3-H4 but does not
form octamers; and (iii) the interactions between NF-YA, NF-YB-NF-YC,
and H3-H4 or nucleosomes are not mutually exclusive. Thus, NF-Y can
intervene at different steps during nucleosome formation, and this
scenario might be paradigmatic for other histone fold proteins involved in gene regulation.
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INTRODUCTION |
Gene expression is controlled by
gene-specific trans-acting factors and general transcription
proteins recognizing discrete elements in promoters-enhancers and
operating in the context of chromatin structures (reviewed in reference
45). The fundamental chromatin unit is the
nucleosome, a DNA-protein complex formed by 146 bp of DNA that wraps
around core histones, H2A, H2B, H3, and H4. Histones are among the most
conserved proteins in evolution, having in their C-terminal regions a
65-amino-acid histone fold motif (HFM) with low sequence identity (14 to 18%) and high structural resemblance (2). It is
minimally composed of three 
helices, 1, 2, and 3. The long
central 2 (28 amino acids) is flanked by two short ones separated by
loop-strand regions; this structure enables histone-histone
interactions and contacts with the DNA (2, 29). Histones
also possess N-terminal tails that are acetylated at specific lysine
residues. This process is highly regulated by several acetylases,
including some transcriptional coactivators, and is thought to
contribute to regulation of gene expression in multiple ways:
facilitation of transcription factors binding (43) and of
RNA polymerase progression (42) and chromatin solubility
(38). Formation of nucleosomes is a stepwise phenomenon initiated by tetramerization of H3-H4 through H3-H3 interactions and
binding of the tetramer to DNA; this nucleates wrapping of DNA, but
formation of a stable complex requires subsequent association of two
H2A-H2B dimers, mainly through H2B-H4 contacts (12, 16-18). H3-H4 tetramers, but not H2A-H2B dimers, dictate nucleosome positioning (12).
Several polypeptides involved in the process of transcriptional
regulation were shown to contain HFM domains (3): (i)
Drosophila TAFII60 (dTAFII60)/human
TAFII80 (hTAFII80),
dTAFII40/hTAFII31, hTAFII28,
hTAFII18, and hTAFII20/dTAFII30,
which are part of the general TFIID complex (crystallization of
dTAFII60/dTAFII40 and hTAFII28/hTAFII18 dimers revealed their
histone-like structures [6, 8]); (ii) the two subunits
of NC2 (also called Dr1/DRAP1), which bind TATA-binding protein and
repress transcription (15); (iii) an
hTAFII80-like subunit (PAF65) of the P/CAF histone
acetylase complex (37); and (iv) two subunits (NF-YB and
NF-YC) of NF-Y, a ubiquitous CCAAT-binding heterotrimeric complex
(3).
The CCAAT box is present in 25% of eukaryotic promoters, with a strong
position preference at 
60 to 80 (33). In vivo
footprinting of several promoters invariably found this element
protected, and functional experiments indicate that it plays an
important and sometimes essential role in transcription. NF-Y,
originally identified as the protein binding to the major
histocompatibility complex (MHC) class II Ea promoter Y box, has an
almost absolute requirement for the five CCAAT nucleotides and has been
implicated in the activation of most, if not all, CCAAT-containing
promoters (reviewed in references 31 and
33). It is composed of three different subunits,
NF-YA, NF-YB, NF-YC, each containing evolutionarily conserved domains.
NF-YB and NF-YC belong to the H2A-H2B subfamily; their dimerization,
elicited through strong HFM interactions, is required for NF-YA
binding. For this function, a complex surface resulting from
heterodimerization and comprising specific residues in NF-YC 1, in
NF-YB 2, and at the C terminus of 3 is necessary (21,
40). Detailed mutational analysis of NF-YA and of the yeast
homologue HAP2 identified a 56-amino-acid region that can be split into
two short separable parts, responsible for contacting NF-YB-NF-YC and
DNA (32, 46). Similarly, NF-YB and NF-YC histone folds
contain DNA-binding subdomains (21, 40, 47).
We have started to investigate the relationships between NF-Y and
higher-order structures on the MHC class II Ea promoter, using an in
vitro chromatin reconstitution system from the brine shrimp
Artemia franciscana and nucleosome assembly assays with purified chicken histones. We found that a small NF-Y formed by the
homology domains can associate with preformed nucleosomes. Translational analysis indicated that CCAAT positioning at one end of
the fragment leads to NF-Y binding with slightly higher affinity
(36). Detailed DNA-binding studies with bending and phasing
assays indicated that the small NF-Y associates the CCAAT box and
distorts DNA in a way that is reminiscent of histones in the nucleosome
(36). However, careful examination of a set of wild-type
(wt) and mutant NF-Y subunit combinations indicated that important
DNA-binding parameters, such as flexure angles and off rates, are
remarkably influenced by regions outside the conserved parts
(28). In this study, we pursued our characterization of
NF-Y-nucleosome interactions by using wt NF-Y and recombinant histones,
focusing in particular on the separated H2A-H2B and H3-H4 dimers.
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MATERIALS AND METHODS |
Expression and purification of recombinant histone and NF-Y
proteins.
The vectors coding for Xenopus laevis
histones (29) (kindly provided by K. Luger, ETH, Zurich,
Switzerland) were used to transform Escherichia coli
BL21(DE3) (LysS). Protein expression was induced at an A600
of 0.6 by addition of isopropyl-
-D-thiogalactopyranoside to a final concentration of 1 mM for 3 h for H2A, H2B, and H3 and
1.5 h for histone H4. Bacterial pellets were resuspended and sonicated in sonication buffer (150 mM KCl, 20 mM Tris-HCl [pH 7.8],
0.05% NP-40, 0.1 mM EDTA, 5 mM 2-mercaptoethanol, 1 mM
phenylmethylsulfonyl fluoride [PMSF; Sigma], protein inhibitors) and
centrifuged at 23,000 × g in a Beckman SW27Ti rotor
for 30 min at 4°C. The inclusion body pellet was resuspended in
sonication buffer, sonicated, and centrifuged again. Three cycles of
this procedure yield proteins that are >90% pure. Inclusion bodies
were finally resuspended in 6 M GnCl-20 mM sodium acetate (pH 5.2)-5
mM 2-mercaptoethanol-1 mM PMSF, and unfolding was allowed to proceed
for 1 h at room temperature on a rotating wheel. The four
histones, or H3-H4 and H2A-H2B couples, were mixed to a final
concentration of 1.6 mg/ml and dialyzed against a 100-fold excess of
refolding buffer (30) in 3-kDa-cutoff dialysis bags; the
glycerol concentration was adjusted to 20%, and proteins were stored
at 80°C. The full-length NF-Y subunits were expressed and purified
as described in reference 28; NF-YB4 and NF-YC5
purification was also described previously (5).
Nucleosome reconstitution and EMSA.
Labeled probes used for
nucleosome reconstitutions were fragments 2, 2m, and 6 described in
reference 36. One microgram of renatured core
histones or 600 ng of H3-H4 or H2A-H2B dimers was incubated with 250 ng
of competitor DNA (salmon sperm DNA sonicated to an average length of
200 bp) and 1 ng of labeled DNA (105 cpm) in a final volume
of 10 µl in 1 M NaCl-10 mM Tris-HCl (pH 7.8)-500 ng of bovine serum
albumin (BSA)/µl-1 mM 2-mercaptoethanol for 30 min at 20°C. The
reaction mixture was serially diluted to 0.8, 0.67, 0.57, 0.5, and 0.1 M NaCl by addition of TE buffer (10 mM Tris-HCl [pH 7.6], 1 mM EDTA)
every 15 min. NF-Y binding reactions and electrophoretic mobility shift
assays (EMSAs) were performed as in reference 36.
For most of the experiments described, we used PCR-derived labeled
fragment 2, containing positions 115 to +60 of the Ea promoter
derived from the PE3 plasmid (36). For Fig. 3C, we used an
identical fragment mutated in the Y box, generated by PCR (32,
36). For Fig. 4, we also used fragment 6, harboring a CCAAT box
in a central position (36). Antibody challenge experiments were performed by adding 200 ng of anti-NF-Y (33),
anti-Gata1 (Santa Cruz Biotechnology, Santa Cruz, Calif.), or
antihistone (Boehringer Mannheim, Mannheim, Germany) antibodies to the
binding reaction mixture and then incubating it on ice for further 30 min.
DNase I footprinting, MNase accessibility assay, and Exo III
digestion.
For DNase I footprinting, micrococcal nuclease (MNase)
accessibility assays, and exonuclease III (Exo III) digestions, we used
twice the amount of recombinant histones as employed for EMSA. In this
procedure, 20,000 cpm of reconstituted tetramer or octamer particles
was digested with 0.1 U of DNase I (grade I; Boehringer Mannheim)
supplemented with 5 mM MgCl2 and 10 mM CaCl2 at
37°C for 3 min, while free DNA was digested with 0.001 U of DNase I. The same amounts of reconstituted tetramers or octamers and free DNA
were digested in 2 mM CaCl2 with 0.01 U of MNase (Sigma) at
room temperature for 2 min. DNase I and MNase digestions were
terminated by adding 2 volumes of DNase I stop buffer (1.5% sodium
dodecyl sulfate [SDS], 30 mM EDTA, 450 mM sodium acetate [pH 5.2]).
Then 50,000 cpm of reconstituted tetramers, octamers, or free DNA was
digested with 100 U of Exo III (Boehringer Mannheim) with 66 mM
Tris-HCl (pH 8)-2.5 mM MgCl2-1 mM 2-mercaptoethanol at
37°C, and aliquots of 28 µl were taken after 15, 30, 60, and 120 min and added to 56 µl of DNase I stop buffer. DNase I, MNase, and
Exo III digestion products were phenol-chloroform extracted, ethanol
precipitated, and analyzed on 7 M urea-8% polyacrylamide gels.
Polyacrylamide gel purification of DNase I-digested
complexes.
Probe (105 cpm) was assembled with
histones, histones and NF-YB-NF-YC, H3-H4, and H3-H4-NF-YB-NF-YC
and digested with DNase I as described above. Reactions were stopped on
ice in 5 mM EDTA and immediately loaded on a 4% polyacrylamide gel.
Bands corresponding to the different complexes located by
autoradiography of the wet gel were cut, crushed, and incubated with
500 µl of diffusion buffer (0.5 M ammonium acetate, 10 mM magnesium
acetate, 1 mM EDTA [pH 8.0], 0.1% SDS) at 50°C for 30 min. Samples
were centrifuged at 14,000 rpm for 5 min, and supernatants were passed
through packed glass wool to eliminate any residual polyacrylamide. DNA was phenol extracted, ethanol precipitated, and analyzed on a sequencing gel as described above.
Protein-protein interactions.
Pure histone dimers and the
His-tagged NF-YB4-NF-YC5 dimer (10 µg of each in 80 µl) were
incubated together in BC2000 (2 M KCl, 20 mM Tris-HCl [pH 7.5], 1 mM
-mercaptoethanol, 0.05% NP-40, 100 µg of BSA/ml, 0.25 mM PMSF)
and step diluted with BC100 (same as BC2000 but containing 100 mM KCl)
over a period of 2 h, until a salt concentration of 0.35 M KCl was
reached; 20 µl of nickel-nitrilotriacetic acid (NTA)-agarose resin
(Qiagen, Hilden, Germany) was then added, and the samples were rocked
for 1 h and washed twice with 1 ml of BC500. All procedures were
performed at 4°C. Bound proteins were eluted by boiling samples in
SDS buffer and analyzed in 17% gels stained with Coomassie blue. The
NF-YB4 and NF-YB43 Sepharose columns were described earlier
(4); the NF-YB43 mutant contain amino acids 51 to 117, lacking the C-terminal six amino acids of the HFM. Histones (10 µg)
were incubated overnight at 4°C with 50 µl of either column in 200 µl of BC300 supplemented with 0.05% NP-40, 100 µg of BSA/ml, and
0.25 mM PMSF. Samples were then washed with the same buffer, eluted,
and analyzed as described above.
| |
RESULTS |
Binding of wt NF-Y to nucleosomal DNA.
In a previous study, we
used the short evolutionary conserved domains of NF-Y to show that the
trimer can associate with DNA that was preassembled with purified
chicken histones. By analyzing DNA binding, bending, and phasing of
several mutant combinations, we became aware of two important facts:
(i) the two large Q-rich regions of NF-YA and NF-YC influence angle
amplitude and (ii) the presence of NF-YC N and NF-YB C, absent in
our YB4 and YC5 mutants, alters some of the DNA-binding parameters,
most notably shortening the off rate of the DNA complex
(28). For these reasons, we felt important to assess the
affinity of the wt NF-Y trimer for preassembled nucleosomal DNA. A
fragment of the MHC class II Ea promoter containing the Y box in a
semicentral position (fragment 2 [36]) was assembled
with recombinant X. laevis histones, recently used for
crystallographic studies (Fig. 1A, lane
5). Increasing amounts of wt NF-Y were
added, either on naked DNA (lanes 1 to 4) or on 30% nucleosomized DNA
(lanes 6 to 9); upper complexes of slower mobilities were readily seen
at relatively low NF-Y concentrations (compare lanes 2 and 7). To
ascertain whether these complexes contain all NF-Y subunits, we
challenged them with anti-NF-Y antibodies (33). Figure 1B
shows that antibodies directed against all three subunits supershift
the upper complexes, as well as the NF-Y band on naked DNA (compare
lanes 3 to 5 and 8 to 10). Note that in the latter experiments, the
70% nucleosomized fragment yielded, with comparable NF-Y
concentrations, only nucleosome-NF-Y complexes (compare lanes 2 and
7); this behavior is similar to that observed with the small
YA9-YB4-YC5 mutant previously used in these assays (36).
Thus, like the short NF-Y mutant, wt NF-Y preferentially binds to a
naked CCAAT box, but the amount of wt NF-Y required (1.3 ng) to bind
DNA in a nucleosomal context is low compared to other transcription
factors (see reference 36 and references therein).
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FIG. 1.
wt NF-Y associates a nucleosome-bound Ea Y box. (A) EMSA
of a dose response of wt NF-Y on mock-reconstituted (0.5, 1, 3, and 10 ng; lanes 1 to 4) or nucleosome (NUC.)-reconstituted (lanes 6 to 9) Ea
fragment 2 (115 to +60 of Ea [36]). Lane 5, no NF-Y
added to nucleosomal DNA. (B) A 70% nucleosomized Ea fragment 2 was
run without NF-Y (lane 1), with 5 ng of NF-Y (lane 2), and with the
same amount of NF-Y incubated with the indicated anti-NF-Y antibody
(Ab; 200 ng of purified antibody; lanes 3 to 5). The same was in lanes
7 to 10 except that mock-reconstituted DNA was used.
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Association of NF-Y during nucleosome reconstitution.
Our
reconstitution assay can also be used to dissect NF-Y binding during
histone-DNA association. We incubated histones (Fig. 2, lanes 1 to 6), NF-Y (lanes 13 to 18),
or histones and NF-Y together (lanes 7 to 12) in the presence of cold
competitor DNA and 1 M NaCl; the salt concentration was then
progressively lowered over 15-min periods, and at each point an aliquot
of the samples was loaded on a running EMSA. The resulting patterns
gave indications as to the binding of the different complexes to DNA.
During nucleosome assembly, two bands were observed at 1 M (lane 1);
they have been observed in other studies (17, 18, 41) and
most likely represent the H3-H4 tetramer and ditetramers species
detailed in glycerol gradient experiments by Spangenberg et al.
(41). In line with this interpretation, they are observed
upon reconstitution with H3-H4 only (see below). At 0.8 M, the H3-H4
lower complex is still present, while an intermediate band becomes
apparent and progressively predominant at lower salt concentrations
(lanes 2 and 3 to 6); this represents H2A-H2B association and formation
of a stable histone octamer. With NF-Y alone, no binding is observed
until the NaCl concentration is lower than 0.5 M (compare lanes 13 to 17 with lane 18); this finding is in full agreement with previous results (19). When histones and NF-Y are incubated together, two slowly migrating complexes are observed at 1 M NaCl, together with
the H3-H4 tetrameric complexes (compare lanes 1, 7, and 13). These
complexes persist at lower concentrations, progressively merging into
one major complex as H2A and H2B associate (compare lanes 7 to 11).
These results indicate that in the presence of histones, NF-Y can bind
DNA in nonpermissive salt conditions and suggest that this is
accomplished through association with H3-H4.
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FIG. 2.
Binding of NF-Y during nucleosome assembly.
Stoichiometric amounts of histones were assembled in high salts with Ea
fragment 2 and cold competitor DNA, in the absence (lanes 1 to 6) or
presence (lanes 7 to 12) of 5 ng of wt NF-Y. In lanes 13 to 18, 5 ng of
wt NF-Y was used as in lanes 7 to 12, in the absence of histones.
Mixtures were progressively diluted, and at each NaCl concentration,
aliquots were added to a running polyacrylamide gel. The NF-Y, H3-H4,
nucleosome, and NF-Y-nucleosome bands are indicated.
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Association of NF-Y HFM subunits with H3-H4 on the DNA.
The
experiments described above suggest that the histone fold subunits of
NF-Y can bind histones while assembly takes place, in the absence of
NF-YA. To gain insight into the mechanism, we reconstituted nucleosomes
by incubating increasing near-stoichiometric amounts of the
NF-YB-NF-YC dimer alone, with the four core histones, or with H3-H4 in
the presence of cold competitor DNA. Initially, we used the YB4-YC5
mutant containing the evolutionarily conserved domains; as expected,
they had no DNA-binding capacity on their own (Fig. 3A, lanes 1 to
3) However, upon reconstitution with all
core histones (lanes 4 to 7) and with H3-H4 (lanes 8 to 11), a distinct
band was generated, with an electrophoretic mobility different from
that of the nucleosome or of the H3-H4 tetramers (compare lanes 9 and 7 with lanes and 11). This complex was stable for several days at 4°C
(not shown). To investigate the protein composition in such complexes,
we challenged it with increasing amounts of purified anti-NF-YB (Fig.
3B, lanes 1 to 3) and antihistone antibodies (lanes 4 to 7). Both
antibodies were able to specifically supershift the
H3-H4-NF-YB-NF-YC complex, while an irrelevant anti-Gata1 antibody
had no effect (lanes 8 to 10). These experiments suggest that a hybrid
complex containing both H3-H4 and NF-YB-NF-YC dimers can be formed on
DNA. We repeated the experiments with full-length NF-Y subunits; the
different combinations gave results similar to those for YB4-YC5, as
complexes of dissimilar electrophoretic mobility were observed (Fig.
3C, lanes 1 to 5). In parallel, we also checked whether the integrity
of the CCAAT box was required for formation of the
NF-YB-NF-YC-nucleosome and NF-YB-NF-YC-H3-H4 or YB4-YB5-H3-H4
complexes. For this, we used an Ea fragment of identical length
containing in the Y box a 10-bp mutation that renders it unable to
interact with NF-Y (36, 44). As shown in Fig. 3C and D, the
patterns generated with the different combinations were essentially
identical to that for the wt Ea fragment (Fig. 3C [compare lanes 1 to
5 with lanes 6 to 10] and D [compare lanes 2 and 3 with lanes 6 and
7]), indicating that association of NF-YB-NF-YC does not require the
CCAAT box. Altogether, these results indicate that NF-YB-NF-YC dimers
associate with H3-H4 and suggest the possibility that they might be
incorporated with H3-H4 into hybrid nucleosomes or nucleosome-like
complexes.
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FIG. 3.
EMSA of a NF-YB-NF-YC-H3-H4 complex on the Ea
promoter DNA. (A) Reconstitution of fragment 2 with increasing amounts
of NF-YB4-NF-YC5 alone (200 ng, 400 ng, and 1 µg; lanes 1 to 3),
with all core histones (lanes 5 to 7), or with H3-H4 only (lanes 9 to
11). Control reconstitutions with core histones and H3-H4 alone are in
lanes 4 and 8. The hybrid complex is indicated. Nuc., nucleosomes. (B)
Antibody challenge of the hybrid NF-YB-NF-YC-H3-H4 complex. The
hybrid complex was incubated for 30 min at 4°C with increasing
amounts of anti-NF-YB (100 and 500 ng; lanes 2 and 3), antihistone (10 ng, 100 ng, and 1 µg; lanes 5 to 7), or control anti-Gata1 (100 and
500 ng; lanes 9 and 10) antibodies (Ab). The supershifted complexes are
indicated by asterisks. (C) The indicated combinations of proteins
(H2A-H2B [lanes 1 and 6], H3-H4 [lanes 2 and 7],
H3-H4-NF-YB-NF-YC [lanes 3 and 8], H2A-H2B-H3-H4 [lanes 4 and
9], and H2A-H2B-H3-H4-NF-YB-NF-YC [lanes 5 and 10]) were incubated
with wt Ea DNA (lanes 1 to 5) or with a Y-box mutant (lanes 6 to 10).
(D) Same as panel C except that H3-H4 tetramers were incubated alone
(lanes 1 and 5) or with NF-YB4-NF-YC5 (200 ng [lanes 2 and 6] and 1 µg [lanes 3 and 7]). Nucleosomes are in lanes 4 and 8.
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Analysis of histone-NF-YB-NF-YC complexes with DNase I, MNase,
and Exo III assays.
To verify this possibility, we performed
analysis with DNase I, MNase, and Exo III. These enzymes, particularly
MNase, have been widely used to assess the presence of nucleosomes and
map their exact positions. Figure 4A
shows DNase I footprints on fragment 6 (a fragment with the CCAAT box
in the dyad symmetry) and fragment 2 (CCAAT in a semicentral position)
on both strands (36). Reconstitution of fragment 2 with
either H2A-H2B, wt NF-YB-NF-YC, or combinations of the four proteins
resulted in no differences in cutting patterns with respect to the
mock-reconstituted control (Fig. 4A; compare lanes 1 and 3 to 5); note
that the same result was obtained with the small-homology-containing
proteins (data not shown). H3-H4 and nucleosome reconstitutions
generated regular DNase I patterns of 10-bp cuts very similar, albeit
not identical, among each other (compare lane 1 with lanes 6 and 8).
Addition of the wt NF-YB-NF-YC dimer did not modify substantially the
H3-H4 pattern, failing to render it identical to the pattern of the
nucleosome (compare lanes 6 to 8). However, addition of NF-YB-NF-YC to
core histones provoked a decrease in the intensity of a band in the
NF-Y footprinted region (compare lanes 8 and 9; see lane 2). Similar
experiments were performed with fragment 2 labeled on both strands:
when a labeled top strand was used, essentially identical patterns were obtained with the different combinations tested (compare lanes 10 and
12 to 15); on the bottom strand, more pronounced differences were seen
between H3-H4 and nucleosomes (compare lanes 18 and 20). Addition of
NF-YB-NF-YC failed to alter the patterns, with the exception of an
increased accessibility of an area at the edge of the NF-Y footprinted
region (compare lanes 20 and 21; see lanes 16, 17, 21, and 23). We also
performed footprinting experiments following gel isolation of the
complexes shown in Fig. 3. Nucleosomes, nucleosome-NF-YB-NF-YC,
H3-H4, and H3-H4-NF-YB-NF-YC were reconstituted as usual and treated
with DNase I; whole reconstitutions were loaded on a polyacrylamide
gel; complexes were separated; corresponding bands were excised,
eluted, and run on sequencing gels. Results of such experiment on
fragment 2 labeled on the top strand are shown in Fig. 4B. The overall
patterns are rather similar, with two prominent hypersensitive sites in
H3-H4-NF-YB-NF-YC complexes compared to H3-H4 (Fig. 4B; compare
lanes 3 and 4), while a clear protection is observed in
nucleosome-NF-YB-NF-YC complexes compared to nucleosomes (compare
lanes 5 and 6). Note that one of the hypersensitive/protection sites is
located within the NF-Y footprinted area (lanes 1 and 2). In summary,
modifications on H3-H4 and on nucleosomes induced by NF-YB-NF-YC
addition are subtle in this assay.
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FIG. 4.
DNase I footprint of histone-NF-YB-NF-YC combinations.
(A) The DNAs used were Ea fragment 2 (labeled on the top strand; lanes
1 to 9) and fragment 6 (145 to +35 of Ea [36];
labeled on the top strand [lanes 10 to 15] and bottom strand [lanes
16 to 23]). After reconstitutions with stoichiometric amounts of the
indicated HFM protein combinations, aliquots were digested with DNase I
and analyzed in sequencing gels. Asterisks denote bands that were
diminished (lanes 8 and 9) or increased (lanes 20 and 21) when
NF-YB-NF-YC was added to reconstitutions. To locate the position of
the NF-Y footprinted area, samples in lanes 2, 11, 17, and 23 contained
only the NF-Y trimer, without histones. Asterisks indicate protections
(lane 9) and hypersensitivities (lanes 19 and 21) upon addition of
NF-YB-NF-YC to histones. F, Free DNA; Nuc, nucleosomes. (B) The
indicated complexes were DNase I digested, purified from gels (see
Materials and Methods), eluted, and run on sequencing gels. Lane 1, free DNA; lane 2, DNA and NF-Y; lanes 3 to 6, H3-H4,
H3-H4-NF-YB-NF-YC, nucleosome, and nucleosome-NF-YB-NF-YC,
respectively. Asterisks indicate protections (lane 4) and
hypersensitivity (lane 6).
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In DNase I assays, differences between the H3-H4 and nucleosome
patterns are relatively subtle, as expected from the notion
that H3-H4
tetramers are primarily responsible for the 10-bp cuts;
thus, the
differences effected by NF-YB-NF-YC could be largely
missed. To
obviate this possibility, we used MNase cleavage. This
assay is based
on the differential cuts generated after reconstitution
of H3-H4
tetramers, which tend to protect a 75-bp fragment generated
from the
dyad symmetry, from those observed with nucleosomes,
which protect a
larger 150-bp fragment corresponding to the whole
nucleosome. After
reconstitution of nucleosomes on fragment 2,
MNase was added and
fragments of different lengths were indeed
generated, as judged from
the protein composition of the complexes
(Fig.
5). On the top strand, H3-H4 yielded
prevalent fragments
of 95 and 106 bp (Fig.
5, lane 8); addition of
NF-YB-NF-YC to
H3-H4 generated a predominant H3-H4-like pattern but
gave protections
of intermediate bands at positions +10 to 15 (compare
lanes 8
and 9). On the other hand, the nucleosome protected a larger
fragment
of 170 bp (lane 6); NF-YB-NF-YC induced a large protection in
the region at the 3' end of the nucleosome (compare lanes 6 and
7). In
parallel, we performed DNase I footprints on the same H3-H4
and
H3-H4-NF-YB-NF-YC reconstitutions and observed regular 10-bp
cutting
patterns, strongly suggesting that the MNase-resistant
bands observed
in these experiments are indeed generated by the
presence of highly
positioned H3-H4 tetramers (lanes 1 and 2).
The same type of analysis
was performed on the bottom strand of
this fragment, also giving
regular 10-bp cuts in parallel DNase
I experiments (lanes 10 and 11).
MNase cuts at positions
11 to
17 with H3-H4 and at position
84
with all four histones (lanes
14 and 16). Addition of NF-YB-NF-YC
increased the intensities
of the H3-H4-generated cuts and yielded
shorter fragments with
nucleosomes in the NF-Y protected region at
65
(compare lanes
13 and 14 with lanes 15 and 16). Again, NF-YB-NF-YC did
not generate
a nucleosome-like pattern. Overall, these MNase
experiments are
consistent with the idea that a nucleosome is highly
positioned
on the Ea promoter, with boundaries at
85 and +60 and a
dyad
symmetry at
10 with respect to the major start site (see Fig.
7
for a summary).
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FIG. 5.
MNase accessibility assay of histone-NF-YB-NF-YC
combinations. Stoichiometric amounts of the indicated combinations of
HFM proteins were reconstituted with fragment 2 (labeled on the top
strand [lanes 4 to 9] and bottom strand [lanes 13 to 18]), cut with
MNase, and analyzed on sequencing gels. In lane 17, the NF-Y trimer was
used to show the NF-Y footprinted area. F refers to free,
mock-reconstituted DNA (lanes 4 and 5; uncut and cut with MNase,
respectively). Arrows correspond to the major and minor hypersensitive
sites. Part of the H3-H4 and H3-H4-NF-YB-NF-YC reconstitutions were
cut with DNase I and run in parallel (lanes 1, 2, 10, and 11). Bars
correspond to the 10-bp cutting patterns of DNase I. Sequencing
reactions (T; lanes 3 and 12) were run in parallel to precisely map the
sites of MNase cuts.
|
|
We also performed Exo III experiments on our reconstitutions (Fig.
6); this assay is based on the 3'-5'
nuclease activity
of this processive enzyme, which is a measure of the
stability
of the protein-DNA complexes. As expected, Exo III digestions
of nucleosomes generated protections larger than with tetramers,
on
both the top (Fig.
6A; compare lanes 1 to 4 with lanes 5 to
8 and 13 to
16) and bottom (Fig.
6B; compare lanes 1 to 3, 4 to
6, and 10 to 13)
strands of fragment 2. Addition of NF-YB-NF-YC
stabilized the H3-H4
tetramers (compare lanes 5 to 8 and 9 to
12 in Fig.
6A and lanes 4 to 6 and 7 to 9 in Fig.
6B) and nucleosomes
(compare lanes 13 to 16 and 16 to 20 in Fig.
6A and lanes 10 to
13 and 14 to 17 in Fig.
6B). Moreover,
NF-YB-NF-YC reduced some
hypersensitive sites (Fig.
6B; compare lanes
11 and 15). However,
clear differences between H3-H4-NF-YB-NF-YC and
nucleosomal patterns
were present (compare lanes 9 to 12 and 13 to 16 in Fig.
6A and
lanes 7 to 9 and 10 to 13 in Fig.
6B). The results with
Exo III,
summarized in Fig.
7, are in
agreement with the nucleosome position
derived by MNase and are
consistent with the hypothesis that the
HFM subunits are associated to
tetramers and nucleosomes but do
not transform the formers in
octamer-like structures. From this
set of experiments, we conclude that
reconstitutions of NF-YB-NF-YC
with H3-H4 do not lead to the formation
of bona fide nucleosomes,
but addition of NF-YB-NF-YC does modify the
tetramer (and octamer)
patterns in ways that are consistent with
association of the HFM
subunits.
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FIG. 6.
Exo III assay of histone-NF-YB-NF-YC combinations.
Stoichiometric amounts of the indicated combinations of HFM proteins
were reconstituted with fragment 2 (labeled on the top strand [A] and
bottom strand [B]), cut with Exo III for the indicated length of
time, and analyzed on sequencing gels. Nuc., nucleosome.
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FIG. 7.
Recapitulation of the data obtained with DNase I, MNase,
and Exo III assays. The X, Y, and Inr elements are boxed, and the major
+1 start site of the Ea promoter is outlined. (A) DNase I. Arrows
indicate the cuts in the nucleosomal region. (B) MNase. Thick arrows
indicate the cuts with nucleosomes and dotted arrows with H3-H4
tetramers, thin arrows represent minor cutting sites, and brackets
delimit the boundaries of the nucleosome. (C) Exo III. Thick and dotted
lines indicate major stops with nucleosomes and H3-H4 tetramers,
respectively. The small arrow indicates a major stop which is bypassed
when NF-YB-NF-YC is reconstituted with nucleosomes. Asterisks refer to
differences in the pattern observed when the NF-YB and NF-YC subunits
are added to histones.
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|
NF-YB-NF-YC dimers bind H3-H4 in solution.
Because of the
data obtained from the DNA reconstitutions with NF-YB-NF-YC and the
evidence that HFM-containing TAFIIs are able to interact
with core histones in solution (8), we wanted to test
whether H3-H4 could bind directly to NF-YB-NF-YC in the absence of
DNA. To do this, we incubated equimolar amounts of H3-H4 with homology
domains containing His-tagged NF-YB-NF-YC in high-salt (2 M KCl)
conditions and progressively diluted the sample to 0.35 M KCl. We then
added the NTA-agarose resin, to which the recombinant NF-YB-NF-YC
complexes bind; following an extensive wash with 0.5 M KCl buffers, we
eluted bound proteins by boiling in SDS buffer and analyzed them in
SDS-gels. The result of such experiment is shown in Fig.
8A. H3-H4 complexes were efficiently retained by the nickel-NTA column only in the presence of NF-YB-NF-YC (lanes 3 and 4), whereas they were in the unbound material when incubated alone on the column (lanes 5 and 6). In similar experiments, H2A-H2B were not bound to NTA columns, either in the presence or in the
absence of NF-YB-NF-YC (not shown).
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FIG. 8.
Protein-protein interactions between NF-YB-NF-YC and
core histone dimers. (A) NTA-agarose columns. Lanes: 1 and 2, NF-YB4-NF-YC5 and H3-H4, respectively; 3 and 4, flowthrough and eluted
material from NTA-agarose supplemented with His-tagged NF-YB4-NF-YC5;
5 and 6, control NTA-agarose columns run without NF-YB4-NF-YB5. (B)
NF-YB4 and NF-YB43-Sepharose (Seph.) columns. Load, flowthrough, and
eluates of pure H2A-H2B (lanes 1 to 5) and H3-H4 (lanes 6 to 10) are
indicated. The four histones are run together in lane 11.
|
|
To confirm these data and verify whether the HFM of NF-YB is involved
in interactions, as in the case of H2B-H4 (
29), we
used a
different approach (
4). The homology domains containing
YB4
and NF-YB43 (a mutant lacking part of helix
3) were coupled
to a
Sepharose matrix, and the resulting columns were loaded with
H3-H4 or
H2A-H2B histone dimers. Bound material was recovered
in SDS buffer and
analyzed. As shown in Fig.
8B, H3-H4 were retained,
albeit not
completely, by the NF-YB4 column, but not by NF-YB43
(lanes 6 to 10),
while H2A-H2B did not bind to either columns
(lanes 1 to 5); the lower
efficiency with respect to the NTA columns
is most likely due to the
fact that coupling of recombinant proteins
to CnBr-activated Sepharose
is a random process, involving active
sites in the HFM of the short YB4
mutant. Taken together, these
data prove that (i) NF-YB-NF-YC can
efficiently bind to H3-H4
but not to H2A-H2B, (ii) NF-YB-NF-YC regions
outside the homology
domains are expendable for this activity, and
(iii) the HFM of
NF-YB is
involved.
Association of NF-YA with the NF-YB-NF-YC dimer in a nucleosomal
context.
The experiments described so far suggest that the
NF-YB-NF-YC dimer is able to interact with H3-H4, both in solution and
during reconstitutions, in a way that is different from H2A-H2B
association. Since NF-YB-NF-YC binding to H3-H4 is mediated by the
histone folds, which are also required for trimer formation with NF-YA, an important issue was to establish whether such NF-YB-NF-YC-H3-H4 complexes are compatible with NF-YA association and CCAAT box binding
or whether preengagement of HFM subunits with histones would preclude
NF-YA binding. To address this point, we added increasing amounts of
NF-YA to the reconstituted combinations detailed in Fig. 3 to 6. As
expected, no effect was seen on nucleosomes and on H3-H4 tetramers
(Fig. 9, lanes 1 to 3 and 7 to 9); an
upper complex was observed when NF-YA was added to the
NF-YB-NF-YC-containing reconstitutions, either with H3-H4 (lanes 5 and
6) or with nucleosomes (lanes 11 and 12). This upper complex has an
electrophoretic mobility different from that of the band generated by
the NF-Y trimer on naked DNA (compare lanes 5, 6, 11, and 12 with lanes
14 and 15). Moreover, the efficiencies of upper complex formation are
similar whether a nucleosome or H3-H4 tetramers are present, further
suggesting that H3-H4, and not H2A-H2B, tetramers are NF-Y docking
spots. The protein composition in this upper band was checked with
anti-NF-Y antibodies, and all three NF-Y subunits were found to be
involved in this interaction (not shown). Thus, association of
NF-YB-NF-YC with H3-H4 and with nucleosomes is not incompatible with
subsequent binding of NF-YA.
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FIG. 9.
NF-YA associates with histone-bound NF-YB-NF-YC.
Increasing concentrations of wt NF-YA (1 ng [lanes 2, 5, 8, 11, and
14] and 5 ng [lanes 3, 6, 9, 12, and 15]) were incubated with mixed
complexes previously reconstituted with the indicated combinations of
HFM proteins: H3-H4 (lanes 1 to 3), H3-H4-NF-YB-NF-YC (lanes 4 to
6), H3-H4-H2A-H2B (lanes 7 to 9), H3-H4-H2A-H2B-NF-YB-NF-YC (lanes
10 to 12), and NF-YB-NF-YC (lanes 13 to 15). Nuc., nucleosome.
|
|
| |
DISCUSSION |
In this study, we pursued our investigation on the interactions
between NF-Y and nucleosomal structures and detailed its remarkable interactions with core histones. We found evidence that NF-YB-NF-YC complexes bind to H3-H4, but not to H2A-H2B, both in solution and in
reconstitution assays with DNA. The integrity of the NF-YB HFM is
necessary for histone interactions, thus suggesting that the HFMs of
histones, not their N-terminal tails, mediate association. Interestingly, a highly positioned nucleosome is bound to the Ea core
promoter. DNase I and MNase digestions documented that addition of the
NF-YB-NF-YC dimer to H3-H4 tetramers or nucleosomes generated
differences consistent with NF-YB-NF-YC association but did not
provide unambiguous proof of an hybrid octamer-like structures.
Finally, the complexes retain remarkable NF-YA binding capacity.
NF-Y is thought to be an architectural protein playing a major role in
promoter and/or enhancer organization. Its peculiar structure leads to
the idea that part of its function stems from special connections with
nucleosomes. Few studies have focused on the chromatin structure of
NF-Y-dependent systems in vivo; in the Xenopus HSP70
promoter, NF-Y prevents the formation of repressing arrays of
nucleosomes, facilitating the activity of the heat shock factor and of
the general machinery (23). In the rat uteroglobin enhancer,
NF-Y is unable to bind at the linker between two positioned nucleosomes
unless progesterone, the inducer of enhancer activity, is added
(39). Previous experiments of our lab started to dissect
nucleosome-NF-Y interactions in vitro; an NF-Y mutant, containing only
the evolutionarily conserved domains, showed specific and rather
efficient interactions with nucleosomal DNA (36). Although
the CCAAT specificity of this NF-Y mutant is identical to that of the
wt trimer, bending and phasing studies of several combinations of NF-Y
mutants on the double CCAAT of the 
-globin promoter yielded clear
indications that two important parameters are considerably different
from the wt protein: (i) the half-life of the small NF-Y-CCAAT complex
is much longer, 4 h compared to 15 min; and (ii) the flexure
angles are ampler, 80° versus 56° (28). Because of these
findings, it was important to verify the histone-NF-Y-DNA
interactions with a physiologically relevant trimer. One of the most
interesting, and somewhat surprising, results of the present study is
that NF-Y associates DNA during histone deposition under high-salt
conditions which do not allow CCAAT binding on naked DNA (reference
19 and Fig. 2). The most likely explanation for this
phenomenon is that NF-Y is recruited on DNA through hydrophobic
interactions with histone dimers, mediated by HFM subunits. Because the
NF-Y complexes are seen at 1 M NaCl, when only H3-H4 tetramers are
bound to DNA, it seems logical to suppose that H3-H4 tetramers are
responsible of this recruitment, especially since we have shown H3-H4
binding in protein-protein interactions in solution and de novo
assembly without H2A-H2B (Fig. 3 and 8). Other factors are able to
associate with H3-H4 tetramers: Tup1, a yeast global repressor,
interacts with H3-H4 through the N terminus of H3 (13); the
NF-1 P-rich activation domain also interacts with H3 and H3-H4
(1); NF1 and OTF1 were shown to bind tetramers but not
nucleosomes on a reconstituted mouse mammary tumor virus promoter
(41); similarly, H2A-H2B inhibits binding of TFIIIA to H3-H4
tetramers in X. borealis somatic 5S RNA gene
(18). NF-Y is the first transcription factor for which
histone fold association during nucleosome assembly has been documented.
Our in vitro observations might have important physiological
consequences: many genes that are active early after replication require a DNA-bound NF-Y, and CCAAT-containing promoters of cell cycle
regulated genes are constantly bound by NF-Y in vivo (reference 33 and references therein). Thus, early association
of this protein during nucleosome deposition might be an essential
signal of a soon to be active promoter and a pivotal step in building up of additional interactions with nearby DNA-binding activators and
with the general transcriptional machinery or holoenzyme. The
demonstration of a remarkably well positioned nucleosome on the Ea
promoter, which overlaps the CCAAT and Inr elements and whose 5'
boundaries are adjacent to the crucial X-box element, will spur further
investigation on the existence of such structures in vivo. Moreover,
the recent recapitulation of the natural RFX complex, which binds the X
box as a trimer and makes cooperative interactions with NF-Y (reference
35 and references therein), will allow studies aimed
at clarifying the interactions between these two trimers in the
well-characterized nucleosome context described here.
We feel that our results have wider implications pertaining the histone
fold family, a growing group of proteins known to form complex
interactions among them, as exemplified by HFM TAFIIs (6, 8). Results of TAFII-histone interactions
showed that the H4-like hTAFII80 can bind to H3, the
H3-like hTAFII31 binds to H4, and hTAFII20
binds to H2A and H2B (8). Our findings of interactions of
NF-YB-NF-YC with H3-H4, but not with H2A-H2B, support the hypothesis
that distinct subfamilies of HFM proteins have coevolved cross-dimer
preferences. The H3-H4 tetramer interacts with H2A-H2B mainly via
H2B-H4 association, elicited by hydrogen bonds of H4-H75 and H4-K93
with H2B-E90 and H2B-E73, respectively (29); in the
corresponding positions, NF-YB also harbors acidic residues, D115 and
E98, two of the relatively few amino acids that are absolutely
conserved in 26 sequences from different species (33a),
suggesting that indeed NF-YB contacts H4 and indicating a reason for
the strong evolutionary pressure on these residues. On the other hand,
the inability to interact with H2A-H2B is in accordance with our recent
observation that NF-YB-NF-YC cannot cross-dimerize with the
H2A-H2B-like subunits of NC2 despite their closer relatedness
(47). Moreover, interactions between NF-Y and HFM
TAFIIs have been recently documented in our lab
(14a).
NF-YB-NF-YC, either the wt complex or short versions containing the
evolutionary conserved parts, can form complexes in stoichiometric amounts with H3-H4 in our reconstitution assays, in which a large (250-fold) excess of cold sonicated salmon sperm DNA is present; neither NF-YA nor the CCAAT box is necessary. It was therefore of some
importance to establish whether such complexes could be considered as
nucleosome-like structures. DNase I, MNase, and Exo III assays were
informative in this respect: in general, our data are not in favor of
this hypothesis, especially since a clear difference exists between the
patterns generated by MNase on nucleosomal DNA and those of
NF-YB-NF-YC-H3-H4, which resemble those of H3-H4 tetramers. However,
differences were found upon addition of NF-YB-NF-YC in all assays,
with respect to both H3-H4 tetramers and nucleosomes. Our data imply
that the NF-YB-NF-YC dimer is involved in contacts outside the
octameric or tetrameric structures, by associating directly with H3-H4.
The extended protections are an indication that additional sequences
are contacted by the NF-YB-NF-YC dimer; this might have important
consequences for the three-dimensional structure of the promoter by
altering, disturbing, or even arresting nucleosome deposition or
hampering association of linker histones. It should be remembered that
H2A-H2B association is an essential step in formation of a
transcriptionally repressive unit (16); histone folds
interfering with this step might thus counteract repression.
What is the physiological basis for performing experiments with
isolated NF-YB-NF-YC dimers? Studies on immortalized cell lines
suggested that NF-Y was a constant, noninducible trimeric factor.
Indeed, evaluation of HFM subunits expression in different systems
indicated that they are ubiquitous (9, 14, 34). However, two
types of evidence challenge this view. (i) HFM dimers were shown to
engage in high-molecular-weight complexes in the absence of NF-YA, and
evidence of association with TFIID has been presented (4).
Recent experiments confirm these findings, as proteins involved in
histone acetylation are found associated with NF-Y: human GCN5 binds to
the NF-YB-NF-YC dimer (10), p300 binds to NF-YB
(26), and P/CAF binds to NF-YA (20). It should be
noted that P/CAF is part of a large complex containing more than 20 polypeptides, including hTAFII31, hTAFII20, and
PAF65, all proteins containing histone folds (37).
Moreover, binding of p300 to Xenopus NF-YB results in
acetylation of NF-YB, the functional consequences of which are unknown
(26). Interestingly, activation assays with HFM subunits
fused to GAL4 indicated that they are sufficient to activate
transcription robustly, two- to fourfold better than the NF-Y trimer
(11); thus, even in the absence of NF-YA, NF-YB-NF-YC could
serve the dual function of being able to confer nucleosome binding, as
shown here, and transcriptional activation potential to associated
complexes. (ii) The expression of NF-YA in physiological cellular
systems is sometimes limiting and highly regulated
posttranscriptionally: NF-YA is dramatically down-modulated in
IMR90 fibroblasts upon senescence and in terminally differentiated
C2C12 myotubes (9, 14) but up-modulated in human peripheral
monocytes following macrophage maturation (34). The latter
process is accomplished without cell division and de novo chromatin
deposition; it is possible that NF-YA can directly interact with the
structures described here, activating, among others, genes of the
antigen presentation pathway, such as MHC class II, all dependent on
CCAAT boxes. Within this conceptual framework, we feel that the
remarkable efficiency of NF-YA binding to a NF-YB-NF-YC dimer
preengaged in histone interactions is an important finding.
In summary, we think that NF-Y is a well-suited interface with basic
chromatin structures that can employ multiple mechanisms to "open
up" a promoter, as outlined in the scheme presented in Fig.
10. It can prevent promoters from being
shut off by nucleosome deposition, and it can bind sites that need to
be activated but are embedded in nucleosomes. NF-YB-NF-YC dimers,
thanks to their histone-like structures, can associate DNA during
nucleosome formation; further deposition of NF-YA will then lead to
proper CCAAT box binding, local changes in the nucleosomal structure,
and access of activators binding nearby. The assays used here will now
be implemented in the study of facilitation of other activators binding to the Ea promoter, both upstream and downstream of the CCAAT box.
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FIG. 10.
Models for NF-Y-histone association. The NF-Y trimer
associates with H3-H4 tetramers (a) or nucleosomes (c). The
NF-YB-NF-YC dimer associates with H3-H4 tetramers (b) and nucleosomes,
presumably through H3-H4, and forms structures which can still be bound
by NF-YA (d). H3-H4 tetramers are in yellow; nucleosomes are in
green.
|
|
| |
ACKNOWLEDGMENTS |
We thank K. Luger and T. Richmond for the PET3 histones plasmids
and G. F. Badaracco for encouragement and helpful discussions.
G.C. was a recipient of a Telethon fellowship. This work was supported
by grants from MURST (PRIN-"Nucleic acid-proteins interactions") and CNR to R.M. The contribution of Telethon grant E582 to R.M. is
gratefully acknowledged.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Dipartimento di
Genetica e Biologia dei Microrganismi, Università di Milano, Via
Celoria 26, 20133 Milan, Italy. Phone: 39-2-26605239. Fax:
39-2-2664551. E-mail: mantor{at}imiucca.csi.unimi.it.
Present address: Nederlands Kanker Institut, 1066 CX Amsterdam, The Netherlands.
| |
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0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
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