Unité des Virus Oncogènes, UA1644 du Centre National de la Recherche Scientifique, Département des Biotechnologies, Institut Pasteur, 75724 Paris, France
Biochemical and genetic evidence suggest that the SWI/SNF complex is involved in the remodeling of chromatin during gene activation. We have used antibodies specific against three human subunits of this complex to study its subnuclear localization, as well as its potential association with active chromatin and the nuclear skeleton. Immunofluorescence studies revealed a punctate nuclear labeling pattern that was excluded from the nucleoli and from regions of condensed chromatin. Dual labeling failed to reveal significant colocalization of BRG1 or hBRM proteins with RNA polymerase II or with nuclear speckles involved in splicing. Chromatin fractionation experiments showed that both soluble and insoluble active chromatin are enriched in the hSWI/SNF proteins as compared with bulk chromatin. hSWI/SNF proteins were also found to be associated with the nuclear matrix or nuclear scaffold, suggesting that a fraction of the hSWI/SNF complex could be involved in the chromatin organization properties associated with matrix attachment regions.
It is becoming clear that structural aspects of chromatin
and the architecture of the nucleus are important factors in the control of gene expression (Felsenfeld,
1992 Several groups have demonstrated that a complex homologous to the yeast SWI/SNF complex exists in higher
eukaryotes (Kwon et al., 1994 The high degree of similarity between BRG1 and hBRM
raises the possibility that they may be functionally redundant. On the other hand, we have observed that BRG1
and hBRM are phosphorylated during mitosis, and, while
hBRM is partially degraded, the levels of BRG1 remain
constant throughout the cell cycle (Muchardt et al., 1996 Recently, it has been proposed that the yeast SWI/SNF
complex copurifies with the holoenzyme fraction of RNA
polymerase II (RNAP II), suggesting that interaction with
RNAP II may be the mechanism by which SWI/SNF complex is recruited to its genomic targets (Wilson et al., 1996 Nuclear fractionation studies have shown that transcriptionally active DNA is tightly associated with the nuclear
skeleton or nuclear matrix, while inactive loci are not (Stratling, 1987 In the present study we have used specific antibodies that
recognize BRG1, hBRM, and hSNF5 to study the subnuclear localization of the human SWI/SNF complex. Immunofluorescent staining revealed a punctate distribution of
BRG1 and hBRM in interphase HeLa nuclei, the lowest
concentration appearing in regions of high DNA density. However, we failed to show strong overlap between
hBRM or BRG1 and RNA polymerase II staining. Chromatin fractionation demonstrated that three components
of the hSWI/SNF complexes (BRG1, hBRM, and hSNF5)
were enriched in highly transcribed chromatin and associated with the nuclear matrix. Association with chromatin
or nuclear structures was abolished during mitosis. Finally,
we show that hSWI/SNF complexes can be released from
the nucleus by incubation with ATP and that this process
is inhibited by protein kinase inhibitors.
Cell Culture and Cell Cycle Synchronization
HeLa cells were grown at 37°C in 7% CO2 in DME (GIBCO BRL, Gaithersburg, MD) supplemented with 7% FCS. For cell cycle synchronization, exponentially growing cells were treated with 5 mM thymidine for 40 h.
Cells were then released from the block, and samples were taken at different times for flow cytometry analysis and for extract preparation. 12 h after the thymidine block release, 0.1 µg/ml nocodazole was added to the
medium to block the cells in mitosis.
Isolation of Cell Nuclei and Total Extract
The procedure was adapted from Cereghini et al. (1988) When total extract was required, 107 cells were lysed in 200 µl of urea
buffer (8 M urea, 0.1 M NaH2PO4, 0.01 M Tris, pH 8). The protein concentration was determined by Bradford assays (Bradford, 1976 Nuclear Matrix Isolation
High salt isolation of nuclear matrix was carried out essentially as described (He et al., 1990 For low salt preparation of nuclear matrix and scaffolds, nuclei were
isolated as described by Mirkovitch et al. (1984) Chromatin Fractionation
Isolation of S1, S2, and P fractions from HeLa nuclei chromatin was performed according to the method of Rose and Garrard (1984) Immunoblotting and Antibodies
Immunoblotting was carried out according to standard procedures. Proteins were separated by SDS-PAGE (Laemmli, 1970 Indirect Immunofluorescence Analysis
HeLa cells, grown on coverslips, were fixed in 3.5% freshly prepared
paraformaldehyde in PBS for 10 min at room temperature, and then permeabilized with 0.05% Triton X-100 in PBS for 30 min at room temperature. Alternatively, cells were permeabilized with ice-cold CSK buffer
supplemented with 0.5% Triton X-100 for 3 min, before fixation. For in
situ isolation of nuclear matrix, cells were extracted directly on the coverslips with the high salt method described above, and then fixed with 4%
paraformaldehyde in PBS. To enhance exposure of hidden epitopes, cells
were treated with 6 N guanidine hydrochloride as described previously
(Peränen et al., 1993 ATP-dependent Release of hSWI/SNF from Cell Nuclei
Nuclei from HeLa cells were isolated as described above. 107 nuclei were
washed in 1 ml of nuclear buffer, centrifuged, and resuspended in 100 µl
of the same buffer. 10-µl aliquots were incubated for 1 h at 30°C in the
presence or absence of 3 mM ATP. When indicated, 3 mM of adenosine
5 For in situ ATP-dependent release of BRG1 and hBRM, HeLa cells
grown on coverslips were permeabilized with 0.5% Triton X-100-CSK buffer as previously described and incubated in nuclear buffer (see above)
with or without ATP for 1 h at room temperature. Afterward, cells were
washed with PBS and fixed with paraformaldehyde.
Subnuclear Immunolocalization of hBRM and BRG1
We have previously described the characterization of affinity-purified polyclonal antibodies that specifically recognize BRG1 or hBRM proteins (
It has been reported that the yeast SWI/SNF proteins
are integral components of the RNAP II holoenzyme, being part of the SRB (suppressor of RNA polymerase B)
complex. This complex is tightly associated with the RNAP II
large subunit CTD (Wilson et al., 1996 hSNF/SWI Complex Is Partially Associated with the
Nuclear Matrix
To get further insight on the association of hSWI/SNF components with the nucleus, different procedures were tested
for their ability to release the hSWI/SNF complex from
HeLa nuclei. More than 60% of the amount of hBRM,
BRG1, and hSNF5 proteins was found to be resistant to
extraction with detergents and 0.45 M NaCl or 100 mM
MgCl2, even after total DNA digestion with DNase I (data not shown). Such treatments are normally used to extract
chromatin components including high mobility group proteins, transcription factors, or histones. To investigate the
possibility that the hSWI/SNF complex may bind to the
nuclear skeleton or nuclear matrix, we isolated the nuclear
matrix by the sequential extraction procedure of He et al.
(1990)
The possibility has been raised that the high salt extraction procedure used for nuclear matrix preparations induces the precipitation of some nuclear proteins (Kirov and
Tsanev, 1986 To investigate whether the distribution of hBRM and
BRG1 proteins is similar in whole nuclei and in nuclear
matrices, we used
hSWI/SNF Proteins Are Enriched in Active Chromatin
In the previously described nuclear matrix isolation protocol, >95% of chromatin was solubilized in a single fraction.
To try to partition between active and inactive chromatin,
we have used an established fractionation procedure in
which nuclei are subjected to mild digestion with micrococcal nuclease and subsequent extraction with EDTA
(Huang and Garrard, 1989
Association of BRG1 and hBRM with the Nuclei during
the Cell Cycle
We have recently demonstrated that hBRM and BRG1
are phosphorylated in mitotic cells. The phosphorylated
forms of the proteins are localized in the entire cell volume with exclusion from the condensed chromosomes
(Muchardt et al., 1996
ATP-dependent Release of BRG1 and hBRM from
the Nucleus
We further investigated the mechanisms that influence the
binding of SWI/SNF complex to its targets in chromatin
and in the nuclear matrix (Muchardt et al., 1996
To verify whether this process involved a protein kinase
activity, we have incubated HeLa nuclei with ATP in the
presence of several kinase inhibitors: H7, an inhibitor of
serine and threonine kinases (Hidaka et al., 1984 To investigate the step(s) in gene activation in which the
hSWI/SNF complex operates, we have compared the spatial distribution and the characteristics of the association
of three hSWI/SNF proteins with other nuclear components. BRG1 and hBRM were not homogeneously distributed in the nucleus of HeLa cells. Indirect immunofluorescent labeling revealed a punctate staining pattern that was
excluded from nucleoli and from regions of very condensed chromatin. Little is known about the distribution
of transcription factors in the interphase nucleus. The few
studies that have been published so far show that transcription factors occur in clusters rather than being diffusely distributed throughout the nucleoplasm. Such intranuclear distribution has been described for Rb (Mancini
et al., 1994 Recently, it has been reported that the yeast SWI/SNF
complex copurifies with an active fraction of yeast RNAP
II (Wilson et al., 1996 To further monitor the partition of the SWI/SNF complex in the nucleus, we applied several subnuclear fractionation procedures directed towards the isolation of the
nuclear matrix or nuclear scaffold. DNA binds to nuclear
matrix through regions called MAR or SAR (for review
see Laemmli et al., 1992 We further investigated the distribution of the hSWI/
SNF proteins in active and inactive fractions of chromatin.
hBRM, hSNF5 and, to a lesser extent, BRG1 were enriched both in chromatin highly accessible to micrococcal
nuclease and in "insoluble chromatin," or chromatin that
remains bound to the nuclear skeleton. These two fractions (termed S1 and P) were shown to be enriched in
transcriptionally active genes (Rose and Garrard, 1984 We have also investigated the conditions that determine
the binding of hSWI/SNF complex to its targets in the nucleus. The release of SWI/SNF proteins from the tight nuclear interaction coincides temporally with the start of mitosis (Fig. 5). This corresponds in time with the onset of
BRG1 and hBRM hyperphosphorylation, suggesting that
either phosphorylation itself or an event linked to this
modification is the cause of the dissociation event. We found that treatment of permeabilized nuclei with hydrolyzable ATP leads to the release of BRG1 and hBRM
from the nuclei. ATP-dependent release was inhibited by
a protein tyrosine kinase inhibitor and a cdc2 substrate
peptide, suggesting that phosphorylation of some nuclear
components is involved in this process. However, released BRG1 and hBRM were not hyperphosphorylated after
ATP treatment in the same way than they are during mitosis. Changes in the activity and morphology of the nucleus
throughout the cell cycle require the nuclear structure to
be dynamic. Phosphorylation appears to be a major control mechanism of the nuclear skeleton. For example, nuclear disassembly is driven by the hyperphosphorylation of
lamin filaments (Fisher, 1987 Finally, in this work we have analyzed the distribution of
components of the hSWI/SNF complex in different fractions of the nucleus and the chromatin. Numerous observations indicate a very high level of structural organization
and compartmentalization for the activities occurring within
the nucleus. We think that these structural aspects will be
important factors for the understanding of the mechanism
by which the SWI/SNF complex operates.
; Paranjape et al., 1994
; Stroboulis and Wolffe, 1996
).
DNA in the nucleus is organized into a hierarchy of structures where the basic building block is the nucleosome.
The packaging of DNA in nucleosomes and higher order
structures represents an obstacle to the binding of specific proteins (Laybourn and Kadonaga, 1991
) and RNA polymerases (Williamson and Felsenfeld, 1978
) to control elements and transcription initiation sites. The same is true
for transcriptional elongation. A convergence of biochemical and genetic studies has identified several ATP-dependent multiprotein complexes that may help transcriptional
activators to overcome chromatin-mediated repression
(Kingston et al., 1996
). The SWI/SNF complex is one of
these complexes. The SWI (for mating type switching) and
SNF (for sucrose nonfermenting) genes were first identified in yeast (SWI/SNF gene complex) by mutations interfering with the activation of several inductible promoters (for review see Carlson and Laurent, 1994
; Peterson and
Tamkun, 1995
; Peterson, 1996
). Alterations in each of the
four histones and in some presumed chromatin structural
proteins all result in partial suppression of the impaired transcriptional phenotype of swi or snf mutations (Winston
and Carlson, 1992
). Genetic and biochemical analysis demonstrated that SWI and SNF proteins function together as
one multisubunit complex (Peterson and Hershkowitz, 1992; Cairns et al., 1994
; Peterson et al., 1994
) able to facilitate the binding of activator proteins to nucleosomal
DNA in an ATP-dependent way (Côté et al., 1994
).
Within SWI/SNF proteins, SNF2 is of special interest. It
contains sequence motifs closely related to those found in
DNA-dependent ATPases and helicases (Laurent et al.,
1993
), and, indeed, bacterially expressed SNF2 protein shows DNA-dependent ATPase activity. These data suggest
that SNF2 is an essential component of the ATPase-dependent remodeling activity of the complex.
; Wang et al., 1996a
,b). One
of the first relatives of SWI2/SNF2 to be discovered was
brahma (brm), an activator of Drosophila homeotic genes
(Tamkun et al., 1992
). brm was identified in a screen for
suppressors of mutations in polycomb, a repressor of homeotic genes that is thought to act by altering chromatin structure. Humans have at least two genes closely related
to SWI2/SNF2: hBRM (human brahma or hSNF2
) and
BRG1 (brahma-related gene 1 or hSNF2
) (Muchardt and
Yaniv, 1993
; Khavari et al., 1993
; Chiba et al., 1994
). Both
hBRM and BRG1 have been shown to enhance transcriptional activation by the glucocorticoid receptor (Muchardt
and Yaniv, 1993
; Chiba et al., 1994
) through a mechanism
that may also involve the retinoblastoma (Rb)1 protein
(Dunaief et al., 1994
; Singh et al., 1995
). Human homologues of SNF5 and SWI3 have also been cloned (Kalpana
et al., 1994
; Muchardt et al., 1995
; Wang et al., 1996b
). In
addition, human SWI/SNF complexes containing hSNF5,
either BRG1 or hBRM proteins, and seven to ten additional BRG1-associated factors have been purified from
different cell lines (Wang et al., 1996a
). Like the yeast
complex, the human SWI/SNF complexes show, in vitro, nucleosome remodeling activity and facilitate the binding
of activators to nucleosomal DNA (Imbalzano et al., 1994
;
Kwon et al., 1994
; Wang et al., 1996a
).
).
These results suggest that the two proteins may play distinct roles during the cell cycle.
).
However, the SWI/SNF complex can also be isolated from
yeast without an associated holoenzyme (Cairns et al., 1994
;
Côté et al., 1994
). At present, it is unclear whether the human SWI/SNF proteins are also associated with the RNAP
II holoenzyme. In addition, it was also demonstrated that the yeast SWI/SNF complex contains a DNA binding activity that may target it directly to specific DNA structures
(Quinn et al., 1996
). These examples demonstrate that the
mechanism involved in the recruitment of the SWI/SNF
complex to its targets in the chromatin, in vivo, remains
unclear.
; Jackson and Cook, 1985
; Jackson et al., 1993
).
The nuclear matrix is operationally defined as the nuclear
structure that remains after the salt extraction of nucleasetreated nuclei. It consists of a peripheral lamina-pore complex and an internal filamentous ribonucleoprotein network that has not been well characterized (for review see
Berezney et al., 1995
). This component of the nuclear architecture provides the internal scaffold of the nucleus. The matrix- or scaffold-associated DNA regions (MARs
or SARs) may function as boundary elements for transcriptional domains and confer position-independent expression of associated genes in transgenic mice (Laemmli
et al., 1992
; Jenuwein et al., 1993
). Biochemical studies
have also demonstrated that transcriptionally active chromatin exhibit increased sensitivity to nucleases. These observations explain why a fraction of actively transcribed
chromatin is easily solubilized after nuclease treatment of
isolated nuclei while the rest is tightly bound to the nuclear matrix (Kamakaka and Thomas, 1990
; Davie, 1995
).
Materials and Methods
. 107 cells were
resuspended in 200 µl of HNB (0.5 M sucrose, 15 mM Tris-HCl, pH 7.5, 60 mM KCl, 0.25 mM EDTA, pH 8, 0.125 mM EGTA, pH 8, 0.5 mM spermidine, 0.15 mM spermine, 1 mM DTT, 0.5 mM PMSF, 5 µg/ml pepstatin,
5 µg/ml leupeptin, and 5 µg/ml aprotinin). Then 100 µl of HNB supplemented with 1% NP-40 was added dropwise. After 5 min of incubation at
4°C, nuclei were pelleted by centrifugation at 6,000 rpm for 3 min.
).
). After wash in PBS, cells were extracted in cytoskeleton buffer (CSK): 10 mM Pipes, pH 6.8, 100 mM NaCl, 300 mM sucrose, 3 mM MgCl2, 1 mM EGTA, supplemented with leupeptin, aprotinin,
and pepstatin (1 µg/ml each), 1 mM PMSF, 1 mM DTT, and 0.5% (vol/
vol) Triton X-100. After 3 min at 4°C, the cytoskeletal frameworks were
separated from soluble proteins by centrifugation at 5,000 g for 3 min.
Chromatin was solubilized by DNA digestion with 1 mg/ml of RNase-free
DNAase I in CSK buffer plus proteinases inhibitors for 15 min at 37°C. Then ammonium sulfate was added from a 1 M stock solution in CSK buffer to a final concentration of 0.25 M and, after 5 min at 4°C, samples
were pelleted again. The pellet was further extracted with 2 M NaCl in
CSK buffer for 5 min at 4°C, and then centrifuged. This treatment removed all the DNA and the histones from the nucleus, as shown by agarose gel electrophoresis and SDS-PAGE, respectively. The remaining pellet was solubilized in urea buffer and was considered the nuclear matrix-
containing fraction.
. Nuclei were then stabilized in isolation buffer (3.75 mM Tris HCl, pH 7.5, 0.05 mM spermine,
0.125 mM spermidine, 0.5 mM EDTA, 5 mM MgCl2, 20 mM KCl) for 20 min at 37°C, and then DNA was digested by incubation under the same
conditions for another 15 min in the presence of 1 mg/ml of RNase-free
DNAase I. After centrifugation, nuclei were washed with isolation buffer
and extracted with the same buffer supplemented with 25 mM 3,5-diiodosalicilic acid, lithium salt (LIS) for 5 min at room temperature. Chromatin-depleted nuclei were recovered by centrifugation and the pellet was
solubilized in urea buffer.
with minor
modifications. 107 nuclei were isolated as described above and resuspended in 200 µl of nuclear buffer (20 mM Tris-HCl, pH 7.5, 70 mM NaCl,
20 mM KCl, 5 mM MgCl2, and 3 mM CaCl2 supplemented with protease
inhibitors). Nuclei suspension was incubated with 3 U of micrococcal nuclease (Sigma Chemical Co., St. Louis, MO) at room temperature during the indicated time. The digestion was terminated by the addition of EDTA
and EGTA to 5 mM each, the mixture was then centrifuged at 5,000 g for
3 min, and the supernatant was designated the S1 fraction. The nuclear
pellet was lysed in 2 mM EDTA for 15 min at 4°C. This was followed by
centrifugation, and the supernatant and the pellet were designated the S2
and P fractions, respectively. For DNA analysis of S1, S2, and P fractions,
aliquots were treated with lysis buffer (50 mM Tris-HCl, pH 7.5, 100 mM NaCl, 5 mM EDTA, 0.5% SDS) for 1 h at 37°C and with phenolCHCl3 extraction. Proteins were analyzed by SDS-PAGE. After 2 min of
micrococcal nuclease digestion, S1, S2, and P contained ~5%, 80%, and
15% of the total DNA, respectively.
) and transferred to
nitrocellulose. The membrane was then blocked with PBS/0.2% Tween20/10% horse serum and incubated with the various antibodies. Enhanced
chemiluminescence reagents (ECL; Amersham, Les Ulis, France) were
used for detection. The mAb pol 3/3 recognizes the RNAPII largest subunit at an evolutionary conserved epitope located outside the carboxy-terminal domain (CTD) (Krämer et al., 1980
) and was kindly provided by O. Bensaude (Ecole Normal Superieure, Paris, France). The monoclonal
CC3 antibody was raised against a nuclear p255 phosphoprotein (Thibodeau et al., 1989
) and provided by M. Vincent (Université Laval,
Sainte-Foy, Quebec, Canada). Recently, it has been demonstrated that the
epitope recognized by this antibody corresponds to a subpopulation of hyperphosphorylated RNAPII largest subunit (Vincent et al., 1997
; Dubois et
al., 1997
). Antibodies against BRG1, hBRM, hSNF5, and JunB have been
previously described (Muchardt et al., 1995
, 1996; Pfarr et al., 1994
). To prepare anti-glucocorticoid receptor antibodies, rabbits were immunized
with an Escherichia coli-expressed chimeric protein spanning amino acids
106-318 plus 407-556 from the human glucocorticoid receptor protein.
). In all cases, the coverslips were incubated overnight with the appropriate antibodies in PBS/10% horse serum/0.1% Tween-20. Fluorescein- or Texas red-linked anti-rabbit or anti-mouse antibodies from Amersham were used for detection. The cellular DNA was labeled with 0.05% 4
,6-diamidino-2-phenylindole (DAPI) or propidium iodide. The preparations were observed at ×100 magnification with an Axiophot microscope (Zeiss, Oberkochen, Germany) or at ×100 magnification with
a confocal microscope using a 488-nm laser and a 535-nm narrow band filter for the FITC signal, and a 568-nm laser and a 590-nm long band filter
for Texas red and propidium iodide signal.
-(
,
-methylene) triphosphate (AMP-PCP) or adenosine 5
-O-(3-thiotriphosphate) (ATP
S) was added to the reaction.
Results
-BRG1 and
-hBRM,
respectively). In immunofluorescence studies, these antibodies revealed a strictly nuclear signal except in mitotic cells
where hBRM and BRG1 signals were found to be excluded from the regions containing the condensed chromosomes (Muchardt et al., 1996
). A more detailed analysis
of the labeling pattern of HeLa cells, using confocal microscopy, revealed a diffuse nucleoplasmic signal and a variable number of bright dots or foci (Fig. 1 A). Furthermore,
hBRM and BRG1 staining was excluded from the nucleoli
and from regions of highly condensed heterochromatin, which are stained brightly by propidium iodide. hBRM
and, to a lesser extent, BRG1 were also excluded from the
periphery of the nucleus. It is known that transcriptionally
inactive heterochromatin is adjacent to the inner nuclear
membrane (Mathog et al., 1984
). These data suggest that
hSWI/SNF complex is excluded from heterochromatin. The intranuclear distribution of both proteins was the
same in cells that were extracted with Triton X-100 before
fixation or in nonextracted cells.
Fig. 1.
Subnuclear distribution of hBRM and BRG1 proteins in HeLa cells. HeLa cells grown on coverslips were fixed with 3% paraformaldehyde. (A) After fixation, cells were labeled with -hBRM (top left) or
-BRG1 (top right) and detected with a fluoresceinconjugated secondary antibody, using confocal microscopy. Cellular DNA was stained with propidium iodide (PI) (middle). Superimposition of antibody staining and PI (bottom). (B and C) Fixed cells were double labeled with pol 3/3 mAbs against the RNAP II-LS (visualized with fluorescein; middle) and
-BRG1 (B) or
-hBRM (C) (visualized with Texas red; left). Confocal images from each fluorochrome were recorded and superimposed (green staining for RNAP II-LS protein and red staining for hBRM or BRG1; right). Regions of colocalization (yellow). (D and E) Fixed cells were double labeled with cc3 mAbs against CTD-hyperphosphorylated RNAP II (visualized with fluorescein; middle) and
-BRG1 (D) or
-hBRM (E) (visualized with Texas red; left). Confocal images from each fluorochrome were recorded and superimposed (green staining for CTD-hyperphosphorylated RNAP II protein and red staining for hBRM or BRG1;
right). Regions of colocalization (yellow). Intensities were adjusted for maximum contrast. Bar, 5 µm.
[View Larger Version of this Image (49K GIF file)]
). To test if human
SWI/SNF complexes are associated with RNAP II in situ,
we looked for potential colocalization between hBRM or
BRG1 and RNAP II. Two mAbs against the largest subunit of RNAP II (RNAP II-LS) were used: the pol 3/3 antibody
recognizes nonphosphorylated and phosphorylated forms
of RNAP II-LS, and the cc-3 antibody recognizes a subpopulation of hyperphosphorylated RNAP II-LS (Vincent
et al., 1997
; Dubois et al., 1997
) located in 20-30 discrete
nuclear foci (Bisotto et al., 1995
). These foci are closely
linked to speckle domains (irregularly shaped intranuclear regions that contain splicing factors) and colocalize with
the splicing factor SC-35 (Bisotto et al., 1995
; Bregman et
al., 1995
; Mortillaro et al., 1996
). Combination of
-hBRM
or
-BRG1 labeling and pol 3/3 or cc-3 labeling was performed and analyzed by confocal microscopy (Fig. 1, B-E).
Pol 3/3 antibodies revealed a punctate staining pattern
throughout the nucleus that was excluded from the nucleoli. Although some colocalization could be observed (Fig. 1, B and C, right panels, yellow), a large fraction of the
hBRM or BRG1 dots showed little or no RNAP II staining and vice versa. We analyzed the degree of colocalization quantitatively by plotting the pixel intensity distribution of a dual-channel section (two-dimensional scatter
plot diagram) or by plotting the signal intensities of the
red and the green signals along a single line drawn
through the image of a doubly labeled nucleus (not
shown). These plots show that there is no clear correlation
between the spatial distribution of hBRM or BRG1 and
RNAP II. The cc3 antibody recognized 20-30 brightly
stained foci. hBRM- and BRG1-containing dots did not colocalize with these foci either (Fig. 1, D and E). It has
also been reported that RNAP II inhibitors like
-amanitin or actinomycin D provoke a redistribution of RNA pol
II and an increased concentration of the enzyme in the
speckles (Bregman et al., 1995
). Treatment of HeLa cells
with such inhibitors provoked an enlargement of the
speckles (around twofold surface increase), revealed by
the cc-3 antibody, but did not produce any reorganization
of the signals revealed by the
-BRG1 or
-hBRM antibodies (data not shown). These data suggest that a large
fraction of the hSWI/SNF complex is not associated with
RNAP II and vice versa.
. In the first fractionation step, soluble proteins are
removed by extraction with Triton X-100. Chromatin proteins are then released by DNase I digestion and extraction with 0.25 M ammonium sulfate. 95% of the histones
were extracted in this step (data not shown). After washing with 2 M NaCl, the last fraction is composed of structural nuclear matrix proteins and nuclear matrix-associated proteins. Supernatants from each extraction step and
the final nuclear matrix pellet were analyzed by SDSPAGE and immunoblotting. As shown in Fig. 2 A, ~50%
of the BRG1, hBRM, and hSNF5 proteins were released
with the chromatin proteins, while the remainder was
tightly associated with the nuclear matrix proteins. This
was compared with the distribution of other nuclear proteins. It has been shown previously that a fraction of hypophosphorylated Rb protein is associated with the nuclear
matrix (Mancini et al., 1994
). In our extracts, hyperphosphorylated Rb appeared in the first fraction together with
soluble proteins. Most hypophosphorylated Rb was released in the Triton X-100 extraction or in the chromatin
fraction, while ~20% was found in the insoluble nuclear
matrix pellet (Fig. 2 A). It has also been reported that glucocorticoid receptor and other nuclear receptors are associated with the nuclear matrix (van Steensel et al., 1995b).
Indeed, our nuclear matrix preparations contained ~50%
of the nuclear glucocorticoid receptor (GR) from dexamethasone-treated HeLa cells. However, in nontreated
cells, all the GR was found in the cytoplasmic fraction
(Fig. 2 A). In contrast, the transcription factor JunB and
the large subunit of the RNAP II (revealed by the pol 3/3 antibody) were fully extracted in the chromatin fraction,
indicating that nuclear matrix preparations were not contaminated with all transcription factors. Finally, we also
used an antibody against lamin B, one of the major components of the nuclear matrix, as a marker to verify that
cytoplasmic and chromatin fractions were not contaminated with nuclear matrix proteins. As expected, lamin B
was solely found in the nuclear matrix fraction (Fig. 2 A).
Fig. 2.
A fraction of the
hSWI/SNF complex is associated with nuclear matrix. (A)
HeLa nuclear matrix was prepared by the high salt method
as described in Materials and
Methods. Cells were sequentially extracted with 0.5%
Triton X-100 (Cytoplasm),
DNase I and 0.25 M (NH4)2SO4
(Chromatin), and 2 M NaCl
(Wash 2M NaCl), and the remaining pellet was solubilized
in 8 M urea (Nuclear Matrix). An equivalent aliquot of each
step of the extraction protocol was subjected to SDSPAGE and immunoblotted
with the indicated antibodies.
RNAP II-LS was detected
with pol 3/3 antibodies. When indicated, HeLa cells were
treated with 106 M of dexamethasone (DEX). (B)
HeLa nuclear matrix was
prepared by the LIS method
as described in Materials and
Methods. Cells were sequentially extracted with 0.5%
Triton X-100, DNase I, 25 mM LIS in low ionic strength
buffer, and low-ionic strength
buffer, and finally the pellet
was resuspended in urea
buffer (Nuclear Matrix). An
equivalent aliquot of each
step of the extraction protocol was subjected to SDSPAGE and immunoblotted
with the indicated antibodies.
[View Larger Version of this Image (39K GIF file)]
). To verify the observations described above
with a method that avoids high salt conditions, we used the
procedure of Mirkovich et al. (1984). This protocol entails
stabilization of nuclei by a brief incubation at elevated temperature, followed by extraction of histones and other
chromatin components with detergent-like LIS and digestion of the genomic DNA. The resulting structures have
been termed nuclear scaffolds (Mirkovich et al., 1984). When
nuclear scaffolds were isolated by this method, ~50% of
hBRM and BRG1 proteins were extracted in the LIS-soluble fraction, together with chromatin proteins, whereas
the other 50% appeared in the nuclear scaffold preparation (Fig. 2 B). However, LIS solubilized a large fraction of the hSNF5 protein, suggesting that the LIS treatment
may disrupt the hSWI/SNF complex or the association of
hSNF5 with other members of the complex (Fig. 2 B).
Taken together, these data demonstrate that the hSWI/
SNF complex is distributed among different compartments of the nucleus. The existence of several hSWI/SNF complexes with distinct subunit composition (Wang et al.,
1996a
) opens the possibility that nuclear matrix-associated and nonassociated complexes may have a partially
different subunit composition.
-hBRM and
-BRG1 antibodies in indirect immunofluorescence analysis of the nuclear material remaining after in situ sequential DNase I and high
salt extraction. As shown in Fig. 3, the labeling pattern was
similar for both proteins before and after extraction, but the intensity of the signal decreased in extracted nuclei. As expected, the DAPI signal disappeared completely in the
nuclear matrix preparations (Fig. 3 B).
-lamin B antibodies gave a strong signal in the nuclear lamina and a much
weaker, diffuse signal in the nucleoplasm. The intensity of
the signal was similar in whole nuclei and in extracted nuclei; however, lamina of extracted nuclei appeared slightly
deformed or broken, probably as a result of the osmotic
shock occurring during the extraction procedure (Fig. 3 B).
Fig. 3.
In situ extraction of nuclear
matrix. (A) Immunofluorescent
staining of nonextracted HeLa cells
with -BRG1,
-hBRM, and
-lamin B antibodies. (B) Immunofluorescent staining pattern of in situ prepared nuclear matrices with
-BRG1,
-hBRM, and
-lamin B antibodies. Microscopy and photography
parameters were standardized for
all of the images. Bar, 10 µm.
[View Larger Version of this Image (44K GIF file)]
; Rose and Garrard, 1984
). After nuclease treatment of HeLa cell nuclei for 1, 2, or 4 min and centrifugation, the supernatant fraction S1 contained between 1% and 8% of the total cellular DNA. The
pellet was then resuspended in 2 mM EDTA, recentrifuged, and separated into a second supernatant fraction S2
and a pellet P, which contained ~80% and 15% of the total DNA, respectively. As shown by DNA analysis in agarose gel, the S1 and S2 fractions represent differences in
the nuclease accessibility of chromatin (Fig. 4 A). Fraction S1 is mainly composed of mononucleosomal-sized DNA
fragments, whereas the S2 fraction contained a typical nucleosomal ladder of DNA fragments. The P fraction contained heterogeneous-sized DNA that remained bound to
the nuclear scaffold after the fractionation. This fraction
has also been called insoluble chromatin (Xu et al., 1986
).
It has been shown that S1 and P fractions are enriched in
transcriptionally active DNA, whereas fraction S2 is depleted of transcribed sequences (Rose and Garrard, 1984
).
Aliquots of S1, S2, and P fractions were subjected to SDSPAGE followed by electrotransfer to nitrocellulose membranes and by immunoblot analysis. As shown in Fig. 4 B,
BRG1, hBRM, and hSNF5 proteins were enriched in fractions S1 and P with respect to fraction S2. This enrichment
appears to be higher for hBRM and hSNF5 than for BRG1 (around two- to threefold for BRG1, 10-15-fold for
hBRM, and 20-30-fold for SNF5). Since fraction S2 contained the major part of the DNA, abundance of the
hSWI/SNF proteins including BRG1, relative to DNA,
was very low in this fraction. These data suggest that the
hSWI/SNF complex is mostly concentrated in regions highly sensitive to micrococcal nuclease and in the fraction
of the transcriptionally active chromatin that remains
bound to the nuclear pellet after digestion. On the contrary, RNAP II was only found in fraction P, consistent
with reports that demonstrate that transcriptional activity
is associated with an insoluble phase of the nucleus (Jackson and Cook, 1985
). Although at first view contradictory,
this result is compatible with the fact that RNAP II was
found in the soluble fraction in the experiments described in Fig. 2. RNAP II is extractable from the nucleus with the
high salt concentration used in the nuclear matrix isolation
protocol, but not with the low ionic strength buffers used
in the chromatin fractionation protocol.
Fig. 4.
Active chromatin is enriched in hSWI/SNF components. 107 nuclei were subjected to partial digestion by micrococcal nuclease for the indicated times and separated into supernatant (S1) and pellet. The pellet was extracted with EDTA and
centrifuged to yield supernatant (S2) and pellet (P) chromatin
fractions. (A) DNA from each fraction was electrophoresed in 1%
agarose gels and stained with ethidium bromide. M, 100-bp standards. (B) An equivalent volume of each fraction was subjected to
SDS-PAGE and immunoblotted with -BRG1,
-hBRM,
-SNF5,
and pol 3/3 (anti-RNAP II-LS) antibodies.
[View Larger Version of this Image (43K GIF file)]
). To determine more accurately the
moment at which phosphorylation occurs and to pinpoint whether a correlation exists between the nature of the nuclear association of the hSWI/SNF complex and the position in the cell cycle, we have fractionated nuclei of HeLa
cells synchronized at various stages of the cycle. Exponentially growing HeLa cells were blocked with thymidine
(S-phase arrest) for 40 h, and then released from the
block. Flow cytometry analysis revealed that after 12 h
~95% of the cells contained a 4 N chromosomal content (Fig. 5 A). However, only ~15% of the cells had entered
mitosis, as determined by phase-contrast microscopy. At
that time, nocodazole was added to the medium to block
the cells in mitosis. Samples were taken at different times
and total extracts were prepared. Alternatively, cells were
subjected to the DNase I-high salt fractionation protocol
described above. As shown in Fig. 5 B, both BRG1 and hBRM were phosphorylated at the time when cells entered mitosis but not in S and G2 phases. Both BRG1 and
hBRM remained associated with the nuclear matrix during G1, S, and G2 phases (Fig. 5 C). However, all of the
signal appeared in the cytoplasmic fraction in mitotic cells,
consistent with the breakdown of the nuclear structure at
mitosis and the exclusion of hBRM and BRG1 from the condensed chromatin as previously published (Muchardt
et al., 1996
).
Fig. 5.
Association of BRG1 and hBRM with the nuclear matrix in synchronized HeLa cells. (A) HeLa Cells were synchronized by
treatment with thymidine for 40 h. After release of the block (t = 0), samples were taken at the indicated time for flow cytometry analysis. 12 h later nocodazole was added at 0.1 µg/ml final concentration. (B) Synchronized cells were taken at the indicated time and total extracts were prepared. Equal quantities of protein were subjected to SDS-PAGE in 5% acrylamide gels and immunoblotted with -BRG1 and
-hBRM antibodies. Phosphorylated and unphosphorylated BRG1 and hBRM are indicated. (C) Synchronized cells were taken at
the indicated time and fractionated as described in Fig. 2. Cytoplasmic (Cy), chromatin (Chr), and nuclear matrix (NM) fractions were electrophoresed in 5% acrylamide gels and immunoblotted with
-BRG1 and
-hBRM antibodies.
[View Larger Version of this Image (36K GIF file)]
). BRG1
and hBRM are phosphorylated very late in G2 phase or at
the beginning of mitosis, coinciding with their exclusion
from the condensed chromatin. Therefore, we tested if incubation of isolated HeLa nuclei with mitotic cell extracts
in the presence of ATP would release BRG1 and hBRM
from the nuclei. As a control, nuclei were also incubated
with ATP in the absence of mitotic cell extract or without
ATP. Surprisingly, release of BRG1 and hBRM from the
nucleus depended only on the presence of ATP but not on
the presence of mitotic extract (data not shown). We therefore investigated the ATP-dependent release of hBRM
and BRG1 from the nucleus using immunofluorescence.
HeLa cells grown on coverslips were permeabilized in isotonic buffer supplemented with 0.5% Triton X-100,
washed, and then incubated for 1 h in the presence or absence of 3 mM ATP before fixation with paraformaldehyde. Immunofluorescent staining of these cells, using
-BRG1,
-hBRM, or
-lamin B antibodies, revealed that
BRG1 and hBRM, but not lamin B, were released from
the nuclei of the ATP-treated cells (Fig. 6). The release of
hBRM after incubation of nuclei with ATP could also be
followed by immunoblotting (Fig. 7), demonstrating that
hBRM was not degraded. Incubation of the nuclei with
nonhydrolyzable ATP analogues like AMP-PCP or ATP
S had essentially no effect on the release of hBRM from the
nucleus (Fig. 7 A). In addition, the presence of ATP
S together with ATP decreased the quantity of released
hBRM (Fig. 7 A).
Fig. 6.
In situ, ATP-dependent release of BRG1 and hBRM from the nuclei. HeLa cells grown on coverslips were permeabilized with
CSK 0.5% Triton X-100 buffer and incubated in nuclear buffer with or without 3 mM ATP for 1 h at room temperature. Thereafter,
cells were washed with PBS, fixed with 3% paraformaldehyde, and incubated with the indicated antibodies. Bar, 10 µm.
[View Larger Version of this Image (44K GIF file)]
Fig. 7.
ATP-dependent release of hBRM from the nuclei requires a hydrolyzable form of ATP. (A) HeLa nuclei were incubated with
3 mM ATP or the same concentration of AMP-PCP or ATPS. After a 1-h incubation at 30°C, nuclei were pelleted, and proteins from
the supernatant (S) or the pellet (P) were electrophoresed and immunoblotted with
-hBRM antibody. (B) HeLa nuclei were incubated as
in A with the indicated kinase inhibitor at 0.1 mM final concentration, except in the case of cdc2 peptide that was used at 0.1 and 10 mM.
[View Larger Version of this Image (14K GIF file)]
); genistein, a tyrosine kinase inhibitor (Akiyama and Ogawara,
1991
); or a cdc2 peptide that competitively inhibits phosphorylation by cyclin-dependent kinases (Kemp and Pearson, 1991
). As shown in Fig. 7 B, genistein and a high concentration of the cdc2 peptide strongly inhibited the release
of hBRM from the nuclei (the same results were obtained
for BRG1), suggesting that phosphorylation by several
distinct protein kinases or by a cascade of activating kinases is involved in the release of BRG1 and hBRM from
the nuclear structure. However, ATP-released hBRM protein was not phosphorylated in the same way as in mitotic cells, as deduced by the absence of a change in its electrophoretic mobility (Fig. 7).
Discussion
), p53 (Jackson et al., 1994
), GR (van Steensel
et al., 1995b), or RNA polymerase II (van Driel et al.,
1995). In the case of GR, this punctate distribution has
been interpreted as evidence that this factor is present in
the nucleus in many hundreds of clusters of 10-100 receptor molecules each (van Steensel et al., 1995a). These clusters are distributed throughout the nucleoplasm and excluded from the nucleoli. Earlier studies have shown that
both hBRM and BRG1 proteins enhance transcriptional
activation by GR. It is attractive to speculate that those
genes that require the interplay of both GR and hSWI/
SNF complex are associated with domains that contain
both factors.
). However, this complex can be also
purified without any associated RNAP II holoenzyme
(Cairns et al., 1994
; Côté et al., 1994
). In addition, RNAP
II-free SWI/SNF complex functions in conjunction with
nucleosome-bound transcription factors to generate regions of nucleosome disruption (Owen-Hughes et al., 1996
).
Our double-immunolabeling experiments using
-BRG1
and
-hBRM antibodies and two antibodies that recognize
two subpopulations of RNAP II did not reveal strong colocalization between the hSWI/SNF complex and RNAP II
(Fig. 1). We cannot rule out the possibility that a fraction of
the hSWI/SNF complex interacts with a fraction of RNAP II
holoenzyme. However, our experiments indicate that a
large fraction of RNAP II is not associated with the majority of the hSWI/SNF complex. This result suggests that the
hSWI/SNF complex can be targeted to particular regions
by interactions with specific transcription factors or DNA
sequences without requiring interaction with RNAP II.
). These regions are distributed
throughout the genome and organize the chromatin in loops
of variable size. Numerous experiments extend this notion, suggesting a functional role of SARs in gene expression. SARs are frequently observed in close association
with enhancer elements. In flanking positions, SARs confer elevated and position-independent expression of genes
in homologous as well as heterologous systems (Laemmli
et al., 1992
). How SARs activate transcription is not clear;
however, it has been suggested that it may relate to changes in chromatin structure, affected by factors that bind to
them. Studies by Forrester et al. (1994)
indicate that the
IgH locus becomes remodeled and DNase I hypersensitive
at the pre-B cell stage, and that the Eµ SARs are necessary for this event (Jenuwein et al., 1997
). In a number of
cases, SARs have been found at the boundaries of chromatin domains as defined by the level of general DNase I
sensitivity (Loc and Strätling, 1988
; Levy-Wilson and Fortier, 1990). Taken together, all these data suggest that
SARs and/or their associated proteins are involved in
chromatin remodeling activity. Our experiments clearly
demonstrate that ~50% of BRG1 and hBRM and a slightly
lower percentage of hSNF5 proteins are strongly associated with the nuclear matrix, suggesting that a fraction of
the hSWI/SNF complex is attached to this nuclear structure. There are several well-characterized SAR binding
proteins. One of these proteins called Bright binds to
SARs placed proximal to the heavy chain enhancer Eµ of
the IgH gene (Herrscher et al., 1995
). Bright binds to the
minor grove of DNA through a DNA binding domain that
shows a significant sequence identity with the yeast SWI1
protein, a component of the yeast SWI/SNF complex
(Herrscher et al., 1995
). An homologous domain has also
been identified in other SAR binding proteins. Furthermore, a DNA minor grove binding activity has been recently reported for the yeast SWI/SNF complex (Quinn
et al., 1996
). Cross-linking experiments suggest that SWI1 is the protein responsible for this binding activity. It is unknown if a homologue of SWI1 exists in the human SWI/
SNF complex. However, our results demonstrate that hSWI/
SNF components are present in scaffold preparations, suggesting that the hSWI/SNF complex could contain a SAR
binding protein. An attractive hypothesis is that a fraction
of the hSWI/SNF complex may contain a protein homologous to SWI1 or Bright that can bind SARs. This SARbound hSWI/SNF complex could be responsible for the
chromatin remodeling activity associated with SAR elements. Recently, it has been demonstrated that multiple
forms of hSWI/SNF complexes exist, with different subunit composition, in the same cell, as well as different complexes in different cell types (Wang et al., 1996a
). Our data
suggest the existence of two subpopulations of the hSWI/
SNF complex, one associated with the nuclear matrix and
another not associated with this nuclear structure.
).
These data agree with our immunolocalization experiments,
showing that BRG1 and hBRM are excluded from heterochromatin. In the fractionation procedure, RNAP II was
found almost exclusively in the P fraction, suggesting that
DNA sequences found in this fraction are being actively
transcribed. We should outline that, even though fraction
S1 was shown to contain DNA from actively transcribed
genes, it lacks RNAP II. Easily solubilized mononucleosomes may originate from regions with open chromatin
that are not being transcribed, like enhancers, or from regions in transcribed templates that precede or follow the
actively transcribing RNAP II. Our results suggest that the
hSWI/SNF complex is associated in vivo with regions of
open chromatin where RNAP II is not present, as well as
with DNA segments directly bound by RNAP II. Taken
together, our subnuclear fractionation studies clearly demonstrate that components of the hSWI/SNF complexes may be associated with several distinct steps in gene activation. We can speculate that it may participate in SAR or
MAR function, global chromatin remodeling during gene
activation, and perhaps the transcription initiation process
itself. Further studies will be important to prove our hypothesis and to clarify the exact biochemical role of the
hSWI/SNF complex in transcription control.
). There is also evidence of
both casein kinase and tyrosine kinase activity associated
with the nuclear matrix (Ohmuda et al., 1986; Tawfic and
Ahmed, 1994
). Since both tyrosine kinases and serine- and
threonine-phosphorylating kinases seem to be implicated,
it is possible that ATP-dependent release of hSWI/SNF
complex from its nuclear targets is a consequence of a cascade of kinase activities. It is also possible that this cascade is
involved in the normal cell cycle regulation of the nuclear
structure and may not be specific for the SWI/SNF complex.
Received for publication 18 November 1996 and in revised form 6 February 1997.
J.C. Reyes was the recipient of European Molecular Biology Organization and Human Frontier Science Program Organization postdoctoral fellowships. The work was supported by Association pour la Recherche sur le Cancer, Ligue Nationale Française Contre le Cancer, and the Actions Concertées des Sciences du Vivant program of the French Ministry of Science.We are grateful to O. Bensaude for pol 3/3 antibodies and valuable discussion of the manuscript. We thank M. Vincent, J.C. Courvalin, and D. Lallemand for cc-3, anti-lamin B, and anti-JunB antibodies, respectively. We are grateful to R. Hellio for performing confocal microscopy, and to J. Weitzman for critical reading of the manuscript.
CTD, carboxy-terminal domain;
DAPI, 4,6-diamidino-2-phenylindole;
GR, glucocorticoid receptor;
LIS, 3,5-diiodosalicilic acid, lithium salt;
MAR, matrix-associated region;
SAR, scaffold-associated region;
Rb, retinoblastoma;
RNAP II, RNA polymerase II.