Cyclin E Associates with BAF155 and BRG1, Components of the Mammalian SWI-SNF Complex, and Alters the Ability of BRG1 To Induce Growth Arrest

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Shanahan, F.
	Articles by Lees, E.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Shanahan, F.
	Articles by Lees, E.

Molecular and Cellular Biology, February 1999, p. 1460-1469, Vol. 19, No. 2
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Cyclin E Associates with BAF155 and BRG1, Components of the Mammalian SWI-SNF Complex, and Alters the Ability of BRG1 To Induce Growth Arrest

Frances Shanahan, Wolfgang Seghezzi, David Parry, Daniel Mahony, and Emma Lees^*

Cell Signaling Department, DNAX Research Institute, Palo Alto, California 94304

Received 9 September 1998/Returned for modification 16 October 1998/Accepted 7 November 1998

	ABSTRACT

Top Abstract Introduction Materials and methods Results Discussion References

SWI-SNF complexes have been implicated in transcriptional regulation by chromatin remodeling. We have identified an interactionbetween two components of the mammalian SWI-SNF complex and cyclinE, an essential cell cycle regulatory protein required for G₁/Stransition. BRG1 and BAF155, mammalian homologs of yeast SWI2and SWI3, respectively, are found in cyclin E complexes and arephosphorylated by cyclin E-associated kinase activity. In thisreport, we show that overexpression of BRG1 causes growth arrestand induction of senescence-associated $beta$ -galactosidase activity,which can be overcome by cyclin E. Our results suggest that cyclinE may modulate the activity of the SWI-SNF apparatus to maintainthe chromatin in a transcriptionally permissivestate.

	INTRODUCTION

Top Abstract Introduction Materials and methods Results Discussion References

Progression through the cell cycle is a tightly controlled process requiring many critical regulatory proteins (reviewed inreference 47). The cyclin-dependent kinases (cdks) and theirregulatory cyclin subunits promote passage through each phaseof the cell division cycle. The activation of cyclin-cdk complexesis strictly regulated both at the level of protein synthesis anddestruction and by posttranslational modifications to dictateprecisely when in the cell cycle each complex becomes active (28,36).

Cyclin E is synthesized during the G₁ phase of the cell cycle and binds cdk2 to become maximally active at the G₁/S boundary(10, 26). Cyclin E-cdk2 complexes have been shown to playan essential and rate-limiting role in the transition betweenG₁ and S phase (40, 44, 52, 53). The manner in which cyclinE-cdk2 promotes S-phase entry remains poorly defined, since fewdownstream effectors of cyclin E-cdk2 are known. One potentialsubstrate is the protein product of the retinoblastoma tumor suppressorgene, pRb, which is also phosphorylated by the D-type cyclin-cdkcomplexes (9, 13, 24). However, unlike cyclin D, cyclinE remains essential in the absence of pRb, illustrating a fundamentaldifference between these two complexes and strongly suggestingthat other key rate-limiting substrates exist for cyclin E-cdk2(1, 33). Other targets identified more recently include SAP155,a component of the pre-mRNA splicing apparatus (46), and NPAT(58). The role of such molecules in modulating cell cycle progressionhas yet to beestablished.

SWI-SNF complexes are evolutionarily conserved and have been implicated in transcriptional regulation through remodeling ofchromatin structure (reviewed in references 5 and 42). Componentsof the SWI-SNF apparatus are believed to bind to chromatin andrelieve nucleosome-mediated repression of transcription, thusproviding access to transcriptional activators (7, 21, 27,31, 42, 45). While SWI-SNF complexes are nonessential inyeast, a second related complex, RSC, is required for yeast cellgrowth (3, 4, 32). In mammalian cells, SWI-SNF complexeshave been implicated in hormone receptor activation and growthcontrol (6, 11, 25, 39, 49). The ability of SWI-SNFcomplexes to regulate cell growth is believed to be mediated throughthe interaction of the human homologs of the SWI2-SNF2 protein(BRG1 and hBRM) with pRb (11, 49, 51). The mechanism bywhich pRb modulates BRG1 function is not known. Other modes ofregulation impinging on SWI-SNF functions probably exist, butthey have not been well characterized. SWI-SNF complexes havebeen identified with variable subunit compositions (57), andthe phosphorylation states of some components of SWI-SNF complexesare altered in a cell cycle-dependent fashion (37).

To further elucidate the role of cyclin E-cdk2 in growth control and in cell cycle transitions, we looked for novel proteinsthat associate with cyclin E within the cell. By immunoprecipitationanalysis of various cell lines using antibodies against cyclinE, we identified the presence of two components of the SWI-SNFapparatus, BAF155 and BRG1. This interaction would appear to befunctionally significant, because cyclin E can abrogate the abilityof BRG1 to induce growtharrest.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and methods Results Discussion References

Cell lines. SW13, C33A, 293, and SAOS-2 cells were grown as monolayers, and ML-1 cells were grown as suspension cultures in Dulbecco'smodified Eagle medium (DMEM) supplemented with 10% heat-inactivatedfetal calf serum (FCS) and nonessential amino acids. All celllines were obtained from the American Type CultureCollection.

Antibodies. Antibodies to cyclins D1, D2, and D3 and cdc2, cdk2, and cdk6 were raised against C-terminal peptides. Antibodies againstp27 and hBRM were purchased from Transduction Labs. Antibodiesagainst p107, p130, E2F4, and cdc25A were obtained from SantaCruz Biotech. Antibodies to SAP155 are described elsewhere (46).HE antibodies were raised against full-length cyclin E: the HE172epitope comprises amino acids (aa) 386 to 396, and the HE67 epitopecomprises aa 366 to 381. Polyclonal antibodies against BAF155were raised against a glutathione S-transferase (GST) fusion proteincarrying aa 751 to 1105. The same antigen was used to generatemonoclonal antibodies to BAF155 in BALB/c mice according to standardprotocols (17), Ini1 antibodies were raised against C-terminalpeptide aa residues 369 to 386. BRG1 antibodies were raised againstan N-terminal GST fusion protein (residues 1 to 700). The anti-BRG1antibody, J1, used for immunofluorescence was a kind gift of G.Crabtree (25).

Immunoprecipitations. Cells were lysed in lysis buffer containing 5 mM HEPES (pH 7.0), 250 mM NaCl, 0.1% Nonidet P-40 (NP-40) plus protease inhibitors(Complete EDTA-free tablets, protease inhibitor cocktail; BoehringerMannheim). Immunoprecipitations and kinase assays were performedaccording to standard protocols (17). For metabolic labeling,cells were starved for methionine by incubation in methionine-freeDMEM (Gibco) for 30 min and subsequently labeled for 4 h with100 µCi of [³⁵S]methionine per ml. Two washes with ice-cold phosphate-bufferedsaline (PBS) were performed before celllysis.

Covalent coupling of antibodies to protein A-Sepharose (Pharmacia) was performed with dimethyl pimelimidate (Pierce) accordingto the manufacturer's instructions. The preparation of large-scaleimmunoprecipitations for the purification and sequencing of polypeptidesis described elsewhere (46). All peptide sequencing was performedby W. Lane, Harvard Microchemistry Laboratory. Preclearing experimentswere performed by three sequential rounds of antibody incubationand capture on protein A-Sepharose beads. Lysates were then spunthrough filters (Costar) to remove residual beads prior toimmunoprecipitation.

Immunoblots. For immunoblotting, samples were transferred to an Immobilon polyvinylidene difluoride membrane (Millipore) by Western blottingat 60 V for 6 h at 4°C. After transfer was complete, the membraneswere blocked in TNT (10 mM Tris, 150 mM NaCl, 0.2% [vol/vol] Tween20) containing 5% milk for 30 min at room temperature. The filterswere probed with primary antibodies diluted to 2 µg/ml in 5% milk-TNTand incubated on a shaker for 1 h at room temperature. The filterswere washed in TNT at room temperature four times for 15 min eachtime and probed with horseradish peroxidase-conjugated anti-rabbitor anti-mouse antibody (Amersham) diluted 1:5,000 in 5% milk-TNTand incubated on a shaker at room temperature for 1 h. The filterswere washed as before and detected by enhanced chemiluminescence(ECL;Amersham).

Transfections. For transient transfections, SW13 cells were transfected with 6 µg of total plasmid DNA, including 1 µg of pHook-1 plasmid(Invitrogen), 2 µg of pBJ5.BRG or pBJ5.BRG K798R (25), and 3µg of cytomegalovirus (CMV) cyclin E (29) as indicated. pBSK(Stratagene) was used as the carrier. Fifteen dishes (100 by 20mm) were transfected for each experiment with 25 µl of Lipofectaminereagent (Life Technologies, Inc.). The cells were incubated for3 h at 37°C in a CO₂ incubator. After the incubation, 5 ml ofDMEM containing 20% serum and antibiotics was added. The mediumwas replaced with fresh complete medium 18 to 24 h after transfection.Cells were harvested with the Capture-Tec kit (Invitrogen) 72h after transfection according to the manufacturer's instructions.After harvesting, the cells were pelleted and lysed in lysis bufferforimmunoprecipitation.

For stable transfections, SW13 cells were transfected as described above with 6 µg of total plasmid DNA, including 2 µg ofpBJ5.BRG1 or pBJ5.BRG1-K798R and 3 µg of CMV cyclin E or othercyclins as indicated. pBSK was used as the carrier. Forty-eighthours posttransfection, cells were trypsinized and counted, and10⁷ cells were replated in the presence of puromycin (Sigma) at 2µg/ml of complete medium for 10days.

Crystal violet staining. SW13 cells were transfected as described above and selected with puromycin. After 10 days of selection, cells were rinsedtwice with 5 ml of PBS and fixed overnight in methanol. The methanolwas removed, and the cells were stained in crystal violet solution(2% crystal violet in 20% methanol) for 5 h. The plates were rinsedwith water until the background plastic was clear. The plateswere inverted and dried overnight at roomtemperature.

BrdU staining. Transfected SW13 cells were split into two six-well Falcon dishes 48 h after transfection. Puromycin selection of transfectedcells was started on the following day (2 µg/ml of complete medium)and continued for 10 days. Cells were labeled with bromodeoxyuridine(BrdU) labeling reagent supplied in the Amersham cell proliferationkit; the labeling reagent was diluted 1:1,000 in complete medium.Cells were labeled for 18 h at 37°C in a CO₂ incubator, washedbriefly in PBS, and fixed in acid-ethanol (90% ethanol-5% aceticacid-5% water) for 30 min at room temperature. The cells werestained according to the manufacturer's instructions. Cells werephotographed at a magnification of ×40 on a Nikon Diaphot 300microscope.

SA $beta$ -galactosidase staining. SW13 cells were transfected as for BrdU staining and selected with puromycin. After 10 days of selection, cells were stainedfor senescence-associated (SA) $beta$ -galactosidase activity as previouslydescribed (8).

Immunofluorescence. Cells were fixed in ice-cold methanol for 3 min at $-$ 20°C, washed in PBS, and then incubated in 0.5% NP-40-PBS for 5 min atroom temperature. Following a PBS wash, samples were blocked for1 h at room temperature in 10% normal sheep serum-0.5% Tween 20in PBS and then incubated with primary antibody in PBS-0.5% Tween20 (J1 [5 µg/ml]) for 1 h at room temperature. Secondary antibody(Texas red-coupled sheep anti-rabbit [Amersham]) was used at a1:200 dilution in PBS-0.5% Tween 20, and then the mixture wasincubated for 1 h at room temperature. Samples were mounted with4',6-diamidino-2-phenylindole (DAPI)-containing mounting medium(Vectshield; Vector Laboratories), and signals were detected byfluorescence microscopy (Axioskop; Zeiss) at ×40magnification.

	RESULTS

Top Abstract Introduction Materials and methods Results Discussion References

Cyclin E-associated proteins. Immunoprecipitations of cyclin E were performed from [³⁵S]methionine-labeled ML-1 cells by using a cyclin E-specific monoclonalantibody, HE172. By using this approach, we were able to identifya number of proteins specifically coprecipitating with cyclinE (Fig. 1A). Cyclin A immunoprecipitations were performed forcomparison, and PAb419 immunoprecipitates were included as a negativecontrol. The coprecipitating molecules included proteins previouslyestablished to interact with cyclin E, such as cdk2 and the pRb-relatedproteins p107 and p130 (Fig. 1A, lane 2), which were also presentin cyclin A immunoprecipitates (Fig. 1A, lane 3) (12, 14,29). The presence of additional proteins known to associatewith cyclin E was examined by immunoblot analysis (Fig. 1B). CyclinE was immunoprecipitated from ML-1 cell lysates, and the resultingimmune complexes were resolved by sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE) and then immunoblotted with antibodiesagainst a variety of proteins. As shown in Fig. 1B, cyclin E immunecomplexes from ML-1 cells contained SAP155 (46, 55), p130,p107, cdc25A (19, 22), E2F 4 (16), p27 (43), and cdk2but not cdc2. Immunoprecipitations with a negative control antibodydid not precipitate these proteins. These results demonstratethat cyclin E associates with several known cellular proteinsand that complexes containing these proteins can be recognizedby antibodies to cyclin E.

View larger version (55K):
[in this window]
[in a new window]

FIG. 1. Association of cyclin E with cellular proteins. (A) Immunoprecipitations were performed with cyclin E monoclonal antibody (HE172), cyclin A (cycA) (BF683), or a negative control antibody (PAb419) as indicated from [³⁵S]methionine metabolically labeled ML-1 cell lysates. (B) Cyclin E (HE172)- or control antibody (PAb419)-cross-linked beads were used to immunoprecipitate protein complexes from 1 mg of ML-1 extract. Polypeptides were separated by SDS-PAGE and analyzed by immunoblotting with antibiotics as indicated. One hundred micrograms of ML-1 extract was included as a positive control. (C) Immunoprecipitations were performed with cyclin E monoclonal antibody (HE172), cyclin A (BF683), or negative control antibody (PAb419) as indicated from ML-1 cells. Immunocomplexes were subjected to an in vitro kinase assay with 5 µCi of [ $gamma$ -³²P]ATP before separation by SDS-PAGE and autoradiography. (D) Immunoprecipitations were performed as described above from ML-1 cells metabolically labelled with 2 mCi of ³²P_ir/ml for 30 min. The identities of associated molecules are as indicated; asterisks denote unknown proteins.

Several novel proteins were also identified in the cyclin E immunoprecipitations, including two proteins with sizes of approximately150 and 200 kDa (marked p150* and p200*, respectively, in Fig.1A, lane 2). These molecules were not recognized under denaturingconditions, confirming that they were associated proteins andwere not directly recognized by the antibody (data not shown andreference 46). To determine whether these proteins could serveas substrates for cyclin E-cdk2, we tested whether they couldbe phosphorylated in kinase assays in vitro and whether they existedas phosphoproteins in vivo. Immunoprecipitations were performedwith lysates prepared from ML-1 cells by using antibodies againstcyclin E and cyclin A and with PAb419 as a negative control. Immunecomplexes were then subjected to in vitro kinase assays. Phosphorylatedproteins were resolved by SDS-PAGE and visualized by autoradiography.A subset of the cyclin E-associated proteins served as substratesfor cyclin E-cdk2, including p107, p130, and the novel proteinsp150 and p200 (Fig. 1C, lane 2). Cyclin A-associated kinase activitycould also phosphorylate p107 and p130 but did not associate withor phosphorylate either p150 or p200 (Fig. 1C, lane 3). To studythe in vivo phosphorylation state of the various cyclin E-associatedproteins, ML-1 cells were labeled with ³²P_i. Lysates were prepared and immunoprecipitated with the sameantibodies as before. Both p150 and p200 were heavily phosphorylatedin the cyclin E immunoprecipitates (Fig. 1D, lane 2). As expected,p107 and p130 were also found phosphorylated in both cyclin Eand cyclin A immunoprecipitations, but not in control immunoprecipitations(Fig. 1D)

These experiments thus identified two novel phosphoproteins that specifically interacted with cyclin E and that were phosphorylatedby kinase activity associated with cyclin E-cdk2.

p150 is BAF155, a component of the mammalian SWI-SNF complex. To establish the identity of the cyclin E-associated phosphoprotein p150, large-scale cyclin E immunoprecipitations were performedwith 2 × 10⁹ ML-1 cells. Immune complexes were resolved by SDS-PAGE, and theprotein corresponding to p150 was excised from the gel for sequencing.Mass spectroscopic sequencing of tryptic peptides yielded fourpeptide sequences (Fig. 2A) which were contained in a previouslyisolated protein, BAF155 (Fig. 2B) (57). BAF155 is a mammalianhomolog of SWI3, a component of the yeast SWI-SNF complex (57).

View larger version (42K):
[in this window]
[in a new window]

FIG. 2. Cyclin E associates with BAF155. (A) Peptide sequences obtained from mass spectroscopic sequencing of p150. (B) Schematic representation of BAF155. Alignments of peptides to BAF155 are shown by solid bars. The shaded regions share sequence homology with yeast SWI3 (57). (C) A SalI-NotI fragment encoding full-length BAF155 in pSPORT (Invitrogen) was in vitro translated (ivt) with T7 RNA polymerase with the TNT kit (Promega). V8 partial proteolytic mapping of in vitro-translated BAF155 protein and p150 derived from cyclin E immunoprecipitation (cycE ip) was performed according to standard protocols (46). (D) One milligram of ML-1 cell lysate was immunoprecipitated with cyclin E monoclonal antibodies from the HE series (46). PAb419 was included as a negative control. Immunoprecipitates (IP) were analyzed by immunoblotting with antibodies against BAF155 and cdk2. (E) One milligram of ML-1 (lanes 1 to 4) or U2OS (lanes 5 to 9) cell lysate was immunoprecipitated with monoclonal antibodies against cyclin E (HE172), cyclin A (BF683), and cyclin B (GNS1) and polyclonal peptide antisera against cyclins D1, D2, and D3 as indicated. PAb419 and normal rabbit serum (NR) were included as negative controls. Immunoprecipitates were separated by SDS-PAGE and immunoblotted with antibodies against BAF155. cdc2, cdk2, or cdk6.

To confirm that the p150 seen in cyclin E immunoprecipitations was BAF155, we performed V8 proteolytic mapping with in vitro-translatedBAF155 (Fig. 2C, left panel) and p150 isolated from a cyclin Eimmunoprecipitation (Fig. 2C, right panel). Both proteins yieldedidentical profiles, confirming that the cyclin E-associated p150protein was BAF155. To further analyze the interaction betweencyclin E and BAF155, antisera were raised against BAF155 and usedin immunoblot analysis of cyclin E immunoprecipitates. Two monoclonalantibodies that recognize different epitopes of cyclin E, HE172and HE67 (46), could both coprecipitate BAF155 (Fig. 2D). Immunoprecipitationswith antibodies against cyclin A (Fig. 2E, lane 3), cyclin B1(lane 4), and the D-type cyclins (lanes 6 to 8) did not containdetectable BAF155 (Fig. 2E, upper panel), suggesting that associationwith BAF155 may be specific for cyclinE.

Cyclin E associates with several SWI-SNF components. The presence of BAF155 in cyclin E complexes raised the possibility that other components of the SWI-SNF complex may alsoassociate with cyclin E. The novel 200-kDa protein seen in thecyclin E immunoprecipitations (p200* [Fig. 1]) has a molecularmass similar to that of BRG1, a mammalian homolog of yeast SWI2/SNF2(25). BRG1 has DNA-dependent ATPase activity and is an integralcomponent of the SWI-SNFcomplex.

V8 partial proteolytic mapping of the 200-kDa protein in cyclin E immunoprecipitations (Fig. 3A, left panel) and in vitro-translatedBRG1 (Fig. 3A, right panel) showed that the two profiles weresimilar, hence identifying the cyclin E-associated p200 proteinas BRG1. A similar 200-kDa protein seen in BAF155 immunoprecipitationswas also confirmed to be BRG1 by V8 analysis (Fig. 3A, middlepanel), confirming previous observations that BAF155 and BRG1are associated in vivo (57). Immunoblot analysis with an antibodydeveloped against BRG1 confirmed the presence of BRG1 in cyclinE immunoprecipitations with the two different cyclin E monoclonalantibodies, HE172 and HE67 (Fig. 3B, upper panel).

View larger version (44K):
[in this window]
[in a new window]

FIG. 3. BRG1 is associated with the cyclin E-BAF155 complex. (A) V8 partial proteolytic mapping of in vitro-translated (ivt) BRG1 protein and p200 derived from cyclin E (cyc E) and BAF155 immunoprecipitations (ip). (B) Immunoblot analysis of cyclin E (HE172, HE67) or control (PAb419) immunoprecipitations from ML-1 cells with antibodies to BRG1 and Ini1 as indicated. One hundred micrograms of cell lysate was loaded as a positive control. (C) Immunoblot analysis of cyclin E (HE172) or control (PAb419) immunoprecipitations from ML-1 cells with antibodies to hBRM. One hundred micrograms of cell lysate was loaded as a positive control.

Another well-characterized component of the mammalian SWI-SNF complex, Ini1-hSNF5 (23), was clearly detectable in the cyclinE immunoprecipitations (Fig. 3B, lower panel). These data demonstratethat cyclin E associates with several subunits of the SWI-SNFapparatus present within a cell and suggest that the entire SWI-SNFcomplex may be involved. Gel filtration on Superose 6 demonstratedthat the cyclin E-BAF155-containing complexes eluted well aheadof the 699-kDa thyroglobulin marker at an estimated molecularmass of over 1 MDa, consistent with the size of the SWI-SNF complexes(data not shown and reference 56). These complexes representonly a fraction of the cyclin E present within the cells. Thesecomplexes appear to be relatively stable and are resistant tostringent washing conditions with salt concentrations of up to750 mM NaCl (data notshown).

In further analysis, we were able to demonstrate that the BRG1-related protein hBRM (39), which is believed to form distinctSWI-SNF complexes from BRG1 (56), also associates with cyclinE (Fig. 3C). This provides evidence that more than one SWI-SNFspecies may be recognized by cyclinE.

BRG1 promotes the association of cyclin E with BAF155. To study the interaction of cyclin E with SWI-SNF complexes in more detail, we examined several human cell lines, includingtwo that lack components of the SWI-SNF apparatus, SW13 and C33A.SW13 is a human carcinoma cell line derived from a tumor of theadrenal cortex, which does not express detectable levels of BRG1or hBRM (39). Although much of the SWI-SNF complex remains assembledin SW13 cells (56), and BAF155 is expressed (Fig. 4A, bottompanel), we were unable to detect any BAF155 associated with cyclinE (Fig. 4A). Experiments with C33A cells, a cervical carcinomacell line that also does not express hBRM (39) and only expresseslow levels of BRG1, revealed reduced levels of BAF155 found complexedwith cyclin E (Fig. 4A, lane 3, top panel). In contrast, in 293cells that express wild-type BRG1, coprecipitation of BAF155 withcyclin E was easily observed. These results inplied that expressionof BRG1 is required for the stable association of cyclin E withthe SWI-SNF complex.

View larger version (40K):
[in this window]
[in a new window]

FIG. 4. BRG1 is required for the interaction between cyclin E and BAF155. (A) Immunoblot analysis of cyclin E (HE172) or control (PAb419) immunoprecipitations from cell lines as indicated, probed with antibodies against BAF155 or cyclin E. Lysates were also probed directly for BAF155 expression (lower panel). (B) SW13 cells were transiently transfected with pHook-1 (Invitrogen) alone (lanes 3 and 4) or together with pBJ5.BRG1 (lanes 5 and 6), pBJ5.BRG1-K798R (lanes 7 and 8), and pBJ5.BRG1 plus pCMV-cyclin E (lanes 9 and 10) as indicated. Transfected cells were harvested with the Capture-Tec kit (Invitrogen) 72 h after transfection. Cyclin E (HE172) or control (PAb419) immunoprecipitations were performed from 100 µg of lysate and probed with antibodies to BAF155 (upper panel), BRG1 (middle panel), and cyclin E (lower panel). Untransfected SW13 (lanes 1 and 2) and ML-1 (lanes 11 and 12) cells were included as controls.

To test this hypothesis, we asked whether introduction of BRG1 into SW13 cells would restore the stable interaction betweencyclin E and BAF155. SW13 cells were transiently transfected withan expression construct for BRG1, together with a selectable cellsurface marker (pHook-1; Invitrogen). Seventy-two hours posttransfection,cells were harvested and positively selected for expression ofthe cotransfected cell surface marker. Lysates were prepared fromthe selected cells and immunoprecipitated with the cyclin E monoclonalantibody, HE172, or a negative control,PAb419.

Immunoprecipitates were resolved by SDS-PAGE and immunoblotted with BAF155 antisera (Fig. 4B, upper panel). Lysates from untransfectedSW13 and ML-1 cells were also immunoprecipitated to act as negativeand positive controls, respectively. Ectopic expression of BRG1was sufficient to facilitate the coprecipitation of BAF155 withcyclin E (Fig. 4B, compare lanes 4 and 6). The immunoblot wasreprobed with BRG1 antisera to demonstrate the presence of BRG1in this newly formed complex (Fig. 4B, middle panel) and withantibodies to cyclin E to show that the immunoprecipitations wereequally efficient at precipitating cyclin E (Fig. 4B, lower panel).The intrinsic ATPase activity of BRG1 was not required for thisassociation, because the catalytically inactive K798R mutant ofBRG1 (39) was also able to stimulate complex formation (Fig.4B, lane 8). Cotransfection with cyclin E did not increase theamount of cyclin E-BAF155 complexes over endogenous levels (Fig.4B, lane 10). These results demonstrate that the expression ofBRG1 facilitates the interaction of cyclin E with the SWI-SNFcomplex.

Cyclin E association with BRG1 does not require pRb family members. A possible explanation for the association seen between cyclin E and the SWI-SNF complex was that it was mediated by membersof the pRb family. Cyclin E binds stably to p107 and p130 (seeFig. 1 and reference 15), and since BRG1 can also interact withpRb, p107, and p130 (11, 49), it was possible that they wereall contained within the samecomplex.

As shown previously (Fig. 4A), cyclin E was associated with BAF155 in 293 cells that do not express functional pRb, suggestingthat pRb may not be an absolute requirement for the cyclin E-BAF155complex to form. To extend this analysis, we examined SAOS-2 cells,a pRb-negative human osteosarcoma cell line. Cell lysates wereprepared and immunoprecipitated with the cyclin E monoclonal antibody,HE172 (Fig. 5A, lane 1), or a control antibody, PAb419 (Fig. 5A,lane 2). Immunocomplexes were resolved by SDS-PAGE and immunoblottedwith antibodies to BAF155. As shown in Fig. 5A, the associationbetween cyclin E and BAF155 is easily detectable, confirming thatpRb is dispensable for this interaction. To determine whetherp107 or p130 was present in the complex, cell lysates were preclearedwith antibodies to p107 and p130 (Fig. 5A, lanes 4 and 6) or withnormal rabbit serum as a negative control (Fig. 5A, lanes 3 and5) prior to immunoprecipitation. Significantly, depletion of p107and p130 did not reduce the amount of BAF155 bound to cyclin E(Fig. 5A, lane 6). Precleared lysates were immunoblotted withantibodies to p107, p130, and pRb to verify the depletion of allthree proteins from these extracts (Fig. 5B). As expected, examinationof cyclin E levels demonstrated that depletion of p107 and p130led to a reduction of cyclin E levels in the SAOS-2 cell lysate(Fig. 5B, top panel), since cyclin E is found in stable complexeswith p107 and p130 (29). Our findings therefore suggest thatonly a proportion of the cyclin E in the cell is bound to p107and p130 and that the SWI-SNF-containing cyclin E complex is likelyto be a novel and distinct complex that does not require pRb proteinsfor its assembly.

View larger version (16K):
[in this window]
[in a new window]

FIG. 5. Association of cyclin E with SWI-SNF complex does not require the presence of pRb family member proteins. (A) Immunoblot analysis of cyclin E (HE172 [lane 1]) or control (PAb419 [lane 2]) immunoprecipitations (IP) from SAOS-2 cells. In lanes 3 to 6, lysates were precleared prior to immunoprecipitation with antibodies to p107 and p130 (lanes 4 and 6) or normal rabbit (NR) serum (lanes 3 and 5). ML-1 lysate was run as a positive control in lane 7. Blots were probed with antibodies against BAF155. (B) Extracts (100 µg) from lysates precleared with normal rabbit serum or p107 and p130 were immunoblotted with antibodies as indicated.

BRG1 induces cell cycle arrest. To address the functional significance of cyclin E's interaction with the SWI-SNF complex, we examined the properties of BRG1by using an assay that has previously been described for the analysisof BRG1 function (11, 49). When overexpressed in SW13 cells,BRG1 induces a change in cell morphology. We were interested inseeing whether we could influence the ability of BRG1 to inducesuch a flat-cell phenotype by the coexpression of cyclin E. SW13cells were cotransfected with BRG1 and a puromycin resistanceplasmid. Cells were grown under puromycin selection for 10 daysand then stained with crystal violet, and flat cells were counted.As expected, transfection of BRG1 induced a flat-cell phenotypein a percentage of the cells (Fig. 6B and Table 1). Immunostainingwith anti-BRG1 sera demonstrated that BRG1 was expressed in theflat-cell population and not in adjacent normal cells (Fig. 6E).To ascertain whether these flat cells were still proliferating,drug-selected cells were labeled with BrdU. BRG1-expressing flatcells failed to stain with BrdU, even with 18- to 24-h labelingtimes, while adjacent growing colonies readily incorporated BrdU(Fig. 6G), indicating that the flat cells were growth arrested.The morphological changes we observed are often associated withcellular senescence. To investigate this phenomenon further, weassayed for SA $beta$ -galactosidase activity (8). As shown in Fig.6H, all of the flat cells stained positive for SA $beta$ -galactosidaseactivity, indicative of replicative senescence. Thus, introductionof BRG1 into SW13 cells was sufficient to induce growth arrestand markers of senescence.

View larger version (48K):
[in this window]
[in a new window]

FIG. 6. BRG1 induces growth arrest. SW13 cells were transfected as described in Materials and Methods with 6 µg of total plasmid DNA, including 2 µg of pBJ5.BRG1. pBSK was used as the carrier. Cells were grown in the presence of puromycin for 10 days. Cells were then either fixed and stained with 2% crystal violet-20% methanol for 5 h (original magnification, ×40 [A and B]), fixed and stained with normal rabbit serum and counterstained with DAPI (original magnification, ×40) [C and D]), fixed and stained with BRG1 antibody (J1) (25) and counterstained with DAPI (original magnification, ×40 [E and F]), labelled with BrdU (original magnification, ×20 [G]), or stained for SA $beta$ -galactosidase activity as previously described (8) (original magnification, ×40 [H]).

View this table:
[in this window]
[in a new window]

TABLE 1. BRG1 induction of flat-cell morphology in SW13 cells

Cyclin rescue of flat-cell phenotype and prevention of growth arrest. We next tested whether cyclin E could suppress the ability of BRG1 to induce the flat-cell phenotype. SW13 cells were cotransfectedwith cyclin E and BRG1 and were then grown under puromycin selectionfor 10 days as before. The coexpression of cyclin E with BRG1significantly reduced the frequency of flat cells by up to 50%(Table 1). The levels of BRG1 expression were not affected bythe presence of cyclin E (Fig. 4B, compare lanes 6 and 10). Introductionof the ATP-binding mutant of BRG1, K798R, induced flat cells atonly 32% of the frequency of wild-type BRG1 (11). However, thisvalue was further reduced by the overexpression of cyclin E, suggestingthat cyclin E affects an ATP-independent function of BRG1. Wenext examined whether other cyclins shared the ability with cyclinE to abrogate flat-cell production by BRG1. Cotransfection ofcyclin D1 could also reduce flat-cell induction by BRG1 to a similardegree (52%). Cyclin A showed toxicity in this assay and was notevaluated further. The abilities to abrogate BRG1-induced growtharrest in this assay were therefore comparable between cyclinE and cyclin D1, although the stable association of cyclin E,but not cyclin D1, with the SWI-SNF complex suggests that cyclinE may be the more physiologically relevanteffector.

	DISCUSSION

Top Abstract Introduction Materials and methods Results Discussion References

Analysis of cyclin E-containing complexes in the cell demonstrated that cyclin E associated with several cellular proteins.These include its kinase partner, cdk2, and molecules that affectthe activity of cyclin E-cdk2 complexes both positively (cdc25A)and negatively (p27). In addition, this approach has previouslyyielded the identification of novel substrates, including bothp107 and p130, suggesting that cdks can form stable enzyme-substratecomplexes in vivo. This stable interaction may provide a mechanismby which increased specificity and selectivity can beachieved.

In this study, we have characterized two novel cyclin E-associated proteins as components of the mammalian SWI-SNF complex.Both BAF155 and BRG1 contain cdk consensus phosphorylation sites,and both could be phosphorylated by cyclin E-cdk2-associated kinaseactivity in vitro. Furthermore, BRG1 and BAF155 are in a phosphorylatedform in the cyclin E complex. Another component of the SWI-SNFapparatus, the Ini1-hSNF5 protein, is also present in cyclin Eimmunoprecipitations, which suggests that the entire SWI-SNF complexmay be recognized by cyclin E. Our experiments further demonstratean intriguing requirement for the presence of BRG1 in the SWI-SNFcomplex to promote the recruitment of cyclin E. This observationsuggests that either BRG1 recruits some essential factor to thecomplex, or the SWI-SNF apparatus is somehow modified in the presenceof BRG1 so that it is recognized by cyclin E. The presence ofthe BRG1-related molecule hBRM in cyclin E immunoprecipitationsimplies that at least two different SWI-SNF complexes may be targetedby cyclin E, since hBRM and BRG1 are believed to be mutually exclusivecomponents of the SWI-SNF apparatus (56). Immunodepletion experimentssuggest that the cyclin E-BAF155-BRG1 complex is distinct fromthose cyclin E complexes containing p107 and p130 and that neitherpRb nor its related family members p107 and p130 are needed forcyclin E-BAF155-BRG1 complexassembly.

To demonstrate that the interaction of the SWI-SNF apparatus with cyclin E was functionally significant, we took advantageof a flat-cell assay established previously for BRG1 (11). BRG1is capable of inducing a flattened-cell morphology in SW13 cells.These cells do not divide and express markers indicative of replicativesenescence, namely, SA $beta$ -galactosidase activity. Both cyclin Eand cyclin D1 could abrogate this property of BRG1, reducing flat-cellinduction by as much as 50%, suggesting that these cyclins canmodulate the activity of BRG1. The flat-cell phenotype describedin this study is similar to the one observed with the introductionof pRb into SAOS-2 cells (18, 20, 35, 50). In SAOS-2 cells,pRb similarly causes growth arrest and induction of SA $beta$ -galactosidaseactivity, which can be rescued by overexpression of G₁ cyclins(18). While a dependence on BRG1 for pRb-mediated growth suppressionhas not yet been shown, a mutant form of BRG1 that is defectivein the ability to bind pRb can no longer induce growth arrestin SW13 cells (11). Hence, it has been proposed that pRb andBRG1 may function together to induce cell cyclearrest.

It will be important to establish the mechanism by which cyclin E suppresses flat-cell development and whether it is similarin both the SW13 and SAOS-2 assays. The ability of cyclins torescue growth in the SAOS-2 cotransfection experiments was originallyinterpreted to be through pRb phosphorylation (18). However,more recent experiments show that cyclins can also rescue thegrowth arrest induced by a nonphosphorylatable form of pRb (30).The ability of cyclins to rescue growth in the SW13 cotransfectionexperiments may also be independent of the pRb family of proteins,since even in their absence, cyclin E can associate with SWI-SNFcomponents. Furthermore, complexes between BRG1 and pRb appearunaffected by overexpression of cyclin E (data not shown). Ourexperiments thus raise the possibility that cyclin E may impingeon the SWI-SNF apparatus directly to revert the flat-cell phenotype.We are currently examining the phosphorylation status of variouscomponents of the SWI-SNF complex to see if they are altered withcyclin Eoverexpression.

A recent report by Sif et al. has demonstrated that the mitotic inactivation of the human SWI-SNF complex is caused by phosphorylationof various SWI-SNF subunits, including BRG1 (48). The identityof the kinases responsible for these regulatory phosphorylationsremains unknown. These observations, taken together with our results,suggest that the SWI-SNF apparatus may be modulated both positivelyand negatively through the cell cycle. While mitotic phosphorylationof BRG1 may be required for chromatin-mediated transcriptionalrepression during mitosis, phosphorylation on different sitesof BRG1 or of other SWI-SNF subunits may be required for chromatinremodeling during G₁ as cells prepare for DNA synthesis. Targetsfor modulation may include Ini1-hSNF5, because the yeast homologSfh1p is phosphorylated in a cell cycle-dependent manner duringG₁ (4). Since Ini1-hSNF5 is present in cyclin E immunoprecipitations,it will be important to address whether it also serves as a substratefor cyclin E-cdk2. A detailed analysis of the phosphorylationstatus of each of the SWI-SNF components as a function of cellcycle progression, and how this affects the chromatin remodelingactivity of the complex, will help to elucidate how the SWI-SNFapparatus is coordinatelyregulated.

The demonstration that BRG1 may induce senescence is significant, because it implies that chromatin reorganization may beimportant during cell cycle exit and perhaps in the maintenanceof a postmitotic state. Recent data suggest that inhibition ofcdk activity can induce a senescent state (2, 34). Our dataare consistent with a role for cyclin E in preventing cells fromexiting from the cell cycle permanently through modulation ofthe SWI-SNF complex. It may be significant that Ini1-hSNF5 (23,38) has recently been shown to be mutated in aggressive cancers(54). Such observations provide further evidence that criticalcomponents of the chromatin remodeling machinery may act as growthsuppressors that can be regulated by the cell cycle machinery.Overexpression of cyclin E in many human tumors may thus be amechanism by which malignant cells escape cell cycle exit andsenescence.

	ACKNOWLEDGMENTS

We thank W. Wang and G. Crabtree for reagents and W. Lane at the Harvard Microchemistry Laboratory for peptide sequencing.We are grateful to W. Korver and M. McMahon for discussions andcomments on themanuscript.

The DNAX Research Institute is supported by Schering-PloughCorporation.

	FOOTNOTES

^* Corresponding author. Mailing address: Cell Signaling Department, DNAX Research Institute, 901 California Ave., Palo Alto,CA 94304. Phone: (650) 496-1257. Fax: (650) 496-1200. E-mail:lees{at}dnax.org.

REFERENCES

Top
Abstract
Introduction
Materials and methods
Results
Discussion
References

1. Alevizopoulos, K., J. Vlach, S. Hennecke, and B. Amati. 1997. Cyclin E and c-Myc promote cell proliferation in the presence of p16INK4a and of hypophosphorylated retinoblastoma family proteins. EMBO J. 16:5322-5333[Medline].

2. Brown, J., W. Wei, and J. Sedivy. 1997. Bypass of senescence after disruption of p21CPI1/WAF1 gene in normal diploid human fibroblasts. Science 277:831-834[Abstract/Free Full Text].

3. Cairns, B. R., Y. Lorch, Y. Li, M. Zhang, L. Lacomis, H. Erdjument-Bromage, P. Tempst, J. Du, B. Laurent, and R. D. Kornberg. 1996. RSC, an essential, abundant chromatin-remodeling complex. Cell 87:1249-1260[Medline].

4. Cao, Y., B. R. Cairns, R. D. Kornberg, and B. C. Laurent. 1997. Sfh1p, a component of a novel chromatin-remodeling complex, is required for cell cycle progression. Mol. Cell. Biol. 17:3323-3334[Abstract].

5. Carlson, M., and B. C. Laurent. 1994. The SWI/SNFI family of global transcriptional activators. Curr. Opin. Cell Biol. 6:396-402[Medline].

6. Chiba, H., M. Muramatsu, A. Nomoto, and H. Kato. 1994. Two human homologues of Saccharomyces cerevisiae SWI/SNF2 complex and Drosophila brahma are transcriptional coactivators cooperating with the estrogen receptor and the retinoic receptor. Nucleic Acids Res. 22:1815-1820[Abstract/Free Full Text].

7. Cote, J., J. Quinn, J. L. Workman, and C. L. Peterson. 1994. Stimulation of GAL4 derivative binding to nucleosomal DNA by the yeast SWI/SNF complex. Science 265:53-60[Abstract/Free Full Text].

8. Dimri, G. P., X. Lee, G. Basile, M. Acosta, G. Scott, C. Roskelley, E. E. Medrano, M. Linskens, I. Rubelj, O. Pereira-Smith, M. Peacocke, and J. Campisi. 1995. A biomarker that identifies senescent human cells in culture and in aging skin in vivo. Proc. Natl. Acad. Sci. USA 92:9363-9367[Abstract/Free Full Text].

9. Dowdy, S. F., P. W. Hinds, K. Louie, S. I. Reed, A. Arnold, and R. A. Weinberg. 1993. Physical interaction of the retinoblastoma protein with human D cyclins. Cell 73:499-511[Medline].

10. Dulic, V., E. Lees, and S. I. Reed. 1992. Association of human cyclin E with a periodic G1-S phase protein kinase. Science 257:1958-1961[Abstract/Free Full Text].

11. Dunaief, J. L., B. E. Strober, S. Guha, P. A. Khavari, K. Alin, J. Luban, M. Begemann, G. R. Crabtree, and S. P. Goff. 1994. The retinoblastoma protein and BRG1 form a complex and cooperate to induce cell cycle arrest. Cell 79:119-130[Medline].

12. Ewen, M., B. Faha, E. Harlow, and D. Livingston. 1992. Interaction of p107 with cyclin A independent of complex formation with viral oncoproteins. Science 255:85-87[Abstract/Free Full Text].

13. Ewen, M. E., H. K. Sluss, C. J. Sherr, H. Matsushime, J. Kato, and D. M. Livingston. 1993. Functional interactions of the retinoblastoma protein with mammalian D-type cyclins. Cell 73:487-497[Medline].

14. Faha, B., M. E. Ewen, L. H. Tsai, D. M. Livingston, and E. Harlow. 1992. Interaction between human cyclin A and adenovirus E1A-associated p107 protein. Science 255:87-90[Abstract/Free Full Text].

15. Faha, B., E. Harlow, and E. Lees. 1993. The adenovirus E1A-associated kinase consists of cyclin E-p33^cdk2 and cyclin A-p33^cdk2. J. Virol. 67:2456-2465[Abstract/Free Full Text].

16. Ginsberg, D., G. Vairo, T. Chittenden, Z. H. Xiao, G. Xu, K. L. Wydner, J. A. DeCaprio, J. B. Lawrence, and D. M. Livingston. 1994. E2F-4, a new member of the E2F transcription factor family, interacts with p107. Genes Dev. 8:2265-2679.

17. Harlow, E., and D. Lane. 1988. Antibodies: a laboratory manual. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

18. Hinds, P. W., S. Mittnacht, V. Dulic, A. Arnold, S. I. Reed, and R. A. Weinberg. 1992. Regulation of retinoblastoma protein functions by ectopic expression of human cyclins. Cell 70:993-1006[Medline].

19. Hoffmann, I., G. Draetta, and E. Karsenti. 1994. Activation of the phosphatase activity of human cdc25A by a cdk2-cyclin E dependent phosphorylation at the G1/S transition. EMBO J. 13:4302-4310[Medline].

20. Huang, H. J., J. K. Yee, J. Y. Shew, P. L. Chen, R. Bookstein, T. Friedman, E. Y. Lee, and W. H. Lee. 1998. Suppression of the neoplastic phenotype by replacement of the RB gene in human cancer cells. Science 242:1563-1566.

21. Imbalzano, A. N., H. Kwon, M. R. Green, and R. E. Kingston. 1994. Facilitated binding of TATA-binding protein to nucleosomal DNA. Nature 370:481-485[Medline].

22. Jinno, S., K. Suto, A. Nagata, M. Igarashi, Y. Kanaoka, H. Nojima, and H. Okayama. 1994. Cdc25A is a novel phosphatase functioning early in the cell cycle. EMBO J. 13:1549-1556[Medline].

23. Kalpana, G. V., S. Marmon, W. Wang, G. R. Crabtree, and S. P. Goff. 1994. Binding and stimulation of HIV-1 integrase by a human homolog of yeast transcription factor SNF5. Science 266:2002-2006[Abstract/Free Full Text].

24. Kato, J., H. Matsushime, S. W. Hiebert, M. E. Ewen, and C. J. Sherr. 1993. Direct binding of cyclin D to the retinoblastoma gene product (pRb) and pRb phosphorylation by the cyclin D-dependent kinase CDK4. Genes Dev. 7:331-342[Free Full Text].

25. Khavari, P., C. Peterson, J. Tamkun, D. Mendel, and G. Crabtree. 1993. BRG1 contains a conserved domain of the SWI2/SNF2 family necessary for normal mitotic growth and transcription. Nature 366:170-174[Medline].

26. Koff, A., A. Giordano, D. Desai, K. Yamashita, W. Harper, S. Elledge, T. Nishimoto, D. Morgan, R. Franza, and J. Roberts. 1992. Formation and activation of a cyclin E-cdk2 complex during the G1 phase of the human cell cycle. Science 257:1689-1693[Abstract/Free Full Text].

27. Kwon, H., A. N. Imbalzano, P. A. Khavari, R. E. Kingston, and M. R. Green. 1994. Nucleosome disruption and enhancement of activator binding by a human SWI/SNF complex. Nature 370:477-481[Medline].

28. Lees, E. 1995. Cyclin dependent kinase regulation. Curr. Opin. Cell Biol. 7:773-780[Medline].

29. Lees, E., B. Faha, V. Dulic, S. I. Reed, and E. Harlow. 1992. Cyclin E/cdk2 and cyclin A/cdk2 kinases associate with p107 and E2F in a temporally distinct manner. Genes Dev. 6:1874-1885[Abstract/Free Full Text].

30. Leng, X., L. Connell-Crowley, D. Goodrich, and J. W. Harper. 1997. S-phase entry upon ectopic expression of G1 cyclin-dependent kinases in the absence of retinoblastoma protein phosphorylation. Curr. Biol. 7:709-712[Medline].

31. Logie, C., and C. L. Peterson. 1997. Catalytic activity of the yeast SWI/SNF complex on reconstituted nucleosome arrays. EMBO J. 16:6772-6782[Medline].

32. Lorch, Y., B. R. Cairns, M. Zhang, and R. D. Kornberg. 1998. Activated RSC-nucleosome complex and persistently altered form of the nucleosome. Cell 94:29-34[Medline].

33. Lukas, J., T. Herzinger, K. Hansen, M. C. Moroni, D. Resnitzky, K. Helin, S. I. Reed, and J. Bartek. 1997. Cyclin E-induced S phase without activation of the pRb/E2F pathway. Genes Dev. 11:1479-1492[Abstract/Free Full Text].

34. McConnell, B. B., M. Starborg, S. Brookes, and G. Peters. 1998. Inhibitors of cyclin-dependent kinases induce features of replicative senescence in early passage human diploid fibroblasts. Curr. Biol. 8:351-354[Medline].

35. Mittnacht, S., and R. A. Weinberg. 1991. G1/S phosphorylation of the retinoblastoma protein is associated with altered affinity for the nuclear compartment. Cell 65:381-393[Medline].

36. Morgan, D. O. 1995. Principles of CDK regulation. Nature 374:131-134[Medline].

37. Muchardt, C., J. C. Reyes, B. Bourachot, E. Leguoy, and M. Yaniv. 1996. The hbrm and BRG-1 proteins, components of the human SWI/SNF complex, are phosphorylated and excluded from the condensed chromosomes during mitosis. EMBO J. 15:3394-3402[Medline].

38. Muchardt, C., C. Sardet, B. Bourachot, C. Onufryk, and M. Yaniv. 1995. A human protein with homology to Saccharomyces cerevisiae SNF5 interacts with the potential helicase hbrm. Nucleic Acids Res. 23:1127-1132[Abstract/Free Full Text].

39. Muchardt, C., and M. Yaniv. 1993. A human homologue of Saccharomyces cerevisiae SNF2/SWI2 and Drosophila brm genes potentiates transcriptional activation by the glucocorticoid receptor. EMBO J. 12:4279-4290[Medline].

40. Ohtsubo, M., A. M. Theodoras, J. Schumacher, J. M. Roberts, and M. Pagano. 1995. Human cyclin E, a nuclear protein essential for the G₁-to-S phase transition. Mol. Cell. Biol. 15:2612-2624[Abstract].

41. Owen-Hughes, T., R. T. Utley, J. Cote, C. L. Peterson, and J. L. Workman. 1996. Persistent site-specific remodeling of a nucleosome array by transient action of the SWI/SNF complex. Science 273:513-516[Abstract].

42. Peterson, C. L., and J. W. Tamkun. 1995. The SWI-SNF complex: a chromatin remodeling machine? Trends Genet. 20:143-146.

43. Polyak, K., M. H. Lee, B. H. Erdjument, A. Koff, J. M. Roberts, P. Tempst, and J. Massague. 1994. Cloning of p27Kip1, a cyclin-dependent kinase inhibitor and a potential mediator of extracellular antimitogenic signals. Cell 78:59-66[Medline].

44. Resnitzky, D., M. Gossen, H. Bujard, and S. I. Reed. 1994. Acceleration of the G₁/S phase transition by expression of cyclins D1 and E with an inducible system. Mol. Cell. Biol. 14:1669-1679[Abstract/Free Full Text].

45. Schnitzler, G., S. Sif, and R. E. Kingston. 1998. Human SWI/SNF interconverts a nucleosome between its base and a stable remodeled state. Cell 94:17-27[Medline].

46. Seghezzi, W., K. Chua, F. Shanahan, O. Gozani, R. Reed, and E. Lees. 1998. Cyclin E associates with components of the pre-mRNA splicing machinery in mammalian cells. Mol. Cell. Biol. 18:4526-4536[Abstract/Free Full Text].

47. Sherr, C. J. 1996. Cancer cell cycles. Science 274:1674-1677.

48. Sif, S., P. T. Stukenburg, M. W. Kirschner, and R. E. Kingston. 1998. Mitotic inactivation of a human SWI/SNF chromatin remodeling complex. Genes Dev. 12:2842-2851[Abstract/Free Full Text].

49. Strober, B. E., J. L. Dunaief, S. Guha, and S. P. Goff. 1996. Functional interactions between the hBRM/hBRG1 transcriptional activators and the pRB family of proteins. Mol. Cell. Biol. 16:1576-1583[Abstract].

50. Templeton, D. J., S. H. Park, L. Lanier, and R. A. Weinberg. 1991. Nonfunctional mutants of the retinoblastoma protein are characterised by defects in phosphorylation, viral oncoprotein association, and nuclear tethering. Proc. Natl. Acad. Sci. USA 88:3033-3037[Abstract/Free Full Text].

51. Trouche, D., C. Le Chalony, C. Muchardt, M. Yaniv, and T. Kouzarides. 1997. RB and hbrm cooperate to repress the activation functions of E2F1. Proc. Natl. Acad. Sci. USA 94:11268-11273[Abstract/Free Full Text].

52. Tsai, L.-H., E. Lees, B. Faha, E. Harlow, and K. Riabowol. 1993. The cdk2 kinase is required for the G1-to-S transition in mammalian cells. Oncogene 8:1593-1602[Medline].

53. van den Heuvel, S., and E. Harlow. 1993. Distinct roles for cyclin-dependent kinases in cell cycle control. Science 262:2050-2054[Abstract/Free Full Text].

54. Versteege, I., N. Sevenet, J. Lange, M.-F. Rousseau-Merck, P. Ambros, R. Handgretinger, A. Aurias, and O. Delattre. 1998. Truncating mutations of hSNF5/INI1 in aggressive paediatric cancer. Nature 394:203-206[Medline].

55. Wang, C., K. Chua, W. Seghezzi, E. Lees, O. Gozani, and R. Reed. 1998. Phosphorylation of the spliceosomal protein SAP155 is coupled with splicing catalysis. Genes Dev. 12:1409-1414[Abstract/Free Full Text].

56. Wang, W., J. Cote, Y. Xue, S. Zhou, P. A. Khavari, S. R. Biggar, C. Muchardt, G. V. Kalpana, S. P. Goff, M. Yaniv, J. L. Workman, and G. R. Crabtree. 1996. Purification and biochemical heterogeneity of the mammalian SWI-SNF complex. EMBO J. 15:5370-5382[Medline].

57. Wang, W., Y. Xue, S. Zhou, A. Kuo, B. Cairns, and G. Crabtree. 1996. Diversity and specialization of mammalian SWI/SNF complexes. Genes Dev. 10:2117-2130[Abstract/Free Full Text].

58. Zhao, J., B. Dynlacht, T. Imai, T. Hori, and E. Harlow. 1998. Expression of NPAT, a novel substrate of cyclin E-CDK2, promotes S-phase entry. Genes Dev. 12:456-461[Abstract/Free Full Text].

This article has been cited by other articles:

Inayoshi, Y., Miyake, K., Machida, Y., Kaneoka, H., Terajima, M., Dohda, T., Takahashi, M., Iijima, S. (2006). Mammalian Chromatin Remodeling Complex SWI/SNF Is Essential for Enhanced Expression of the Albumin Gene during Liver Development. J Biochem 139: 177-188 [Abstract] [Full Text]
Marignani, P A (2005). LKB1, the multitasking tumour suppressor kinase. J. Clin. Pathol. 58: 15-19 [Abstract] [Full Text]
Hill, D. A., Chiosea, S., Jamaluddin, S., Roy, K., Fischer, A. H., Boyd, D. D., Nickerson, J. A., Imbalzano, A. N. (2004). Inducible changes in cell size and attachment area due to expression of a mutant SWI/SNF chromatin remodeling enzyme. J. Cell Sci. 117: 5847-5854 [Abstract] [Full Text]
Zraly, C. B., Marenda, D. R., Dingwall, A. K. (2004). SNR1 (INI1/SNF5) Mediates Important Cell Growth Functions of the Drosophila Brahma (SWI/SNF) Chromatin Remodeling Complex. Genetics 168: 199-214 [Abstract] [Full Text]
Shaw, R. J., Kosmatka, M., Bardeesy, N., Hurley, R. L., Witters, L. A., DePinho, R. A., Cantley, L. C. (2004). Inaugural Article: The tumor suppressor LKB1 kinase directly activates AMP-activated kinase and regulates apoptosis in response to energy stress. Proc. Natl. Acad. Sci. USA 101: 3329-3335 [Abstract] [Full Text]
Muller, C., Calkhoven, C. F., Sha, X., Leutz, A. (2004). The CCAAT Enhancer-binding Protein {alpha} (C/EBP{alpha}) Requires a SWI/SNF Complex for Proliferation Arrest. J. Biol. Chem. 279: 7353-7358 [Abstract] [Full Text]
Kang, H., Cui, K., Zhao, K. (2004). BRG1 Controls the Activity of the Retinoblastoma Protein via Regulation of p21CIP1/WAF1/SDI. Mol. Cell. Biol. 24: 1188-1199 [Abstract] [Full Text]
Hendricks, K. B., Shanahan, F., Lees, E. (2004). Role for BRG1 in Cell Cycle Control and Tumor Suppression. Mol. Cell. Biol. 24: 362-376 [Abstract] [Full Text]
Reisman, D. N., Sciarrotta, J., Wang, W., Funkhouser, W. K., Weissman, B. E. (2003). Loss of BRG1/BRM in Human Lung Cancer Cell Lines and Primary Lung Cancers: Correlation with Poor Prognosis. Cancer Res. 63: 560-566 [Abstract] [Full Text]
Marenda, D. R., Zraly, C. B., Feng, Y., Egan, S., Dingwall, A. K. (2003). The Drosophila SNR1 (SNF5/INI1) Subunit Directs Essential Developmental Functions of the Brahma Chromatin Remodeling Complex. Mol. Cell. Biol. 23: 289-305 [Abstract] [Full Text]
Lee, D., Lim, C., Seo, T., Kwon, H., Min, H., Choe, J. (2002). The Viral Oncogene Human Papillomavirus E7 Deregulates Transcriptional Silencing by Brm-related Gene 1 via Molecular Interactions. J. Biol. Chem. 277: 48842-48848 [Abstract] [Full Text]
Zhang, Q. J., Goddard, M., Shanahan, C., Shapiro, L., Bennett, M. (2002). Differential Gene Expression in Vascular Smooth Muscle Cells in Primary Atherosclerosis and In Stent Stenosis in Humans. Arterioscler. Thromb. Vasc. Bio. 22: 2030-2036 [Abstract] [Full Text]
Bandyopadhyay, D., Okan, N. A., Bales, E., Nascimento, L., Cole, P. A., Medrano, E. E. (2002). Down-Regulation of p300/CBP Histone Acetyltransferase Activates a Senescence Checkpoint in Human Melanocytes. Cancer Res. 62: 6231-6239 [Abstract] [Full Text]
Zhang, Z.-K., Davies, K. P., Allen, J., Zhu, L., Pestell, R. G., Zagzag, D., Kalpana, G. V. (2002). Cell Cycle Arrest and Repression of Cyclin D1 Transcription by INI1/hSNF5. Mol. Cell. Biol. 22: 5975-5988 [Abstract] [Full Text]
Sarnowski, T. J., Swiezewski, S., Pawlikowska, K., Kaczanowski, S., Jerzmanowski, A. (2002). AtSWI3B, an Arabidopsis homolog of SWI3, a core subunit of yeast Swi/Snf chromatin remodeling complex, interacts with FCA, a regulator of flowering time. Nucleic Acids Res 30: 3412-3421 [Abstract] [Full Text]
Marcotte, R., Wang, E. (2002). Replicative Senescence Revisited. J. Gerontol. A Biol. Sci. Med. Sci. 57: B257-269 [Abstract] [Full Text]
Schrem, H., Klempnauer, J., Borlak, J. (2002). Liver-Enriched Transcription Factors in Liver Function and Development. Part I: The Hepatocyte Nuclear Factor Network and Liver-Specific Gene Expression. Pharmacol. Rev. 54: 129-158 [Abstract] [Full Text]
Kato, H., Tjernberg, A., Zhang, W., Krutchinsky, A. N., An, W., Takeuchi, T., Ohtsuki, Y., Sugano, S., de Bruijn, D. R., Chait, B. T., Roeder, R. G. (2002). SYT Associates with Human SNF/SWI Complexes and the C-terminal Region of Its Fusion Partner SSX1 Targets Histones. J. Biol. Chem. 277: 5498-5505 [Abstract] [Full Text]
Calgaro, S., Boube, M., Cribbs, D. L., Bourbon, H.-M. (2002). The Drosophila Gene taranis Encodes a Novel Trithorax Group Member Potentially Linked to the Cell Cycle Regulatory Apparatus. Genetics 160: 547-560 [Abstract] [Full Text]
Asp, P., Wihlborg, M., Karlen, M., Farrants, A.-K. O. (2002). Expression of BRG1, a human SWI/SNF component, affects the organisation of actin filaments through the RhoA signalling pathway. J. Cell Sci. 115: 2735-2746 [Abstract] [Full Text]
Kim, J. K., Huh, S.-O., Choi, H., Lee, K.-S., Shin, D., Lee, C., Nam, J.-S., Kim, H., Chung, H., Lee, H. W., Park, S. D., Seong, R. H. (2001). Srg3, a Mouse Homolog of Yeast SWI3, Is Essential for Early Embryogenesis and Involved in Brain Development. Mol. Cell. Biol. 21: 7787-7795 [Abstract] [Full Text]
Kim, T.-Y., Kaelin, W. G. Jr. (2001). Differential Control of Transcription by DNA-bound Cyclins. Mol. Biol. Cell 12: 2207-2217 [Abstract] [Full Text]
Guidi, C. J., Sands, A. T., Zambrowicz, B. P., Turner, T. K., Demers, D. A., Webster, W., Smith, T. W., Imbalzano, A. N., Jones, S. N. (2001). Disruption of Ini1 Leads to Peri-Implantation Lethality and Tumorigenesis in Mice. Mol. Cell. Biol. 21: 3598-3603 [Abstract] [Full Text]
Biggs, J. R., Yang, J., Gullberg, U., Muchardt, C., Yaniv, M., Kraft, A. S. (2001). The human brm protein is cleaved during apoptosis: The role of cathepsin G. Proc. Natl. Acad. Sci. USA 10.1073/pnas.071057398v1 [Abstract] [Full Text]
Xue, Y., Canman, J. C., Lee, C. S., Nie, Z., Yang, D., Moreno, G. T., Young, M. K., Salmon, E. D., Wang, W. (2000). The human SWI/SNF-B chromatin-remodeling complex is related to yeast Rsc and localizes at kinetochores of mitotic chromosomes. Proc. Natl. Acad. Sci. USA 10.1073/pnas.240208597v1 [Abstract] [Full Text]
Wong, A. K. C., Shanahan, F., Chen, Y., Lian, L., Ha, P., Hendricks, K., Ghaffari, S., Iliev, D., Penn, B., Woodland, A.-M., Smith, R., Salada, G., Carillo, A., Laity, K., Gupte, J., Swedlund, B., Tavtigian, S. V., Teng, D. H-F., Lees, E. (2000). BRG1, a Component of the SWI-SNF Complex, Is Mutated in Multiple Human Tumor Cell Lines. Cancer Res. 60: 6171-6177 [Abstract] [Full Text]
Harbour, J. W., Dean, D. C. (2000). The Rb/E2F pathway: expanding roles and emerging paradigms. Genes Dev. 14: 2393-2409 [Full Text]
Kadam, S., McAlpine, G. S., Phelan, M. L., Kingston, R. E., Jones, K. A., Emerson, B. M. (2000). Functional selectivity of recombinant mammalian SWI/SNF subunits. Genes Dev. 14: 2441-2451 [Abstract] [Full Text]
Ewen, M. E. (2000). Where the cell cycle and histones meet. Genes Dev. 14: 2265-2270 [Full Text]
Zhao, J., Kennedy, B. K., Lawrence, B. D., Barbie, D. A., Matera, A. G., Fletcher, J. A., Harlow, E. (2000). NPAT links cyclin E-Cdk2 to the regulation of replication-dependent histone gene transcription. Genes Dev. 14: 2283-2297 [Abstract] [Full Text]
de la Serna, I. L., Carlson, K. A., Hill, D. A., Guidi, C. J., Stephenson, R. O., Sif, S., Kingston, R. E., Imbalzano, A. N. (2000). Mammalian SWI-SNF Complexes Contribute to Activation of the hsp70 Gene. Mol. Cell. Biol. 20: 2839-2851 [Abstract] [Full Text]
Vignali, M., Hassan, A. H., Neely, K. E., Workman, J. L. (2000). ATP-Dependent Chromatin-Remodeling Complexes. Mol. Cell. Biol. 20: 1899-1910 [Full Text]
Schuchner, S., Wintersberger, E. (1999). Binding of Polyomavirus Small T Antigen to Protein Phosphatase 2A Is Required for Elimination of p27 and Support of S-Phase Induction in Concert with Large T Antigen. J. Virol. 73: 9266-9273 [Abstract] [Full Text]
Staehling-Hampton, K., Ciampa, P. J., Brook, A., Dyson, N. (1999). A Genetic Screen for Modifiers of E2F in Drosophila melanogaster. Genetics 153: 275-287 [Abstract] [Full Text]
Bourachot, B., Yaniv, M., Muchardt, C. (1999). The Activity of Mammalian brm/SNF2alpha Is Dependent on a High-Mobility-Group Protein I/Y-Like DNA Binding Domain. Mol. Cell. Biol. 19: 3931-3939 [Abstract] [Full Text]
Marignani, P. A., Kanai, F., Carpenter, C. L. (2001). LKB1 Associates with Brg1 and Is Necessary for Brg1-induced Growth Arrest. J. Biol. Chem. 276: 32415-32418 [Abstract] [Full Text]
Underhill, C., Qutob, M. S., Yee, S.-P., Torchia, J. (2000). A Novel Nuclear Receptor Corepressor Complex, N-CoR, Contains Components of the Mammalian SWI/SNF Complex and the Corepressor KAP-1. J. Biol. Chem. 275: 40463-40470 [Abstract] [Full Text]
Strobeck, M. W., DeCristofaro, M. F., Banine, F., Weissman, B. E., Sherman, L. S., Knudsen, E. S. (2001). The BRG-1 Subunit of the SWI/SNF Complex Regulates CD44 Expression. J. Biol. Chem. 276: 9273-9278 [Abstract] [Full Text]
Biggs, J. R., Yang, J., Gullberg, U., Muchardt, C., Yaniv, M., Kraft, A. S. (2001). The human brm protein is cleaved during apoptosis: The role of cathepsin G. Proc. Natl. Acad. Sci. USA 98: 3814-3819 [Abstract] [Full Text]
Xue, Y., Canman, J. C., Lee, C. S., Nie, Z., Yang, D., Moreno, G. T., Young, M. K., Salmon, E. D., Wang, W. (2000). The human SWI/SNF-B chromatin-remodeling complex is related to yeast Rsc and localizes at kinetochores of mitotic chromosomes. Proc. Natl. Acad. Sci. USA 97: 13015-13020 [Abstract] [Full Text]

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Similar articles in this journal
	Similar articles in PubMed

1.	Alevizopoulos, K., J. Vlach, S. Hennecke, and B. Amati. 1997. Cyclin E and c-Myc promote cell proliferation in the presence of p16INK4a and of hypophosphorylated retinoblastoma family proteins. EMBO J. 16:5322-5333[Medline].
2.	Brown, J., W. Wei, and J. Sedivy. 1997. Bypass of senescence after disruption of p21CPI1/WAF1 gene in normal diploid human fibroblasts. Science 277:831-834[Abstract/Free Full Text].
3.	Cairns, B. R., Y. Lorch, Y. Li, M. Zhang, L. Lacomis, H. Erdjument-Bromage, P. Tempst, J. Du, B. Laurent, and R. D. Kornberg. 1996. RSC, an essential, abundant chromatin-remodeling complex. Cell 87:1249-1260[Medline].
4.	Cao, Y., B. R. Cairns, R. D. Kornberg, and B. C. Laurent. 1997. Sfh1p, a component of a novel chromatin-remodeling complex, is required for cell cycle progression. Mol. Cell. Biol. 17:3323-3334[Abstract].
5.	Carlson, M., and B. C. Laurent. 1994. The SWI/SNFI family of global transcriptional activators. Curr. Opin. Cell Biol. 6:396-402[Medline].
6.	Chiba, H., M. Muramatsu, A. Nomoto, and H. Kato. 1994. Two human homologues of Saccharomyces cerevisiae SWI/SNF2 complex and Drosophila brahma are transcriptional coactivators cooperating with the estrogen receptor and the retinoic receptor. Nucleic Acids Res. 22:1815-1820[Abstract/Free Full Text].
7.	Cote, J., J. Quinn, J. L. Workman, and C. L. Peterson. 1994. Stimulation of GAL4 derivative binding to nucleosomal DNA by the yeast SWI/SNF complex. Science 265:53-60[Abstract/Free Full Text].
8.	Dimri, G. P., X. Lee, G. Basile, M. Acosta, G. Scott, C. Roskelley, E. E. Medrano, M. Linskens, I. Rubelj, O. Pereira-Smith, M. Peacocke, and J. Campisi. 1995. A biomarker that identifies senescent human cells in culture and in aging skin in vivo. Proc. Natl. Acad. Sci. USA 92:9363-9367[Abstract/Free Full Text].
9.	Dowdy, S. F., P. W. Hinds, K. Louie, S. I. Reed, A. Arnold, and R. A. Weinberg. 1993. Physical interaction of the retinoblastoma protein with human D cyclins. Cell 73:499-511[Medline].
10.	Dulic, V., E. Lees, and S. I. Reed. 1992. Association of human cyclin E with a periodic G1-S phase protein kinase. Science 257:1958-1961[Abstract/Free Full Text].
11.	Dunaief, J. L., B. E. Strober, S. Guha, P. A. Khavari, K. Alin, J. Luban, M. Begemann, G. R. Crabtree, and S. P. Goff. 1994. The retinoblastoma protein and BRG1 form a complex and cooperate to induce cell cycle arrest. Cell 79:119-130[Medline].
12.	Ewen, M., B. Faha, E. Harlow, and D. Livingston. 1992. Interaction of p107 with cyclin A independent of complex formation with viral oncoproteins. Science 255:85-87[Abstract/Free Full Text].
13.	Ewen, M. E., H. K. Sluss, C. J. Sherr, H. Matsushime, J. Kato, and D. M. Livingston. 1993. Functional interactions of the retinoblastoma protein with mammalian D-type cyclins. Cell 73:487-497[Medline].
14.	Faha, B., M. E. Ewen, L. H. Tsai, D. M. Livingston, and E. Harlow. 1992. Interaction between human cyclin A and adenovirus E1A-associated p107 protein. Science 255:87-90[Abstract/Free Full Text].
15.	Faha, B., E. Harlow, and E. Lees. 1993. The adenovirus E1A-associated kinase consists of cyclin E-p33^cdk2 and cyclin A-p33^cdk2. J. Virol. 67:2456-2465[Abstract/Free Full Text].
16.	Ginsberg, D., G. Vairo, T. Chittenden, Z. H. Xiao, G. Xu, K. L. Wydner, J. A. DeCaprio, J. B. Lawrence, and D. M. Livingston. 1994. E2F-4, a new member of the E2F transcription factor family, interacts with p107. Genes Dev. 8:2265-2679.
17.	Harlow, E., and D. Lane. 1988. Antibodies: a laboratory manual. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
18.	Hinds, P. W., S. Mittnacht, V. Dulic, A. Arnold, S. I. Reed, and R. A. Weinberg. 1992. Regulation of retinoblastoma protein functions by ectopic expression of human cyclins. Cell 70:993-1006[Medline].
19.	Hoffmann, I., G. Draetta, and E. Karsenti. 1994. Activation of the phosphatase activity of human cdc25A by a cdk2-cyclin E dependent phosphorylation at the G1/S transition. EMBO J. 13:4302-4310[Medline].
20.	Huang, H. J., J. K. Yee, J. Y. Shew, P. L. Chen, R. Bookstein, T. Friedman, E. Y. Lee, and W. H. Lee. 1998. Suppression of the neoplastic phenotype by replacement of the RB gene in human cancer cells. Science 242:1563-1566.
21.	Imbalzano, A. N., H. Kwon, M. R. Green, and R. E. Kingston. 1994. Facilitated binding of TATA-binding protein to nucleosomal DNA. Nature 370:481-485[Medline].
22.	Jinno, S., K. Suto, A. Nagata, M. Igarashi, Y. Kanaoka, H. Nojima, and H. Okayama. 1994. Cdc25A is a novel phosphatase functioning early in the cell cycle. EMBO J. 13:1549-1556[Medline].
23.	Kalpana, G. V., S. Marmon, W. Wang, G. R. Crabtree, and S. P. Goff. 1994. Binding and stimulation of HIV-1 integrase by a human homolog of yeast transcription factor SNF5. Science 266:2002-2006[Abstract/Free Full Text].
24.	Kato, J., H. Matsushime, S. W. Hiebert, M. E. Ewen, and C. J. Sherr. 1993. Direct binding of cyclin D to the retinoblastoma gene product (pRb) and pRb phosphorylation by the cyclin D-dependent kinase CDK4. Genes Dev. 7:331-342[Free Full Text].
25.	Khavari, P., C. Peterson, J. Tamkun, D. Mendel, and G. Crabtree. 1993. BRG1 contains a conserved domain of the SWI2/SNF2 family necessary for normal mitotic growth and transcription. Nature 366:170-174[Medline].
26.	Koff, A., A. Giordano, D. Desai, K. Yamashita, W. Harper, S. Elledge, T. Nishimoto, D. Morgan, R. Franza, and J. Roberts. 1992. Formation and activation of a cyclin E-cdk2 complex during the G1 phase of the human cell cycle. Science 257:1689-1693[Abstract/Free Full Text].
27.	Kwon, H., A. N. Imbalzano, P. A. Khavari, R. E. Kingston, and M. R. Green. 1994. Nucleosome disruption and enhancement of activator binding by a human SWI/SNF complex. Nature 370:477-481[Medline].
28.	Lees, E. 1995. Cyclin dependent kinase regulation. Curr. Opin. Cell Biol. 7:773-780[Medline].
29.	Lees, E., B. Faha, V. Dulic, S. I. Reed, and E. Harlow. 1992. Cyclin E/cdk2 and cyclin A/cdk2 kinases associate with p107 and E2F in a temporally distinct manner. Genes Dev. 6:1874-1885[Abstract/Free Full Text].
30.	Leng, X., L. Connell-Crowley, D. Goodrich, and J. W. Harper. 1997. S-phase entry upon ectopic expression of G1 cyclin-dependent kinases in the absence of retinoblastoma protein phosphorylation. Curr. Biol. 7:709-712[Medline].
31.	Logie, C., and C. L. Peterson. 1997. Catalytic activity of the yeast SWI/SNF complex on reconstituted nucleosome arrays. EMBO J. 16:6772-6782[Medline].
32.	Lorch, Y., B. R. Cairns, M. Zhang, and R. D. Kornberg. 1998. Activated RSC-nucleosome complex and persistently altered form of the nucleosome. Cell 94:29-34[Medline].
33.	Lukas, J., T. Herzinger, K. Hansen, M. C. Moroni, D. Resnitzky, K. Helin, S. I. Reed, and J. Bartek. 1997. Cyclin E-induced S phase without activation of the pRb/E2F pathway. Genes Dev. 11:1479-1492[Abstract/Free Full Text].
34.	McConnell, B. B., M. Starborg, S. Brookes, and G. Peters. 1998. Inhibitors of cyclin-dependent kinases induce features of replicative senescence in early passage human diploid fibroblasts. Curr. Biol. 8:351-354[Medline].
35.	Mittnacht, S., and R. A. Weinberg. 1991. G1/S phosphorylation of the retinoblastoma protein is associated with altered affinity for the nuclear compartment. Cell 65:381-393[Medline].
36.	Morgan, D. O. 1995. Principles of CDK regulation. Nature 374:131-134[Medline].
37.	Muchardt, C., J. C. Reyes, B. Bourachot, E. Leguoy, and M. Yaniv. 1996. The hbrm and BRG-1 proteins, components of the human SWI/SNF complex, are phosphorylated and excluded from the condensed chromosomes during mitosis. EMBO J. 15:3394-3402[Medline].
38.	Muchardt, C., C. Sardet, B. Bourachot, C. Onufryk, and M. Yaniv. 1995. A human protein with homology to Saccharomyces cerevisiae SNF5 interacts with the potential helicase hbrm. Nucleic Acids Res. 23:1127-1132[Abstract/Free Full Text].
39.	Muchardt, C., and M. Yaniv. 1993. A human homologue of Saccharomyces cerevisiae SNF2/SWI2 and Drosophila brm genes potentiates transcriptional activation by the glucocorticoid receptor. EMBO J. 12:4279-4290[Medline].
40.	Ohtsubo, M., A. M. Theodoras, J. Schumacher, J. M. Roberts, and M. Pagano. 1995. Human cyclin E, a nuclear protein essential for the G₁-to-S phase transition. Mol. Cell. Biol. 15:2612-2624[Abstract].
41.	Owen-Hughes, T., R. T. Utley, J. Cote, C. L. Peterson, and J. L. Workman. 1996. Persistent site-specific remodeling of a nucleosome array by transient action of the SWI/SNF complex. Science 273:513-516[Abstract].
42.	Peterson, C. L., and J. W. Tamkun. 1995. The SWI-SNF complex: a chromatin remodeling machine? Trends Genet. 20:143-146.
43.	Polyak, K., M. H. Lee, B. H. Erdjument, A. Koff, J. M. Roberts, P. Tempst, and J. Massague. 1994. Cloning of p27Kip1, a cyclin-dependent kinase inhibitor and a potential mediator of extracellular antimitogenic signals. Cell 78:59-66[Medline].
44.	Resnitzky, D., M. Gossen, H. Bujard, and S. I. Reed. 1994. Acceleration of the G₁/S phase transition by expression of cyclins D1 and E with an inducible system. Mol. Cell. Biol. 14:1669-1679[Abstract/Free Full Text].
45.	Schnitzler, G., S. Sif, and R. E. Kingston. 1998. Human SWI/SNF interconverts a nucleosome between its base and a stable remodeled state. Cell 94:17-27[Medline].
46.	Seghezzi, W., K. Chua, F. Shanahan, O. Gozani, R. Reed, and E. Lees. 1998. Cyclin E associates with components of the pre-mRNA splicing machinery in mammalian cells. Mol. Cell. Biol. 18:4526-4536[Abstract/Free Full Text].
47.	Sherr, C. J. 1996. Cancer cell cycles. Science 274:1674-1677.
48.	Sif, S., P. T. Stukenburg, M. W. Kirschner, and R. E. Kingston. 1998. Mitotic inactivation of a human SWI/SNF chromatin remodeling complex. Genes Dev. 12:2842-2851[Abstract/Free Full Text].
49.	Strober, B. E., J. L. Dunaief, S. Guha, and S. P. Goff. 1996. Functional interactions between the hBRM/hBRG1 transcriptional activators and the pRB family of proteins. Mol. Cell. Biol. 16:1576-1583[Abstract].
50.	Templeton, D. J., S. H. Park, L. Lanier, and R. A. Weinberg. 1991. Nonfunctional mutants of the retinoblastoma protein are characterised by defects in phosphorylation, viral oncoprotein association, and nuclear tethering. Proc. Natl. Acad. Sci. USA 88:3033-3037[Abstract/Free Full Text].
51.	Trouche, D., C. Le Chalony, C. Muchardt, M. Yaniv, and T. Kouzarides. 1997. RB and hbrm cooperate to repress the activation functions of E2F1. Proc. Natl. Acad. Sci. USA 94:11268-11273[Abstract/Free Full Text].
52.	Tsai, L.-H., E. Lees, B. Faha, E. Harlow, and K. Riabowol. 1993. The cdk2 kinase is required for the G1-to-S transition in mammalian cells. Oncogene 8:1593-1602[Medline].
53.	van den Heuvel, S., and E. Harlow. 1993. Distinct roles for cyclin-dependent kinases in cell cycle control. Science 262:2050-2054[Abstract/Free Full Text].
54.	Versteege, I., N. Sevenet, J. Lange, M.-F. Rousseau-Merck, P. Ambros, R. Handgretinger, A. Aurias, and O. Delattre. 1998. Truncating mutations of hSNF5/INI1 in aggressive paediatric cancer. Nature 394:203-206[Medline].
55.	Wang, C., K. Chua, W. Seghezzi, E. Lees, O. Gozani, and R. Reed. 1998. Phosphorylation of the spliceosomal protein SAP155 is coupled with splicing catalysis. Genes Dev. 12:1409-1414[Abstract/Free Full Text].
56.	Wang, W., J. Cote, Y. Xue, S. Zhou, P. A. Khavari, S. R. Biggar, C. Muchardt, G. V. Kalpana, S. P. Goff, M. Yaniv, J. L. Workman, and G. R. Crabtree. 1996. Purification and biochemical heterogeneity of the mammalian SWI-SNF complex. EMBO J. 15:5370-5382[Medline].
57.	Wang, W., Y. Xue, S. Zhou, A. Kuo, B. Cairns, and G. Crabtree. 1996. Diversity and specialization of mammalian SWI/SNF complexes. Genes Dev. 10:2117-2130[Abstract/Free Full Text].
58.	Zhao, J., B. Dynlacht, T. Imai, T. Hori, and E. Harlow. 1998. Expression of NPAT, a novel substrate of cyclin E-CDK2, promotes S-phase entry. Genes Dev. 12:456-461[Abstract/Free Full Text].