Target Gene Specificity of E2F and Pocket Protein Family Members in Living Cells

doi:10.1128/MCB.20.16.5797-5807.2000

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
	Reprints and Permissions
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Wells, J.
	Articles by Farnham, P. J.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Wells, J.
	Articles by Farnham, P. J.

Previous Article | Next Article

Molecular and Cellular Biology, August 2000, p. 5797-5807, Vol. 20, No. 16
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Target Gene Specificity of E2F and Pocket Protein Family Members in Living Cells

Julie Wells, Kathryn E. Boyd, Christopher J. Fry, Stephanie M. Bartley, and Peggy J. Farnham^*

McArdle Laboratory for Cancer Research, University of Wisconsin Medical School, Madison, Wisconsin 53706

Received 30 November 1999/Returned for modification 19 January 2000/Accepted 6 May 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

E2F-mediated transcription is thought to involve binding of an E2F-pocket protein complex to promoters in the G₀ phase ofthe cell cycle and release of the pocket protein in late G₁, followedby release of E2F in S phase. We have tested this model by monitoringprotein-DNA interactions in living cells using a formaldehydecross-linking and immunoprecipitation assay. We find that E2Ftarget genes are bound by distinct E2F-pocket protein complexeswhich change as cells progress through the cell cycle. We alsofind that certain E2F target gene promoters are bound by pocketproteins when such promoters are transcriptionally active. Ourdata indicate that the current model applies only to certain E2Ftarget genes and suggest that Rb family members may regulate transcriptionin both G₀ and S phases. Finally, we find that a given promotercan be bound by one of several different E2F-pocket protein complexesat a given time in the cell cycle, suggesting that cell cycle-regulatedtranscription is a stochastic, not a predetermined,process.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The E2F family of transcription factors plays an important role in the regulation of gene expression at the G₁/S-phase transitionof the mammalian cell cycle (see reference 16 for an extensivereview of the E2F regulatory pathway). E2F binding sites are foundin the promoters of genes whose products are required for nucleotidesynthesis (e.g., dihydrofolate reductase [DHFR] and thymidinekinase [TK]), for DNA replication (e.g., DNA polymerase $alpha$ andcdc6), and for cell cycle progression (e.g., cyclin E, cyclinD1, c-myc, b-myb, and cdc2). Transcription from each of thesepromoters increases during late G₁ or early S phase, and thisregulation is mediated by protein binding to one or more E2F bindingsites (3, 11, 22, 30, 34, 43, 44). To date, eightmembers of the E2F family have been identified: six E2F proteins(E2F1 to -6) and two DP proteins (DP1 and DP2). The E2F and DPproteins bind to DNA as a heterodimer and can function as activatorsof transcription. Alternatively, E2F-DP heterodimers can alsorepress transcription when complexed with members of the Rb familyof pocket proteins (pRb, p107, and p130) due to the ability ofthe pocket proteins to bind to and mask the E2F transactivationdomain and to recruit histone deacetylases (6, 17, 25).Individual E2Fs preferentially bind to different pocket proteins.E2F1, E2F2, and E2F3, for example, bind to pRb, while E2F4 predominantlybinds to p130 and p107 and E2F5 binds top130.

A popular model for how E2F family members regulate G₁/S-phase-specific gene expression invokes a complex pattern of protein-proteinand protein-DNA interactions that change as cells progress throughthe cell cycle (Fig. 1A). As depicted, transcription from E2Fsite-containing promoters is thought to be repressed in G₀ phasedue to the binding of a trimolecular E2F-DP-pocket protein complexand recruitment of histone deacetylase activity by the pocketprotein component (6, 17, 25). As cells progress throughthe cell cycle, various cyclin-cyclin-dependent kinase (cdk) complexesphosphorylate the pocket proteins, causing release of the hyperphosphorylatedpocket protein and associated proteins from the DNA-bound E2F-DPheterodimer (1, 2, 7). Finally, traversal through S phaseis thought to be accompanied by cyclin-cdk-mediated phosphorylationof the DP subunit of E2F1-3-DP complexes, resulting in releaseof the heterodimers from the promoter DNA (15, 21, 42).In some cells, E2F4-containing complexes are thought to be inactivatedby relocation to the cytoplasm (28, 38).

View larger version (24K):
[in this window]
[in a new window]

FIG. 1. E2F-mediated transcriptional regulation. (A) The current model of E2F-mediated transcriptional regulation is thought to involve binding of an E2F-pocket protein complex to promoters in G₀ phase of the cell cycle and release of the pocket protein in late G₁, followed by release of E2F in S phase, either as a result of the action of cyclin-cdk's or due to changes in subcellular localization of E2F. (B) Shown is the protocol for formaldehyde cross-linking and immunoprecipitation used to detect E2F and pocket protein binding to endogenous target genes. (C) Shown are the E2F sites present in the promoters of the different target genes analyzed in this study. The DHFR, b-myb, and TK promoters have a set of inverted, overlapping E2F recognition sites whereas the cyclin E and cdc2 promoters have a single E2F recognition site.

Although this model is attractive, it is largely based upon circumstantial data, and several important questions remain unanswered.For example, the transcriptional activity of complexes containingE2F4 and E2F5 may be shut off during mid- to late S phase by associationwith unphosphorylated p107 or p130, rather than by relocationto the cytoplasm (10). Additionally, it is not known if E2Ftarget gene specificity exists or if all six E2Fs bind to andregulate every target gene or if Rb family members display targetgene specificity. Determination of target gene specificity hasbeen difficult due to the fact that most cells studied to datecontain all of the E2Fs and pocket proteins. Thus, most analysesof E2F and pocket protein binding specificity have been performedusing in vitro systems or by overexpression of an individual E2For pocket protein in cells. In vitro systems, however, cannotrecapitulate the complex environment of living cells, and alteringthe relative amounts of individual proteins through overexpressionmay abolish important protein-protein interactions. Therefore,we wished to determine which E2Fs and pocket proteins bind toand regulate expression of specific target genes in intact cellsunder physiological conditions. We felt that the use of an unperturbedin vivo system was of particular importance in the analysis ofE2F target gene specificity since regulation occurs in the contextof cell cycle progression which cannot be mimicked in vitro andwhich is often altered when individual E2F proteins are overexpressed.Toward this goal, we have used a formaldehyde cross-linking andimmunoprecipitation system to monitor protein-DNA and protein-proteininteractions on E2F target genes in living cells. Importantly,this procedure has allowed us to determine the in vivo patternsof E2F and pocket protein binding to specific E2F target genesas cells progress through a cell cycle. Our results indicate that,while some promoters fit the proposed model for E2F-mediated transcriptionalregulation, others do not, necessitating individualization ofthe current model. Furthermore, our data suggest that cell cycle-regulatedactivity is a stochastic event, as cells have the ability to formseveral different E2F-pocket protein complexes on a given promoterat each stage of the cellcycle.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Cell culture and synchronization. Cells were maintained in Dulbecco's modified Eagle medium (BRL-Life Technologies) supplemented with 5% bovine calf serum (BCS;BRL-Life Technologies) and 1% penicillin-streptomycin (BRL-LifeTechnologies) and grown in a 5% CO₂ incubator. NIH 3T3 cells whichhave been stably transfected with a plasmid containing a 290-bpregion of the murine DHFR promoter in which the E2F binding sitehas been mutated from TTTCGCGCCAAA to CCCTATATCAAA have been describedpreviously (26). For synchronization, cells were trypsinized(BRL-Life Technologies) and plated in starvation medium, Dulbecco'smodified Eagle medium supplemented with 0.5% BCS and 1% penicillin-streptomycin.After 60 h of growth in starvation medium, cells were either collectedas G₀-phase cells or stimulated to reenter the cell cycle by theaddition of serum to a final concentration of 10%. G₁-phase cellswere harvested at 8 h after serum stimulation, G₁/S-phase cellswere harvested at 12 h, and S-phase cells were harvested at 16h.

Replicate cultures of cells were trypsinized, fixed in ethanol, and stained with propidium iodide. Stained cells were analyzedon a FACS Caliber flow cytometer (Becton Dickinson) using CellQuestacquisition and analysis software. Pulse width and area allowedthe exclusion of doublets. Cell cycle percentages were calculatedwith ModFit 2.0 software (Verity SoftwareHouse).

RNA preparation and RT-PCR analysis. Cytoplasmic RNA was prepared from either asynchronously growing or replicate plates of synchronized NIH 3T3 cells as previouslydescribed (34). For reverse transcription-PCR (RT-PCR) analysis,each reaction mixture contained 100 ng of RNA, 1× EZ buffer (Perkin-Elmer),0.3 mM (each) deoxynucleoside triphosphates, 5 U of rTth DNA polymerase(Perkin-Elmer), 2.5 mM manganese acetate, and 4 nmol of each primerin a final reaction volume of 50 µl. Reaction mixtures were amplifiedfor 1 cycle of 60°C for 30 min and 95°C for 2 min and 35 cyclesof 95°C for 1 min, melting temperature of the primers for 2 min,and 60°C for 1 min followed by incubation at 60°C for 10 min.PCR products were resolved by electrophoresis through a 1.5% agarosegel and visualized by ethidium bromide staining. The sequencesof the primers used for RT-PCR analysis are as follows: TK1a,5'-CAGCATCTTGAACCTGGTGC-3'; TK1b, 5'-CTGAGAGGCAAAGAGCTTCC-3';GAPDH1, 5'-TGGCCAAGGTCATCCATGAC-3'; GAPDH2, 5'-ATGTAGGCCATGAGGTCCAC-3';cdc2a, 5'-CTTACACCAAATGCTCCAGG-3'; cdc2b, 5'-CGTTTGGCAGGATCATAGAC-3';dhfr1a, 5'-CCAGCATATGCACAGGGTAC-3'; dhfr1b, 5'-CTCTCGTCTCCATGGAACAC-3';cyclin E1a, 5'-GCAGAAGGTCTCAGGTTATC-3'; cyclin E1b, 5'-GTGGCCTCCTTAACTTCAAG-3';b-myb 1560, 5'-CTCTCCAGCTCCAGGGTATC-3'; and b-myb 1211, 5'-GCACTGCAGTCATCCCAGCA-3'.

Formaldehyde cross-linking and immunoprecipitation. Cells were formaldehyde cross-linked essentially as described previously (5). In brief, formaldehyde (Fisher Scientific)was added directly to tissue culture medium to a final concentrationof 1%. Cross-linking was allowed to proceed for 10 min at roomtemperature and was then stopped by the addition of glycine toa final concentration of 0.125 M. Cross-linked cells were trypsinized,scraped, washed with 1× phosphate-buffered saline, and swelledin RSB buffer (3 mM MgCl₂, 10 mM NaCl, 10 mM Tris-chloride [pH7.4], and 0.1% IGEPAL CA-330 [Sigma]). Nuclei were pelleted bymicrocentrifugation and lysed by incubation in nuclear lysis buffer(1% sodium dodecyl sulfate, 10 mM EDTA, 50 mM Tris-chloride [pH8.1], 0.5 mM phenylmethylsulfonyl fluoride, 100 ng of leupeptinper ml, and 100 ng of aprotinin per ml). The resulting chromatinsolution was sonicated for three 30-s pulses at maximum power.After microcentrifugation, the supernatant was precleared withblocked protein A-positive Staph cells (Boehringer Mannheim),diluted 1:5 with dilution buffer (0.01% sodium dodecyl sulfate,1.1% Triton X-100, 1.2 mM EDTA, 16.7 mM Tris-chloride [pH 8.1],167 mM NaCl, 0.5 mM phenylmethylsulfonyl fluoride, 100 ng of leupeptinper ml, and 100 ng of aprotinin per ml), and divided into aliquots.One microgram of antibody was added to each aliquot of chromatinand incubated on a rotating platform for 12 to 16 h at 4°C. Antibodiesagainst E2F and pocket proteins, E2F-1 (sc-193), E2F-2 (sc-633),E2F-3 (sc-879), E2F-4 (sc-866), E2F-5 (a cocktail of sc-1083 andsc-999), pRb (sc-1538), p107 (sc-318), and p130 (sc-317), werepurchased from Santa Cruz. Antibody-protein-DNA complexes wereisolated by immunoprecipitation with blocked protein A-positiveStaph A cells. Following extensive washing, bound DNA fragmentswere eluted and analyzed by subsequentPCR.

PCR analysis and Southern blotting. Immunoprecipitates were dissolved in 30 µl of water, except for input samples which were diluted in 100 µl and then furtherdiluted 1:100. Each reaction mixture contained 3 µl of immunoprecipitatedchromatin, 1× Taq reaction buffer (Promega), 1.5 mM MgCl₂, 50ng of each primer, 1.7 U of Taq polymerase (Promega), 200 µM (each)deoxynucleoside triphosphates (Boehringer Mannheim), and 1 M betaine(Sigma) in a final reaction volume of 20 µl. PCR mixtures wereamplified for 1 cycle of 95°C for 5 min, annealing temperatureof the primers for 5 min, and 72°C for 3 min and 34 to 36 cyclesof 95°C for 1 min, annealing temperature of the primers for 2min, and 72°C for 1.5 min. PCR products were separated by electrophoresisthrough a 1.5% agarose gel and visualized by ethidium bromideintercalation. Alternatively, immunoprecipitates were amplifiedfor 16 cycles of PCR, separated by electrophoresis on a 1.5% agarosegel, transferred to Hybond-N membranes (Amersham Life Science),and visualized by hybridization with a radiolabeled probe as previouslydescribed (4). Radiolabeled probes were generated by nick translatingPCR products created by amplification of genomic DNA using thesame primers as those used for analysis of the immunoprecipitates.Each experiment was performed a minimum of three times, and representativeresults are shown in Fig. 2, 3, 5, and 6. All of the log-phaseresults shown in Fig. 2A and 3 were generated using chromatinfrom the same experiment. Similarly, the results of Fig. 5 weregenerated using chromatin from one experiment, and the resultsof Fig. 6 were generated by PCR analysis of chromatin from a secondexperiment. The sequences of the primers used are as follows:myb+446, 5'-CAGAGCCAGGCCTCGCGCCTCATTG-3'; myb+858, 5'-TCAGGACTCAGGCTGCTCGAGCCGC-3';dhfr+962, 5'-CGGCAATCCTAGGGTGAAGGCTGGT-3'; dhfr+1360, 5'-GGCTCCATTCAGCGACGAAAGGTGC-3';cycE $-$ 134, 5'-AAGAACACGCCCCCCGGGAGGCCAC-3'; cycE+202, 5'-AAGCTGTGTCCGCCGCAGGCAGGCG-3';cdc2 $-$ 20, 5'-GGTAAAGCTCCCGGGATCCGCCAAT-3'; cdc2 $-$ 358, 5'-GTGGACTGTCACTTTGGTGGCTGGC-3';mAlb A, 5'-GGACACAAGACTTCTGAAAGTCCTC-3'; and mAlb B, 5'-TTCCTACCCCATTACAAAATCATA-3'.All primers were synthesized at the University of Wisconsin BiotechnologyCenter.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

E2F4 binding is localized to the DHFR promoter and requires an intact E2F binding site. In an effort to determine if specific E2Fs bind to specific target genes in vivo, we used a formaldehyde cross-linking assay(Fig. 1B) to monitor binding to the promoters of several E2F targetgenes in murine NIH 3T3 cells. Briefly, this protocol involvestreating cells with formaldehyde to cross-link the transcriptioncomplexes to the promoter DNA and immunoprecipitation of the protein-DNAcomplexes with an antibody against an individual E2F or pocketprotein followed by analysis of the immunoprecipitated DNA byPCR using promoter-specific primers (see Fig. 1C for the sequencesof analyzed E2F binding sites). Before analyzing the transcriptionalcomplexes bound to target gene promoters of interest, we firstwished to demonstrate the specificity of our cross-linking assay.We began by analyzing binding of E2F4, the most abundant E2F proteinin most cell types studied to date, to several regions of theDHFR gene (Fig. 2A). E2F4 binding was visualized by ethidium bromidestaining of the products obtained after 36 cycles of PCR amplificationand by Southern blotting of the PCR products obtained after 16cycles of PCR amplification. The results from both analyses arenearly identical and demonstrate that E2F4 bound to the DHFR promoterregion but not to either intron 2 or the 3' untranslated regionof the gene. Since binding of E2F4 was localized to the promoterregion of the DHFR gene, we next wished to determine if bindingof E2F4 was dependent upon the presence of an intact E2F bindingsite. Toward this goal, we utilized a line of NIH 3T3 cells whichhave been stably transfected with a plasmid containing a 290-bpregion of the DHFR promoter in which the sequence of the overlappingE2F binding sites has been mutated from TTTCGCGCCAAA to CCCTATATCAAA(Fig. 2B). PCR analysis of E2F4-immunoprecipitated chromatin fromthese cells showed that E2F4 bound to the endogenous DHFR promoterbut not to the integrated DHFR promoter construct bearing themutated E2F binding sites. Thus, formaldehyde cross-linking demonstratesthat binding of E2F4 is localized to the DHFR promoter and requiresan intact E2F binding site.

View larger version (25K):
[in this window]
[in a new window]

FIG. 2. E2F4 binding to the DHFR gene is promoter specific and requires an intact E2F binding site. As a demonstration of the specificity of our formaldehyde cross-linking assay, we monitored binding of E2F4 to three regions of the DHFR gene in NIH 3T3 cells (A) and to both the endogenous and integrated DHFR promoter construct in NIH 3T3 NW luc cells (B). Cross-linked chromatin from asynchronously growing cells was incubated with an antibody against E2F4 or in the absence of antibody (No Ab). Immunoprecipitates from each sample were analyzed by PCR using primers specific for different regions of the DHFR promoter. As a positive control, a sample representing 0.03% of the total input chromatin (input) was included in the PCRs. Additional controls include a precipitation lacking both antibody and chromatin (Water).

E2F target genes can be bound by multiple E2Fs and pocket proteins. Satisfied with the specificity of our cross-linking assay, we next determined which E2F proteins were bound to the b-myb,DHFR, TK, cdc2, and cyclin E promoters in asynchronously growingNIH 3T3 cells. We also analyzed E2F binding to the albumin promoter,which does not contain a consensus E2F binding site, nor is expressionof albumin thought to be regulated by E2F. As expected, we didnot detect binding of any E2F protein to the albumin promoter,as indicated by the lack of PCR signals in all lanes except forthe input positive control sample (Fig. 3A). However, we did detectE2F protein bound to each of the E2F target gene promoters. Ourresults suggest that very little binding specificity exists inasynchronous cells, as all five E2F proteins bound to a varietyof binding site sequences. For example, the binding patterns onthe TK and cdc2 promoters are similar and yet the TK promotercontains two inverted overlapping E2F binding sites while thecdc2 promoter contains one binding site with a sequence whichdiffers from both sites of the TK promoter. Interestingly, theintensity of the signals for the individual E2F proteins relativeto the input signal for the DHFR promoter was considerably weakerthan those for the other E2F target genes. This result was unexpected,since the DHFR E2F site is the only site which is composed oftwo perfect matches to the consensus binding site (Fig. 1C) andis a high-affinity site when analyzed using gel mobility shiftassays.

View larger version (36K):
[in this window]
[in a new window]

FIG. 3. E2F target genes lack E2F and pocket protein binding specificity in asynchronously growing NIH 3T3 cells. The figure shows analysis of E2F (A) and pocket protein (B) binding to E2F target genes in asynchronously growing NIH 3T3 cells. Cross-linked chromatin from asynchronously growing cells was incubated with antibodies against E2F1-5, pRb, p107, or p130 or in the absence of antibody (No Ab). Immunoprecipitates from each sample were analyzed by PCR using primers specific for the different promoters. As a control, a sample representing 0.03% of the total input chromatin (Input) was included in the PCRs. This ensures that a low signal (as in the case of the DHFR samples precipitated with pocket protein antibodies) is not due to failure of the PCRs. Additional controls included a precipitation lacking both antibody and chromatin (Mock) and a PCR control to which water was added instead of template DNA (Water). IP, immunoprecipitation.

Examination of pocket protein binding to the E2F target genes indicated that p107 and p130 were bound to the TK, cdc2, b-myb,and cyclin E promoters (Fig. 3B). In fact, the pocket proteinbinding patterns on these four promoters are indistinguishable.However, similar to the E2F results, we detected very weak signalsfor pocket protein binding to the DHFR promoter. The same immunoprecipitatedchromatin samples were used to monitor E2F and pocket proteinbinding to the DHFR promoter as were used to monitor binding tothe other target gene promoters. Therefore, the low signals onthe DHFR promoter are not due to variation between experimentsor technical difficulties with the cross-linking assay. As expected,we did not detect binding of any of the pocket proteins to thealbuminpromoter.

E2F binding patterns on target genes change as cells progress through the cell cycle. Genes containing E2F sites display cell cycle-stage-specific transcriptional regulation. Therefore, it was possible that weobserved multiple E2Fs bound to given target genes in asynchronouslygrowing cells because different E2Fs bound to the same promoterduring different stages of the cell cycle. To test this hypothesis,we synchronized mouse 3T3 cells using a serum starvation and stimulationprotocol and then treated the cells with formaldehyde at 0, 8,12, and 16 h after serum stimulation. For each experiment, replicatecultures of cells were ethanol fixed and stained with propidiumiodide and the DNA content of each population used in formaldehydecross-linking assays was determined by flow cytometry analysis.As shown in Fig. 4, NIH 3T3 cells were arrested and became quiescentafter 48 to 60 h of growth in low-serum (0.5%)-containing medium.Following stimulation with 10% serum, cells entered a cell growthcycle as indicated by the lateral movement of the fluorescencepeak. Although flow cytometry analysis is not able to distinguishquiescent and early G₁ cells from mid- to late-G₁-phase cells,the 16-h time points clearly indicate that cells reentered thecell cycle following the addition of serum and entered S phase.Immunoprecipitation of the chromatin using antibodies againstE2F1-5 was then performed, and the samples were assayed by PCRusing primers specific for the different target genes. In contrastto the data from asynchronous cells, we found that each E2F targetgene displayed a unique pattern of binding of the E2F family members(Fig. 5). For example, the b-myb promoter was occupied by E2F4after serum starvation with reduced signal intensity for E2F4at the G₁/S-phase boundary and no detectable binding during Sphase. These cross-linking results corroborate the previous invivo footprinting studies of b-myb (44) and extend the analysesby suggesting that E2F4 is the sole regulator of b-myb as quiescentcells are induced to proliferate. We found that the DHFR promoterwas occupied by E2F4 from quiescence through S phase but thatadditional E2Fs also bound to DHFR at specific times in the cellcycle. In quiescent cells, E2F5 bound to the DHFR promoter whileE2F1 binding was prominent only 8 h later. Again, these cross-linkingdata corroborate previous in vivo footprinting studies which showedthat one strand of the E2F site was constitutively occupied butthat the pattern of binding to the other strand changed as cellsprogressed through the cycle (41). Similar to b-myb, we observedthat E2F4 was the predominant E2F binding activity detected onthe TK, cdc2, and cyclin E promoters although faint signals fromthe other E2F proteins were visible.

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

FIG. 4. Synchronization of NIH 3T3 cells by serum starvation and stimulation. Cells were serum starved (0.5% BCS) for 48 to 60 h and then stimulated to reenter the cell cycle by the addition of 10% serum. At 0, 8, 12, and 16 h after serum stimulation, cells were trypsinized, ethanol fixed, and stained with propidium iodide. The DNA content of each population of cells was measured by flow cytometry analysis. As a reference, analysis of a population of asynchronous cells which were not starved and stimulated (log) is also included. IP, immunoprecipitation.

View larger version (32K):
[in this window]
[in a new window]

FIG. 5. Analysis of E2F binding to target genes in NIH 3T3 cells synchronized by a serum starvation and stimulation procedure. Cross-linked chromatin from synchronized cell populations was incubated with antibodies to E2F1-5 and analyzed as described in the Fig. 2 legend.

E2F target genes can be bound by Rb family members in all stages of the cell cycle. Inspection of the E2F binding pattern on the different promoters indicated that most promoters were predominantly bound byE2F4, suggesting that most E2F target genes could be regulatedby any of the three pocket proteins. To test this hypothesis,3T3 cells were treated with formaldehyde at various times in thecell cycle and then the chromatin was immunoprecipitated usingantibodies against Rb, p107, or p130 (see Fig. 6). Since previousgel shift analysis of extracts from NIH 3T3 (9) and other murine(18) cells detected pocket protein-containing complexes mainlyduring G₀ and early G₁ phase, we expected that the target promoterswould be immunoprecipitated with antibodies against the pocketproteins predominantly from quiescent cells. Accordingly, we foundthat all of the E2F target genes tested were bound by pocket proteinsin quiescent cells. However, the particular pocket protein boundduring quiescence as well as the pattern of pocket protein bindingto the promoter during the subsequent stages of the cell cyclevaried for each target gene. For example, we detected bindingof p130 and p107 to the b-myb promoter during quiescence and bindingof p107 during early G₁ but did not detect binding of any pocketproteins during subsequent stages of the cell cycle. In contrast,we detected binding of p107 and p130 to the cdc2 promoter fromquiescence through S phase in addition to binding of pRb fromlate G₁ through early S phase. We detected binding of p130 tothe cyclin E promoter from quiescence through S phase. We alsoobserved binding of pRb to the cyclin E promoter during quiescence,and binding persisted until cells entered S phase, at which pointp107 replaced pRb. Analysis of pocket protein binding to the DHFRpromoter revealed binding of pRb and p130 in quiescent cells.As cells reentered the cell cycle, we detected binding of p107and p130 to the DHFR promoter during G₁, binding of only pRb 4h later, and binding of all three pocket proteins in S-phase cells.In contrast to the other promoters tested, we observed bindingof all three pocket proteins to the TK promoter during quiescenceand loss of binding in mid-G₁. Once cells entered S phase, weagain detected binding of p107 to the TK promoter. As for Fig.5, all of the results in Fig. 6 were obtained from analysis ofchromatin from the same immunoprecipitation experiment. Therefore,the differences we detected were promoter specific and not dueto experimental variation.

View larger version (37K):
[in this window]
[in a new window]

FIG. 6. Analysis of pocket protein binding to target genes in synchronized cell populations. Cross-linked chromatin from synchronized cell populations was incubated with antibodies to the pocket proteins and analyzed as described in the Fig. 2 legend. IP, immunoprecipitation.

E2F and pocket proteins are bound to target gene promoters when the genes are being transcribed. Our results clearly showed binding of E2Fs and pocket proteins to certain promoters during S phase. Although E2F-pocket proteincomplexes have previously been observed for extracts preparedfrom S-phase cells (19, 27, 31, 32), it has remained unclearas to whether these complexes functioned to activate or to represstranscription of target genes. To address this question, we serumstarved NIH 3T3 cells and stimulated them to enter the growthcycle by the addition of serum. Flow cytometric analysis indicatedthat during serum starvation >94% of the cells had a 2N DNA contentand entered S phase by 16 h following serum stimulation (the S-phaseprofile is shown in Fig. 4). We prepared cytoplasmic RNA fromasynchronously growing cells and from cells collected at 0 and16 h following serum stimulation. RT-PCR analysis revealed thatexpression of b-myb, DHFR, TK, cdc2, and cyclin E was low in serum-starvedcells and increased during S phase (Fig. 7C). Therefore, as expectedbased on previous studies, there appeared to be higher transcriptionalactivity of all five target genes in S phase than in quiescentcells. In this same serum starvation and stimulation experiment,we also treated the cells with formaldehyde at 16 h and repeatedthe immunoprecipitation assay using antibodies against the fiveE2Fs and the three pocket proteins. In the experiments shown inFig. 5 and 6, the E2F and pocket protein binding had been analyzedusing chromatin that was immunoprecipitated in separate experimentsdue to the large number of different cell cycle stages examined.However, the use of all eight antibodies in a single experimenteliminates any possible variation in cell synchrony between experimentsand also allows a comparison of the S-phase binding patterns intwo separate experiments. In agreement with the results shownin Fig. 5 and 6, we detected S-phase binding of E2F and pocketprotein complexes to all of the promoters tested except for b-myb.Comparison of the results shown in Fig. 5, 6, and 7 demonstratesthat the cross-linking and immunoprecipitation assay is consistentand reproducible. Therefore, our results support the conclusionthat some E2F target promoters are bound by E2F-pocket proteincomplexes when they are transcriptionally active.

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

FIG. 7. Analysis of protein binding to and expression of target genes in S-phase cells. Cross-linked chromatin from synchronized S-phase cells was immunoprecipitated with antibodies against E2F1-5 (A) or pocket proteins (B) and analyzed as described in the Fig. 2 legend. Replicate plates of cells were harvested, and cytoplasmic RNA was prepared from these cells. Expression levels of target genes were measured by RT-PCR analysis of 100 ng of RNA from asynchronous log-phase cells, quiescent serum-starved cells (0 h), or S-phase cells (16 h) (C). IP, immunoprecipitation; GAPDH, glyceraldehyde-3-phosphate dehydrogenase.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Previous studies have investigated E2F target gene specificity by overexpressing exogenous E2F family members using eitherretroviruses (13) or transfection assays (33, 39). Althoughsuch studies have, in some cases, shown differential patternsof gene expression by the different E2Fs, the experimental designprecludes a conclusive interpretation of these studies. For example,exogenously introduced E2F can drive quiescent cells into S phase(33). Since E2F target genes show increased expression at theG₁/S-phase boundary, there is no way to determine if overexpressionof a particular E2F leads to direct activation of a particulartarget gene or if target gene activation is an indirect responsedue to cell proliferation. An alternative method for examiningE2F target gene specificity has been to prepare nuclear extractsand perform in vitro gel shift assays using antibodies againstthe E2F and pocket proteins to determine which E2F-pocket proteincomplex binds to an isolated E2F site (37, 41). Unfortunately,such studies often identify the most abundant E2F and pocket proteinbut do not necessarily reflect protein-DNA specificity. Due tothe shortcomings of overexpression and/or in vitro systems, wehave used an in vivo formaldehyde cross-linking assay to determinewhich endogenous E2F family members bind to specific E2F targetgenes at different stages of the cell cycle (summarized in Fig.8). Several conclusions can be drawn from our studies.

View larger version (38K):
[in this window]
[in a new window]

FIG. 8. Molecular snapshots of the transcription complexes formed on E2F target genes. Shown is a schematic summarizing the predominant E2F and pocket proteins detected on the b-myb, DHFR, TK, cdc2, and cyclin E promoters at different stages of the cell cycle. As noted in the text, the presence of multiple E2F or pocket proteins bound to the same promoter at a specific stage of the cell cycle does not necessitate that all proteins are bound to the same DNA site simultaneously or that all complexes are transcriptionally active. For simplicity, we have depicted the pocket proteins as being recruited by the E2F proteins. However, it remains possible that pocket proteins can be recruited to promoters via interaction with different DNA binding proteins.

(i) Binding patterns of E2F and pocket proteins are both promoter and cell cycle phase specific. Very little difference in binding site specificity has been observed between the different E2F proteins using in vitro assays.Accordingly, we found little difference in the E2F binding patternsof the individual promoters tested in log-phase cells, as mostpromoters were bound by several E2F proteins. In contrast to log-phasecells, our results clearly show different E2F binding patternson different target gene promoters during the first cell cyclefollowing serum starvation and stimulation. On the b-myb promoter,for example, we detected only binding of E2F4 in synchronizedcells, whereas on the DHFR promoter, we detected binding of E2F1,E2F4, and E2F5 and binding patterns changed as cells progressedfrom quiescence through S phase. Unexpectedly, we detected verylittle binding of E2F2 or E2F3 to any of the promoters testedin synchronized cells despite our observation that these E2F proteinsbound to several promoters in asynchronous cells. Using the samechromatin samples analyzed in Fig. 5, we have recently detectedrobust E2F2 and E2F3 binding to the retinoblastoma gene promoter(data not shown). Thus, our inability to detect binding of E2F2and E2F3 in the experiment shown in Fig. 5 does not appear tobe the result of a technical problem with the assay. At present,we cannot rule out the possibility that E2F2 or E2F3 is boundto one of the promoters we tested but in a conformation that isnot recognized by the antibodies we used. Our results also raisethe possibility that E2F binding patterns during the first cellcycle after serum starvation and stimulation may be differentfrom the E2F binding patterns during the cell cycles of proliferatingcells. Preliminary results of experiments comparing G₁-phase bindingpatterns in cells synchronized by serum starvation and stimulationwith G₁-phase cells isolated by fluorescence-activated cell sortingsuggest that binding patterns of certain E2F proteins in subsequentcell cycles are different for some promoters (data not shown),as previously proposed by Leone et al. (23).

Analogous to the E2F proteins, we observed that the pocket proteins also displayed promoter- and cell cycle phase-specificbinding patterns. For example, we detected binding of p107 andp130 to the b-myb promoter in G₀ phase but not during S phase.In contrast, we detected binding of pocket proteins to the DHFR,cdc2, and cyclin E promoters from quiescence through S phase.Thus, each promoter tested showed cell cycle variation in pocketprotein binding. We also found that p107 and p130 bound to allE2F target genes tested here (at some stage of the cell cycle)but that pRb did not bind to the b-myb promoter. Previously, Hurfordet al. studied the cell cycle-regulated expression of severalE2F target genes, including those tested here, in primary mouseembryo fibroblasts lacking pRb, p107, p130, or both p107 and p130(18). Our results are consistent with several aspects of thatprevious study. For example, Hurford et al. found that loss ofp107 or p130 alone did not alter the expression of any E2F targetgene analyzed but that expression of several E2F target geneswas altered by loss of both p107 and p130. Accordingly, we havefound that both p107 and p130 were bound to all E2F target genesexamined. Hurford et al. also found that cyclin E was one of onlytwo E2F target genes whose expression was deregulated in Rb nullcells, and we have shown that the cyclin E promoter is bound bypRb in vivo. However, our results are not completely consistentwith those of Hurford et al. For example, we found that the TKpromoter is bound by p107 and p130, but the previous studies didnot show an alteration in regulation of TK gene expression inthe p107-p130 null cells. It is possible that pocket proteinsmay bind to some promoters, such as TK, and yet not play a criticalrole in regulating expression of such genes. Alternatively, discrepanciesbetween our results and those of Hurford et al. could be due todifferences in E2F and pocket protein binding patterns in primarymouse embryo fibroblasts versus cultured NIH 3T3 cells, a possibilitywhich we are currentlytesting.

(ii) The standard model for E2F-mediated regulation does not reflect the E2F-pocket protein binding pattern for most E2F target genes. Previous studies have shown that the promoters analyzed in this study all show low transcriptional activity in G₀-phase cellsand high activity in late-G₁- and early-S-phase cells (3, 11,22, 30, 34, 43, 44). In agreement with previous studies,we found that mRNA levels of all of the genes that we tested herewere higher in S-phase cells than in serum-starved cells (Fig.7C). It has been commonly believed that the promoters tested herewere bound by E2F-pocket protein complexes in G₀ phase whereasthe E2F site was unoccupied in S phase. Many of the data usedto support this model of E2F-mediated regulation come from studiesof the b-myb promoter. Accordingly, we show that the b-myb promoterdoes show release of all DNA-bound E2F and pocket proteins duringS phase, the time at which the b-myb promoter is most active.However, various aspects of the binding patterns of the otherE2F target gene promoters analyzed here contradict elements ofthe current model. For example, the DHFR, cdc2, and cyclin E promotersare bound by E2F complexes both at the G₁/S-phase boundary andduring mid-S phase. Previously, it has been proposed that E2F4complexes would not be bound to promoters during S phase due totranslocation of E2F4 to the cytoplasm during S phase in somecell types (38). In contrast, others (24) have found thatthe amount of E2F4 in nuclear extracts is fairly constant duringprogression from G₀ to S phase. One possibility is that, whilenon-DNA-bound E2F4 is translocated to the cytoplasm during S phase,E2F4 that is part of a DNA-bound transcriptional complex remainsin the nucleus. In support of this hypothesis, Leone et al. foundthat the abundance of E2F4 DNA binding activity in nuclear extractsfrom synchronized REF52 cells did not change as cells enteredS phase despite their finding that >80% of E2F4 DNA binding activitywas cytoplasmic at this time (23).

Given the current view that hyperphosphorylation of pocket proteins during late G₁ phase leads to dissociation of pRb-, p107-,and p130-containing complexes from DNA, our finding that pocketproteins were bound to certain promoters through S phase was,at first, surprising. Although it could be argued that the pocketprotein binding that we detected during S phase is due to inefficientcell synchronization, we do not favor this explanation for severalreasons. First, flow cytometry analysis revealed that >95% ofthe cells analyzed in the experiments shown in Fig. 5 and 6 hadentered S phase by 16 h after serum stimulation (profiles shownin Fig. 4). Second, RT-PCR analysis showed that all of the genestested were highly expressed in our S-phase population of cells.Accordingly, we have also recently performed transfection studiesin NIH 3T3 cells which confirm that, under identical synchronizationconditions, the DHFR, b-myb, and cdc2 promoters are all more activein G₁/S- and S-phase cells than in G₀-phase cells (M. J. Oberleyand P. J. Farnham, unpublished data). Finally, we stress thatthe same chromatin samples used to show loss of E2F and pocketprotein binding to the b-myb promoter as cells entered S phasewere also used to show retention of E2F and pocket protein bindingto the other promoters. Our results are in agreement with thoseof Moberg et al., who detected complexes containing pRb and E2F4in human T cells only after cells had reached the G₁/S-phase boundary(27) as well as with the results of others who have detectedE2F-pRb complexes during S phase (19, 31). Additionally, ourobservation that pRb is bound to the cdc2, DHFR, and cyclin Epromoters at the G₁/S-phase boundary and during S phase is consistentwith data showing increased Rb promoter activity at these sametime points (14). Thus, we detected binding of pRb to the promotersof E2F target genes at a time when pRb protein is maximally abundant.The p107 promoter is also activated in late G₁ phase, resultingin peak p107 protein levels during late G₁ and early S phase (35).In contrast, p130 protein levels are maximal in G₀ phase, andyet we can detect binding of p130 to certain promoters throughoutthe cell cycle. Although the decrease in p130 levels after serumstimulation of starved cells may prevent new p130-containing transcriptionalcomplexes from forming on promoter DNA, the complexes that wedetected at later times in the cell cycle may represent stabletranscription complexes which were formed during quiescence orG₁. Evidence in support of the idea that, once formed, an E2F-pocketprotein complex can be long-lived comes from experiments showingthat transcription complexes can be stable even after severalrounds of DNA replication (40). Thus, it is possible, perhapseven likely, that a majority of the E2F-p130 complexes that wedetected during S phase represent stable complexes that were formedearlier in the cellcycle.

Our demonstration that most of the promoters tested here were bound by E2F-pocket protein complexes during mid-S phase raisesseveral interesting possibilities. For example, gene expressionmay be activated in only a small portion of S-phase cells (i.e.,those which do not have pocket proteins bound to the promoters).The strict requirement for the products of these genes for cellcycle progression, however, makes this scenario unlikely. An alternativehypothesis is that pocket proteins may not always serve as transcriptionalrepressors when bound to promoters. In support of this hypothesis,others have shown that Rb and p107 can interact with Sp1 (8,12), and evidence suggests that pRb may be an important activatorof certain promoters that contain Sp1 sites (8, 20, 36).Therefore, promoter-bound pocket proteins may act as docking platformsfor repressors in quiescent cells and activators in S-phase cells.Alternatively, pocket proteins bound to promoters in S phase mayhave a neutral effect on transcription, simply remaining boundto recruit repressors, such as histone deacetylases, during G₁phase of the following cellcycle.

(iii) Multiple complexes can be formed on an E2F target gene promoter. Clearly, E2F target genes are not regulated by a single, static transcription complex (Fig. 8). Rather, the E2Fs and pocketproteins bound to a given promoter during one stage of the cellcycle are not necessarily identical to the E2F and pocket proteinsbound to the same promoter in a different stage of the cell cycle.Interestingly, some promoters are bound by one of several differentE2F and pocket proteins at a given time during the cell cycle.For example, the DHFR promoter can be bound by either E2F4 orE2F5 in G₀-phase cells and by either E2F1 or E2F4 in mid-G₁-phasecells. At present, we cannot eliminate the possibility that morethan one E2F can bind to the same DNA site simultaneously. However,we favor the alternate interpretation that each cell in a synchronizedpopulation of cells has the potential to form several differenttranscription complexes and the actual complex which does formis a result of stochastic, not predetermined, events. Therefore,during mid-G₁ phase, the DHFR promoter in one cell may be occupiedby E2F1 whereas the DHFR promoter in an adjacent cell may be occupiedby E2F4. The presence of alternative transcription complexes ona given promoter at a given time in the cell cycle raises thevery intriguing possibility that different cells in a synchronizedpopulation may have different transcriptional profiles. Supportfor a stochastic model of transcriptional regulation comes fromprevious studies showing that a given promoter is activated onlyin a subset of the nuclei of multinucleated myofibers at a giventime, despite the fact that all the nuclei share a common cytoplasm(29). The ability to separate transcriptionally active complexesfrom transcriptionally inactive complexes prior to immunoprecipitationis required before an understanding of the role of the differentE2F-pocket complexes can be completelyunderstood.

In summary, analysis of in vivo DNA-protein interactions has allowed us to develop a molecular snapshot of the transcriptioncomplexes bound to different E2F target genes at different stagesof the cell cycle. Our results indicate that the accepted modelfor E2F-mediated gene regulation is applicable to only a subsetof E2F target genes. We are currently extending our use of theformaldehyde cross-linking assay toward the refinement of additionalmodels which more closely represent the molecular mechanisms bywhich cell cycle regulation of a variety of E2F target genes isachieved.

	ACKNOWLEDGMENTS

This work was supported in part by Public Health Service grant CA45240 (to P.J.F.) and training grants CA09681 (J.W.) andCA09135 (K.E.B. and C.J.F.) from the National Institutes ofHealth.

We thank Kathleen Schell, Kristin Elmer, and Janet Lewis for excellent technical assistance with flow cytometry analysis;members of the Farnham lab for helpful discussions; and Rick Maserfor critical reading of the manuscript. We also express our gratitudeto the laboratories of Mark Biggen, David Allis, and Richard Treismanfor sharing cross-linkingprotocols.

	ADDENDUM

While the manuscript was under review, a similar study reporting different results was published by Takahashi et al. (35a).It is possible that the discrepancies between the two studiesare due to promoter-specific variations. However, the b-myb promoterwas analyzed in both studies, and we detected robust binding ofonly E2F4 to the b-myb promoter in serum-starved and G₁-phasecells which disappeared as cells entered S phase. In contrast,Takahashi et al. observed very low levels of E2F binding to theb-myb promoter in G₀ and early G₁ cells. We would like to emphasizethat our cross-linking results are in agreement with previousin vivo footprinting analyses showing occupancy of the E2F sitewithin the b-myb promoter from G₀ through G₁ phase in serum-synchronizedNIH 3T3 cells (44). Strikingly, Takahashi et al. reported nobinding of E2F4 to promoters of target genes during S phase, whilewe observed robust S-phase binding of E2F4 to several target genepromoters. Since different antibodies had been used in the twostudies, we performed an additional cross-linking experiment todirectly compare the immunoprecipitation efficiencies of the E2F4antibody which we used for the results presented here (sc-866X;Santa Cruz) and of that used by Takahashi et al. (sc-1082X; SantaCruz). Our results indicated that both antibodies detected bindingof E2F4 to several different promoters in synchronized NIH 3T3cells but that the sc-1082X antibody generated a noticeably weakersignal on some promoters, and this difference was most pronouncedin S-phase cells (data not shown). Finally, the differences inour results and those of Takahashi et al. could be species specific,as we used immortalized murine cells (NIH 3T3) while they useda human glioblastoma cell line (T98G). Recent cross-linking experiments(data not shown) have confirmed binding of E2F proteins, particularlyE2F4, to multiple promoters during S phase in aphidicolin-synchronizedHeLa and Raji cells, both of which are human tumor cell lines.It remains possible that expression of E2F target genes in T98Gcells may be mediated by different E2F proteins than those inother human or murine celllines.

	FOOTNOTES

^* Corresponding author. Mailing address: McArdle Laboratory for Cancer Research, University of Wisconsin Medical School, Madison,WI 53706. Phone: (608) 262-2071. Fax: (608) 262-2824. E-mail:farnham{at}oncology.wisc.edu.

Present address: Department of Pathology, Yale University School of Medicine, New Haven, CT06520.

Present address: Program in Molecular Medicine, University of Massachusetts Medical Center, Worcester, MA01605.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Bagchi, S., R. Weinmann, and P. Raychaudhuri. 1991. The retinoblastoma protein copurifies with E2F-1, an E1A-regulated inhibitor of the transcription factor E2F. Cell 65:1063-1072[CrossRef][Medline].

2. Bandara, L. R., J. P. Adamczewski, T. Hunt, and N. B. La Thangue. 1991. Cyclin A and the retinoblastoma gene product complex with a common transcription factor. Nature 352:249-251[CrossRef][Medline].

3. Botz, J., K. Zerfass-Thome, D. Spitkovsky, H. Delius, B. Vogt, M. Eilers, A. Hatzigeorgiou, and P. Jansen-Dürr. 1996. Cell cycle regulation of the murine cyclin E gene depends on an E2F binding site in the promoter. Mol. Cell. Biol. 16:3401-3409[Abstract].

4. Boyd, K. E., and P. J. Farnham. 1997. Myc versus USF: discrimination at the cad gene is determined by core promoter elements. Mol. Cell. Biol. 17:2529-2537[Abstract].

5. Boyd, K. E., J. Wells, J. Gutman, S. M. Bartley, and P. J. Farnham. 1998. c-Myc target gene specificity is determined by a post-DNA-binding mechanism. Proc. Natl. Acad. Sci. USA 95:13887-13892[Abstract/Free Full Text].

6. Brehm, A., E. A. Miska, D. J. McCance, J. L. Reid, A. J. Bannister, and T. Kouzarides. 1998. Retinoblastoma protein recruits histone deacetylase to repress transcription. Nature 391:597-601[CrossRef][Medline].

7. Chellappan, S. P., S. W. Hiebert, M. Mudryj, J. M. Horowitz, and J. R. Nevins. 1991. The E2F transcription factor is a cellular target for the RB protein. Cell 65:1053-1061[CrossRef][Medline].

8. Chen, L. I., T. Nishinaka, K. Kwan, I. Kitabayashi, K. Yokoyama, Y.-H. F. Fu, S. Grunwald, and R. Chiu. 1994. The retinoblastoma gene product RB stimulates Sp1-mediated transcription by liberating Sp1 from a negative regulator. Mol. Cell. Biol. 14:4380-4389[Abstract/Free Full Text].

9. Chen, X., and R. Prywes. 1999. Serum-Induced expression of the cdc25A gene by relief of E2F-mediated repression. Mol. Cell. Biol. 19:4695-4702[Abstract/Free Full Text].

10. Cobrinik, D., P. Whyte, D. S. Peeper, T. Jacks, and R. A. Weinberg. 1993. Cell cycle-specific association of E2F with the p130 E1A-binding protein. Genes Dev. 7:2392-2404[Abstract/Free Full Text].

11. Dalton, S. 1992. Cell cycle regulation of the human cdc2 gene. EMBO J. 11:1797-1804[Medline].

12. Datta, P. K., P. Raychaudhuri, and S. Bagchi. 1995. Association of p107 with Sp1: genetically separable regions of p107 are involved in regulation of E2F- and Sp1-dependent transcription. Mol. Cell. Biol. 15:5444-5452[Abstract].

13. DeGregori, J., G. Leone, A. Miron, L. Jakoi, and J. R. Nevins. 1997. Distinct roles for E2F proteins in cell growth control and apoptosis. Proc. Natl. Acad. Sci. USA 94:7245-7250[Abstract/Free Full Text].

14. DiFiore, B., A. Palena, A. Felsani, F. Palitti, M. Caruso, and P. Lavia. 1999. Cytosine methylation transforms an E2F site in the retinoblastoma gene promoter into a binding site for the general repressor methylcytosine-binding protein 2 (MeCP2). Nucleic Acids Res. 27:2852-2859[Abstract/Free Full Text].

15. Dynlacht, B. D., O. Flores, J. A. Lees, and E. Harlow. 1994. Differential regulation of E2F transactivation by cyclin/cdk2 complexes. Genes Dev. 8:1772-1786[Abstract/Free Full Text].

16. Dyson, N. 1998. The regulation of E2F by pRB-family proteins. Genes Dev. 12:2245-2262[Free Full Text].

17. Ferreira, R., L. Magnaghi-Jaulin, P. Robin, A. Harel-Bellan, and D. Trouche. 1998. The three members of the pocket proteins family share the ability to repress E2F activity through recruitment of a histone deacetylase. Proc. Natl. Acad. Sci. USA 95:10493-10498[Abstract/Free Full Text].

18. Hurford, R. K. J., D. Cobrinik, M.-H. Lee, and N. Dyson. 1997. pRB and p107/p130 are required for the regulated expression of different sets of E2F responsive genes. Genes Dev. 11:1447-1463[Abstract/Free Full Text].

19. Ikeda, M.-A., L. Jakoi, and J. R. Nevins. 1996. A unique role for the Rb protein in controlling E2F accumulation during cell growth and differentiation. Proc. Natl. Acad. Sci. USA 93:3215-3220[Abstract/Free Full Text].

20. Kim, S.-J., U. S. Onwuta, Y. I. Lee, R. Li, M. R. Botchan, and P. D. Robbins. 1992. The retinoblastoma gene product regulates Sp1-mediated transcription. Mol. Cell. Biol. 12:2455-2463[Abstract/Free Full Text].

21. Krek, W., M. E. Ewen, S. Shirodkar, Z. Arany, W. G. J. Kaelin, and D. M. Livingston. 1994. Negative regulation of the growth-promoting transcription factor E2F-1 by a stably bound cyclin A-dependent protein kinase. Cell 78:161-172[CrossRef][Medline].

22. Lam, E. W.-F., and R. J. Watson. 1993. An E2F-binding site mediates cell-cycle regulated repression of mouse B-myb transcription. EMBO J. 12:2705-2713[Medline].

23. Leone, G., J. DeGregori, Z. Yan, L. Jakoi, S. Ishida, R. S. Williams, and J. R. Nevins. 1998. E2F3 activity is regulated during the cell cycle and is required for the induction of S phase. Genes Dev. 12:2120-2130[Abstract/Free Full Text].

24. Lindeman, G. J., S. Gaubatz, D. M. Livingston, and D. Ginsberg. 1997. The subcellular localization of E2F-4 is cell cycle dependent. Proc. Natl. Acad. Sci. USA 94:5095-5100[Abstract/Free Full Text].

25. Magnaghi-Jaulin, L., R. Groisman, I. Naguibneva, P. Robin, S. Lorain, J. P. Villain, F. Troalen, D. Trouche, and A. Harel-Bellan. 1998. Retinoblastoma protein represses transcription by recruiting a histone deacetylase. Nature 391:601-605[CrossRef][Medline].

26. Means, A. L. 1991. Ph.D. Thesis. University of Wisconsin, Madison.

27. Moberg, K., M. A. Starz, and J. A. Lees. 1996. E2F-4 switches from p130 to p107 and pRB in response to cell cycle reentry. Mol. Cell. Biol. 16:1436-1449[Abstract].

28. Müller, H., M. Moroni, E. Vigo, B. O. Peterson, J. H. Barteck, and K. Helin. 1997. Induction of S-phase entry by E2F transcription factors depends on their nuclear localization. Mol. Cell. Biol. 17:5508-5520[Abstract].

29. Newlands, S., L. K. Levitt, C. S. Robinson, A. B. C. Karpf, V. R. M. Hodgson, R. P. Wade, and E. C. Hardeman. 1998. Transcription occurs in pulses in muscle fibers. Genes Dev. 12:2748-2758[Abstract/Free Full Text].

30. Ogris, E., H. Rotheneder, I. Mudrak, A. Pichler, and E. Wintersberger. 1993. A binding site for transcription factor E2F is a target for trans activation of murine thymidine kinase by polyomavirus large T antigen and plays an important role in growth regulation of the gene. J. Virol. 67:1765-1771[Abstract/Free Full Text].

31. Schwarz, J. K., S. H. Devoto, E. J. Smith, S. P. Chellappan, L. Jakoi, and J. R. Nevins. 1993. Interactions of the p107 and Rb proteins with E2F during the cell proliferation response. EMBO J. 12:1013-1020[Medline].

32. Shirodkar, S., M. Ewen, J. A. DeCaprio, J. Morgan, D. M. Livingston, and T. Chittenden. 1992. The transcription factor E2F interacts with the retinoblastoma product and a p107-cyclin A complex in a cell cycle-regulated manner. Cell 68:157-166[CrossRef][Medline].

33. Slansky, J. E., and P. J. Farnham. 1996. Introduction to the E2F family: protein structure and gene regulation, p. 1-30. In P. J. Farnham (ed.), Transcriptional control of cell growth: the E2F gene family. Springer-Verlag, New York, N.Y.

34. Slansky, J. E., Y. Li, W. G. Kaelin, and P. J. Farnham. 1993. A protein synthesis-dependent increase in E2F1 mRNA correlates with growth regulation of the dihydrofolate reductase promoter. Mol. Cell. Biol. 13:1610-1618[Abstract/Free Full Text]. (Author's correction, 13:7201.)

35. Smith, E. J., G. Leone, and J. R. Nevins. 1998. Distinct mechanisms control the accumulation of the Rb-related p107 and p130 proteins during cell growth. Cell Growth Differ. 9:297-303[Abstract].

35a. Takahashi, Y., J. B. Rayman, and B. D. Dynlacht. 2000. Analysis of promoter binding by the E2F and pRB families in vivo: proteins mediate activation and repression. Genes Dev. 14:804-816[Abstract/Free Full Text].

36. Udvadia, A. J., K. T. Rogers, P. D. R. Higgins, Y. Murata, K. H. Martin, P. A. Humphrey, and J. M. Horowitz. 1993. Sp-1 binds promoter elements regulated by the RB protein and Sp-1-mediated transcription is stimulated by RB coexpression. Proc. Natl. Acad. Sci. USA 90:3265-3269[Abstract/Free Full Text].

37. van der Sman, J., N. S. B. Thomas, and E. W.-F. Lam. 1999. Modulation of E2F complexes during G0 to S phase transition in human primary B-lymphocytes. J. Biol. Chem. 274:12009-12016[Abstract/Free Full Text].

38. Verona, R., K. Moberg, S. Estes, M. Starz, J. P. Vernon, and J. A. Lees. 1997. E2F activity is regulated by cell cycle-dependent changes in subcellular localization. Mol. Cell. Biol. 17:7268-7282[Abstract].

39. Watanabe, G., C. Albanese, R. J. Lee, A. Reutens, G. Vairo, B. Henglein, and R. G. Pestell. 1998. Inhibition of cyclin D1 kinase activity is associated with E2F-mediated inhibition of cyclin D1 promoter activity through E2F and Sp1. Mol. Cell. Biol. 18:3212-3222[Abstract/Free Full Text].

40. Weintraub, H. 1988. Formation of stable transcription complexes as assayed by analysis of individual templates. Proc. Natl. Acad. Sci. USA 85:5819-5823[Abstract/Free Full Text].

41. Wells, J., P. Held, S. Illenye, and N. H. Heintz. 1996. Protein-DNA interactions at the major and minor promoters of the divergently transcribed dhfr and rep3 genes during the Chinese hamster ovary cell cycle. Mol. Cell. Biol. 16:634-647[Abstract].

42. Xu, M., K. A. Sheppard, C. Y. Peng, A. S. Yee, and H. Piwnica-Worms. 1994. Cyclin A/CDK2 binds directly to E2F-1 and inhibits the DNA-binding activity of E2F-1/DP-1 by phosphorylation. Mol. Cell. Biol. 14:8420-8431[Abstract/Free Full Text].

43. Zacksenhaus, E., R. A. Phillips, and B. L. Gallie. 1993. Molecular cloning and characterisation of the RB1 promoter. Oncogene 8:2343-2351[Medline].

44. Zwicker, J., N. Liu, K. Engeland, F. C. Lucibello, and R. Müller. 1996. Cell cycle regulation of E2F site occupation in vivo. Science 271:1595-1597[Abstract].

This article has been cited by other articles:

Seifried, L. A., Talluri, S., Cecchini, M., Julian, L. M., Mymryk, J. S., Dick, F. A. (2008). pRB-E2F1 Complexes Are Resistant to Adenovirus E1A-Mediated Disruption. J. Virol. 82: 4511-4520 [Abstract] [Full Text]
Bhardwaj, A., Rao, M. K., Kaur, R., Buttigieg, M. R., Wilkinson, M. F. (2008). GATA Factors and Androgen Receptor Collaborate To Transcriptionally Activate the Rhox5 Homeobox Gene in Sertoli Cells. Mol. Cell. Biol. 28: 2138-2153 [Abstract] [Full Text]
Saenz-Robles, M. T., Markovics, J. A., Chong, J.-L., Opavsky, R., Whitehead, R. H., Leone, G., Pipas, J. M. (2007). Intestinal Hyperplasia Induced by Simian Virus 40 Large Tumor Antigen Requires E2F2. J. Virol. 81: 13191-13199 [Abstract] [Full Text]
Rathi, A. V., Saenz Robles, M. T., Pipas, J. M. (2007). Enterocyte Proliferation and Intestinal Hyperplasia Induced by Simian Virus 40 T Antigen Require a Functional J Domain. J. Virol. 81: 9481-9489 [Abstract] [Full Text]
Gunawardena, R. W., Fox, S. R., Siddiqui, H., Knudsen, E. S. (2007). SWI/SNF Activity Is Required for the Repression of Deoxyribonucleotide Triphosphate Metabolic Enzymes via the Recruitment of mSin3B. J. Biol. Chem. 282: 20116-20123 [Abstract] [Full Text]
Yochum, G. S., Cleland, R., McWeeney, S., Goodman, R. H. (2007). An Antisense Transcript Induced by Wnt/beta-Catenin Signaling Decreases E2F4. J. Biol. Chem. 282: 871-878 [Abstract] [Full Text]
Lin, S., Saxena, N. K., Ding, X., Stein, L. L., Anania, F. A. (2006). Leptin Increases Tissue Inhibitor of Metalloproteinase I (TIMP-1) Gene Expression by a Specificity Protein 1/Signal Transducer and Activator of Transcription 3 Mechanism. Mol. Endocrinol. 20: 3376-3388 [Abstract] [Full Text]
Weitsman, G. E., Li, L., Skliris, G. P., Davie, J. R., Ung, K., Niu, Y., Curtis-Snell, L., Tomes, L., Watson, P. H., Murphy, L. C. (2006). Estrogen Receptor-{alpha} Phosphorylated at Ser118 Is Present at the Promoters of Estrogen-Regulated Genes and Is Not Altered Due to HER-2 Overexpression.. Cancer Res. 66: 10162-10170 [Abstract] [Full Text]
Chung, H.-J., Liu, J., Dundr, M., Nie, Z., Sanford, S., Levens, D. (2006). FBPs Are Calibrated Molecular Tools To Adjust Gene Expression.. Mol. Cell. Biol. 26: 6584-6597 [Abstract] [Full Text]
Rodriguez, J. M., Glozak, M. A., Ma, Y., Cress, W. D. (2006). Bok, Bcl-2-related Ovarian Killer, Is Cell Cycle-regulated and Sensitizes to Stress-induced Apoptosis. J. Biol. Chem. 281: 22729-22735 [Abstract] [Full Text]
Harbour, J. W. (2006). Eye Cancer: Unique Insights into Oncogenesis The Cogan Lecture. IOVS 47: 1737-1745 [Full Text]
Banchio, C., Lingrell, S., Vance, D. E. (2006). Role of Histone Deacetylase in the Expression of CTP:Phosphocholine Cytidylyltransferase {alpha}. J. Biol. Chem. 281: 10010-10015 [Abstract] [Full Text]
Gritsko, T., Williams, A., Turkson, J., Kaneko, S., Bowman, T., Huang, M., Nam, S., Eweis, I., Diaz, N., Sullivan, D., Yoder, S., Enkemann, S., Eschrich, S., Lee, J.-H., Beam, C. A., Cheng, J., Minton, S., Muro-Cacho, C. A., Jove, R. (2006). Persistent Activation of Stat3 Signaling Induces Survivin Gene Expression and Confers Resistance to Apoptosis in Human Breast Cancer Cells. Clin. Cancer Res. 12: 11-19 [Abstract] [Full Text]
Park, S., Kim, D., Kaneko, S., Szewczyk, K. M., Nicosia, S. V., Yu, H., Jove, R., Cheng, J. Q. (2005). Molecular Cloning and Characterization of the Human AKT1 Promoter Uncovers Its Up-regulation by the Src/Stat3 Pathway. J. Biol. Chem. 280: 38932-38941 [Abstract] [Full Text]
Verlinden, L., Eelen, G., Beullens, I., Van Camp, M., Van Hummelen, P., Engelen, K., Van Hellemont, R., Marchal, K., De Moor, B., Foijer, F., Riele, H. T., Beullens, M., Bollen, M., Mathieu, C., Bouillon, R., Verstuyf, A. (2005). Characterization of the Condensin Component Cnap1 and Protein Kinase Melk as Novel E2F Target Genes Down-regulated by 1,25-Dihydroxyvitamin D3. J. Biol. Chem. 280: 37319-37330 [Abstract] [Full Text]
Minuzzo, M., Ceribelli, M., Pitarque-Marti, M., Borrelli, S., Erba, E., diSilvio, A., D'Incalci, M., Mantovani, R. (2005). Selective Effects of the Anticancer Drug Yondelis (ET-743) on Cell-Cycle Promoters. Mol. Pharmacol. 68: 1496-1503 [Abstract] [Full Text]
Yatsula, B., Lin, S., Read, A. J., Poholek, A., Yates, K., Yue, D., Hui, P., Perkins, A. S. (2005). Identification of Binding Sites of EVI1 in Mammalian Cells. J. Biol. Chem. 280: 30712-30722 [Abstract] [Full Text]
Imbriano, C., Gurtner, A., Cocchiarella, F., Di Agostino, S., Basile, V., Gostissa, M., Dobbelstein, M., Del Sal, G., Piaggio, G., Mantovani, R. (2005). Direct p53 Transcriptional Repression: In Vivo Analysis of CCAAT-Containing G2/M Promoters. Mol. Cell. Biol. 25: 3737-3751 [Abstract] [Full Text]
Zhu, X., Jiang, J., Shen, H., Wang, H., Zong, H., Li, Z., Yang, Y., Niu, Z., Liu, W., Chen, X., Hu, Y., Gu, J. (2005). Elevated {beta}1,4-Galactosyltransferase I in Highly Metastatic Human Lung Cancer Cells: IDENTIFICATION OF E1AF AS IMPORTANT TRANSCRIPTION ACTIVATOR. J. Biol. Chem. 280: 12503-12516 [Abstract] [Full Text]
Lieman, J. H., Worley, L. A., Harbour, J. W. (2005). Loss of Rb-E2F Repression Results in Caspase-8-mediated Apoptosis through Inactivation of Focal Adhesion Kinase. J. Biol. Chem. 280: 10484-10490 [Abstract] [Full Text]
Chang, W. Y., Bryce, D. M., D'Souza, S. J. A., Dagnino, L. (2004). The DP-1 Transcription Factor Is Required for Keratinocyte Growth and Epidermal Stratification. J. Biol. Chem. 279: 51343-51353 [Abstract] [Full Text]
Caretti, G., Di Padova, M., Micales, B., Lyons, G. E., Sartorelli, V. (2004). The Polycomb Ezh2 methyltransferase regulates muscle gene expression and skeletal muscle differentiation. Genes Dev. 18: 2627-2638 [Abstract] [Full Text]
Lavrrar, J. L., Farnham, P. J. (2004). The Use of Transient Chromatin Immunoprecipitation Assays to Test Models for E2F1-specific Transcriptional Activation. J. Biol. Chem. 279: 46343-46349 [Abstract] [Full Text]
Taylor-Harding, B., Binne, U. K., Korenjak, M., Brehm, A., Dyson, N. J. (2004). p55, the Drosophila Ortholog of RbAp46/RbAp48, Is Required for the Repression of dE2F2/RBF-Regulated Genes. Mol. Cell. Biol. 24: 9124-9136 [Abstract] [Full Text]
Hlaing, M., Spitz, P., Padmanabhan, K., Cabezas, B., Barker, C. S., Bernstein, H. S. (2004). E2F-1 Regulates the Expression of a Subset of Target Genes during Skeletal Myoblast Hypertrophy. J. Biol. Chem. 279: 43625-43633 [Abstract] [Full Text]
Friedman, J. R., Larris, B., Le, P. P., Peiris, T. H., Arsenlis, A., Schug, J., Tobias, J. W., Kaestner, K. H., Greenbaum, L. E. (2004). Orthogonal analysis of C/EBP{beta} targets in vivo during liver proliferation. Proc. Natl. Acad. Sci. USA 101: 12986-12991 [Abstract] [Full

1.	Bagchi, S., R. Weinmann, and P. Raychaudhuri. 1991. The retinoblastoma protein copurifies with E2F-1, an E1A-regulated inhibitor of the transcription factor E2F. Cell 65:1063-1072[CrossRef][Medline].
2.	Bandara, L. R., J. P. Adamczewski, T. Hunt, and N. B. La Thangue. 1991. Cyclin A and the retinoblastoma gene product complex with a common transcription factor. Nature 352:249-251[CrossRef][Medline].
3.	Botz, J., K. Zerfass-Thome, D. Spitkovsky, H. Delius, B. Vogt, M. Eilers, A. Hatzigeorgiou, and P. Jansen-Dürr. 1996. Cell cycle regulation of the murine cyclin E gene depends on an E2F binding site in the promoter. Mol. Cell. Biol. 16:3401-3409[Abstract].
4.	Boyd, K. E., and P. J. Farnham. 1997. Myc versus USF: discrimination at the cad gene is determined by core promoter elements. Mol. Cell. Biol. 17:2529-2537[Abstract].
5.	Boyd, K. E., J. Wells, J. Gutman, S. M. Bartley, and P. J. Farnham. 1998. c-Myc target gene specificity is determined by a post-DNA-binding mechanism. Proc. Natl. Acad. Sci. USA 95:13887-13892[Abstract/Free Full Text].
6.	Brehm, A., E. A. Miska, D. J. McCance, J. L. Reid, A. J. Bannister, and T. Kouzarides. 1998. Retinoblastoma protein recruits histone deacetylase to repress transcription. Nature 391:597-601[CrossRef][Medline].
7.	Chellappan, S. P., S. W. Hiebert, M. Mudryj, J. M. Horowitz, and J. R. Nevins. 1991. The E2F transcription factor is a cellular target for the RB protein. Cell 65:1053-1061[CrossRef][Medline].
8.	Chen, L. I., T. Nishinaka, K. Kwan, I. Kitabayashi, K. Yokoyama, Y.-H. F. Fu, S. Grunwald, and R. Chiu. 1994. The retinoblastoma gene product RB stimulates Sp1-mediated transcription by liberating Sp1 from a negative regulator. Mol. Cell. Biol. 14:4380-4389[Abstract/Free Full Text].
9.	Chen, X., and R. Prywes. 1999. Serum-Induced expression of the cdc25A gene by relief of E2F-mediated repression. Mol. Cell. Biol. 19:4695-4702[Abstract/Free Full Text].
10.	Cobrinik, D., P. Whyte, D. S. Peeper, T. Jacks, and R. A. Weinberg. 1993. Cell cycle-specific association of E2F with the p130 E1A-binding protein. Genes Dev. 7:2392-2404[Abstract/Free Full Text].
11.	Dalton, S. 1992. Cell cycle regulation of the human cdc2 gene. EMBO J. 11:1797-1804[Medline].
12.	Datta, P. K., P. Raychaudhuri, and S. Bagchi. 1995. Association of p107 with Sp1: genetically separable regions of p107 are involved in regulation of E2F- and Sp1-dependent transcription. Mol. Cell. Biol. 15:5444-5452[Abstract].
13.	DeGregori, J., G. Leone, A. Miron, L. Jakoi, and J. R. Nevins. 1997. Distinct roles for E2F proteins in cell growth control and apoptosis. Proc. Natl. Acad. Sci. USA 94:7245-7250[Abstract/Free Full Text].
14.	DiFiore, B., A. Palena, A. Felsani, F. Palitti, M. Caruso, and P. Lavia. 1999. Cytosine methylation transforms an E2F site in the retinoblastoma gene promoter into a binding site for the general repressor methylcytosine-binding protein 2 (MeCP2). Nucleic Acids Res. 27:2852-2859[Abstract/Free Full Text].
15.	Dynlacht, B. D., O. Flores, J. A. Lees, and E. Harlow. 1994. Differential regulation of E2F transactivation by cyclin/cdk2 complexes. Genes Dev. 8:1772-1786[Abstract/Free Full Text].
16.	Dyson, N. 1998. The regulation of E2F by pRB-family proteins. Genes Dev. 12:2245-2262[Free Full Text].
17.	Ferreira, R., L. Magnaghi-Jaulin, P. Robin, A. Harel-Bellan, and D. Trouche. 1998. The three members of the pocket proteins family share the ability to repress E2F activity through recruitment of a histone deacetylase. Proc. Natl. Acad. Sci. USA 95:10493-10498[Abstract/Free Full Text].
18.	Hurford, R. K. J., D. Cobrinik, M.-H. Lee, and N. Dyson. 1997. pRB and p107/p130 are required for the regulated expression of different sets of E2F responsive genes. Genes Dev. 11:1447-1463[Abstract/Free Full Text].
19.	Ikeda, M.-A., L. Jakoi, and J. R. Nevins. 1996. A unique role for the Rb protein in controlling E2F accumulation during cell growth and differentiation. Proc. Natl. Acad. Sci. USA 93:3215-3220[Abstract/Free Full Text].
20.	Kim, S.-J., U. S. Onwuta, Y. I. Lee, R. Li, M. R. Botchan, and P. D. Robbins. 1992. The retinoblastoma gene product regulates Sp1-mediated transcription. Mol. Cell. Biol. 12:2455-2463[Abstract/Free Full Text].
21.	Krek, W., M. E. Ewen, S. Shirodkar, Z. Arany, W. G. J. Kaelin, and D. M. Livingston. 1994. Negative regulation of the growth-promoting transcription factor E2F-1 by a stably bound cyclin A-dependent protein kinase. Cell 78:161-172[CrossRef][Medline].
22.	Lam, E. W.-F., and R. J. Watson. 1993. An E2F-binding site mediates cell-cycle regulated repression of mouse B-myb transcription. EMBO J. 12:2705-2713[Medline].
23.	Leone, G., J. DeGregori, Z. Yan, L. Jakoi, S. Ishida, R. S. Williams, and J. R. Nevins. 1998. E2F3 activity is regulated during the cell cycle and is required for the induction of S phase. Genes Dev. 12:2120-2130[Abstract/Free Full Text].
24.	Lindeman, G. J., S. Gaubatz, D. M. Livingston, and D. Ginsberg. 1997. The subcellular localization of E2F-4 is cell cycle dependent. Proc. Natl. Acad. Sci. USA 94:5095-5100[Abstract/Free Full Text].
25.	Magnaghi-Jaulin, L., R. Groisman, I. Naguibneva, P. Robin, S. Lorain, J. P. Villain, F. Troalen, D. Trouche, and A. Harel-Bellan. 1998. Retinoblastoma protein represses transcription by recruiting a histone deacetylase. Nature 391:601-605[CrossRef][Medline].
26.	Means, A. L. 1991. Ph.D. Thesis. University of Wisconsin, Madison.
27.	Moberg, K., M. A. Starz, and J. A. Lees. 1996. E2F-4 switches from p130 to p107 and pRB in response to cell cycle reentry. Mol. Cell. Biol. 16:1436-1449[Abstract].
28.	Müller, H., M. Moroni, E. Vigo, B. O. Peterson, J. H. Barteck, and K. Helin. 1997. Induction of S-phase entry by E2F transcription factors depends on their nuclear localization. Mol. Cell. Biol. 17:5508-5520[Abstract].
29.	Newlands, S., L. K. Levitt, C. S. Robinson, A. B. C. Karpf, V. R. M. Hodgson, R. P. Wade, and E. C. Hardeman. 1998. Transcription occurs in pulses in muscle fibers. Genes Dev. 12:2748-2758[Abstract/Free Full Text].
30.	Ogris, E., H. Rotheneder, I. Mudrak, A. Pichler, and E. Wintersberger. 1993. A binding site for transcription factor E2F is a target for trans activation of murine thymidine kinase by polyomavirus large T antigen and plays an important role in growth regulation of the gene. J. Virol. 67:1765-1771[Abstract/Free Full Text].
31.	Schwarz, J. K., S. H. Devoto, E. J. Smith, S. P. Chellappan, L. Jakoi, and J. R. Nevins. 1993. Interactions of the p107 and Rb proteins with E2F during the cell proliferation response. EMBO J. 12:1013-1020[Medline].
32.	Shirodkar, S., M. Ewen, J. A. DeCaprio, J. Morgan, D. M. Livingston, and T. Chittenden. 1992. The transcription factor E2F interacts with the retinoblastoma product and a p107-cyclin A complex in a cell cycle-regulated manner. Cell 68:157-166[CrossRef][Medline].
33.	Slansky, J. E., and P. J. Farnham. 1996. Introduction to the E2F family: protein structure and gene regulation, p. 1-30. In P. J. Farnham (ed.), Transcriptional control of cell growth: the E2F gene family. Springer-Verlag, New York, N.Y.
34.	Slansky, J. E., Y. Li, W. G. Kaelin, and P. J. Farnham. 1993. A protein synthesis-dependent increase in E2F1 mRNA correlates with growth regulation of the dihydrofolate reductase promoter. Mol. Cell. Biol. 13:1610-1618[Abstract/Free Full Text]. (Author's correction, 13:7201.)
35.	Smith, E. J., G. Leone, and J. R. Nevins. 1998. Distinct mechanisms control the accumulation of the Rb-related p107 and p130 proteins during cell growth. Cell Growth Differ. 9:297-303[Abstract].
35a.	Takahashi, Y., J. B. Rayman, and B. D. Dynlacht. 2000. Analysis of promoter binding by the E2F and pRB families in vivo: proteins mediate activation and repression. Genes Dev. 14:804-816[Abstract/Free Full Text].
36.	Udvadia, A. J., K. T. Rogers, P. D. R. Higgins, Y. Murata, K. H. Martin, P. A. Humphrey, and J. M. Horowitz. 1993. Sp-1 binds promoter elements regulated by the RB protein and Sp-1-mediated transcription is stimulated by RB coexpression. Proc. Natl. Acad. Sci. USA 90:3265-3269[Abstract/Free Full Text].
37.	van der Sman, J., N. S. B. Thomas, and E. W.-F. Lam. 1999. Modulation of E2F complexes during G0 to S phase transition in human primary B-lymphocytes. J. Biol. Chem. 274:12009-12016[Abstract/Free Full Text].
38.	Verona, R., K. Moberg, S. Estes, M. Starz, J. P. Vernon, and J. A. Lees. 1997. E2F activity is regulated by cell cycle-dependent changes in subcellular localization. Mol. Cell. Biol. 17:7268-7282[Abstract].
39.	Watanabe, G., C. Albanese, R. J. Lee, A. Reutens, G. Vairo, B. Henglein, and R. G. Pestell. 1998. Inhibition of cyclin D1 kinase activity is associated with E2F-mediated inhibition of cyclin D1 promoter activity through E2F and Sp1. Mol. Cell. Biol. 18:3212-3222[Abstract/Free Full Text].
40.	Weintraub, H. 1988. Formation of stable transcription complexes as assayed by analysis of individual templates. Proc. Natl. Acad. Sci. USA 85:5819-5823[Abstract/Free Full Text].
41.	Wells, J., P. Held, S. Illenye, and N. H. Heintz. 1996. Protein-DNA interactions at the major and minor promoters of the divergently transcribed dhfr and rep3 genes during the Chinese hamster ovary cell cycle. Mol. Cell. Biol. 16:634-647[Abstract].
42.	Xu, M., K. A. Sheppard, C. Y. Peng, A. S. Yee, and H. Piwnica-Worms. 1994. Cyclin A/CDK2 binds directly to E2F-1 and inhibits the DNA-binding activity of E2F-1/DP-1 by phosphorylation. Mol. Cell. Biol. 14:8420-8431[Abstract/Free Full Text].
43.	Zacksenhaus, E., R. A. Phillips, and B. L. Gallie. 1993. Molecular cloning and characterisation of the RB1 promoter. Oncogene 8:2343-2351[Medline].
44.	Zwicker, J., N. Liu, K. Engeland, F. C. Lucibello, and R. Müller. 1996. Cell cycle regulation of E2F site occupation in vivo. Science 271:1595-1597[Abstract].