©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Cell Cycle Regulation of Nuclear Factor p92 DNA-binding Activity by Novel Phase-specific Inhibitors (*)

(Received for publication, December 1, 1995; and in revised form, February 1, 1996)

Edgar Grinstein Inge Weinert Brigitte Droese Michele Pagano (1) Hans-Dieter Royer (§)

From the Department of Medical Genetics, Max-Delbrück Center for Molecular Medicine, 13122 Berlin, Germany and Mitotix Inc., Cambridge, Massachusetts 02139

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

The nuclear factor p92, originally discovered by its interaction with the human papillomavirus type 18 enhancer, is a cellular protein whose activity is restricted to S phase in human primary fibroblasts. The human papillomavirus type 18 p92 binding sequence confers enhancer activity on a heterologous promoter, suggesting that p92 acts as a transcription factor. We have identified a class of nuclear inhibitory proteins, I-92s, which noncovalently associate with p92 but not with other transcription factors such as AP1, E2F, or NF-kappaB. Different I-92s occur in G(1), G(2), and G(0), while no I-92 is detectable in S phase. Phase-specific inhibitors, therefore, are responsible for the cell cycle dependence of p92 activity and provide a novel mechanism linking transcription factor regulation with the cell cycle.


INTRODUCTION

We have previously identified a novel cell cycle-regulated DNA-binding protein termed p92, which interacts with multiple p92 recognition sites within the enhancer of human papilloma virus type 18 (HPV18)(^1)(1) . HPV18 belongs to the group of human papilloma viruses with high oncogenic potential(2) . p92 is a sequence-specific nuclear factor that specifically binds to the 5`-AATTGCTTGCATAA motif and other related motifs in the HPV18 enhancer (1, 3) . p92 was originally identified by binding site blotting experiments(1) , and retarded p92s containing DNA-protein complexes were identified by preparative electrophoretic mobility shift experiments and analysis of eluted proteins by binding site blotting (4) . In addition, the 5`-AATTGCTTGCATAA motif is recognized by p92-related factors as was shown by UV cross-linking experiments(3) . p92, however, is the most prominent retarded DNA-protein complex in electrophoretic mobility shift assays(4) . The HPV18 p92 recognition sequence 5`-AATTGCTTGCATAA consists of two partially overlapping octamer-related motifs(1, 3) . We have shown by electrophoretic mobility shift assays (EMSAs) that in vitro translated Oct-1 protein interacts with the 5`-AATTGCTTGCATAA motif. p92, however, is not related to Oct-1, as was shown by immunoblotting using an Oct-1 antiserum(1) . In addition, the intracellular distribution of p92 is regulated by growth factors, because p92 was found in the cytoplasm of serum-starved nontumorigenic HeLa-fibroblast hybrid cells (444 cells) and was translocated to the nucleus upon serum stimulation at the beginning of S phase(1, 4) . We have shown by centrifugal elution experiments that during the cell cycle p92 DNA binding activity is restricted to S phase of 444 cells that contain integrated human papillomavirus type 18(4) . In crude nuclear extracts, we have identified an uncharacterized activity, termed I-92, which inhibits DNA binding of p92(4) . In cell cycle populations of 444 cells, p92 DNA binding activity could not be detected in nuclear extracts from G(1) phase and from G(2) phase cells. It was, however, possible to detect p92 after treatment of these extracts with the detergent deoxycholate(4) , suggesting that p92 was complexed to an inhibitor in G(1) and in G(2) phase of the cell cycle.

In the present communication we characterized I-92 biochemically and functionally. We have delineated a molecular mechanism underlying p92 cell cycle regulation and identified four nuclear inhibitors that link cell cycle regulation with p92 regulation. In normal diploid human fibroblasts (NHDFs), p92 DNA binding is restricted to S phase. In addition, we have determined that p92 may act as a transcription factor because a p92 binding site from the HPV18 upstream regulatory region conferred enhancer activity on a heterologous promoter. The p92/I-92 system, therefore, may represent a novel mechanism of phase-specific gene regulation.


EXPERIMENTAL PROCEDURES

Cell Culture, Cell Synchronization, and Preparation of Extracts

Normal human fibroblasts (PromoCell) and the nontumorigenic HeLa-fibroblast hybrid cell line 444 (5) were maintained in Dulbecco's modified Eagle's medium supplemented with 10% fetal calf serum (Life Technologies, Inc.). Nuclear extracts were prepared as described (6) with some modifications(1) . In brief, cells were scraped from plates, washed with phosphate-buffered saline, and then lysed with 0.65% Nonidet P-40 (Sigma), and nuclei were prepared by low speed centrifugation at 4 °C. Nuclear proteins were eluted with 520 mM NaCl and slight agitation followed by dialysis against a buffer containing 50% glycerol, 50 mM NaCl, 10 mM Hepes (pH 7.9), 0.5 mM phenylmethylsulfonyl fluoride, and 0.5 mM dithiothreitol. Lovastatin (a generous gift of Merck, Sharp and Dome) was used to prepare G(1) phase 444 cells (7, 8) for the extraction of nuclear proteins and the analysis of I-92 during the cell cycle. Semiconfluent fibroblasts and 444 cells were cultivated for 24 h in the presence of 20 µM lovastatin and then processed for the extraction of nuclear proteins. The efficiencies of G(1) phase synchronization were determined by nuclear staining with propidium iodide and fluorescence-activated cell sorting (FACS) measurements of the DNA content. FACS analysis showed that 70% of cells had a diploid DNA content (2n), S phase cells were 14%, and 4n cells were 15%. The drug aphidicolin blocks the activity of DNA polymerase alpha(9, 10, 11) . We used this reagent to synchronize 444 in S phase of the cell cycle. In brief, we treated fibroblasts and 444 cells in culture for 24 h with 3 µM aphidicolin followed by a 3-h release in fresh medium. Under those conditions FACS analysis showed that 65% of cells were in S phase, 28% were 4n, and 6% were 2n. We used an aphidicolin release strategy to obtain 444 cells in G(2) phase of the cell cycle. We determined empirically that after a 24-h aphidicolin treatment (3 µM) and a 10-h release, 87% of the cells were 4n as was shown by FACS analysis. In addition we controlled this synchronization event by Western blot analysis using anti-cyclin B antibodies, because cyclin B expression is restricted to G(2) phase of the cell cycle(12, 13, 14) . We found strong expression of cyclin B in G(2) phase-synchronized 444 cells, whereas no signal or very little signal was evident in G(1) phase and in S phase 444 cells. The latter result is another good control for S phase synchronization because cyclin B is already expressed early in G(2) phase. The drug nocodazole blocks the formation of microtubules, which mediate chromosome segregation during mitosis(15, 16) . Treatment of 444 cells with nocodazole (10 µg/ml) for 18 h yields floating cells that no longer attach to plastic. These shake-off cells are in mitosis, and they were used as a source for the preparation of ``mitotic'' nuclear extracts. This preparation contained 86% 4n cells as was measured by FACS analysis. Deprivation of growth factors or cultivation in low serum leads to a reversible exit from the cell cycle into the G(0) phase(17, 18) . In order to obtain G(0) phase 444 cells, we grew these in 0.05% fetal calf serum for 48 h. FACS analysis, however, will not be able to discriminate between G(1) phase and G(0) phase cells because both have a 2n DNA content. We used the nuclear proliferation marker Ki67 (19) as a measure to assess G(0) synchronization, because Ki67 is expressed in cycling but not in resting G(0) cells.

Determination of the Cellular DNA Content by FACS Analysis

5 times 10^5 cells were treated with ethanol for 1 h at -20 °C. Subsequently, cells were washed with phosphate-buffered saline, suspended in 500 µl of phosphate-buffered saline containing 40 U/ml of RNase A and 100 µg/ml propidium iodide, incubated for 30 min at 37 °C, and analyzed by the fluorescence-activated cell sorter using the Cellquest program (Beckton Dickinson).

Transient Transfection Assays

The p92 recognition site present in RP3 was cloned in pGL-2 enhancer tester construct; likewise, a p92 binding mutant RP3-Delta was cloned in pGL-2 (Promega). As a control for transfection efficiencies pSV-gal (Promega) and pCMV-gal (Promega) were used. 1.8 times 10^5 444 cells were transfected using the calcium phosphate technique and 10 µg of either pRP3-GL-2 or pRP3-/RP3-Delta and in combination with 5 µg of pSV-gal or 5 µg of pCMV-gal as internal control. After 24 h, fresh Dulbecco's modified Eagle's medium was added, and the cells were incubated for an additional 48 h. Cell lysis and processing of lysates for luciferase measurements was according to the recommended procedures by the producer of the luciferase kit (Promega) and a luminometer (Berthold). The internal control for transfection efficiency was measured using a Galactolight kit (Tropix).

Preparation and Biochemical Characterization of I-92

Crude I-92 was prepared following a published protocol (20, 21) with modifications (3, 4) from fibroblasts and 444 cells. In brief, nuclear extracts were treated with the detergent deoxycholate (DOC), passed over heparin-Sepharose after the addition of Nonidet P-40 and the flow-through fraction (crude I-92) was collected. Crude I-92 (200 µg) was size-separated by Sephacryl S300 HR chromatography (500 times 7-mm inner diameter) using electrophoretic mobility shift (EMS)-DNA binding buffer as column buffer (1) and a flow rate of 0.1 ml/min at 4 °C. In each experiment 80 fractions (200 µl) were collected and assayed for I-92 activity (50 µl). In other experiments crude I-92 (5 mg) was fractionated by Mono Q-Sepharose. After loading, the column was washed with 1 column volume (2 ml) of column buffer, 5% glycerol, 20 mM Hepes (pH 8), 50 mM NaCl, 1 mM dithiothreitol, and 0.5 mM phenylmethylsulfonyl fluoride. Subsequently, bound proteins were eluted with a NaCl step gradient as indicated in the figures. Each eluate consisted of 2 times 0.5-ml fractions, and for the determination of I-92 activity 25 µl were used. All eluates were dialyzed using EMS-DNA binding buffer. I-92 activity in all experiments was monitored by a p92 electrophoretic mobility shift inhibition assay (EMSIA).

Renaturation of I-92 after SDS-PAGE

Crude I-92 (1 mg) from 444 cells was size-separated by SDS-PAGE (10%). After electrophoresis the gel was cut in slices, and proteins were eluted overnight using an elution buffer (750 µl) containing 10 mM Tris, pH 7.9, 100 mM NaCl, 5 mM dithiothreitol, 0.1 mM EDTA, 0.1% SDS, and 0.1 mg/ml insulin as carrier. Eluted proteins were precipitated with acetone and resuspended in EMS-DNA binding buffer containing 6 M urea. Denatured proteins were subsequently renatured after an overnight dialysis against 3 M urea followed by dialysis against EMS-DNA binding buffer. The procedure followed published protocols(20, 21, 22) . I-92 activity was monitored by a p92 EMSIA.

EMSA, Immunoshift, p92 EMSIA, and I-92 Unit Definition

EMSA was performed as previously published(1) . For the detection of AP-1 a consensus sequence was used (Santa Cruz), for the detection of E2F a consensus oligonucleotide was used(23) , and for the detection of NF-kappaB a consensus oligonucleotide was used(24) . Double-stranded oligonucleotides (BioTez) were radioactively labeled as published(25) . For immunoshift analysis an anti-Fos rabbit polyclonal antiserum (Medac) was used at the concentrations indicated in the legend to Fig. 3. As a control an unrelated rabbit polyclonal antiserum directed against a human endogenous retrovirus antigen (a gift of R. Kurth, Paul Ehrlich Institute, Langen) was used at the concentrations indicated in the legend to Fig. 3. For the quantitation of I-92 activity we used partially purified p92 as a target and an electrophoretic mobility shift as a read-out system. A nuclear extract of 444 cells was treated with deoxycholate and passed over heparin-Sepharose. p92 was eluted with 500 mM NaCl and dialyzed against EMS-DNA binding buffer, 10 mM Tris (pH 7.5), 50 mM NaCl, 50 mM dithiothreitol, 4% glycerol. In all electrophoretic mobility shift inhibition assays, 0.4 µg from the same p92 preparation were used. For EMSIA I-92, preparations were incubated with 0.4 µg of partially purified p92 at room temperature (20 min), and end-labeled RP3 double-stranded oligonucleotide (15,000 cpm) and 200 ng of poly(dI-dC)(dI-dC) were added and incubated for 15 min. Subsequently DNA-protein complexes were analyzed on a 4% native polyacrylamide gel using 0.25% TBE (25) as a running buffer. Dried gels were exposed at -70 °C using Kodak X-Omat AR films.


Figure 3: Selectivity of I-92 inhibition. EMSA with a [-P]ATP end-labeled AP-1 consensus recognition site (Santa Cruz) as a probe and a nuclear extract from 444 cells. Free AP-1 oligonucleotide and retarded AP-1 complexes are indicated by arrows (lane 1). As a specificity control for the identification of the retarded AP-1 DNA-protein complex a polyclonal anti-Fos antiserum (Medac), 1 and 5 µg was included in the binding reaction (lanes 2 and 3). Lanes 4 and 5 contained the same amounts of an unrelated rabbit polyclonal anti-Gag antiserum directed at a human endogenous retrovirus antigen. In order to test whether I-92 affects DNA binding of AP-1 (lane 6), crude I-92 was included in the binding reaction prior to the addition of the probe: 0.5 units of crude I-92 (lane 7), 1 unit of crude I-92 (lane 8), and 2 units of crude I-92 (lane 9). EMSA was performed as described under ``Experimental Procedures.''



Western Blot Analysis

SDS-polyacrylamide gel electrophoresis and Western immunoblot analysis were performed according to standard procedures(25) . Samples (30 µg) were mixed with an equal volume of twice concentrated Laemmli sample buffer (26) and boiled for 5 min. Samples were subjected to SDS-PAGE (10% polyacrylamide), and the proteins were transferred onto nitrocellulose (Bio-Rad). The blots were blocked with 10% dried milk (Carnation) in TTBS buffer (25) for 2 h. Rabbit polyclonal antiserum directed against a peptide of the cyclin B protein was used at 1:200 dilution, and a monoclonal antiserum directed against the Ki67 antigen (Dianova) was used at 1:300 dilution. Detection of immunoreactive bands was by the enhanced chemiluminiscence method (Amersham Corp.).


RESULTS

Our previous work suggested that the DNA binding activity of nuclear factor p92 is cell cycle-regulated by an inhibitor termed I-92 (4) . It was the aim of this study to characterize I-92 and p92 biochemically and functionally.

Cell Cycle Regulation of p92 in Normal Human Diploid Fibroblasts

As shown previously, p92 DNA binding activity is cell cycle-regulated in 444 cells, which are immortalized, nontumorigenic HeLa-fibroblast hybrid cells harboring integrated human papillomavirus type 18 DNA(1) . First we wanted to address the question of p92 regulation in a nontransformed normal human cell population. We therefore analyzed p92 activity in NHDFs. NHDFs were synchronized in tissue culture using lovastatin for G(1) phase cells, aphidicolin and a 3-h release for S phase cells, aphidicolin and a 7-h release for G(2) phase cells, nocodazole for mitotic cells, and serum starvation for G(0) phase cells. From each synchronized cell population nuclear extracts were prepared and examined for p92 DNA binding activity by EMSAs. p92 was not detectable in serum-starved G(0) phase cells (Fig. 1, lane 1), almost undetectable in lovastatin-treated G(1) phase cells, and likewise almost undetectable in G(2) phase cells (Fig. 1, lanes 2 and 4). In S phase cells, however, large amounts of p92 were present (Fig. 1, lane 3). In addition, p92 was almost undetectable in mitotic cells (Fig. 1, lane 5). We conclude from these results that p92 is a factor that operates in normal human diploid fibroblasts and that p92 activity is restricted to S phase of the cell cycle. These results were also confirmed by centrifugal elution of NHDF cells. (^2)


Figure 1: Cell cycle regulation of p92 in synchronized human fibroblasts. Electrophoretic mobility shift analysis of p92 in nuclear extracts from serum-starved fibroblasts (lane 1), from lovastatin-treated fibroblasts (lane 2), from aphidicolin-treated fibroblasts and a 3-h release (lane 3), from G(2) phase fibroblasts after aphidicolin treatment and a 7-h release (lane 4), and from nocodazole treated fibroblasts (lane 5). EMSA was performed as described under ``Experimental Procedures.'' Free RP3 oligonucleotide and retarded p92-RP3 complexes are indicated by arrows. The probe used was a [-P]ATP end-labeled RP3 double-stranded oligonucleotide containing a p92 recognition sequence.



The p92 Recognition Motif Confers Activation of a Heterologous Promoter

One goal of this study was to characterize p92 functionally. In order to do so, we wanted to determine whether p92 might act as a transcription factor. We have previously characterized multiple p92 recognition sites in the enhancer of HPV18 (1) and presented evidence that the 5`-AATTGCTTGCATAA motif, consisting of two partially overlapping octamer-related sequences specifically interacted with p92 and other p92-related proteins, as was shown by UV cross-linking(3) . EMSAs revealed, however, that in S phase the retarded RP3-p92 complex is always the most prominent DNA-protein complex (Fig. 1, lane 3)(4) . The 5`-AATTGCTTGCATAA motif is part of the longer oligonucleotide RP3, which was previously identified as a p92 binding sequence element(1, 3) . In oligonucleotide RP3-Delta the 5`-TTGCTTGCATAA sequence of the 5`-AATTGCTTGCATAA motif was deleted, and we showed that p92 no longer bound to the RP3-Delta mutant (3) . In addition, we have shown previously that the deleted 5`-TTGCTTGCATAA sequence binds p92 in a sequence-specific manner(3) . For functional analysis oligonucleotides RP3 and RP3-Delta were cloned in the enhancer tester luciferase construct pGL-2 and assayed in the nontumorigenic HeLa-fibroblast hybrid cell line 444. RP3 mediated activation of the luciferase reporter gene to a level of 12.9% when compared with the cotransfected pSV-beta-gal control, whereas the deletion mutant RP3-Delta did not confer significant luciferase gene activation (Fig. 2). Reporter gene assays were repeated 6 times with two different DNA preparations and were reproducible. The error bars in the control experiments pGL-2 and RP3-/delta are not visible due to low luciferase activities of these constructs. These experiments showed that the p92 recognition site conferred transcriptional activation, and suggests that proteins that specifically bind to this sequence act as transcription factors. We assume that p92 was responsible for transcriptional activation in these experiments because it is the major retarded complex detectable by EMSA in nuclear extracts of 444 cells(4) . It was not part of this work to analyze in detail the sequence requirements for p92 DNA binding.


Figure 2: p92-mediated activation of the SV40 minimal promoter in pGl-2 enhancer tester construct. RP3 oligonucleotide containing a p92 recognition site was cloned in pGl-2 enhancer tester vector. RP3-Delta is a p92 binding mutant where the p92 binding sequence was deleted. Transfection efficiencies were controlled by cotransfection of a pSV-beta-gal reporter construct. All transient expression assays were done in triplicate using two different DNA preparations as described under ``Experimental Procedures.'' Luciferase activity was measured in a luminometer, and the values are indicated in the figure as relative light units (RLU) of the cotransfected pSV-beta-gal control. The error bars of the control and the p92 binding mutant RP3-Delta are not visible due to low luciferase activities of these constructs.



Functional and Biochemical Characterization of I-92

A key question is how gene expression is coordinated with cell cycle progression. In this report we have shown that a p92 binding site conferred activation of the SV40 minimal promoter present in reporter gene vector pGL2. We have established previously that in the HeLa-fibroblast hybrid cell line 444, which contains integrated human papillomavirus type 18, p92 DNA binding was restricted to S phase of the cell cycle, and we have presented evidence that the DNA binding activity of p92 could be regulated by a putative nuclear inhibitor(4) . This assumption was based on our observation that p92 could be released from putative I-92-p92 complexes by treatment with the detergent DOC (4) . Based on the observation that p92 acts as a transcription factor and that p92 might be cell cycle-regulated by I-92, we hypothesized that I-92 could link cell cycle regulation with transcription factor regulation. In order to characterize I-92 we have accomplished a biochemical and functional analysis of I-92 activities. In the following we summarize several features that candidate I-92 proteins must show in order to be considered as I-92. 1) The DNA binding activity of p92 should be inhibited by partially purified I-92. 2) I-92 inhibition of p92 DNA binding should be selective. 3) I-92 inhibition of p92 DNA binding should be cell cycle-regulated. 4) I-92 inhibition of p92 DNA binding should be reversible after treatment with the detergent DOC.

Selectivity of I-92 Inhibition

p92 binds to octamer-related sequences from the HPV18 enhancer(1) . We have previously shown that ``crude'' I-92 did not inhibit DNA binding of the Oct-1 transcription factor(3) . In order to prepare crude I-92, nuclear extracts of 444 cells were treated with the detergent DOC following a published procedure (4, 20, 21) and passed over heparin-Sepharose. The flow-through contains crude I-92. In order to further define selectivity of I-92 inhibition we chose to analyze other transcription factors whose DNA binding activities are regulated by specific inhibitors. We examined the transcription factor AP-1, which is regulated by IP-1(27) . In this experiment an AP-1 consensus oligonucleotide was used in EMSA. The identity of Fos-Jun retarded complexes was verified by immunoshift analysis using a polyclonal rabbit anti-Fos antiserum (Fig. 3, lanes 2 and 3). As a control an unrelated polyclonal rabbit antiserum was used directed against the Gag protein of a human endogenous retrovirus HERV-K (Fig. 3, lanes 4 and 5). The addition of increasing amounts of crude I-92 did not affect AP-1 retarded complex formation, suggesting that AP-1 is not regulated by I-92 (Fig. 3, lanes 7, 8, and 9). The I-92 unit definition was described(3) . In addition we found that DNA binding of neither NF-kappaB, which is regulated by I-kappaB(25) , nor of E2F(23, 28) , which is regulated by pRB(29) , was regulated by I-92. (^3)These results demonstrate that I-92 inhibition is selective for p92.

Biochemical Characterization of I-92 Proteins

As a source of crude I-92 we used the nontumorigenic HeLa-fibroblast hybrid cell line 444(5) , because the limited life span and slow growth rates of normal diploid human fibroblasts preclude large scale cell culture, which is required for I-92 preparations. Crude I-92 prepared from 444 cells was size-separated by Sephacryl S300 chromatography. Individual Sephacryl fractions were assayed for I-92 activity by a p92 EMSIA using a defined amount of partially purified p92 (0.4 µg) and the p92 recognition site RP3 as a probe. These experiments reproducibly revealed I-92 activities in fractions 46-53 of the S300 column, corresponding to a molecular mass range from 15 to approximately 50 kDa (Fig. 4A), suggesting that either multiple I-92 proteins exist or that I-92 proteins form oligomers.


Figure 4: Identification of diverse I-92 proteins. A, a nuclear extract from 444 cells was treated with the detergent DOC following published procedures(4, 20, 21) , and passed over heparin-Sepharose. The flow-through fraction termed ``crude I-92'' was size-fractionated by chromatography on Sephacryl S300 HR. Individual Sephacryl S300 fractions were analyzed for I-92 by an EMSIA, as described under ``Experimental procedures'' using partially purified p92 and [-P]ATP end-labeled RP3 double-stranded oligonucleotide as a probe. Previous experiments established that all detectable I-92 activities from 444 cells were present between fractions 46 and 52 in our Sephacryl S300 column. B, crude I-92 was size-fractionated by SDS-PAGE, after electrophoresis the gel was dissected into small gel slices. Proteins were eluted from individual slices in elution buffer and renatured. I-92 activity from individual gel slices was monitored by EMSIA. C, crude I-92 was fractionated by Mono Q chromatography and elution with a salt step gradient. Each salt elution was in two steps of 0.5 ml. I-92 was monitored by the EMSIA: p92 control (lane -), Mono Q flow-through (lane FT), 100 mM salt (lanes 1 and 2), 200 mM salt (lanes 3 and 4), 300 mM salt (lanes 5 and 6), 400 mM salt (lanes 7 and 8), 500 mM salt (lanes 9 and 10), 600 mM salt (lanes 11 and 12), 700 mM salt (lanes 13 and 14), 800 mM salt (lanes 15 and 16), and 900 mM salt (lanes 17 and 18). Free RP3 and the p92 retarded complex are indicated by arrows. The faster migrating RP3-protein complexes in lanes 2, 3, 5, and 6 are derived from the I-92 preparation.



Identification of Diverse I-92 Proteins

In order to address the issue whether diverse I-92 proteins exist we have size-fractionated crude I-92 on reducing 10% SDS-polyacrylamide gels with the aim of recovering I-92 for EMSIAs. After electrophoresis, a gel area corresponding to an individual lane was cut in small segments, and proteins were eluted, renatured, and assayed for I-92 activities by EMSIA (Fig. 4B). In order to determine molecular weights of I-92 and to monitor protein recovery, eluted proteins were analyzed by SDS-PAGE and silver staining.^3 I-92 activities were recovered from gel slices 2, 11, 12, 13, and 14 (Fig. 4B). The apparent molecular masses range from 15 (slice 2) to 50 kDa (slice 14). In Fig. 4B eluates from slices 6-8 are not shown because they did not contain detectable I-92 activity. Given the fact that a reducing SDS-PAGE was used in this experiment we conclude that diverse I-92 proteins exist. In order to characterize I-92 further, we have analyzed crude I-92 by Mono Q chromatography. After loading crude I-92 onto the Mono Q column the flow-through fraction was collected. Subsequently, bound proteins were eluted with a NaCl step gradient, and from each salt step two 0.5-ml fractions were collected. All I-92 activities were retained on the column, because the flow-through fraction did not contain any detectable I-92 activity (Fig. 4C, lane FT). The Mono Q fractionation yielded four different salt fractions with I-92 activity: 100 mM NaCl, 200 mM NaCl, 700 mM NaCl, and 800 mM NaCl, as was shown by EMSIA (Fig. 4C, lanes 2, 4, 13, 14, 15, and 16). These results strongly support the observation that diverse I-92 proteins exist. Note that the faster migrating complexes in lanes 2, 3, 5, and 6 were derived from the crude I-92 preparation, because they could be detected by EMSA without added p92, suggesting that they are not p92 degradation products that could have been generated during the electrophoretic mobility shift inhibition assay.^3 Some of the fast moving complexes in fraction 2 of the 200 mM NaCl eluate, however, may have been generated, at least in part, during the electrophoretic mobility shift inhibition assay (see below). In contrast, none of these faster moving complexes could be detected either in SDS-PAGE eluates containing the four I-92s (Fig. 4B, lanes 2, 11, 12, 13, and 14) or in Sephacryl S300 fractions with I-92 activity (Fig. 4A).

Cell Cycle Regulation of I-92 Proteins

Next we analyzed whether the four different I-92 activities that were identified by Mono Q chromatography are subject to cell cycle regulation. The most important feature of I-92 candidate proteins is that their activities should be cell cycle-regulated. More specifically, they should be active either in G(1) phase and/or in G(2) phase but not in S phase. We have used biochemical cell synchronization approaches as outlined under ``Experimental Procedures'' in order to obtain sufficient amounts of crude I-92 for further characterization by Mono Q chromatography and EMSIAs. The efficiencies of cell synchronization were controlled by propidium iodide staining of cellular DNA and FACS analysis. Western blot analysis using an antibody against the proliferation marker Ki67 (19) was used for the assessment of G(0) phase synchronization, and cyclin B antibodies were used for the determination of the G(2) phase synchronization of 444 cells (Fig. 5A). We conclude that our experiments were efficiently synchronizing G(1), S, G(2), M, and G(0) phase cell populations.


Figure 5: Cell cycle regulation of I-92: identification of G(1) phase, G(2) phase, and G(0) phase inhibitors. A, assessment of cell synchrony of 444 cells: FACS analysis of propidium iodide-stained DNA from G(1) phase cells that were treated with lovastatin (top, left). Shown are FACS analysis of propidium iodide-stained DNA from aphidicolin treated S phase cells (top, middle) and FACS analysis of G(2) phase cells that were treated with aphidicolin and a 10-h release (top, right). The efficiency of G(2) phase synchronization was verified by the detection of G(2) phase cyclin B in nuclear extracts of G(2) phase 444 cells (bottom, right). FACS analysis of propidium iodide-stained DNA from nocodazole-treated mitotic cells (bottom, middle) is shown. G(0) synchronization (bottom, left), was verified by analysis of Ki67 expression in serum-starved 444 (G(0)) cells by Western blotting using a polyclonal rabbit antiserum (DAKO) directed against the proliferation marker Ki67. Nuclear extract from serum-starved 444 cells (lane G) and from exponentially growing 444 cells (lane C, bottom left). As a detection system we used the ECL kit (Amersham). Details of the biochemical cell synchronization conditions are described under ``Experimental Procedures.'' B, crude I-92 from lovastatin-treated 444 cells (G(1) phase) was fractionated by Mono Q chromatography (as described in Fig. 4), and I-92 was monitored by the EMSIA. Each salt elution was in two steps of 0.5 ml. p92 control (lane -), 100 mM salt (lanes 1 and 2), 200 mM salt (lanes 3 and 4), 300 mM salt (lanes 5 and 6), 400 mM salt (lanes 7 and 8), 500 mM salt (lanes 9 and 10), 600 mM salt (lanes 11 and 12), 700 mM salt (lanes 13 and 14), 800 mM salt (lanes 15 and 16), and 900 mM salt (lanes 17 and 18) are shown. Free RP3 and the p92 retarded complex are indicated by arrows. C, crude I-92 from aphidicolin-treated 444 cells (S phase cells) was fractionated by Mono Q chromatography as above, and I-92 was monitored by EMSIA. Each salt elution was in two steps of 0.5 ml. p92 control (lane -), 100 mM salt (lanes 1 and 2), 200 mM salt (lanes 3 and 4), 300 mM salt (lanes 5 and 6), 400 mM salt (lanes 7 and 8), 500 mM salt (lanes 9 and 10), 600 mM salt (lanes 11 and 12), 700 mM salt (lanes 13 and 14), 800 mM salt (lanes 15 and 16), 900 mM salt (lanes 17 and 18) are shown. Free RP3 and the p92 retarded complex are indicated by arrows. D, 444 cells were treated with aphidicolin and a 10-h release. G(2) phase was confirmed by a cyclin B Western blot and by FACS analysis of propidium iodide-stained cells. Crude I-92 was prepared from nuclear extracts of G(2) phase 444 cells and analyzed by Mono Q chromatography as above, and I-92 was monitored by EMSIA. Each salt elution was in two steps of 0.5 ml. p92 control (lane -), 100 mM salt (lanes 1 and 2), 200 mM salt (lanes 3 and 4), 300 mM salt (lanes 5 and 6), 400 mM salt (lanes 7 and 8), 500 mM salt (lanes 9 and 10), 600 mM salt (lanes 11 and 12), 700 mM salt (lanes 13 and 14), 800 mM salt (lanes 15 and 16), and 900 mM salt (lanes 17 and 18) are shown. Free RP3 and the p92 retarded complex are indicated by arrows. E, crude I-92 from nocodazole-treated 444 cells was analyzed by Mono Q chromatography as above and EMSIA. Each salt elution was in two steps of 0.5 ml. p92 control (lane -), 100 mM salt (lanes 1 and 2), 200 mM salt (lanes 3 and 4), 300 mM salt (lanes 5 and 6), 400 mM salt (lanes 7 and 8), 500 mM salt (lanes 9 and 10), 600 mM salt (lanes 11 and 12), 700 mM salt (lanes 13 and 14), 800 mM salt (lanes 15 and 16), and 900 mM salt (lanes 17 and 18) are shown. Free RP3 and the p92 retarded complex are indicated by arrows. F, crude I-92 was prepared from nuclear extracts of serum-starved 444 cells. Crude I-92 was fractionated by Mono Q chromatography and elution with a salt step gradient. I-92 was monitored by EMSIA. Each salt elution was in two steps of 0.5 ml. p92 control (lane -), 100 mM salt (lanes 1 and 2), 200 mM salt (lanes 3 and 4), 300 mM salt (lanes 5 and 6), 400 mM salt (lanes 7 and 8), 500 mM salt (lanes 9 and 10), 600 mM salt (lanes 11 and 12), 700 mM salt (lanes 13 and 14), 800 mM salt (lanes 15 and 16), and 900 mM salt (lanes 17 and 18) are shown. Free RP3 and the p92 retarded complex are indicated by arrows.



Identification of Two Different G(1) Phase Inhibitors

444 cells were synchronized with lovastatin, and nuclear extracts were prepared. Crude I-92 was isolated after DOC treatment of the extract and passage over heparin-Sepharose columns. Subsequently I-92 was fractionated by Mono Q chromatography. I-92 was eluted with 100 mM increments of NaCl, and two independent fractions were collected of each eluate. Each salt eluate was assayed for I-92 activity by EMSIA (Fig. 5B). We discovered here that I-92 was present in fraction 2 of a 100 mM NaCl eluate (Fig. 5B, lane 2) and in fractions 1 and 2 of a 700 mM NaCl eluate (Fig. 5B, lanes 13 and 14). For screening I-92 activities in Mono Q fractions, an arbitrary amount of each fraction was used (25 µl). Note that the 100 mM NaCl I-92 activity seems to be present in much lower concentrations than the 700 mM NaCl I-92 activity. It is, however, possible to titrate this inhibitory activity and obtain complete inhibition of p92 DNA binding in EMSIA (see also Fig. 6, lane 2). We conclude that the 100 mM and the 700 mM NaCl Mono Q eluates contain two forms of I-92 that are active in G(1) phase of the cell cycle. We call I-92 from the 100 mM eluate G(1) I-92a and from the 700 mM eluate G(1) I-92b. Note that the 300 mM Mono Q eluate contains an activity that generates faster moving RP3-protein complexes (Fig. 5B, lane 6). This activity, however, was not further characterized and will be part of future work.


Figure 6: Negative regulation of p92 DNA binding by G(1), G(2) and G(0) inhibitors is reversible. Inhibition of p92 DNA binding by the G(1) inhibitor (G(1) I-92a) present in the 100 mM salt fraction of a Mono Q I-92 fractionation (lane 2), by the G(2) inhibitor (G(2) I-92) (lane 3), the 700 mM G(1) by the G(1) I-92b inhibitor present in the 700 mM fraction (lane 4) and the G(0) inhibitor (G(0) I-92) (lane 5). p92 without added inhibitor (lane -). Release of p92 from inactive I-92-p92 complexes after DOC treatment is shown. Treatment of partially purified p92 with 0.2% DOC (lane 6), DOC treatment after inhibition with G(1) I-92a (lane 7), G(2) I-92 (lane 8), G(1) I-92b (lane 9) and G(0) I-92 (lane 10) are shown. The retarded p92 complex and free RP3 are indicated by arrows.



In S Phase I-92 Is Not Detectable

We had previously shown that p92 DNA binding activity was restricted to S phase of eluted 444 cells(4) . For this reason I-92 should not be active in S phase of the cell cycle. We analyzed crude I-92 preparations from S phase synchronized 444 cells, using aphidicolin and a 3-h release, by Mono Q chromatography and EMSIA. We found that none of the four I-92 activities that were identified in exponentially growing 444 cells (see Fig. 4C) were detectable in Mono Q fractions of S phase cells (Fig. 5C). This result demonstrates that all four inhibitors that were identified by Mono Q chromatography of a crude I-92 preparation from 444 cells are subject to cell cycle regulation.

Identification of G(2) Phase I-92

In order to obtain G(2) phase 444 cells, 444 cells were synchronized by aphidicolin treatment followed by a 10-h release, and subsequently crude I-92 was analyzed as described above. The efficiency of G(2) phase synchronization was controlled by FACS analysis and Western blotting using a cyclin B antiserum (Fig. 5A, bottom right). Analysis of the Mono Q fractions by EMSIA demonstrated clearly that in G(2) phase cells only a single I-92 activity was detectable in fraction 2 of the 200 mM NaCl eluate (Fig. 5D, lane 4). We call the G(2) phase inhibitor G(2) I-92. G(2) I-92 was undetectable in the 200 mM Mono Q salt eluates of G(1) phase and S phase cells (Fig. 5, panel B, lane 4, and panel C, lane 4), very low levels of G(2) I-92 could be detected in 200 mM Mono Q salt eluates of M phase and G(0) phase 444 cells (Fig. 5, panel E, lane 4, panel F, lane 4. Note that there are two faster moving complexes in EMSIA of the 200 mM NaCl fraction containing G(2) I-92 (Fig. 5D, lane 4). These complexes were reproducibly detected by EMSIA experiments using Mono Q-separated G(2) I-92 preparations. In contrast, G(2) I-92 from Sephacryl S300 fractions did not contain similar complexes.^3

I-92 Is Not Active in Mitotic 444 Cells

In NHDFs, p92 DNA binding was restricted to S phase of the cell cycle (Fig. 1), and p92 was undetectable in M phase. We noticed, however, that in mitotic 444 cells p92 was detectable by EMSA.^3 In order to examine I-92 in M phase of 444 cells we have used nocodazole-treated 444 shake-off cells for I-92 analysis. An examination of a Mono Q fractionation of mitotic 444 cell nuclear extracts revealed that I-92 was undetectable with the exception of a low amount of the G(2) I-92 inhibitor present in the 200 mM NaCl eluate (Fig. 5E, lane 4). Note that this fraction, however, did not contain any detectable faster moving RP3-protein complexes (Fig. 5, panel E, lane 4, and compare with panel D, lane 4). This result suggested that I-92s are not active in M phase of 444 cells and that for this reason the transcription factor p92 is deregulated in mitotic 444 cells. We interpret this result to indicate a deficiency of I-92 in mitotic 444 cells. However, we have not attempted to identify the putative mitotic inhibitor in NHDFs. It is also possible that p92 is inactivated or degraded during mitosis in normal human fibroblasts. These questions will be addressed as part of future experiments.

I-92 in G(0) Phase Cells

We next wanted to analyze I-92 regulation in G(0) phase of the cell cycle. 444 cells were serum-starved for 48 h and assayed for the quiescent state by Western blotting using the Ki67 antibody (19) (Fig. 5A, bottom left, lane G(0)). The Ki67 antigen is present at any stage of the cell cycle but down-regulated in G(0) phase. The serum starvation for 48 h of 444 cells was effective because the proliferation marker Ki67 was undetectable, whereas in exponentially growing 444 cells the Ki67 signal was readily detectable (Fig. 5A, bottom left, lane C). The activity of I-92 was analyzed in Mono Q fractions by EMSIA, and we identified another I-92 activity in fraction 2 of the 800 mM NaCl eluate (Fig. 5F, lane 16). We call this inhibitor G(0) I-92. The G(1) phase inhibitors were undetectable, and a low amount of G(2) I-92 was detected (Fig. 5F, lane 4). Further experiments, which are beyond the scope of this report, are necessary to characterize the different cell cycle-regulated I-92 activities at the molecular level.

Taken together these observations demonstrate cell cycle regulation of the diverse I-92 forms and suggest that the different I-92 activities are sequentially activated during the cell cycle and therefore link cell cycle regulation with transcription factor regulation. The I-92 system is an example of a novel mechanism of phase-specific transcription factor regulation and, in consequence, of phase-specific gene control.

Inhibition of p92 DNA Binding by Different I-92 Proteins Is Reversible

We have identified four different I-92 activities by SDS-PAGE and Mono Q chromatography. Our previous work suggested that crude I-92 inhibits p92 DNA binding in a reversible manner(4) . However, it is also conceivable that other activities exist, unrelated to I-92, which could degrade p92 or remove or add modifications, which in consequence could regulate the DNA binding activity of p92. In order to resolve this issue we tested whether inhibition of p92 DNA binding by the cell cycle regulated inhibitors present in Mono Q fractions was reversible by DOC treatment. For this purpose, appropriate amounts of the 100 mM NaCl (G(1) I-92a), 200 mM NaCl (G(2) I-92), 700 mM NaCl (G(1) I-92b), and 800 mM NaCl (G(0) I-92 Mono Q eluates were used in order to inhibit DNA binding of partially purified p92 (0.4 µg) in the EMSIA (Fig. 6, lanes 2, 3, 4, and 5). We then tested whether ``free'' p92 could be recovered after DOC treatment (Fig. 6, lanes 7, 8, 9, and 10). We observed that G(1) I-92a, G(1) I-92b, G(2) I-92, and G(0) I-92 inhibited p92 binding in a reversible fashion, although subtle differences were observed. p92 DNA binding inhibition by G(1) I-92b from the 700 mM eluate was 100% reversible (Fig. 6, lanes 4 and 9), whereas p92 DNA binding inhibitions by G(1) I-92a (lanes 2 and 7) from the 100 mM eluate, by G(2) I-92 from the 200 mM NaCl fraction (lanes 3 and 8) and by G(0) I-92 from the 800 mM NaCl fraction (lanes 5 and 10) were reversible to a lesser extent. These results demonstrate that the four phase-specific I-92 forms were able to complex and inactivate p92 in a reversible manner.


DISCUSSION

p92 was previously identified in nontumorigenic HeLa-fibroblast hybrid cells as a cell cycle-regulated DNA-binding protein interacting with the enhancer of human papillomavirus type 18(1) . We have established in this report that p92 is also present in normal human diploid fibroblasts and have shown by cell synchronization experiments that p92 DNA binding activity was restricted to S phase of the cell cycle. We have established in the present communication that a p92 recognition site conferred activation of the SV40 minimal promoter, suggesting that the proteins that bind to the 5`-AATTGCTTGCATAA motif act as transcription factors. We think, however, that p92 might be the responsible factor-mediating transcriptional activation because p92 is the major retarded complex detectable by EMSA in 444 cells(4) . This issue will have to be analyzed after regulated in vivo expression of p92 cDNAs. We are currently engaged in sequencing p92 protein for cDNA cloning.

Diverse Phase-specific Nuclear Inhibitors Link Cell Cyle Regulation with Transcription Factor Regulation

The major finding of this report is the identification of a novel mechanism of phase-specific gene regulation due to the activity of phase-specific nuclear inhibitors, termed I-92s. The consequence of this regulation is that the DNA binding activity of the transcription factor p92 is restricted to S phase of the cell cycle. In nuclear extracts of 444 cells, we have identified two G(1) phase inhibitors (G(1) I-92a, and G(1) I-92b), one G(2) phase inhibitor (G(2) I-92) and a G(0) phase inhibitor (G(0) I-92). In S phase of the cell cycle I-92 was undetectable, demonstrating that the different I-92s regulate the DNA binding activity of the transcription factor p92 in a phase-specific manner, thereby linking cell cycle regulation with transcription factor regulation.

The existence of G(1) I-92a, G(1) I-92b, G(2) I-92, and G(0) I-92 was revealed by biochemical cell synchronization experiments of 444 cells and fractionation of crude I-92 preparations by Mono Q chromatography. The efficiency of cell synchronizations was assessed by measurements of the DNA content (FACS). Western blot analysis controlled for G(0) and the G(2) phase populations using the Ki67 antibody (G(0)) and a cyclin B antibody (G(2)). The latter was used to determine empirically the onset of G(2) phase after an aphidicolin release. Chromatography of crude I-92 on Sephacryl S300 HR columns revealed I-92 activities in a molecular mass range from 15 kDa to 50 kDa. These results were confirmed by preparative, reducing SDS-polyacrylamide gel electrophoresis of crude I-92, subsequent elution of proteins from individual gel slices and renaturation of eluted proteins. I-92 was monitored functionally by an EMSIA. The identification of multiple I-92 activities with different molecular weights in this experiment supports the notion that diverse I-92s exist. A molecular weight determination of the G(1) I-92a, G(1) I-92b, G(2) I-92, and G(0) I-92 inhibitors from Mono Q fractions will be part of future experiments.

We have characterized I-92 functionally and determined that the inhibition of p92 DNA binding by the two G(1) phase inhibitors, the G(2) phase inhibitor, and the G(0) phase inhibitor was reversible, because p92 could be released from inactive I-92-p92 complexes by treatment with the detergent deoxycholate. The G(2) phase inhibitor G(2) I-92 is present in the 200 mM NaCl Mono Q fraction of exponentially growing 444 cells and in G(2) phase-synchronized 444 cells (Fig. 4C, lane 4 and Fig. 5D, lane 4), and low activities of this inhibitor could be detected in M phase and G(0) cells (Fig. 5, panel E, lane 4, and panel F, lane 4). We noted that there were additional faster moving DNA-protein complexes present in the 200 mM NaCl Mono Q fractions that might have been generated during I-92 assays (Fig. 5D, lane 4), because they were undetectable in electrophoretic mobility shift inhibition assays without added p92. In contrast, fast moving complexes could not be detected in Sephacryl S300 fractions and in SDS-PAGE eluates (see Fig. 4, A and B). In addition, Sephacryl S300 fractions from normal human diploid fibroblasts likewise did not contain any detectable faster moving complexes.^3 Furthermore, we have identified a cancer-derived cell line that contains only G(2) I-92.^3 G(2) I-92 from this cell line was present in fraction 46 of a Sephacryl S300 column and in the 200 mM NaCl fraction of a Mono Q column. G(2) I-92 assays from these cells revealed that this Mono Q fraction generated similar faster moving complexes as the one from 444 cells, whereas G(2) I-92 from Sephacryl S300 fraction 46 did not contain any faster moving complexes ^3. It is therefore possible that additional factors are present in the 200 mM NaCl Mono Q fraction that lead to a partial degradation of p92 in EMSIA. Partial degradation of p92 could also explain why in DOC release experiments lower amounts of p92 were recovered when compared with input levels (Fig. 6, lanes 3 and 8). Future experiments will be required to resolve this issue.

We have analyzed whether I-92 is selective in its ability to form complexes with p92. For this reason we selected three other transcription factors and asked whether they are targets for I-92. We could show that the DNA binding activities of AP-1 (Fig. 3), E2F, and NF-kappaB were not affected by one or two units of crude I-92, which completely inactivated a given amount of p92. These data demonstrate that I-92 is selective, and this result is further supported by the fact that the DNA binding activity of Oct-1 was not regulated by crude I-92(3) . A number of transcription factors are regulated by specific inhibitors, which modulate their DNA binding activities. AP-1 is regulated by IP-1(27) , the POU transcription factor Cf1-a is regulated by I-POU(30) , and the helix-loop-helix protein MyoD is regulated by Id (31) , and in these cases nonfunctional heterodimers are formed. I-92s negatively regulate p92 DNA-binding in G(1), G(2), and G(0) phase by physical association with p92. During the process of p92 purification we have observed that other proteins exist that specifically bind to the p92 recognition site present in RP3 and have shown that the DNA binding activities of most of these were regulated by crude I-92(3) . These results show that I-92s selectively regulate, besides p92, the DNA binding activities of other related proteins, and this suggests that I-92s could link the activities of multiple factors with the cell cycle. It is conceivable that this regulatory principle could be a more general mechanism whereby multiple specific inhibitors for a variety of different transcription factors could link the regulation of many genes with the cell cycle.


FOOTNOTES

*
This work was supported by German Research Foundation (DFG) Grants Ro 945/2-1, Ro 945/2-2, Ro 945/3-1, and Ro 945/2-3. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
To whom correspondence and reprint requests should be addressed: Dept. of Medical Genetics, Max-Delbrück Center for Molecular Medicine, Robert-Rössle Str. 10, 13122 Berlin, Germany. Tel.: 49-30-9406-2170; Fax: 49-30-9406-3842.

(^1)
The abbreviations used are: HPV18, human papilloma virus type 18; DOC, sodium deoxycholate; EMSA, electrophoretic mobility shift assay; EMSIA, electrophoretic mobility shift inhibition assay; FACS, fluorescence-activated cell sorting; NHDF, normal human diploid fibroblast; PAGE, polyacrylamide gel electrophoresis; EMS-DNA, electrophoretic mobility shift-DNA; AP-1, activating protein-1.

(^2)
Marijana Kopun and H.-D. Royer, unpublished results.

(^3)
E. Grinstein and H.-D. Royer, unpublished results.


ACKNOWLEDGEMENTS

We thank B. Royer-Pokora, W. Birchmeier, C. Scheidereit, M. Lipp, U. Heinemann, and P. Herrlich for comments on the manuscript and for discussions.


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