Cell Cycle Progression in Monkey Cells Expressing Simian Virus 40 Small t Antigen from Adenovirus Vectors

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Journal of Virology, December 1998, p. 9637-9644, Vol. 72, No. 12
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Cell Cycle Progression in Monkey Cells Expressing Simian Virus 40 Small t Antigen from Adenovirus Vectors

Alan K. Howe, Stéphanie Gaillard, John S. Bennett, and Kathleen Rundell^*

Department of Microbiology-Immunology and The Lurie Cancer Center, Northwestern University, Chicago, Illinois 60611

Received 21 May 1998/Accepted 27 August 1998

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

The simian virus 40 small t antigen (small-t) is required for optimal viral replication and transformation, especially duringthe infection of nondividing cells, suggesting that the functionof small-t is to promote cell cycle progression. The mechanismthrough which small-t promotes cell growth reflects, in part,its binding and inhibition of protein phosphatase 2A (PP2A). Theuse of recombinant adenoviruses allows small-t expression in amajority of cells in a population, thus providing a convenientsource of cells for biochemical analyses. In monkey kidney CV1cells, small-t expressed from these adenovirus vectors activatedthe mitogen-activated protein kinase (MAPK) pathway, induced JNKactivity, and increased AP-1 DNA-binding activity, all in a PP2A-dependentmanner. Expression of small-t also caused an increase in the phosphorylationof the Na⁺/H⁺ antiporter, a mitogen-activated ion exchanger whose activitycorrelates with its phosphorylation. At least part of the antiporterphosphorylation induced by small-t reflected activation of theMAPK pathway, as suggested by results of assays using a chemicalinhibitor of the MAPK-activating kinase, MEK. Finally, small-texpression from adenovirus vectors promoted efficient cell cycleprogression by growth-arrested cells. These vectors should facilitatefurther analysis of effects of small-t on cell cyclemediators.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

The small t antigen (small-t) of simian virus 40 (SV40) enhances viral transformation of several nonpermissive murine celllines (8, 33, 34, 50, 57, 61), is required for inductionof focus formation in semipermissive human fibroblasts (11,42), and also augments viral and cellular DNA replication (13,56, 58). There is now a substantial body of evidence thatthis enhancement may be a result of the ability of small-t topromote cell cycle progression. First, the inefficient transformationinduced by viruses lacking small-t was improved under conditionswhich promote cell cycle progression. These conditions includeinfection of actively growing versus growth-arrested cells, allowinginfected cells to undergo one or more rounds of cell divisionbefore selection in soft agar, and treatment of infected cellswith serum or phorbol ester. SV40-mediated tumorigenesis in vivois also affected by small-t in that the absence of small-t expressionrestricts transformation to actively dividing tissues (e.g., lymphoidtissue) (10, 12). The ability of small-t to induce cell cycleprogression was more directly supported by experiments with nonpermissivemouse embryo fibroblasts in which wild-type (WT) SV40 was ableto induce multiple rounds of cell division whereas mutant viruseslacking small-t induced only a single round of division (23).Finally, growth promotion by small-t was also directly demonstratedin permissive CV1 cells (14, 58).

One of the most important biochemical characteristics of small-t is its association with and inhibition of the cellular serine-threonineprotein phosphatase 2A (PP2A) (39, 66, 70, 71). PP2A existsas a heterotrimer of the catalytic C subunit and two regulatorysubunits, A and B (15). Small-t, like the B subunits, bindsPP2A primarily through interaction with the A subunit (24, 51),although interaction between small-t and the C subunit may furtherstabilize the small-t/A/C complex (51). The consequence of small-tinteraction with PP2A is inhibition of phosphatase activity towardmost substrates (54, 58, 59, 70). The importance of PP2Abinding on small-t function has been firmly established throughanalysis of small-t mutants. Point mutation of either of the cysteinesat positions 97 and 103, or the interposed proline at position101, severely diminishes PP2A binding (37), and these mutationsdecrease viral transformation efficiency in small-t-dependentassays (37, 42). A second region, comprising amino acids 110to 130 and containing the first cysteine-rich cluster, has alsobeen implicated as important for PP2A binding, and deletion ofthis region affects the ability of small-t to mediate growth ofCV1 cells in low serum (58). Transient transfection of small-tmutants have also established PP2A binding as important for small-t-mediatedactivation of components of the mitogen-activated protein kinase(MAPK) cascade (58, 69) and some transcriptional events (20,69).

Another activity of small-t antigen that influences cell growth is not linked to PP2A interaction. Our laboratory has shownthat mutations within the region from amino acids 42 to 47 reducethe ability of small-t to transactivate both the adenovirus E2Aand mammalian cyclin A promoters and also attenuate small-t-dependenttransformation of human and rodent fibroblasts (42). This regionis not required for interaction with PP2A, as a bacterially expressedtruncated version of small-t that lacks this region binds PP2Aas efficiently as full-length small-t (37). However, this regionis strongly conserved among the papovaviruses (41) and is relatedto the DnaJ family of molecular chaperones, known to interactwith and regulate certain heat shock proteins (26). Indeed,it was recently shown that small-t can activate the ATPase activityof hsc70 in a manner that is dependent on the integrity of theregion from amino acids 42 to 47 (60).

An early system used to study growth promotion by small-t is its ability to confer resistance to growth arrest elicited bythe methylxanthine compound theophylline (52), a known inhibitorof cyclic AMP phosphodiesterase. Surprisingly, theophylline-mediatedgrowth arrest correlates not with increased levels of intracellularcyclic AMP (47) but rather with inhibition of the Na⁺/H⁺ antiporter (38). The antiporter, or Na⁺/H⁺ exchanger (NHE), represents a family of mitogen-responsive iontransporters and regulators of intracellular pH (5, 16, 72).It is activated rapidly after stimulation by many, diverse growthfactors, and its activation correlates with an increase in phosphorylation(6). Recent evidence suggests that phosphorylation of the antiportermay be regulated, directly or indirectly, by the MAPKs (1,4, 63, 67).

In this study, we used recombinant adenovirus vectors expressing WT small-t (Adt) or various point mutants to further investigatethe biochemical effects of small-t expression in permissive cells.The use of these adenoviruses has several advantages over otherpreviously used systems, not least of which is the ability toinfect virtually all cells in a population. These recombinantviruses allow the expression of small-t, in the absence of theSV40 large-T, in very short periods of time, making it easierto determine that effects seen after infection are directly attributableto the expression of small-t. We demonstrate that expression ofsmall-t during adenovirus infection can elicit established small-teffects, including activation of the MAPK pathway and the AP-1transcription factor, and induction of cell cycle progression.Furthermore, we show that small-t expression can affect the phosphorylationstate of the Na⁺/H⁺ antiporter, an effect dependent on small-t inhibition of PP2Aand, in part, activation of the MAPK pathway. Our studies underscorethe potential value of these recombinant adenoviruses in exploringadditional effects of small-t antigen on signal transduction andcell cyclepathways.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Cell culture. African green monkey kidney (CV1) cells and human helper 293 cells were maintained in Dulbecco modified Eagle (DME) mediumcontaining 10% fetal bovine serum (FBS). WT SV40 and the small-tmutant dl888 were propagated and titered in CV1 cells, while helper293 cells were used to grow recombinant adenoviruses. In bothcases, stocks were initiated from low-multiplicity infections.Construction of the recombinant adenoviruses was described previously(42).

Immunoprecipitation of the NHE. Infected cells were labeled with 1 mCi of [³²P]orthophosphate per ml for 6 h in phosphate-free DME (Adt infections) or overnightin phosphate-free DME containing 50 µM sodium phosphate (SV40infections). Labeled cells were washed three times and then usedto prepare membranes. Washed cell pellets were resuspended in0.5 ml of hypotonic buffer (20 mM Tris [pH 7.4], 50 mM NaCl) andallowed to swell on ice for 20 min. The cell suspension was passedthrough a 25-gauge needle 10 times, and nuclei were removed bycentrifugation at 2,000 rpm for 10 min at 4°C. The supernate wastransferred to an SW50.1 tube (Beckman Industries), brought toa final volume of 4.8 ml with hypotonic buffer, and centrifugedat 40,000 rpm for 2 h at 15°C. The supernate was aspirated, andthe membrane pellet was solubilized in 400 to 500 µl of NHE lysisbuffer (50 mM HEPES [pH 7.4], 150 mM NaCl, 3 mM KCl, 12.5 mM sodiumpyrophosphate, 5 mM EDTA, 10 mM ATP, 1% Thesit [Boehringer Mannheim],1 mM phenylmethylsulfonyl fluoride, 1 µg each of aprotinin, leupeptin,and pepstatin per ml) for 1 h on ice. After gentle vortexing for15 s, the solution was transferred to a microcentrifuge tube,and insoluble material was removed by centrifugation. Solubleproteins were reacted with rabbit polyclonal antibody to the NHE(7) and formalin-fixed Staphylococcus aureus Cowan. Immunoprecipitateswere washed six to eight times with NHE lysis buffer and thenboiled in Laemmli sample buffer before polyacrylamide gel electrophoresis(PAGE) on sodium dodecyl sulfate (SDS)-7.5% polyacrylamide PAGEgels. Quantitation of images was done either by phosphorimagingor by scanning of films with a Molecular Dynamics SIdensitometer.

PD98059 (MEK inhibitor). PD98059 (New England Biolabs) was used at a concentration of 50 µM from a 50 mM stock in dimethyl sulfoxide (DMSO). For cellstreated with vehicle alone, 1 µl of DMSO per ml was added to themedium.

Western blotting. Cells were washed twice with ice-cold phosphate-buffered saline, scraped in a volume of 1 ml of phosphate-buffered saline,and pelleted by brief (20-s) centrifugation at room temperaturein a microcentrifuge. The supernatant was aspirated, and the volumeof the pellet was estimated. Cells were lysed in cold lysis buffer(50 mM Tris [pH 7.4], 200 mM NaCl, 1 mM EDTA, 1 mM EGTA, 1 mMdithiothreitol, 2% glycerol, 0.5% Nonidet P-40) containing proteaseand phosphatase inhibitors (0.5 mM phenylmethylsulfonyl fluoride,10 µg each of leupeptin, pepstatin, and aprotinin per ml, 1 mMNaF, 1 mM sodium orthovanadate). After vigorous vortexing for15 s, extracts were incubated on ice for 10 to 15 min, and theninsoluble material was removed. Equal amounts of total proteinwere loaded onto SDS-polyacrylamide gels (Laemmli), separatedby PAGE, and then transferred to nitrocellulose. After incubationwith appropriate primary and secondary antibodies, proteins werevisualized by using enhanced chemiluminescence reagents (PierceChemical).

The following primary antibodies were obtained from Santa Cruz Biotechnology (specificity and typical dilutions are givenin parentheses): sc-154 (ERK2; 1:1,000); sc-474 (JNK1; 1:1,000);sc-093 (ERK1; 1:1,000); sc-437 (MEKK; 1:750); sc-44 (c-Jun; 1:500);and sc-052 (c-Fos; 1:500). Transduction Laboratories antibody17020/L3 (MEK1; 1:2,000) was also used. The monoclonal antibodyPAb419 (22) was used at a dilution of 1:20 for detection ofsmall-t.

Immunoprecipitation kinase (IP Kinase) assays. Cells were extracted in cold lysis buffer containing 0.1% SDS. Equal amounts of protein (typically 400 to 800 µg) were usedin all experiments, and extracts were incubated with saturatingamounts of the antibodies described above. Immunoprecipitateswere collected by using protein A-agarose (Santa Cruz Biotechnology)and then washed once in lysis buffer, twice in 100 mM Tris (pH8.6)-500 mM LiCl, and once in kinase buffer (50 mM HEPES [pH 7.4],10 mM MgCl₂, 10 mM MnCl₂, 1 mM DTT). Immunoprecipitates were resuspendedin 40 µl of kinase buffer containing approximately 50 µg of theappropriate substrate per ml and 15 µCi of [ $gamma$ -³²P]ATP (3,000 Ci/mmol, Amersham) and then incubated at 25°C for20 min. Reactions were stopped by the addition of SDS sample buffer,and the mixture was boiled for 5 min. Substrates included myelinbasic protein (MBP; Sigma) to assay MAPK, histidine-tagged kinase-inactivep42 ERK1 for MEK (MAPK^K/R) (48), histidine-tagged, kinase-inactive MEK (His₆-MEK) (29,30) for MEKK and Raf, and glutathione S-transferase (GST)-Jun^1-135 fusion protein (a gift from Richard Pestell, Albert EinsteinCollege of Medicine) forJNK1.

Electrophoretic mobility shift assays. Nuclear extracts were made essentially as described previously (55). Protein concentration was determined by the Bradfordmethod (Bio-Rad). A double-stranded, end-labeled oligonucleotide(5'-TCGAGA TGAGTCA GGTGA TGAGTCA GC-3') containingthe two tandem AP-1 sites (boldface) from the c-jun promoter wasused as a probe. For binding reactions, 3 to 5 µg of nuclear extractwas incubated with 1 to 5 fmol (50,000 to 70,000 cpm) of labeledprobe and 5 µg of poly(dI-dC) (Boehringer Mannheim). Complexeswere separated by using nondenaturing 5% acrylamide. For supershiftanalysis, 2 µl of anti-c-Jun antibody (Santa Cruz sc-44X) wasadded to diluted extracts and incubated for 45 min on ice priorto the addition of the labeled probe-poly(dI-dC)mix.

Cell cycle analysis by flow cytometry. Confluent CV1 cells were removed from 6-cm-diameter tissue culture plates by trypsinization and pelleted by centrifugationfor 10 min at 2,000 rpm. At 30 h postinfection (p.i.), cells weretrypsinized and collected by centrifugation; then cells were lysedand stained in a solution containing 4 mM sodium citrate (pH 7.8),100 µg of propidium iodide (PI) per ml, 0.5 mg of RNase per ml,0.1% Triton X-100, and 3% polyethylene glycol 8000. After 20 minat 37°C, an equal volume of hypertonic salt solution (0.35 M sodiumchloride, 100 µg of PI, 0.1% Triton X-100, and 3% polyethyleneglycol 8000) was added. Stained nuclei were held overnight at4°C, passed through nylon filters, and then analyzed on a BectonDickinson flow cytometer using CellQuestsoftware.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Recombinant adenoviruses used to study small-t. To directly assess functions of small-t in the absence of large-T, we used defective adenoviruses that expressed WT or mutantsmall-t under the control of the cytomegalovirus promoter (42,62). By 8 to 12 h after infection with Adt, levels of small-tpresent were similar to levels found in SV40-infected CV1 cellsat 48 h p.i., a time that is about midway through the permissiveinfection (Fig. 1A). Adenoviruses expressing mutant alleles ofsmall-t were also constructed. Ad97 and Ad103 express small-twith Ser in place of the Cys residues at positions 97 and 103,respectively. Both of these forms of small-t have greatly reducedability to bind and inhibit PP2A (37). Ad43/45 expresses a small-tin which Pro43 and Lys45 are replaced by Leu and Asp, respectively.Sequences in this region of small-t have no effect on PP2A bindingbut reduce DnaJ-like activity. All mutant forms of small-t werestable and were expressed at about the same level as the WT protein(Fig. 1B), consistent with earlier findings with these mutantproteins (37, 42).

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FIG. 1. Expression of WT and mutant small-t by adenovirus vectors. (A) CV1 cells were infected with Adt (20 PFU/cell) and then extracted after 8 or 12 h. For comparison, CV1 cells were infected with SV40 (WT) or the small-t deletion mutant dl888 (DL) (each at 20 PFU/cell) and then extracted after 48 h, the peak time in SV40 productive infection. Levels of small-t in these extracts were determined by analyzing 50 µg of total protein on SDS-gels, followed by transfer to nitrocellulose and detection of small-t with monoclonal antibody PAb419 and peroxidase-conjugated rabbit anti-mouse serum. (B) CV1 cells were infected for 8 h with Adt, Ad43/45, Ad97, or Ad103 (each at 20 PFU/cell), and then extracts were made and used to compare levels of WT and mutant proteins by Western blot analysis. Bacterially expressed small-t (Bact. t) is shown as a marker.

Phosphorylation of the Na⁺/H⁺ antiporter during SV40 infection. To determine the effect of small-t on antiporter phosphorylation during SV40 infection, the antiporter was immunoprecipitatedfrom whole-cell extracts of CV1 cells that had been infected withvarious multiplicities of the small-t deletion mutant dl888 (T⁺/t) or WT SV40. Infected cells were labeled with [³²P]orthophosphate from 36 to 48 h p.i. In the experiment shownin Fig. 2A, the level of antiporter phosphorylation in dl888-infectedcells was similar to the basal phosphorylation seen in mock-infectedcells, although a slight increase in antiporter phosphorylationcould be detected at higher multiplicities. In cells infectedwith WT SV40, which expresses small-t, the level of antiporterphosphorylation was consistently higher than that seen in mock-infectedcells. Thus, the presence of small-t results in phosphorylationof the antiporter to a level that is not attainable by large-Talone. The increase in phosphorylation was not attributable toincreased antiporter expression in WT-infected cells, as bothdl888- and WT-infected cells had similar levels of antiporterprotein, detected by Western blot analysis (Fig. 2A, inset). Phosphorylationof the antiporter in response to serum is shown as a positivecontrol but cannot be directly compared to those of infected cellsbecause of differences in the labeling periods.

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FIG. 2. Small-t increases phosphorylation of the Na⁺/H⁺ antiporter. (A) Confluent CV1 cells were serum starved for 48 h and then treated with mock lysate (M) or infected with 50, 20, or 5 PFU of WT SV40 or dl888 per cell. Cells were labeled from 36 to 48 h p.i. with [³²P]orthophosphate, and then the antiporter was solubilized from partially purified membranes and immunoprecipitated as described in Materials and Methods. As a positive control, cells were stimulated with 10% serum for 30 min (S⁺) and then processed for immunoprecipitation. Levels of phosphorylation in this control cannot be directly compared to those in infected cell extracts because of differences in labeling periods. A Western blot for total antiporter protein in WT- and dl888 (DL)-infected cell extracts is shown in the inset to the right. The arrow indicates the position of the antiporter at 115 kDa in the immunoprecipitates and the Western blot. (B) Serum-depleted CV1 cells were infected with various recombinant adenoviruses (each at 20 PFU/cell) for 2 h and then incubated in ³²P-containing medium until 8 h p.i. The Na⁺/H⁺ antiporter was immunoprecipitated from partially purified membranes as described in Materials and Methods. Levels of ³²P-labeled antiporter in Adt-infected cells were compared to those found following mock infection (M), infection with the control virus AdE4 (E4), or infection with Ad97, which expresses the C97S mutant small-t. As a positive control, cells were stimulated with 10% serum for 30 min (S⁺).

Phosphorylation of the Na⁺/H⁺ antiporter during Adt infection. To determine if small-t could affect antiporter phosphorylation in the absence of large-T, serum-starved CV1 cells were infectedwith Adt, control virus AdE4, or Ad97 and labeled with [³²P]orthophosphate throughout the 8-h infection period; then theantiporter was immunoprecipitated from partially purified membranes.As shown in Fig. 2B, cells infected with AdE4 showed little phosphorylationof the antiporter above the basal level seen in mock-infectedcells. Antiporter isolated from Adt-infected cells, however, showeda dramatic increase in phosphorylation. The ability of small-tto affect antiporter phosphorylation depended on the ability ofsmall-t to bind to and inhibit PP2A, as little or no increasein phosphorylation was seen during infection with Ad97. Again,the response to serum is shown as a positive control but cannotbe directly compared to responses of Adt-infected cells becauseof differences in the labelingperiods.

Activation of MAPK by Adt infection. The increase in antiporter phosphorylation during Adt infection is likely to reflect activation of growth-regulated kinasesby small-t. A key enzyme involved in cell activation is MAPK,a phosphoprotein and known substrate for PP2A in vitro. IncreasedMAPK activity has been observed in cells 72 h after transfectionwith a small-t-expressing plasmid (58). To determine if expressionof small-t during Adt infection could activate MAPK, we infectedserum-starved CV1 cells for 8 or 24 h with either AdE4 or Adtand determined the MAPK activity in the infected cells by an IPkinase assay (Fig. 3A). The MAPK activity in cells infected withAdE4 for 8 h was identical to mock levels, but significant activationoccurred in Adt infections. In the example shown here, scanningdensitometry showed a 3.2-fold increased phosphorylated MBP at8 h p.i. Activation of MAPK by small-t was seen as early as 5h p.i. (data not shown) and was still apparent at 24 h p.i., althoughlevels of MAPK activity had declined in both Adt- and AdE4-infectedpopulations. Activity of MAPK at 8 h p.i. was similar to thatfound 15 min following addition of 10% serum (Fig. 4B).

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FIG. 3. Activation of MAPK and JNK in Adt-infected cells. CV1 cells were mock infected (M) or infected with recombinant adenoviruses (each at 20 PFU/cell) and then extracted at various times p.i. to determine activities of the intracellular kinases, MAPK and JNK. (A) Cells were infected with AdE4 (E4) or Adt (t) for 8 or 24 h prior to extraction. MAPK was immunoprecipitated as described in Materials and Methods and then assayed with MBP as a substrate. (B) Cells were infected with adenoviruses that express mutant small-t for 8 h and then extracted and immunoprecipitated to determine MAPK activity as described for panel A. As a positive control, cells were stimulated with 10% serum for 15 min before analysis (S⁺). (C) Infected or serum-stimulated cells were extracted and immunoprecipitated with antibody to JNK, which was then assayed with GST-Jun^1-135 as a substrate.

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FIG. 4. Effects of small-t antigen on MEK, Raf-1, and MEKK. CV1 cells were mock infected (M) or infected with recombinant adenoviruses (each at 20 PFU/cell) and then extracted at 8 h p.i. (A) Extracts were immunoprecipitated with antibody to MEK, and then precipitates were analyzed with kinase-inactive MAPK (MAPK^K/R) as a substrate. As a positive control, cells were stimulated with 10% serum for 10 min before extraction (S¹⁰). (B) MEK activity was inhibited by incubating infected cells in the presence of 50 µM PD98059 throughout the 8-h infection period. The effect of this treatment on MAPK activity was determined by immunoprecipitation of MAPK for analysis of its kinase activity. (C) IP kinase assays were performed with antibodies to Raf-1 or MEKK, and precipitates were assayed with His-MEK as the substrate. The asterisk denotes the position of autophosphorylated Raf-1.

Adenoviruses that expressed mutant forms of small-t were also assayed for the ability to induce MAPK activity (Fig. 3B). Thedouble-point mutations at positions 43 and 45 did not affect PP2Abinding or inhibition, and expression of this mutant protein resultedin a fourfold increase in MAPK activity, similar to that elicitedby WT small-t. In contrast, mutations at position 97 or 103, whichgreatly reduce binding to PP2A, abolished the ability of small-tto activate MAPK. Thus, activation of MAPK by small-t antigenrequires inhibition ofPP2A.

Based on the similarity between regulation of JNK and MAPK activity, it seemed possible that small-t could activate the JNKpathway in addition to the MAPK pathway. JNK activity was determinedby using an IP kinase assay with GST-Jun^1-135 as a substrate. JNK activity was activated but less dramaticallythan MAPK by Adt infection (Fig. 3C). The 2-fold activation ofJNK by small-t and the reduced response to serum (1.5-fold) wereconsistent and seen in at least three separateexperiments.

Activation of MEK by small-t. MAPK is activated by phosphorylation on both Thr and Tyr residues by the dual-specificity kinase MEK, which is also a substratefor PP2A (2, 21, 73). Thus, the ability of small-t to inhibitPP2A may result in activation of MEK, which in turn would activateMAPK. Using the adenovirus vectors described above, we testedthe abilities of WT and mutant small-t antigens to activate MEK.MEK activity in infected cells was tested 8 h p.i. by IP kinaseassay using a kinase-inactive form of MAPK purified from bacteriaas a substrate. As with MAPK, MEK was activated by WT small-tas well as the double-point mutant Ad43/45 (Fig. 4A). No activationwas seen in cells infected with control virus (AdE4) or eitherof the viruses expressing the PP2A-binding mutants of small-t(Ad97 andAd103).

Inhibition of PP2A by small-t could activate MAPK directly by inhibiting its dephosphorylation or indirectly by activatingMEK. To determine which mechanism is responsible, the effect ofPD98059, a synthetic inhibitor of MEK activation (3, 18),was determined. PD98059 inhibits activation of MEK by bindingunphosphorylated MEK and preventing its phosphorylation. The inhibitoryeffect of PD98059 is relatively specific for MEK, as several otherenzymes, most notably SEK, were unaffected by the drug (3,18, 40). DME containing either 50 µM PD98059 or the vehicleDMSO was added to cells at the end of the infection period andwas present until the cells were extracted at 8 h p.i. Data werecollected and analyzed by phosphorimaging. In the example shownin Fig. 4B, MAPK activity was increased 3.3-fold in cells infectedwith Adt in the presence of DMSO alone. In contrast, cells maintainedin PD98059-containing medium showed lower basal levels of MAPK,and these were not increased by Adt infection. The concentrationof PD98059 used and length of treatment were not toxic to CV1cells, as pretreatment of cells with 50 µM PD98059 for 6 h followedby extensive washing did not prevent subsequent activation ofMAPK by Adt infection (data not shown). These studies suggestthat the increased MAPK detected in Adt-infected cells requiresMEK activity and that MAPK is not directly activated by the presenceof small-t.

Involvement of MEK in antiporter phosphorylation. To determine whether activation of MAPK was required for small-t to increase antiporter phosphorylation, mock- or Adt-infectedcells were labeled with [³²P]orthophosphate in the presence or absence of 50 µM PD98059.The ability of Adt to increase antiporter phosphorylation wasreduced 60 to 70% in cells treated with 50 µM PD98059 (Fig. 5),suggesting that the increase of antiporter phosphorylation bysmall-t is carried out, at least in part, through activation ofMEK and the MAPK pathway.

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FIG. 5. Inhibition of MEK decreases small-t-mediated antiporter phosphorylation. Confluent, serum-starved CV1 cells were infected with recombinant adenoviruses (each at 20 PFU/ml) and then placed in medium containing [³²P]phosphate (1 mCi/m) in the presence or absence of 50 µM PD98059. At 8 h p.i., cells were extracted and the antiporter was immunoprecipitated from partially purified membranes as described in Materials and Methods. Immunoprecipitated proteins were separated by SDS-PAGE and visualized on a Molecular Dynamics Phosphorimager SI. The radioactivity in the band corresponding to the antiporter was quantitated for each sample and compared to radioactivity present in control infections in which uninfected cells were incubated with or without PD98059.

Small-t does not activate Raf-1 or MEKK. Upstream activators of MAPK and JNK are Raf-1 and MEKK, respectively. These enzymes were tested by IP kinase assays with appropriateantibodies and with His₆-MEK as a substrate for either enzyme.Analysis was done by phosphorimaging. Autophosphorylation of Raf-1,manifest by a second radiolabeled band migrating above the substrateband, occurred during these assays. Serum stimulation inducedRaf-1 kinase activity, but no activation was seen 8 h after Adtinfection (Fig. 4C). This finding, along with the observationthat inhibition of MEK ablates MAPK activation by small-t, suggeststhat small-t activates the MAPK kinase cascade primarily throughactivation of MEK. MEKK was also unaffected by small-t expression(Fig. 4C), suggesting that the activation of JNK by small-t isthrough an effector downstream ofMEKK.

PP2A binding by small-t antigen is required for induction of AP-1. The recombinant adenoviruses were also used to examine more downstream effects that often result from activation of the MAPKpathway. It was of interest to examine levels of the c-Fos proteinbecause of a recent report that c-fos transcription may actuallybe decreased by small-t antigen (68). Contrary to this report,cells infected with Adt showed increased c-Fos protein levelsat times that paralleled activation of MAPK (Fig. 6A).

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FIG. 6. Induction of c-Fos protein levels and AP-1 activity in Adt-infected cells. Confluent, serum-starved CV1 cells were mock infected (M) or infected with Adt or AdE4 for 5 or 8 h and then used to prepare nuclear extracts. (A) Levels of c-Fos protein were determined by Western blotting and compared to levels found in cells that had been stimulated with 10% serum for 60 (S⁶⁰) or 90 (S⁹⁰) min. (B) Nuclear extracts were prepared and incubated with a 27-residue oligonucleotide that contained two tandem AP-1 sites from the c-jun promoter as described in Materials and Methods. Extracts of cells infected with Adt and AdE4 were compared to extracts of cells that had been serum stimulated for 30 min (S⁺). In lane $alpha$ , antibody to c-Jun was shown to disrupt complex formation.

It has also been reported that small-t can increase AP-1-driven transcription in microinjected cells, especially when plasmidsthat encode small-t are coinjected with plasmids that expressMAPK itself. Serum-starved CV1 cells had low basal levels of AP-1binding activity which increased four- to fivefold 30 min afterserum stimulation (Fig. 6B). The identity of the shifted complexwas confirmed by preincubating extracts with an anti-c-Jun antibodywhich disrupts AP-1 binding and by competition of probe bindingwith unlabeled AP-1 oligonucleotide (data not shown). A dramaticincrease in AP-1 binding activity was seen 8 h after Adt infection.Some of this increase may be due to binding of adenovirus virionsor to a cellular response to adenovirus infection, as a slightincrease was also seen after AdE4 infection. However, the increasein AP-1 binding activity in response to small-t expression wasfar greater than that seen in response to AdE4 infection or toserumstimulation.

Adenoviruses expressing mutant small-t were also assayed for the ability to induce AP-1 binding. The increase elicited byWT small-t was abrogated by mutation of Cys97 or Cys103, bothof which affect PP2A binding (not shown). This finding is in agreementwith results of microinjection studies that suggested that PP2Abinding by small-t was required to drive expression from AP-1-responsivepromoters (20). The double mutation at residues 43 and 45 hadno effect on the induction of AP-1 DNA binding activity (notshown).

PP2A binding, but not the DnaJ region, of small-t is required for induction of cell proliferation. To determine whether infection with Adt could result in active cell cycle progression, cells were analyzed by flow cytometry(Fig. 7). It is difficult to completely arrest the growth of CV1cells. In these experiments, cells were grown to confluence andthen held in serum-free medium for 48 h before infection. Mock-infectedcultures treated in this fashion showed significant arrest, withthe majority of cells showing a single peak of DNA fluorescencetypical of cells in G₀/G₁. In contrast, by 30 h after infectionwith WT Adt, over half the infected cells had exited G₁. Growthinduction required the PP2A binding ability of small-t. Cellsinfected with Ad103 did not progress through the cell cycle, andthe proportion of cells remaining in G₁ (79%) was nearly identicalto that seen in uninfected cells (82%). Mutations in the DnaJdomain did not affect this small-t function, and Ad43/45 was fullycompetent for induction of cell cycle progression.

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FIG. 7. Induction of cell cycle progression by small-t. CV1 cells were either mock infected or infected with 20 PFU of Adt, Ad43/45, or Ad103 per cell. At 30 h p.i., cells were trypsinized, and nuclei were prepared for flow cytometric analysis as described in Materials and Methods. The fluorescent dye PI binds DNA in proportion to its concentration. In these profiles, cells with resting, diploid DNA content (G₁) were found in the tallest peak on the left side of each tracing and the percentage of cells in G₁ is shown for each population.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

Interaction with PP2A is a principal mechanism through which SV40 small-t exerts its biological effects. While small-t canreduce PP2A activity, potential modification of substrate selectivityand/or intracellular localization may also be an important elementin small-t function, as it is believed to be for various B subunits(17, 25). The identification of in vivo targets affected bysmall-t expression is crucial to understanding its helper function.Our work along these lines was greatly facilitated by the useof adenovirus vectors expressing WT and mutant small-t. Adenovirusvectors have become increasingly useful biological tools becauseof their high virus yields, allowing infection of large numbersof target cells, and rapid expression of recombinant proteins.In this report, we have documented the small-t-dependent increasein phosphorylation of the Na⁺/H⁺ antiporter in cells infected for 48 h with SV40. With recombinantadenoviruses, such phosphorylation is apparent within 8 h afterinfection. Similarly, we have confirmed findings of others fortransfected cells that small-t, through its PP2A-binding activity,results in increased MAPK and MEK activities (58). We have extendedthese studies to show modest increases in JNK1 as well. The overalltiming of our experiments reinforces the belief that small-t isan immediate effector and that cascades that develop only overlong periods may not be responsible for increased kinaseactivities.

While key to the growth process, activation of the MAPK pathway alone does not necessarily lead to cell division, especiallywhen kinase activity is sustained rather than transient (32).Thus, other intracellular targets must be considered as necessaryto drive cell cycle progression in response to small-t. The presentwork implicates the Na⁺/H⁺ antiporter as an excellent candidate in this regard. A significantliterature has shown that activation of the Na⁺/H⁺ antiporter, resulting in cytoplasmic alkalinization, is a prerequisitefor the activation of quiescent cells, and early studies suggestedthat such alkalinization may even be sufficient for S-phase progression(9, 36). Certainly, cell growth and DNA synthesis are restrictedbelow a certain threshold intracellular pH (28, 43). In addition,disruption of antiporter function, through mutation (44, 49)or pharmacological inhibition (28, 64), precludes the growthof normal cells at neutral to acidic pH (44), prevents mitogenicsignal-induced gene expression (64), and presents cell cycleprogression (28).

The Na⁺/H⁺ antiporter is likely to be a key target of small-t's effects on PP2A in permissive cells, i.e., cells that supportviral DNA replication. This possibility is suggested by the abilityof small-t to overcome growth-inhibitory effects of theophylline,an inhibitor of antiporter function. Other potential targets inpermissive cells include the viral large-T itself, a moleculethat is both positively and negatively regulated by phosphorylationand is a known substrate of PP2A (19, 54). Interestingly,PP2A was shown to stimulate SV40 DNA replication in a purifiedin vitro system (65). While this at first seemed contradictory,because small-t enhances viral DNA replication in vivo yet inhibitsPP2A in vitro, it was argued that G₁ progression driven by small-tcould far outweigh any inhibitory effects (13). Alternatively,small-t might target PP2A to specific substrates that play a rolein regulating DNA replication in vivo. Evidence for altered intracellularlocalization of PP2A by small-t was suggested recently in studiesof microtubule-associated enzyme (59).

It will be equally critical to identify cellular targets of PP2A modified by small-t in nonpermissive systems. Given the wealthof activities stimulated by large-T, it is remarkable that small-tplays such a significant role in many nonpermissive cell systems.It is likely that the importance of small-t in these systems willbe found to be attributable to its ability to regulate biochemicaltargets over which large-T has no direct control, such as MAPKand the Na⁺/H⁺ antiporter. Although not formally demonstrated, activation ofthe Na⁺/H⁺ antiporter is likely to have effects in nonpermissive cells thatare as pronounced as those in permissive cells. It would be evenmore important to demonstrate that such activation was requiredfor cell cycle progression or, ultimately, transformation of aparticular nonpermissive celltype.

Effects of small-t explored in this study focus on early events in cell cycle progression, an area in which large-T has noapparent mechanism of action. It is interesting to speculate thatthe cellular response to small-t expression might mimic the normalsteps followed in progression through the cell cycle and therebybalance potentially apoptotic signals generated by the effectsof large-T. For example, such apoptotic signals might ensue ina cell that has encountered enhanced E2F activity resulting fromlarge-T sequestration of Rb but has failed to follow a normalsequence of earlier, i.e., pre-S-phase, events in cellular activation(27, 45).

The joint requirement for small-t and large-T is well established in several nonpermissive cell systems. For example, neithersmall-t nor large-T alone stimulates cell cycle reentry by density-arrestedhuman diploid fibroblasts, and both viral proteins must be presentfor cell cycle progression to occur (53). In a second system,induction of anchorage-independent growth in rat F111 cells requiresboth large-T and small-t (37). It has recently been establishedthat mitogenic activation of the MAPK pathway is inefficient innonadherent cells (31, 35, 46). Thus, it will be of interestto determine the ability of small-t to induce known biochemicaleffects (e.g., activation of MAPK, Na⁺/H⁺ antiporter, or other enzymes) in nonadherent conditions or densityarrest of cell types such as primary human fibroblasts. The useof adenovirus constructs that individually express the large-Tand small-t, and various mutants of each protein, will be a valuablemethod for analyzing specific cellular functions altered in growthpromotion and the initial stages of transformation in these morestrictly growth controlled celltypes.

	ACKNOWLEDGMENTS

Polyclonal antibody for the Na⁺/H⁺ antiporter was the kind gift of Mitchell Villereal, University ofChicago.

This work was supported by NIH grant R01 CA21327 to K.R. A.K.H. and J.S.B. were supported by NIH grants T32 GM08061 and F32CA66283,respectively.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Microbiology-Immunology, Northwestern University, 303 E. Chicago Ave.,Chicago, IL 60611. Phone: (312) 503-5923. Fax: (312) 908-1372.E-mail: krundell{at}nwu.edu.

Present address: Department of Pharmacology, University of North Carolina, Chapel Hill, NC27514.

Present address: Department of Biology, Clarke College, Dubuque, IA52001.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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2.	Ahn, N. G., R. Seger, and E. G. Krebs. 1992. The mitogen-activated protein kinase activator. Curr. Opin. Cell Biol. 4:992-999[Medline].
3.	Alessi, D. R., N. Gomez, G. Moorhead, T. Lewis, S. M. Keyse, and P. Cohen. 1995. Inactivation of p42 MAP kinase by protein phosphatase 2A and a protein tyrosine phosphatase, but not CL100, in various cell lines. Curr. Biol. 5:283-295[Medline].
4.	Bianchini, L., G. L'Allemain, and J. Pouyssegur. 1997. The p42/p44 mitogen-activated protein kinase cascade is determinant in mediating activation of the Na⁺/H⁺ exchanger (NHE1 isoform) in response to growth factors. J. Biol. Chem. 272:271-279[Abstract/Free Full Text].
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