From the Department of Molecular Microbiology and Immunology, K. Norris Jr. Comprehensive Cancer Center, University of Southern California, Los Angeles, California 90033
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ABSTRACT |
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Protein phosphatases are involved in many cellular processes. One of the most abundant of these enzymes, the serine/threonine-specific protein phosphatase type 2A (PP2A), is present in most eukaryotic cells and serves a variety of functions. However, the detailed study of its regulation and function has been hampered by the difficulty of manipulating its expression level in cell culture. By using a new mammalian expression vector to forcibly overexpress PP2A in the mouse fibroblast cell line NIH3T3, we now show that the catalytic subunit of PP2A is subject to a potent autoregulatory mechanism that adjusts PP2A protein to constant levels. This control is exerted at the translational level and does not involve regulation of transcription or RNA processing. Thus, our results demonstrate tight control of PP2A expression, and provide an explanation for the difficulty of increasing PP2A expression experimentally.
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INTRODUCTION |
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Reversible protein phosphorylation events play a key role in many cellular processes, such as metabolic pathways, ion channel regulation, signal transduction pathways, and the regulation of gene expression. While one component of this regulation, the protein kinases, has been studied intensively, the importance of the other component, the protein phosphatases, has only lately received more acknowledgment. The finding that some phosphatases are crucial components of pathways that regulate cellular growth and, consequently, may play a role in the process of tumorigenic transformation, has brought them to the forefront of cancer research (1-5).
One of the best studied members of this class is protein phosphatase type 2A (PP2A),1 an abundantly expressed enzyme which targets mainly phosphoseryl and phosphothreonyl residues in its substrates (6). Its role in cell growth regulation has been suggested by several findings. For example, in frog oocytes, PP2A has been shown to be a negative regulator of maturation promoting factor, a cyclin-dependent kinase complex that is essential for cell cycle progression (1). Furthermore, the small and medium T antigens of the DNA tumor viruses SV40 and polyoma virus form stable complexes with PP2A (4). This interaction inhibits phosphatase activity and leads to the activation of mitogen-activated protein kinase pathways in the absence of growth factor-initiated signaling (7). Moreover, a negative role of PP2A in the regulation of immediate early gene expression has been demonstrated by microinjection studies (8) and by the use of okadaic acid (9), a tumor promoter that inhibits PP2A (and certain other phosphatases) (10). In human breast cancer cells, PP2A was found to inhibit the activity of telomerase, a ribonuleoprotein complex that catalyzes the elongation of telomeres, the length of which regulates cell proliferation (11).
In mammalian cells, the native forms of the PP2A holoenzyme consist of
oligomeric complexes of three subunits, termed A, B, and C (2, 4). The
core of these structures are the catalytic C subunit complexed with the
regulatory A subunit. This dimer exists alone, or in association with
one of the B subunits, which is a diverse group of regulatory proteins
that determine substrate specificity and subcellular localization
(12-14). Several isoforms of the various subunits exist; for example,
the C subunit is encoded by two isoforms, and
, which are 97%
conserved at the amino acid level and likely serve redundant functions
(15, 16). Besides subunit composition, the activity of the C subunit is determined by post-translational modifications, such as phosphorylation and methylation, and by interactions with heat-stable protein inhibitors (17-22).
Despite PP2A's negative function in cell growth control, it is ubiquitously expressed at high levels and appears to be essential for cell viability. Genetic inactivation of PP2A in yeast (23), or inhibition of PP2A by okadaic acid in mammalian cells (9), severely impairs cell growth and survival. However, the opposite experimental approach, the stable overexpression of PP2A, has proven difficult to achieve, despite the availability of an expression vector that produces functional PP2A in mammalian cells (24). It is therefore conceivable that the expression of PP2A is tightly regulated in order to ensure constant amounts of PP2A protein, which may constitute an essential component of cellular function. To test this hypothesis, we have analyzed the regulation of expression of the catalytic C subunit of PP2A. We found a potent autoregulatory control that adjusts the amount of PP2A C subunit to constant levels. This control is exerted at the translational level and does not involve transcriptional mechanisms.
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EXPERIMENTAL PROCEDURES |
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Materials-- Okadaic acid was obtained from Alexis/LC Laboratories (San Diego, CA) and dissolved in dimethyl sulfoxide to a final concentration of 100 µM. Rabbit anti-PP2A antibodies were obtained from Upstate Biotechnology Inc. (UBI, Lake Placid, NY), mouse anti-HA-tag antibodies were from Boehringer Mannheim (Indianapolis, IN).
Cell Culture and Transfection-- Mouse NIH3T3 and human HeLa cells were grown in 10% calf serum/Dulbecco's modified Eagle's medium as described (25). Transfections were performed in 6-cm tissue culture dishes using the calcium-phosphate-DNA precipitation technique. The precipitate was added into the medium for 8 h. Then the cells were rinsed twice with phosphate-buffered saline and incubated with fresh medium. For transient transfections, the cells were harvested 16 to 36 h after transfection. For stable transfections, the cells were split 1:5 and selected in 500 µg/ml G418. Individual colonies were isolated and propagated in the continued presence of 200 µg/ml G418. For mass cultures, >500 colonies were pooled.
Transfection Analysis--
Transiently transfected cells were
harvested and analyzed for luciferase activity exactly as described
(25). After lysis and clearing by centrifugation, the protein
concentration of each lysate was determined, and the same amount of
total cellular protein was used for each assay. Each plasmid was tested
by transfection and luciferase assay at least three times. For the
determination of transfection efficiency, a CMV--galactosidase
plasmid was co-transfected in some of the experiments, and
-galactosidase activity was determined in parallel to luciferase
activity.
Plasmid Constructs--
A full-length cDNA encoding the
catalytic subunit of PP-2A ( isoform) was obtained from Brian E. Wadzinski (24). This cDNA contained a 9-amino acid HA-tag at its N
terminus. The coding sequence of this cDNA clone (including its
HA-tag but not its 3'-UTR), was subcloned into vector pRD114, which
contains the murine leukemia virus (MLV) long terminal repeat (26).
pRD114 was kindly supplied by Ralph Dornburg. In our experiments,
pRD114 was renamed MLV-control, and the same vector containing the
HA-tagged PP2A insert was named MLV-PP2A. In addition, we generated a
construct similar to MLV-PP2A that contained parts of the PP2A 3'-UTR
with its polyadenylation signal (called MLV-PP2A-3').
Northern Blot Analysis--
The isolation of
poly(A)+ RNA and further details of Northern blot analysis
are described in Ref. 27. For hybridization, the following
radioactively labeled probes were used. For the detection of the total
amount of PP2A, we used a 2-kilobase fragment from plasmid MLV-PP2A
that represented the complete PP2A coding sequence plus the
vector-derived 3'-UTR. This probe recognized exogenous PP2A mRNA,
as well as both isoforms, and
, of the endogenous PP2A mRNA.
For the specific detection of the
and
isoforms of PP2A
mRNA, we used the same probes as described earlier in Ref. 15: the
-specific probe was a 400 bp fragment from the 3'-UTR of the PP2A
-isoform, the
-specific probe was a 470-base pair fragment from
the 3'-UTR of the PP2A
isoform. As control probes for equal
mRNA loading in each lane, we used either
-actin or choA. ChoA
is an abundant, ubiquitous RNA which was originally isolated from
Chinese hamster ovary cells as clone A (28).
Western Blot Analysis-- Cells were lysed in RIPA buffer as described (25). 20 µg of each sample was separated by polyacrylamide gel electrophoresis and blotted onto nitrocellulose. After blocking with blotto (5% milk, 0.1% Tween 20, 10 mM Tris-HCl, pH 7.5, 150 mM NaCl) for 1 h, the membrane was exposed to the primary antibody diluted in blotto at 4 °C overnight. All antibodies were diluted according to manufacturer's instructions. The secondary antibodies were coupled to horseradish peroxidase, and were detected by chemiluminescence using the SuperSignalTM Substrate (Pierce Chemical Co.).
Polysome Extraction and Sucrose Gradient Analysis--
The
procedure for isolation of cytoplasmic ribosomes from monolayer
cultures was modified from that of Thomas et al. (29). Ten
10-cm dishes of logarithmically growing cells were used per gradient.
The monolayers were rinsed three times with ice-cold Dulbecco's
modified Eagle's medium containing 10 µg/ml cyclohexamide. Cells
were then scraped into 5 ml of ice-cold Dulbecco's modified Eagle's
medium/cyclohexamide and harvested with a brief centrifugation. The
cell pellet was suspended in 1 ml of polysome lysis buffer (125 mM KCl, 12.5 mM MgCl2, 10 mM Hepes, pH 6.8, 0.1 mM dithiothreitol, 10 µg/ml cyclohexamide, 0.5% Triton X-100, and 0.5% deoxycholate), followed by seven passes of a Dounce homogenizer to lyse the cells. The
resulting cell extracts were then layered onto 11 ml of a 10-40%
sucrose gradient (125 mM KCl, 12.5 mM
MgCl2, 10 mM Hepes, pH 6.8, 0.1 mM
dithiothreitol, and 10 µg/ml cyclohexamide) and centrifuged at
4 °C in a SW41 rotor at 36,000 rpm for 1.75 h. The gradients
were analyzed with a UV monitor and flow cell fractions were collected
with a Gilson Micro-Fractionator. The gradient fractions were adjusted
to 1% SDS and extracted twice with phenol/chloroform (CHCl3)/isoamyl alcohol (25:24:1, v/v), followed by a
single extraction with CHCl3/isoamyl alcohol (24:1, v/v).
The samples were adjusted to 0.3 M sodium acetate and
precipitated in 2 volumes of ethanol at 20 °C. The RNA was
collected by centrifugation, washed twice with 70% ethanol, and
suspended in 10 µl of H2O.
Determination of PP2A Protein Half-life-- Cells were grown in 6-cm culture dishes. The growth medium was removed and the cell monolayers were rinsed three times with medium deficient in methionine and cysteine. Then medium lacking methionine and cysteine was added together with 10% dialyzed fetal bovine serum and 125 µCi/ml Tran35S-label (ICN, Costa Mesa, CA), which contained [35S]methionine and [35S]cysteine at 1200 Ci/mmol. After 8 h incubation, the radioactive medium was replaced by fresh medium containing excess non-radioactive methionine and cysteine. At different times thereafter, the cells were harvested in RIPA buffer (30). Each lysate was subjected to immunoprecipitation with anti-PP2A antibodies. The antigen-antibody complexes were harvested with protein A-Sepharose and separated by polyacrylamide gel electrophoresis. The gel was dried and exposed to Kodak X-AR film. The amount of radioactivity in each lane was determined with the AMBIS radioanalytic imaging system.
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RESULTS |
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To investigate a possible autoregulatory control of PP2A expression, NIH3T3 mouse fibroblasts were treated with okadaic acid, a phosphatase inhibitor. We reasoned that, should there be an autoregulatory control, the inhibition of phosphatase activity by this drug might stimulate a compensatory increase in PP2A expression in the cells. We used 50 nM okadaic acid, which we have shown before inhibits PP2A by 80% in these cells (25). Another major serine/threonine phosphatase, type 1 (PP-1), is not inhibited at this concentration (25). The cells were incubated in the presence of okadaic acid for 24 and 48 h, then the amount of PP2A protein was determined by Western blot analysis. As shown in Fig. 1A, there was a substantial increase in PP2A protein levels when PP2A activity was blocked by okadaic acid. This effect was completely reversible, as after the removal of okadaic acid the amount of PP2A protein returned to pretreatment levels. This effect did not appear to be cell type-specific, because a similar effect could be observed in the human cervix carcinoma cell line HeLa (Fig. 1B). Thus, this finding indicated the presence of an autoregulatory loop where inhibition of phosphatase activity generated a signal that led to the increased synthesis of PP2A.
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Should this autoregulation exist indeed, we would expect that elevated PP2A activity should generate the opposite effect, namely the down-regulation of PP2A synthesis. We tested this by transfecting expression vectors for PP2A, and analyzing the consequences for endogenous PP2A expression. NIH3T3 cells were stably transfected with a cDNA encoding the PP2A catalytic subunit under the control of the MLV-long terminal repeat. The two plasmids we used were MLV-PP2A and MLV-PP2A-3' (see "Experimental Procedures" for details). In each case, the PP2A coding sequence contained an N-terminal HA-tag, which allowed the specific identification of transfected PP2A. As a control, the vector without PP2A cDNA (MLV-control) was transfected in parallel. Mass cultures were established and analyzed for the expression of PP2A. As shown in Fig. 2, the transfected HA-tagged PP2A protein was expressed efficiently in cells that had received construct MLV-PP2A or MLV-PP2A-3'. In control cells (either untransfected or transfected with MLV-control), there was no expression of HA-tagged PP2A. Intriguingly, however, when the amount of total PP2A protein (exogenous plus endogenous) was analyzed, only a minor increase (<20%) in the overall amount of PP2A could be detected in the cells transfected with PP2A cDNA (Fig. 2). This suggested that in the presence of transfected PP2A, the synthesis of endogenous PP2A was reduced.
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We confirmed this by comparing the amount of endogenous PP2A protein between cells that were transfected with either MLV-control or MLV-PP2A. Because antibodies against PP2A cannot distinguish between endogenous and transfected HA-tagged PP2A, we performed an immunoblot to solve this issue (Fig. 3). We first immunoprecipitated the transfected PP2A with an antibody against the HA-tag, which left only the endogenous PP2A back in the lysate. Then the amount of endogenous PP2A in this precleared lysate could be determined by Western blot analysis. As shown in Fig. 3, the amount of endogenous PP2A was reduced by 75% in cells that had been transfected with PP2A cDNA. Thus, it appeared that in response to increased PP2A levels (by transfection), the cells reduced the synthesis of endogenous PP2A to adjust to pretransfection levels of the protein. Similarly, when the enzymatic activity of PP2A was determined in crude cell lysates, no statistically significant difference could be found between non-transfected cells and cells transfected with MLV-control, MLV-PP2A, or MLV-PP2A-3' (not shown).
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In order to investigate the mechanism underlying this autoregulation of
PP2A expression, we first analyzed the mRNA levels of transfected
and endogenous PP2A. For this purpose, poly(A)+ RNA was
harvested from untransfected cells, or from cells stably transfected
with MLV-control, MLV-PP2A, or MLV-PP2A-3' and subjected to Northern
blot analysis. As shown in Fig. 4, the
cells containing the PP2A expression vectors produced 9-10-fold more
PP2A mRNA than the control cells. However, when the two isoforms of
the endogenous PP2A mRNA were visualized, there was no obvious
difference in the amount of either the or
subunit mRNA
(Fig. 4). Thus, despite the presence of high levels of exogenous PP2A
mRNA, no down-regulation of the endogenous PP2A mRNA became
apparent.
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The previous experiment indicated that there was no negative effect of
transfected PP2A on the transcription of the endogenous PP2A gene. This
was confirmed by transient co-transfection of the PP2A expression
vector together with a luciferase reporter construct under the control
of the PP2A promoter. For these experiments we used the and
isoforms of the PP2A promoter fused to the luciferase gene, and NIH3T3
cells as recipient cells. As shown in Fig.
5, co-transfected PP2A did not result in
altered PP2A promoter activity, consistent with our observation above
that endogenous PP2A mRNA levels were not altered in response to
transfected PP2A.
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Because the experiments in Figs. 2-4 were performed with mass cultures of transfected cells, with the chance of obscuring strong effects in individual PP2A-transfected clones, we also analyzed a few isolated clones of transfected cells. Three clones of MLV-PP2A transfected cells were compared with three clones of MLV-control transfected cells. High levels of HA-tagged PP2A could be detected in the MLV-PP2A transfected clones, but not in the clones transfected with vector alone (Fig. 6A). However, in keeping with our results obtained with mass cultures, the overall amount of PP2A protein (endogenous plus exogenous) was only weakly increased (Fig. 6A).
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When the levels of PP2A mRNA were analyzed in these clones, the
lack of transcriptional or post-transcriptional autoregulation became
even more apparent. Despite 8-10-fold elevated overall levels of PP2A
mRNA, the amount of the endogenous and
isoform mRNAs
remained the same (Fig. 6B). Nevertheless, in agreement with
our results shown in Fig. 3 above, the amount of endogenous, non-HA-tagged PP2A protein was greatly reduced (not shown), suggesting that autoregulation took place at translational or post-translational levels.
In order to further characterize this autoregulatory loop, we compared the rate of PP2A mRNA translation in MLV-control cells to that in MLV-PP2A cells. For this purpose, the association of PP2A mRNA with cytoplasmic polysomes was determined. In control cells without transfected PP2A (MLV-control), the great majority (81%) of the PP2A mRNA was associated with high molecular weight polysomes (Fig. 7), indicating an efficient rate of PP2A translation. In contrast, in PP2A-transfected cells (MLV-PP2A), only half (48%) of the PP2A mRNA was located in these structures, and the percentage of low molecular weight polysomes and monosomes each increased 2.5-fold from 14 to 36% and from 5 to 16%, respectively (Fig. 7B), demonstrating a lower rate of translation. Therefore, this experiment indicates that in PP2A-transfected cells the overall rate of PP2A mRNA translation is significantly reduced, and provides an explanation for the observed discrepancy between elevated mRNA levels and constant amounts of protein.
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As the above experiment does not exclude potential additional autoregulatory mechanisms at the post-translational level, we next investigated the turnover of PP2A protein in MLV-control and MLV-PP2A cells. The cells were pulse-chased with [35S]methionine, then PP2A protein was immunoprecipitated 6, 12, 18, and 24 h thereafter. We detected only a minor difference in the rate of decay of PP2A protein between the two cell lines (not shown). In MLV-control cells, the half-life of PP2A protein was determined to be 16.5 h, whereas in MLV-PP2A cells the half-life was shortened to 15 h. This difference, however, was not statistically significant, and especially during the first 12 h there was no difference in the decay rate. We therefore conclude that turnover of the protein is not a major factor in the autoregulatory process.
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DISCUSSION |
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In this paper we have investigated the control of PP2A catalytic subunit expression. We found a strong autoregulatory mechanism that appears to ensure relatively constant levels of PP2A synthesis. We show that in cells with highly elevated amounts of PP2A mRNA (due to transfection), there is no corresponding increase in PP2A protein levels because of a control mechanism at the translational level that reduces the efficiency of PP2A translation.
Our data may provide an explanation for earlier seemingly contradictory findings by others who investigated PP2A expression. For example, in various mammalian cells and in fission yeast, it has been shown that the level of PP2A protein remains constant throughout the cell cycle (31-33). In contrast, analyzing the amount of mRNA, others have demonstrated increased PP2A mRNA levels during the early stages of G1 in mammalian cells (34, 35). Moreover, Kakinoki et al. (36) by performing partial hepatectomy, presented evidence of almost constant levels of PP2A protein in regenerating liver, despite a 30-fold increase in PP2A mRNA. These observed discrepancies between elevated mRNA levels and rather constant protein levels can be resolved by our finding of a potent autoregulatory mechanism of PP2A protein synthesis.
However, even though PP2A protein levels remain constant, there are examples of altered enzymatic activity of PP2A (1, 4, 7, 37). These alterations of PP2A activity can be brought about by post-translational mechanisms, e.g. by interactions with regulatory subunits, such as the various B subunits (13, 14) or heat-stable protein inhibitors (21). Moreover, PP2A has been shown to interact with various other cellular proteins which affect its phosphatase activity (38, 39). In addition, post-translational modifications of the catalytic subunit have been implicated in the regulation of PP2A activity (19, 20, 40). Together with our data, it therefore appears that the main regulation of PP2A occurs at the post-translational level. Even though there are occasions where PP2A mRNA levels are dramatically increased, the above described autoregulatory mechanism seems to prevent these changes from translating into elevated levels of PP2A protein.
Our findings have important implications for the study of PP2A function in cells. As noted previously (24), the study of serine/threonine protein phosphatases in mammalian cells using genetic strategies have been frustrating due to difficulties in expressing functional phosphatases with standard gene transfer techniques. Wadzinski et al. (24) modified the N terminus of the PP2A protein by the addition of a 9-amino acid peptide sequence derived from the influenza hemagglutinin protein which allowed, for the first time, functional expression of PP2A in mammalian cells. However, as our results with this same modified PP2A cDNA show, an efficient overall increase in PP2A protein cannot be achieved due to an autoregulatory block of translation. Therefore, for the purpose of functional studies, other avenues need to be pursued to manipulate phosphatase activity.
One possibility, which was successful in the past, is the microinjection of purified PP2A (8, 41). This assay, however, is limited by the low number of cells that can be used per experiment. Another approach is the transient transfection of HA-tagged PP2A, which has been shown to generate certain cellular effects (25). The drawback of that assay is its transient nature, which most likely is rapidly terminated by the autoregulatory feedback loop of PP2A expression. A further strategy to increase PP2A activity in cells was recently presented by Ruediger et al. (42). These authors generated an N-terminal mutant of the regulatory A subunit that was able to bind to the catalytic C subunit, but not to the regulatory B subunit. This resulted in an increase in the amount of core protein (A-C) and a decrease in the amount of holoenzyme (B-A-C) with concomitant alterations in phosphatase activity. Combined with the observed difficulty of increasing the overall amount of the catalytic C subunit (our manuscript), it therefore is likely that approaches which manipulate the expression levels of the regulatory subunits will be more successful in altering phosphatase activity to allow the study of PP2A function.
In the same vein, it will be important to establish the precise
mechanism by which PP2A autoregulates expression of its catalytic subunit at the translational level. Several translation factors have
been found to be reversibly phosphorylated and thus are potential targets for PP2A. For example, okadaic acid causes increased
phosphorylation of translation elongation factor 2 (EF-2) (43, 44), and
phosphorylated EF-2 is a substrate for PP2A in vitro (44,
45). In addition, in reticulocyte lysates, PP2A appears to be the
principal enzyme responsible for dephosphorylating the -subunit of
translation initiation factor 2 (46), and, to a lesser extent, the
-subunit of eukaryotic initiation factor-2 (45). Moreover, the
catalytic subunit of PP2A has been found associated with translation
termination factor eRF1 (eukaryotic release factor 1) in
vivo (47), and the authors postulate that this interaction may
serve to recruit PP2A into polysomes and into contact with putative
targets among the components of the translational apparatus.
However, neither of the above findings would suffice as a basis for the specific autoregulatory control of PP2A translation, because these translation factors are part of the general machinery involved in the synthesis of a multitude of different proteins. Furthermore, it is unlikely that autoregulation is controlled via specific sequences in the 5'- or 3'-UTR of the PP2A mRNA, as the transfected construct MLV-PP2A, which is also autoregulated, does not contain PP2A-specific UTRs, but PP2A coding region only. The lack of the PP2A-specific 5'-UTR in the transfected constructs would also exclude translational initiation as a means of autoregulation. Combined with the above mentioned interactions of PP2A with other general translation factors, our findings may rather point to the rate of translational elongation as a possible component of PP2A autoregulation. Whether the coding region of PP2A mRNA harbors the information for autoregulation, and/or whether other factors are involved in this process, will be subject to future investigations.
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ACKNOWLEDGEMENTS |
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We are grateful to Brian E. Wadzinski for the PP2A cDNA clone, Brian A. Hemmings for PP2A genomic clones, and Ralph Dornburg for the MLV expression vector pRD114. We thank Stanley M. Tahara for advice on polysome fractionation. The technical assistance of Silvina Campos and Ray-Chang Wu is acknowledged.
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FOOTNOTES |
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* This work was supported by American Cancer Society Grant CN-82601 and National Institutes of Health Grant R29CA74278-01.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
To whom correspondence should be addressed: Dept. of Microbiology,
University of Southern California, HMR-405, 2011 Zonal Ave., Los
Angeles, CA 90033-1034. Tel.: 213-342-1730; Fax: 213-342-1721; E-mail: schontha{at}hsc.usc.edu.
1 The abbreviations used are: PP2A, protein phosphatase type 2A; UTR, untranslated region; MLV, murine leukemia virus.
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REFERENCES |
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