Leucine Zipper-mediated Dimerization Is Essential for the PTC1 Oncogenic Activity*

(Received for publication, September 25, 1996, and in revised form, December 31, 1996)

Qiang Tong , Shunhua Xing and Sissy M. Jhiang Dagger

From the Department of Physiology and the Department of Internal Medicine, Ohio State University, Columbus, Ohio 43210

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

The PTC1 chimeric oncogene is generated by the fusion of the tyrosine kinase domain of the RET proto-oncogene to the 5'-terminal region of another gene named H4 (D10S170). This oncogene has been detected only in human papillary thyroid carcinomas. We have previously demonstrated that the putative leucine zipper in the N-terminal region of H4 can mediate oligomerization of the PTC1 oncoprotein in vitro. In this study, we further demonstrated that the PTC1 oncoprotein forms a dimer in vivo, and the leucine zipper is responsible for this dimerization. The H4 leucine zipper-mediated dimerization is essential for tyrosine hyperphosphorylation and the transforming activity of the PTC1 oncoprotein. Introducing a loss-of-function PTC1 mutant into PTC1-transformed NIH3T3 cells suppressed the transforming activity of PTC1 and reversed the transformed phenotype of these cells, presumably by forming inactive heterodimers between the two forms of PTC1. Taken together, these data indicate that constitutive dimerization of the PTC1 oncoprotein is essential for PTC1 transforming activity and suggest that constitutive oligomerization acquired by rearrangement or by point mutations may be a general mechanism for the activation of receptor tyrosine kinase oncogenes.


INTRODUCTION

The PTC1 chimeric oncogene, formed by intrachromosomal rearrangement between H4 (D10S170) and the RET proto-oncogene, has been detected in 2.5-30% of papillary thyroid carcinomas (1-3). The product of the PTC1 oncogene is a fusion protein containing the N terminus of H4 fused to the tyrosine kinase domain of c-RET (1). The H4 gene shows no significant homology to known genes, and the function of H4 protein is unknown (4). The RET proto-oncogene encodes a receptor-type tyrosine kinase (5, 6), whose ligand has been identified as glial cell line-derived neurotrophic factor (7-9). A variety of mutations involving the RET proto-oncogene have been found to be associated with a number of human neuroendocrine diseases, such as multiple endocrine neoplasia type 2 inherited cancer syndromes (10-12), the congenital developmental defect Hirschsprung's disease (13), and some sporadic medullary thyroid carcinomas (14).

The PTC1 oncoprotein has been demonstrated to be hyperphosphorylated (15) and to exert transforming activity in NIH3T3 cells (16). The causative role of the PTC1 oncogene in human papillary thyroid carcinoma is further supported by the fact that our transgenic mouse model with targeted expression of the PTC1 oncogene in the thyroid gland develops papillary thyroid carcinomas (17). However, the molecular mechanism of PTC1 activation in the development of papillary thyroid tumors has yet to be elucidated. We have previously demonstrated that the PTC1 chimeric oncogene shows unscheduled expression in the thyroid follicular cells and that recombinant proteins containing the putative leucine zipper domain of H4 form oligomeric complexes in vitro (18). As dimerization is considered to be a crucial step for receptor tyrosine kinase activation (19, 20), we hypothesized that both unscheduled expression of RET tyrosine kinase and constitutive oligomerization of PTC1 proteins are responsible for PTC1-transforming activity in the thyroid.

In this study, we further demonstrated that the leucine zipper region of H4 is responsible for the dimerization of the PTC1 oncoprotein in vivo. Our data also indicated that the leucine zipper-mediated dimerization is essential for tyrosine hyperphosphorylation and the transforming activity of PTC1. Furthermore, the transforming activity of PTC1 can be suppressed by introducing a loss-of-function mutant of PTC1 into PTC1-transformed NIH3T3 cells.


EXPERIMENTAL PROCEDURES

Cell Lines and Antibodies

The African green monkey kidney cell line, COS-7 cells (ATCC 1651), was maintained in Dulbecco's modified Eagle's medium with 10% fetal bovine serum. Both NIH3T3 and NIH3T3/PTC1 were maintained in Dulbecco's modified Eagle's medium with 10% donor calf serum. All media contain 100 units/ml penicillin and 100 µg/ml streptomycin. The monoclonal antibody MSJ was generated in our laboratory. Its epitope was tentatively mapped to amino acid residues 824-828 of RET.1 The polyclonal antibody, C17, was raised against a synthetic peptide (CKRRDYLDLAASTPSDSL) located at amino acid residues 1011-1027 of the C terminus of the RET tyrosine kinase (Immuno-Dynamics, Inc.). The C17 antibody was purified through an affinity column covalently bound with the synthetic peptide. The monoclonal antibody against phosphotyrosine (4G10) was obtained from Upstate Biotechnology Inc.

Plasmid Constructs

The PTC1/CMV was constructed by excising the PTC1 cDNA from the plasmid TPC-1 (15) and inserting it into the XbaI and ApaI sites of pRc/CMV (Invitrogen). The PTC1/LNCX was obtained by excising the PTC1 fragment from PTC1/CMV with HindIII and inserting it into the HindIII site of pLNCX. To clone PTC1Delta zip/CMV and PTC1Delta zip/LNCX, the T7 primer and another primer (5'-AACGGAACGGCGAGATGA-3'), which is located to a region just ahead of the leucine zipper, were used to perform polymerase chain reaction using PTC1/CMV as DNA template. The 250-base pair polymerase chain reaction product was digested with BamHI and used to replace the 400-base pair BamHI fragment of H4 in PTC1/CMV and PTC1/LNCX. To clone PTC1Delta N/CMV and PTC1Delta N/LNCX, a sense primer (5'-TATGCCATGGCGCCGTTCCGCCTG-3'), which is located at the beginning of the leucine zipper region, was paired with an antisense primer (5'-AGTTCTTCCGAGGGAATTCC-3'), which is located at the beginning of the RET tyrosine kinase domain, to perform polymerase chain reaction on the PTC1/CMV template. A 200-base pair BamHI fragment was excised from the polymerase chain reaction product and used to replace the 400-base pair H4 fragment of PTC1/CMV and PTC1/LNCX. The PTC1Delta C/CMV was generated by unidirectional deletion of the PTC1 insert, starting from the C terminus of PTC1. A mutation (Arg897 right-arrow Glu), found in some patients with Hirschsprung's disease (13), was first introduced into c-RET cDNA by site-directed mutagenesis (Muta-gene M13 in vitro mutagenesis kit, Bio-Rad) and later subcloned into PTC1/CMV and PTC1Delta zip/CMV to obtain PTC1HS/CMV and PTC1Delta zipHS/CMV.

DNA Transfection

For transient transfection, 5 × 105 COS-7 cells were transfected with 10-20 µg of various DNA constructs using the calcium phosphate transfection kit (Life Technologies, Inc.). For the focus formation assay, 1.3 × 105 NIH3T3 cells were transfected with 0.3 µg of various DNA constructs. Three weeks later, the foci were stained with Giemsa and counted. For NIH3T3 stable transfectants, 4 × 104 NIH3T3 cells were transfected with 1 µg of various DNA constructs, and the G418-resistant colonies were screened for PTC1 expression by immunoprecipitating the cell lysates with the antibody C17, followed by immunoblot analysis with the antibody MSJ.

Immunoprecipitation and Immunoblot Analysis

Cells were lysed in 20 mM Tris-HCl, pH 7.5, 150 mM NaCl, 2 mM EDTA, 1% Nonidet P-40, and 0.5 mM Na3VO4. For immunoprecipitation, cell lysates were incubated at 4 °C overnight with C17 polyclonal antibody that was covalently conjugated to protein A beads (21). For the immunoblot assay, proteins were separated by SDS-PAGE2 and then transferred to a nitrocellulose membrane. The membrane was blocked in TBST buffer (10 mM Tris-HCl, pH 7.5, 100 mM NaCl, and 0.1% Tween 20) containing 5% nonfat dry milk at 4 °C overnight. After incubation with the primary antibody for 1 h and horseradish peroxidase-conjugated anti-mouse IgG (Transduction Laboratories) for an additional hour, the membrane was treated with ECL reagent (Amersham Corp.) and exposed to x-ray film.

Cross-linking was carried out at room temperature with 0.01% glutaraldehyde in 50 mM triethanolamine (pH 8.2) and 100 mM NaCl, using 20-50 µl of lysate of COS-7 cells transfected with various DNA constructs. Aliquots were removed at the times indicated, and the reaction was terminated by boiling the mixture in SDS-PAGE sample buffer. The sample was resolved by SDS-PAGE and detected by immunoblot with the anti-RET antibody MSJ.

Soft Agar Assay

The soft agar assay was carried out as follows. A bottom layer of agar was prepared in 60-mm Petri dishes using 3 ml of 0.5% noble agar (Difco) in normal growth medium. Next, 3 ml of 0.35% noble agar in normal growth medium containing 9 × 103 cells were added on top of the solidified bottom layer. Colonies with anchorage-independent growth were counted 2 weeks later.


RESULTS

PTC1 Oncoprotein Forms Dimers in Vivo, and Its Dimerization Is Mediated by the Leucine Zipper of H4

To investigate the oligomerization status of PTC1 oncoprotein in eukaryotic cells, the PTC1 oncoprotein was expressed in COS-7 cells by transient transfection with a DNA construct PTC1/CMV. The lysates of COS-7 transfectants expressing PTC1 were treated with glutaraldehyde to stabilize the oligomeric protein complexes (Fig. 1b). Without cross-linking treatment, PTC1 oncoprotein can be detected at the size of 53 kDa, since the PTC1 used in our experiment is the alternative spliced isoform with a shorter C terminus (6). After 1 min of treatment with glutaraldehyde, a 105-kDa protein complex can be readily detected. By 16 min, the PTC1 monomer can no longer be detected. We consistently observed that the PTC1 protein complexes had a stronger signal intensity than the PTC1 monomers in immunoblot detection. One possible explanation is that the formation of protein complexes may alter the conformation of the RET tyrosine kinase for better binding of the MSJ antibody to the epitope site.


Fig. 1. The cross-linking of PTC1 protein complexes by glutaraldehyde depends on the presence of the leucine zipper. a, the schematic representation of PTC1 and its mutants used in this study. The localization and amino acid sequence of the leucine zipper of H4 is shown. b, lysates of COS-7 cells expressing PTC1, PTC1Delta zip, or PTC1Delta N were treated with 0.01% glutaraldehyde for the times indicated. The conjugated protein complexes were resolved on a 7.5% SDS-PAGE gel and detected by immunoblot with MSJ antibody against RET. The potential dimer forms are indicated by arrowheads.
[View Larger Version of this Image (53K GIF file)]


To investigate the role of the leucine zipper of H4 in the formation of PTC1 protein complexes, two forms of PTC1 mutant, PTC1Delta zip and PTC1Delta N, were constructed. PTC1Delta zip had the leucine zipper region of H4 (amino acid residues 56-102) deleted. PTC1Delta N had the N terminus of H4 (amino acid residues 3-52) deleted but retained the leucine zipper (Fig. 1a). As shown in Fig. 1b, the PTC1Delta zip (46 kDa) fails to form protein complexes even after a 16-min treatment with glutaraldehyde. In contrast, PTC1Delta N (49 kDa) retains the ability to form protein complexes. These data indicate that the formation of PTC1 protein complex is mediated by the leucine zipper of H4.

A co-immunoprecipitation assay was performed to further investigate whether the PTC1 forms homodimers. A mutated form of PTC1, PTC1Delta C, had the extreme C terminus of PTC1 (amino acid residues 345-461) deleted. Therefore, PTC1Delta C is no longer recognized by the polyclonal antibody C17 (Fig. 2a). When the PTC1Delta C was co-expressed in COS-7 cells with either PTC1, PTC1Delta zip, or PTC1Delta N, the PTC1Delta C-encoded protein cannot be immunoprecipitated by C17 unless it forms protein complexes with other forms of PTC1 containing an intact C terminus. The expression of PTC1 and its mutants in various cell lysates is detected by the MSJ monoclonal antibody, which can react with all forms of PTC1 protein including PTC1Delta C (Fig. 2b). The PTC1Delta C product (38 kDa) cannot be immunoprecipitated by C17 when it was expressed alone or co-expressed with PTC1Delta zip (Fig. 2c, lanes 2 and 4), but can be co-immunoprecipitated when it was co-expressed with PTC1 or PTC1Delta N (Fig. 2c, lanes 3 and 5). From the results of the cross-linking experiment and the co-immunoprecipitation assay we conclude that PTC1 oncoprotein forms a homodimer in vivo, and the dimerization is mediated by the leucine zipper domain of H4.


Fig. 2. The co-immunoprecipitation of PTC1Delta C with PTC1 is mediated by the leucine zipper. a, the schematic representation of PTC1 and PTC1Delta C proteins and antibodies used in this experiment. b, the expression of PTC1 and its mutants in COS-7 cell lysates. Proteins in cell lysates were resolved on 9% SDS-PAGE and immunoblotted with MSJ antibody. c, co-immunoprecipitation of PTC1Delta C with PTC1 or PTC1Delta N, but not with PTC1Delta zip. COS-7 cell lysates were immunoprecipitated with the C17 antibody and then subjected to SDS-PAGE and immunoblot with MSJ antibody. Lysates of COS-7 cells transfected with various DNA constructs are indicated as follows: lane 1, PTC1; lane 2, PTC1Delta C; lane 3, PTC1 and PTC1Delta C; lane 4, PTC1Delta zip and PTC1Delta C; lane 5, PTC1Delta N and PTC1Delta C.
[View Larger Version of this Image (25K GIF file)]


The H4 Leucine Zipper-mediated Dimerization Is Essential for Tyrosine Hyperphosphorylation of the PTC1 Oncoprotein

It has been shown that dimerization of receptor tyrosine kinases promotes the transphosphorylation of tyrosine residues on intracellular domains (20). To investigate whether there is a correlation between dimerization and transphosphorylation, the tyrosine phosphorylation levels of PTC1, PTC1Delta zip, and PTC1Delta N proteins expressed in COS-7 cells were examined (Fig. 3). The equivalent amount of PTC1, PTC1Delta zip, and PTC1Delta N proteins used in the immunoblot analysis was also shown. The PTC1 and PTC1Delta N oncoprotein are hyperphosphorylated on tyrosine residues. However, deletion of the leucine zipper region of PTC1 dramatically reduced the tyrosine phosphorylation level of the PTC1Delta zip-encoded protein.


Fig. 3. The hyperphosphorylation of PTC1 depends on the leucine zipper-mediated dimerization. Top panel, the tyrosine phosphorylation levels of PTC1, PTC1Delta zip, and PTC1Delta N were revealed by immunoblot with anti-phosphotyrosine antibody 4G10. Bottom panel, an equal amount of PTC1, PTC1Delta zip, and PTC1Delta N proteins used in the experiment is demonstrated by immunoblot with the MSJ antibody.
[View Larger Version of this Image (27K GIF file)]


The H4 Leucine Zipper-mediated Dimerization Is Required for the PTC1 Transforming Activity

To correlate the leucine zipper-mediated dimerization and tyrosine hyperphosphorylation with the transforming activity of PTC1, both focus formation assay and soft agar assay were performed to evaluate the transforming activity of PTC1, PTC1Delta zip, or PTC1Delta N. The expression of PTC1, PTC1Delta zip, or PTC1Delta N proteins encoded by the corresponding DNA constructs was initially confirmed by transient transfection in COS-7 cells, and the expression levels of these three proteins did not appear to be different in COS-7 cells. For focus formation assay, NIH3T3 fibroblast cells were transfected with PTC1/LNCX, PTC1Delta zip/LNCX, or PTC1Delta N/LNCX DNA constructs. The transfected NIH3T3 cells were either left in the plates for 3 weeks to score for the number of foci formed (loss of contact inhibition) or were under G418 selection to monitor the transfection efficiency. As shown in Table I, although all DNA constructs showed equivalent transfection efficiency, NIH3T3 cells transfected with PTC1/LNCX or PTC1Delta N/LNCX, but not with PTC1Delta zip/LNCX or vector DNA, lost contact inhibition and displayed the ability to form foci.

Table I.

Focus formation assay to compare the transforming activity of PTC1, PTC1Delta zip, and PTC1Delta N in NIH3T3 cells


DNA construct Foci/pmol G418R colonies/pmol

pLNCX <1 5.7  × 102
PTC1 5.4  × 102 6.0  × 102
PTC1Delta zip <1 5.7  × 102
PTC1Delta N 4.0  × 102 5.5  × 102

For soft agar assay, NIH3T3 stable transfectants expressing PTC1, PTC1Delta zip, or PTC1Delta N were established. We consistently observed that the protein expression levels of PTC1 or PTC1Delta N were higher than those of PTC1Delta zip in corresponding NIH3T3 stable transfectants (Fig. 4). The clones expressing the lowest amount of PTC1 (PTC1-5 and PTC1-10), a clone expressing the highest amount of PTC1Delta zip (PTC1Delta zip-3), and clones expressing both high (PTC1Delta N-2) and low (PTC1Delta N-1) amounts of PTC1Delta N were selected for soft agar assay. The result of soft agar assay demonstrated that NIH3T3 cells expressing PTC1 or PTC1Delta N, but not PTC1Delta zip, acquired anchorage-independent growth in soft agar (Table II).


Fig. 4. The expression of PTC1, PTC1Delta zip, or PTC1Delta N proteins in the corresponding NIH3T3 stable transfectants. Lysates of various NIH3T3 stable transfectants (1 × 106 cells) were immunoprecipitated with the C17 anti-RET polyclonal antibody, followed by immunoblotting with the MSJ anti-RET monoclonal antibody. Three stable transfectants of each DNA construct (PTC1, clones 5, 7, and 10; PTC1Delta zip clones 2, 3, and 11; or PTC1Delta N, clones 1, 2, and 3) are shown.
[View Larger Version of this Image (31K GIF file)]


Table II.

Soft agar assay to compare the transforming activity of PTC1, PTC1Delta zip, and PTC1Delta N in NIH3T3 stable transfectants


Cell line Number of colonies

NIH3T3 0
PTC1-5 255  ± 30
PTC1-10 228  ± 6
PTC1Delta zip-3 0
PTC1Delta N-1 44  ± 6
PTC1Delta N-2 50  ± 16

Although no difference in the ability to form foci was observed between cells expressing PTC1 and cells expressing PTC1Delta N (Table I), fewer colonies were formed in soft agar for PTC1Delta N-expressing cells compared with PTC1-expressing cells (Table II). Even though two different clones of both PTC1 and PTC1Delta N were tested by soft agar assay, the clonal effect cannot be completely excluded. Alternatively, the N-terminal region of H4 may contain some elements contributing to the anchorage-independent growth of PTC1 but not to the loss of contact inhibition. Taken together, the results of focus formation assay and soft agar assay indicate that the leucine zipper-mediated dimerization is required for the PTC1 transforming activity.

The PTC1 Transforming Activity Can Be Suppressed by a Loss-of-function PTC1 Mutant through the Formation of Heterodimers

Since intermolecular phosphorylation of dimerized receptor tyrosine kinases is crucial for the PTC1 activation, it is possible to suppress the PTC1 transforming activity by introducing a loss-of-function PTC1 mutant to form inactive heterodimers with PTC1. A mutation at codon 897 of c-RET, changing arginine to glutamine, was identified in some patients with Hirschsprung's disease (13). This mutant has been characterized as a loss-of-function mutation (22). PTC1HS, a PTC1 mutant containing this mutation, was transfected into the NIH3T3/PTC1 cells, which were established by transfecting NIH3T3 cells with human thyroid tumor genomic DNA that contains the naturally occurring PTC1 transforming gene (1). Since the NIH3T3/PTC1 cells do not have G418 resistance, NIH3T3/PTC1 cells transfected with various DNA constructs can be selected by G418, and the transformed phenotype of the G418-resistant colonies was evaluated by their ability to form foci. As shown in Fig. 5, approximately 68.6% of the mock transfected (pRc/CMV vector only) NIH3T3/PTC1 cells and 52.5% of the PTC1Delta zipHS/CMV-transfected NIH3T3/PTC1 cells retained the ability to form foci. When analyzed by Student's t test, there was no significant difference between the effects of PTC1Delta zipHS and mock transfection. However, only 18.5% of PTC1HS/CMV-transfected NIH3T3/PTC1 cells maintained transformed phenotype, which was significantly different from that of NIH3T3/PTC1 cells transfected with pRc/CMV vector (p < 0.001) or cells transfected with PTC1Delta zipHS/CMV (p < 0.05).


Fig. 5. The suppression of PTC1 transforming activity with a loss-of-function PTC1 mutant. NIH3T3/PTC1 cells were transfected with pRc/CMV, PTC1HS/CMV, or PTC1Delta zipHS/CMV. The percentages shown on the chart represent the number of colonies that formed foci divided by the total number of G418-resistant colonies. Three independent experiments were performed, with each sample being tested in triplicate during each experiment. * indicates that the PTC1 transforming activity was significantly suppressed by PTC1HS/CMV compared with pRc/CMV vector (p < 0.001) or PTC1Delta zipHS/CMV (p < 0.05).
[View Larger Version of this Image (17K GIF file)]



DISCUSSION

In this study, we demonstrated that the PTC1 oncoprotein forms dimers in vivo and the dimerization of PTC1 is mediated by the leucine zipper in the H4 portion of PTC1. Our data also indicated that the leucine zipper-mediated dimerization was essential for the constitutive phosphorylation and the transforming activity of the PTC1 oncoprotein. Furthermore, a loss-of-function PTC1 mutant can reverse the transformed phenotype of NIH3T3/PTC1 cells, presumably by forming inactive heterodimers.

The PTC1 oncoprotein, with the extracellular and transmembrane domains of c-RET replaced by H4, is localized in the cytoplasm (15) instead of the plasma membrane of cells. It was proposed that the translocation of PTC1 from the cell membrane to the cytoplasm could have provided the structural basis for its escape from the modulatory effect of the membrane-associated protein kinase C (23). However, our data indicate that loss of membrane localization is not enough for the activation of the RET tyrosine kinase, since PTC1Delta zip, which is also localized in the cytoplasm, lost both tyrosine hyperphosphorylation and transforming activity. Our data indicated that the leucine zipper-mediated dimerization is required for the activation of PTC1 tyrosine kinase.

In human papillary thyroid carcinomas, three different forms of the PTC oncogenes have been identified in which the RET tyrosine kinase domain becomes fused with the N-terminal sequences of three different genes (1, 24-26). In addition to PTC1, the PTC2 oncoprotein has also been shown to form dimers in vivo (24), and the dimerization is required for the mitogenic activity of PTC2 (27). Although PTC3 has not been shown to form oligomers experimentally, a potential coiled-coil motif was identified in the ELE1 sequence of PTC3.1 In addition to PTC oncogenes, RETI and RETII transforming genes, which were formed by rearrangements during in vitro transfection (28, 29), also form dimers in vivo (30).1 Therefore, constitutive oligomerization of RET appears to be a common mechanism for the activation of rearranged RET oncoproteins. In fact, constitutive oligomerization may serve as a common mechanism for oncogenic activation of other receptor tyrosine kinases in thyroid tumors. The TPR protein, which is involved in a rearrangement with the tyrosine kinase domain of the TRK nerve growth factor receptor in human papillary thyroid carcinoma (31), contains a leucine zipper domain and forms dimers in vivo (32). All of the tyrosine kinase oncogenes formed by rearrangement in human papillary carcinomas seem to be activated by constitutive oligomerization.

Rodrigues and Park (32) have proposed that oligomerization may serve as a general mechanism for oncogenic activation of receptor tyrosine kinases in many types of tumors. They demonstrated that the leucine zipper domain in TPR mediates dimerization of the TPR-MET oncoprotein, and this constitutive dimerization is essential for its transforming activity. Not only can rearrangement cause oligomerization to activate receptor tyrosine kinases, but point mutations have also been shown to promote constitutive dimerization of receptor tyrosine kinases. Point mutations of RET found in MEN2A patients, resulting in the substitution of one of five Cys residues in the extracellular domain, caused constitutive dimerization and activation of RET tyrosine kinase (33, 34). An amino acid substitution of the NEU oncogene has also been shown to induce oncoprotein aggregation, and increase tyrosine kinase activity and transforming activity (35). Therefore, the approach of using a loss-of-function mutant to suppress the transforming activity of the corresponding oncogene provides a new strategy to specifically intervene with the oncogenic activity of various receptor tyrosine kinase oncogenes in a variety of tumors.


FOOTNOTES

*   This work was supported in part by National Institutes of Health Grant R29 CA60074 and American Cancer Society Grant EDT-67 (to S. M. J.).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.
Dagger    To whom correspondence should be addressed: 302 Hamilton Hall, 1645 Neil Ave., Columbus, OH 43210. Tel.: 614-292-4312; Fax: 614-292-4888.
1   Q. Tong, S. Xing, and S. M. Jhiang, unpublished data.
2   The abbreviation used is: PAGE, polyacrylamide gel electrophoresis.

ACKNOWLEDGEMENTS

We thank Dr. William T. Wong for the NIH3T3 cells, Dr. Massimo Santoro for the NIH3T3/PTC1 cells, and Dr. Benigno C. Valdez for the pLNCX vector. We are grateful to Drs. William T. Wong, Massimo Santoro, and James Lang for valuable suggestions and help.


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