Expression of the Tumor Suppressor Protein 14-3-3{sigma} Is Down-regulated in Invasive Transitional Cell Carcinomas of the Urinary Bladder Undergoing Epithelial-to-Mesenchymal Transition*

José M. A. Moreira{ddagger}, Pavel Gromov and Julio E. Celis{ddagger}

From the Institute of Cancer Biology, Danish Cancer Society, Copenhagen, Denmark


    ABSTRACT
 TOP
 ABSTRACT
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
The 14-3-3 proteins constitute a family of abundant, highly conserved and broadly expressed acidic polypeptides that are involved in the regulation of various cellular processes such as cell-cycle progression, cell growth, differentiation, and apoptosis. One member of this family, the 14-3-3 isoform {sigma}, is expressed only in epithelial cells and is frequently down-regulated in a variety of human cancers. To determine the prevalence of 14-3-3{sigma} silencing in bladder cancer progression, we have studied the expression of this protein in normal urothelium and bladder transitional cell carcinomas (TCCs) of various grades and stages using two-dimensional gel electrophoresis in combination with Western blotting and immunohistochemistry. We show that the expression of 14-3-3{sigma} is down-regulated in invasive TCCs, particularly in lesions that are undergoing epithelial-to-mesenchymal conversion. Altered expression of 14-3-3{sigma} in invasive TCCs is not due to increased externalization of the protein nor to an aberrant proliferative potential of neoplastic cells. Furthermore, we found that impaired 14-3-3{sigma} expression is not associated with increased levels of the dominant-negative transcriptional regulator {Delta}Np63. Down-regulation of 14-3-3{sigma} was confirmed by indirect immunofluorescence using a peptide-based rabbit polyclonal antibody specific for this protein. We also show that the expression of 14-3-3{sigma} is highly up-regulated in pure squamous cell carcinomas. Taken together, these results provide evidence that deregulation of 14-3-3{sigma} may play a key role in bladder cancer progression, in particular in differentiation events leading to epithelial-to-mesenchymal transition and stratified squamous metaplasia.


The 14-3-3 proteins comprise a family of abundant, highly conserved and broadly expressed eukaryotic 25- to 33-kDa acidic polypeptides. Their biological role is still somewhat unclear, but it has been demonstrated that these proteins play a regulatory role in cell proliferation, differentiation, cell death, and in modulating signal transduction pathways (1). At least seven isoforms have been identified so far. The {sigma} isoform was originally isolated as an epithelial-specific marker (HME1) whose expression level is drastically decreased in breast cancer cell lines as compared with normal mammary epithelial cells (2). Our group identified and cloned this molecule independently as a transformation-sensitive epithelial marker that we termed stratifin, present in cultured epithelial cells and in stratified squamous keratinizing epithelium (3). There is now evidence that 14-3-3{sigma} (stratifin) is involved in many biological processes, including cell-cycle progression and cell death (48), and several studies have confirmed a major regulatory role for this protein in the G2/M checkpoint control. This observation together with its reported down-regulation in various human cancers, including breast, stomach, colon, lung, liver, pancreas, oral cavity, and vulva (917), have established this protein as a tumor suppressor likely to be involved in carcinogenesis.

Bladder cancer is the second most common genitourinary tumor and the fourth most common solid malignancy in Denmark. It encompasses a large variety of histological heterogeneous tumor types arising predominantly in the epithelium (urothelium) lining of the urinary bladder and the ureters. Tumor types of the urothelium include transitional cell carcinomas (TCCs),1 squamous cell carcinomas (SCCs), adenocarcinomas, as well as other less frequent lesions (18). At present, established prognostic criteria for urothelial malignancies are of limited value, underscoring the urgency for discovering new molecular markers for the prognosis of bladder cancer patients, in particular for patients that are at high risk of progression and recurrence.

For many years, we have carried out a systematic and comprehensive proteomic analysis of bladder tumors in an effort to identify protein markers that may form the basis for improved diagnosis, prognosis, and new forms of treatment (19, 20). The strategy we have employed is based on the systematic comparison of the proteome expression profiles of fresh tissue biopsies from normal and malignant urothelium. To date, this approach has revealed a number of proteins, including but not limited to adypocyte-type fatty acid binding protein, glutathione S-transferase-m, prostaglandin dehydrogenase, and keratin 13, whose rate of synthesis correlates with tumor progression (21, 22). Here we present evidence indicating that deregulation of the tumor suppressor protein 14-3-3{sigma} may play a key role in bladder cancer progression, in particular in events leading to epithelial-to-mesenchymal transition (EMT) and stratified squamous metaplasia.


    EXPERIMENTAL PROCEDURES
 TOP
 ABSTRACT
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Bladder Tumor Biopsies—
Bladder specimens collected over a period of 5 years at Skejby Hospital, Aarhus, Denmark were analyzed. Tumors were classified by an experienced pathologist according to Bergkvist and colleagues (23). All tumors were evaluated according to TNM stages and morphological grades and are presented according to the nomenclature: stage Ta, grade 1, pTa G1; stage Ta, grade 2, pTa G2; stage Ta, grade 3, pTa G3; stage T1, grade 2, pT1 G2; stage T1, grade 3, pT1 G3; stage T2-4, grade 3, pT2-4 G3; and stage T2-4, grade 4, pT2-4 G4. The Scientific and Ethical Committee of Aarhus County approved the project.

Labeling of Bladder Samples with [35S]Methionine—
Tumor samples clean of clots and contaminating tissue and urothelium random biopsies diagnosed as normal were dissected, split into small pieces with the aid of a scalpel, and subsequently labeled with [35S]methionine in a 10-ml sterile conical plastic tube containing 0.2 ml of modified Eagle’s medium devoid of methionine, 2% dialyzed (against 0.95% NaCl) fetal calf serum, and 100 µCi of [35S]methionine (SJ204; Amersham Biosciences, Uppsala, Sweden). After labeling for 14–16 h, the medium was carefully aspirated, and the pieces were dissolved in 0.3–0.4 ml of lysis solution (8 M Urea, 100 mM dithiothreitol, 2% Nonidet P-40, 2% carrier ampholytes 7–9) with the aid of a 1-ml plastic pipette. In the cases where extracellular proteins were examined, the aspirated medium was freeze-dried and resuspended in 0.3–0.4 ml of lysis solution. Samples thus prepared were stored at -20 °C until use.

Proteomic Analysis and Quantitation of the Levels of 14-3-3{sigma}
Two-dimensional gel electrophoresis (2D PAGE) was performed as previously described (24). Gels were stained with silver nitrate or in some cases with Coomassie Brilliant Blue and subjected to autoradiography. Proteins were identified using a combination of procedures that included: matrix-assisted laser desorption/ionization time-of-flight, Biflex (Bruker Daltonics, Billerica, MA); 2D PAGE Western immunoblotting; and comparison with the master 2D gel images of human keratinocytes and TCC proteins (proteomics.cancer.dk). For quantitation, 2D gel autoradioraphs were scanned using a Molecular Imager device (Bio-Rad Laboratories, Hercules, CA) and were analyzed using PDQuest 7.1 analysis software (Bio-Rad Laboratories). Only gels presenting well-focused spots and limited amount of protein remaining at the origin were selected for quantitation. Protein levels were normalized to actin, and the average means with corresponding standard deviations were determined.

Cell Cultures—
Primary cell cultures were derived from bladder tumors and cultured as previously described (25). Also examined were two established cell lines; RT4, a human bladder cancer cell line derived from a papilloma of the urinary bladder, and MRC5, a human fibroblast cell line. Established cell lines were cultured according to the procedures suggested by the American Type Culture Collection (Manassas, VA).

Indirect Immunofluorescence—
All bladder specimens (tumors, random biopsies, and cystectomies) were frozen immediately upon arrival to our laboratory and stored frozen in liquid nitrogen. Immunohistochemical analysis was performed on 6-µm-thick sections of frozen tissue according to standard methods using either a rabbit polyclonal antibody raised against a C-terminal peptide (H2N-CNAGEEGGEAPQEPQS-CONH2) specific for 14-3-3{sigma} (Eurogentec, Brussels, Belgium) and/or a mouse monoclonal antibody against cytokeratin 5 (CK5; Neomarkers, Freemont, CA). Briefly, formaldehyde-fixed sections (3.6% formaldehyde for 4 min) were immersed for 15 min in normal fetal calf serum to block nonspecific staining and then were incubated with the relevant primary antibodies overnight at 4 °C. Next, the formed antibody complexes were detected with a tetramethyl rhodamine isothiocyanate (TRITC)-labeled secondary antibody. The sections were washed three times with cold phosphate-buffered saline between incubations. Normal goat or mouse serum instead of primary antibody was used as a negative control. Double staining, using appropriate fluorescein isothiocyante (FITC)- and TRITC-labeled secondary antibodies (Dako, Glostrup, Denmark) were performed to investigate the relative localization of 14-3-3{sigma} and CK5. To examine the possible co-localization of p63 and 14-3-3{sigma}, we used isoform-specific rabbit antibodies reactive against TAp63{alpha} or {Delta}Np63{alpha} (kindly provided by Karin Nylander) and 14-3-3{sigma} using the ZenonTM Tricolor Rabbit IgG Labeling Kit (Molecular Probes, Eugene, OR). Sections were imaged using either standard epiluminescence fluorescence microscopy (Leica DMRB; Deerfield, IL) or laser scanning microscopy (Zeiss 510LSM; Oberkochen, Germany).

Western Blot Analysis—
Western blotting was performed essentially as previously described (26). Proteins were resolved by 2D PAGE, blotted onto Immobilon-P polyvinylidene difluoride membranes (Millipore, Bedford, MA), and detected with a 14-3-3{sigma}-specific rabbit peptide polyclonal antibody prepared by Eurogentec using Supersignal WestPico detection reagents according to manufacturer’s instructions (Pierce, Rockford, IL).


    RESULTS
 TOP
 ABSTRACT
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Expression Analysis of 14-3-3{sigma} in Bladder Tissue Biopsies—
Fresh bladder tumors and normal random biopsies were analyzed blindly by 2D PAGE in combination with autoradiography and/or silver nitrate staining. Of the biopsy specimens examined, only those yielding high-quality protein profiles and exhibiting minor contamination with connective and/or muscle tissue, judged by the levels of expression of vimentin and desmin, were chosen for comparison. These include: 42 normal biopsies, 11 pTa G1, 23 pTa G2, 1 pT1 G2, 5 pTa G3, 9 pT1 G3, 12 pT2-4 G3, 5 pT2-4 G4, and 5 pure SCCs. Fig. 1 shows representative 2D PAGE proteome expression profiles of fresh biopsies from normal urothelium (cyst 189) and an invasive TCC (566-1 pT2-4 G3) labeled with [35S]methionine, with the latter exhibiting much lower levels of 14-3-3{sigma} protein. Samples were divided into three groups according to their relative expression levels of 14-3-3{sigma}: low (15–75 relative units; average 46 ± 30), medium (140–250 relative units; average 180 ± 50), and high (300–830 relative units; average 530 ± 190). The ratio of the average means in these groups is 1:4:12 (low:medium:high). Some representative gels are shown in Fig. 2. In general, normal biopsies and noninvasive TCCs exhibited high levels of 14-3-3{sigma}, while 10 out of 36 invasive lesions examined had either medium or low levels of this protein (Table I). Closer analysis of the protein expression profiles of the 10 invasive tumors showing down-regulation of 14-3-3{sigma} indicated that 6 out of these 10 tumors are undergoing EMT as judged by their expression of the mesenchyme-specific markers vimentin and protein gene product 9.5 (PGP 9.5) (Fig. 3) (27, 28).



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FIG. 1. Proteomic analysis of invasive TCCs. [35S]Methionine-labeled proteins synthesized in a normal urothelium specimen (cyst 189) and an invasive TCC (566-1 T2-4 G3) were separated by 2D PAGE (isoelectric focusing, IEF) and visualized by autoradiography. The position of actin is given as a reference. The framed area in the gel, corresponding to the portion of the gel containing the 14-3-3 ß, {sigma}, {eta}, and {zeta} isoforms, is shown enlarged in the lower panels of the figure, with the positions for the respective isoforms indicated.

 


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FIG. 2. Illustration of 14-3-3{sigma} down-regulation in bladder carcinomas. Magnified sections of representative 2D PAGE gels run with lysates from normal urothelium (cyst 473, cyst 975) and TCCs of various grades and stages (916-1 pTa G1; 865-3 pTa G2; 702 pT2-4 G3; 697 pT1 G3; 1121-1 pT1 G3; 566 pT2-4 G4). Gels were visualized by autoradiography. Arrowheads indicate the position of 14-3-3{sigma} in the various gels. Expression levels of 14-3-3{sigma} are divided into high (H), medium (M), or low (L).

 

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TABLE I Distribution of tumor samples according to relative levels of expression of 14-3-3{sigma}

 


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FIG. 3. IEF 2D gel of [35S]methionine-labeled proteins synthesized by an invasive TCC (569-1 pT2-4 G4) presenting low levels of 14-3-3{sigma} expression. Arrowheads indicate positions for epithelial-specific proteins (CK18 and 14-3-3{sigma}), mesenchymal-specific proteins (vimentin and PGP 9.5), and a ubiquitously expressed protein (actin).

 
To exclude the possibility that the lower levels of 14-3-3{sigma} protein observed in some invasive tumors were caused by increased release of this protein to the medium during the labeling process, we also analyzed the 2D gel patterns of externalized proteins from whole biopsies, normal as well as tumor specimens. Fig. 4 shows representative 2D gels of whole-cellular extracts from a normal biopsy (cyst 473) and an invasive TCC (375-2, pT2-4 G4). High levels of intracellular 14-3-3{sigma} were matched by comparably high levels of this protein in the medium (Fig. 4, upper panels). Likewise, low levels of intracellular 14-3-3{sigma} were accompanied by equally low levels of externalized protein as illustrated in the case of TCC 375-2 (pT2-4 G4) (Fig. 4, lower panels). These results show that the down-regulation of 14-3-3{sigma} observed in some invasive TCCs is not due to increased protein release to the medium during labeling.



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FIG. 4. Proteomic analysis of externalized proteins. [35S]Methionine-labeled proteins synthesized by normal urothelium (cyst 473) or an invasive TCC (375-2 pT2-4 G4) and either maintained intracellularly (specimen) or released to the medium (released) were separated by 2D PAGE (IEF) and visualized by autoradiography. The area of the gel that contains the 14-3-3 ß, {sigma}, {eta}, and {zeta} isoforms is shown enlarged with the positions for the respective isoforms indicated.

 
2D PAGE and indirect immunofluorescence analysis of pure bladder SCCs revealed very high levels of expression of 14-3-3{sigma} (Fig. 5), comparable to those observed in keratinizing stratified squamous epithelia (3). High expression levels of this protein were also observed in squamous metaplasias (results not shown).



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FIG. 5. Expression of 14-3-3{sigma} in SCCs. Shown is a magnified section of a representative 2D PAGE gel run with a lysate from an SCC (SCC 219 tumor) and an indirect immunofluorescence analysis for 14-3-3{sigma} (SCC 536-1; magnification, x100). Arrowheads indicate the positions of the 14-3-3 isoforms in the 2D gel.

 
Immunostaining of 14-3-3{sigma} in Normal and Invasive TCCs—
To confirm the differential expression of 14-3-3{sigma} in invasive TCCs, we raised a peptide-specific antibody against this protein in rabbits in collaboration with Eurogentec. This antibody was tested for cross-reactivity with other 14-3-3 protein family members by 2D PAGE immunoblotting using both isoelectrofocusing and nonequilibrium pH gradient electrophoresis (25). As depicted in Fig. 6, the antibody shows exquisite isoform specificity as it reacted only with 14-3-3{sigma} in the RT4 bladder epithelial cancer cell line. No cross-rectivity was detected in nonepithelial cells known to express all other isoforms (Fig. 6, human MRC5 fibroblasts).



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FIG. 6. Antibody specificity ascertained by 2D-PAGE Western immunoblotting (IEF) of total cellular protein extracts from the RT4 human bladder cancer cell line and the human MRC5 fibroblast cell line. The positions for the 14-3-3 ß, {sigma}, {eta}, and {zeta} isoforms are indicated.

 
The 14-3-3{sigma} antibody was subsequently used to perform immunostaining of cryostat sections of specimens examined by 2D gel electrophoresis. As shown in Fig. 7, normal as well as noninvasive TCCs showed strong immunoreactivity for 14-3-3{sigma} in the epithelium lining of the urinary bladder (Fig. 7, A–D). Notably, in normal urothelium the 14-3-3{sigma} immunoreactivity was often weaker in the suprabasal intermediate layer as compared with basal (Fig. 7, B and C, white arrowheads) and umbrella cells (Fig. 7, B and C, yellow arrowheads). This differential staining was occasionally not observed in some histological normal specimens derived from patients with invasive TCCs (Fig. 7D).



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FIG. 7. Indirect immunofluorescence analysis of 14-3-3{sigma} in bladder specimens, in normal urothelium (A, cyst 981; B, cyst 981; C, cyst 1004; and D, cyst 975), and invasive TCCs (E, 898-3 pTa G1; F, 738; G, 702 pT2-4 G3; H, 697 pT1 G3; I, 566 pT2-4 G4). Original magnification, x100 (A, D–I) and x400 (B and C). Grading was performed by an experienced pathologist and was based on hematoxylin and eosin-stained sections.

 
Differential 14-3-3{sigma} immunoreactivity with stronger staining of the basal layers (Fig. 7, E and F, white arrowheads) was observed in some patients bearing superficial (Fig. 7E, 898-3 pTa G1) or invasive lesions (Fig. 7F, 738 pT1 G3), most likely reflecting tumor type differences (20). Highly invasive TCCs, on the other hand, showed homogenous staining (Fig. 7, G, 702 pT2-4 G3; H, 697 pT1 G3; and I, 566-1 pT2-4 G4), with immunoreactivity to 14-3-3{sigma} corresponding well to the protein profiles obtained by 2D gel analysis (cf. Fig. 7, G–I, with corresponding panels in Fig. 2). Staining of SCCs with the 14-3-3{sigma} antibody confirmed the high expression of this protein as determined by 2D PAGE (Fig. 5).

The staining phenotypes of both normal urothelium and malignant lesions were confirmed by double immunostaining with 14-3-3{sigma} and CK5 antibodies (Fig. 8). In nonmalignant tissue, we observed complete co-distribution between CK5 and 14-3-3{sigma} staining of the basal, intermediate, and superficial layers (Fig. 8A, white arrowhead). Invasive tumors that showed low levels of 14-3-3{sigma} expression in the 2D PAGE analysis were characterized by the absence of 14-3-3{sigma} staining in cells that stained throughout with the CK5 antibody (e.g. Fig. 7B; 569-1 pT2-4 G4). Additionally, we observed heterogeneous staining patterns with aberrant 14-3-3{sigma} staining in five lesions that had shown high levels of expression by 2D PAGE analysis. The extent of the staining heterogeneity varied, but it included variants of the two major subtypes shown in Fig. 8, C and D. Thus, in three specimens we could observe single scattered cells and/or areas of abnormal {sigma} expression (e.g. Fig. 8C, white arrowheads; 916-1 pTa G1), while in two other cases the heterogeneity was characterized by the progressive loss of expression of 14-3-3{sigma}, with the most invasive areas of the lesion displaying negative staining (e.g. Fig. 8D, white arrowheads; 817-5 pT2-4 G3). All samples showed high levels of 14-3-3{sigma} expression by 2D gel analysis, underscoring the importance of complementary immunostaining studies.



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FIG. 8. Laser scanning analysis of the double-labeled immunofluorescence for 14-3-3{sigma} (FITC; green) and CK5 (TRITC; red). Original magnification, x400 (A, cyst 1004 normal) and x100 (B–D). This figure shows that 14-3-3{sigma} expression in tumors ranges from abrogation of expression (B, 569-1 pT2-4 G3) to a highly heterogeneous expression with mosaicism (C, 916-1 pTa G1) or progressive loss of expression (D, 817-5 pT2-4 G3) in malignant tissue. The inset is a magnified section of a 2D PAGE analysis of total protein extracts from the corresponding specimen with the position for 14-3-3{sigma} indicated (black arrowheads).

 
Impaired Expression of 14-3-3{sigma} Is Not Associated with Altered p63 Expression—
In an effort to identify the molecular alterations that could be responsible for the down-regulation of 14-3-3{sigma} expression in invasive TCCs, we analyzed the levels of p63 in the invasive lesions, as several studies on human tumors have suggested an oncogenic function for p63 isoforms (29, 30), in particular in urothelial lesions (31–33). p63 is a homologue of the p53 gene that encodes two types of isoforms that can either function to transactivate p53 responsive genes (TAp63 isoforms) or act as a dominant-negative transcription factor ({Delta}Np63 isoforms) (29, 30). The dominant-negative splice variant {Delta}Np63 has transcriptional repressor activity and can bind to the 14-3-3{sigma} promoter in vivo (34). We performed double immunostainings to characterize the distribution of p63 and 14-3-3{sigma} in normal urothelium, TCCs of various grades and stages, as well as SCCs, using either a TAp63{alpha} or a {Delta}Np63{alpha} isoform-specific antibody (35) in combination with the 14-3-3{sigma}-specific antibody. In all cases examined, the expression of 14-3-3{sigma}, normal or aberrant, did not show any particular correlation with that of the p63 isoforms. SCCs (exemplified in Fig. 9A; SCC 536-1), noninvasive tumors (exemplified in Fig. 9B; 916-1 pTa G1), as well as high-grade invasive lesions (exemplified in Fig. 9C; 817-5 pT2-4 G3) all co-expressed the dominant-negative {Delta}Np63{alpha} and 14-3-3{sigma} (high levels), ruling out potential inhibitory effects of this isoform on 14-3-3{sigma} transcription as the basis for loss of expression. Conversely, we also found that the expression of the trans-activating isoform TAp63{alpha} does not correlate with high expression levels of 14-3-3{sigma}. Thus, SCCs (exemplified in Fig. 9D; SCC 536-1), noninvasive tumors (exemplified in Fig. 9B; 916-1 pTa G1), as well as high-grade invasive lesions (exemplified in Fig. 9C; 817-5 pT2-4 G3), all expressed the trans-activating isoform TAp63{alpha} in cells devoid of 14-3-3{sigma} (low levels).



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FIG. 9. Laser scanning analysis of the double-labeled immunofluorescence for 14-3-3{sigma} (Alexa Fluor® 594; red) and p63 (Alexa Fluor® 488; green). Original magnification, x100 (A and D, SCC 536-1), x800 (B and C, 916-1 pTa G1 and 817-5 pT2-4 G3, respectively), and x630 (E and F, 916-1 pTa G1 and 817-5 pT2-4 G3, respectively); also x630 for lower right panel inset in A (corresponding to the framed area in the lower left panel). This figure shows that 14-3-3{sigma} expression in tumors does not correlate with the dominant-negative splice variant {Delta}Np63 (A–C) nor with the trans-activating variant TAp63{alpha} (D–F).

 
Proliferative Status Is Not a Major Determinant of 14-3-3{sigma} Expression—
It has been shown that down-regulation of 14-3-3{sigma} can make primary human epithelial cells grow indefinitely (36) and that overexpression leads to inhibition of cell proliferation and prevents anchorage-independent growth of breast cancer cells (6), presumably due to inhibition of CDK activity. These results indicate that cell-cycle control is one of the key functions of 14-3-3{sigma} and thus down-regulation of this protein might be an important early event leading to uncontrolled cell growth of malignant cells. To determine if down-regulation of 14-3-3{sigma} was required for increased cell proliferation, we analyzed by 2D PAGE the levels of this protein in papillary tumors (low grade and stage) and in primary cultures (6 days) derived from them. As an example, Fig. 10 shows that high levels of expression of 14-3-3{sigma} in a pTa G1 tumor (with low proliferating cell nuclear antigen (PCNA) expression) were matched by comparably high amounts of {sigma} protein in the proliferating cultured cells (with high PCNA expression), indicating that malignant epithelial cell populations do not necessarily need to down-regulate 14-3-3{sigma} in order to proliferate, in agreement with the fact that several proliferating, invasive TCCs exhibited high levels of this protein.



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FIG. 10. Gel-based proteomic analysis of a low-grade papillary tumor and a primary culture derived from it. [35S]Methionine-labeled proteins synthesized by bladder TCC 519-1 (G1 Ta) specimen, and a primary cell culture derived from it (6 days in culture), were separated by 2D PAGE (IEF) and visualized by autoradiography. The area of the gel that contains the 14-3-3 ß, {sigma}, {eta}, and {zeta} isoforms is shown enlarged, with the positions for the respective isoforms indicated. Tropomyosin (tm) is also indicated as one of the changes that consistently occur during culturing. The position of the proliferation marker PCNA is indicated for reference.

 

    DISCUSSION
 TOP
 ABSTRACT
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
The 14-3-3{sigma} is a member of a multifunctional protein family that comprises seven isoforms (ß, {gamma}, {eta}, {tau}, {sigma}, {epsilon}, and {zeta}). These proteins are involved in a plethora of biological processes such as apoptotic cell death, mitogenic signal transduction, and cell-cycle control (1). The latter is particularly relevant in the case of the {sigma} isoform, as this protein has been shown to inhibit G2/M progression in a p53-regulated manner and is critical to uphold G2 arrest upon DNA damage in colorectal cancer cells (4, 7). Furthermore, 14-3-3{sigma} has been associated with Cdk2 and Cdk4, suggesting that it may also regulate G1/S progression (6). In primary human epidermal keratinocytes, down-regulation of 14-3-3{sigma} results in evasion from senescence (36), and inactivation of this protein in various cancers has been generally attributed to hypermethylation of the CpG island present in the promoter area of the 14-3-3{sigma} gene (9–17, 37). Down-regulation of 14-3-3{sigma}, however, is not a general requirement for neoplastic transformation as this protein is overexpressed in the neoplastic epithelium of pancreatic adenocarcinoma as compared with normal pancreas (39). Overall, these lines of evidence indicate that functional inactivation of 14-3-3{sigma} may be linked to carcinogenesis and suggest that silencing of 14-3-3{sigma} may be an important event in tumor progression in specific forms of cancer.

Here we have presented evidence showing that down-regulation of 14-3-3{sigma} in bladder carcinomas occurs mainly in invasive TCCs and that the low levels of 14-3-3{sigma} observed in some tumors are not due to increased externalization of the protein, or to the proliferative status of malignant cells as primary cultures derived from tumors of low grades and stages showed high levels of expression of this protein. We found that 10 out of 36 invasive specimens examined showed down-regulation of this protein, and of these, 6 out of the 10 corresponded to lesions undergoing EMT, a phenomena in which cells dissociate from the epithelia and migrate freely, thus contributing to the invasion and metastatic process (38). The manifestation of the mesenchyme phenotype was not merely due to sample contamination with connective tissue, as we could observe expression of PGP 9.5, a marker associated with mesenchymal neoplasms (28), which is not expressed in connective tissue (27). It is likely that down-regulation of 14-3-3{sigma} in high-grade neoplasms is due to the greater plasticity of these cells to differentiation events, as well as to the effect of the tumor microenvironment. The latter may explain the variability observed in immunoreactivity within the same tumor. Immunofluorescence analysis of cryostat sections confirmed these data, revealing positive staining of bladder epithelia in normal samples, but weak or negative staining of malignant cells in specimens that showed low levels of 14-3-3{sigma} as determined by 2D PAGE (Fig. 7). Additionally, we identified some specimens that albeit showing normal levels of 14-3-3{sigma} in 2D gels possessed heterogeneity areas devoid of 14-3-3{sigma} (mosaicism or progressive loss in the front of invasion of the tumor; Fig. 8), underscoring the importance of complementary immunostaining studies.

Interestingly, our studies also revealed generally elevated levels of 14-3-3{sigma} in SCCs compared with normal urothelium (Fig. 5), an observation that is in line with a recent report that demonstrated that 14-3-3{sigma} expression had a tendency to be stronger in cells destined for squamous epithelium or differentiating toward a squamous cell lineage (39). High levels of 14-3-3{sigma} have also been reported in hyperproliferative skin diseases, such as psoriasis, condylomata acuminata, and actinic keratoses (40, 41; see also proteomics.cancer.dk/2Dgallery/kerat+pso_kerat.html), suggesting again that down-regulation of this protein is not an absolute requirement for cellular proliferation. However, because 14-3-3 proteins are known for their potential to regulate cellular activity by binding and sequestering proteins containing a cognate phosphorylated consensus motif (1), we cannot exclude the possibility that expression of a {sigma}-interacting protein is affected in these cultured cells resulting in impaired cellular activity, functionally equivalent to down-regulation of 14-3-3{sigma}.

In an effort to shed some light into the molecular mechanism underlying the down-regulation of 14-3-3{sigma} in some invasive TCCs, we analyzed the expression of p63 in these lesions, as studies on human tumors have suggested an oncogenic function for p63 isoforms (29, 30) in urothelial lesions (31–33). p63 is a homolog of the p53 gene that encodes two types of isoforms that can either function to transactivate p53-responsive genes (TAp63 isoforms) or act as a dominant-negative transcription factor ({Delta}Np63 isoforms) (29, 30). The dominant-negative splice variant {Delta}Np63 has transcriptional repressor activity and can bind to the 14-3-3 {sigma} promoter in vivo (34). Our results showed concomitant expression of {Delta}Np63{alpha} and 14-3-3{sigma} in TCCs having both high and low expression of 14-3-3{sigma} (Fig. 9), ruling out potential inhibitory effects of this isoform on 14-3-3{sigma} transcription as the basis for the loss of expression observed. An alternative mechanism for the down-regulation of 14-3-3{sigma} is the targeting of this protein for proteasomal degradation by the ubiquitin E3-ligase Efp (10). However, we found no evidence of proteolytic fragments of 14-3-3{sigma} in the 2D PAGE and 2D Western analyses we performed, making Efp-targeted proteolysis, if anything, a minor contributing mechanism for down-regulation of 14-3-3{sigma} in invasive bladder carcinomas.

As a general rule one, can say that levels of 14-3-3{sigma} are highly cell-type dependent. Thus, squamous epithelial cells are clearly the cell type displaying the highest levels of 14-3-3{sigma}, whereas mesenchymal cells lack this protein. Similarly, SCCs overall show significantly higher levels of this protein than TCCs. In addition, tumor progression with associated epithelial plasticity also leads to altered levels of 14-3-3{sigma}, in particular in tumors undergoing EMTs, which display impaired expression of 14-3-3{sigma}. Consequently, quantification of 14-3-3{sigma} can potentially be of great value for the pathological evaluation of bladder carcinomas. Furthermore, conversion from an epithelial to a mesenchymal phenotype is increasingly being considered as an important event in carcinoma progression and metastasis, and to generally correlate with a poor prognosis of the disease, with loss of epithelial characteristics and acquisition of a migratory, fibroblastoid phenotype being associated with invasive cell behavior (39, 42, 43). Studying the molecular mechanisms involved in EMT might provide new insights into tumor progression and metastasis and may lead to the identification of molecular pathways and key regulators that are important for the progression of carcinoma toward dedifferentiated and more malignant states. Our results provide evidence that deregulation of 14-3-3{sigma} may play a key role in bladder cancer progression, in particular in differentiation events leading to EMT and stratified squamous metaplasia. In this respect, it is noteworthy to mention that 14-3-3{sigma} has recently been found as a gene associated with transforming growth factor ß-induced EMT in Ha-Ras-transformed EpH4 mammary epithelial cells (44). Levels of 14-3-3{sigma} can therefore present a valuable marker for tumor progression and aggressive behavior.

In summary, determination of functional threshold levels and clarification of the functional role(s) of 14-3-3{sigma} in bladder cancer progression may shed some light as to the molecular mechanism(s) involved in epithelial differentiation and plasticity in normal urothelium and provide a novel therapeutic target for the specific treatment of aggressive bladder carcinomas.


    ACKNOWLEDGMENTS
 
We thank Karin Nylander for providing p63 isoform-specific antibodies. We also thank Dorrit Lützhøft and Hanne Nors for expert technical assistance.


    FOOTNOTES
 
Received, December 18, 2003, and in revised form, January 21, 2004.

Published, MCP Papers in Press, January 21, 2004, DOI 10.1074/mcp.M300134-MCP200

1 The abbreviations used are: TCC, transitional cell carcinoma; SCC, squamous cell carcinoma; 2D PAGE, two-dimensional gel electrophoresis; FITC, fluorescein isothiocyanate; TRITC, tetramethyl rhodamine isothiocyanate; EMT, epithelial-to-mesenchymal transition; CK5, cytokeratin 5; PCNA, proliferating cell nuclear antigen; PGP 9.5, protein gene product 9.5; IEF, isoelectric focusing. Back

* This work was supported by grants from the Danish Cancer Society (to J. M. A. M. and J. E. C.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. Back

{ddagger} To whom correspondence should be addressed: Department of Proteomics in Cancer, Institute of Cancer Biology, Danish Cancer Society, Strandboulevarden 49, DK-2100 Copenhagen Ø, Denmark. Tel.: 45-35257500; Fax: 45-35257721; E-mail: jom{at}cancer.dk and jec{at}cancer.dk


    REFERENCES
 TOP
 ABSTRACT
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 

  1. van Hemert, M. J., Steensma, H. Y., and van Heusden, G. P. (2001) 14-3-3 proteins: Key regulators of cell division, signalling and apoptosis. Bioessays 23, 936 –946[CrossRef][Medline]

  2. Prasad, G. L., Valverius, E. M., McDuffie, E., and Cooper, H. L. (1992) Complementary DNA cloning of a novel epithelial cell marker protein, HME1, that may be down-regulated in neoplastic mammary cells. Cell Growth Differ. 3, 507 –513[Abstract]

  3. Leffers, H., Madsen, P., Rasmussen, H. H., Honore, B., Andersen, A. H., Walbum, E., Vandekerckhove, J., and Celis, J. E. (1993) Molecular cloning and expression of the transformation sensitive epithelial marker stratifin. A member of a protein family that has been involved in the protein kinase C signaling pathway. J. Mol. Biol. 231, 982 –998[CrossRef][Medline]

  4. Chan, T. A, Hermeking, H., Lengauer, C., Kinzler, K. W., and Vogelstein, B. (1999) 14-3-3{sigma} is required to prevent mitotic catastrophe after DNA damage. Nature 401, 616 –620[CrossRef][Medline]

  5. Samuel, T., Weber, H. O., Rauch, P., Verdoodt, B., Eppel, J. T., McShea, A., Hermeking, H., and Funk, J. O. (2001) The G2/M regulator 14-3-3{sigma} prevents apoptosis through sequestration of Bax. J. Biol. Chem. 276, 45201 –45206[Abstract/Free Full Text]

  6. Laronga, C., Yang, H. Y., Neal, C., and Lee, M. H. (2000) Association of the cyclin-dependent kinases and 14-3-3{sigma} negatively regulates cell cycle progression. J. Biol. Chem. 275, 23106 –23112[Abstract/Free Full Text]

  7. Hermeking, H., Lengauer, C., Polyak, K., He, T. C., Zhang, L., Thiagalingam, S., Kinzler, K. W., and Vogelstein B. (1997) 14-3-3{sigma} is a p53-regulated inhibitor of G2/M progression. Mol. Cell 1, 3 –11[Medline]

  8. Kino, T., Souvatzoglou, E., De Martino, M. U., Tsopanomihalu, M., Wan, Y., and Chrousos, G. P. (2003) Protein 14-3-3{sigma} interacts with and favors cytoplasmic subcellular localization of the glucocorticoid receptor, acting as a negative regulator of the glucocorticoid signaling pathway. J. Biol. Chem. 278, 25651 –25656[Abstract/Free Full Text]

  9. Logsdon, C. D., Simeone, D. M., Binkley, C., Arumugam, T., Greenson, J. K., Giordano, T. J., Misek, D. E., Kuick, R., and Hanash, S. (2003) Molecular profiling of pancreatic adenocarcinoma and chronic pancreatitis identifies multiple genes differentially regulated in pancreatic cancer. Cancer Res. 63, 2649 –2657[Abstract/Free Full Text]

  10. Urano, T., Saito, T., Tsukui, T., Fujita, M., Hosoi, T., Muramatsu, M., Ouchi, Y., and Inoue, S. (2002) Efp targets 14-3-3{sigma} for proteolysis and promotes breast tumour growth. Nature 417, 871 –875[CrossRef][Medline]

  11. Osada, H., Tatematsu, Y., Yatabe, Y., Nakagawa, T., Konishi, H., Harano, T., Tezel, E., Takada, M., and Takahashi, T. (2002) Frequent and histological type-specific inactivation of 14-3-3{sigma} in human lung cancers. Oncogene 21, 2418 –2424[CrossRef][Medline]

  12. Gasco, M., Bell, A. K., Heath, V., Sullivan, A., Smith, P., Hiller, L., Yulug, I., Numico, G., Merlano, M., Farrell P. J., Tavassoli, M., Gusterson, B., and Crook, T. (2002) Epigenetic inactivation of 14-3-3{sigma} in oral carcinoma: Association with p16INK4a silencing and human papillomavirus negativity. Cancer Res. 62, 2072 –2076[Abstract/Free Full Text]

  13. Gasco, M., Sullivan, A., Repellin, C., Brooks, L., Farrell, P. J., Tidy, J. A., Dunne, B., Gusterson, B., Evans D. J., and Crook, T. (2002) Coincident inactivation of 14-3-3{sigma} and p16INK4a is an early event in vulval squamous neoplasia. Oncogene 21, 1876 –1881[CrossRef][Medline]

  14. Umbricht, C. B., Evron, E., Gabrielson, E., Ferguson, A., Marks, J., and Sukumar, S. (2001) Hypermethylation of 14-3-3 {sigma} (stratifin) is an early event in breast cancer. Oncogene 20, 3348 –3353[CrossRef][Medline]

  15. Suzuki, H., Itoh, F., Toyota, M., Kikuchi, T., Kakiuchi, H., and Imai, K. (2000) Inactivation of the 14-3-3{sigma} gene is associated with 5' CpG island hypermethylation in human cancers. Cancer Res. 60, 4353 –4357[Abstract/Free Full Text]

  16. Ferguson, A. T., Evron, E., Umbricht, C. B., Pandita, T. K., Chan, T. A., Hermeking, H., Marks, J. R., Lambers, A. R., Futreal, P. A., Stampfer, M. R., and Sukumar, l. S. (2000) High frequency of hypermethylation at the 14-3-3{sigma} locus leads to gene silencing in breast cancer. Proc. Natl. Acad. Sci. U. S. A. 97, 6049 –6054[Abstract/Free Full Text]

  17. Iwata, N., Yamamoto, H., Sasaki, S., Itoh, F., Suzuki, H., Kikuchi, T., Kaneto, H., Iku, S., Ozeki, I., Karino, Y., Satoh, T., Toyota, J., Satoh, M., Endo, T., and Imai, K. (2000) Frequent hypermethylation of CpG islands and loss of expression of the 14-3-3{sigma} gene in human hepatocellular carcinoma. Oncogene 19, 5298 –5302[CrossRef][Medline]

  18. Pauli, B. U., Alroy, J., and Weinstein, R. S. (1983) The ultrastructure and pathobiology of urinary bladder cancer, in The Pathology of Bladder Cancer (Bryan, G. T., and Cohen, S. M., eds) Vol. II, pp.41 –140, CRC Press, Boca Raton, FL

  19. Celis, J. E., Wolf, H., and Østergaard, M. (2000) Bladder squamous cell carcinoma biomarkers derived from proteomics. Electrophoresis 21, 2115 –2121[CrossRef][Medline]

  20. Celis, J. E., Celis, P., Palsdottir, H., Østergaard, M., Gromov, P., Primdahl, H., Ørntoft, T. F., Wolf, H., Celis, A., and Gromova, I. (2002) Proteomic strategies to reveal tumor heterogeneity among urothelial papillomas. Mol. Cell. Proteomics 1, 269 –279[Abstract/Free Full Text]

  21. Celis, J. E., Østergaard, M., Basse, B., Celis, A., Lauridsen, J. B., Ratz, G. P., Andersen, I., Hein, B., Wolf, H., Ørntoft, T. F., and Rasmussen, H. H. (1996) Loss of adipocyte-type fatty acid binding protein and other protein biomarkers is associated with progression of human bladder transitional cell carcinomas. Cancer Res. 56, 4782 –4790[Abstract]

  22. Østergaard, M., Rasmussen, H. H., Nielsen, H. V., Vorum, H., Ørntoft, T. F., Wolf, H., and Celis, J. E. (1997) Proteome profiling of bladder squamous cell carcinomas: Identification of markers that define their degree of differentiation. Cancer Res. 57, 4111 –4117[Abstract]

  23. Bergkvist, A., Ljungqvist, A., and Moberger, G. (1965) Classification of bladder tumours based on the cellular pattern. Preliminary report of a clinical-pathological study of 300 cases with a minimum follow-up of eight years. Acta Chir. Scand. 130, 371 –378[Medline]

  24. Celis, J. E., Ratz, G., Basse, B., Lauridsen, J. B., and Celis, A. (1994) High-resolution two-dimensional gel electrophoresis of proteins: Isoelectric focusing and non-equilibrium pH gradient electrophoresis (NEPHGE), in Cell Biology: A Laboratory Handbook (Celis, J. E., ed) Vol. III, pp.222 –230, Academic Press, Orlando, FL

  25. Celis, A., Rasmussen, H. H., Celis, P., Basse, B., Lauridsen, J. B., Ratz, G., Hein, B., Østergaard, M., Wolf, H., Ørntoft, T., and Celis, J. E. (1999) Short-term culturing of low-grade superficial bladder transitional cell carcinomas leads to changes in the expression levels of several proteins involved in key cellular activities. Electrophoresis 20, 355 –361[CrossRef][Medline]

  26. Celis, J. E., Gromov, P. (2000) High-resolution two-dimensional gel electrophoresis and protein identification using western blotting and ECL detection. EXS 88, 55 –67[Medline]

  27. Campbell, L. K., Thomas, J. R., Lamps, L. W., Smoller, B. R., and Folpe, A. L (2003) Protein gene product 9.5 (PGP 9.5) is not a specific marker of neural and nerve sheath tumors: An immunohistochemical study of 95 mesenchymal neoplasms. Mod. Pathol. 16, 963 –969[CrossRef][Medline]

  28. Honoré, B., Rasmussen, H. H., Vandekerckhove, J., and Celis, J. E. (1991) Neuronal protein gene product 9.5 (IEF SSP 6104) is expressed in cultured human MRC-5 fibroblasts of normal origin and is strongly down-regulated in their SV40 transformed counterparts. FEBS Lett. 280, 235 –240[CrossRef][Medline]

  29. Wu, G., Nomoto, S., Hoque, M. O., Dracheva, T., Osada, M., Lee, C. C., Dong, S. M., Guo, Z., Benoit, N., Cohen, Y., Rechthand, P., Califano, J., Moon, C. S., Ratovitski, E., Jen, J., Sidransky, D., and Trink, B. (2003) {Delta}Np63{alpha} and TAp63{alpha} regulate transcription of genes with distinct biological functions in cancer and development. Cancer Res. 63, 2351 –2357[Abstract/Free Full Text]

  30. Little, N. A., and Jochemsen, A. G. (2002) p63. Int. J. Biochem. Cell Biol. 34, 6 –9[CrossRef][Medline]

  31. Urist, M. J., Di Como, C. J., Lu, M. L., Charytonowicz, E., Verbel, D., Crum, C. P., Ince, T. A., McKeon, F. D., and Cordon-Cardo, C. (2002) Loss of p63 expression is associated with tumor progression in bladder cancer. Am. J. Pathol. 161, 1199 –1206[Abstract/Free Full Text]

  32. Park, B. J., Lee, S. J., Kim, J. I., Lee, S. J., Lee, C. H., Chang, S. G., Park, J. H., and Chi, S. G. (2000) Frequent alteration of p63 expression in human primary bladder carcinomas. Cancer Res. 60, 3370 –3374[Abstract/Free Full Text]

  33. Koga, F., Kawakami, S., Kumagai, J., Takizawa, T., Ando, N., Arai, G., Kageyama, Y., and Kihara, K. (2003) Impaired {Delta}Np63 expression associates with reduced ß-catenin and aggressive phenotypes of urothelial neoplasms. Br. J. Cancer 88, 740 –747[CrossRef][Medline]

  34. Westfall, M. D., Mays, D. J., Sniezek, J. C., and Pietenpol, J. A. (2003) The {Delta}Np63{alpha} phosphoprotein binds the p21 and 14-3-3{sigma} promoters in vivo and has transcriptional repressor activity that is reduced by Hay-Wells syndrome-derived mutations. Mol. Cell. Biol. 23, 2264 –2276[Abstract/Free Full Text]

  35. Nylander, K., Vojtesek, B., Nenutil, R., Lindgren, B., Roos, G., Zhanxiang, W., Sjöström, B., Dahlqvist, A., and Coates, P. J. (2002) Differential expression of p63 isoforms in normal tissues and neoplastic cells. J. Pathol. 198, 417 –427[CrossRef][Medline]

  36. Dellambra, E., Golisano, O., Bondanza, S., Siviero, E., Lacal, P., Molinari, M., D’Atri, S., and De Luca, M. (2000) Downregulation of 14-3-3{sigma} prevents clonal evolution and leads to immortalization of primary human keratinocytes. J. Cell Biol. 149, 1117 –1130[Abstract/Free Full Text]

  37. Lehmann, U., Langer, F., Feist, H., Glockner, S., Hasemeier, B., and Kreipe, H. Quantitative assessment of promoter hypermethylation during breast cancer development. Am. J. Pathol. 160, 605 –612

  38. Thiery, J. P., and Chopin D. (1999) Epithelial cell plasticity in development and tumor progression. Cancer Metastasis Rev. 18, 31 –42[CrossRef][Medline]

  39. Nakajima, T., Shimooka, H., Weixa, P., Segawa, A., Motegi, A., Jian, Z., Masuda, N., Ide, M., Sano, T., Oyama, T., Tsukagoshi, H., Hamanaka, K., and Maeda, M. (2003) Immunohistochemical demonstration of 14-3-3 sigma protein in normal human tissues and lung cancers, and the preponderance of its strong expression in epithelial cells of squamous cell lineage. Pathol. Int. 53, 353 –360[CrossRef][Medline]

  40. Olsen, E., Rasmussen, H. H., and Celis, J. E. (1995) Identification of proteins that are abnormally regulated in differentiated cultured human keratinocytes. Electrophoresis 16, 2241 –2248[Medline]

  41. Lodygin, D., Yazdi, A. S., Sander, C. A., Herzinger, T., and Hermeking, H. (2003) Analysis of 14-3-3{sigma} expression in hyperproliferative skin diseases reveals selective loss associated with CpG-methylation in basal cell carcinoma. Oncogene 22, 5519 –5524[CrossRef][Medline]

  42. Birchmeier, C., Birchmeier, W., Brand-Saberi, B. (1996) Epithelial-mesenchymal transitions in cancer progression. Acta Anat. 156, 217 –126[Medline]

  43. Thiery J. P. (2002) Epithelial-mesenchymal transitions in tumour progression. Nat. Rev. Cancer 2, 442 –454[CrossRef][Medline]

  44. Jechlinger, M., Grunert, S., Tamir, I. H., Janda, E., Ludemann, S., Waerner, T., Seither, P., Weith, A., Beug, H., and Kraut, N. (2003) Expression profiling of epithelial plasticity in tumor progression. Oncogene 22, 7155 –7169[CrossRef][Medline]