Our previous study demonstrated that tyrosine phosphorylation of p145met/β-subunit of hepatocyte growth factor receptor by epidermal growth factor receptor and Src contributes to the anti-apoptotic growth of human bladder carcinoma cell 5637 under serum-starved conditions. Here, we show that some other cell lines of human bladder carcinoma, but not other types of human cancer cells, also exhibit Src-dependent, anti-apoptotic proliferation under serum-starved conditions, and that low-density, detergent-insoluble membrane microdomains (MD) serve as a structural platform for signaling events involving p145met, EGFR, and Src. As an MD-associated molecule that may contribute to bladder carcinoma-specific cellular function, we identified uroplakin IIIa (UPIIIa), an urothelium-specific protein. Results obtained so far revealed: 1) UPIIIa undergoes partial proteolysis in serum-starved cells; 2) a specific antibody to the extracellular domain of UPIIIa inhibits the proteolysis of UPIIIa and the activation of Src, and promotes apoptosis in serum-starved cells; and 3) knockdown of UPIIIa by short interfering RNA also promotes apoptosis in serum-starved cells. GM6001, a potent inhibitor of matrix metalloproteinase (MMP), inhibits the proteolysis of UPIIIa and promotes apoptosis in serum-starved cells. Furthermore, serum starvation promotes expression and secretion of the heparin-binding EGF-like growth factor in a manner that depends on the functions of MMP, Src, and UPIIIa. These results highlight a hitherto unknown signaling network involving a subset of MD-associated molecules in the anti-apoptotic mechanisms of human bladder carcinoma cells.
Cancer cells acquire one or more of the cancer cell-specific functions upon establishment of their malignancy. They include self-sufficiency of proliferation, insensitivity to anti-proliferation signals, sustained angiogenesis, anti-apoptotic growth (as highlighted in this study), limitless replication of genomic DNA, and tissue invasion and metastasis (Hanahan and Weinberg, 2000). Since the initial discovery of Ras protein as a causative gene product for some cases of bladder carcinoma in human, much attention has been paid to understand the relationship between cellular signal transduction and human cancer (Hanahan and Weinberg, 2000). Src and epidermal growth factor receptor/kinase (EGFR/kinase) are also classically as well as contemporary well-known examples, whose de-regulated protein functions by virtue of genetic mutations and/or altered expression level lead to an initiation, promotion, and progression of malignant cell transformation. Involvement of Src and/or EGFR/kinase in a number of specific cases of human cancer has become well documented and many specific inhibitors to them are now in use for clinical settings or trials (Aleshin and Finn, 2010; Hunter, 2009; Hynes and Lane, 2005). Against this background, however, the role played by Src and/or EGFR/kinase in bladder cancer is not well understood until recently (see below).
When a population of cancer cells arises in the vicinity of normal cells and tissues, there will be an insufficiency or complete lack of blood supply to those cancer cells. A similar type of shortage could also occur for cancer cells at later stages (e.g. upon invasive propagation). These conditions, involving lowered levels of oxygen pressure (i.e. hypoxia) and other factors for survival (e.g. growth factors and other nutrient compounds, as highlighted in this study), would act as selective pressure for cancer cells, by which only those successfully adapted would continue their malignant growth. It is well known that cancer cells overcome these kinds of environmental pressures by promoting several responses to hypoxia that include altered gene expression (e.g. up-regulation of hypoxia-inducible genes) and signal transduction for angiogenesis (e.g. expression of vascular endothelial growth factor) (Griffin and Shockcor, 2004; Harris, 2002). On the other hand, the molecular mechanisms of cancer cell adaptation to a shortage of survival factors remain less clear (for a review, see Pirkmajer and Chibalin, 2011).
Protein-tyrosine phosphorylation is a well-known mechanism of intracellular signal transduction, by which the transmembrane growth-controlling events (e.g. the binding of growth factor to the cognate cell surface receptor) are translated to the activation of cytoplasmic protein functions and nuclear gene expression. In general, protein-tyrosine phosphorylation catalyzed by receptor/kinase (e.g. EGFR/kinase) and/or cytoplasmic kinase (e.g. Src and other Src family kinases) in the normal cell system is a rapid and transient phenomenon in response to a transmembrane growth-promoting signal(s) (Hunter, 2009; Thomas and Brugge, 1997). In previous studies using 5637 human bladder carcinoma cells, serum-independent growth was reported (Ruck et al., 1994; Ruck and Paulie, 1997; Ruck and Paulie, 1998); however, we found that the activity of the tyrosine kinase Src became stably up-regulated after several hours of serum deprivation in the culture media (Yamamoto et al., 2006). Further studies demonstrated that the activated Src contributed to the anti-apoptotic growth of the 5637 cells under serum-starved conditions through phosphorylation of the β-subunit of c-Met/hepatocyte growth factor (HGF) receptor. In the present study, we have tried to achieve further insight into the anti-apoptotic mechanism involving Src by focusing on the importance of cholesterol-enriched membrane microdomains (MDs) and their associated molecules, whose architecture and cellular functions have recently been extensively studied (Brown and London, 1998; Hemler, 2005; Mahbub Hasan et al., 2011; Simons and Toomre, 2000). We demonstrate that MD-associated uroplakin IIIa, a transmembrane protein that has been originally identified and characterized as a major component of asymmetric unit membrane (AUM) of urinary bladder epithelium (Jenkins and Woolf, 2007; Khandelwal et al., 2009; Wu et al., 2009; Wu et al., 1994; Wu and Sun, 1993), plays an important role in the Src-dependent signal transduction.
Materials and Methods
Antibodies, inhibitors, and other reagents
Mouse anti-phosphotyrosine antibody (PY99) and rabbit anti-Met/HGF receptor antibody were purchased from Santa Cruz Biotechnology (Santa Cruz, CA). Mouse anti-Src antibody was obtained from Oncogene Research Products (San Diego, CA). Rabbit anti-active Src (phosphotyrosine-418 or pY418) and anti-inactive Src (phosphotyrosine-527 or pY529) antibodies were obtained from Biosource International (Camarillo, CA). Rabbit anti-active mitogen-activated protein kinase (phospho-MAPK or pMAPK) was from Cell Signaling Technology (Danvers, MA). Mouse antibody against β-tubulin was from BD Biosciences (Tokyo, Japan). Rabbit antibodies to the carboxyl-terminal region of human EGFR (anti-EGFR antibody), the extracellular domain or the carboxyl-terminal region of Xenopus laevis uroplakin III (UPIII) (anti-UPIII-ED and anti-UPIII-CT antibodies) were prepared as previously described (Mahbub Hasan et al., 2005; Sakakibara et al., 2005; Sato et al., 1995). Rabbit anti-human UPIIIa antibody was raised against a synthetic peptide that corresponds to residues 274–287 of the human UPIIIa (PLDRAEVYSSKLQD). Mouse anti-EGF antibody (mAb 528), goat anti-heparin binding EGF-like growth factor (HB-EGF) antibody (Ab-1), Src-specific tyrosine kinase inhibitor PP2 (4-amino-5-(4-chlorophenyl)-7-(t-butyl)pyrazolo[3,4-d]pyrimidine), its inactive analogs PP3 (4-amino-7-phenylpyrazol[3,4-d]pyrimidine), a broad-specificity inhibitor of matrix metalloproteinase (MMP) (N-[(2R)-2-(hydroxamido-carbonylmethyl)-4- methylpentanoyl]-L-tryptophan methylamide, GM6001), and its inactive analog GM6001 n.c. (N-t-butoxycarbonyl-L-leucyl-L-tryptophan methylamide), and a specific inhibitor for MAPK kinase (MEK) U0126 were obtained from Calbiochem-EMD Chemicals USA (Gibbstown, NJ). Protease inhibitors, leupeptin and (p-amidinophenyl)methane-sulfonyl fluoride hydrochloride (APMSF), were purchased from the Peptide Institute (Osaka, Japan) and Wako Pure Chemicals, respectively. Methyl-β-cyclodextrin was from Wako Pure Chemicals (Osaka, Japan). A synthetic substrate for caspase 3/7, Ac-Asp-Glu-Val-Asp-AMC (Ac-DEVD-AMC), was obtained from Calbiochem-EMD Chemicals USA. Protein A-Sepharose was obtained from Amersham Biosciences (Uppsala, Sweden). Other chemicals were of analytical grade and purchased from Sigma-Aldrich (St. Louis, MO), Wako Pure Chemicals, or Nacalai Tesque (Kyoto, Japan).
Cell culture and transfection
The following human cell lines were obtained from American Type Culture Collection (Rockville, MD): bladder carcinoma cell lines 5637, HT-1197, HT-1376, and UMUC-3, kidney carcinoma cell line ACHN, colon carcinoma cell line HT-29, breast cancer cell line MCF7, epidermoid carcinoma cell line A431, and embryonic kidney cell line 293; and were maintained in either DMEM or RPMI1640 medium supplemented with 10% fetal calf serum (FCS), 1 mM L-glutamine, and antibiotics. Cells were grown at 37°C in a humidified 5% CO2 atmosphere. For all experiments, confluent cells were trypsinized, and aliquots of single-cell suspension were re-seeded and cultured in poly-L-lysine-coated new culture dishes containing normal culture medium for 24–48 h. After the normal growth treatment, cells were treated in several different conditions as specified in the text. Quantification of cell number and cell viability was carried out as described previously (Yamamoto et al., 2006). For exogenous expression of FLAG-tagged kinase-negative or wild type Src, cells at 40–60% confluence in 60-mm dishes were incubated with 6 µg plasmid DNA per dish for 24 h using FuGeneTM reagent (Roche Applied Science, Indianapolis, IN) according to the manufacturer's protocol. For knockdown of UPIIIa, cells at 20–40% confluence in 35-mm dishes were transfected with none (DEPC-treated water alone), control short interference RNA (siRNA) (scrambled), or siRNA directed against UPIIIa, for 24–36 h using TransIT-siTKO reagents (MirusCorp., Madison, WI) according to the manufacturer's instructions. Three different silencer siRNA oligos for UPIIIa, whose sequences were not disclosed by the vendor, were purchased from Invitrogen (Carlsbad, CA). After the transfection treatments described above, cells were cultured under different conditions as specified in the text, analyzed for their proliferation and viability as described above, and processed for extraction and fractionation as described below.
Cell extraction and fractionation
All manipulations were carried out on ice or at 4°C. Cells in 60-mm dishes were washed twice with ice-cold phosphate-buffered saline (PBS) and supplemented with 0.15–0.3 ml of buffer per dish containing 1% Triton X-100, 150 mM NaCl, 20 mM Tris-HCl, pH 7.5, 1 mM EDTA, 1 mM EGTA, 10 mM β-mercaptoethanol, 1 mM sodium orthovanadate, 10 µg/ml leupeptin, and 20 µM APMSF. The mixtures were collected and homogenized with a Dounce homogenizer by 10–15 strokes, followed by incubation on ice for 10 min. The cell homogenates were then subjected to centrifugation at 500 g for 10 min to remove debris, and the supernatants were further centrifuged at 150,000 g for 20 min. The resulting supernatants were collected as Triton X-100-solubilized whole cell lysates (WCLs) and used for experiments. Alternatively, when low-density, detergent-insoluble (cholesterol-enriched) MDs were required, the debris-free supernatants prepared as above were subjected to discontinuous sucrose density gradient ultracentrifugation as described previously (Mahbub Hasan et al., 2007).
SDS-PAGE, immunoprecipitation, and immunoblotting
Protein samples, the amounts as specified in the text, were analyzed by SDS-polyacrylamide gel electrophoresis (SDS-PAGE) on 10% gels as previously described (Laemmli, 1970). Immunoprecipitation and immunoblotting using specific antibodies as specified in the text were performed as described previously (Yamamoto et al., 2006).
Enzyme-linked immunosorbent assay (ELISA)
The amounts of EGF and HB-EGF released into culture media from 5637 cells were quantified by ELISA. The culture media at the specified times of cell culture were collected and centrifuged in CentriconTM tubes (Millipore, Billerica, MA) at 3,000 g for 10–30 min. The concentrated supernatants were applied to a 96-well plate overnight at 4°C. After the overnight incubation, wells were blocked with BlockAce (Dainihon-Seiyaku, Japan) overnight at 4°C. Wells were then washed three times (3 min per wash) in PBS supplemented with 0.05% Tween 20 (T-PBS). Wells were then supplemented with the anti-EGF antibody, the anti-HB-EGF antibody, or the diluents for the antibodies (PBS containing 0.1% bovine serum albumin, B-PBS) alone. The antibody treatment proceeded for 2–3 h at room temperature and was terminated by washing with T-PBS (3 min × 3 times). Horseradish peroxidase-conjugated anti-mouse IgG or anti-goat IgG (Cappel, Germany) was then applied to wells at a dilution of 1:5,000 in B-PBS. The secondary antibody incubation proceeded for 2–3 h at room temperature and was terminated by washing with T-PBS (3 min × 3 times). The binding of the antibodies was demonstrated by the addition of a developing solution containing 66 mM NaHPO4, 33 mM citric acid, 0.015% H2O2, and 1 mg/mL O-phenylenediamine dichloride (OPD) compound (Sigma) for 20 min at room temperature. The color development was terminated by the addition of 2N H2SO4. Colorimetric determination was carried out with a spectrophotometer set at 492 nm.
Total RNAs were extracted from 5637 cells using an RNeasy Plus Mini kit (Qiagen, Valencia, CA) according to the manufacturer's instructions. The following manipulations and analyses were performed by Bio Matrix Research Inc. (Nagareyama, Japan). Quantity and/or quality of RNA samples were verified using a spectrophotometer and an electropherogram. To evaluate the expression level of mRNA for HB-EGF and EGF, and all other genes, the RNA samples were then analyzed using a microarray platform, GeneChip®Human Genome U133 PLUS 2.0 Array. Data obtained were analyzed using the GeneSpring® program.
Other methods and statistics
Protein content in the samples was determined spectrophotometrically using an assay kit (Nacalai Tesque). Enzyme assays for caspase 3/7 in the whole cell extracts were carried out as described previously (Yamamoto et al., 2006). All immunoblotting data are representative of more than three independent experiments. Bars in the graphical data are means ± standard deviations of three independent experiments.
Bladder carcinoma-specific, Src-dependent, and MAPK-independent proliferation under serum-starved culture conditions
We initially examined whether the Src-dependent survival and growth could be generally seen in serum-starved human bladder carcinomas (malignancy grade of 3–4) other than 5637 cells (malignancy grade of 2). Serum starvation promotes activation of Src in 5637 cells (2.2±0.2 fold, n = 4), as determined by the elevation of phosphorylation of tyrosine-418 in the Src molecule, and in two other cell lines: HT1197 (malignancy grade of 4) (1.4±0.3 fold, n = 4) and HT1376 (malignancy grade of 3) (2.8±0.6 fold, n = 4) (Fig. 1A). HT1197 and HT1376, like 5637 cells, exhibit serum-independent proliferation that could be blocked by PP2, an Src-specific inhibitor (Fig. 1B; supplementary material Fig. S1). In these cell lines, tyrosine phosphorylation of some other cellular proteins is also stimulated (data not shown). Under the same conditions, however, MAPK, a well-known protein kinase that is activated in response to serum stimulation (supplementary material Fig. S2), is not activated (Fig. 1A), as judged by the elevation of activating phosphorylation in normalized amounts of 42- and 44-kDa MAPK (data not shown). In addition, U0126, a potent inhibitor of the MAPK kinase (MEK), does not inhibit the serum-independent proliferation (Fig. 1B). On the other hand, UMUC3, another cell line of human bladder carcinoma (malignancy grade of 3), does not show any sign of Src activation (0.8±0.3 fold, n = 4) or proliferation under serum-starved conditions (Fig. 1A,B; supplementary material Fig. S1). It should also be noted that the expression level of Src in UMUC3 cells is much lower than that in other bladder carcinomas (Fig. 1A). Other types of human cancer or immortalized cells (renal carcinoma ACHN, 1.2±0.4-fold, n = 3; colon carcinoma HT29, 1.0±0.1-fold, n = 3; epidermoid carcinoma A431, 0.7±0.1-fold, n = 3; breast adenocarcinoma MCF7, 0.6±0.4-fold, n = 3; and embryonic kidney cell 293, 1.3±0.5-fold, n = 4) do not show any sign of Src activation under serum-starved conditions (Fig. 1). Interestingly, ACHN and A431 cells exhibit serum-independent and PP2-sensitive proliferation (Fig. 1B; supplementary material Fig. S1). However, proliferation of these cells is also sensitive to U0126 (Fig. 1B). There is a possibility that serum-independent proliferation of ACHN and A431 cells require basal activity of both Src and MAPK. Taking these findings together, we conclude that only a certain kind of bladder carcinoma cell is capable of proliferating under serum-starved conditions in an Src-dependent and MAPK-independent manner.
Requirement of Src activity for survival and proliferation in 5637 cells under serum-starved culture conditions
To evaluate further the specific importance of Src in serum-independent proliferation, 5637 cells expressing FLAG-tagged Src of either kinase-negative mutant (KN-Src) or wild type (WT-Src) and control cells were cultured in normal or serum-deprived conditions, and analyzed for their biochemical and cell biological properties. In control cells, serum starvation promoted tyrosine phosphorylation of p145met and endogenous Src, indicative of Src activation (Fig. 2A, lanes 1, 4). Serum-starved control cells exhibited an active proliferation (Fig. 2B) and a very low incidence in cell death (Fig. 2C), as seen in the serum-added control cells (Yamamoto et al., 2006). However, cells expressing KN-Src did not promote tyrosine phosphorylation in response to serum starvation (Fig. 2A, lanes 2, 5), and showed a reduced proliferation rate and signs of apoptosis, namely, elevated cell death and activation of caspase 3/7 (Fig. 2B,C). On the other hand, cells expressing WT-Src promoted tyrosine phosphorylation irrespective of culture conditions (Fig. 2A, lanes 3, 6), and showed a similar viability to the control cells (Fig. 2B,C). It should also be noted that, under serum-containing culture conditions, cell expressing KN-Src exhibited an active proliferation as seen in cells expressing WT-Src or control cells (data not shown). These results demonstrate that inhibition of Src activity impairs the ability of 5637 cells to survive and proliferate under serum-deprived culture conditions.
Cholesterol-enriched MDs play a role in the anti-apoptosis of serum-starved 5637 cells
We next examined the effect of methyl-β-cyclodextrin (MβCD), a substance that disrupts the cholesterol-dependent membrane structures, on the anti-apoptotic signal transduction and growth of serum-starved 5637 cells. Immunoblotting experiments demonstrated that MβCD inhibited the tyrosine phosphorylation of p145met and Src in serum-starved 5637 cells (Fig. 3A). The MβCD treatment blocked cell proliferation and induced cell death accompanied by stimulation of the caspase 3/7 activity (Fig. 3B,C). In normally cultured 5637 cells, a fraction of both p145met and Src, but not EGFR, localizes to the low-density, detergent-insoluble membrane (i.e. MD) fractions (Fig. 3D, control, FCS +). In serum-starved cells, tyrosine phosphorylated forms of p145met and Src predominantly localized to the MD fractions. Under the same conditions, EGFR was also recruited to the MD fractions (Fig. 3D, serum-starved). Co-incubation of serum-starved 5637 cells with MβCD, however, disrupted all of these characteristics (Fig. 3D, + MβCD).
MD-associated protein uroplakin III undergoes partial proteolysis in serum-starved 5637 cells
Results obtained from the study on MD led us to analyze the expression, localization, and function of a single-transmembrane protein, UPIIIa. In our previous studies on signal transduction of fertilization in Xenopus laevis, African clawed frog, UPIIIa and Src were shown to interact with each other to accomplish gamete interaction and subsequent induction of embryonic development (for a review, see Mahbub Hasan et al., 2011). UPIIIa was originally identified as an urothelial tissue-specific structural protein, and thus should make an important contribution to bladder-specific cancer cell functions. Immunoblotting experiments demonstrated that an antibody against the extracellular domain of Xenopus laevis UPIII (anti-UPIII-ED antibody) recognized a protein of 45 kDa, which is similar to known molecular sizes of mammalian UPIIIa protein on SDS-PAGE gels, in 5637 cells (Fig. 4A; supplementary material Fig. S3). The 45-kDa protein was also recognized by another antibody that was raised against the carboxyl-terminal sequence of human UPIIIa (data not shown). In addition, recombinant protein of the extracellular domain of Xenopus laevis UPIII interferes with the recognition of the 45-kDa protein, and treatment of the 5637 cell extracts with N-glycosidase resulted in a downshift of the 45-kDa band's mobility to 30 kDa, a known feature of mammalian UPIII (data not shown). From these data, we concluded that the immunoreactive 45-kDa protein is UPIIIa and conducted further experiments.
We next examined the expression of UPIIIa in other cell lines including non-bladder carcinomas. Immunoblotting experiments demonstrated that UPIIIa was expressed in all of the four bladder carcinomas, but not in non-bladder carcinomas (Fig. 4A). In bladder carcinomas, the expression level of UPIIIa, as normalized by the protein amounts tested (Fig. 4A, tubulin data), was higher in 5637, intermediate in UMUC3, and lower in HT1197 and HT1376, showing an inverse correlation with the malignancy grade of bladder cancer.
Subcellular fractionation studies demonstrated that UPIIIa localizes to both MD and non-MD fractions before and after serum starvation (Fig. 4B). In MβCD-treated 5637 cells, the localization of UPIIIa to the MDs was, like that of p145met, Src, and EGFR, entirely disrupted in both control (data not shown) and serum-starved culture conditions (Fig. 3B). Unlike p145met, Src, and EGFR, however, UPIIIa is not phosphorylated on tyrosine residues in response to serum starvation (data not shown). On the other hand, immunoblotting experiments demonstrated that UPIIIa underwent partial proteolysis, in which anti-UPIII immunoreactive bands of ∼25-kDa protein were newly appeared, in the course of serum starvation (Fig. 4C) that could be reversed by the addition of serum (Fig. 4D).
Uroplakin IIIa and matrix metalloproteinase play important roles in the anti-apoptosis of serum-starved 5637 cells
We then tried to explore the potential role of partial proteolysis of UPIIIa in serum-starved 5637 cells. To this end, we first surveyed a substance that could block the proteolysis of UPIIIa. In Xenopus laevis, it has been shown that two synthetic peptides that contain an Arg-Arg sequence, namely, UPIII-GRR peptide and BOC-GRR-MCA peptide (Mahbub Hasan et al., 2005), are inhibitory to partial proteolysis of UPIII by sperm-derived tryptic protease or by the purified cathepsin B. However, these peptides did not show any effect on the proteolysis of UPIIIa in serum-starved 5637 cells (supplementary material Fig. S4). On the other hand, the anti-UPIII-ED antibody and GM6001, a matrix metalloproteinase-specific inhibitor, were shown to inhibit the proteolysis of UPIIIa (Fig. 5A). Under the same conditions, tyrosine phosphorylation of Src was also inhibited (Fig. 5A), and the cells showed a reduced rate of proliferation (Fig. 5B) and underwent apoptotic cell death (Fig. 5C). These results suggest that partial proteolysis of UPIIIa is required for the activation of Src in serum-starved 5637 cells. However, an Src-specific inhibitor, PP2, which was shown to inhibit the activation of Src and the survival of 5637 cells (Yamamoto et al., 2006), also inhibited the proteolysis of UPIIIa (supplementary material Fig. S5), indicating that the activation of Src and the proteolysis of UPIIIa depend on each other (see Discussion).
Further support for the importance of UPIIIa was obtained with knockdown experiments. By using small interfering RNA approaches, we prepared 5637 cells transiently down-regulating UPIIIa (Fig. 6A, siRNA no. 3). Those knockdown cells exhibited an altered morphology in their peripheral regions when compared with control cells expressing UPIIIa normally (Fig. 6B), although its molecular insight is unknown. Moreover, knockdown of UPIIIa resulted in a reduced rate of proliferation (Fig. 6C) and enhanced the apoptotic cell death (Fig. 6D, siRNA no. 3). It should also be noted the occurrence depended upon the species of siRNA (Fig. 6B,C, siRNA no. 1 and no. 2).
Serum starvation promotes up-regulation of heparin-binding EGF-like growth factor and some other genes in an Src-dependent manner
It has been shown that serum-starved 5637 cells promote tyrosine phosphorylation and activation of EGFR (Fig. 3) (Yamamoto et al., 2006) through autocrined secretion of EGF and/or EGF-related ligands (Ruck and Paulie, 1998). Enzyme-lined immunosorbent assays demonstrated that secretion of HB-EGF, but not EGF, was upregulated in the course of serum starvation (Fig. 7A). Analyses of the expression level of mRNA using an Affymetrix Gene-chip array showed that serum starvation of 5637 cells promoted upregulation of HB-EGF in an Src-dependent manner (Fig. 7B). The array analyses also demonstrated a global change of gene expression in serum-starved 5637 cells. 1021 genes were identified to be more than 2-fold up-regulated in serum-starved cells (compared with control cells) (Fig. 7C, list shown on left), and 512 of these 1021 genes were found to be more than 2-fold down-regulated in serum-starved and PP2-containing culture conditions (compared with serum-starved cells). As a result, 66 genes were identified as being up-regulated in an Src-dependent manner (Fig. 7C; supplementary material Fig. S6). On the other hand, 1050 genes were identified as being down-regulated more than 0.5-fold in serum-starved cells (Fig. 7C, list shown on right), and 307 of these 1050 genes were found to be more than 2-fold up-regulated in serum-starved and PP2-containing conditions. As a result, 45 genes were identified as being down-regulated in an Src-dependent manner (Fig. 7C; supplementary material Fig. S7).
HB-EGF plays an important role in signal transduction and anti-apoptosis in serum-starved 5637 cells
An antibody against the HB-EGF had no effect on the proteolysis of UPIIIa; however, it caused inhibition of the activation of Src and promoted apoptotic cell death in serum-starved 5637 cells (Fig. 8A,B). These results suggest that HB-EGF acts as an upstream, positive signal for Src activation in response to serum starvation and that proteolysis of UPIIIa is an independent phenomenon from such a signaling cascade involving HB-EGF (see Discussion). Secretion of HB-EGF was inhibited by GM6001 and consistently, the tyrosine kinase signaling involving phosphorylation of p145met and Src was also impaired under the same conditions (Fig. 8C,D). Inhibition of the secretion of HB-EGF was also observed with the anti-UPIII-ED antibody, PP2, and MβCD treatments (Fig. 8D). These results suggest that proteolysis of UPIIIa, Src activity, and cholesterol-enriched MDs are required for the HB-EGF secretion in response to serum starvation.
Serum starvation has been widely employed as a means of control treatment of cells whose reactions to a variety of extracellular stimuli (e.g. growth factors) are of interest. During the past several years, however, serum starvation by itself has received much attention from researchers (Pirkmajer and Chibalin, 2011; Tavaluc et al., 2007); namely, it has been employed as a model experimental condition of interest, by which researchers can investigate the behavior of cancer cells under such a stressful environment in vitro. Other experimental conditions that could represent the physiological microenvironment of cancer cells in vivo include hypoxia (low O2 concentration), lack of cell adhesion to substratum (leading to anoikis in normal cells), and low nutrient (e.g. depletion of glucose). Under these stressful conditions, cancer cells with high malignancy somehow acquire the ability to evade the onset of apoptosis. Our previous study using the bladder carcinoma cell 5637 demonstrated that the tyrosine kinase signaling pathway involving Src, EGFR, and Met acts as an anti-apoptotic mechanism that allows the cells to proliferate under serum-starved culture conditions (Yamamoto et al., 2006). On the other hand, other types of human cancer cells employ Akt protein kinase (Huang et al., 2011; for a review, see Hemmings, 1997), protein kinase Cδ (Chen et al., 2010), glycogen synthase kinase 3β (Yang et al., 2010), AAA-ATPase (Fang et al., 2010), and survivin (Islam et al., 2000) as an anti-apoptotic or anti-death mechanism under serum-starved conditions. This background led us to examine further the role of tyrosine kinase signaling pathway in 5637 and other bladder carcinoma cells.
In this study, we show that serum-independent proliferation operates not only in 5637 cells but also in some other bladder carcinoma cells (HT1197 and HT1376) (Fig. 1). In these cells, serum starvation promotes Src activation and no MAPK activation, and consistently, PP2, a pharmacological Src inhibitor, but not U0126, an inhibitor of MAPK kinase (MEK), blocks the cell proliferation and lead to apoptosis under serum-starved conditions. It should be noted that elevation of activating phosphorylation on tyrosine-418 of Src is always observed in serum-independent proliferation-positive cells, whereas a decrease in inhibitory phosphorylation on tyrosine-529 is hardly detectable in these cells, suggesting a phosphatase-independent, but UPIIIa-dependent, mechanism of Src activation (see below). Forced expression of kinase-inactive Src mutant also abolishes the proliferation and promotes apoptosis of serum-starved 5637 cells (Fig. 2). These results suggest that anti-apoptotic serum-independent proliferation of bladder carcinoma cells involves Src-dependent and MAPK-independent mechanisms, whereas the opposite mechanisms (i.e. Src-independent and MAPK-dependent) seem to work under serum-containing conditions (supplementary material Fig. S2). On the other hand, we did not detect 5637 cell-like functions in other types of human cancer or immortalized cells (A431, ACHN, HEK293, HT29, and MCF7) (Fig. 1; supplementary material Fig. S1). Thus, the Src-dependent and MAPK-independent mechanisms of anti-apoptosis under serum-starved conditions seem to be a specific feature of bladder carcinoma cells.
As a structural platform for Src tyrosine kinase signaling in 5637 cells, we have identified and characterized cholesterol-enriched MDs, where Src, EGFR, and Met are stably or transiently localized and activated in response to serum starvation (Fig. 3). Serum-starved 5637 cells undergo apoptosis in the presence of MβCD, a drug that disrupts the cholesterol-dependent structure and function of MDs. MβCD is also shown to abolish the MD localization of Src, EGFR, and Met and their activating phosphorylations (Fig. 3). It should be noted that the protein expression level of these signaling molecules is not altered in MβCD-treated cells, suggesting that their MD localizations are important for signal transduction and cell behavior. Several lines of evidence indicate that, in a variety of cells and tissues, and irrespective of physiological and pathological situations, MDs and their associated molecules (e.g. proteins, lipids) play an important role in sensing extracellular environmental signals and triggering the cellular responses (Brown and London, 1998; Simons and Toomre, 2000). Although it is currently unknown how serum starvation is sensed and translated to signal transduction in 5637 cells (see below), our present study demonstrates for the first time the importance of MDs in this kind of signal transduction.
Cellular functions of MDs often require a certain kind of membrane protein(s) (e.g. caveolin, tetraspanin, and their associated proteins) that acts as a membrane organizer (Anderson, 1998; Hemler, 2005). In this study, we have identified UPIIIa, an urothelium-specific, type I transmembrane protein that is a member of the UP protein family, as an MD-associated component of serum starvation-induced Src tyrosine kinase signaling leading to anti-apoptotic proliferation in 5637 cells. Like Src and Met, UPIIIa stably localizes to MDs irrespective of serum conditions in a cholesterol-dependent manner (Fig. 4). Further experiments demonstrated that UPIIIa undergoes partial proteolysis in response to serum starvation (Fig. 4), and that the inhibition of the proteolysis by a specific antibody to the extracellular domain of UPIIIa or an MMP inhibitor GM6001 results in failure of Src activation and the occurrence of apoptosis (Fig. 5). Moreover, knockdown of UPIIIa by short interfering RNA also promotes apoptosis of serum-starved 5637 cells (Fig. 6). From these data, we conclude that UPIIIa is involved in Src-dependent signal transduction for survival and proliferation of 5637 cells under serum-starved conditions.
UPIIIa was originally identified in mammals, including humans, as a component of AUMs that are made of clusters of 16-nm crystal structures in the apical surface of water-impermeable urothelial cell membranes (Jenkins and Woolf, 2007; Khandelwal et al., 2009; Liang et al., 2001; Wu et al., 2009; Wu and Sun, 1993). In the structures of AUMs, all four members of the UP family protein are indispensable: UPIIIa forms a heterodimer with uroplakin Ib (UPIb), a tetraspanin molecule, and the UPIb-UPIIIa complex associates further with UPIa (tetraspanin)-UPII (type I transmembrane protein) complex (Liang et al., 2001; Wu et al., 1994; Wu et al., 1990). On the other hand, the role of individual UP family proteins in bladder cell function has also been demonstrated recently (Lobban et al., 1998; Moll et al., 1995). In particular, the following cellular features and/or functions of mammalian UPIIIa other than for urothelial membrane architecture (Hu et al., 2000) have been reported: 1) it can be used as a urinary marker for the detection of bladder cancer (Lai et al., 2010), 2) its expression level inversely correlates with the malignancy grade of bladder cancers (Fig. 4A) (Koga et al., 2003; Matsumoto et al., 2008; Ohtsuka et al., 2006; Parker et al., 2003), 3) mutation in the UPIIIa sequence is often associated with the occurrence of some renal diseases (Jenkins et al., 2005; Schönfelder et al., 2006), and 4) it is involved in urothelial cell death or casein kinase II-dependent phospho-signal transduction in response to uropathogenic bacterial infection (Thumbikat et al., 2009a; Thumbikat et al., 2009b). In addition, studies using the African clawed frog Xenopus laevis have demonstrated that fertilization triggers partial proteolysis and tyrosine phosphorylation of UPIIIa in egg, and that the egg UPIIIa associates with UPIb and localizes to MDs, and thus may be involved in sperm-induced activation of Src tyrosine kinase signaling (Mahbub Hasan et al., 2011; Mahbub Hasan et al., 2007; Mahbub Hasan et al., 2005; Sakakibara et al., 2005). Taken these findings into account, it is not so surprising that UPIIIa, through its MD localization and partial proteolysis (but not tyrosine phosphorylation), is involved in the Src-dependent signal transduction for anti-apoptosis in serum-starved 5637 cells.
Currently, it is not known how functions of UPIIIa (partial proteolysis) and Src in 5637 cells are connected. In the case of Xenopus egg system, it has been suggested that, in unfertilized eggs, the UPIb/UPIIIa complex negatively regulates the activity of Src and that, upon fertilization, negative regulation of Src is canceled by the action of sperm-derived tryptic protease (Mahbub Hasan et al., 2011; Mahbub Hasan et al., 2007; Mahbub Hasan et al., 2005). In this case, proteolysis of UPIIIa does not require Src activity (signal flows mono-directionally from UPIIIa-like protein to Src). In serum-starved 5637 cells, application of an antibody against the extracellular domain of UPIIIa blocks the proteolysis of UPIIIa and activation of Src, suggesting that the proteolysis of UPIIIa occurs in a similar manner to that seen in Xenopus egg. However, neither inhibitors nor a synthetic substrate for tryptic protease block the proteolysis of UPIIIa (supplementary material Fig. S4). Instead, GM6001, a broad-specificity inhibitor of MMP, shows a strong inhibitory effect on UPIIIa proteolysis, Src activation, and cell survival and proliferation (Fig. 5). Thus, partial proteolysis of UPIIIa in serum-starved 5637 cells seems to involve MMP activity. Interestingly, Src inhibitor PP2 also blocks proteolysis of UPIIIa (supplementary material Fig. S5), suggesting that proteolysis of UPIIIa and activation of Src constitute a positive feedback loop (signal flows bi-directionally between UPIIIa and Src) (Fig. 9).
It is well known that extracellular secretion of EGF ligands such as EGF and HB-EGF depends on the activity of MMPs that process the immature and membrane-anchored forms of EGF and HB-EGF (Higashiyama et al., 2008; Miyamoto et al., 2006; Sanderson et al., 2006). In fact, we demonstrated that expression and secretion of HB-EGF, but not EGF, is up-regulated in serum-starved 5637 cells in a GM6001-sensitive manner (Figs 7, 8). Further characterization of HB-EGF employing its neutralizing antibody as well as aforementioned experimental conditions demonstrates that HB-EGF is an important factor for the Src-dependent anti-apoptosis mechanism (Fig. 8). Moreover, it is suggested that MMP-dependent production of HB-EGF and Src activation constitute a positive feedback loop (Fig. 9). On the other hand, blockage of HB-EGF does not result in inhibition of partial proteolysis of UPIIIa, whereas specific inhibition of UPIIIa proteolysis attenuates the secretion of HB-EGF (maybe because of Src inhibition). Taking these findings in together, we suggest that the anti-apoptotic mechanism of 5637 cells under serum-starved conditions involves a signal transduction system of hitherto unknown combination, that is, activity of MMPs, HB-EGF, UPIIIa, and Src, all of which are connected with each other (Fig. 9). DNA microarray analysis carried out in this study demonstrates that expression of a number of genes may be up- or down-regulated under the control of Src activity (Fig. 7; supplementary material Figs S6, S7). In future study, we will examine how the membrane-associated, non-genomic signaling machinery, mainly highlighted in the present study, interacts with the nuclear, genomic regulatory system. This kind of study will also involve the characterization of sensing system for serum starvation, possibly metabolic regulatory machinery in anti-apoptosis of cancer cells.
We thank the former and current members of our laboratories. This work is supported in part by a Grant-in-Aid for Scientific Research (B), Japan Society for the Promotion of Science (19370094), a grant for Private University Strategic Research Foundation Support Program (S0801060), and a Grant-in-Aid on Innovative Areas, Ministry of Education, Culture, Sports, Science, and Technology, Japan (22112522) to K.S.
↵‡ Present address: Department of Biochemistry and Molecular Biology, University of Dhaka, Dhaka 1000, Bangladesh
Competing interests The authors have no competing interests to declare.
- Received March 1, 2012.
- Accepted June 6, 2012.
- © 2012. Published by The Company of Biologists Ltd
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