Cathepsin B is involved in the apoptosis intrinsic pathway induced by Bacillus Calmette-Guérin in transitional cancer cell lines

Bacillus Calmette-Guérin (BCG) is the most effective treatment for superficial and in situ transitional bladder cancer. Although the complete mechanisms for its effect are not fully understood yet, both immunological and direct effects on tumor cells have been proposed. It has been proposed that apoptotic tumor cells could be better inducers of immunity than necrotic ones. Thus, apoptosis of bladder cancer cells could contribute to a global response to BCG. Lysosomal hydrolase cathepsin B (CB) is involved in the apoptotic process and has a key role in breast cancer cell programmed death through the activation of a pro-apoptotic protein BID. Truncated BID participates in the mitochondrial apoptotic pathway that involves the activation of pro-caspase 9. The possibility that CB can be involved in apoptosis of TCC line has not been explored yet. Therefore, we analyzed the participation of CB in BCG-induced apoptosis of human and murine TCC lines. Apoptosis was evaluated by a morphologic assay and CB activity by a substrate-specific colorimetric method. Expression of CB, BID and pro-caspase 9 was determined by Western blotting. BCG induced apoptosis of murine (MBT2, MB49) and human (T24) TCC lines. An increase in both CB activity and protein was also observed. The apoptosis of T24 and MB49 cell lines was mediated by activation of pro-caspase 9 and BID, both proteins are involved in mitochondrial apoptosis. Apoptosis and activation of pro-caspase 9 and BID were inhibited by CA-074Me (CA), a cell permeable CB inhibitor. Thus, CB is involved in BCG-induced apoptosis of TCC lines, using at least in part the mitochondrial pathway.     

HLA-G polymorphism and transitional cell carcinoma of the bladder in a Brazilian population

The morphologic appearance and clinical behavior of the human urinary bladder papillary transitional cell carcinoma (TCC) probably result from a complex interaction between carcinogenic insults and host resistance during the patient's life. While the main recognized risk factors are of environmental origin (e.g. smoking), relatively little information exists about the susceptibility to TCC development. The human leukocyte antigen G (HLA-G) molecule plays an important role in immune response regulation and has been implicated in the inhibition of the cytolytic function of natural killer and cytotoxic T cells. Several lines of evidence indicate that HLA-G polymorphisms influence the expression level and production of different HLA-G isoforms. The aim of this study was to explore a possible influence of the HLA-G polymorphism on the susceptibility to urinary bladder TCC development and progression in smokers and nonsmokers Brazilian subjects. The HLA-G locus was found to be associated with susceptibility to TCC development and progression. The G*0104 allelic group (specially the G*010404 allele) and the G*0103 allele were associated with a tobacco-dependent influence on TCC development. The G*0104 group was associated with progression to high-grade tumors, irrespective of smoking habit, while the G*0103 allele was associated to high-grade tumor only in smoking patients. Our results are an evidence that the HLA-G locus itself, or as part of an extended haplotype encompassing this chromosome region (particularly the HLA-A given the high linkage disequilibrium observed between them in this data series), may be associated with TCC susceptibility and tumor progression, suggesting a tobacco-dependent influence of these polymorphisms.     

FEZ1/LZTS1 is down-regulated in high-grade bladder cancer, and its restoration suppresses tumorigenicity in transitional cell carcinoma cells

FEZ1/LZTS1 is a tumor suppressor gene that maps to chromosome 8p22, a chromosomal region frequently deleted in many human malignancies, including transitional cell carcinoma (TCC) of the urinary bladder. FEZ1/LZTS1 alterations have been reported in esophageal, breast, prostate, and gastric carcinomas. Fez1 expression was studied in five TCC-derived cancer cell lines by Western blot analysis and in 60 primary TCCs of the urinary bladder by immunohistochemistry. Fez1 protein was absent or reduced in four of five cell lines and in 37 of 60 primary TCC examined. We also restored Fez1 protein expression in human SW780 TCC-derived cells lacking endogenous Fez1 protein to study the effects of Fez1 expression on cell proliferation, cell kinetics, and tumorigenicity in BALB/c nude mice. In vitro transduction of SW780 Fez1-negative cell, with Ad-FEZ1, inhibited cell growth, altered cell cycle progression, and suppressed subcutaneous tumor growth in nude mice. These results suggest that FEZ1/LZTS1 gene plays a role in the development of TCC of the urinary bladder by acting as a bona fide tumor suppressor gene both in vitro and in vivo.     

The relationship of BRMS1 and RhoGDI2 gene expression to metastatic potential in lineage related human bladder cancer cell lines

We have recently characterized a human bladder cancer cell line T24 and a more aggressive lineage related variant of it, T24T. To gain further insights, we have studied their metastatic ability in an in vivo model system. Results show that T24 forms significantly fewer [4/12 (1/11) mice had metastases with 1-2 lesions/mouse] metastasis in SCID/bg mice than T24T [14/14 (6/6) mice had metastases with a mean of 24-28 lesions/mouse]. To begin exploring the mechanisms underlying this difference, we evaluated the mRNA and protein expression levels of metastasis-suppressor genes, known to be important in the progression of other cancers, in our model of bladder cancer progression. A higher mRNA expression of BRMS1, a metastasis suppressor in breast cancer, was observed in T24 cells. In addition, RhoGDI2 mRNA expression was only observed in T24 when compared to T24T, suggesting that Rho activation might play a significant role in the metastatic cascade. However, a basal level mRNA expression of KISS1, described as metastasis suppressor in melanoma and breast, was observed in both the lines and had slightly higher expression in T24T. No difference of Nm23-H1, KAI1, MKK4/SEK1 and E-Cadherin protein levels were noted between these two lines. In summary, it appears that the T24/T24T paired cell lines constitute a useful model for the study of human bladder cancer metastasis that will allow both the discovery and mechanistic evaluation of genes potentially involved in this process. This revised version was published online in July 2006 with corrections to the Cover Date.     

The loss of expression of transforming growth factor-beta receptors correlates with the histopathologic tumor grade in bladder transitional cell carcinoma patients.

Transforming growth factor-beta (TGF-beta), a pleiotropic growth factor, is a potent inhibitor of cellular proliferation in cells of epithelial origin. Recently, it has been suggested that a loss of sensitivity to TGF-beta through a loss of expression of TGF-beta receptors T beta R-I and T beta R-II--is associated with tumor initiation and progression. Therefore, to investigate the relationship between TGF-beta receptors expression and carcinogenesis of bladder TCC, this study examined the expression of T beta R-I and T beta R-II in 46 bladder TCC patients using immunohistochemistry. Since histopathological grade is a widely accepted marker of prognosis, the results were compared in relation to the three grades of bladder TCC. The results demonstrated that the loss of TGF-beta receptors expression is associated with increasing histopathological grades of bladder TCC. Specifically, both T beta R-I and T beta R-II were readily detected in all 10 normal bladder mucosa specimens. Likewise, all 6 specimens of grade I TCC samples expressed high levels of both TGF-beta receptors. However, among grade II TCC samples, T beta R-I and T beta R-II were detected in 78% and 89%, respectively: among grade III TCC samples, T beta R-I and T beta R-II were detected in 45% and 41%, respectively. These results suggested that loss of sensitivity to TGF-beta may play a role in the progression of TCC from low to high grade disease.     

Human urinary bladder transitional cell carcinomas acquire the functional Fas ligand during tumor progression

The interaction between FasL on tumor cells and Fas on lymphocytes may represent a tumor immune escape mechanism. We explored FasL expression and function in human urinary bladder transitional cell carcinomas (TCCs). FasL expression was observed in situ in 45% of TCCs (n = 45) and was absent in normal urothelium (n = 20). A correlation existed between FasL expression and high tumor grade (0% in G1, 14% in G2, and 75% in G3; P < 0.0001) and stage (13% in superficial Ta-T1 versus 81% in invasive T2-T4; P < 0.0001). FasL function was shown by the ability of two FasL-positive primary culture TCC cell lines (established from two FasL-positive invasive TCCs) to induce Fas-mediated killing not only of conventional Fas-sensitive targets (such as Jurkat cells or phytohemagglutinin-lymphoblasts), but also of autologous T lymphocytes generated in a mixed lymphocyte tumor-cell culture. In addition, an association between FasL expression by TCC cells and activated caspase-8, -9, and -3 expression by interferon-gamma-producing CD8-positive tumor-infiltrating lymphocytes was observed in situ. Our results show a functional expression of TCC-expressed FasL that correlates with tumor progression. These results suggest that TCC-expressed FasL may induce apoptosis of anti-tumor T lymphocytes in vivo, providing new insights on the mechanisms involved in bladder TCC progression.     

Patterns of protein kinase C isoenzyme expression in transitional cell carcinoma of bladder. Relation to degree of malignancy

We determined the pattern of protein kinase C (PKC) isoform expression in human cell lines by Western blotting and immunofluorescent staining techniques. In addition, we examined PKC isoform expression in tissue samples of transitional cell carcinoma (TCC) of the bladder. PKC delta, PKC beta II, and PKC eta were found primarily in the RT4 cell line (low-grade tumor), and PKC zeta was expressed most strongly in the SUP cell line (invasive tumor). In tissue samples of urinary bladder cancer, PKC isoenzymes were expressed differentially as a function of tumor stage and grade; expression of PKC beta II and PKC delta was high in normal tissue and in low-grade tumors and decreased with increasing stage and grade of TCC. The opposite pattern was seen with PKC zeta. The differences in expression of specific isoenzymes as related to levels of malignancy of the cell lines and tissue samples suggest that the PKC family has an important role in normal and neoplastic urothelium.     

Highly invasive transitional cell carcinoma of the bladder in a simian virus 40 T-antigen transgenic mouse model

Transitional cell carcinoma (TCC), a neoplasm of urinary bladder urothelial cells, generally appears in either of two forms, papillary non-invasive or invasive TCC, although intermediate forms can occur. Each has a distinctive morphology and clinical course. Altered expression of the p53 and pRb genes has been associated with the more serious invasive TCC, suggesting that the loss of activity of these tumor suppressor proteins may have a causal role in this disease. To test this hypothesis directly, transgenic mice were developed that expressed the simian virus 40 large T antigen (TAg) in urothelial cells under the control of the cytokeratin 19 gene (CK19) regulatory elements. In one CK19-TAg lineage, all transgenic mice developed highly invasive bladder neoplasms that resembled invasive human bladder TCCs. Stages of disease progression included development of carcinoma in situ, stromal invasion, muscle invasion, rapid growth, and, in 20% of affected mice, intravascular lung metastasis. Papillary lesions never were observed. Western blot analysis indicated that TAg was bound to both p53 and pRb, which has been shown to cause inactivation of these proteins. Our findings support suggestions that (i) inactivation of p53 and/or pRb constitutes a causal step in the etiology of invasive TCC, (ii) papillary and invasive TCC may have different molecular causes, and (iii) carcinoma in situ can represent an early stage in the progression to invasive TCC.     

Pro-inflammatory type-1 and anti-inflammatory type-2 macrophages differentially modulate cell survival and invasion of human bladder carcinoma T24 cells

Findings from numerous studies suggest that inflammation is likely to have an important role in bladder carcinogenesis and cancer disease progression. While macrophages (M?s) constitute a major inflammatory component of the stroma of human bladder carcinoma, the regulatory role of such inflammatory leukocytes in tumor cell survival and invasion remains elusive. Human urothelial bladder cancer (UBC) T24 cells and monocyte-derived macrophages were used to study the relative contribution of pro-inflammatory type-1 (M?-1) and anti-inflammatory type-2 (M?-2) macrophages in the regulation of UBC cell behaviour. Cell-to-cell studies indicated that the number of viable cells were considerable higher in T24 cell/M?-2 cocultures but lower in T24 cell/M?-1 cocultures when compared to cultures of T24 cells alone. M?-1-derived factors inhibit T24 cell growth but fail to induce caspase-3-mediated apoptosis. M?-2-derived factors have the ability to suppress the inhibitory effect of M?-1-derived factors on T24 cell growth. Exogenous interleukin (IL)-10 reverse M?-1-mediated arrest growth in T24 cell/M?-1 cell cocultures. Further analyses showed that M?-1-derived factors induced tumor necrosis factor (TNF)-α gene expression, promoted cellular invasiveness and increased phosphoinositide 3-kinase (PI 3-K)/Akt signaling pathway activity in T24 cells. Inhibition of PI 3-K activation in T24 cells or blockade of TNFα receptor in T24 cell/M?-1 cell cocultures decreased cellular invasiveness but did not affect T24 cell viability. Based on these observations, we propose that similar functional interactions between UBC cells and infiltrating macrophages can take place in vivo and influence tumor cell survival and invasion during bladder cancer progression.     

Aneusomy for detection of bladder cancer recurrence: a Southwest Oncology Group study

The high risk of recurrence in superficial transitional cell cancer (TCC) of the bladder prompted evaluation of whether chromosome changes detected at first recurrence were correlated with relapse or with response to fluoroquinolone treatment. Fluorescence in situ hybridization analysis was applied to desquamated cells from bladder washings obtained immediately before surgical resection. Cells were screened for numeric changes in chromosomes 7 and 9. Aberrations were identified in 38/54 patients eligible for evaluation. Although no clear associations were established owing to sample size, the results suggested that risk of progression/relapse was positively associated with loss of chromosome 9 and with polysomy, and negatively associated with gain of chromosome 7, the latter in contrast to published data. A short-term survival advantage was noted anecdotally with gain of chromosome 9.     

Influence of the microenvironment on invasiveness of human bladder carcinoma cell lines

To investigate the importance of the microenvironment in bladder cancer invasion, a panel of six bladder carcinoma cell lines (SD, RT112, JON, 1207, T24, and J82) was tested in both in vitro and in vivo invasion assays. Furthermore, invasiveness was correlated with the expression of components of the E-cadherin-catenin complex. The E-cadherin-negative cell lines, T24 and J82, displayed a high in vitro invasive capacity, whereas the E-cadherin-positive cell lines, SD and JON, completely lacked in vitro invasive capacity. In contrast, in vivo invasion was noted for all cell lines, with the exception of cell line JON. Most notably, SD formed highly invasive tumors in vivo. The in vivo invasiveness of the E-cadherin-positive bladder carcinoma cell lines was associated with a heterogeneous expression of the E-cadherin-catenin complex. The discrepancy between in vitro and in vivo invasive behavior implies that, in vivo, the microenvironment plays an important role in the establishment of the invasive phenotype. In addition, it was found that orthotopic xenografting of 1207 and T24 bladder carcinoma cells resulted in site-specific tumor take and an enhanced tumor outgrowth and invasiveness, respectively, compared with heterotopic (i.e., subcutaneous) inoculation. We conclude that the site-specific growth and invasion of the bladder carcinoma cell lines in vivo and the observed assay specific invasion (in vitro vs in vivo) points to an effect of the local (bladder) microenvironment on tumor cell behavior.     

Suppressive effect of platycodin D on bladder cancer through microRNA-129-5p-mediated PABPC1/PI3K/AKT axis inactivation

Platycodin D (PD) is a major constituent of Platycodon grandiflorum and has multiple functions in disease control. This study focused on the function of PD in bladder cancer cell behaviors and the molecules involved. First, we administered PD to the bladder cancer cell lines T24 and 5637 and the human uroepithelial cell line SV-HUC-1. Cell viability and growth were evaluated using MTT, EdU, and colony formation assays, and cell apoptosis was determined using Hoechst 33342 staining and flow cytometry. The microRNAs (miRNAs) showing differential expression in cells before and after PD treatment were screened. Moreover, we altered the expression of miR-129-5p and PABPC1 to identify their functions in bladder cancer progression. We found that PD specifically inhibited the proliferation and promoted the apoptosis of bladder cancer cells; miR-129-5p was found to be partially responsible for the cancer-inhibiting properties of PD. PABPC1, a direct target of miR-129-5p, was abundantly expressed in T24 and 5637 cell lines and promoted cell proliferation and suppressed cell apoptosis. In addition, PABPC1 promoted the phosphorylation of PI3K and AKT in bladder cancer cells. Altogether, PD had a concentration-dependent suppressive effect on bladder cancer cell growth and was involved in the upregulation of miR-129-5p and the subsequent inhibition of PABPC1 and inactivation of PI3K/AKT signaling.     

Karyotypic characterization of urinary bladder transitional cell carcinomas

Samples from 34 primary transitional cell carcinomas (TCCs) of the bladder were short-term-cultured and processed for cytogenetic analysis after G-banding of the chromosomes. Clonal chromosome abnormalities were detected in 27 tumors and normal karyotypes in 3, and the cultures from 4 tumors failed to grow. Losses of genetic material were more common than gains, indicating that loss of tumor suppressor genes may be of major importance in TCC pathogenesis. There was no clonal heterogeneity within individual tumors, consonant with the view that TCCs are monoclonal in origin. The most striking finding was the involvement of chromosome 9 in 92% of the informative cases, as numerical loss of one chromosome copy in 15 cases, but as structural rearrangement in 8. The changes in chromosome 9 always led to loss of material; from 9p, from 9q, or of the entire chromosome. A total of 16 recurrent, unbalanced structural rearrangements were seen, of which del(1)(p11), add(3)(q21), add(5)(q11), del(6)(q13), add(7)(q11), add(11)(p11), i(13)(q10), del(14)(q24), and i(17)(q10) are described here for the first time. The karyotypic imbalances were dominated by losses of the entire or parts of chromosome arms 1p, 9p, 9q, 11p, 13p, and 17p, loss of an entire copy of chromosomes 9, 14, 16, 18, and the Y chromosome, and gains of chromosome arms 1q and 13q and of chromosomes 7 and 20. The chromosome bands and centomeric breakpoints preferentially involved in structural rearrangements were 1q12, 2q11, 5q11, 8q24, 9p13, 9q13, 9q22, 11p11, and 13p10. Rearrangements of 17p and the formation of an i(5)(p10) were associated with more aggressive tumor phenotypes. There was also a general correlation between the tumors' grade/stage and karyotypic complexity, indicating that progressive accumulation of acquired genetic alterations is the driving force behind multistep bladder TCC carcinogenesis.     

Novel chromosome findings in bladder cancer cell lines detected with multiplex fluorescence in situ hybridization

Bladder cancer is a common neoplasm worldwide, consisting mainly of transitional cell carcinomas, while squamous, adenocarcinoma, and sarcomatoid bladder cancers account for the remaining cases. In the present study, multiplex fluorescence in situ hybridization (M-FISH) has been used to characterize chromosome rearrangements in eight transitional and one squamous cell carcinoma cell line, RT112, of UMUC-3, 5637, CAT(wil), FGEN, EJ28, J82, 253J, and SCaBER. Alterations of chromosome 9 are the most frequent cytogenetic and molecular findings in transitional cell carcinomas of all grades and stages, while changes of chromosomes 3, 4, 8, 9, 11, 14, and 17 are also frequently observed. In the present study, alterations previously described, including del(8)(p10), del(9)(p10), del(17)(p10), and overrepresentation of chromosome 20, as well as several novel findings, were observed. These novel findings were a del(15)(q15) and isochromosome 14q, both occurring in three of nine cell lines examined. These abnormalities may reflect changes in bladder tumor biology. M-FISH represents an effective preliminary screening tool for the characterization of complex tumor karyotypes.     

TRIO amplification and abundant mRNA expression is associated with invasive tumor growth and rapid tumor cell proliferation in urinary bladder cancer

Studies by comparative genome hybridization have suggested that 5p amplification is related to tumor progression in urinary bladder cancer. In this study seven genes (TAS2R, ADCY2, DNAH5, CTNND2, TRIO, ANKH, and MYO10) located to 5p15.31-5p15.1 were analyzed by fluorescence in situ hybridization using a tissue microarray containing samples from tumors and cell lines with known 5p amplification by comparative genome hybridization. Amplification frequency was highest for TRIO, which maps to 5p15.2 and encodes a protein with a putative role in cell-cycle regulation. To further investigate the role of TRIO amplification in bladder cancer, a tissue microarray containing samples from 2317 bladder tumors was used for fluorescence in situ hybridization analysis. TRIO amplification was strongly associated with invasive tumor phenotype, high tumor grade, and rapid tumor cell proliferation (Ki67 LI) (P < 0.0001 each). Only 7 of 456 pTaG1/G2 tumors (1.5%) but 62 of 485 pT1-4 carcinomas (12.8%) had TRIO amplification. TRIO amplification was not associated with poor prognosis. Using a frozen bladder tumor tissue microarray RNA in situ hybridization confirmed that TRIO is up-regulated in amplified tumors. It is concluded that TRIO up-regulation through amplification has a potential role in bladder cancer progression.     

Down-regulating ribonuclease inhibitor enhances metastasis of bladder cancer cells through regulating epithelial–mesenchymal transition and ILK signaling pathway

Accumulating evidences implicate that ribonuclease inhibitor (RI) plays a suppressing role in cancer development. However, the mechanisms underlying antitumor of RI remain largely unknown. Epithelial–mesenchymal transition (EMT) is regarded as a key event in tumor progression. The reports have demonstrated that EMT was implicated in metastasis of bladder cancer. Therefore, we suppose that RI might involve regulating EMT of bladder cancer. Here bladder cancer T24 cells were transfected with pGensil-1-siRNA-RI vectors. HE staining, living cell observation, Phalloidine-FITC staining of microfilament, cell adhesion, scratch migration, and Matrigel invasion were examined respectively. RI expression and colocalization with ILK were detected using confocal microscope. Proteins associated with EMT were determined with Western blotting and immunohistochemistry in vivo and in vitro. Effects of RI expression on tumor growth, metastasis and EMT related proteins in BALB/C nude mouse and clinical human bladder cancer specimens were valued with histological, immunohistochemical and immunofluorescent examination respectively. We demonstrated that down-regulating RI increased cell proliferation, migration and invasion, changed cell morphology and adhesion, and rearranged cytoskeleton by inducing EMT and ILK signaling pathway in bladder cancer cells. In addition, we showed that down-regulating RI promoted tumorigenesis and metastasis of bladder cancer in vivo. Finally, we found that bladder cancer with invasive capability had higher Vimentin, Snail, Slug and Twist as well as lower E-cadherin and RI expression in clinical human specimens. Our results suggest that RI could play a novel role in inhibiting metastasis of bladder through regulating EMT and ILK signaling pathway.