Expression of a human cell adhesion molecule, MUC18, in prostate cancer cell lines and tissues

BACKGROUND: Over expression of huMUC18, a cell adhesion molecule in the immunoglobulin gene superfamily, causes a non-metastatic human melanoma cell line to become metastatic in a nude mouse system. To determine if MUC18 expression correlates with the malignant progression of prostate cancer, we investigated differential expression of human MUC18 (huMUC18) in normal prostate epithelial cells, prostate cancer cell lines, and prostatic normal and cancer tissues. METHODS: RT-PCR and Western blot analyses were used to analyze the expression of MUC18 mRNA and protein in four human prostate cancer cell lines, cultured primary normal prostate epithelial cells, normal prostate and malignant prostate tissues. Immunohistochemistry was used to determine the expression of MUC18 antigen in prostatic tissues at different stages of malignancy. RESULTS: Human MUC18 mRNA and protein was expressed in three different prostate cancer cell lines (TSU-PR1, DU145, and PC-3), but not in one prostate cancer cell line (LNCaP.FGC). HuMUC18 protein was also expressed at high levels in extracts prepared from tissue sample sections containing high grade prostatic intraepithelial neoplasia (PIN), but weakly expressed in extracts prepared from either cultured primary normal prostatic epithelial cells or the normal prostate gland. Immunohistochemical analysis showed that huMUC18 was expressed at higher levels in the epithelial cells of high-grade PIN and prostatic carcinomas and in cells of a lymph node metastasis compared to that in normal or benign hyperplastic epithelium (BPH). CONCLUSIONS: We therefore conclude that MUC18 is expressed at higher levels in pre-malignant and malignant prostatic epithelium, including metastasis. We suggest that over-expression of MUC18 may be a new marker of human prostate cancer and also implicates its possible role in development and progression of prostate cancer.     

Immunohistochemistry and biochemistry in detection of androgen, progesterone, and estrogen receptors in benign and malignant human prostatic tissue.

The relative distribution of androgen (AR), progesterone (PR), and estrogen receptors (ER) was localized and estimated in human prostate tissue by immunohistochemistry in five normal tissue samples, in eight benign hyperplastic (BPH) samples, in nine primary cancers, and in seven prostate cancer metastases. Moreover, three prostatic cancer cell lines (LNCaP, DU 145, and PC 3) were analyzed. A comparison between the results obtained by radioligand binding assays and immunohistochemistry was performed for the AR and PR. Using immunohistochemistry, the AR was exclusively detected in the nuclei of both benign and malignant prostatic epithelial cells. The highest proportion of AR-positive cells was found in BPH and in prostate cancer metastases as compared with normal prostatic tissue. In a majority of the cases, the PR was only present in the nuclei of stromal cells. Benign hyperplastic prostates contained higher proportions of PR-positive cells as compared with primary carcinoma. PR was sparse in epithelial cells. ER-positive stromal cell nuclei were only detected in carcinomatous prostates. A few ER-positive epithelial cell nuclei were found in one sample each of a BPH and normal prostate. All cells from the androgen-dependent, LNCaP, cell line and a majority of the cells from the androgen-independent, DU 145, cell line were AR-positive. In contrast, the cells from the androgen-independent, PC 3, cell line were all AR-negative. All three cell lines were PR- and ER-negative. The radioligand binding technique detected the AR in extracts from both the cytosol and the nucleus. Again BPH contained higher amounts of AR as compared with normal prostatic tissue. The LNCaP cells contained high amounts of cytosolic AR while cells from the DU 145 and PC 3 cell lines lacked detectable AR as estimated by biochemical techniques. There seemed to be a discrepancy between biochemically measured and immunohistochemically estimated receptor content.     

GREB1 is a novel androgen-regulated gene required for prostate cancer growth

BACKGROUND: Gene regulated in breast cancer 1 (GREB1) is a novel estrogen-regulated gene shown to play a pivotal role in hormone-stimulated breast cancer growth. GREB1 is expressed in the prostate and its putative promoter contains potential androgen receptor (AR) response elements. METHODS: We investigated the effects of androgens on GREB1 expression and its role in androgen-dependent prostate cancer growth. RESULTS: Real-time PCR demonstrated high level GREB1 expression in benign prostatic hypertrophy (BPH), localized prostate cancer (L-PCa), and hormone refractory prostate cancer (HR-PCa). Androgen treatment of AR-positive prostate cancer cells induced dose-dependent GREB1 expression, which was blocked by anti-androgens. AR binding to the GREB1 promoter was confirmed by chromatin immunoprecipitation (ChIP) assays. Suppression of GREB1 by RNA interference blocked androgen-stimulated LNCaP cell proliferation. CONCLUSIONS: GREB1 is expressed in proliferating prostatic tissue and prostate cancer, is regulated by androgens, and suppression of GREB1 blocks androgen-induced growth suggesting GREB1 may be critically involved in prostate cancer proliferation.     

Aberrant expression of transmembrane mucins, MUC1 and MUC4, in human prostate carcinomas

BACKGROUND: Mucins are considered important markers for early diagnosis and targeted therapy due to their aberrant and unique expression pattern during malignant progression of carcinomas. Recent findings have provided substantial evidence for the involvement of transmembrane mucins, MUC1 and MUC4, in altered cell signaling, tumor growth, and metastasis. METHODS: Immunohistochemical analyses were performed on prostate tumor tissues for expression profiling of the two transmembrane mucins, MUC1 and MUC4. In cancer cell lines, the expression was studied by RT-PCR and immunoblot analyses. Cells were treated with DNA-methylase and histone-deacetylase inhibitors to examine the implication of epigenetic mechanism(s) in MUC4 regulation. RESULTS: The expression of MUC4 was significantly down regulated in prostate cancer tissues (n=38, P=0.0026) compared to normal/benign prostatic hyperplastic regions. A faint to moderate staining was observed in 26.3% cases of cancer, while 84.2% cases of adjacent normal were positive for MUC4 with moderate to strong staining in most cases. Similar observations were made in immortalized normal prostate epithelial and cancer cell lines. MUC1 also showed a reduced expression in prostate tumor tissues; however, its expression was comparable in all normal prostate epithelial and cancer cell lines. Interestingly, we also found that epigenetic mechanism(s) might be implicated in MUC4 gene silencing. CONCLUSIONS: Our data suggest that MUC4 downregulation may be of significance for diagnostic applications in prostate cancer.     

凋亡抑制基因XIAP在前列腺癌细胞中的表达及与临床病理特征的关系

目的 :研究XIAP基因在前列腺癌细胞系和前列腺癌组织的表达情况 ,及其与前列腺癌临床病理特征的关系。　方法 :应用RT PCR检测前列腺癌组织、正常前列腺组织和前列腺癌细胞株PC 3,DU 14 5 ,LNCaP细胞XIAP基因的表达 ,并通过免疫组化SP法检测 5 6例前列腺癌组织标本XIAP蛋白的表达情况。　结果 :XIAP基因在前列腺癌组织和前列腺癌细胞株PC 3,DU 14 5 ,LNCaP细胞高表达 ,正常前列腺组织无表达。在前列腺癌组织和癌旁组织中 ,XIAP蛋白阳性检出率分别为 5 3.6 % (30 / 5 6 )和 2 1.5 % (12 / 5 6 ) (P <0 .0 1) ;不同分期、分级组XIAP阳性检出率相比差异无显著性 (P >0 .0 5 )。　结论 :凋亡抑制基因XIAP与前列腺癌相关 ,在前列腺癌发生过程中具有重要的作用 ,有可能成为前列腺癌治疗的靶标。     

Alternative splicing isoforms of hippostasin (PRSS20/KLK11) in prostate cancer cell lines

BACKGROUND: Hippostasin is a kallikrein-like protease (PRSS20/KLK11), which is expressed preferentially in the hippocampus and prostate. We have reported that alternative splicing variants of human hippostasin are regulated in a tissue-specific manner. Brain-type hippostasin consists of 250 amino acids including a typical signal sequence, and is expressed in the brain and prostate. The prostate-type hippostasin, which has 32 extra amino acids at the N-terminal end, is expressed only in the prostate. METHODS: We analyzed the expression and localization of hippostasin in normal prostate tissue, BPH tissue, and prostate cancer cell lines. We performed northern blotting, in situ hybridization, immunohistochemistry, and RT-PCR. RESULTS: Hippostasin mRNA is expressed preferentially in the normal prostate and weakly in the testis. It was detected in prostate secretory epithelium. Hippostasin protein was localized in the prostate secretory epithelium, and western blotting showed that hippostasin was present in semen. All tested prostate cancer cell lines, including PSA-negative cell lines, expressed hippostasin. Interestingly, all the prostate cancer cell lines expressed only brain-type but not prostate-type hippostasin, while normal prostate and BPH expressed both types of hippostasin CONCLUSIONS: Our results suggest the possibility that hippostasin may be a useful marker by which prostate cancer and BPH can be distinguished.     

Loss of CD10 (neutral endopeptidase) is a frequent and early event in human prostate cancer

BACKGROUND: We hypothesized that the aggressive LNCaP-derived androgen-independent cell line, CL1, might differ from LNCaP in their repertoire of cell surface markers and that these differences might typify changes that occur during clinical prostate cancer progression. METHODS: The cell surface marker expression profiles of CL1 and LNCaP were examined using flow cytometry. Markedly differential gene expression was confirmed using RT-PCR and further examined using immunohistochemistry among the prostate cancer cell lines LAPC-4, LNCaP, CL1, CL2, DU145, and PC-3. The expression of the most markedly differentially expressed surface marker, CD10, was further explored in a tissue microarray containing radical prostatectomy samples from 219 hormone na?ve prostate cancer patients. RESULTS: There were marked differences in the expression of CD10, CD13, CD26, CD33, CD44, CD54, CD55, and CD104 between CL1 and LNCaP. Results from both the RT-PCR and immunohistochemistry confirmed the differential expression and found that CD10 demonstrated a pattern of expression in hormone sensitive but not hormone refractory cell lines. When CD10 expression was examined in a tissue microarray, CD10 expression was below the 25th percentile of matched normal prostate tissue in 68% of prostate cancers, below the median expression of matched normal prostate tissue in 86% of cancers, and completely absent in 34% of cancers. Samples of prostatic intraepithelial neoplasia demonstrated CD10 expression that was intermediate between normal prostatic tissue and prostate cancer. Among prostate cancer patients, CD10 expression did not correlate with Gleason score, pathological stage, or biochemical recurrence following radical prostatectomy. CONCLUSIONS: These findings demonstrate that loss or decreased expression of CD10 is an early and frequent event in human prostate cancer and implicates CD10 as a potential therapeutic target for early stage hormone sensitive prostate cancer.     

Differential localization of MT1-MMP in human prostate cancer tissue: role of IGF-1R in MT1-MMP expression

BACKGROUND: MT1-MMP is a metalloproteinase involved in prostate cancer metastasis. The IGF-1R is a tyrosine kinase receptor involved with tumor progression and metastasis. The purpose of this investigation was to examine MT1-MMP and IGF-1R expression and localization in prostate cancer tissues and explore the role of IGF-1R in regulating MT1-MMP in prostate cancer cell lines. METHODS: Immunohistochemistry was utilized to study MT1-MMP and IGF-1R expression in human prostate tissues. IGF-1R regulation of MT1-MMP expression was determined by gene promoter analysis, quantitative RT-PCR and Western blot analysis following pharmacological inhibition of the receptor in PC-3N cells and treatment of LNCaP cells with androgen and IGF-1. RESULTS: MT1-MMP expression was high in the apical regions of the luminal cells in PIN and prostate cancer and less intense in the basalateral regions of benign tissues. IGF-1R was expressed primarily in the basal cells of normal glands and highly expressed in prostate cancer. Inhibition of IGF-1R in PC-3N cells decreased MT1-MMP expression and treatment of LNCaP cells with a synthetic androgen and IGF-1 increased MT1-MMP expression. CONCLUSIONS: These data demonstrate that MT1-MMP is highly expressed in the apical cytoplasmic regions of the luminal cells in PIN and prostate cancer when compared to basalateral cytoplasmic membrane staining in benign glands. Additionally, we demonstrate that IGF-1R is highly expressed in human prostate carcinoma. These findings suggest that MT1-MMP localization and IGF-1R expression in prostate carcinoma could be predictive biomarkers for aggressive disease and support IGF-1R as a promising therapeutic target to decrease processes of prostate cancer metastasis.     

Molecular analysis of WFDC1/ps20 gene in prostate cancer

BACKGROUND: WFDC1/ps20 protein has been previously established as a growth suppressor of the prostate cancer cell line PC3. It maps to chromosome 16q23.1, a region of frequent loss of heterozygosity, familial association, and genomic loss in prostate cancer. We, therefore, chose to examine WFDC1/ps20 for mutations and expression changes in prostate cancer. METHODS: DNA from 21 prostate cancer patients and 5 prostate cancer cell lines was screened for mutations in the WFDC1/ps20 gene by sequencing PCR products of each exon. An SphI polymorphism in the 5' UTR was screened in 23 tumors, 22 normal adjacent prostate tissue samples, and 35 control DNAs. Expression of WFDC1/ps20 in different tissue types was examined by Northern blot and by PCR across a multi-tissue cDNA panel. Expression patterns of WFDC1/ps20 in primary tumors were examined by full-length RT-PCR and products were cloned and sequenced to identify novel splice forms. Quantitative RT-PCR analysis of WFDC1/ps20 was performed in a separate cohort of matched tumor/benign tissues. RESULTS: No tumor-associated mutations were identified in the coding region of WFDC1/ps20. A novel polymorphism was found in exon 6 in DNA from cell lines, tumors, and normal adjacent benign tissue. A novel splice form completely deleted for exon 3 was found in tumor and normal prostate RNA. Quantitative RT-PCR demonstrated significant down regulation of WFDC1/ps20 in prostate tumors. Subdivision of normal tissue into stromal and epithelial compartments showed that WFDC1/ps20 expression correlates exponentially with the amount of stroma present. CONCLUSIONS: WFDC1/ps20 is down regulated but not frequently mutated in prostate cancer. It is expressed predominantly in the normal stroma of the prostate. We, therefore, propose that WFDC1/ps20 may not be a classical tumor suppressor gene, but might play a role in the maintenance of the normal extra cellular matrix milieu in the prostate.     

Identification of a novel prostate cancer-associated tumor antigen

BACKGROUND: The identification of antigens that distinguish cancer cells from normal cells is of major importance for the definition of therapeutic targets in human malignancies. Using sera from cancer patients, we have previously reported on the identification of immunologically recognized proteins that belong to the family of cancer testis antigens (CTAs). METHODS: A normal testicular cDNA library was screened with pooled allogeneic sera from patients with prostate cancer using a modified SEREX approach. Subsequently we have identified and characterized a novel antigen, T21, with an expression pattern similar to that of CTAs. mRNA expression of T21 was determined using a panel of whole tissues and prostate cell lines using Q-RT-PCR. For laser microdissection, fresh prostate cancer and benign tissue was obtained using our novel validated harvesting technique. Protein expression and cellular localization of T21 were assessed in prostate cell lines using Western blotting, confocal microscopy and flow cytometry. RESULTS: T21 showed tissue-restricted mRNA expression in gastric, kidney and prostate cancers, and in normal testis and prostate tissues. Following laser microdissection, T21 was significantly over-expressed in malignant compared to benign prostatic epithelium. We have demonstrated expression of T21 at the protein level and confocal microscopy on PC3 cells probed with a T21-monospecific antibody revealed cytoplasmic localization of T21 protein. CONCLUSIONS: The highly restricted expression pattern of T21 makes it an attractive vaccine target for prostate cancer. Several CTAs reportedly induce cytotoxic T-lymphocyte responses, therefore it is reasonable to assume that T21 will be a valuable target for cancer immunotherapy.