Prostatic Neoplasms: Hemstreet GP

Kawachi MH, Bahnson RR, Barry M, Carroll PR, Carter HB, Catalona WJ, Epstein JI, Etzioni RB, Hemstreet GP, Howe RJ, Kopin JD, Lange PH, Lilja H, Mohler J, Moul J, Nadler RB, Patterson S, Pollack A, Presti JC, Stroup AM, Urban DA, Wake R, Wei JT, Anonymous00333. · No affiliation provided · J Natl Compr Canc Netw. · Pubmed #17692177 No free full text.

This publication has no abstract.

Huang D, Casale GP, Tian J, Wehbi NK, Abrahams NA, Kaleem Z, Smith LM, Johansson SL, Elkahwaji JE, Hemstreet GP. · Department of Surgery, Urologic Surgery Section, 982360 Nebraska Medical Center, Omaha, NE 68198-2360, USA. · Cancer Epidemiol Biomarkers Prev. · Pubmed #17623804 links to  free full text

Abstract: The surprising disparity between the number of protein-encoding genes ( approximately 30,000) in the human genome and the number of proteins ( approximately 300,000) in the human proteome has inspired the development of translational proteomics aimed at protein expression profiling of disease states. Translational proteomics, which offers the promise of early disease detection and individualized therapy, requires new methods for the analysis of clinical specimens. We have developed quantitative fluorescence imaging analysis (QFIA) for accurate, reproducible quantification of proteins in slide-mounted tissues. The method has been validated for the analysis of beta-catenin in archived prostate specimens fixed in formalin. QFIA takes advantage of the linearity of fluorescence antibody signaling for tissue epitope content, a feature validated for beta-catenin in methacarn-fixed prostate specimens analyzed by reverse-phase protein array analysis and QFIA (r = 0.97). QFIA of beta-catenin in formaldehyde-fixed tissues correlated directly with beta-catenin content (r = 0.86). Application of QFIA in a cross-sectional study of biopsies from 42 prostate cancer (PC) cases and 42 matched controls identified beta-catenin as a potential field marker for PC. Receiver operating characteristic plots revealed that beta-catenin expression in the normal-appearing acini of cancerous glands identified 42% (95% confidence intervals, 26-57%) of cancer cases, with 88% (95% confidence intervals, 80-96%) specificity. The marker may contribute to a PC biomarker panel. In conclusion, we report the development and validation of a new method for fluorescence quantification of proteins in archived tissues and its application to archived specimens for an evaluation of beta-catenin expression as a biomarker for PC.

Lewis TE, Milam TD, Klingler DW, Rao PS, Jaggi M, Smith DJ, Hemstreet GP, Balaji KC. · Division of Urological Surgery, University of Nebraska Medical Center, Omaha, NE 68198-2360, USA. · Urol Oncol. · Pubmed #16301118 No free full text.

Abstract: We have previously described that tissue transglutaminase (tTG) is a high level phenotypic biomarker in prostate cancer, which is down regulated in prostate cancer and surrounding premalignant field compared to benign prostate glands. To understand the function of tTG in prostate cancer, we sought to identify proteins that interact with the transglutaminase moiety of tTG using a human prostate cancer complementary deoxyribonucleic acid library in a Yeast 2-Hybrid system. The Yeast 2-Hybrid experiments identified a strong and novel interaction between the transglutaminase moiety and protein kinase A anchor protein 13 (AKAP13), which was quantified by beta-galactosidase assay, confirmed in vitro by immunoprecipitation experiments using PC3 prostate cancer cell lysates, and in vivo colocalization was confirmed by immunofluorescence studies in PC3 cells. Because AKAP plays a major role in protein kinase A and Rho protein mediated signaling, functional studies are underway to elucidate the significance of tTG-AKAP13 interaction in prostate cancer.

Jaggi M, Rao PS, Smith DJ, Wheelock MJ, Johnson KR, Hemstreet GP, Balaji KC. · Urological Surgery, University of Nebraska Medical Center, Omaha, NE 68198, USA. · Cancer Res. · Pubmed #15695390 links to  free full text

Abstract: The cadherin family of transmembrane glycoproteins plays a critical role in cell-to-cell adhesion and cadherin dysregulation is strongly associated with cancer metastasis and progression. In this study, we report a novel interaction between protein kinase D1 [PKD1; formerly known as protein kinase C mu (PKCmu)] and E-cadherin. PKD1 is a serine/threonine-specific kinase known to play a role in multiple cellular processes including apoptosis, cytoskeleton remodeling, and invasion. Our study shows that PKD1 colocalizes with E-cadherin at cell junctions in LNCaP prostate cancer cells and coimmunoprecipitates with E-cadherin from lysates of LNCaP cells. In vitro kinase assays have shown that PKD1 phosphorylates E-cadherin. Inhibition of PKD1 activity by the selective inhibitor Gö6976 in LNCaP cells resulted in decreased cellular aggregation and overexpression of PKD1 in C4-2 prostate cancer cells increased cellular aggregation and decreased cellular motility. We also validated the PKD1 and E-cadherin colocalization in human prostate cancer tissue by confocal laser scanning microscopy. Our study has identified E-cadherin as a novel substrate of PKD1, and phosphorylation of E-cadherin by PKD1 is associated with increased cellular aggregation and decreased cellular motility in prostate cancer. Because both E-cadherin and PKD1 are known to be dysregulated in prostate cancer, our study identified an important protein-protein interaction influencing the signal transduction system associated with cell adhesion in prostate cancer.

Rao PS, Jaggi M, Smith DJ, Hemstreet GP, Balaji KC. · Division of Urological Surgery, Department of Surgery, University of Nebraska Medical Center, Omaha, NE 68198-2360, USA. · Biochem Biophys Res Commun. · Pubmed #14550308 No free full text.

Abstract: Prostate cancer (PC) patients die from progression to androgen independence (AI) and chemoresistance (CR). Protein kinase Cmu (PKCmu) a novel member of the PKC family of signal transduction proteins is downregulated in AI PC. Studying PKCmu interactors in the yeast two-hybrid system identified metallothionein 2A (MT 2A) as an interactor of PKCmu kinase domain (KD) in PC, which was quantified by beta-gal assay, confirmed in PC cells by immunoprecipitation, and PKCmu-MT 2A co-localization in vivo by immunofluorescence studies. PKCmu domain interaction studies revealed that MT 2A interacted strongly with KD, relatively weakly with C1, and failed to interact with C2, PH or kinase mutant domains. Peptide library and in silico analysis strongly suggest that MT 2A is a novel substrate of PKCmu and our data indicate that the PKCmu-MT 2A interaction depends on PKCmu kinase activity. Because metallothioneins are associated with cell proliferation and CR, the PKCmu-MT 2A interaction may contribute to CR and/or AI in PC.

Jaggi M, Rao PS, Smith DJ, Hemstreet GP, Balaji KC. · Division of Urology, Department of Surgery, University of Nebraska Medical Center, 982360 Nebraska Medical Center, Omaha, NE 68198-2360, USA. · Biochem Biophys Res Commun. · Pubmed #12859948 No free full text.

Abstract: Progression to androgen independence (AI) is the main cause of death in prostate cancer. Our prior differential gene expression studies by microarray analysis in progressive prostate cancer cell line model identified dysregulation of protein kinase C mu (PKCmu) expression in prostate cancer. In this study, quantitative ribonuclease protection assay and immunoblot analysis demonstrate down regulation of PKCmu at transcription and translational level, respectively, in AI C4-2 cells compared to its parental androgen dependent (AD) LNCaP prostate cancer cells. Significantly lower PKCmu kinase activity was confirmed in C4-2 cells by in vitro kinase assay. Immunohistochemical studies of prostate cancer tissue from patient progressing to AI prostate cancer demonstrated that PKCmu expression is decreased in 100% of AI human prostate cancers. The consistent down regulation of PKCmu in cell line models and human prostate cancer tissues suggests a possible functionally significant role for PKCmu in progression to AI in prostate cancer.

Wehbi NK, Dugger AL, Bonner RB, Pitha JV, Hurst RE, Hemstreet GP. · Department of Urology, University of Oklahoma Health Sciences Center, Oklahoma City, USA. · J Urol. · Pubmed #11956481 No free full text.

Abstract: PURPOSE: High level phenotypic biomarkers such as cadherins are needed to identify individuals at risk for biologically active prostate cancer and determine which individuals with elevated prostate specific antigen or a prostate nodule are candidates for re-biopsy. Cadherins are a high level phenotypic biomarker associated with decreased cell adhesion, which is a cardinal event in carcinogenesis. Recently we reported that G-actin and tissue transglutaminase type II are potential biomarkers for prostate cancer. In this study we present cadherins as a potential third component of the biomarker profile. MATERIALS AND METHODS: Prostate tissues from 38 patients with cancer and 33 controls with a 10-year prostate cancer-free followup were labeled for pan-cadherin by immunohistochemical testing. Immunoreactivity was quantified using a Pathology Workstation (Autocyte Inc., Elon College, North Carolina). RESULTS: Visually benign glands from controls generally expressed cadherins, whereas regions of adenocarcinoma were generally negative. On quantitative immunohistochemistry 36 of 38 prostate cancer cases expressed a lower mean percent area positive for cadherin than the 19 benign prostatic hyperplasia and 14 prostatitis cases (odds ratio 978, 95% confidence interval 45 to 21,140, relative risk 18, 95% confidence interval 5 to 67, p <0.0001). Receiver operating characteristics analysis of immunohistochemical testing data showed that an optimal threshold of 7 produced 95% sensitivity and 100% specificity. CONCLUSIONS: Quantitative down-regulation of cadherin expression in prostate cancer tissue sections is a strong biomarker for prostate cancer. Analysis of cadherin and other high level phenotypic biomarker expression in the premalignant field may provide additional diagnostic information to decide which patients need re-biopsy, more intensive monitoring or chemoprevention.

Hemstreet GP, Bonner RB, Hurst RE, Bell D, Bane BL. · Department of Urology, University of Oklahoma Health Sciences Center, Oklahoma City 73190, USA. · Cancer Detect Prev. · Pubmed #11129989 No free full text.

Abstract: The distribution of altered G-actin was investigated in prostatic cells obtained by fine needle aspiration (FNA) from 27 excised prostate glands obtained during radical prostatectomy. FNA, which was used to obtain single cells for image analysis, sampled in the region of any nodules and in grossly normal areas of the contralateral lobes. Quantitative fluorescence-image analysis was used to assay the amount of G-actin in individual cells. Abnormal G-actin, a precursor cytoskeletal protein representing cytoskeletal rearrangements accompanying cellular transformation, was associated with the presence of adenocarcinoma in 22 of 27 specimens from the dominant nodule, but only 3 of 20 in the grossly normal specimens (P<.0001). The mean G-actin content of all samples from the dominant nodule was 113.2+/-6.87 and 69.57+/-4.47 from the grossly normal area, the difference being significant at P<.0001. Altered G-actin was not associated with Gleason score (P = .95), grade (P = .26), stage (P = .058), or tumor volume (P = .32), thereby indicating it is a general marker for prostate adenocarcinoma.

Birckbichler PJ, Bonner RB, Hurst RE, Bane BL, Pitha JV, Hemstreet GP. · Department of Urology, University of Oklahoma Health Sciences Center, Oklahoma City, Oklahoma 73190, USA. · Cancer. · Pubmed #10918174 links to  free full text

Abstract: BACKGROUND: Additional molecular tissue biomarkers for prostate carcinoma are needed to stratify patients with clinically suspicious findings, such as an elevated prostate specific antigen (PSA) with a negative biopsy, according to risk. METHODS: Prostate tissues from 43 cancer cases and 47 controls with no evidence of cancer were labeled for transglutaminase by immunohistochemistry. Immunoreactivity was quantified using the Autocyte Pathology Workstation. In addition, quantitative fluorescence image analysis was used to compare transglutaminase concentrations in cells obtained by fine-needle aspiration from excised prostates. Loss of gene expression was evaluated by reverse transcriptase-polymerase chain reaction and growth with 5-azacytidine. RESULTS: Visually, benign glands from controls generally expressed tissue transglutaminase, whereas regions with adenocarcinoma generally were negative. With quantitative immunohistochemistry, 41 of 43 adenocarcinoma of the prostate (CaP) cases expressed lower mean percentage areas positive for transglutaminase than did 30 of 30 benign prostatic hyperplasia (BPH) and 17 of 17 prostatitis cases (P < 0.0001; odds ratio [OR], 1577; 95% confidence interval (CI), 74-33, 820; relative risk [RR], 25; 95% CI, 6-95). Quantitative immunofluorescence of 3277 cells collected by FNA from 19 CaP cases and 645 cells from 5 cases of BPH showed that the mean content of transglutaminase was 93 femtograms (fg) for the CaP-derived cells and 138 fg for the BPH cells (P < 0.0001). Receiver operating curve analysis of the immunohistochemistry data showed an optimized threshold produced 95% sensitivity with 100% specificity. Growth of LNCaP cells with 5-azacytidine failed to stimulate transglutaminase expression, suggesting that loss of expression was likely not attributable to promoter methylation. CONCLUSIONS: Measurements of transglutaminase on tissue sections provides additional diagnostic information that is potentially useful for risk assessment of patients with suspicious clinical findings, such as nodules or positive PSA and negative biopsies, without overdetecting disease.