Your search keyword '"Strand, Siri H."' showing total 23 results

1. Analysis of ductal carcinoma in situ by self-reported race reveals molecular differences related to outcome

Author

Strand, Siri H., Houlahan, Kathleen E., Branch, Vernal, Lynch, Thomas, Rivero-Guitiérrez, Belén, Harmon, Bryan, Couch, Fergus, Gallagher, Kristalyn, Kilgore, Mark, Wei, Shi, DeMichele, Angela, King, Tari, McAuliffe, Priscilla, Curtis, Christina, Owzar, Kouros, Marks, Jeffrey R., Colditz, Graham A., Hwang, E. Shelley, and West, Robert B.

Published

2024

2. Chromatin insulation orchestrates matrix metalloproteinase gene cluster expression reprogramming in aggressive breast cancer tumors

Author

Llinàs-Arias, Pere, Ensenyat-Mendez, Miquel, Íñiguez-Muñoz, Sandra, Orozco, Javier I. J., Valdez, Betsy, Salomon, Matthew P., Matsuba, Chikako, Solivellas-Pieras, Maria, Bedoya-López, Andrés F., Sesé, Borja, Mezger, Anja, Ormestad, Mattias, Unzueta, Fernando, Strand, Siri H., Boiko, Alexander D., Hwang, E Shelley, Cortés, Javier, DiNome, Maggie L., Esteller, Manel, Lupien, Mathieu, and Marzese, Diego M.

Published

2023

3. Molecular classification and biomarkers of clinical outcome in breast ductal carcinoma in situ: Analysis of TBCRC 038 and RAHBT cohorts

Author

Strand, Siri H., Rivero-Gutiérrez, Belén, Houlahan, Kathleen E., Seoane, Jose A., King, Lorraine M., Risom, Tyler, Simpson, Lunden A., Vennam, Sujay, Khan, Aziz, Cisneros, Luis, Hardman, Timothy, Harmon, Bryan, Couch, Fergus, Gallagher, Kristalyn, Kilgore, Mark, Wei, Shi, DeMichele, Angela, King, Tari, McAuliffe, Priscilla F., Nangia, Julie, Lee, Joanna, Tseng, Jennifer, Storniolo, Anna Maria, Thompson, Alastair M., Gupta, Gaorav P., Burns, Robyn, Veis, Deborah J., DeSchryver, Katherine, Zhu, Chunfang, Matusiak, Magdalena, Wang, Jason, Zhu, Shirley X., Tappenden, Jen, Ding, Daisy Yi, Zhang, Dadong, Luo, Jingqin, Jiang, Shu, Varma, Sushama, Anderson, Lauren, Straub, Cody, Srivastava, Sucheta, Curtis, Christina, Tibshirani, Rob, Angelo, Robert Michael, Hall, Allison, Owzar, Kouros, Polyak, Kornelia, Maley, Carlo, Marks, Jeffrey R., Colditz, Graham A., Hwang, E. Shelley, and West, Robert B.

Published

2022

4. Transition to invasive breast cancer is associated with progressive changes in the structure and composition of tumor stroma

Author

Risom, Tyler, Glass, David R., Averbukh, Inna, Liu, Candace C., Baranski, Alex, Kagel, Adam, McCaffrey, Erin F., Greenwald, Noah F., Rivero-Gutiérrez, Belén, Strand, Siri H., Varma, Sushama, Kong, Alex, Keren, Leeat, Srivastava, Sucheta, Zhu, Chunfang, Khair, Zumana, Veis, Deborah J., Deschryver, Katherine, Vennam, Sujay, Maley, Carlo, Hwang, E. Shelley, Marks, Jeffrey R., Bendall, Sean C., Colditz, Graham A., West, Robert B., and Angelo, Michael

Published

2022

5. The Human Tumor Atlas Network: Charting Tumor Transitions across Space and Time at Single-Cell Resolution

Author

Aberle, Denise, Achilefu, Samuel I., Ademuyiwa, Foluso O., Adey, Andrew C., Aft, Rebecca L., Agarwal, Rachana, Aguilar, Ruben A., Alikarami, Fatemeh, Allaj, Viola, Amos, Christopher, Anders, Robert A., Angelo, Michael R., Anton, Kristen, Ashenberg, Orr, Aster, Jon C., Babur, Ozgun, Bahmani, Amir, Balsubramani, Akshay, Barrett, David, Beane, Jennifer, Bender, Diane E., Bernt, Kathrin, Berry, Lynne, Betts, Courtney B., Bletz, Julie, Blise, Katie, Boire, Adrienne, Boland, Genevieve, Borowsky, Alexander, Bosse, Kristopher, Bott, Matthew, Boyden, Ed, Brooks, James, Bueno, Raphael, Burlingame, Erik A., Cai, Qiuyin, Campbell, Joshua, Caravan, Wagma, Cerami, Ethan, Chaib, Hassan, Chan, Joseph M., Chang, Young Hwan, Chatterjee, Deyali, Chaudhary, Ojasvi, Chen, Alyce A., Chen, Bob, Chen, Changya, Chen, Chia-hui, Chen, Feng, Chen, Yu-An, Chheda, Milan G., Chin, Koei, Chiu, Roxanne, Chu, Shih-Kai, Chuaqui, Rodrigo, Chun, Jaeyoung, Cisneros, Luis, Coffey, Robert J., Colditz, Graham A., Cole, Kristina, Collins, Natalie, Contrepois, Kevin, Coussens, Lisa M., Creason, Allison L., Crichton, Daniel, Curtis, Christina, Davidsen, Tanja, Davies, Sherri R., de Bruijn, Ino, Dellostritto, Laura, De Marzo, Angelo, Demir, Emek, DeNardo, David G., Diep, Dinh, Ding, Li, Diskin, Sharon, Doan, Xengie, Drewes, Julia, Dubinett, Stephen, Dyer, Michael, Egger, Jacklynn, Eng, Jennifer, Engelhardt, Barbara, Erwin, Graham, Esplin, Edward D., Esserman, Laura, Felmeister, Alex, Feiler, Heidi S., Fields, Ryan C., Fisher, Stephen, Flaherty, Keith, Flournoy, Jennifer, Ford, James M., Fortunato, Angelo, Frangieh, Allison, Frye, Jennifer L., Fulton, Robert S., Galipeau, Danielle, Gan, Siting, Gao, Jianjiong, Gao, Long, Gao, Peng, Gao, Vianne R., Geiger, Tim, George, Ajit, Getz, Gad, Ghosh, Sharmistha, Giannakis, Marios, Gibbs, David L., Gillanders, William E., Goecks, Jeremy, Goedegebuure, Simon P., Gould, Alanna, Gowers, Kate, Gray, Joe W., Greenleaf, William, Gresham, Jeremy, Guerriero, Jennifer L., Guha, Tuhin K., Guimaraes, Alexander R., Guinney, Justin, Gutman, David, Hacohen, Nir, Hanlon, Sean, Hansen, Casey R., Harismendy, Olivier, Harris, Kathleen A., Hata, Aaron, Hayashi, Akimasa, Heiser, Cody, Helvie, Karla, Herndon, John M., Hirst, Gilliam, Hodi, Frank, Hollmann, Travis, Horning, Aaron, Hsieh, James J., Hughes, Shannon, Huh, Won Jae, Hunger, Stephen, Hwang, Shelley E., Iacobuzio-Donahue, Christine A., Ijaz, Heba, Izar, Benjamin, Jacobson, Connor A., Janes, Samuel, Jané-Valbuena, Judit, Jayasinghe, Reyka G., Jiang, Lihua, Johnson, Brett E., Johnson, Bruce, Ju, Tao, Kadara, Humam, Kaestner, Klaus, Kagan, Jacob, Kalinke, Lukas, Keith, Robert, Khan, Aziz, Kibbe, Warren, Kim, Albert H., Kim, Erika, Kim, Junhyong, Kolodzie, Annette, Kopytra, Mateusz, Kotler, Eran, Krueger, Robert, Krysan, Kostyantyn, Kundaje, Anshul, Ladabaum, Uri, Lake, Blue B., Lam, Huy, Laquindanum, Rozelle, Lau, Ken S., Laughney, Ashley M., Lee, Hayan, Lenburg, Marc, Leonard, Carina, Leshchiner, Ignaty, Levy, Rochelle, Li, Jerry, Lian, Christine G., Lim, Kian-Huat, Lin, Jia-Ren, Lin, Yiyun, Liu, Qi, Liu, Ruiyang, Lively, Tracy, Longabaugh, William J.R., Longacre, Teri, Ma, Cynthia X., Macedonia, Mary Catherine, Madison, Tyler, Maher, Christopher A., Maitra, Anirban, Makinen, Netta, Makowski, Danika, Maley, Carlo, Maliga, Zoltan, Mallo, Diego, Maris, John, Markham, Nick, Marks, Jeffrey, Martinez, Daniel, Mashl, Robert J., Masilionais, Ignas, Mason, Jennifer, Massagué, Joan, Massion, Pierre, Mattar, Marissa, Mazurchuk, Richard, Mazutis, Linas, Mazzilli, Sarah A., McKinley, Eliot T., McMichael, Joshua F., Merrick, Daniel, Meyerson, Matthew, Miessner, Julia R., Mills, Gordon B., Mills, Meredith, Mondal, Suman B., Mori, Motomi, Mori, Yuriko, Moses, Elizabeth, Mosse, Yael, Muhlich, Jeremy L., Murphy, George F., Navin, Nicholas E., Nawy, Tal, Nederlof, Michel, Ness, Reid, Nevins, Stephanie, Nikolov, Milen, Nirmal, Ajit Johnson, Nolan, Garry, Novikov, Edward, Oberdoerffer, Philipp, O’Connell, Brendan, Offin, Michael, Oh, Stephen T., Olson, Anastasiya, Ooms, Alex, Ossandon, Miguel, Owzar, Kouros, Parmar, Swapnil, Patel, Tasleema, Patti, Gary J., Pe’er, Dana, Pe'er, Itsik, Peng, Tao, Persson, Daniel, Petty, Marvin, Pfister, Hanspeter, Polyak, Kornelia, Pourfarhangi, Kamyar, Puram, Sidharth V., Qiu, Qi, Quintanal-Villalonga, Álvaro, Raj, Arjun, Ramirez-Solano, Marisol, Rashid, Rumana, Reeb, Ashley N., Regev, Aviv, Reid, Mary, Resnick, Adam, Reynolds, Sheila M., Riesterer, Jessica L., Rodig, Scott, Roland, Joseph T., Rosenfield, Sonia, Rotem, Asaf, Roy, Sudipta, Rozenblatt-Rosen, Orit, Rudin, Charles M., Ryser, Marc D., Santagata, Sandro, Santi-Vicini, Maria, Sato, Kazuhito, Schapiro, Denis, Schrag, Deborah, Schultz, Nikolaus, Sears, Cynthia L., Sears, Rosalie C., Sen, Subrata, Sen, Triparna, Shalek, Alex, Sheng, Jeff, Sheng, Quanhu, Shoghi, Kooresh I., Shrubsole, Martha J., Shyr, Yu, Sibley, Alexander B., Siex, Kiara, Simmons, Alan J., Singer, Dinah S., Sivagnanam, Shamilene, Slyper, Michal, Snyder, Michael P., Sokolov, Artem, Song, Sheng-Kwei, Sorger, Peter K., Southard-Smith, Austin, Spira, Avrum, Srivastava, Sudhir, Stein, Janet, Storm, Phillip, Stover, Elizabeth, Strand, Siri H., Su, Timothy, Sudar, Damir, Sullivan, Ryan, Surrey, Lea, Suvà, Mario, Tan, Kai, Terekhanova, Nadezhda V., Ternes, Luke, Thammavong, Lisa, Thibault, Guillaume, Thomas, George V., Thorsson, Vésteinn, Todres, Ellen, Tran, Linh, Tyler, Madison, Uzun, Yasin, Vachani, Anil, Van Allen, Eliezer, Vandekar, Simon, Veis, Deborah J., Vigneau, Sébastien, Vossough, Arastoo, Waanders, Angela, Wagle, Nikhil, Wang, Liang-Bo, Wendl, Michael C., West, Robert, Williams, Elizabeth H., Wu, Chi-yun, Wu, Hao, Wu, Hung-Yi, Wyczalkowski, Matthew A., Xie, Yubin, Yang, Xiaolu, Yapp, Clarence, Yu, Wenbao, Yuan, Yinyin, Zhang, Dadong, Zhang, Kun, Zhang, Mianlei, Zhang, Nancy, Zhang, Yantian, Zhao, Yanyan, Zhou, Daniel Cui, Zhou, Zilu, Zhu, Houxiang, Zhu, Qin, Zhu, Xiangzhu, Zhu, Yuankun, Zhuang, Xiaowei, Hupalowska, Anna, Rood, Jennifer E., Hanlon, Sean E., Hughes, Shannon K., Hwang, E. Shelley, Johnson, Bruce E., Shalek, Alex K., Spira, Avrum E., and West, Robert B.

Published

2020

6. FRMD6 has tumor suppressor functions in prostate cancer

Author

Haldrup, Jakob, Strand, Siri H., Cieza-Borrella, Clara, Jakobsson, Magnus E., Riedel, Maria, Norgaard, Maibritt, Hedensted, Stine, Dagnaes-Hansen, Frederik, Ulhoi, Benedicte Parm, Eeles, Rosalind, Borre, Michael, Olsen, Jesper V., Thomsen, Martin, Kote-Jarai, Zsofia, and Sorensen, Karina D.

Published

2021

7. Elevated miR-615-3p Expression Predicts Adverse Clinical Outcome and Promotes Proliferation and Migration of Prostate Cancer Cells

Author

Laursen, Emma B., Fredsøe, Jacob, Schmidt, Linnéa, Strand, Siri H., Kristensen, Helle, Rasmussen, Anne K.I., Daugaard, Tina F., Mouritzen, Peter, Høyer, Søren, Kristensen, Gitte, Stroomberg, Hein V., Brasso, Klaus, Røder, Martin Andreas, Borre, Michael, and Sørensen, Karina D.

Published

2019

8. Validation of the four-miRNA biomarker panel MiCaP for prediction of long-term prostate cancer outcome

Author

Strand, Siri H., Schmidt, Linnéa, Weiss, Simone, Borre, Michael, Kristensen, Helle, Rasmussen, Anne Karin Ildor, Daugaard, Tina Fuglsang, Kristensen, Gitte, Stroomberg, Hein Vincent, Røder, Martin Andreas, Brasso, Klaus, Mouritzen, Peter, and Sørensen, Karina Dalsgaard

Published

2020

9. Exploring the transcriptome of hormone-naive multifocal prostate cancer and matched lymph node metastases

Author

Schmidt, Linnéa, Møller, Mia, Haldrup, Christa, Strand, Siri H., Vang, Søren, Hedegaard, Jakob, Høyer, Søren, Borre, Michael, Ørntoft, Torben, and Sørensen, Karina Dalsgaard

Published

2018

10. Dysregulation and prognostic potential of 5-methylcytosine (5mC), 5-hydroxymethylcytosine (5hmC), 5-formylcytosine (5fC), and 5-carboxylcytosine (5caC) levels in prostate cancer

Author

Storebjerg, Tine Maj, Strand, Siri H., Høyer, Søren, Lynnerup, Anne-Sofie, Borre, Michael, Ørntoft, Torben F., and Sørensen, Karina D.

Published

2018

11. Molecular classification and biomarkers of clinical outcome in breast ductal carcinoma in situ: Analysis of TBCRC 038 and RAHBT cohorts

Author

Strand, Siri H., Rivero-Gutiérrez, Belén, Houlahan, Kathleen E., Seoane, Jose A., King, Lorraine M., Risom, Tyler, Simpson, Lunden A., Vennam, Sujay, Khan, Aziz, Cisneros, Luis, Hardman, Timothy, Harmon, Bryan, Couch, Fergus, Gallagher, Kristalyn, Kilgore, Mark, We, Shi, DeMichele, Angela, King, Tari, McAuliffe, Priscilla F., Nangia, Julie, Lee, Joanna, Tseng, Jennifer, Storniolo, Anna Maria, Thompson, Alastair M., Gupta, Gaorav P., Burns, Robyn, Veis, Deborah J., DeSchryver, Katherine, Zhu, Chunfang, Matusiak, Magdalena, Wang, Jason, Zhu, Shirley X., Tappenden, Jen, Ding, Daisy Yi, Zhang, Dadong, Luo, Jingqin, Jiang, Shu, Varma, Sushama, Anderson, Lauren, Straub, Cody, Srivastava, Sucheta, Curtis, Christina, Tibshirani, Rob, Angelo, Robert Michael, Hall, Allison, Owzar, Kouros, Polyak, Kornelia, Maley, Carlo, Marks, Jeffrey R., Colditz, Graham A., Hwang, E. Shelley, and West, Robert B.

Published

2023

12. A novel combined miRNA and methylation marker panel (miMe) for prediction of prostate cancer outcome after radical prostatectomy.

Author

Strand, Siri H., Bavafaye‐Haghighi, Elham, Kristensen, Helle, Rasmussen, Anne K., Hoyer, Soren, Borre, Michael, Mouritzen, Peter, Besenbacher, Soren, Orntoft, Torben F., and Sorensen, Karina D.

Subjects

PROSTATE cancer, MIME, MICRORNA, METHYLATION, GLEASON grading system, PROSTATECTOMY, LOG-rank test

Abstract

Improved prognostic biomarkers are needed to guide personalized prostate cancer (PC) treatment decisions. Due to the prominent molecular heterogeneity of PC, multimarker panels may be more robust. Here, 25 selected top‐candidate miRNA and methylation markers for PC were profiled by qPCR in malignant radical prostatectomy (RP) tissue specimens from 198 PC patients (Cohort 1, training). Using GLMnet, we trained a novel multimarker model (miMe) comprising nine miRNAs and three methylation markers that predicted postoperative biochemical recurrence (BCR) independently of the established clinicopathological CAPRA‐S nomogram in Cox multivariate regression analysis in Cohort 1 (HR [95% CI]: 1.53 [1.26–1.84], p < 0.001). This result was successfully validated in two independent RP cohorts (Cohort 2, n = 159: HR [95% CI]: 1.35 [1.06–1.73], p = 0.015. TCGA, n = 350: HR [95% CI]: 1.34 [1.01–1.77], p = 0.04). Notably, in CAPRA‐S low‐risk patients, a high miMe score was associated with >6 times higher risk of BCR, suggesting that miMe may help identify PC patients at high risk of progression despite favorable clinicopathological factors postsurgery. Finally, miMe was a significant predictor of cancer‐specific survival (p = 0.019, log‐rank test) in a merged analysis of 357 RP patients. In conclusion, we trained, tested and validated a novel 12‐marker panel (miMe) that showed significant independent prognostic value in three RP cohorts. In the future, combining miMe score with existing clinical nomograms may improve PC risk stratification and thus help guide treatment decisions. What's new? Although localized prostate cancer (PC) can be cured by radical prostatectomy (RP), both over‐ and under‐treatment remain a major clinical problem as currently available routine prognostic tools cannot accurately distinguish aggressive from non‐aggressive PCs at time of diagnosis. Here, the authors report a novel combined miRNA/methylation marker panel (miMe) for PC prognosis that was a significant independent predictor of post‐operative PC outcome in three large RP cohorts. The results suggest that miMe may help guide personalized treatment decisions in the future, e.g. by identifying high‐risk PC patients who might be candidates for intensified therapy. [ABSTRACT FROM AUTHOR]

Published

2019

13. Biomarker potential of <italic>ST6GALNAC3</italic> and <italic>ZNF660</italic> promoter hypermethylation in prostate cancer tissue and liquid biopsies.

Author

Haldrup, Christa, Pedersen, Anne L., Øgaard, Nadia, Strand, Siri H., Høyer, Søren, Borre, Michael, Ørntoft, Torben F., and Sørensen, Karina D.

Abstract

Current diagnostic and prognostic tools for prostate cancer (PC) are suboptimal, leading to overdiagnosis and overtreatment. Aberrant promoter hypermethylation of specific genes has been suggested as novel candidate biomarkers for PC that may improve diagnosis and prognosis. We here analyzed ST6GALNAC3 and ZNF660 promoter methylation in prostate tissues, and ST6GALNAC3, ZNF660, CCDC181, and HAPLN3 promoter methylation in liquid biopsies. First, using four independent patient sample sets, including a total of 110 nonmalignant (NM) and 705 PC tissue samples, analyzed by methylation‐specific qPCR or methylation array, we found that hypermethylation of ST6GALNAC3 and ZNF660 was highly cancer‐specific with areas under the curve (AUC) of receiver operating characteristic (ROC) curve analysis of 0.917–0.995 and 0.846–0.903, respectively. Furthermore, ZNF660 hypermethylation was significantly associated with biochemical recurrence in two radical prostatectomy (RP) cohorts of 158 and 392 patients and remained significant also in the subsets of patients with Gleason score ≤7 (univariate Cox regression and log‐rank tests, P < 0.05), suggesting that ZNF660 methylation analysis can potentially help to stratify low‐/intermediate‐grade PCs into indolent vs. more aggressive subtypes. Notably, ZNF660 hypermethylation was also significantly associated with poor overall and PC‐specific survival in the RP cohort (n = 158) with long clinical follow‐up available. Moreover, as proof of principle, we successfully detected highly PC‐specific hypermethylated circulating tumor DNA (ctDNA) for ST6GALNAC3, ZNF660, HAPLN3, and CCDC181 in liquid biopsies (serum) from 27 patients with PC vs. 10 patients with BPH, using droplet digital methylation‐specific PCR analysis. Finally, we generated a three‐gene (ST6GALNAC3/CCDC181/HAPLN3) ctDNA hypermethylation model, which detected PC with 100% specificity and 67% sensitivity. In conclusion, we here for the first time demonstrate diagnostic biomarker potential of ST6GALNAC3 and ZNF660 methylation, as well as prognostic biomarker potential of ZNF660. Furthermore, we show that hypermethylation of four genes can be detected in ctDNA in liquid biopsies (serum) from patients with PC. [ABSTRACT FROM AUTHOR]

Published

2018

14. From the lab to the clinic: Lessons learned from a translational working group.

Author

Lynch, Thomas, Basila, Desiree, Schnitt, Stuart J., Marks, Jeffrey R, Strand, Siri H, Hyslop, Terry, Badve, Sunil S., Watson, Mark A, Le-Petross, Huong T., Grimm, Lars, West, Robert B., Weiss, Anna, Rapperport, Anna, King, Lorraine, Factor, Rachel E., Ryser, Marc D, Partridge, Ann H., Hwang, Eun-Sil Shelley, Thompson, Alastair Mark, and Collyar, Deborah E.

Published

2023

15. High levels of 5-hydroxymethylcytosine (5hmC) is an adverse predictor of biochemical recurrence after prostatectomy in ERG-negative prostate cancer.

Author

Strand, Siri H., Hoyer, Soren, Lynnerup, Anne-Sofie, Haldrup, Christa, Storebjerg, Tine Maj, Borre, Michael, Orntoft, Torben F., and Sorensen, Karina D.

Subjects

*PROSTATECTOMY, *PROSTATE cancer, *DNA methylation

Abstract

Background: Prostate cancer (PC) can be stratified into distinct molecular subtypes based on TMPRSS2-ERG gene fusion status, but its potential prognostic value remains controversial. Likewise, routine clinicopathological features cannot clearly distinguish aggressive from indolent tumors at the time of diagnosis; thus, new prognostic biomarkers are urgently needed. The DNA methylation variant 5-hydroxymethylcytosine (5hmC, an oxidized derivative of 5-methylcytosine) has recently emerged as a new diagnostic and/or prognostic biomarker candidate for several human malignancies. However, this remains to be systematically investigated for PC. In this study, we determined 5hmC levels in 311 PC (stratified by ERG status) and 228 adjacent non-malignant (NM) prostate tissue specimens by immunohistochemical analysis of a tissue microarray, representing a large radical prostatectomy (RP) cohort with long clinical follow-up. We investigated possible correlations between 5hmC and routine clinicopathological variables and assessed the prognostic potential of 5hmC by Kaplan-Meier and uni- and multivariate Cox regression analyses in ERG+ (n = 178) vs.E R G- (n = 133) PCs using biochemical recurrence (BCR) as endpoint. Results: We observed a borderline significant (p = 0.06) reduction in 5hmC levels in PC compared to NM tissue samples, which was explained by a highly significant (p < 0.001) loss of 5hmC in ERG- PCs. ERG status was not predictive of BCR in this cohort (p = 0.73), and no significant association was found between BCR and 5hmC levels in ERG+ PCs (p = 0.98). In contrast, high 5hmC immunoreactivity was a significant adverse predictor of BCR after RP in ERG- PCs, independent of Gleason score, pathological tumor stage, surgical margin status, and pre-operative prostate-specific antigen (PSA) level (hazard ratio (HR) (95 % confidence interval (CI)): 1.62 (1.15-2.28), p = 0.006). Conclusions: This is the first study to demonstrate a prognostic potential for 5hmC in PC. Our findings highlight the importance of ERG stratification in PC biomarker studies and suggest that epigenetic mechanisms involving 5hmC are important for the development and/or progression of ERG- PC. [ABSTRACT FROM AUTHOR]

Published

2015

16. Epigenetic Analysis of Circulating Tumor DNA in Localized and Metastatic Prostate Cancer: Evaluation of Clinical Biomarker Potential.

Author

Bjerre, Marianne Trier, Nørgaard, Maibritt, Larsen, Ole Halfdan, Jensen, Sarah Østrup, Strand, Siri H., Østergren, Peter, Fode, Mikkel, Fredsøe, Jacob, Ulhøi, Benedicte Parm, Mortensen, Martin Mørck, Jensen, Jørgen Bjerggaard, Borre, Michael, and Sørensen, Karina D.

Subjects

CIRCULATING tumor DNA, BIOMARKERS, PROSTATE cancer, METASTASIS, BENIGN prostatic hyperplasia, EPIGENETICS

Abstract

Novel and minimally-invasive prostate cancer (PCa)-specific biomarkers are needed to improve diagnosis and risk stratification. Here, we investigated the biomarker potential in localized and de novo metastatic PCa (mPCa) of methylated circulating tumor DNA (ctDNA) in plasma. Using the Marmal-aid database and in-house datasets, we identified three top candidates specifically hypermethylated in PCa tissue: DOCK2,HAPLN3, and FBXO30 (specificity/sensitivity: 80%–100%/75–94%). These candidates were further analyzed in plasma samples from 36 healthy controls, 61 benign prostatic hyperplasia (BPH), 102 localized PCa, and 65 de novo mPCa patients using methylation-specific droplet digital PCR. Methylated ctDNA for DOCK2/HAPLN3/FBXO30 was generally not detected in healthy controls, BPH patients, nor in patients with localized PCa despite a positive signal in 98%–100% of matched radical prostatectomy tissue samples. However, ctDNA methylation of DOCK2,HAPLN3, and/or FBXO30 was detected in 61.5% (40/65) of de novo mPCa patients and markedly increased in high- compared to low-volume mPCa (89.3% (25/28) vs. 32.1% (10/31), p < 0.001). Moreover, detection of methylated ctDNA was associated with significantly shorter time to progression to metastatic castration resistant PCa, independent of tumor-volume. These results indicate that methylated ctDNA (DOCK2/HAPLN3/FBXO30) may be potentially useful for identification of hormone-naïve mPCa patients who could benefit from intensified treatment. [ABSTRACT FROM AUTHOR]

Published

2020

17. Aberrant DOCK2, GRASP, HIF3A and PKFP Hypermethylation has Potential as a Prognostic Biomarker for Prostate Cancer.

Author

Bjerre, Marianne T., Strand, Siri H., Nørgaard, Maibritt, Kristensen, Helle, Rasmussen, Anne KI, Mortensen, Martin Mørck, Fredsøe, Jacob, Mouritzen, Peter, Ulhøi, Benedicte, Ørntoft, Torben, Borre, Michael, and Sørensen, Karina D.

Subjects

*PROSTATE cancer, *BIOLOGICAL tags, *DNA, *CONFIDENCE intervals, *GENE expression

Abstract

Prostate cancer (PCa) is a clinically heterogeneous disease and currently, accurate diagnostic and prognostic molecular biomarkers are lacking. This study aimed to identify novel DNA hypermethylation markers for PCa with future potential for blood-based testing. Accordingly, to search for genes specifically hypermethylated in PCa tissue samples and not in blood cells or other cancer tissue types, we performed a systematic analysis of genome-wide DNA methylation data (Infinium 450K array) available in the Marmal-aid database for 4072 malignant/normal tissue samples of various types. We identified eight top candidate markers (cg12799885, DOCK2, FBXO30, GRASP, HIF3A, MOB3B, PFKP, and TPM4) that were specifically hypermethylated in PCa tissue samples and hypomethylated in other benign and malignant tissue types, including in peripheral blood cells. Potential as diagnostic and prognostic biomarkers was further assessed by the quantitative methylation specific PCR (qMSP) analysis of 37 nonmalignant and 197 PCa tissue samples from an independent population. Here, all eight hypermethylated candidates showed high sensitivity (75–94%) and specificity (84–100%) for PCa. Furthermore, DOCK2, GRASP, HIF3A and PKFP hypermethylation was significantly associated with biochemical recurrence (BCR) after radical prostatectomy (RP; 197 patients), independent of the routine clinicopathological variables. DOCK2 is the most promising single candidate marker (hazard ratio (HR) (95% confidence interval (CI)): 1.96 (1.24–3.10), adjusted p = 0.016; multivariate cox regression). Further validation studies are warranted and should investigate the potential value of these hypermethylation candidate markers for blood-based testing also. [ABSTRACT FROM AUTHOR]

Published

2019

18. 5hmC Level Predicts Biochemical Failure Following Radical Prostatectomy in Prostate Cancer Patients with ERG Negative Tumors.

Author

Kristensen, Gitte, Strand, Siri H., Røder, Martin Andreas, Berg, Kasper Drimer, Toft, Birgitte Grønkær, Høyer, Søren, Borre, Michael, Sørensen, Karina Dalsgaard, and Brasso, Klaus

Subjects

*PROSTATE cancer patients, *PROSTATECTOMY, *IMMUNOHISTOCHEMISTRY, *TUMORS, *RISK assessment, *COHORT analysis, *REGRESSION analysis

Abstract

This study aimed to validate whether 5-hydroxymethylcytosine (5hmC) level in combination with ERG expression is a predictive biomarker for biochemical failure (BF) in men undergoing radical prostatectomy (RP) for prostate cancer (PCa). The study included 592 PCa patients from two consecutive Danish RP cohorts. 5hmC level and ERG expression were analyzed using immunohistochemistry in RP specimens. 5hmC was scored as low or high and ERG was scored as negative or positive. Risk of BF was analyzed using stratified cumulative incidences and multiple cause-specific Cox regression using competing risk assessment. Median follow-up was 10 years (95% CI: 9.5–10.2). In total, 246 patients (41.6%) had low and 346 patients (58.4%) had high 5hmC level. No significant association was found between 5hmC level or ERG expression and time to BF (p = 0.2 and p = 1.0, respectively). However, for men with ERG negative tumors, high 5hmC level was associated with increased risk of BF following RP (p = 0.01). In multiple cause-specific Cox regression analyses of ERG negative patients, high 5hmC expression was associated with time to BF (HR: 1.8; 95% CI: 1.2–2.7; p = 0.003). In conclusion, high 5hmC level was correlated with time to BF in men with ERG negative PCa, which is in accordance with previous results. [ABSTRACT FROM AUTHOR]

Published

2019

19. Single Cell Expression Analysis of Ductal Carcinoma in Situ Identifies Complex Genotypic-Phenotypic Relationships Altering Epithelial Composition.

Author

Qin X, Strand SH, Lee MR, Saraswathibhatla A, van IJzendoorn DGP, Zhu C, Vennam S, Varma S, Hall A, Factor RE, King L, Simpson L, Luo X, Colditz GA, Jiang S, Chaudhuri O, Hwang ES, Marks JR, Owzar K, and West RB

Abstract

To identify mechanisms underlying the growth of ductal carcinoma in situ (DCIS) and properties that lead to progression to invasive cancer, we performed single-cell RNA-sequencing (scRNA-seq) on DCIS lesions and matched synchronous normal breast tissue. Using inferred copy number variations (CNV), we identified neoplastic epithelial cells from the clinical specimens which contained a mixture of DCIS and normal ducts. Phylogenetic analysis based on the CNVs demonstrated intratumoral clonal heterogeneity was associated with significant gene expression differences. We also classified epithelial cells into mammary cell states and found that individual genetic clones contained a mixture of cell states suggesting an ongoing pattern of differentiation after neoplastic transformation. Cell state proportions were significantly different based on estrogen receptor (ER) expression with ER-DCIS more closely resembling the distribution in the normal breast, particularly with respect to cells with basal characteristics. Using deconvolution from bulk RNA-seq in archival DCIS specimens, we show that specific alterations in cell state proportions are associated with progression to invasive cancer. Loss of an intact basement membrane (BM) is the functional definition of invasive breast cancer (IBC) and scRNA-seq data demonstrated that ongoing transcription of key BM genes occurs in specific subsets of epithelial cell states. Examining BM in archival microinvasive breast cancers and an in vitro model of invasion, we found that passive loss of BM gene expression due to cell state proportion alterations is associated with loss of the structural integrity of the duct leading to an invasive phenotype. Our analyses provide detailed insight into DCIS biology., Significance: Single cell analysis reveals that preinvasive breast cancer is comprised of multiple genetic clones and there is substantial phenotypic diversity both within and between these clones. Ductal carcinoma in situ (DCIS) of the breast is a non-invasive condition commonly identified through mammographic screening. A primary diagnosis of DCIS carries little mortality risk on its own, but its presence is a risk factor for subsequent clonally related invasive breast cancer (IBC) (1-5).

Published

2024

20. Biomarker potential of ST6GALNAC3 and ZNF660 promoter hypermethylation in prostate cancer tissue and liquid biopsies.

Author

Haldrup C, Pedersen AL, Øgaard N, Strand SH, Høyer S, Borre M, Ørntoft TF, and Sørensen KD

Subjects

Aged, Aged, 80 and over, Humans, Liquid Biopsy, Male, Middle Aged, Prostatic Neoplasms pathology, Biomarkers, Tumor metabolism, DNA Methylation, DNA-Binding Proteins metabolism, Models, Biological, Neoplasm Proteins metabolism, Promoter Regions, Genetic, Prostatic Neoplasms metabolism, Sialyltransferases metabolism

Abstract

Current diagnostic and prognostic tools for prostate cancer (PC) are suboptimal, leading to overdiagnosis and overtreatment. Aberrant promoter hypermethylation of specific genes has been suggested as novel candidate biomarkers for PC that may improve diagnosis and prognosis. We here analyzed ST6GALNAC3 and ZNF660 promoter methylation in prostate tissues, and ST6GALNAC3, ZNF660, CCDC181, and HAPLN3 promoter methylation in liquid biopsies. First, using four independent patient sample sets, including a total of 110 nonmalignant (NM) and 705 PC tissue samples, analyzed by methylation-specific qPCR or methylation array, we found that hypermethylation of ST6GALNAC3 and ZNF660 was highly cancer-specific with areas under the curve (AUC) of receiver operating characteristic (ROC) curve analysis of 0.917-0.995 and 0.846-0.903, respectively. Furthermore, ZNF660 hypermethylation was significantly associated with biochemical recurrence in two radical prostatectomy (RP) cohorts of 158 and 392 patients and remained significant also in the subsets of patients with Gleason score ≤7 (univariate Cox regression and log-rank tests, P < 0.05), suggesting that ZNF660 methylation analysis can potentially help to stratify low-/intermediate-grade PCs into indolent vs. more aggressive subtypes. Notably, ZNF660 hypermethylation was also significantly associated with poor overall and PC-specific survival in the RP cohort (n = 158) with long clinical follow-up available. Moreover, as proof of principle, we successfully detected highly PC-specific hypermethylated circulating tumor DNA (ctDNA) for ST6GALNAC3, ZNF660, HAPLN3, and CCDC181 in liquid biopsies (serum) from 27 patients with PC vs. 10 patients with BPH, using droplet digital methylation-specific PCR analysis. Finally, we generated a three-gene (ST6GALNAC3/CCDC181/HAPLN3) ctDNA hypermethylation model, which detected PC with 100% specificity and 67% sensitivity. In conclusion, we here for the first time demonstrate diagnostic biomarker potential of ST6GALNAC3 and ZNF660 methylation, as well as prognostic biomarker potential of ZNF660. Furthermore, we show that hypermethylation of four genes can be detected in ctDNA in liquid biopsies (serum) from patients with PC., (© 2018 The Authors. Published by FEBS Press and John Wiley & Sons Ltd.)

Published

2018

21. RHCG and TCAF1 promoter hypermethylation predicts biochemical recurrence in prostate cancer patients treated by radical prostatectomy.

Author

Strand SH, Switnicki M, Moller M, Haldrup C, Storebjerg TM, Hedegaard J, Nordentoft I, Hoyer S, Borre M, Pedersen JS, Wild PJ, Park JY, Orntoft TF, and Sorensen KD

Subjects

Adult, Aged, Denmark, Epigenesis, Genetic, Humans, Male, Middle Aged, Neoplasm Grading, Prognosis, Promoter Regions, Genetic, Prostatectomy, Prostatic Neoplasms genetics, Prostatic Neoplasms pathology, Survival Analysis, Switzerland, United States, Biomarkers, Tumor genetics, Cation Transport Proteins genetics, DNA Methylation, Membrane Glycoproteins genetics, Membrane Proteins genetics, Prostatic Neoplasms surgery

Abstract

Purpose: The lack of biomarkers that can distinguish aggressive from indolent prostate cancer has caused substantial overtreatment of clinically insignificant disease. Here, by genome-wide DNA methylome profiling, we sought to identify new biomarkers to improve the accuracy of prostate cancer diagnosis and prognosis., Experimental Design: Eight novel candidate markers, COL4A6, CYBA, TCAF1 (FAM115A), HLF, LINC01341 (LOC149134), LRRC4, PROM1, and RHCG, were selected from Illumina Infinium HumanMethylation450 BeadChip analysis of 21 tumor (T) and 21 non-malignant (NM) prostate specimens. Diagnostic potential was further investigated by methylation-specific qPCR analysis of 80 NM vs. 228 T tissue samples. Prognostic potential was assessed by Kaplan-Meier, uni- and multivariate Cox regression analysis in 203 Danish radical prostatectomy (RP) patients (cohort 1), and validated in an independent cohort of 286 RP patients from Switzerland and the U.S. (cohort 2)., Results: Hypermethylation of the 8 candidates was highly cancer-specific (area under the curves: 0.79-1.00). Furthermore, high methylation of the 2-gene panel RHCG-TCAF1 was predictive of biochemical recurrence (BCR) in cohort 1, independent of the established clinicopathological parameters Gleason score, pathological tumor stage, and pre-operative PSA (HR (95% confidence interval (CI)): 2.09 (1.26 - 3.46); P = 0.004), and this was successfully validated in cohort 2 (HR (95% CI): 1.81 (1.05 - 3.12); P = 0.032)., Conclusion: Methylation of the RHCG-TCAF1 panel adds significant independent prognostic value to established prognostic parameters for prostate cancer and thus may help to guide treatment decisions in the future. Further investigation in large independent cohorts is necessary before translation into clinical utility.

Published

2017

22. HNF1B variants associate with promoter methylation and regulate gene networks activated in prostate and ovarian cancer.

Author

Ross-Adams H, Ball S, Lawrenson K, Halim S, Russell R, Wells C, Strand SH, Ørntoft TF, Larson M, Armasu S, Massie CE, Asim M, Mortensen MM, Borre M, Woodfine K, Warren AY, Lamb AD, Kay J, Whitaker H, Ramos-Montoya A, Murrell A, Sørensen KD, Fridley BL, Goode EL, Gayther SA, Masters J, Neal DE, and Mills IG

Subjects

Alleles, Cell Line, Tumor, Cell Movement, Cell Proliferation, Epithelial-Mesenchymal Transition, Female, Genetic Predisposition to Disease, Genetic Variation, Genome-Wide Association Study, Genotype, Humans, Linkage Disequilibrium, Male, Ovarian Neoplasms pathology, Polymorphism, Single Nucleotide, Prostatic Neoplasms pathology, Risk, DNA Methylation, Gene Expression Regulation, Neoplastic, Gene Regulatory Networks, Hepatocyte Nuclear Factor 1-beta genetics, Ovarian Neoplasms genetics, Promoter Regions, Genetic, Prostatic Neoplasms genetics

Abstract

Two independent regions within HNF1B are consistently identified in prostate and ovarian cancer genome-wide association studies (GWAS); their functional roles are unclear. We link prostate cancer (PC) risk SNPs rs11649743 and rs3760511 with elevated HNF1B gene expression and allele-specific epigenetic silencing, and outline a mechanism by which common risk variants could effect functional changes that increase disease risk: functional assays suggest that HNF1B is a pro-differentiation factor that suppresses epithelial-to-mesenchymal transition (EMT) in unmethylated, healthy tissues. This tumor-suppressor activity is lost when HNF1B is silenced by promoter methylation in the progression to PC. Epigenetic inactivation of HNF1B in ovarian cancer also associates with known risk SNPs, with a similar impact on EMT. This represents one of the first comprehensive studies into the pleiotropic role of a GWAS-associated transcription factor across distinct cancer types, and is the first to describe a conserved role for a multi-cancer genetic risk factor.

Published

2016

23. Prognostic DNA methylation markers for prostate cancer.

Author

Strand SH, Orntoft TF, and Sorensen KD

Subjects

Adenocarcinoma chemistry, Adenocarcinoma mortality, Biomarkers, Body Fluids chemistry, DNA, Neoplasm analysis, DNA, Neoplasm chemistry, Early Detection of Cancer, Gene Expression Profiling, Humans, Male, MicroRNAs genetics, Microtubule Proteins, Neoplasm Invasiveness genetics, Predictive Value of Tests, Prognosis, Promoter Regions, Genetic genetics, Prostatic Neoplasms chemistry, Prostatic Neoplasms mortality, Proteins genetics, Adenocarcinoma genetics, DNA Methylation, DNA, Neoplasm genetics, Gene Expression Regulation, Neoplastic physiology, Neoplasm Proteins genetics, Prostatic Neoplasms genetics, RNA, Neoplasm genetics

Abstract

Prostate cancer (PC) is the most commonly diagnosed neoplasm and the third most common cause of cancer-related death amongst men in the Western world. PC is a clinically highly heterogeneous disease, and distinction between aggressive and indolent disease is a major challenge for the management of PC. Currently, no biomarkers or prognostic tools are able to accurately predict tumor progression at the time of diagnosis. Thus, improved biomarkers for PC prognosis are urgently needed. This review focuses on the prognostic potential of DNA methylation biomarkers for PC. Epigenetic changes are hallmarks of PC and associated with malignant initiation as well as tumor progression. Moreover, DNA methylation is the most frequently studied epigenetic alteration in PC, and the prognostic potential of DNA methylation markers for PC has been demonstrated in multiple studies. The most promising methylation marker candidates identified so far include PITX2, C1orf114 (CCDC181) and the GABRE~miR-452~miR-224 locus, in addition to the three-gene signature AOX1/C1orf114/HAPLN3. Several other biomarker candidates have also been investigated, but with less stringent clinical validation and/or conflicting evidence regarding their possible prognostic value available at this time. Here, we review the current evidence for the prognostic potential of DNA methylation markers in PC.

Published

2014