Stefan Bentink

Publications (4)17.74 Total impact

• Article: Stem Cell-Like Gene Expression in Ovarian Cancer Predicts Type II Subtype and Prognosis.

  Matthew Schwede, Dimitrios Spentzos, Stefan Bentink, Oliver Hofmann, Benjamin Haibe-Kains, David Harrington, John Quackenbush, Aedín C Culhane
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  ABSTRACT: Although ovarian cancer is often initially chemotherapy-sensitive, the vast majority of tumors eventually relapse and patients die of increasingly aggressive disease. Cancer stem cells are believed to have properties that allow them to survive therapy and may drive recurrent tumor growth. Cancer stem cells or cancer-initiating cells are a rare cell population and difficult to isolate experimentally. Genes that are expressed by stem cells may characterize a subset of less differentiated tumors and aid in prognostic classification of ovarian cancer. The purpose of this study was the genomic identification and characterization of a subtype of ovarian cancer that has stem cell-like gene expression. Using human and mouse gene signatures of embryonic, adult, or cancer stem cells, we performed an unsupervised bipartition class discovery on expression profiles from 145 serous ovarian tumors to identify a stem-like and more differentiated subgroup. Subtypes were reproducible and were further characterized in four independent, heterogeneous ovarian cancer datasets. We identified a stem-like subtype characterized by a 51-gene signature, which is significantly enriched in tumors with properties of Type II ovarian cancer; high grade, serous tumors, and poor survival. Conversely, the differentiated tumors share properties with Type I, including lower grade and mixed histological subtypes. The stem cell-like signature was prognostic within high-stage serous ovarian cancer, classifying a small subset of high-stage tumors with better prognosis, in the differentiated subtype. In multivariate models that adjusted for common clinical factors (including grade, stage, age), the subtype classification was still a significant predictor of relapse. The prognostic stem-like gene signature yields new insights into prognostic differences in ovarian cancer, provides a genomic context for defining Type I/II subtypes, and potential gene targets which following further validation may be valuable in the clinical management or treatment of ovarian cancer.
  PLoS ONE 01/2013; 8(3):e57799. · 4.09 Impact Factor
• Article: iBBiG: iterative binary bi-clustering of gene sets.

  Daniel Gusenleitner, Eleanor A Howe, Stefan Bentink, John Quackenbush, Aedín C Culhane
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  ABSTRACT: Meta-analysis of genomics data seeks to identify genes associated with a biological phenotype across multiple datasets; however, merging data from different platforms by their features (genes) is challenging. Meta-analysis using functionally or biologically characterized gene sets simplifies data integration is biologically intuitive and is seen as having great potential, but is an emerging field with few established statistical methods. We transform gene expression profiles into binary gene set profiles by discretizing results of gene set enrichment analyses and apply a new iterative bi-clustering algorithm (iBBiG) to identify groups of gene sets that are coordinately associated with groups of phenotypes across multiple studies. iBBiG is optimized for meta-analysis of large numbers of diverse genomics data that may have unmatched samples. It does not require prior knowledge of the number or size of clusters. When applied to simulated data, it outperforms commonly used clustering methods, discovers overlapping clusters of diverse sizes and is robust in the presence of noise. We apply it to meta-analysis of breast cancer studies, where iBBiG extracted novel gene set-phenotype association that predicted tumor metastases within tumor subtypes. Implemented in the Bioconductor package iBBiG CONTACT: aedin@jimmy.harvard.edu.
  Bioinformatics 07/2012; 28(19):2484-92. · 5.47 Impact Factor
• Article: Angiogenic mRNA and microRNA gene expression signature predicts a novel subtype of serous ovarian cancer.

  Stefan Bentink, Benjamin Haibe-Kains, Thomas Risch, Jian-Bing Fan, Michelle S Hirsch, Kristina Holton, Renee Rubio, Craig April, Jing Chen, Eliza Wickham-Garcia, Joyce Liu, Aedin Culhane, Ronny Drapkin, John Quackenbush, Ursula A Matulonis
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  ABSTRACT: Ovarian cancer is the fifth leading cause of cancer death for women in the U.S. and the seventh most fatal worldwide. Although ovarian cancer is notable for its initial sensitivity to platinum-based therapies, the vast majority of patients eventually develop recurrent cancer and succumb to increasingly platinum-resistant disease. Modern, targeted cancer drugs intervene in cell signaling, and identifying key disease mechanisms and pathways would greatly advance our treatment abilities. In order to shed light on the molecular diversity of ovarian cancer, we performed comprehensive transcriptional profiling on 129 advanced stage, high grade serous ovarian cancers. We implemented a, re-sampling based version of the ISIS class discovery algorithm (rISIS: robust ISIS) and applied it to the entire set of ovarian cancer transcriptional profiles. rISIS identified a previously undescribed patient stratification, further supported by micro-RNA expression profiles, and gene set enrichment analysis found strong biological support for the stratification by extracellular matrix, cell adhesion, and angiogenesis genes. The corresponding "angiogenesis signature" was validated in ten published independent ovarian cancer gene expression datasets and is significantly associated with overall survival. The subtypes we have defined are of potential translational interest as they may be relevant for identifying patients who may benefit from the addition of anti-angiogenic therapies that are now being tested in clinical trials.
  PLoS ONE 01/2012; 7(2):e30269. · 4.09 Impact Factor
• Source

  Available from: Aedín C Culhane

  Article: Therapeutic implications of GIPC1 silencing in cancer.

  Thomas W Chittenden, Jane Pak, Renee Rubio, Hailing Cheng, Kristina Holton, Niall Prendergast, Vladimir Glinskii, Yi Cai, Aedin Culhane, Stefan Bentink, [......], Eleanor A Howe, Martin Aryee, Razvan Sultana, Anthony A Lanahan, Jennifer M Taylor, Chris Holmes, William C Hahn, Jean J Zhao, J Dirk Iglehart, John Quackenbush
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  ABSTRACT: GIPC1 is a cytoplasmic scaffold protein that interacts with numerous receptor signaling complexes, and emerging evidence suggests that it plays a role in tumorigenesis. GIPC1 is highly expressed in a number of human malignancies, including breast, ovarian, gastric, and pancreatic cancers. Suppression of GIPC1 in human pancreatic cancer cells inhibits in vivo tumor growth in immunodeficient mice. To better understand GIPC1 function, we suppressed its expression in human breast and colorectal cancer cell lines and human mammary epithelial cells (HMECs) and assayed both gene expression and cellular phenotype. Suppression of GIPC1 promotes apoptosis in MCF-7, MDA-MD231, SKBR-3, SW480, and SW620 cells and impairs anchorage-independent colony formation of HMECs. These observations indicate GIPC1 plays an essential role in oncogenic transformation, and its expression is necessary for the survival of human breast and colorectal cancer cells. Additionally, a GIPC1 knock-down gene signature was used to interrogate publically available breast and ovarian cancer microarray datasets. This GIPC1 signature statistically correlates with a number of breast and ovarian cancer phenotypes and clinical outcomes, including patient survival. Taken together, these data indicate that GIPC1 inhibition may represent a new target for therapeutic development for the treatment of human cancers.
  PLoS ONE 01/2010; 5(12):e15581. · 4.09 Impact Factor