New paper provides important insights into how carcinoma-associated fibroblasts function in breast cancers | News | Notre Dame News | University of Notre Dame Skip To Content Skip To Navigation Skip To Search University of Notre Dame Notre Dame News Experts ND in the News Subscribe About Us Home Contact Search Menu Home › News › New paper provides important insights into how carcinoma-associated fibroblasts function in breast cancers New paper provides important insights into how carcinoma-associated fibroblasts function in breast cancers Published: May 07, 2014 Author: William G. Gilroy Carcinoma-associated fibroblasts (CAFs) A new paper by a team of researchers led by Zachary T. Schafer, Coleman Assistant Professor of Cancer Biology in the Department of Biological Sciences at the University of Notre Dame, offers important new insights into the role carcinoma-associated fibroblasts (CAFs) play in tumor biology. A number of recent studies have revealed CAFs to be a major contributor to tumor progression through a variety of mechanisms. Despite this information, the precise role CAFs play in augmenting the growth of tumors is still poorly understood. In their new paper, Schafer and his fellow researchers describe a critical role for CAFs in blocking anoikis, a cell death process that inhibits the spread of tumor cells to distant sites, through the secretion of insulin-like growth factor-binding proteins (IGFBPs). They revealed the precise molecular mechanism utilized by IGFBPs to inhibit anoikis: the stabilization of an anti-cell-death protein called Mcl-1. “While cells present in the tumor microenvironment are now widely appreciated to actively contribute to tumor progression, our studies have unveiled a novel mechanism by which this can occur,” Schafer said. “Therapies designed to hinder this role for IGFBPs might be particularly useful in slowing breast cancer metastasis.” Schafer noted, however, that additional pre-clinical studies are necessary to better understand which IGFBPs might be amenable to target and to determine the precise point during tumor progression that IGBFP inhibition could be effective. This study stems from a V Scholar Award from the V Foundation for Cancer Research that was awarded to Schafer in 2011. Schafer notes that this paper was made possible by the contribution of a diverse and multidisciplinary team of scientists. In particular, the patient CAF samples utilized in this study were obtained through a collaboration with William Kaliney, the executive vice president of the South Bend Medical Foundation. Co-first authorship on this paper was shared by Kelsey Weigel, a graduate student in Schafer’s lab, and Ana Jakimenko, a former postdoctoral fellow in his lab. Additional contributors include Brooke Conti, a Ph.D. student at The Rockefeller University and a 2013 Notre Dame graduate; W. Matthew Leevy and Sarah Chapman from the Notre Dame Integrated Imaging Facility; and Matthew Champion from the Mass Spectrometry & Proteomics Facility and the Department of Chemistry and Biochemistry. The paper was published online on May 7 in the journal Molecular Cancer Research. It can be found at mcr.aacrjournals.org/content/early/2014/05/06/1541-7786.MCR-14-0090.abstract. Contact: Zachary T. Schafer, 574-631-0875, zschafe1@nd.edu Posted In: Research Home Experts ND in the News Subscribe About Us Related October 05, 2022 Astrophysicists find evidence for the presence of the first stars October 04, 2022 NIH awards $4 million grant to psychologists researching suicide prevention September 29, 2022 Notre Dame, Ukrainian Catholic University launch three new research grants September 27, 2022 Notre Dame, Trinity College Dublin engineers join to advance novel treatment for cystic fibrosis September 22, 2022 Climate-prepared countries are losing ground, latest ND-GAIN index shows For the Media Contact Office of Public Affairs and Communications Notre Dame News 500 Grace Hall Notre Dame, IN 46556 USA Facebook Twitter Instagram YouTube Pinterest © 2022 University of Notre Dame Search Mobile App News Events Visit Accessibility Facebook Twitter Instagram YouTube LinkedIn