NPPB is a novel candidate biomarker expressed by cancer-associated fibroblasts in epithelial ovarian cancer
INTERNATIONAL JOURNAL OF CANCER
Authors: Lawrenson, Kate; Grun, Barbara; Lee, Nathan; Mhawech-Fauceglia, Paulette; Kan, Jenny; Swenson, Steve; Lin, Yvonne G.; Pejovic, Tanja; Millstein, Joshua; Gayther, Simon A.
Abstract
Most solid tumors contain cancer-associated fibroblasts (CAFs) that support tumorigenesis and malignant progression. However, the cellular origins of CAFs in epithelial ovarian cancers (EOCs) remain poorly understood, and their utility as a source of clinical biomarkers for cancer diagnosis has not been explored in great depth. Here, we report establishing in vitro and in vivo models of CAFs in ovarian cancer development. Normal ovarian fibroblasts and mesenchymal stem cells cultured in the presence of EOC cells acquired a CAF-like phenotype, and promoted EOC cell migration in vitro. CAFs also promoted ovarian cancer growth in vivo in both subcutaneous and intraperitoneal murine xenograft assays. Molecular profiling of CAFs identified gene expression signatures that were highly enriched for extracellular and secreted proteins. We identified novel candidate CAF-specific biomarkers for ovarian cancer including NPPB, which was expressed in the stroma of 60% primary ovarian cancer tissues (n=145) but not in the stroma of normal ovaries (n=4). NPPB is a secreted protein that was also elevated in the blood of 50% of women with ovarian cancer (n=8). Taken together, these data suggest that the tumor stroma is a novel source of biomarkers, including NPPB, that may be of clinical utility for detection of EOC. What's new? Biomarkers that can reliably detect early-stage ovarian cancer (EOC) are urgently needed. In this study, the authors found that NPPB, a protein not previously implicated in EOC, is upregulated by cancer-associated fibroblasts in ovarian tumors, and was detected in the blood of half of the ovarian cancer patients tested. NPPB may, therefore, be a promising candidate as an ovarian-cancer biomarker; these results also indicate that tumor stroma may be a useful source of cancer biomarkers.
Pharmacological "Cross-Inhibition" of Connexin Hemichannels and Swelling Activated Anion Channels
GLIA
Authors: Ye, Zu-Cheng; Oberheim, Nancyann; Kettenmann, Helmut; Ransom, Bruce R.
Abstract
The study of ion channels has relied heavily on the use of pharmacological blocking agents. However, many of these agents have multiple effects, which may compromise interpretation of results when the affected mechanisms/pathways mediate similar functions. Volume regulated anion channels (VRAC) and connexin hemichannels can both mediate the release of glutamate and taurine, although these channels have distinct activation stimuli and hemichannels, but not VRAC, are permeable to Lucifer Yellow (LY). It has been reported that some anion channel blockers may inhibit connexin hemichannels. We further examined the effects of classic gap junction/hemichannel blockers and anion channel blockers on these channels. The typical VRAC blockers, NPPB, LAA-94, and tamoxifen blocked low divalent cation-induced glutamate and taurine release and LY loading, presumed due to hemichannel opening. The blocking action of these compounds on hemichannels was concentration dependent and fell within the same range where the drugs classically block VRACs. Conversely, carbenoxolone (CBX), the most widely used gap junction/hemichannel blocker, was an effective blocker of VRAC-mediated glutamate and taurine release, and blocked these channels at similar concentrations at which it blocked hemichannels. The CBX effect on VRACs was verified using astrocytes from connexin 43 knock out (Cx43 KO) animals. In these cells, the hypotonic induced amino acid flux was retained whereas the low divalent cation solution-induced flux was lost. These results extend our knowledge about "cross-inhibition" of VRACs and gap junctions/hemichannels by certain pharmacological agents. Given the overlap in function of these two types of channels, great care must be exerted in using pharmacological blockers to identify one channel from the other. (C) 2008 Wiley-Liss, Inc.