Activin Receptor-like Kinase 1 Ligand Trap Reduces Microvascular Density and Improves Chemotherapy Efficiency to Various Solid Tumors

Therapeutic cell differentiatio

E-cadherin promotor methylation and mutation are inversely related to motility capacity of breast cancer cells

Item does not contain fulltextInactivation of the tumor suppressor E-cadherin is an important event during breast tumorigenesis, as its decreased expression is linked to aggressiveness and metastasis. However, the relationship between the different modes of E-cadherin inactivation (mutation versus promotor hypermethylation) and breast cancer cell behavior is incompletely understood. The high correlation between E-cadherin inactivation status and cell morphology in vitro suggests different biological roles for the two inactivation modes during breast tumorigenesis. Because E-cadherin has been linked to cell invasion and metastasis, and cell motility is a crucial prerequisite to form metastases, we here compared the cell motility capacities of breast cancer cell lines with known E-cadherin status. Using barrier migration assays and time-lapse microscopy, we analyzed the migratory capacity of nine well-characterized human breast cancer cell lines (MDA-MB-231, MCF-7, T47D, BT549, MPE600, CAMA-1, SUM159PT, SUM52PE, and SK-BR-3). This subset was chosen based on E-cadherin gene status (wild-type, mutated, and promotor hypermethylated): three cell lines of each group. In addition, cell proliferation assays were performed for all conditions, to dissect migratory from proliferative effects. In this study, we demonstrate an overt association between the mode of E-cadherin inactivation and cell migration. Promotor hypermethylated E-cadherin cell lines showed a higher migration capacity, while cell lines with mutated E-cadherin were less motile compared to wild-type E-cadherin cell lines. Migration induction by fibronectin and basic fibroblast growth factor did not alter the cell motility association differences. Cell proliferation assays showed that the associations found were not caused by proliferation differences. Inhibition and overexpression of E-cadherin as well as DNA demethylation confirmed the relationship between E-cadherin and breast cancer cell motility. Our results demonstrate an association between the mode of E-cadherin inactivation and migration of breast cancer cells, which justifies more detailed research on the role of E-cadherin inactivation in cell migration and metastasis

Distinct gene mutation profiles among luminal-type and basal-type breast cancer cell lines

Breast cancer has for long been recognized as a highly diverse tumor group, but the underlying genetic basis has been elusive. Here, we report an extensive molecular characterization of a collection of 41 human breast cancer cell lines. Protein and gene expression analyses indicated that the collection of breast cancer cell lines has retained most, if not all, molecular characteristics that are typical for clinical breast cancers. Gene mutation analyses identified 146 oncogenic mutations among 27 well-known cancer genes, amounting to an average of 3.6 mutations per cell line. Mutations in genes from the p53, RB and PI3K tumor suppressor pathways were widespread among all breast cancer cell lines. Most important, we have identified two gene mutation profiles that are specifically associated with luminal-type and basal-type breast cancer cell lines. The luminal mutation profile involved E-cadherin and MAP2K4 gene mutations and amplifications of Cyclin D1, ERBB2 and HDM2, whereas the basal mutation profile involved BRCA1, RB1, RAS and BRAF gene mutations and deletions of p16 and p14ARF. These subtype-specific gene mutation profiles constitute a genetic basis for the heterogeneity observed among human breast cancers, providing clues for their underlying biology and providing guidance for targeted pharmacogenetic intervention in breast cancer patients