Comprehensive genetic and functional characterization of IPH-926: a novel CDH1-null tumour cell line from human lobular breast cancer.

Infiltrating lobular breast cancer (ILBC) is a clinically and biologically distinct tumour entity defined by a characteristic linear cord invasion pattern and inactivation of the CDH1 tumour suppressor gene encoding for E-cadherin. ILBCs also lack beta-catenin expression and show aberrant cytoplasmic localization of the E-cadherin binding protein p120-catenin. The lack of a well-characterized ILBC cell line has hampered the functional characterization of ILBC cells in vitro. We report the establishment of a permanent ILBC cell line, named IPH-926, which was derived from a patient with metastatic ILBC. The DNA fingerprint of IPH-926 verified genetic identity with the patient and had no match among the human cell line collections of several international biological resource banks. IPH-926 expressed various epithelial cell markers but lacked expression of E-cadherin due to a previously unreported, homozygous CDH1 241ins4 frameshift mutation. Detection of the same CDH1 241ins4 mutation in archival tumour tissue of the corresponding primary ILBC proved the clonal origin of IPH-926 from this particular tumour. IPH-926 also lacked beta-catenin expression and showed aberrant cytoplasmic localization of p120-catenin. Array-CGH analysis of IPH-926 revealed a profile of genomic imbalances that included many distinct alterations previously observed in primary ILBCs. Spectral karyotyping of IPH-926 showed a hyperdiploid chromosome complement and numerous clonal, structural aberrations. IPH-926 cells were anti-cancer drug-resistant, clonogenic in soft agar, and tumourigenic in SCID mice. In xenograft tumours, IPH-926 cells recapitulated the linear cord invasion pattern that defines ILBCs. In summary, IPH-926 significantly extends the biological spectrum of the established breast cancer cell lines and will facilitate functional analyses of genuine human ILBC cells in vitro and in vivo.

KAI1/CD82 is a novel target of estrogen receptor-mediated gene repression and downregulated in primary human breast cancer.

The cell-surface glycoprotein KAI1 suppresses tumor growth and metastasis in various animal models. Downregulation of KAI1 has been implicated in the progression of cancer. However, the mechanisms of KAI1 inactivation are poorly understood. This is the first study that investigates expression and regulation of KAI1 in human breast cancer. KAI1 expression was analyzed on custom-made tissue microarrays comprising 209 well-characterized breast cancers and normal mammary gland tissue. Strong KAI1 immunoreactivity was observed throughout the normal mammary gland epithelium. In breast cancer tissue, KAI1 immunoreactivity was lost in 161/209 (77%) cases. Strikingly, KAI1 was preferentially lost in estrogen receptor (ER)-positive breast cancers (p < 0.001). This was validated by real-time RT-PCR analyses showing a 7.5-fold downregulation of KAI1 mRNA in ER-positive relative to ER-negative tumors (p = 0.028). Notably, this was also corroborated by Affymetrix microarray expression data of an independent cohort of 49 breast cancers. Class comparison analysis identified KAI1 as downregulated in ER-positive tumors. Subsequently, human breast cancer cell lines were employed to test a potential role of ER-activity in the downregulation of KAI1, as suggested by our expression analyses. Exposure of ER-positive breast cancer cells to fulvestrant, a clinically approved ER-antagonist that reverses ER-mediated gene repression, induced a significant upregulation of KAI1 and inhibited cell proliferation as well as migration. In summary, we demonstrate for the first time that KAI1 is a target of ER-mediated gene-repression, and thus, it is downregulated in ER-positive breast cancer. Importantly, KAI1 might be reinducible by endocrine therapy with ER-antagonists in patients suffering from ER-positive breast cancer.

Identification of a distinct side population of cancer cells in the Cal-51 human breast carcinoma cell line.

"Side population" (SP) cells, which pump out the fluorescent dye H33342 via the ABCG2 transporter, define a putative stem/progenitor cell population in the mammary gland. Breast cancer SP cells recently isolated from the MCF-7 cell line possess similar properties and may represent stem cell-like cancer cells. This study extends SP cell analysis to a broad panel of human breast cancer cell lines and investigates the expression of differentiation-associated markers in isolated cancer SP cells. Expression of ABCG2 was determined in 16 breast cancer cell lines by quantitative RT-PCR, Western blotting and immunohistochemistry. Subsequently, all cell lines were screened for the presence of SP cells. Human breast cancer cell lines commonly express ABCG2. ABCG2-immunoreactivity was clearly restricted to rare cancer cells in several cell lines including Cal-51. Analysis of H33342-labeled Cal-51 cells revealed a small fraction of putative SP cells accounting for one percent of all cells. The genuine nature of Cal-51 SP cells was unambiguously verified by demonstrating a 30-fold increased ABCG2-expression in isolated Cal-51 SP cells. During in vitro expansion, Cal-51 SP cells generated heterologous non-SP (NSP) cells and ABCG2-expression declined dramatically. In contrast, NSP cells failed to sustain proliferation. Freshly isolated Cal-51 SP cells also exhibited increased expression of Muc1 and CALLA. Noteworthy, non-malignant mammary epithelial SP cells lack these differentiation markers, highlighting fundamental differences between non-malignant and breast cancer-derived SP cells. In summary, we established Cal-51 SP cells as a novel in vitro model to study differential gene expression in breast cancer-derived SP and NSP cells.