Phenotypic, structural, and ultrastructural analysis of triple-negative breast cancer cell lines and breast cancer stem cell subpopulation.

Triple negative breast cancer (TNBC) is a highly heterogeneous disease, which influences the therapeutic response and makes difficult the discovery of effective targets. This heterogeneity is attributed to the presence of breast cancer stem cells (BCSCs), which determines resistance to chemotherapy and subsequently disease recurrence and metastasis. In this context, this work aimed to evaluate the morphological and phenotypic cellular heterogeneity of two TNBC cell lines cultured in monolayer and tumorsphere (TS) models by fluorescence and electron microscopy and flow cytometry. The BT-549 and Hs 578T analyses demonstrated large phenotypic and morphological heterogeneity between these cell lines, as well as between the cell subpopulations that compose them. BT-549 and Hs 578T are heterogeneous considering the cell surface marker CD44 and CD24 expression, characterizing BCSC mesenchymal-like cells (CD44+/CD24-), epithelial cells (CD44-/CD24+), hybrid cells with mesenchymal and epithelial features (CD44+/CD24+), and CD44-/CD24- cells. BCSC epithelial-like cells (ALDH+) were found in BT-549, BT-549 TS, and Hs 578T TS; however, only BT-549 TS showed a high ALDH activity. Ultrastructural characterization showed the heterogeneity within and among BT-549 and Hs 578T in monolayer and TS models being formed by more than one cellular type. Further, the mesenchymal characteristic of these cells is demonstrated by E-cadherin absence and filopodia. It is well known that tumor cell heterogeneity can influence survival, therapy responses, and the rate of tumor growth. Thus, molecular understanding of this heterogeneity is essential for the identification of potential therapeutic options and vulnerabilities of oncological patients.

STAT3 as a promising chemoresistance biomarker associated with the CD44+/high/CD24-/low/ALDH+ BCSCs-like subset of the triple-negative breast cancer (TNBC) cell line.

The cancer stem cell (CSC) concept is currently employed to explain the mechanism of multidrug resistance that is implicated in the reduced efficacy of many chemotherapeutic agents, consequently leading to metastatic spread and disease relapse. We searched for potential predictive markers of doxorubicin (DOX) resistance in breast cancer stem cells (BCSCs) of the BT-549 human triple-negative breast cancer (TNBC) cell line classified as a claudin-low subtype. In this study, we show that BT-549 presents a BCSCs-like subset determined by a CD44+/high/CD24-/low/ALDH1+ phenotype. The CD44+/high/CD24-/low/ALDH+ BCSCs-like subset presented the downregulation of a majority of the genes analyzed (64 genes), and only 3 genes were upregulated after DOX treatment. Among the upregulated genes, MAPK3, PRKCZ and STAT3, STAT3 presented a higher level of upregulation in the DOX-treated CD44+/high/CD24-/low/ALDH+ BCSCs-like subset. The identification of biomarkers that predict antitumor responses is at the top of cancer research priorities. STAT3 was highlighted as a molecular signature in the CD44+/high/CD24-/low/ALDH1+ BCSCs-like subset obtained from the TNBC BT-549 cell line related to DOX resistance. A majority of the evaluated genes in the EGF pathway appear to be not associated with DOX resistance, as observed in the CD44+/high/CD24-/low/ALDH1+ BCSCs-like subset.

The role of GADD45A in resistance to oxidative stress-mediated cell death in human colon tumor cell lines

Objective: GADD45A is a growth arrest-associated gene, directly involved in the maintenance of genomic stability. In fact, in the absence of this protein cells became sensitized to death by ultraviolet irradiation or cisplatin. However, this role with respect to cell damage triggered by Reactive Oxygen Species (ROS) is not well understood. Thus, in an attempt to evaluate its role in oxidative stress-induced apoptosis, we analyzed its expression after induction of ROS in human colon cell lines. Material and methods: Cell lines derived from human colon tumors (RKO-AS45-1 and HuTu-80) were treated with Menadione (MEN) and Hydrogen Peroxide (HP). Next, the expression of GADD45A was evaluated by semi-quantitative RT-PCR analysis. Results: The results indicated that expression of this gene was associated with resistance to apoptosis. Additionally, cells with high expression of GADD45A were resistant to treatment with oxidative stress-inducing compounds. Conclusion: In conclusion, we propose that the expression of the GADD45A gene can be used as a functional tool to predict cellular responses to antitumor treatments.