Abscission is the final stage of cytokinesis during which the parent cell physically separates to yield two identical daughters. Failure of abscission results in multinucleation, a sign of genomic instability and a precursor to aneuploidy, enabling characteristics of neoplastic progression. Induction of epithelial-mesenchymal transition (EMT) causes multinucleation in mammary epithelial cells cultured on stiff microenvironments that have mechanical properties similar to those found in breast tumors, but not on soft microenvironments reminiscent of the normal mammary gland. Here, we report that on stiff microenvironments, EMT signaling through Snail upregulates the midbody-associated proteins septin-6, Mklp1, and anillin, leading to abscission failure and multinucleation. To uncover the mechanism by which stiff microenvironments promote multinucleation in cells undergoing EMT, we investigated the role of cell-matrix adhesion through β1-integrin and integrin-linked kinase (ILK). We found that ILK expression, but not kinase activity, is required for EMT-associated multinucleation in cells on stiff microenvironments. Conversely, increasing focal adhesions by expressing an autoclustering β1-integrin promotes multinucleation in cells on soft microenvironments. Our data suggest that signaling through focal adhesions causes failure of cytokinesis in cells actively undergoing EMT. These results highlight the importance of tissue mechanics and adhesion in regulating the cellular response to EMT inducers.
Membrane voltage (Vm) plays a critical role in the regulation of several cellular behaviors, including proliferation, apoptosis, and phenotypic plasticity. Many of these same behaviors are affected by the stiffness of the underlying extracellular matrix, but the connections between Vm and the mechanical properties of the microenvironment are unclear. Here, we investigated the relationship between matrix stiffness and Vm by culturing mammary epithelial cells on synthetic substrata, the stiffnesses of which mimicked those of the normal mammary gland and breast tumors. Although proliferation is associated with depolarization, we surprisingly observed that cells are hyperpolarized when cultured on stiff substrata, a microenvironmental condition that enhances proliferation. Accordingly, we found that Vm becomes depolarized as stiffness decreases, in a manner dependent on intracellular calcium. Furthermore, inhibiting calcium-gated chloride currents abolishes the effects of substratum stiffness on Vm. Specifically, we uncovered a role for cystic fibrosis transmembrane conductance regulator (CFTR) in the regulation of Vm by substratum stiffness. Together, these results suggest a novel role for CFTR and membrane voltage in the response of mammary epithelial cells to their mechanical microenvironment.
Metastasis, the leading cause of mortality in cancer patients, depends upon the ability of cancer cells to invade into the extracellular matrix that surrounds the primary tumor and to escape into the vasculature. To investigate the features of the microenvironment that regulate invasion and escape, we generated solid microtumors of MDA-MB-231 human breast carcinoma cells within gels of type I collagen. The microtumors were formed at defined distances adjacent to an empty cavity, which served as an artificial vessel into which the constituent tumor cells could escape. To define the relative contributions of matrix degradation and cell proliferation on invasion and escape, we used pharmacological approaches to block the activity of matrix metalloproteinases (MMPs) or to arrest the cell cycle. We found that blocking MMP activity prevents both invasion and escape of the breast cancer cells. Surprisingly, blocking proliferation increases the rate of invasion but has no effect on that of escape. We found that arresting the cell cycle increases the expression of MMPs, consistent with the increased rate of invasion. To gain additional insight into the role of cell proliferation in the invasion process, we generated microtumors from cells that express the fluorescent ubiquitination-based cell cycle indicator. We found that the cells that initiate invasions are preferentially quiescent, whereas cell proliferation is associated with the extension of invasions. These data suggest that matrix degradation and cell proliferation are coupled during the invasion and escape of human breast cancer cells and highlight the critical role of matrix proteolysis in governing tumor phenotype.
This study investigates how increased stiffness of the tumor microenvironment can induce cellular multinucleation, an easily observable marker of polyploidy. Up to 37% percent of tumors exhibit whole-genome doubling, which typically precedes other somatic copy number alterations. Additionally, induction of tetraploidy in human cells promotes increased tolerance for mutation, resistance to chemotherapeutic drugs, and transformation in culture. Tumors are inherently stiffer than normal tissue, and this property has been shown to affect cell growth and proliferation. Similarly, cell cycle errors have long been linked to chromosomal abnormalities. Here, we used engineered two-dimensional substrata that mimic the stiffness of tumor and normal microenvironments to investigate how matrix stiffness regulates multinucleation in mammary epithelial cells. Multinucleation was quantified by staining with Hoescht to visualize the nuclei. Timelapse microscopy enabled visualization of the process by which cells become multinucleated. Changes in gene expression were determined by quantitative RT-PCR. Cells cultured on “stiff” substrata, representing tumor tissue, showed a nearly 14-fold increase in multinucleation compared to cells cultured on “soft” substrata, representing normal tissue. We found that multinucleation was regulated in part by signaling downstream of matrix metalloproteinase-3 (MMP3), which is commonly upregulated in cancer and known to induce epithelial-mesenchymal transition (EMT). This signaling depended on expression of the Rac1 splice variant, Rac1b, production of ROS, and expression of Snail. Under all conditions, cells cultured on soft substrata maintained a low frequency of multinucleation. Multinucleation on stiff substrata primarily resulted from midbody abscission failure. A soft microenvironment protected the stability of the genome in epithelial cells by preventing midbody stability, which depended on septin 4, a novel target of Snail. Importantly, we found that transforming growth factor-β (TGFβ), another EMT-inducer, also caused multinucleation downstream of Snail, which was prevented by culture on soft substrata. Our data thus suggest that tissue stiffening during tumorigenesis synergizes with oncogenic signaling to promote genomic abnormalities that drive cancer progression. Further, our results suggest that EMT-related signaling pathways are associated with disease progression not necessarily because they induce metastasis, but because they induce genomic instability. Note: This abstract was not presented at the meeting. Citation Format: Allison K. Simi, Alisya A. Anlas, Sherry X. Zhang, Tiffaney Hsia, Derek C. Radisky, Celeste M. Nelson. A soft microenvironment protects from failure of midbody abscission and multinucleation downstream of EMT initiators [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 5914. doi:10.1158/1538-7445.AM2017-5914
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