@article {696, title = {A 3D tension bioreactor platform to study the interplay between ECM stiffness and tumor phenotype.}, journal = {J Biotechnol}, volume = {193}, year = {2015}, month = {2015 Jan 10}, pages = {66-9}, abstract = {

Extracellular matrix (ECM) structure, composition, and stiffness have profound effects on tissue development and pathologies such as cardiovascular disease and cancer. Accordingly, a variety of synthetic hydrogel systems have been designed to study the impact of ECM composition, density, mechanics, and topography on cell and tissue phenotype. However, these synthetic systems fail to accurately recapitulate the biological properties and structure of the native tissue ECM. Natural three dimensional (3D) ECM hydrogels, such as collagen or hyaluronic acid, feature many of the chemical and physical properties of tissue, yet, these systems have limitations including the inability to independently control biophysical properties such as stiffness and pore size. Here, we present a 3D tension bioreactor system that permits precise mechanical tuning of collagen hydrogel stiffness, while maintaining consistent composition and pore size. We achieve this by mechanically loading collagen hydrogels covalently-conjugated to a polydimethylsiloxane (PDMS) membrane to induce hydrogel stiffening. We validated the biological application of this system with oncogenically transformed mammary epithelial cell organoids embedded in a 3D collagen I hydrogel, either uniformly stiffened or calibrated to create a gradient of ECM stiffening, to visually demonstrate the impact of ECM stiffening on transformation and tumor cell invasion. As such, this bioreactor presents the first tunable 3D natural hydrogel system that is capable of independently assessing the role of ECM stiffness on tissue phenotype.

}, issn = {1873-4863}, doi = {10.1016/j.jbiotec.2014.11.008}, author = {Cassereau, Luke and Miroshnikova, Yekaterina A and Ou, Guanqing and Lakins, Johnathon and Weaver, Valerie M} } @article {671, title = {The cancer glycocalyx mechanically primes integrin-mediated growth and survival.}, journal = {Nature}, volume = {511}, year = {2014}, month = {2014 Jul 17}, pages = {319-25}, abstract = {

Malignancy is associated with altered expression of glycans and glycoproteins that contribute to the cellular glycocalyx. We constructed a glycoprotein expression signature, which revealed that metastatic tumours upregulate expression of bulky glycoproteins. A computational model predicted that these glycoproteins would influence transmembrane receptor spatial organization and function. We tested this prediction by investigating whether bulky glycoproteins in the glycocalyx promote a tumour phenotype in human cells by increasing integrin adhesion and signalling. Our data revealed that a bulky glycocalyx facilitates integrin clustering by funnelling active integrins into adhesions and altering integrin state by applying tension to matrix-bound integrins, independent of actomyosin contractility. Expression of large tumour-associated glycoproteins in non-transformed mammary cells promoted focal adhesion assembly and facilitated integrin-dependent growth factor signalling to support cell growth and survival. Clinical studies revealed that large glycoproteins are abundantly expressed on circulating tumour cells from patients with advanced disease. Thus, a bulky glycocalyx is a feature of tumour cells that could foster metastasis by mechanically enhancing cell-surface receptor function.

}, keywords = {Animals, Breast, Cell Line, Tumor, Cell Proliferation, Cell Survival, Fibroblasts, Glycocalyx, Glycoproteins, Humans, Immobilized Proteins, Integrins, Mice, Molecular Targeted Therapy, Mucin-1, Neoplasm Metastasis, Neoplasms, Neoplastic Cells, Circulating, Protein Binding, Receptors, Cell Surface}, issn = {1476-4687}, doi = {10.1038/nature13535}, author = {Paszek, Matthew J and DuFort, Christopher C and Rossier, Olivier and Bainer, Russell and Mouw, Janna K and Godula, Kamil and Hudak, Jason E and Lakins, Jonathon N and Wijekoon, Amanda C and Cassereau, Luke and Rubashkin, Matthew G and Magbanua, Mark J and Thorn, Kurt S and Davidson, Michael W and Rugo, Hope S and Park, John W and Hammer, Daniel A and Giannone, Gr{\'e}gory and Bertozzi, Carolyn R and Weaver, Valerie M} } @article {641, title = {Force engages vinculin and promotes tumor progression by enhancing PI3K activation of phosphatidylinositol (3,4,5)-triphosphate.}, journal = {Cancer Res}, volume = {74}, year = {2014}, month = {2014 Sep 1}, pages = {4597-611}, abstract = {

Extracellular matrix (ECM) stiffness induces focal adhesion assembly to drive malignant transformation and tumor metastasis. Nevertheless, how force alters focal adhesions to promote tumor progression remains unclear. Here, we explored the role of the focal adhesion protein vinculin, a force-activated mechanotransducer, in mammary epithelial tissue transformation and invasion. We found that ECM stiffness stabilizes the assembly of a vinculin-talin-actin scaffolding complex that facilitates PI3K-mediated phosphatidylinositol (3,4,5)-triphosphate phosphorylation. Using defined two- and three-dimensional matrices, a mouse model of mammary tumorigenesis with vinculin mutants, and a novel super resolution imaging approach, we established that ECM stiffness, per se, promotes the malignant progression of a mammary epithelium by activating and stabilizing vinculin and enhancing Akt signaling at focal adhesions. Our studies also revealed that vinculin strongly colocalizes with activated Akt at the invasive border of human breast tumors, where the ECM is stiffest, and we detected elevated mechanosignaling. Thus, ECM stiffness could induce tumor progression by promoting the assembly of signaling scaffolds, a conclusion underscored by the significant association we observed between highly expressed focal adhesion plaque proteins and malignant transformation across multiple types of solid cancer. See all articles in this Cancer Research section, "Physics in Cancer Research."

}, issn = {1538-7445}, doi = {10.1158/0008-5472.CAN-13-3698}, author = {Rubashkin, Matthew G and Cassereau, Luke and Bainer, Russell and DuFort, Christopher C and Yui, Yoshihiro and Ou, Guanqing and Paszek, Matthew J and Davidson, Michael W and Chen, Yunn-Yi and Weaver, Valerie M} } @article {241, title = {Rapid disorganization of mechanically interacting systems of mammary acini.}, journal = {Proc Natl Acad Sci U S A}, volume = {111}, year = {2014}, month = {2014 Jan 14}, pages = {658-63}, abstract = {

Cells and multicellular structures can mechanically align and concentrate fibers in their ECM environment and can sense and respond to mechanical cues by differentiating, branching, or disorganizing. Here we show that mammary acini with compromised structural integrity can interconnect by forming long collagen lines. These collagen lines then coordinate and accelerate transition to an invasive phenotype. Interacting acini begin to disorganize within 12.5 \± 4.7 h in a spatially coordinated manner, whereas acini that do not interact mechanically with other acini disorganize more slowly (in 21.8 \± 4.1 h) and to a lesser extent (P \< 0.0001). When the directed mechanical connections between acini were cut with a laser, the acini reverted to a slowly disorganizing phenotype. When acini were fully mechanically isolated from other acini and also from the bulk gel by box-cuts with a side length \<900 μm, transition to an invasive phenotype was blocked in 20 of 20 experiments, regardless of waiting time. Thus, pairs or groups of mammary acini can interact mechanically over long distances through the collagen matrix, and these directed mechanical interactions facilitate transition to an invasive phenotype.

}, keywords = {Acinar Cells, Breast Neoplasms, Cell Communication, Cell Line, Tumor, Cell Separation, Collagen, Escherichia coli, Female, Humans, Kaplan-Meier Estimate, Mammary Glands, Human, Microscopy, Atomic Force, Microscopy, Electron, Scanning, Microscopy, Fluorescence}, issn = {1091-6490}, doi = {10.1073/pnas.1311312110}, author = {Shi, Quanming and Ghosh, Rajarshi P and Engelke, Hanna and Rycroft, Chris H and Cassereau, Luke and Sethian, James A and Weaver, Valerie M and Liphardt, Jan T} } @article {286, title = {Morphogenesis: Laying down the tracks.}, journal = {Nat Mater}, volume = {11}, year = {2012}, month = {2012 Jun}, pages = {490-2}, keywords = {Cell Movement, Collagen, Epithelium, Extracellular Matrix, Feedback, Morphogenesis}, issn = {1476-1122}, doi = {10.1038/nmat3345}, author = {Cassereau, Luke and DuFort, Christopher C and Weaver, Valerie M} }