Migration regulates cellular mechanical states

Recent studies indicate that adherent cells are keenly sensitive to external physical environment, such as substrate rigidity and topography, and internal physical states, such as cell shape and spreading area. Many of these responses are believed to involve coupled output and input of mechanical forces, which may constitute the key sensing mechanism to generate downstream regulatory signals for cell growth and differentiation. Here, we show that the state of cell migration also plays a regulatory role. Compared with migrating cells, stationary cells generate stronger, less dynamic, and more peripherally localized traction forces. These changes are coupled to reduced focal adhesion turnover and enhanced paxillin phosphorylation. Further, using cells migrating along checkerboard micropatterns, we show that the appearance of new focal adhesions directly in front of existing focal adhesions is associated with the down-regulation of existing focal adhesions and associated traction forces. Together, our results imply a mechanism where cell migration regulates traction forces by promoting dynamic turnover of focal adhesions, which may then regulate processes such as wound healing and embryogenesis where cell differentiation must coordinate with migration state and proper localization.

A synthetic hydrogel for the high-throughput study of cell-ECM interactions

It remains extremely challenging to dissect the cooperative influence of multiple extracellular matrix (ECM) parameters on cell behaviour. This stems in part from a lack of easily deployable strategies for the combinatorial variation of matrix biochemical and biophysical properties. Here we describe a simple, high-throughput platform based on light-modulated hyaluronic acid hydrogels that enables imposition of mutually independent and spatially continuous gradients of ligand density and substrate stiffness. We validate this system by showing that it can support mechanosensitive differentiation of mesenchymal stem cells. We also use it to show that the oncogenic microRNA, miR18a, is nonlinearly regulated by matrix stiffness and fibronectin density in glioma cells. The parallelization of experiments enabled by this platform allows condensation of studies that would normally require hundreds of independent hydrogels to a single substrate. This system is a highly accessible, high-throughput technique to study the combinatorial variation of biophysical and biochemical signals in a single experimental paradigm.

Multiple extracellular matrix parameters influence cellular behaviour, but it is difficult to dissect their cooperative contributions. Here the authors describe a hydrogel system in which ligand density and substrate stiffness can be tuned orthogonally to study the contribution of combinations of these parameters simultaneously.

A composite hydrogel platform for the dissection of tumor cell migration at tissue interfaces

Glioblastoma multiforme (GBM), the most prevalent primary brain cancer, is characterized by diffuse infiltration of tumor cells into brain tissue, which severely complicates surgical resection and contributes to tumor recurrence. The most rapid mode of tissue infiltration occurs along blood vessels or white matter tracts, which represent topological interfaces thought to serve as "tracks" that speed cell migration. Despite this observation, the field lacks experimental paradigms that capture key features of these tissue interfaces and allow reductionist dissection of mechanisms of this interfacial motility. To address this need, we developed a culture system in which tumor cells are sandwiched between a fibronectin-coated ventral surface representing vascular basement membrane and a dorsal hyaluronic acid (HA) surface representing brain parenchyma. We find that inclusion of the dorsal HA surface induces formation of adhesive complexes and significantly slows cell migration relative to a free fibronectin-coated surface. This retardation is amplified by inclusion of integrin binding peptides in the dorsal layer and expression of CD44, suggesting that the dorsal surface slows migration through biochemically specific mechanisms rather than simple steric hindrance. Moreover, both the reduction in migration speed and assembly of dorsal adhesions depend on myosin activation and the stiffness of the ventral layer, implying that mechanochemical feedback directed by the ventral layer can influence adhesive signaling at the dorsal surface.

Altered cell mechanics from the inside: dispersed single wall carbon nanotubes integrate with and restructure actin

With a range of desirable mechanical and optical properties, single wall carbon nanotubes (SWCNTs) are a promising material for nanobiotechnologies. SWCNTs also have potential as biomaterials for modulation of cellular structures. Previously, we showed that highly purified, dispersed SWCNTs grossly alter F-actin inside cells. F-actin plays critical roles in the maintenance of cell structure, force transduction, transport and cytokinesis. Thus, quantification of SWCNT-actin interactions ranging from molecular, sub-cellular and cellular levels with both structure and function is critical for developing SWCNT-based biotechnologies. Further, this interaction can be exploited, using SWCNTs as a unique actin-altering material. Here, we utilized molecular dynamics simulations to explore the interactions of SWCNTs with actin filaments. Fluorescence lifetime imaging microscopy confirmed that SWCNTs were located within ~5 nm of F-actin in cells but did not interact with G-actin. SWCNTs did not alter myosin II sub-cellular localization, and SWCNT treatment in cells led to significantly shorter actin filaments. Functionally, cells with internalized SWCNTs had greatly reduced cell traction force. Combined, these results demonstrate direct, specific SWCNT alteration of F-actin structures which can be exploited for SWCNT-based biotechnologies and utilized as a new method to probe fundamental actin-related cellular processes and biophysics.

Carbon nanotubes reorganize actin structures in cells and ex vivo

The ability of globular actin to form filaments and higher-order network structures of the cytoskeleton is essential for cells to maintain their shape and perform essential functions such as force generation, motility, and division. Alterations of actin structures can dramatically change a cell's ability to function. We found that purified and dispersed single wall carbon nanotubes (SWCNTs) can induce actin bundling in cells and in purified model actin systems. SWCNTs do not induce acute cell death, but cell proliferation is greatly reduced in SWCNT-treated cells with an increase in actin-related division defects. Actin, normally present in basal stress fibers in control cells, is located in heterogeneous structures throughout the SWCNT-treated cell. These SWCNT-induced changes in actin structures are seen functionally in multinucleated cells and with reduced force generation. Ex vivo, purified actin filaments cross-linked with alpha-actinin and formed isotropic networks, whereas SWCNTs caused purified actin filaments to assemble into bundles. While purified, isolated SWCNTs do not appear acutely toxic, this subcellular reorganization may cause chronic changes to cellular functions.