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New Mounting experimental evidences suggest that cells can sense and respond to mechanical cues (i.e. substrate stiffness) and geometric cues in 2D and 3D culture models. Hence, engineered mechanical microenvironment can enable new in vitro mechano-biology studies, which are otherwise complicated to realize. In the first part of my presentation, I will talk about a novel approach to micropattern extracellular matrix (ECM) proteins on 2D polyacrylamide (PA) hydrogels and consequently obtain spatially defined cell culture with precision . This method provides an excellent and robust tool to study the coupled effect of mechanical cues and geometric cues on 2D polyacrylamide hydrogels.
In the second part, I will discuss on the in-vitro metastasis of human colon carcinoma cells driven solely by the elasticity of the substrate . In the work, our group has shown that human colon carcinoma (HCT-8) cells can exhibit a dissociative, metastasis-like phenotype (MLP) in vitro when cultured on ECM coated substrates with appropriate mechanical stiffness (physio-logically relevant 21–47 kPa), but not on very soft (1 kPa) and very stiff (3.6 GPa) substrates . However, the role of cell-ECM adhesions (integrins) or cell-cell adhesions (E-cadherin) in the mechanosensing process remain elusive. Hence, we cultured the HCT-8 cells on E-cadherin coated soft substrates of appropriate mechanical stiffness (21 kPa) to mimic cell-cell interactions. Interestingly, HCT-8 cells show the distinct dissociative phenotype on E-cadherin coated substrates as well. These results suggest that the E-cadherin, but not the integrins, is the dominant mechanosensor for the MLP on soft substrates. The inhibition of the MLP on E-cadherin coated substrates by blebbistatin, a potent inhibitor of non-muscle myosin II ATPase, indicates that the intracellular forces are involved in the initiation of the MLP. In addition, the actin cytoskeletal structure and nuclei deformation on both fibronectin (ECM) and E-cadherin coated substrates are also investigated before and after the MLP using laser scanning confocal microscopy .
 Tang, X.; Ali, M. Y.; Saif, T. A Novel Technique for Micro-patterning Proteins and Cells on Polyacrylamide Gels. Soft Matter 2012 (under review).
 Tang, X., Kuhlenschmidt, T.B., Zhou, J., Bell, P., Wang, F., Kuhlenschmidt, M. S., Saif, T. A. Mechanical Force Affects Expression of an In Vitro Metastasis-Like Phenotype in HCT- 8 Cells. Biophysical Journal 2010; 99:2460-9.  Ali, M. Y.; Saif, T. On the Mechanosensing of Human Colon Carcinonoma Cells on E-Cadherin Coated Soft Substrates (in preparation).
 Ali, M. Y.; Saif, T. On the Mechanosensing of Human Colon Carcinonoma Cells on E-Cadherin Coated Soft Substrates (in preparation).
M. Yakut Ali is a Ph.D. student at Mechanical Science and Engineering department, UIUC under the supervision of Prof. Taher Saif. Earlier, he received his M.S. degree from University of South Carolina, Columbia, SC in 2010 and B.S. from Bangladesh University of Engineering and Technology in 2007, both in Mechanical engineering. His current research interest is in the area of Cell Mechanics. More specifically, he is interested to investigate the effect of mechanical stimuli in mechanics of cancer cells and other types of cell models. He envisages a career in academia or in a research industry. He has co-authored 8 peer reviewed journal publications and conference proceedings.
From Ali's M-CNTC page
Researchers should cite this work as follows:
Muhammad Yakut Ali (2013), "[Illinois] BioNanotechnology Seminar Series Spring 2012: Human Colon Carcinoma Cells on Gels: Spatial Confinement and Mechanosensing," https://nanohub.org/resources/18279.
1000 MNTL, University of Illinois, Urbana-Champaign, Urbana, IL