@article {361, title = {Integrin clustering is driven by mechanical resistance from the glycocalyx and the substrate.}, journal = {PLoS Comput Biol}, volume = {5}, year = {2009}, month = {2009 Dec}, pages = {e1000604}, abstract = {

Integrins have emerged as key sensory molecules that translate chemical and physical cues from the extracellular matrix (ECM) into biochemical signals that regulate cell behavior. Integrins function by clustering into adhesion plaques, but the molecular mechanisms that drive integrin clustering in response to interaction with the ECM remain unclear. To explore how deformations in the cell-ECM interface influence integrin clustering, we developed a spatial-temporal simulation that integrates the micro-mechanics of the cell, glycocalyx, and ECM with a simple chemical model of integrin activation and ligand interaction. Due to mechanical coupling, we find that integrin-ligand interactions are highly cooperative, and this cooperativity is sufficient to drive integrin clustering even in the absence of cytoskeletal crosslinking or homotypic integrin-integrin interactions. The glycocalyx largely mediates this cooperativity and hence may be a key regulator of integrin function. Remarkably, integrin clustering in the model is naturally responsive to the chemical and physical properties of the ECM, including ligand density, matrix rigidity, and the chemical affinity of ligand for receptor. Consistent with experimental observations, we find that integrin clustering is robust on rigid substrates with high ligand density, but is impaired on substrates that are highly compliant or have low ligand density. We thus demonstrate how integrins themselves could function as sensory molecules that begin sensing matrix properties even before large multi-molecular adhesion complexes are assembled.

}, keywords = {Algorithms, Computer Simulation, Extracellular Matrix, Glycocalyx, Integrins, Ligands, Protein Binding, Stress, Physiological, Substrate Specificity}, issn = {1553-7358}, doi = {10.1371/journal.pcbi.1000604}, author = {Paszek, Matthew J and Boettiger, David and Weaver, Valerie M and Hammer, Daniel A} } @article {416, title = {alpha6beta4 integrin activates Rac-dependent p21-activated kinase 1 to drive NF-kappaB-dependent resistance to apoptosis in 3D mammary acini.}, journal = {J Cell Sci}, volume = {120}, year = {2007}, month = {2007 Oct 15}, pages = {3700-12}, abstract = {

Malignant transformation and multidrug resistance are linked to resistance to apoptosis, yet the molecular mechanisms that mediate tumor survival remain poorly understood. Because the stroma can influence tumor behavior by regulating the tissue phenotype, we explored the role of extracellular matrix signaling and tissue organization in epithelial survival. We report that elevated (alpha6)beta4 integrin-dependent Rac-Pak1 signaling supports resistance to apoptosis in mammary acini by permitting stress-dependent activation of the p65 subunit of NF-kappaB through Pak1. We found that inhibiting Pak1 through expression of N17Rac or PID compromises NF-kappaB activation and renders mammary acini sensitive to death, but that resistance to apoptosis could be restored to these structures by overexpressing wild-type NF-kappaB p65. We also observed that acini expressing elevated levels of Pak1 can activate p65 and survive death treatments, even in the absence of activated Rac, yet will die if activation of NF-kappaB is simultaneously inhibited through expression of IkappaBalphaM. Thus, mammary tissues can resist apoptotic stimuli by activating NF-kappaB through alpha6beta4 integrin-dependent Rac-Pak1 signaling. Our data emphasize the importance of the extracellular matrix stroma in tissue survival and suggest that alpha6beta4 integrin-dependent Rac stimulation of Pak1 could be an important mechanism mediating apoptosis-resistance in some breast tumors.

}, keywords = {Apoptosis, Enzyme Activation, Humans, Integrin alpha6beta4, Mammary Glands, Human, p21-Activated Kinases, Proto-Oncogene Proteins c-akt, rac GTP-Binding Proteins, Transcription Factor RelA}, issn = {0021-9533}, doi = {10.1242/jcs.03484}, author = {Friedland, Julie C and Lakins, Johnathon N and Kazanietz, Marcelo G and Chernoff, Jonathan and Boettiger, David and Weaver, Valerie M} } @article {421, title = {Tensional homeostasis and the malignant phenotype.}, journal = {Cancer Cell}, volume = {8}, year = {2005}, month = {2005 Sep}, pages = {241-54}, abstract = {

Tumors are stiffer than normal tissue, and tumors have altered integrins. Because integrins are mechanotransducers that regulate cell fate, we asked whether tissue stiffness could promote malignant behavior by modulating integrins. We found that tumors are rigid because they have a stiff stroma and elevated Rho-dependent cytoskeletal tension that drives focal adhesions, disrupts adherens junctions, perturbs tissue polarity, enhances growth, and hinders lumen formation. Matrix stiffness perturbs epithelial morphogenesis by clustering integrins to enhance ERK activation and increase ROCK-generated contractility and focal adhesions. Contractile, EGF-transformed epithelia with elevated ERK and Rho activity could be phenotypically reverted to tissues lacking focal adhesions if Rho-generated contractility or ERK activity was decreased. Thus, ERK and Rho constitute part of an integrated mechanoregulatory circuit linking matrix stiffness to cytoskeletal tension through integrins to regulate tissue phenotype.

}, keywords = {3T3 Cells, Animals, Cell Line, Tumor, Cell Shape, Cytoskeleton, Homeostasis, Mice, Neoplasms, Phenotype, Stress, Mechanical, Stromal Cells}, issn = {1535-6108}, doi = {10.1016/j.ccr.2005.08.010}, author = {Paszek, Matthew J and Zahir, Nastaran and Johnson, Kandice R and Lakins, Johnathon N and Rozenberg, Gabriela I and Gefen, Amit and Reinhart-King, Cynthia A and Margulies, Susan S and Dembo, Micah and Boettiger, David and Hammer, Daniel A and Weaver, Valerie M} }