. We are interested in understanding how the actin cytoskeleton maintains cell-cell adhesion and epithelial barrier function. Epithelial tissue is characterized by extensive cell-cell adhesive contacts that organize the cells into cohesive sheets or tubes that separate two different environments. E-cadherin is a cell-cell adhesion molecule necessary for the formation and maintenance of many different epithelial sheets. Cadherin mediated cell-cell adhesion is actin dependent, but we do not fully understand how actin contributes to cadherin adhesive function. The prevailing model is that actomyosin dependent tensile forces stabilize cadherin dependent cell-cell junctions, but this system by itself is not robust because small defects in adhesion would tend to propagate and expand if myosin continued to pull on a ruptured junction. Cells must have a back-up plan to maintain cell-cell adhesion and the epithelial barrier whenever adhesive junctions break. We have identified CD2AP, EVL, and CRMP1 as three factors necessary for assembling the actin cytoskeleton at cell-cell junctions. Depleting any of these factors results in a precipitous drop in the amount of junctional actin and a loss of cell-cell adhesion such that the epithelial sheet becomes perforated with holes. CD2AP, EVL, and CRMP1 all modulate actin filament (+) end polymerization in vitro, and they are all necessary for protrusive activity in migrating cells. Therefore, I hypothesize that the three factors direct actin polymerization towards junctions to prevent them from spontaneously rupturing and to quickly reseal them if the junctions should break. Consistent with our hypothesis, we have identified novel populations of actin dependent protruding microspikes and small lamellipodia that form continually at cell junctions in mature epithelial sheets that are no longer moving. Therefore, actin polymerization continues to drive protrusive activity at cell-cell borders long after the cells made contact, stopped moving, and built cell-cell adhesive junctions.
The specific aims are to 1) identify the factors necessary for generating the protrusions at cell-cell junctions and identify the underlying mechanisms, 2) test whether loss of cell-cell adhesion triggers actin assembly, and 3) determine why loss of actin polymerization at cell-cell junctions leads to disruption of E- cadherin organization and adhesive function. Results from this proposal could fundamentally alter our current view of how actin helps maintain cell-cell adhesion while providing new information as to why mutations in CD2AP lead to inherited kidney disease.
. Epithelial cells are characterized by extensive cell-cell adhesive junctions that hold the cells together in sheets or tubes that separate two compartments. In this proposal, we test the hypothesis that epithelial cells are continually pushing against one another to maintain cell-cell adhesion. Our research into this problem has already identified several proteins that, when mutated, cause common forms of human kidney disease.
Kemp Jr, James Peter; Brieher, William M (2018) The actin filament bundling protein ?-actinin-4 actually suppresses actin stress fibers by permitting actin turnover. J Biol Chem 293:14520-14533 |
Yu-Kemp, Hui-Chia; Kemp Jr, James P; Brieher, William M (2017) CRMP-1 enhances EVL-mediated actin elongation to build lamellipodia and the actin cortex. J Cell Biol 216:2463-2479 |
Yu-Kemp, Hui-Chia; Brieher, William M (2016) Collapsin Response Mediator Protein-1 Regulates Arp2/3-dependent Actin Assembly. J Biol Chem 291:658-64 |
Nadkarni, Ambika V; Brieher, William M (2014) Aip1 destabilizes cofilin-saturated actin filaments by severing and accelerating monomer dissociation from ends. Curr Biol 24:2749-57 |
Brieher, William (2013) Mechanisms of actin disassembly. Mol Biol Cell 24:2299-302 |
Tang, Vivian W; Brieher, William M (2013) FSGS3/CD2AP is a barbed-end capping protein that stabilizes actin and strengthens adherens junctions. J Cell Biol 203:815-33 |