Getting Ahead of the Curve: How Cells Generate, Maintain, and use Geometry

Cell shape is critical to cellular function — this is a widely acknowledged fact. But how can we characterize the different aspects of cell shape? Local changes to cell shape are characterized by changes to the membrane curvature both at the plasma membrane and within organelle membranes. One of the open challenges in understanding how cell shape couples cellular function is the dynamic nature of the coupling between membrane curvature, biochemical signal transduction, and the actin cytoskeleton remodeling.

In this talk, I will describe my lab’s efforts to study how cells generate, maintain, and utilize curvature by discussing three different projects. Common to all these projects is the idea of coupling membrane mechanics, signaling, and generating experimentally testable hypotheses.

How is curvature generated? In clathrin-mediated endocytosis (CME), clathrin and various adaptor proteins coat a patch of the plasma membrane, which is reshaped to form a budded vesicle. Experimental studies have demonstrated that elevated membrane tension can inhibit bud formation by a clathrin coat. I will first discuss recent results that show that membrane tension can be heterogeneous along the surface of the membrane and depend on protein concentration. Then I will discuss the mechanics of membrane budding across a range of membrane tensions by simulating clathrin coats that either grow in area or progressively induce greater curvature. I will also discuss how curvature is maintained by protein-distribution along the necks of budding vesicles.

How does curvature regulate signaling? Previously, we showed that cell shape regulates the spatiotemporal temporal dynamics of MAPK activation, as a function of local curvature-induced receptor densities. We now extend this work to show how cell shape changes organelle location and the impact of organelle location on signaling in dendritic spines.