Abstract
Caveolin-1 proteins scaffold 50-100nm large invaginations in the plasma membrane to mediate critical cellular processes. As revealed recently by cryo-electron microscopy, several caveolin-1 protomers can fold into a disk-like structure that embeds in the cytoplasmic leaflet. This 8S complex represents a basal component to drive membrane curvature via higher-order interactions. The biophysical mechanisms behind the membrane remodeling, however, have remained elusive. To address this shortcoming, we have developed a new bottom-up coarse-grained model to overcome the substantial computational limitations for this large system. During simulations with the coarse-grained model, the complexes increasingly coordinate as partially mediated by attractive electrostatic interactions between scaffolding domains. The coordination of complexes strongly correlates with membrane protrusion, as approaching complexes amplify localized stress in the exoplasmic leaflet. Thus, proximity of two CAV1-8S complexes induces dynamic curvature generation that can facilitate access for signaling partners. This mechanism is further explored in clusters of multiple CAV1-8S complexes that form large-scale membrane invaginations.