ABSTRACT The ability of proteins to sense membrane curvature is essential to diverse membrane remodeling processes including clathrin-mediated endocytosis. Multiple adaptor proteins within the clathrin pathway have been shown to assemble together at curved membrane sites, leading to local recruitment of the clathrin coat. Because clathrin does not bind to the membrane directly, it has remained unclear whether clathrin plays an active role in sensing curvature or is passively recruited by its adaptor proteins. Using a synthetic tag to assemble clathrin directly on membrane surfaces, here we show that clathrin is a strong sensor of membrane curvature, comparable to previously studied adaptor proteins. Interestingly, this sensitivity arises from clathrin assembly, rather than from the properties of unassembled triskelia, suggesting that triskelia have preferred angles of interaction, as predicted by earlier structural data. Further, when clathrin is recruited by adaptors, its curvature sensitivity is amplified by two to ten-fold, such that the resulting protein complex is up to 100 times more likely to assemble on a highly curved surface, compared to a flatter one. This exquisite sensitivity points to a synergistic relationship between the coat and its adaptor proteins, which enables clathrin to pinpoint sites of high membrane curvature, an essential step in ensuring robust membrane traffic. More broadly, these findings suggest that protein networks, rather than individual protein domains, are likely the critical drivers of membrane curvature sensing.