High-affinity nanobodies as tools for structural and functional studies on mammalian Arc

Activity-regulated cytoskeleton-associated protein (Arc) is a multidomain protein of retroviral origin with a vital role in the regulation of synaptic plasticity and memory formation in mammals. However, the mechanistic and structural basis of Arc function is little understood. Arc has an NTD involved in membrane binding and a CTD which binds postsynaptic protein ligands. In addition, the NTD and CTD both function in Arc oligomerization, including assembly of retrovirus-like capsid involved in intercellular signaling. We produced and characterised six ultra-high-affinity anti-Arc nanobodies (Nb). The CTD of both rat and human Arc could be crystallised in ternary complexes with two Nbs simultaneously bound (H11 and C11). H11 binding deep into the stargazing-binding pocket of Arc CTD suggested competitive binding with Arc ligand peptides, which was confirmed in vitro. This indicates that the H11 Nb could serve as a genetically-encoded tool for inhibition of endogenous Arc N-lobe interactions in study of neuronal function and plasticity. The crystallisation of the human Arc CTD in two different conformations, accompanied by SAXS data and molecular dynamics simulations, paints a dynamic picture of the mammalian Arc CTD. Dynamics were affected by mutations known to inhibit capsid formation, implying a role for Arc CTD dynamics in oligomerisation. Dimerisation of the NTD, together with structural dynamics of the CTD, suggest a mechanism, by which structural dynamics of the CTD may promote capsomer formation, and dimerisation of the NTD links capsomers, facilitating the formation of capsids. The described recombinant ultrahigh-affinity anti-Arc Nbs are versatile tools that can be further developed for studying mammalian Arc structure and function in vitro and in vivo.