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Пишет bioRxiv Subject Collection: Neuroscience (![[info]](http://lj.rossia.org/img/syndicated.gif){kind=small} syn_bx_neuro)@ 2025-04-29 15:50:00 |
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Shape-Shifting Conotoxins Reveal Divergent Pore-Targeting Mechanisms in Nicotinic Receptors
The neuronal 7 nicotinic acetylcholine receptor (7-nAChR) and muscle-type nicotinic acetylcholine receptor (mt-nAChR) are pivotal in synaptic signaling within the brain and the neuromuscular junction respectively. Additionally, they are both targets of a wide range of drugs and toxins. Here, we utilize cryoEM to delineate structures of these nAChRs in complex with the conotoxins ImI and ImII from Conus imperialis. Despite nominal sequence divergence, ImI and ImII exhibit discrete binding preferences and adopt drastically different conformational states upon binding. ImI engages the orthosteric sites of the 7-nAChR, while ImII forms distinct pore-bound complexes with both the 7-nAChR and mt-nAChR. Strikingly, ImII adopts a compact globular conformation that binds as a monomer to the 7-nAChR pore and as an oblate dimer to the mt-nAChR pore. These structural characterizations advance our understanding of nAChR-ligand interactions as well as the subtle sequence variations that result in dramatically altered functional outcomes in small peptide toxins. Importantly, these results further elucidate the broad nature of cone snail toxin activities and highlight how targeted molecular evolution can give rise to functionally similar activities with surprisingly diverse mechanisms of action.
The neuronal 7 nicotinic acetylcholine receptor (7-nAChR) and muscle-type nicotinic acetylcholine receptor (mt-nAChR) are pivotal in synaptic signaling within the brain and the neuromuscular junction respectively. Additionally, they are both targets of a wide range of drugs and toxins. Here, we utilize cryoEM to delineate structures of these nAChRs in complex with the conotoxins ImI and ImII from Conus imperialis. Despite nominal sequence divergence, ImI and ImII exhibit discrete binding preferences and adopt drastically different conformational states upon binding. ImI engages the orthosteric sites of the 7-nAChR, while ImII forms distinct pore-bound complexes with both the 7-nAChR and mt-nAChR. Strikingly, ImII adopts a compact globular conformation that binds as a monomer to the 7-nAChR pore and as an oblate dimer to the mt-nAChR pore. These structural characterizations advance our understanding of nAChR-ligand interactions as well as the subtle sequence variations that result in dramatically altered functional outcomes in small peptide toxins. Importantly, these results further elucidate the broad nature of cone snail toxin activities and highlight how targeted molecular evolution can give rise to functionally similar activities with surprisingly diverse mechanisms of action.
