PT - JOURNAL ARTICLE AU - Kelly, Maria S. AU - Capelli, Riccardo AU - Dima, Ruxandra I. AU - Carloni, Paolo TI - Structural and functional role of residues undergoing hereditary spastic paraplegias-linked mutations: insights from a simulation of the spiral to ring transition in katanin AID - 10.1101/2024.11.27.625675 DP - 2024 Jan 01 TA - bioRxiv PG - 2024.11.27.625675 4099 - http://biorxiv.org/content/early/2024/11/29/2024.11.27.625675.short 4100 - http://biorxiv.org/content/early/2024/11/29/2024.11.27.625675.full AB - Several dozen mutations in the large human spastin enzyme assembly have been associated with mobility impairment in hereditary spastic paraplegias. Some of them impact the structural determinants of two functional conformations of the protein, spiral and ring. Here we investigate the possible effect of the mutations on the transition between the two conformations, which is essential for the enzymatic function. By performing a variety of molecular simulations (including metadynamics) on the closely related protein katanin, we suggest that about one fourth of the known disease-associated mutations affect the transition and/or the stability of a previously unrecognized intermediate. The protocol used here can be applied to the study of conformational changes in other large biomolecular complexes.Significance Statement By combining molecular dynamics and enhanced sampling simulations with custom-designed collective variables, we explore transient intermediate states in a large protein assembly, the severing enzyme katanin. This enzyme plays a critical role in neuronal microtubule remodeling. By targeting the transition between the spiral and ring conformations of the protein, we reveal mechanisms associated with neurodegenerative mutations that impair the function of spastin, a structurally and functionally similar enzyme. These findings provide insights that may inform future therapeutic strategies. They also expand our ability to simulate molecular processes relevant to health and disease, as our approach can be readily applied to study structural changes in other complex biological systems.Competing Interest StatementThe authors have declared no competing interest.