Quantitative interaction mapping reveals an extended UBX domain in ASPL that 
disrupts functional p97 hexamers

Arumughan, Anup; Roske, Yvette; Barth, Carolin; Forero, Laura Lleras; Bravo-Rodriguez, Kenny; Redel, Alexandra; Kostova, Simona; McShane, Erik; Robert Opitz, Robert; Faelber, Katja; Rau, Kirstin; Mielke, Thorsten; Daumke, Oliver; Selbach, Matthias; Sanchez-Garcia, Elsa; Rocks, Oliver; Daniela Panáková, Daniela; Heinemann, Udo; Wanker, Erich E.

doi:10.1038/ncomms13047

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Quantitative interaction mapping reveals an extended UBX domain in ASPL that disrupts functional p97 hexamers

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Bravo-Rodriguez, Kenny
Research Group Sánchez-García, Max-Planck-Institut für Kohlenforschung, Max Planck Society;

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Sanchez-Garcia, Elsa
Research Group Sánchez-García, Max-Planck-Institut für Kohlenforschung, Max Planck Society;

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Citation

Arumughan, A., Roske, Y., Barth, C., Forero, L. L., Bravo-Rodriguez, K., Redel, A., et al. (2016). Quantitative interaction mapping reveals an extended UBX domain in ASPL that disrupts functional p97 hexamers. Nature Communications, 7: 13047/1-13. doi:10.1038/ncomms13047.

Cite as: https://hdl.handle.net/11858/00-001M-0000-002B-B049-7

Abstract

Interaction mapping is a powerful strategy to elucidate the biological function of protein assemblies and their regulators. Here, we report the generation of a quantitative interaction network, directly linking 14 human proteins to the AAA+ ATPase p97, an essential hexameric protein with multiple cellular functions. We show that the high-affinity interacting protein ASPL efficiently promotes p97 hexamer disassembly, resulting in the formation of stable p97:ASPL heterotetramers. High-resolution structural and biochemical studies indicate that an extended UBX domain (eUBX) in ASPL is critical for p97 hexamer disassembly and facilitates the assembly of p97:ASPL heterotetramers. This spontaneous process is accompanied by a reorientation of the D2 ATPase domain in p97 and a loss of its activity. Finally, we demonstrate that overproduction of ASPL disrupts p97 hexamer function in ERAD and that engineered eUBX polypeptides can induce cell death, providing a rationale for developing anti-cancer polypeptide inhibitors that may target p97 activity.