Cargando…

Dynamic and static components power unfolding in topologically closed rings of a AAA+ proteolytic machine

In the E. coli ClpXP protease, a hexameric ClpX ring couples ATP binding and hydrolysis to mechanical protein unfolding and translocation into the ClpP degradation chamber. Rigid-body packing between the small AAA+ domain of each ClpX subunit and the large AAA+ domain of its neighbor stabilizes the...

Descripción completa

Detalles Bibliográficos
Autores principales:	Glynn, Steven E., Nager, Andrew R., Baker, Tania A., Sauer, Robert T.
Formato:	Online Artículo Texto
Lenguaje:	English
Publicado:	2012
Materias:	Article
Acceso en línea:	https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3372766/ https://www.ncbi.nlm.nih.gov/pubmed/22562135 http://dx.doi.org/10.1038/nsmb.2288

Ejemplares similares

Coordinated gripping of substrate by subunits of a AAA+ proteolytic machine
por: Iosefson, Ohad, et al.
Publicado: (2015)

Mechanochemical basis of protein degradation by a double-ring AAA+ machine
por: Olivares, Adrian O., et al.
Publicado: (2014)

Pore loops of the AAA+ ClpX machine grip substrates to drive translocation and unfolding
por: Martin, Andreas, et al.
Publicado: (2008)

AAA+ protease-adaptor structures reveal altered conformations and ring specialization
por: Kim, Sora, et al.
Publicado: (2022)

Interactions between a subset of substrate side chains and AAA+ motor pore loops determine grip during protein unfolding
por: Bell, Tristan A, et al.
Publicado: (2019)

Subunit asymmetry and roles of conformational switching in the hexameric AAA+ ring of ClpX
por: Stinson, Benjamin M., et al.
Publicado: (2015)

Modular and coordinated activity of AAA+ active sites in the double-ring ClpA unfoldase of the ClpAP protease
por: Zuromski, Kristin L., et al.
Publicado: (2020)

Structure of a AAA+ unfoldase in the process of unfolding substrate
por: Ripstein, Zev A, et al.
Publicado: (2017)

Division of labor between the pore-1 loops of the D1 and D2 AAA+ rings coordinates substrate selectivity of the ClpAP protease
por: Zuromski, Kristin L., et al.
Publicado: (2021)

A closed translocation channel in the substrate-free AAA+ ClpXP protease diminishes rogue degradation
por: Ghanbarpour, Alireza, et al.
Publicado: (2023)

Aaa Proteins: Lords of the Ring
por: Vale, Ronald D.
Publicado: (2000)

Structures of the ATP-fueled ClpXP proteolytic machine bound to protein substrate
por: Fei, Xue, et al.
Publicado: (2020)

Multifunctional Mitochondrial AAA Proteases
por: Glynn, Steven E.
Publicado: (2017)

Heat activates the AAA+ HslUV protease by melting an axial autoinhibitory plug
por: Baytshtok, Vladimir, et al.
Publicado: (2021)

The peroxisomal AAA-ATPase Pex1/Pex6 unfolds substrates by processive threading
por: Gardner, Brooke M., et al.
Publicado: (2018)

AAA+ Machines of Protein Destruction in Mycobacteria
por: Alhuwaider, Adnan Ali H., et al.
Publicado: (2017)

AAA+ Ring and Linker Swing Mechanism in the Dynein Motor
por: Roberts, Anthony J., et al.
Publicado: (2009)

The SspB adaptor drives structural changes in the AAA+ ClpXP protease during ssrA-tagged substrate delivery
por: Ghanbarpour, Alireza, et al.
Publicado: (2023)

Topologically knotted deubiquitinases exhibit unprecedented mechanostability to withstand the proteolysis by an AAA+ protease
por: Sriramoju, Manoj Kumar, et al.
Publicado: (2018)

Lon degrades stable substrates slowly but with enhanced processivity, redefining the attributes of a successful AAA+ protease
por: Kasal, Meghann R., et al.
Publicado: (2023)

The power of AAA-ATPases on the road of pre-60S ribosome maturation — Molecular machines that strip pre-ribosomal particles()
por: Kressler, Dieter, et al.
Publicado: (2012)

The catalytic power of magnesium chelatase: a benchmark for the AAA (+) ATPases
por: Adams, Nathan B. P., et al.
Publicado: (2016)

Ubiquitin-directed AAA+ ATPase p97/VCP unfolds stable proteins crosslinked to DNA for proteolysis by SPRTN
por: Kröning, Alexander, et al.
Publicado: (2022)

Structural basis of ClpXP recognition and unfolding of ssrA-tagged substrates
por: Fei, Xue, et al.
Publicado: (2020)

Engineered AAA+ proteases reveal principles of proteolysis at the mitochondrial inner membrane
por: Shi, Hui, et al.
Publicado: (2016)

Inter-ring rotations of AAA ATPase p97 revealed by electron cryomicroscopy
por: Yeung, Heidi O., et al.
Publicado: (2014)

Structural Elements Regulating AAA+ Protein Quality Control Machines
por: Chang, Chiung-Wen, et al.
Publicado: (2017)

The Diverse AAA+ Machines that Repair Inhibited Rubisco Active Sites
por: Mueller-Cajar, Oliver
Publicado: (2017)

Topological rings
por: Warner, S
Publicado: (1993)

Molecular basis for ATPase-powered substrate translocation by the Lon AAA+ protease
por: Li, Shanshan, et al.
Publicado: (2021)

CERN power converter requirements and topologies for the LEP machine
por: Isch, Hans W, et al.
Publicado: (1983)

The LHC at the AAAS
por: CERN Bulletin
Publicado: (2011)

Screening of AAA
por: Aluigi, L
Publicado: (2010)

Topologies on closed and closed convex sets
por: Beer, Gerald
Publicado: (1993)

The static potential of closed bosonic membranes
por: Floratos, Emmanuel G, et al.
Publicado: (1989)

Non-Hermitian topology in static mechanical metamaterials
por: Wang, Aoxi, et al.
Publicado: (2023)

A scheme for forming high power ion rings in combined static and pulsed magnetic fields
por: Alexakhin, V Yu
Publicado: (1988)

AAA-ATPase valosin-containing protein binds the transcription factor SREBP1 and promotes its proteolytic activation by rhomboid protease RHBDL4
por: Shibuya, Koji, et al.
Publicado: (2022)

Closing the ring /
por: Churchill, Winston, 1874-1965
Publicado: (1962)

Proteolytic regulation of mitochondrial oxidative phosphorylation components in plants
por: Ghifari, Abi S., et al.
Publicado: (2022)

Cannot write session to /tmp/vufind_sessions/sess_flp0j4gi6hqse1sa7bijgrk59r