Deep classification of a large cryo-EM dataset defines the conformational landscape of the 26S proteasome

Unverdorben, Pia; Beck, Florian; Śledź, P.; Schweitzer, A.; Pfeifer, Günter; Plitzko, Jürgen M.; Baumeister, Wolfgang; Förster, Friedrich

doi:10.1073/pnas.1403409111

Cited by 177 publications

(312 citation statements)

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“…1C), indicating less structural heterogeneity. The overall structure differs notably from the reconstruction from 26S proteasomes alone, which predominantly adopt the s1 conformation (6), and appears more similar to the s2 conformation (13). Most importantly, two extra densities in the direct vicinity of Rpn1 are clearly distinguishable.…”

Section: Dmentioning

confidence: 72%

“…Previous analysis revealed that the conformational states of the RPs at the two CP ends are not correlated (6,13,15). Therefore, the following analysis was performed using the holocomplex cut into two halves (6, 13), i.e., the two RPs of the double-capped 26S proteasomes were treated as separate particles.…”

Section: Dmentioning

confidence: 99%

“…In ATP-containing buffer, purified 26S proteasomes primarily adopt the s1 state, which is characterized by pronounced off-axis positioning of the AAAATPase hexamer with respect to the CP and a staircase arrangement of the Rpts with Rpt3 in the most elevated position (6)(7)(8)(9). Under the same conditions a minority of particles (∼20%) adopts the s2 state, in which the axis of the AAA-ATPase is positioned closer to that of the CP and the Rpns concomitantly rotate largely en bloc by ∼25° (13). As a consequence of this Rpn motion, the active site of Rpn11 becomes accessible to the polyubiquitin chain of the substrate, and the ubiquitin receptor Rpn10 is positioned closer to the AAA-ATPase module.…”

mentioning

confidence: 99%

“…At least three distinct states, which we refer to as "s1-s3," can be distinguished (13). In ATP-containing buffer, purified 26S proteasomes primarily adopt the s1 state, which is characterized by pronounced off-axis positioning of the AAAATPase hexamer with respect to the CP and a staircase arrangement of the Rpts with Rpt3 in the most elevated position (6)(7)(8)(9).…”

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confidence: 99%

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Structural characterization of the interaction of Ubp6 with the 26S proteasome

Aufderheide

Beck

Stengel

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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In eukaryotic cells, the 26S proteasome is responsible for the regulated degradation of intracellular proteins. Several cofactors interact transiently with this large macromolecular machine and modulate its function. The deubiquitylating enzyme ubiquitin C-terminal hydrolase 6 [Ubp6; ubiquitin-specific protease (USP) 14 in mammals] is the most abundant proteasome-interacting protein and has multiple roles in regulating proteasome function. Here, we investigate the structural basis of the interaction between Ubp6 and the 26S proteasome in the presence and absence of the inhibitor ubiquitin aldehyde. To this end we have used single-particle electron cryomicroscopy in combination with cross-linking and mass spectrometry. Ubp6 binds to the regulatory particle non-ATPase (Rpn) 1 via its N-terminal ubiquitin-like domain, whereas its catalytic USP domain is positioned variably. Addition of ubiquitin aldehyde stabilizes the binding of the USP domain in a position where it bridges the proteasome subunits Rpn1 and the regulatory particle triple-A ATPase (Rpt) 1. The USP domain binds to Rpt1 in the immediate vicinity of the Ubp6 active site, which may effect its activation. The catalytic triad is positioned in proximity to the mouth of the ATPase module and to the deubiquitylating enzyme Rpn11, strongly implying their functional linkage. On the proteasome side, binding of Ubp6 favors conformational switching of the 26S proteasome into an intermediateenergy conformational state, in particular upon the addition of ubiquitin aldehyde. This modulation of the conformational space of the 26S proteasome by Ubp6 explains the effects of Ubp6 on the kinetics of proteasomal degradation.conformational switching | proteolysis | proteostasis | quality control D egradation of proteins that are misfolded, damaged, or no longer needed is an essential element of cellular homeostasis. In eukaryotic cells, the ubiquitin-proteasome system (UPS) is the major pathway for regulated protein degradation (1). Proteins that are processed by the UPS are marked for destruction by polyubiquitin chains, which are recognized as a degradation signal by the 26S proteasome.The 26S proteasome consists of the core particle (CP), which degrades substrates into short peptides, and one or two 19S regulatory particles (RP), which associate with the ends of the cylinder-shaped CP to recruit substrates and prepare them for degradation (2, 3). Although the structure of the CP has been known for more than two decades (4, 5), the molecular architecture of the RP was unraveled by cryo-electron microscope (EM)-based approaches only recently (6-9). It comprises six RP triple A (AAA) ATPases (Rpt), 1-6, and 13 RP non-ATPases (Rpn), 1-3, 5-13, and 15. Similar to AAA-ATPases in prokaryotic ATP-dependent proteases, the Rpts form a hexameric ring that binds to the ends of the CP and is responsible for substrate unfolding and translocation into the CP. Unlike their prokaryotic counterparts, the Rpts are surrounded by non-ATPases. Apart from Rpn1, all Rpns form a cohesive struct...

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Section: Dmentioning

confidence: 72%

Section: Dmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Structural characterization of the interaction of Ubp6 with the 26S proteasome

Aufderheide

Beck

Stengel

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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“…[26][27][28][29][30][31][32][33][34][35] This kind of information is also crucial for modeling the drug-receptor interactions 36 or for understanding the thermodynamics and kinetics of crystal growth processes 37,38 and, consequently, the polymorphism associated with pharmaceutical compounds. 25 Yet another reason for the conformational landscape analysis of a drug molecule is that it can suffer large structural changes during its functional cycle, 39 so that the conformation of the bioactive conformer could be significantly different from those of the most stable one in a particular solvent or in gas phase. 40 The conformational landscape of LEV in water and dichloromethane was studied previously by Li and Si 40 who identified 9 conformers.…”

Section: Introductionmentioning

confidence: 99%

Conformational Preference and Spectroscopical Characteristics of the Active Pharmaceutical Ingredient Levetiracetam

Luchian

Vinţeler

Chiş

et al. 2017

Journal of Pharmaceutical Sciences

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Cryo‐electron tomography—the cell biology that came in from the cold

2017

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Edited by Wilhelm JustCryo-electron tomography (cryo-ET) provides high-resolution 3D views into cells pristinely preserved by vitrification. Recent technical advances such as direct electron detectors, the Volta phase plate and cryo-focused ion beam milling have dramatically pushed image quality and expanded the range of cryo-ET applications. Cryo-ET not only allows mapping the positions and interactions of macromolecules within their intact cellular context, but can also reveal their in situ structure at increasing resolution. Here, we review how recent work using cutting-edge cryo-ET technologies is starting to provide fresh views into different aspects of cellular biology at an unprecedented level of detail. We anticipate that these developments will soon make cryo-ET a fundamental technique in cell biology. Keywords: Cryo-EM; cryo-FIB; protein aggregationTransmission electron microscopy (TEM) is ideally suited to image biological structures at high resolution. However, water-rich biological samples need to be fixed to withstand the high vacuum of the electron microscope column. TEM preparation of cells and tissues most commonly involves chemical fixation, dehydration, resin embedding, and heavy metal staining. In contrast, cryo-electron microscopy (cryo-EM) relies on physical fixation by rapid freezing. If freezing is sufficiently quick the water molecules do not reorganize into crystals, but instead form amorphous ice. This vitrification process results in the exquisite preservation of biological material, which can be directly studied by cryo-EM [1]. Thus, cryo-EM allows high-resolution imaging of fully hydrated, unstained biological specimens.The most widespread application of cryo-EM is the study of purified macromolecules by the so-called 'single particle' approach [2]. Thousands of individual copies of the macromolecule of interest are embedded in a thin layer of vitreous ice and imaged in 2D. In principle, the macromolecules adopt random orientations within the ice, and therefore a sufficient number of images may provide all the angular views needed for high-resolution 3D reconstruction by averaging. Although such averaging procedures can only be applied to a set of near-identical objects, 3D imaging of unique biological objects such as cells can be performed by tomography. In tomography, 2D projections of the object of interest are recorded from different directions by tilting the specimen within the microscope. These projections are then computationally aligned for tilting imperfections and reconstructed into a 3D volume or 'tomogram' [3][4][5].Numerous cryo-electron tomography (cryo-ET) studies have showed the power of this technique to reveal the native architecture of labile cellular structures in situ [6][7][8][9][10][11].

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Deep classification of a large cryo-EM dataset defines the conformational landscape of the 26S proteasome

Cited by 177 publications

References 44 publications

Structural characterization of the interaction of Ubp6 with the 26S proteasome

Structural characterization of the interaction of Ubp6 with the 26S proteasome

Conformational Preference and Spectroscopical Characteristics of the Active Pharmaceutical Ingredient Levetiracetam

Cryo‐electron tomography—the cell biology that came in from the cold

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