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Cryo-electron tomography combined with subtomogram averaging (StA) has yielded high-resolution structures of macromolecules in their native context. However, high-resolution StA is not commonplace due to beam-induced sample drift, images with poor signal-to-noise ratios (SNR), challenges in CTF correction, and limited particle number. Here we address these issues by collecting tilt series with a higher electron dose at the zero-degree tilt. Particles of interest are then located within reconstructed tomograms, processed by conventional StA, and then re-extracted from the high-dose images in 2D. Single particle analysis tools are then applied to refine the 2D particle alignment and generate a reconstruction. Use of our hybrid StA (hStA) workflow improved the resolution for tobacco mosaic virus from 7.2 to 4.4 Å and for the ion channel RyR1 in crowded native membranes from 12.9 to 9.1 Å. These resolution gains make hStA a promising approach for other StA projects aimed at achieving subnanometer resolution.
Cryo electron tomography (cryo-ET) combined with subtomogram averaging (StA) enables structural determination of macromolecules in their native context. A few structures were reported by StA at resolution higher than 4.5 Å, however all of these are from viral structural proteins or vesicle coats. Reaching high resolution for a broader range of samples is uncommon due to beam-induced sample drift, poor signal-to-noise ratio (SNR) of images, challenges in CTF correction, limited number of particles. Here we propose a strategy to address these issues, which consists of a tomographic data collection scheme and a processing workflow. Tilt series are collected with higher electron dose at zero-degree tilt in order to increase SNR. Next, after performing StA conventionally, we extract 2D projections of the particles of interest from the higher SNR images and use the single particle analysis tools to refine the particle alignment and generate a reconstruction. We benchmarked our proposed hybrid StA (hStA) workflow and improved the resolution for tobacco mosaic virus from 7.2 to 5.2 Å and the resolution for the ion channel RyR1 in crowded native membranes from 12.9 to 9.1 Å. We demonstrate that hStA can improve the resolution obtained by conventional StA and promises to be a useful tool for StA projects aiming at subnanometer resolution or higher.
Ryanodine receptor 1 (RyR1) mediates excitation–contraction coupling by releasing Ca2+ from sarcoplasmic reticulum (SR) to the cytoplasm of skeletal muscle cells. RyR1 activation is regulated by several proteins from both the cytoplasm and lumen of the SR. Here, we report the structure of RyR1 from native SR membranes in closed and open states. Compared to the previously reported structures of purified RyR1, our structure reveals helix‐like densities traversing the bilayer approximately 5 nm from the RyR1 transmembrane domain and sarcoplasmic extensions linking RyR1 to a putative calsequestrin network. We document the primary conformation of RyR1 in situ and its structural variations. The activation of RyR1 is associated with changes in membrane curvature and movement in the sarcoplasmic extensions. Our results provide structural insight into the mechanism of RyR1 in its native environment.
Während meiner Promotion habe ich zwei Projekte unter der Aufsicht von Dr. Misha Kudryashev durchgeführt. Im ersten Projekt habe ich die Strukturen des Ryanodinrezeptors 1 (RyR1) in Apo- und Ryanodin-Bindungszuständen in der nativen Membran durch Tomographie und Subtomogramm-Mittelung bei 12,6 bzw. 17,5 Å bestimmt. Im Vergleich zur Struktur von gereinigtem RyR1 unter Verwendung der Einzelpartikel-Kryo-Elektronenmikroskopie (Cryo-EM) können zusätzliche Dichten in der cytoplasmatischen Domäne und der sarkoplasmatischen Retikulum (SR)-Membran bzw. im SR-Lumen beobachtet werden. Die Auflösung der Struktur von RyR1 im Apo-Zustand wurde von den Kollegen in meinem Labor mithilfe der Hybridmethode auf 9,5 Å verbessert. Diese Arbeit hat unser Verständnis für die Mechanismen von RyR1 in nativen Membranen erweitert. Im zweiten Projekt habe ich die Struktur des Proteins SdeC der SidE-Familie durch Einzelpartikel-Kryo-EM bei 4,6 Å bestimmt. Die Kristallstruktur des C-Terminus von SdeA wurde von meinem Forschungspartner Dr. Mohit Misra gelöst. Durch Überlagerung einer gemeinsamen Helix dieser beiden Strukturen konnten wir ein kombiniertes Modell erstellen und ein allgemeines Verständnis der Proteine der SidE-Familie erhalten.