EMDB-31091: Krios G4 apoferritin test with K3/BioQuantum SerialEM BIS 3x3x4

Basic information

• Entry: Database: EMDB / ID: EMD-31091
• Title: Krios G4 apoferritin test with K3/BioQuantum SerialEM BIS 3x3x4
• Map data: Ewald sphere corrected sharpened map

Sample

• Complex: apoferritin

Function / homology

Function:

Iron uptake and transport / Golgi Associated Vesicle Biogenesis / iron ion sequestering activity / negative regulation of ferroptosis / ferroxidase / autolysosome / ferroxidase activity / intracellular sequestering of iron ion / negative regulation of fibroblast proliferation / endocytic vesicle lumen / autophagosome / Neutrophil degranulation / ferric iron binding / ferrous iron binding / iron ion transport / immune response / iron ion binding / negative regulation of cell population proliferation / mitochondrion / extracellular region / identical protein binding / membrane / cytosol / cytoplasm

Domain/homology:

Ferritin iron-binding regions signature 1. / Ferritin iron-binding regions signature 2. / Ferritin, conserved site / Ferritin / Ferritin-like diiron domain / Ferritin-like diiron domain profile. / Ferritin/DPS protein domain / Ferritin-like domain / Ferritin-like / Ferritin-like superfamily

Component:

Ferritin heavy chain

• Biological species: mus musc (Temminck's mouse)
• Method: single particle reconstruction / cryo EM / Resolution: 1.35 Å
• Authors: Danev R / Yanagisawa H / Kikkawa M

Funding support

Japan, 1 items

Organization	Grant number	Country
Japan Science and Technology	18069571	Japan

• Citation: Journal: Microscopy (Oxf) / Year: 2021; Title: Cryo-EM performance testing of hardware and data acquisition strategies.; Authors: Radostin Danev / Haruaki Yanagisawa / Masahide Kikkawa / ; Abstract: The increasing popularity and adoption rate of cryo-electron microscopy (cryo-EM) is evidenced by a growing number of new microscope installations around the world. The quality and reliability of the instruments improved dramatically in recent years, but site-specific issues or unnoticed problems during installation could undermine productivity. Newcomers to the field may also have limited experience and/or low confidence in the capabilities of the equipment or their own skills. Therefore, it is recommended to perform an initial test of the complete cryo-EM workflow with an 'easy' test sample, such as apoferritin, before starting work with real and challenging samples. Analogous test experiments are also recommended for the quantification of new data acquisition approaches or imaging hardware. Here, we present the results from our initial tests of a recently installed Krios G4 electron microscope equipped with two latest generation direct electron detector cameras-Gatan K3 and Falcon 4. Three beam-image shift-based data acquisition strategies were also tested. We detail the methodology and discuss the critical parameters and steps for performance testing. The two cameras performed equally, and the single- and multi-shot per-hole acquisition schemes produced comparable results. We also evaluated the effects of environmental factors and optical flaws on data quality. Our results reaffirmed the exceptional performance of the software aberration correction in Relion in dealing with severe coma aberration. We hope that this work will help cryo-EM teams in their testing and troubleshooting of hardware and data collection approaches.

History

Deposition	Mar 23, 2021	-
Header (metadata) release	Apr 7, 2021	-
Map release	Apr 7, 2021	-
Update	Dec 8, 2021	-
Current status	Dec 8, 2021	Processing site: PDBj / Status: Released

Map

• File: Download / File: emd_31091.map.gz / Format: CCP4 / Size: 476.8 MB / Type: IMAGE STORED AS FLOATING POINT NUMBER (4 BYTES)
• Annotation: Ewald sphere corrected sharpened map
• Voxel size: X=Y=Z: 0.5991 Å

Density

Contour Level	By AUTHOR: 0.07 / Movie #1: 0.07
Minimum - Maximum	-0.21184005 - 0.7145265
Average (Standard dev.)	4.6750947e-06 (±0.013002123)

• Symmetry: Space group: 1

Details

EMDB XML:

Map geometry	Axis order X Y Z Origin 0 0 0 Dimensions 500 500 500 Spacing 500 500 500
Cell	A=B=C: 299.55 Å α=β=γ: 90.0 °

CCP4 map header:

mode	Image stored as Reals
Å/pix. X/Y/Z	0.5991	0.5991	0.5991
M x/y/z	500	500	500
origin x/y/z	0.000	0.000	0.000
length x/y/z	299.550	299.550	299.550
α/β/γ	90.000	90.000	90.000
MAP C/R/S	1	2	3
start NC/NR/NS	0	0	0
NC/NR/NS	500	500	500
D min/max/mean	-0.212	0.715	0.000

Supplemental data

Mask #1

• File: emd_31091_msk_1.map

Half map: Ewald sphere corrected half map 1

• File: emd_31091_half_map_1.map
• Annotation: Ewald sphere corrected half map 1

Half map: Ewald sphere corrected half map 2

• File: emd_31091_half_map_2.map
• Annotation: Ewald sphere corrected half map 2

Sample components

Entire : apoferritin

• Entire: Name: apoferritin

Components

• Complex: apoferritin

Supramolecule #1: apoferritin

• Supramolecule: Name: apoferritin / type: complex / ID: 1 / Parent: 0 / Details: mouse heavy chain
• Source (natural): Organism: mus musc (Temminck's mouse)
• Recombinant expression: Organism: Escherichia coli 'BL21-Gold(DE3)pLysS AG' (bacteria)
• Molecular weight: Theoretical: 500 kDa/nm

Experimental details

Structure determination

• Method: cryo EM
• Processing: single particle reconstruction
• Aggregation state: particle

Sample preparation

• Concentration: 12 mg/mL
• Buffer: pH: 7.5 / Details: HEPES-NaOH
• Vitrification: Cryogen name: ETHANE / Chamber humidity: 100 % / Chamber temperature: 277 K / Instrument: FEI VITROBOT MARK IV

Electron microscopy

• Microscope: FEI TITAN KRIOS
• Temperature: Min: 77.0 K / Max: 77.0 K
• Alignment procedure: Coma free - Residual tilt: 0.3 mrad
• Specialist optics: Energy filter - Name: GIF Bioquantum / Energy filter - Slit width: 15 eV
• Image recording: Film or detector model: GATAN K3 BIOQUANTUM (6k x 4k) / Digitization - Dimensions - Width: 5760 pixel / Digitization - Dimensions - Height: 4092 pixel / Digitization - Sampling interval: 5.0 µm / Number grids imaged: 1 / Number real images: 2391 / Average exposure time: 3.04 sec. / Average electron dose: 64.5 e/Ų; Details: Beam-image shift acquisition with a custom SerialEM script. Used SerialEM beam-tilt compensated image shift. Acquisition pattern: 3x3 holes, 1 image/hole
• Electron beam: Acceleration voltage: 300 kV / Electron source: FIELD EMISSION GUN
• Electron optics: C2 aperture diameter: 50.0 µm / Calibrated defocus max: 0.8 µm / Calibrated defocus min: 0.2 µm / Calibrated magnification: 125000 / Illumination mode: FLOOD BEAM / Imaging mode: BRIGHT FIELD / Cs: 2.7 mm / Nominal defocus max: 0.8 µm / Nominal defocus min: 0.2 µm / Nominal magnification: 215000
• Sample stage: Specimen holder model: FEI TITAN KRIOS AUTOGRID HOLDER / Cooling holder cryogen: NITROGEN
• Experimental equipment: Model: Titan Krios / Image courtesy: FEI Company

Image processing

• Particle selection: Number selected: 330000
• CTF correction: Software - Name: Gctf
• Startup model: Type of model: OTHER / Details: previous reconstruction
• Final reconstruction: Resolution.type: BY AUTHOR / Resolution: 1.35 Å / Resolution method: FSC 0.143 CUT-OFF / Software - Name: RELION (ver. 3.1) / Number images used: 136064
• Initial angle assignment: Type: MAXIMUM LIKELIHOOD / Software - Name: RELION (ver. 3.1)
• Final angle assignment: Type: MAXIMUM LIKELIHOOD / Software - Name: RELION (ver. 3.1)
• Final 3D classification: Number classes: 5 / Software - Name: RELION