EMDB-29035: Prefusion-stabilized SARS-CoV-2 spike protein

Basic information

Entry

Database: EMDB / ID: EMD-29035

• Title: Prefusion-stabilized SARS-CoV-2 spike protein

Sample

• Complex: SARS-CoV-2 Spike protein
  • Protein or peptide: Spike glycoprotein

• Keywords: Fusion protein / prefusion state / VIRAL PROTEIN

Function / homology

Function:

Maturation of spike protein / viral translation / Translation of Structural Proteins / Virion Assembly and Release / host cell surface / host extracellular space / suppression by virus of host tetherin activity / Induction of Cell-Cell Fusion / structural constituent of virion / entry receptor-mediated virion attachment to host cell / host cell endoplasmic reticulum-Golgi intermediate compartment membrane / membrane fusion / receptor-mediated endocytosis of virus by host cell / Attachment and Entry / positive regulation of viral entry into host cell / receptor-mediated virion attachment to host cell / receptor ligand activity / host cell surface receptor binding / symbiont-mediated suppression of host innate immune response / fusion of virus membrane with host plasma membrane / fusion of virus membrane with host endosome membrane / viral envelope / virion attachment to host cell / SARS-CoV-2 activates/modulates innate and adaptive immune responses / host cell plasma membrane / virion membrane / identical protein binding / membrane / plasma membrane

Domain/homology:

Spike (S) protein S1 subunit, receptor-binding domain, SARS-CoV-2 / Spike (S) protein S1 subunit, N-terminal domain, SARS-CoV-like / Coronavirus spike glycoprotein S1, C-terminal / Coronavirus spike glycoprotein S1, C-terminal / Spike glycoprotein, betacoronavirus / Spike glycoprotein, N-terminal domain superfamily / Betacoronavirus spike (S) glycoprotein S1 subunit N-terminal (NTD) domain profile. / Betacoronavirus spike (S) glycoprotein S1 subunit C-terminal (CTD) domain profile. / Spike (S) protein S1 subunit, receptor-binding domain, betacoronavirus / Spike S1 subunit, receptor binding domain superfamily, betacoronavirus / Spike glycoprotein S1, N-terminal domain, betacoronavirus-like / Betacoronavirus-like spike glycoprotein S1, N-terminal / Betacoronavirus spike glycoprotein S1, receptor binding / Spike glycoprotein S2, coronavirus, heptad repeat 1 / Spike glycoprotein S2, coronavirus, heptad repeat 2 / Coronavirus spike (S) glycoprotein S2 subunit heptad repeat 1 (HR1) region profile. / Coronavirus spike (S) glycoprotein S2 subunit heptad repeat 2 (HR2) region profile. / Spike glycoprotein S2 superfamily, coronavirus / Spike glycoprotein S2, coronavirus / Coronavirus spike glycoprotein S2

Component:

Spike glycoprotein

• Biological species: Severe acute respiratory syndrome coronavirus 2
• Method: single particle reconstruction / cryo EM / Resolution: 3.72 Å
• Authors: Gonzalez KJ / Mousa JJ / Strauch EM

Funding support

United States, 2 items

Organization	Grant number	Country
National Institutes of Health/National Institute Of Allergy and Infectious Diseases (NIH/NIAID)	R01 AI140245	United States
Mercatus Center	FastGrants	United States

• Citation: Journal: bioRxiv / Year: 2023; Title: A general computational design strategy for stabilizing viral class I fusion proteins.; Authors: Karen J Gonzalez / Jiachen Huang / Miria F Criado / Avik Banerjee / Stephen Tompkins / Jarrod J Mousa / Eva-Maria Strauch / ; Abstract: Many pathogenic viruses, including influenza virus, Ebola virus, coronaviruses, and Pneumoviruses, rely on class I fusion proteins to fuse viral and cellular membranes. To drive the fusion process, class I fusion proteins undergo an irreversible conformational change from a metastable prefusion state to an energetically more favorable and stable postfusion state. An increasing amount of evidence exists highlighting that antibodies targeting the prefusion conformation are the most potent. However, many mutations have to be evaluated before identifying prefusion-stabilizing substitutions. We therefore established a computational design protocol that stabilizes the prefusion state while destabilizing the postfusion conformation. As a proof of concept, we applied this principle to the fusion protein of the RSV, hMPV, and SARS-CoV-2 viruses. For each protein, we tested less than a handful of designs to identify stable versions. Solved structures of designed proteins from the three different viruses evidenced the atomic accuracy of our approach. Furthermore, the immunological response of the RSV F design compared to a current clinical candidate in a mouse model. While the parallel design of two conformations allows identifying and selectively modifying energetically less optimized positions for one conformation, our protocol also reveals diverse molecular strategies for stabilization. We recaptured many approaches previously introduced manually for the stabilization of viral surface proteins, such as cavity-filling, optimization of polar interactions, as well as postfusion-disruptive strategies. Using our approach, it is possible to focus on the most impacting mutations and potentially preserve the immunogen as closely as possible to its native version. The latter is important as sequence re-design can cause perturbations to B and T cell epitopes. Given the clinical significance of viruses using class I fusion proteins, our algorithm can substantially contribute to vaccine development by reducing the time and resources needed to optimize these immunogens.

History

Deposition	Dec 7, 2022	-
Header (metadata) release	Apr 12, 2023	-
Map release	Apr 12, 2023	-
Update	Jul 24, 2024	-
Current status	Jul 24, 2024	Processing site: RCSB / Status: Released

Map

• File: Download / File: emd_29035.map.gz / Format: CCP4 / Size: 64 MB / Type: IMAGE STORED AS FLOATING POINT NUMBER (4 BYTES)
• Voxel size: X=Y=Z: 1.024 Å

Density

Contour Level	By AUTHOR: 0.06
Minimum - Maximum	-0.0250706 - 1.7970392
Average (Standard dev.)	0.0028194897 (±0.034053344)

• Symmetry: Space group: 1

Details

EMDB XML:

Map geometry	Axis order X Y Z Origin 0 0 0 Dimensions 256 256 256 Spacing 256 256 256
Cell	A=B=C: 262.144 Å α=β=γ: 90.0 °

Supplemental data

Half map: #1

• File: emd_29035_half_map_1.map

Half map: #2

• File: emd_29035_half_map_2.map

Sample components

Entire : SARS-CoV-2 Spike protein

• Entire: Name: SARS-CoV-2 Spike protein

Components

• Complex: SARS-CoV-2 Spike protein
  • Protein or peptide: Spike glycoprotein

Supramolecule #1: SARS-CoV-2 Spike protein

• Supramolecule: Name: SARS-CoV-2 Spike protein / type: complex / ID: 1 / Parent: 0 / Macromolecule list: all
• Source (natural): Organism: Severe acute respiratory syndrome coronavirus 2

Macromolecule #1: Spike glycoprotein

• Macromolecule: Name: Spike glycoprotein / type: protein_or_peptide / ID: 1 / Number of copies: 3 / Enantiomer: LEVO
• Source (natural): Organism: Severe acute respiratory syndrome coronavirus 2
• Molecular weight: Theoretical: 137.991797 KDa
• Recombinant expression: Organism: Homo sapiens (human)

Sequence

String:

MFVFLVLLPL VSSQCVNLTT RTQLPPAYTN SFTRGVYYPD KVFRSSVLHS TQDLFLPFFS NVTWFHAIHV SGTNGTKRFD NPVLPFNDG VYFASTEKSN IIRGWIFGTT LDSKTQSLLI VNNATNVVIK VCEFQFCNDP FLGVYYHKNN KSWMESEFRV Y SSANNCTF EYVSQPFLMD LEGKQGNFKN LREFVFKNID GYFKIYSKHT PINLVRDLPQ GFSALEPLVD LPIGINITRF QT LLALHRS YLTPGDSSSG WTAGAAAYYV GYLQPRTFLL KYNENGTITD AVDCALDPLS ETKCTLKSFT VEKGIYQTSN FRV QPTESI VRFPNITNLC PFGEVFNATR FASVYAWNRK RISNCVADYS VLYNSASFST FKCYGVSPTK LNDLCFTNVY ADSF VIRGD EVRQIAPGQT GKIADYNYKL PDDFTGCVIA WNSNNLDSKV GGNYNYLYRL FRKSNLKPFE RDISTEIYQA GSTPC NGVE GFNCYFPLQS YGFQPTNGVG YQPYRVVVLS FELLHAPATV CGPKKSTNLV KNKCVNFNFN GLTGTGVLTE SNKKFL PFQ QFGRDIADTT DAVRDPQTLE ILDITPCSFG GVSVITPGTN TSNQVAVLYQ DVNCTEVPVA IHADQLTPTW RVYSTGS NV FQTRAGCLIG AEHVNNSYEC DIPIGAGICA SYQTQTNSPG SASSVASQSI IAYTMSLGAE NSVAYSNNSI AIPTNFTI S VTTEILPVSM TKTSVDCTMY ICGDSTECSN LLLQYGSFCT QLNRALTGIA VEQDKNTQEV FAQVKQIYKT PPIKDFGGF NFSQILPDPS KPSKRSFIED LLFNKVTLAD AGFIKQYGDC LGDIAARDLI CAQKFLGLTV LPPLLTDEMI AQYTSALLAG TITSGWTFG AGAALQIPFQ MQMAYRFNGI GVTQNVFWEN QKLIANQFNS AIGKIQDSLS SDASALGKLQ DVVNQNLQAL N TLVEQLSS NFGAISSVLN DILSRLNPPE AEVQIDRLIT GRLQSLQTYV TQQLIRAAEI RASANLAATK MSECVLGQSK RV DFCGKGY HLMSFPQSAP HGVVFLHVTY VPAQEKNFTT APAICHDGKA HFPREGVFVS NGTHWFVTQR NFYEPQIITT DNT FVSGNC DVVIGIVNNT VYDPLQQELD SFKEELDKYF KNHTSPDVDL GDISGINASV VNIQKEIDRL NEVAKNLNES LIDL QELGK YEQGSGYIPE APRDGQAYVR KDGEWVLLST FLHHHHHH

UniProtKB: Spike glycoprotein

Experimental details

Structure determination

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

Sample preparation

• Buffer: pH: 7.6
• Vitrification: Cryogen name: ETHANE

Electron microscopy

• Microscope: TFS KRIOS
• Image recording: Film or detector model: GATAN K2 SUMMIT (4k x 4k) / Digitization - Dimensions - Width: 3710 pixel / Digitization - Dimensions - Height: 3838 pixel / Average exposure time: 8.0 sec. / Average electron dose: 58.24 e/Ų
• Electron beam: Acceleration voltage: 300 kV / Electron source: FIELD EMISSION GUN
• Electron optics: C2 aperture diameter: 70.0 µm / Illumination mode: FLOOD BEAM / Imaging mode: BRIGHT FIELD / Cs: 2.7 mm / Nominal defocus max: 2.6 µm / Nominal defocus min: 0.8 µm
• Experimental equipment: Model: Titan Krios / Image courtesy: FEI Company

Image processing

• Startup model: Type of model: NONE
• Final reconstruction: Resolution.type: BY AUTHOR / Resolution: 3.72 Å / Resolution method: FSC 0.143 CUT-OFF / Number images used: 87514
• Initial angle assignment: Type: MAXIMUM LIKELIHOOD / Software - Name: cryoSPARC (ver. v3.3.2)
• Final angle assignment: Type: MAXIMUM LIKELIHOOD / Software - Name: cryoSPARC

Atomic model buiding 1

• Refinement: Protocol: AB INITIO MODEL

Output model

PDB-8fez:
Prefusion-stabilized SARS-CoV-2 spike protein