The Electron Microscopy Data Bank (EMDB) is a public repository for cryogenic-sample Electron Microscopy (cryoEM) volumes and representative tomograms of macromolecular complexes and subcellular structures. It covers a variety of techniques, including single-particle analysis, helical reconstruction, electron tomography, subtomogram averaging, and electron crystallography. More...
As of 22 October 2025, EMDB contains 50408 entries (latest entries, trends).
EMDB News
-
Q-score as a reliability measure for protein, nucleic acid and small-molecule atomic coordinate models derived from 3DEM maps
Grigore Pintilie, Chenghua Shao, Zhe Wang, Brian P Hudson, Justin W Flatt, Michael F Schmid, Kyle L Morris, Stephen K Burley, Wah Chiu. (2025) Acta Cryst D81: 410-422 doi: 10.1107/S2059798325005923
Read full article. -
A total of 2,540 respondants took the time to fill in this EMBL-EBI survey. We will learn how EMDB and other services like EMPIAR and PDB help you and this will help EMBL-EBI make the case for why open data resources are critical to life science research. Thank you for the incredible number of responses.
Read full article. -
We are delighted to share that EMDB has officially been elevated to a Core Data Resource by ELIXIR, recognising it as a European data resource of fundamental importance to the wider life-science community and the long-term preservation of biological data.
Read full article.
Explore EMDB
Select a graph from the pull-down menu. Click on any element of a graph to see the corresponding list of EMDB entries.
Quick links
Recent Entries
(Show all)
Cryo-EM structure of the proximal rod-export apparatus of the polar flagellar motor
Cryo-EM structure of the MS ring with the proximal rod and the export apparatus (C1) within the polar flagellar motor
CryoEM structure of human peptidylarginine deiminase type 4 (PAD4) in 10 mM calcium
CryoEM structure of human peptidylarginine deiminase type 4 (PAD4) in complex with heparin oligomer (20 subunits) in 0.1 mM calcium
CryoEM structure of human peptidylarginine deiminase type 4 (PAD4) in complex with heparin oligomer (12 subunits)
Cryo-EM structure of the rod-export apparatus with partial hook within the polar flagellar motor
Human ADP-forming succinyl-CoA ligase complex SUCLG1-SUCLA2 bound to coenzyme A
Cryo-EM structure of the MS ring (C34) within the polar flagellar motor
Structure of human LINE-1 ORF2p with endogenous DNA and RNA/cDNA hybrid bound to dNTP and Mn2+
Structure of full-length human LINE-1 ORF2p with endogenous DNA and RNA/cDNA hybrid
Structure of human LINE-1 ORF2p with endogenous dsDNA and RNA/cDNA hybrid
Local refinement map of Arl2 and TBCD-AR1 domain in the TBC-DE-Arl2-alpha-beta-tubulin-GTP complex
Local refinement map of TBCC-RPD and Arl2 in the TBC-DEC-Arl2-alpha-beta-tubulin-GDP-AlFx complex
Local refinement map of Arl2 in the TBC-DE-Arl2-beta-tubulin-GTP complex
Local refinement map of AR3 domain in the TBC-DE-Arl2-beta-tubulin-GTP complex
Local refinement map of TBCE and alpha-tubulin in the TBC-DE-Arl2-alpha-beta-tubulin-GTP complex
Consensus map of the TBC-DC-Arl2-alpha-beta-tubulin complex with GDP-AlFx
Local refinement map of alpha-tubulin in the TBC-DC-Arl2-alpha-beta-tubulin-GDP-AlFx complex
Consensus map of the TBC-DEC-Arl2-alpha-beta-tubulin complex with GDP-AlFx
Consensus map of the TBC-DE-Arl2-alpha-beta-tubulin complex with GTP
Local refinement map of TBCE in the TBC-DEC-Arl2-alpha-beta-tubulin-GDP-AlFx complex
Local refinement map of TBCE and alpha-tubulin in the TBC-DEC-alpha-beta-tubulin-GDP-AlFx complex
Local refinement map of TBCD and Arl2 in the TBC-DEC-Arl2-alpha-beta-tubulin-GDP-AlFx complex
Local refinement map of TBCD AR3 domain in the TBC-DC-Arl2-alpha-beta-tubulin-GDP-AlFx complex
Local refinement map of TBCD and Arl2 in the TBC-DC-Arl2-alpha-beta-tubulin-GDP-AlFx complex
Local refinement map of TBCC-RPD and Arl2 in the TBC-DC-Arl2-alpha-beta-tubulin-GDP-AlFx complex
Local refinement map of TBCE-LRRD in the TBC-DE-Arl2-beta-tubulin complex
Benchmarking Talos Arctica with Falcon3 in linear mode (50ms/frame)
Cryo-EM structure of the TBC-DE-Arl2-beta-tubulin complex with GTP
Benchmarking Talos Arctica with Falcon3 in linear mode (25ms/frame)
Cryo-EM structure of the TBC-DEC-Arl2-alpha-beta-tubulin complex with GDP-AlFx
Cryo-EM structure of the TBC-DC-Arl2-alpha-beta-tubulin complex with GDP-AlFx
Cryo-EM structure of the TBC-DE-Arl2-alpha-beta-tubulin complex with GTP
CryoEM structure of the T.thermophilus transcription initiation complex bound to Gp4A-C-U and CTP, -1 dC in the template DNA strand
CryoEM structure of the T.thermophilus transcription initiation complex bound to Up4A-C and UTP, -1 dA in the template DNA strand
CryoEM structure of the T.thermophilus transcription initiation complex bound to Up4A-C and Up4A, -1 dA in the template DNA strand
LH2 complex from Ectothiorhodospira haloalkaliphila with inhibited carotenoid biosynthesis
CryoEM structure of the T.thermophilus transcription initiation complex in the presence of Gp4A, -1 dC in the template DNA strand
CryoEM structure of the T.thermophilus transcription initiation complex in the presence of Up4A
CryoEM structure of the T.thermophilus transcription initiation complex
CryoEM structure of the T.thermophilus transcription initiation complex in the presence of Gp4A, -1 dA in the template DNA strand
CryoEM structure of the T.thermophilus transcription initiation complex bound to Ap4A-C, -1 dA in the template DNA strand
CryoEM structure of the T.thermophilus transcription initiation complex bound to Ap4A-C, -1 dC in the template DNA strand
CryoEM structure of the T.thermophilus transcription initiation complex bound to ATP-C, -1 dC in the template DNA strand
CryoEM structure of T.thermophilus transcription initiation complex bound to Gp4A-C, -1 dA in the template DNA strand
Structure of E.coli ribosome in complex with an engineered arrest peptide and trigger factor
Structure of E.coli ribosome in complex with an engineered arrest peptide
CryoEM structure of the T.thermophilus transcription initiation complex bound to Gp4A-C, -1 dC in the template DNA strand
CryoEM structure of the T.thermophilus transcription initiation complex in the presence of ATP
CryoEM structure of the T.thermophilus transcription initiation complex in the presence of Ap4A
Cryo-EM structure of VSV-Indiana glycoprotein (MUDD-SUMMERS strain) in its pre-fusion conformation in complex with 8G5F11 Fab
Consensus map of HSV-1 Origin Binding Protein tetramer in complex with single-stranded DNA recognition sites Box 1 and Box 3 with 10 dT-tail
HSV-1 Origin Binding Protein in complex with double-stranded DNA recognition sequence OriS with 6 basepairs removed from the AT-rich region
Cryo-EM structure of VSV-Indiana (MUDD-SUMMERS strain) glycoprotein under its acidic conformation
Asymmetric cryo-EM reconstruction of the full-length E. coli transmembrane formate transporter FocA
Composite map of HSV-1 Origin Binding Protein tetramer in complex with single-stranded DNA recognition sites Box 1 and Box 3 with 10 dT-tail
Focused map of dimer 2 of HSV-1 Origin Binding Protein tetramer in complex with single-stranded DNA recognition sites Box 1 and Box 3 with 10 dT-tail
Focused map of HSV-1 Origin Binding Protein monomer B in complex with double-stranded DNA recognition sequence OriS with 6 basepairs removed from the AT-rich region
HSV-1 Origin Binding Protein monomer in complex with hairpin DNA OriS recognition sites Box 1 and Box 3 with 10 dT-tail
Cryo-EM reconstruction of the full-length H209N mutant E. coli transmembrane formate transporter FocA
Focused map of HSV-1 Origin Binding Protein monomer A in complex with double-stranded DNA recognition sequence OriS with 6 basepairs removed from the AT-rich region
Focused map of dimer 1 in HSV-1 Origin Binding Protein tetramer in complex with single-stranded DNA recognition sites Box 1 and Box 3 with 10 dT-tail
Cryo-EM reconstruction of the full-length E. coli transmembrane formate transporter FocA
HSV-1 Origin Binding Protein in complex with double-stranded DNA recognition sequence OriS and non-hydrolyzable ATP analog
Cryo-EM structure of VSV-Indiana (MUDD-SUMMERS strain) glycoprotein under its pre-fusion conformation
Tomogram of a mouse tracheal epithelial cell containing the C2CD3 luminal ring protein
Cryo-EM structure of Arabidopsis thaliana Met1 in complex with DNA
Structure of a mutated PSII complex that slows O-O bond formation by perturbing the proton transfer pathway
Cryo-EM structure of filament form Acidithiobacillus caldus (Aca) short prokaryotic argonautes, HNH-associated (SPARHA) with gRNA and tDNA
cryo-EM structure of Vitamin K-dependent gamma-carboxylase complexed with Vitamin K1 2,3-epoxide
cryo-EM structure of Vitamin K-dependent gamma-carboxylase complexed with factor IX(Gla)
cryo-EM structure of Vitamin K-dependent gamma-carboxylase complexed with Osteocalcin
cryo-EM structure of Vitamin K-dependent gamma-carboxylase complexed with factor IX
cryo-EM structure of Vitamin K-dependent gamma-carboxylase complexed with Matrix Gla protein
cryo-EM structure of Vitamin K-dependent gamma-carboxylase complexed with anisindione
Cryo-EM structure of Oryza sativa phosphate transporter SPDT in apo-state
Focused map for the 60S subunit of the hypomthylated yeast 80S from nutrient-limiting cells bound with Suppressor of ToM1 (Stm1)
Structure of the Measles virus Fusion protein ectodomain E170G E455G with mutated furin cleavage site in the pre-fusion conformation
Focused map for the 60S subunit of the hypomthylated yeast 80S from high OD cells bound with E site tRNA
Cas1-2/3 integration complex, 32 bp foreign DNA without PAM, first transesterification
Cas1-2/3 integration complex, 34 bp foreign DNA with PAM, first transesterification
Cas1-2/3 integration complex, 32 bp foreign DNA without PAM, full repeat
Cas1-2/3 integration complex, 32 bp foreign DNA without PAM, CRISPR leader association
Cas1-2/3 integration complex, 34 bp foreign DNA with PAM, CRISPR leader association
HIV-1 Env Q23 NFL TD CC3+ in complex with NHP Q9 V2-apex polyclonal antibody Fabs isolated post-2 immunizations
HIV-1 Env BG505 NFL TD CC3+ in complex with pooled NHP Q8-Q9-Q12 V2-apex polyclonal antibody Fabs isolated post-4 immunizations
Focused map for the body of the 40S subunit of the hypomthylated yeast 80S from nutrient-limiting cells incubated with hygromycin
Focused map for the 60S subunit of the hypomthylated yeast 80S from nutrient-limiting cells incubated with hygromycin B
HIV-1 Env 16055 NFL TD CC2+ in complex with pooled NHP Q8-Q9-Q12 V2-apex polyclonal antibody Fabs isolated post-4 immunizations
HIV-1 Env Q23 NFL TD CC3+ in complex with NHP Q10 V2-apex polyclonal antibody Fabs isolated post-2 immunizations
HIV-1 Env Q23 NFL TD CC3+ in complex with NHP Q12 V2-apex polyclonal antibody Fabs isolated post-2 immunizations
Local refinement of H11 nanotubes assembled from baculovirus capsid protein
Structural Insights into Selective Antagonism of PF04418948 and EP2 Prostaglandin Receptor
Structural Insights into Selective Antagonism Grapiprant and EP4 Prostaglandin Receptor
Cryo-EM structure of the integrin avb3 with CWHM-12, conformation 1
Local refinement of H14 nanotubes assembled from baculovirus capsid protein
Structural Insights into Selective Antagonism of TG6-129 and EP2 Prostaglandin Receptor
structure of phage T4 topoisomerase II central domain bound with DNA
Structural Insights into Selective Antagonism of TG6-129 and EP4 Prostaglandin Receptor
Cryo-EM structure of a tri-heme cytochrome-associated RC-LH1 complex from a marinephotoheterotrophic bacterium, purified with EDTA-containing solutions
Cryo-EM structure of the integrin avb3 with CWHM-12, conformation 2
Local refinement of H12 nanotubes assembled from baculovirus capsid protein
Local refinement of A7 nanotubes assembled from baculovirus capsid protein
Cryo-EM structure of the AGR2 dimer in complex with the monomeric IRE1beta luminal domain
Cryo-EM structure of human histamine receptor H4R in complex with agonist histamine and Gi proteins
Structure of the GH13 and MucBP domains of Ruminococcus bromii Amy10
Structure of the GH13 and MucBP domains of Ruminococcus bromii Amy12
Cryo-EM Map of Brucella Abortus Lumazine Synthase (BLS) Engineered with Shiga Toxin I subunit B (Stx1B) Complexed with Equine Polyclonal Fab Fragments (Complex 1)
Cryo-EM Map of Brucella Abortus Lumazine Synthase (BLS) Engineered with Shiga Toxin II subunit B (Stx2B) Complexed with Equine Polyclonal Fab Fragments (Complex 1)
Cryo-EM Map of Brucella Abortus Lumazine Synthase (BLS) Engineered with Shiga Toxin II subunit B (Stx2B) Complexed with Equine Polyclonal Fab Fragments (Complex 3)
Cryo-EM Map of Brucella Abortus Lumazine Synthase (BLS) Engineered with Shiga Toxin I subunit B (Stx1B) Complexed with Equine Polyclonal Fab Fragments (Complex 2)
Cryo-EM Map of Brucella Abortus Lumazine Synthase (BLS) Engineered with Shiga Toxin II subunit B (Stx2B) Complexed with Equine Polyclonal Fab Fragments (Complex 4)
Cryo-EM Map of Brucella Abortus Lumazine Synthase (BLS) Engineered with Shiga Toxin II subunit B (Stx2B) Complexed with Equine Polyclonal Fab Fragments (Complex 2)
Cryo-EM Map of Brucella Abortus Lumazine Synthase (BLS) Engineered with Shiga Toxin I subunit B (Stx1B) Complexed with Equine Polyclonal Fab Fragments (Complex 3)
Cryo-EM Map of Brucella Abortus Lumazine Synthase (BLS) Engineered with Shiga Toxin II subunit B (Stx2B) Complexed with Equine Polyclonal Fab Fragments (Complex 5)
Cryo-EM structure of acylaminoacyl-peptidase in complex with dichlorvos
CryoEM structure of mammalian AAP in complex with acetyl-alanyl-chloromethylketone
Cryo-EM structure of acylaminoacyl peptidase (AAP) in covalent complex with inhibitor AEBSF
Cryo-EM structure of the ONO2550289-bound prostaglandin D2 receptor (DP1)-bRIL-Fab complex (Receptor-focused)
Cryo-EM structure of the C. neoformans lipid flippase Apt1-Cdc50 bound with butyrolactol A in the E2P state
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #241).
Cryo-EM structure ONO3030297-bound prostaglandin D2 receptor (DP1)-bRIL-Fab complex (Receptor-focused map)
Cryo-EM structure of the ONO2550289-bound prostaglandin D2 receptor (DP1)-bRIL-Fab complex (Fab-foucsed map)
Cryo-EM structure of the ONO2550289-bound prostaglandin D2 receptor (DP1)-bRIL-Fab complex (Concensus map)
Cryo-EM structure ONO3030297-bound prostaglandin D2 receptor (DP1)-bRIL-Fab complex (Concensus map)
Cryo-EM structure ONO3030297-bound prostaglandin D2 receptor (DP1)-bRIL-Fab complex (Fab-focused map)
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #242).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #243).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #246).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #247).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #245).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #244).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #251).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #252).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #248).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #250).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #249).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #255).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #254).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #256).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #253).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #257).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #259).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #258).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #260).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #263).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #262).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #264).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #261).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #265).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #266).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #267).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #269).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #270).
A non-averaged 3D density map of an individual particle, with a 2D lattice formed by octahedral DNA origami and ferritin, was revealed by individual particle cryo-electron tomography (Particle #268).
Cryo-EM structure of Chikungunya virus asymmetric unit with Fab IM-CKV063
Cryo-EM structure of nanodisc (PE:PS:PC) reconstituted GLIC at pH 4 in ioioo conformation
Cryo-EM structure of nanodisc (PE:PS:PC) reconstituted GLIC Y251A mutant at pH 2.5 in ioooo conformation
Cryo-EM structure of nanodisc (PE:PS:PC) reconstituted GLIC at pH 4 in iiiii conformation
Cryo-EM structure of nanodisc (PE:PS:PC) reconstituted GLIC at pH 4 in ooooo conformation
Cryo-EM structure of nanodisc (PE:PS:PC) reconstituted GLIC at pH 4 in iiiio conformation
Cryo-EM structure of nanodisc (PE:PS:PC) reconstituted GLIC F116A mutant at pH 2.5
Cryo-EM structure of nanodisc (PE:PS:PC) reconstituted GLIC at pH 4 in iioio conformation
Cryo-EM structure of nanodisc (PE:PS:PC) reconstituted GLIC at pH 4 in iiooo conformation
Cryo-EM structure of nanodisc (PE:PS:PC) reconstituted GLIC at pH 4 in iiioo conformation
Cryo-EM structure of nanodisc (PE:PS:PC) reconstituted GLIC at pH 4 in ioooo conformation
CryoEM structure of human peptidylarginine deiminase type 4 (PAD4) in complex with heparin oligomer (20 subunits).
Cryo-EM structure of the LRR protein within the polar flagellar motor