+Open data
-Basic information
Entry | Database: EMDB / ID: EMD-13356 | |||||||||
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Title | The 4x177 nucleosome array containing H1 | |||||||||
Map data | ||||||||||
Sample |
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Keywords | Chromatin / Nucleosomes / Linker Histone / DNA BINDING PROTEIN | |||||||||
Function / homology | Function and homology information negative regulation of DNA recombination / Apoptosis induced DNA fragmentation / chromosome condensation / Formation of Senescence-Associated Heterochromatin Foci (SAHF) / negative regulation of megakaryocyte differentiation / protein localization to CENP-A containing chromatin / Chromatin modifying enzymes / heterochromatin / Replacement of protamines by nucleosomes in the male pronucleus / CENP-A containing nucleosome ...negative regulation of DNA recombination / Apoptosis induced DNA fragmentation / chromosome condensation / Formation of Senescence-Associated Heterochromatin Foci (SAHF) / negative regulation of megakaryocyte differentiation / protein localization to CENP-A containing chromatin / Chromatin modifying enzymes / heterochromatin / Replacement of protamines by nucleosomes in the male pronucleus / CENP-A containing nucleosome / Packaging Of Telomere Ends / Recognition and association of DNA glycosylase with site containing an affected purine / Cleavage of the damaged purine / Deposition of new CENPA-containing nucleosomes at the centromere / nucleosomal DNA binding / Recognition and association of DNA glycosylase with site containing an affected pyrimidine / Cleavage of the damaged pyrimidine / Inhibition of DNA recombination at telomere / telomere organization / Meiotic synapsis / Interleukin-7 signaling / RNA Polymerase I Promoter Opening / Assembly of the ORC complex at the origin of replication / SUMOylation of chromatin organization proteins / Regulation of endogenous retroelements by the Human Silencing Hub (HUSH) complex / DNA methylation / Condensation of Prophase Chromosomes / SIRT1 negatively regulates rRNA expression / Chromatin modifications during the maternal to zygotic transition (MZT) / HCMV Late Events / ERCC6 (CSB) and EHMT2 (G9a) positively regulate rRNA expression / innate immune response in mucosa / PRC2 methylates histones and DNA / Regulation of endogenous retroelements by KRAB-ZFP proteins / Defective pyroptosis / Regulation of endogenous retroelements by Piwi-interacting RNAs (piRNAs) / HDACs deacetylate histones / RNA Polymerase I Promoter Escape / Nonhomologous End-Joining (NHEJ) / Transcriptional regulation by small RNAs / Formation of the beta-catenin:TCF transactivating complex / RUNX1 regulates genes involved in megakaryocyte differentiation and platelet function / NoRC negatively regulates rRNA expression / Activated PKN1 stimulates transcription of AR (androgen receptor) regulated genes KLK2 and KLK3 / G2/M DNA damage checkpoint / euchromatin / HDMs demethylate histones / B-WICH complex positively regulates rRNA expression / DNA Damage/Telomere Stress Induced Senescence / chromatin DNA binding / heterochromatin formation / PKMTs methylate histone lysines / Meiotic recombination / Metalloprotease DUBs / Pre-NOTCH Transcription and Translation / RMTs methylate histone arginines / histone deacetylase binding / Activation of anterior HOX genes in hindbrain development during early embryogenesis / HCMV Early Events / Transcriptional regulation of granulopoiesis / structural constituent of chromatin / UCH proteinases / antimicrobial humoral immune response mediated by antimicrobial peptide / nucleosome / antibacterial humoral response / nucleosome assembly / E3 ubiquitin ligases ubiquitinate target proteins / Recruitment and ATM-mediated phosphorylation of repair and signaling proteins at DNA double strand breaks / chromatin organization / RUNX1 regulates transcription of genes involved in differentiation of HSCs / Factors involved in megakaryocyte development and platelet production / HATs acetylate histones / Processing of DNA double-strand break ends / Senescence-Associated Secretory Phenotype (SASP) / double-stranded DNA binding / Oxidative Stress Induced Senescence / defense response to Gram-negative bacterium / Estrogen-dependent gene expression / killing of cells of another organism / chromosome, telomeric region / Ub-specific processing proteases / defense response to Gram-positive bacterium / protein heterodimerization activity / Amyloid fiber formation / negative regulation of cell population proliferation / negative regulation of transcription by RNA polymerase II / protein-containing complex / DNA binding / RNA binding / extracellular space / extracellular exosome / extracellular region / nucleoplasm / membrane / nucleus / cytosol Similarity search - Function | |||||||||
Biological species | Homo sapiens (human) / synthetic construct (others) | |||||||||
Method | single particle reconstruction / cryo EM / Resolution: 9.5 Å | |||||||||
Authors | Dombrowski M / Cramer P | |||||||||
Funding support | European Union, 1 items
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Citation | Journal: Nat Struct Mol Biol / Year: 2022 Title: Histone H1 binding to nucleosome arrays depends on linker DNA length and trajectory. Authors: Marco Dombrowski / Maik Engeholm / Christian Dienemann / Svetlana Dodonova / Patrick Cramer / Abstract: Throughout the genome, nucleosomes often form regular arrays that differ in nucleosome repeat length (NRL), occupancy of linker histone H1 and transcriptional activity. Here, we report cryo-EM ...Throughout the genome, nucleosomes often form regular arrays that differ in nucleosome repeat length (NRL), occupancy of linker histone H1 and transcriptional activity. Here, we report cryo-EM structures of human H1-containing tetranucleosome arrays with four physiologically relevant NRLs. The structures show a zig-zag arrangement of nucleosomes, with nucleosomes 1 and 3 forming a stack. H1 binding to stacked nucleosomes depends on the NRL, whereas H1 always binds to the non-stacked nucleosomes 2 and 4. Short NRLs lead to altered trajectories of linker DNA, and these altered trajectories sterically impair H1 binding to the stacked nucleosomes in our structures. As the NRL increases, linker DNA trajectories relax, enabling H1 contacts and binding. Our results provide an explanation for why arrays with short NRLs are depleted of H1 and suited for transcription, whereas arrays with long NRLs show full H1 occupancy and can form transcriptionally silent heterochromatin regions. | |||||||||
History |
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-Structure visualization
Supplemental images |
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-Downloads & links
-EMDB archive
Map data | emd_13356.map.gz | 17.4 MB | EMDB map data format | |
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Header (meta data) | emd-13356-v30.xml emd-13356.xml | 20.7 KB 20.7 KB | Display Display | EMDB header |
FSC (resolution estimation) | emd_13356_fsc.xml | 7.2 KB | Display | FSC data file |
Images | emd_13356.png | 41.1 KB | ||
Filedesc metadata | emd-13356.cif.gz | 6.3 KB | ||
Archive directory | http://ftp.pdbj.org/pub/emdb/structures/EMD-13356 ftp://ftp.pdbj.org/pub/emdb/structures/EMD-13356 | HTTPS FTP |
-Validation report
Summary document | emd_13356_validation.pdf.gz | 406.9 KB | Display | EMDB validaton report |
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Full document | emd_13356_full_validation.pdf.gz | 406.5 KB | Display | |
Data in XML | emd_13356_validation.xml.gz | 9.6 KB | Display | |
Data in CIF | emd_13356_validation.cif.gz | 12.4 KB | Display | |
Arichive directory | https://ftp.pdbj.org/pub/emdb/validation_reports/EMD-13356 ftp://ftp.pdbj.org/pub/emdb/validation_reports/EMD-13356 | HTTPS FTP |
-Related structure data
Related structure data | 7petMC 7peuC 7pevC 7pewC 7pexC 7peyC 7pezC 7pf0C 7pf2C 7pf3C 7pf4C 7pf5C 7pf6C 7pfaC 7pfcC 7pfdC 7pfeC 7pffC 7pftC 7pfuC 7pfvC 7pfwC 7pfxC M: atomic model generated by this map C: citing same article (ref.) |
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Similar structure data | Similarity search - Function & homologyF&H Search |
-Links
EMDB pages | EMDB (EBI/PDBe) / EMDataResource |
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Related items in Molecule of the Month |
-Map
File | Download / File: emd_13356.map.gz / Format: CCP4 / Size: 30.5 MB / Type: IMAGE STORED AS FLOATING POINT NUMBER (4 BYTES) | ||||||||||||||||||||||||||||||||||||
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Projections & slices | Image control
Images are generated by Spider. | ||||||||||||||||||||||||||||||||||||
Voxel size | X=Y=Z: 2.1 Å | ||||||||||||||||||||||||||||||||||||
Density |
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Symmetry | Space group: 1 | ||||||||||||||||||||||||||||||||||||
Details | EMDB XML:
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-Supplemental data
-Sample components
-Entire : Tetranucleosome from 4x177 nucleosome array
Entire | Name: Tetranucleosome from 4x177 nucleosome array |
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Components |
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-Supramolecule #1: Tetranucleosome from 4x177 nucleosome array
Supramolecule | Name: Tetranucleosome from 4x177 nucleosome array / type: complex / ID: 1 / Parent: 0 / Macromolecule list: all |
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-Macromolecule #1: Histone H3.2
Macromolecule | Name: Histone H3.2 / type: protein_or_peptide / ID: 1 / Number of copies: 8 / Enantiomer: LEVO |
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Source (natural) | Organism: Homo sapiens (human) |
Molecular weight | Theoretical: 15.389036 KDa |
Recombinant expression | Organism: Escherichia coli (E. coli) |
Sequence | String: MARTKQTARK STGGKAPRKQ LATKAARKSA PATGGVKKPH RYRPGTVALR EIRRYQKSTE LLIRKLPFQR LVREIAQDFK TDLRFQSSA VMALQEASEA YLVGLFEDTN LAAIHAKRVT IMPKDIQLAR RIRGERA UniProtKB: Histone H3.2 |
-Macromolecule #2: Histone H4
Macromolecule | Name: Histone H4 / type: protein_or_peptide / ID: 2 / Number of copies: 8 / Enantiomer: LEVO |
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Source (natural) | Organism: Homo sapiens (human) |
Molecular weight | Theoretical: 11.394426 KDa |
Recombinant expression | Organism: Escherichia coli (E. coli) |
Sequence | String: MSGRGKGGKG LGKGGAKRHR KVLRDNIQGI TKPAIRRLAR RGGVKRISGL IYEETRGVLK VFLENVIRDA VTYTEHAKRK TVTAMDVVY ALKRQGRTLY GFGG UniProtKB: Histone H4 |
-Macromolecule #3: Histone H2A type 1-B/E
Macromolecule | Name: Histone H2A type 1-B/E / type: protein_or_peptide / ID: 3 / Number of copies: 8 / Enantiomer: LEVO |
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Source (natural) | Organism: Homo sapiens (human) |
Molecular weight | Theoretical: 16.344873 KDa |
Recombinant expression | Organism: Escherichia coli (E. coli) |
Sequence | String: HHHHHHENLY FQSNAPWMSG RGKQGGKARA KAKTRSSRAG LQFPVGRVHR LLRKGNYSER VGAGAPVYLA AVLEYLTAEI LELAGNAAR DNKKTRIIPR HLQLAIRNDE ELNKLLGRVT IAQGGVLPNI QAVLLPKKTE SHHKAKGK UniProtKB: Histone H2A type 1-B/E |
-Macromolecule #4: Histone H2B type 1-K
Macromolecule | Name: Histone H2B type 1-K / type: protein_or_peptide / ID: 4 / Number of copies: 8 / Enantiomer: LEVO |
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Source (natural) | Organism: Homo sapiens (human) |
Molecular weight | Theoretical: 13.921213 KDa |
Recombinant expression | Organism: Escherichia coli (E. coli) |
Sequence | String: MPEPAKSAPA PKKGSKKAVT KAQKKDGKKR KRSRKESYSV YVYKVLKQVH PDTGISSKAM GIMNSFVNDI FERIAGEASR LAHYNKRST ITSREIQTAV RLLLPGELAK HAVSEGTKAV TKYTSAK UniProtKB: Histone H2B type 1-K |
-Macromolecule #5: Histone H1.4
Macromolecule | Name: Histone H1.4 / type: protein_or_peptide / ID: 5 / Number of copies: 2 / Enantiomer: LEVO |
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Source (natural) | Organism: Homo sapiens (human) |
Molecular weight | Theoretical: 21.800326 KDa |
Recombinant expression | Organism: Escherichia coli (E. coli) |
Sequence | String: SETAPAAPAA PAPAEKTPVK KKARKSAGAA KRKASGPPVS ELITKAVAAS KERSGVSLAA LKKALAAAGY DVEKNNSRIK LGLKSLVSK GTLVQTKGTG ASGSFKLNKK AASGEAKPKA KKAGAAKAKK PAGAAKKPKK ATGAATPKKS AKKTPKKAKK P AAAAGAKK ...String: SETAPAAPAA PAPAEKTPVK KKARKSAGAA KRKASGPPVS ELITKAVAAS KERSGVSLAA LKKALAAAGY DVEKNNSRIK LGLKSLVSK GTLVQTKGTG ASGSFKLNKK AASGEAKPKA KKAGAAKAKK PAGAAKKPKK ATGAATPKKS AKKTPKKAKK P AAAAGAKK AKSPKKAKAA KPKKAPKSPA KAKAVKPKAA KPKTAKPKAA KPKKAAAKKK UniProtKB: Histone H1.4 |
-Macromolecule #6: DNA (702-MER)
Macromolecule | Name: DNA (702-MER) / type: dna / ID: 6 / Number of copies: 1 / Classification: DNA |
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Source (natural) | Organism: synthetic construct (others) |
Molecular weight | Theoretical: 215.396625 KDa |
Sequence | String: (DA)(DT)(DC)(DC)(DC)(DG)(DG)(DA)(DT)(DC) (DC)(DC)(DC)(DT)(DG)(DG)(DA)(DG)(DA)(DA) (DT)(DC)(DC)(DC)(DG)(DG)(DT)(DG)(DC) (DC)(DG)(DA)(DG)(DG)(DC)(DC)(DG)(DC)(DT) (DC) (DA)(DA)(DT)(DT)(DG)(DG) ...String: (DA)(DT)(DC)(DC)(DC)(DG)(DG)(DA)(DT)(DC) (DC)(DC)(DC)(DT)(DG)(DG)(DA)(DG)(DA)(DA) (DT)(DC)(DC)(DC)(DG)(DG)(DT)(DG)(DC) (DC)(DG)(DA)(DG)(DG)(DC)(DC)(DG)(DC)(DT) (DC) (DA)(DA)(DT)(DT)(DG)(DG)(DT)(DC) (DG)(DT)(DA)(DG)(DA)(DC)(DA)(DG)(DC)(DT) (DC)(DT) (DA)(DG)(DC)(DA)(DC)(DC)(DG) (DC)(DT)(DT)(DA)(DA)(DA)(DC)(DG)(DC)(DA) (DC)(DG)(DT) (DA)(DC)(DG)(DC)(DG)(DC) (DT)(DG)(DT)(DC)(DC)(DC)(DC)(DC)(DG)(DC) (DG)(DT)(DT)(DT) (DT)(DA)(DA)(DC)(DC) (DG)(DC)(DC)(DA)(DA)(DG)(DG)(DG)(DG)(DA) (DT)(DT)(DA)(DC)(DT) (DC)(DC)(DC)(DT) (DA)(DG)(DT)(DC)(DT)(DC)(DC)(DA)(DG)(DG) (DC)(DA)(DC)(DG)(DT)(DG) (DT)(DC)(DA) (DC)(DA)(DT)(DA)(DT)(DA)(DT)(DA)(DC)(DA) (DT)(DC)(DC)(DT)(DG)(DT)(DT) (DC)(DC) (DA)(DG)(DT)(DG)(DC)(DC)(DG)(DG)(DA)(DC) (DC)(DC)(DG)(DA)(DG)(DC)(DA)(DT) (DC) (DC)(DG)(DG)(DA)(DT)(DC)(DC)(DC)(DC)(DT) (DG)(DG)(DA)(DG)(DA)(DA)(DT)(DC)(DC) (DC)(DG)(DG)(DT)(DG)(DC)(DC)(DG)(DA)(DG) (DG)(DC)(DC)(DG)(DC)(DT)(DC)(DA)(DA)(DT) (DT)(DG)(DG)(DT)(DC)(DG)(DT)(DA)(DG) (DA)(DC)(DA)(DG)(DC)(DT)(DC)(DT)(DA)(DG) (DC) (DA)(DC)(DC)(DG)(DC)(DT)(DT)(DA) (DA)(DA)(DC)(DG)(DC)(DA)(DC)(DG)(DT)(DA) (DC)(DG) (DC)(DG)(DC)(DT)(DG)(DT)(DC) (DC)(DC)(DC)(DC)(DG)(DC)(DG)(DT)(DT)(DT) (DT)(DA)(DA) (DC)(DC)(DG)(DC)(DC)(DA) (DA)(DG)(DG)(DG)(DG)(DA)(DT)(DT)(DA)(DC) (DT)(DC)(DC)(DC) (DT)(DA)(DG)(DT)(DC) (DT)(DC)(DC)(DA)(DG)(DG)(DC)(DA)(DC)(DG) (DT)(DG)(DT)(DC)(DA) (DC)(DA)(DT)(DA) (DT)(DA)(DT)(DA)(DC)(DA)(DT)(DC)(DC)(DT) (DG)(DT)(DT)(DC)(DC)(DA) (DG)(DT)(DG) (DC)(DC)(DG)(DG)(DA)(DC)(DC)(DC)(DG)(DA) (DG)(DC)(DA)(DT)(DC)(DC)(DG) (DG)(DA) (DT)(DC)(DC)(DC)(DC)(DT)(DG)(DG)(DA)(DG) (DA)(DA)(DT)(DC)(DC)(DC)(DG)(DG) (DT) (DG)(DC)(DC)(DG)(DA)(DG)(DG)(DC)(DC)(DG) (DC)(DT)(DC)(DA)(DA)(DT)(DT)(DG)(DG) (DT)(DC)(DG)(DT)(DA)(DG)(DA)(DC)(DA)(DG) (DC)(DT)(DC)(DT)(DA)(DG)(DC)(DA)(DC)(DC) (DG)(DC)(DT)(DT)(DA)(DA)(DA)(DC)(DG) (DC)(DA)(DC)(DG)(DT)(DA)(DC)(DG)(DC)(DG) (DC) (DT)(DG)(DT)(DC)(DC)(DC)(DC)(DC) (DG)(DC)(DG)(DT)(DT)(DT)(DT)(DA)(DA)(DC) (DC)(DG) (DC)(DC)(DA)(DA)(DG)(DG)(DG) (DG)(DA)(DT)(DT)(DA)(DC)(DT)(DC)(DC)(DC) (DT)(DA)(DG) (DT)(DC)(DT)(DC)(DC)(DA) (DG)(DG)(DC)(DA)(DC)(DG)(DT)(DG)(DT)(DC) (DA)(DC)(DA)(DT) (DA)(DT)(DA)(DT)(DA) (DC)(DA)(DT)(DC)(DC)(DT)(DG)(DT)(DT)(DC) (DC)(DA)(DG)(DT)(DG) (DC)(DC)(DG)(DG) (DA)(DC)(DC)(DC)(DG)(DA)(DG)(DC)(DA)(DT) (DC)(DC)(DG)(DG)(DA)(DT) (DC)(DC)(DC) (DC)(DT)(DG)(DG)(DA)(DG)(DA)(DA)(DT)(DC) (DC)(DC)(DG)(DG)(DT)(DG)(DC) (DC)(DG) (DA)(DG)(DG)(DC)(DC)(DG)(DC)(DT)(DC)(DA) (DA)(DT)(DT)(DG)(DG)(DT)(DC)(DG) (DT) (DA)(DG)(DA)(DC)(DA)(DG)(DC)(DT)(DC)(DT) (DA)(DG)(DC)(DA)(DC)(DC)(DG)(DC)(DT) (DT)(DA)(DA)(DA)(DC)(DG)(DC)(DA)(DC)(DG) (DT)(DA)(DC)(DG)(DC)(DG)(DC)(DT)(DG)(DT) (DC)(DC)(DC)(DC)(DC)(DG)(DC)(DG)(DT) (DT)(DT)(DT)(DA)(DA)(DC)(DC)(DG)(DC)(DC) (DA) (DA)(DG)(DG)(DG)(DG)(DA)(DT)(DT) (DA)(DC)(DT)(DC)(DC)(DC)(DT)(DA)(DG)(DT) (DC)(DT) (DC)(DC)(DA)(DG)(DG)(DC)(DA) (DC)(DG)(DT)(DG)(DT)(DC)(DA)(DC)(DA)(DT) (DA)(DT)(DA) (DT)(DA)(DC)(DA)(DT)(DC) (DC)(DT)(DG)(DT)(DT)(DC)(DC)(DA)(DG)(DT) (DG)(DC)(DC)(DG) (DA)(DT) |
-Macromolecule #7: DNA (702-MER)
Macromolecule | Name: DNA (702-MER) / type: dna / ID: 7 / Number of copies: 1 / Classification: DNA |
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Source (natural) | Organism: synthetic construct (others) |
Molecular weight | Theoretical: 218.332234 KDa |
Sequence | String: (DA)(DT)(DC)(DG)(DG)(DC)(DA)(DC)(DT)(DG) (DG)(DA)(DA)(DC)(DA)(DG)(DG)(DA)(DT)(DG) (DT)(DA)(DT)(DA)(DT)(DA)(DT)(DG)(DT) (DG)(DA)(DC)(DA)(DC)(DG)(DT)(DG)(DC)(DC) (DT) (DG)(DG)(DA)(DG)(DA)(DC) ...String: (DA)(DT)(DC)(DG)(DG)(DC)(DA)(DC)(DT)(DG) (DG)(DA)(DA)(DC)(DA)(DG)(DG)(DA)(DT)(DG) (DT)(DA)(DT)(DA)(DT)(DA)(DT)(DG)(DT) (DG)(DA)(DC)(DA)(DC)(DG)(DT)(DG)(DC)(DC) (DT) (DG)(DG)(DA)(DG)(DA)(DC)(DT)(DA) (DG)(DG)(DG)(DA)(DG)(DT)(DA)(DA)(DT)(DC) (DC)(DC) (DC)(DT)(DT)(DG)(DG)(DC)(DG) (DG)(DT)(DT)(DA)(DA)(DA)(DA)(DC)(DG)(DC) (DG)(DG)(DG) (DG)(DG)(DA)(DC)(DA)(DG) (DC)(DG)(DC)(DG)(DT)(DA)(DC)(DG)(DT)(DG) (DC)(DG)(DT)(DT) (DT)(DA)(DA)(DG)(DC) (DG)(DG)(DT)(DG)(DC)(DT)(DA)(DG)(DA)(DG) (DC)(DT)(DG)(DT)(DC) (DT)(DA)(DC)(DG) (DA)(DC)(DC)(DA)(DA)(DT)(DT)(DG)(DA)(DG) (DC)(DG)(DG)(DC)(DC)(DT) (DC)(DG)(DG) (DC)(DA)(DC)(DC)(DG)(DG)(DG)(DA)(DT)(DT) (DC)(DT)(DC)(DC)(DA)(DG)(DG) (DG)(DG) (DA)(DT)(DC)(DC)(DG)(DG)(DA)(DT)(DG)(DC) (DT)(DC)(DG)(DG)(DG)(DT)(DC)(DC) (DG) (DG)(DC)(DA)(DC)(DT)(DG)(DG)(DA)(DA)(DC) (DA)(DG)(DG)(DA)(DT)(DG)(DT)(DA)(DT) (DA)(DT)(DA)(DT)(DG)(DT)(DG)(DA)(DC)(DA) (DC)(DG)(DT)(DG)(DC)(DC)(DT)(DG)(DG)(DA) (DG)(DA)(DC)(DT)(DA)(DG)(DG)(DG)(DA) (DG)(DT)(DA)(DA)(DT)(DC)(DC)(DC)(DC)(DT) (DT) (DG)(DG)(DC)(DG)(DG)(DT)(DT)(DA) (DA)(DA)(DA)(DC)(DG)(DC)(DG)(DG)(DG)(DG) (DG)(DA) (DC)(DA)(DG)(DC)(DG)(DC)(DG) (DT)(DA)(DC)(DG)(DT)(DG)(DC)(DG)(DT)(DT) (DT)(DA)(DA) (DG)(DC)(DG)(DG)(DT)(DG) (DC)(DT)(DA)(DG)(DA)(DG)(DC)(DT)(DG)(DT) (DC)(DT)(DA)(DC) (DG)(DA)(DC)(DC)(DA) (DA)(DT)(DT)(DG)(DA)(DG)(DC)(DG)(DG)(DC) (DC)(DT)(DC)(DG)(DG) (DC)(DA)(DC)(DC) (DG)(DG)(DG)(DA)(DT)(DT)(DC)(DT)(DC)(DC) (DA)(DG)(DG)(DG)(DG)(DA) (DT)(DC)(DC) (DG)(DG)(DA)(DT)(DG)(DC)(DT)(DC)(DG)(DG) (DG)(DT)(DC)(DC)(DG)(DG)(DC) (DA)(DC) (DT)(DG)(DG)(DA)(DA)(DC)(DA)(DG)(DG)(DA) (DT)(DG)(DT)(DA)(DT)(DA)(DT)(DA) (DT) (DG)(DT)(DG)(DA)(DC)(DA)(DC)(DG)(DT)(DG) (DC)(DC)(DT)(DG)(DG)(DA)(DG)(DA)(DC) (DT)(DA)(DG)(DG)(DG)(DA)(DG)(DT)(DA)(DA) (DT)(DC)(DC)(DC)(DC)(DT)(DT)(DG)(DG)(DC) (DG)(DG)(DT)(DT)(DA)(DA)(DA)(DA)(DC) (DG)(DC)(DG)(DG)(DG)(DG)(DG)(DA)(DC)(DA) (DG) (DC)(DG)(DC)(DG)(DT)(DA)(DC)(DG) (DT)(DG)(DC)(DG)(DT)(DT)(DT)(DA)(DA)(DG) (DC)(DG) (DG)(DT)(DG)(DC)(DT)(DA)(DG) (DA)(DG)(DC)(DT)(DG)(DT)(DC)(DT)(DA)(DC) (DG)(DA)(DC) (DC)(DA)(DA)(DT)(DT)(DG) (DA)(DG)(DC)(DG)(DG)(DC)(DC)(DT)(DC)(DG) (DG)(DC)(DA)(DC) (DC)(DG)(DG)(DG)(DA) (DT)(DT)(DC)(DT)(DC)(DC)(DA)(DG)(DG)(DG) (DG)(DA)(DT)(DC)(DC) (DG)(DG)(DA)(DT) (DG)(DC)(DT)(DC)(DG)(DG)(DG)(DT)(DC)(DC) (DG)(DG)(DC)(DA)(DC)(DT) (DG)(DG)(DA) (DA)(DC)(DA)(DG)(DG)(DA)(DT)(DG)(DT)(DA) (DT)(DA)(DT)(DA)(DT)(DG)(DT) (DG)(DA) (DC)(DA)(DC)(DG)(DT)(DG)(DC)(DC)(DT)(DG) (DG)(DA)(DG)(DA)(DC)(DT)(DA)(DG) (DG) (DG)(DA)(DG)(DT)(DA)(DA)(DT)(DC)(DC)(DC) (DC)(DT)(DT)(DG)(DG)(DC)(DG)(DG)(DT) (DT)(DA)(DA)(DA)(DA)(DC)(DG)(DC)(DG)(DG) (DG)(DG)(DG)(DA)(DC)(DA)(DG)(DC)(DG)(DC) (DG)(DT)(DA)(DC)(DG)(DT)(DG)(DC)(DG) (DT)(DT)(DT)(DA)(DA)(DG)(DC)(DG)(DG)(DT) (DG) (DC)(DT)(DA)(DG)(DA)(DG)(DC)(DT) (DG)(DT)(DC)(DT)(DA)(DC)(DG)(DA)(DC)(DC) (DA)(DA) (DT)(DT)(DG)(DA)(DG)(DC)(DG) (DG)(DC)(DC)(DT)(DC)(DG)(DG)(DC)(DA)(DC) (DC)(DG)(DG) (DG)(DA)(DT)(DT)(DC)(DT) (DC)(DC)(DA)(DG)(DG)(DG)(DG)(DA)(DT)(DC) (DC)(DG)(DG)(DG) (DA)(DT) |
-Experimental details
-Structure determination
Method | cryo EM |
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Processing | single particle reconstruction |
Aggregation state | particle |
-Sample preparation
Concentration | 0.1 mg/mL |
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Buffer | pH: 7 |
Vitrification | Cryogen name: ETHANE |
-Electron microscopy
Microscope | FEI TITAN KRIOS |
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Image recording | Film or detector model: GATAN K3 (6k x 4k) / Average electron dose: 60.0 e/Å2 |
Electron beam | Acceleration voltage: 300 kV / Electron source: FIELD EMISSION GUN |
Electron optics | Illumination mode: FLOOD BEAM / Imaging mode: BRIGHT FIELD |
Experimental equipment | Model: Titan Krios / Image courtesy: FEI Company |