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Showing 1 - 50 of 3,422 items for (author: feng & d)
EMDB-41479:
nhTMEM16 R432A mutant in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+
Method: single particle / : Feng Z, Accardi A
PDB-8tpo:
nhTMEM16 R432A mutant in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+
Method: single particle / : Feng Z, Accardi A
EMDB-38215:
Human GPR34 -Gi complex bound to S3E-LysoPS
Method: single particle / : Kawahara R, Shihoya W, Nureki O
EMDB-38217:
Human GPR34 -Gi complex bound to S3E-LysoPS, receptor focused
Method: single particle / : Kawahara R, Shihoya W, Nureki O
PDB-8xbe:
Human GPR34 -Gi complex bound to S3E-LysoPS
Method: single particle / : Kawahara R, Shihoya W, Nureki O
PDB-8xbg:
Human GPR34 -Gi complex bound to S3E-LysoPS, receptor focused
Method: single particle / : Kawahara R, Shihoya W, Nureki O
EMDB-41453:
nhTMEM16 lipid scramblase in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (closed state)
Method: single particle / : Feng Z, Accardi A
EMDB-41454:
nhTMEM16 lipid scramblase in lipid nanodiscs with MSP2N2 scaffold protein in the presence of Ca2+ (open state)
Method: single particle / : Feng Z, Accardi A
EMDB-41455:
nhTMEM16 lipid scramblase in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (open state)
Method: single particle / : Feng Z, Accardi A
EMDB-41457:
nhTMEM16 lipid scramblase in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (closed state) (consensus map)
Method: single particle / : Feng Z, Accardi A
EMDB-41458:
nhTMEM16 lipid scramblase in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (closed state)(local refined monomer map)
Method: single particle / : Feng Z, Accardi A
EMDB-41477:
nhTMEM16 lipid scramblase in lipid nanodiscs with MSP1E3 scaffold protein in the absence of Ca2+
Method: single particle / : Feng Z, Accardi A
EMDB-41478:
nhTMEM16 lipid scramblase in lipid nanodiscs with MSP2N2 scaffold protein in the presence of Ca2+ (intermediate state)
Method: single particle / : Feng Z, Accardi A
EMDB-41480:
nhTMEM16 R432A mutant in lipid nanodiscs with MSP2N2 scaffold protein in the presence of Ca2+
Method: single particle / : Feng Z, Accardi A
EMDB-41481:
nhTMEM16 A444P mutant in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (long TM6)
Method: single particle / : Feng Z, Accardi A
EMDB-41482:
nhTMEM16 A444P mutant in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (short TM6)
Method: single particle / : Feng Z, Accardi A
EMDB-41483:
nhTMEM16 A444P mutant in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (bent TM6)
Method: single particle / : Feng Z, Accardi A
EMDB-41484:
nhTMEM16 A444P mutant in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (long TM6/short TM6)
Method: single particle / : Feng Z, Accardi A
PDB-8toi:
nhTMEM16 lipid scramblase in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (closed state)
Method: single particle / : Feng Z, Accardi A
PDB-8tok:
nhTMEM16 lipid scramblase in lipid nanodiscs with MSP2N2 scaffold protein in the presence of Ca2+ (open state)
Method: single particle / : Feng Z, Accardi A
PDB-8tol:
nhTMEM16 lipid scramblase in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (open state)
Method: single particle / : Feng Z, Accardi A
PDB-8tpm:
nhTMEM16 lipid scramblase in lipid nanodiscs with MSP1E3 scaffold protein in the absence of Ca2+
Method: single particle / : Feng Z, Accardi A
PDB-8tpn:
nhTMEM16 lipid scramblase in lipid nanodiscs with MSP2N2 scaffold protein in the presence of Ca2+ (intermediate state)
Method: single particle / : Feng Z, Accardi A
PDB-8tpp:
nhTMEM16 R432A mutant in lipid nanodiscs with MSP2N2 scaffold protein in the presence of Ca2+
Method: single particle / : Feng Z, Accardi A
PDB-8tpq:
nhTMEM16 A444P mutant in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (long TM6)
Method: single particle / : Feng Z, Accardi A
PDB-8tpr:
nhTMEM16 A444P mutant in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (short TM6)
Method: single particle / : Feng Z, Accardi A
PDB-8tps:
nhTMEM16 A444P mutant in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (bent TM6)
Method: single particle / : Feng Z, Accardi A
PDB-8tpt:
nhTMEM16 A444P mutant in lipid nanodiscs with MSP1E3 scaffold protein in the presence of Ca2+ (long TM6/short TM6)
Method: single particle / : Feng Z, Accardi A
EMDB-17779:
Structure of human oligosaccharyltransferase OST-A complex bound to NGI-1
Method: single particle / : Ramirez AS, Kowal J, Locher KP
PDB-8pn9:
Structure of human oligosaccharyltransferase OST-A complex bound to NGI-1
Method: single particle / : Ramirez AS, Kowal J, Locher KP
EMDB-42383:
Cryo-EM map of the human CTF18-RFC-PCNA binary complex in the three-subunit binding state (state 2)
Method: single particle / : Wang F, He Q, Li H
EMDB-42384:
Cryo-EM map of the human CTF18-RFC-PCNA binary complex in the four-subunit binding state (state 3)
Method: single particle / : Wang F, He Q, Li H
EMDB-42385:
Cryo-EM map of the human CTF18-RFC-PCNA-DNA ternary complex with narrow PCNA opening state I (state 5)
Method: single particle / : Wang F, He Q, Li H
EMDB-42386:
Cryo-EM map of the human CTF18-RFC-PCNA-DNA ternary complex in the five-subunit binding state (state 4)
Method: single particle / : Wang F, He Q, Li H
EMDB-42388:
Cryo-EM map of the human CTF18-RFC-PCNA-DNA ternary complex with narrow PCNA opening state II (state 6)
Method: single particle / : Wang F, He Q, Li H
EMDB-42389:
Cryo-EM map of the human CTF18-RFC-PCNA-DNA ternary complex with cracked and closed PCNA (state 7)
Method: single particle / : Wang F, He Q, Li H
EMDB-42406:
Cryo-EM map of the human CTF18-RFC alone in the apo state (State 1)
Method: single particle / : Wang F, He Q, Li H
PDB-8umt:
Atomic model of the human CTF18-RFC-PCNA binary complex in the three-subunit binding state (state 2)
Method: single particle / : Wang F, He Q, Li H
PDB-8umu:
Atomic model of the human CTF18-RFC-PCNA binary complex in the four-subunit binding state (state 3)
Method: single particle / : Wang F, He Q, Li H
PDB-8umv:
Atomic model of the human CTF18-RFC-PCNA-DNA ternary complex with narrow PCNA opening state I (state 5)
Method: single particle / : Wang F, He Q, Li H
PDB-8umw:
Atomic model of the human CTF18-RFC-PCNA-DNA ternary complex in the five-subunit binding state (state 4)
Method: single particle / : Wang F, He Q, Li H
PDB-8umy:
Atomic model of the human CTF18-RFC-PCNA-DNA ternary complex with narrow PCNA opening state II (state 6)
Method: single particle / : Wang F, He Q, Li H
PDB-8un0:
Atomic model of the human CTF18-RFC-PCNA-DNA ternary complex with cracked and closed PCNA (state 7)
Method: single particle / : Wang F, He Q, Li H
PDB-8unj:
Atomic model of the human CTF18-RFC alone in the apo state (State 1)
Method: single particle / : Wang F, He Q, Li H
EMDB-36732:
Cryo-EM structure of the gasdermin pore from Trichoplax adhaerens
Method: single particle / : Hou YJ, Sun Q, Zeng H, Ding J
EMDB-36733:
Cryo-EM structure of the gasdermin pore from Trichoplax adhaerens
Method: single particle / : Hou YJ, Sun Q, Zeng H, Ding J
EMDB-36734:
Cryo-EM structure of RCD-1 pore from Neurospora crassa
Method: single particle / : Hou YJ, Sun Q, Li Y, Ding J
PDB-8jyw:
Cryo-EM structure of the gasdermin pore from Trichoplax adhaerens
Method: single particle / : Hou YJ, Sun Q, Zeng H, Ding J
PDB-8jyz:
Cryo-EM structure of RCD-1 pore from Neurospora crassa
Method: single particle / : Hou YJ, Sun Q, Li Y, Ding J
EMDB-34992:
Cryo-EM Structure of CdnG-E2 complex from Serratia marcescens (UltrAuFoil)
Method: single particle / : Xiao J, Wang L
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