9P2R | pdb_00009p2r

Extended, CYR715-bound state of Manduca sexta soluble guanylate cyclase mutant beta C122S


ELECTRON MICROSCOPY

Starting Model(s)

Initial Refinement Model(s)
TypeSourceAccession CodeDetails
in silico modelAlphaFold 
Sample
Ligand-free Manduca sexta soluble guanylase cyclase variant
Specimen Preparation
Sample Aggregation StatePARTICLE
Vitrification InstrumentFEI VITROBOT MARK IV
Cryogen NameETHANE
Sample Vitrification DetailsCryo-EM samples were prepared by applying 3 ul to a glow-discharged Quantifoil R1.2/1.3 holey-carbon cryo-EM grid. The grid was blotted for 4 s with W ...Cryo-EM samples were prepared by applying 3 ul to a glow-discharged Quantifoil R1.2/1.3 holey-carbon cryo-EM grid. The grid was blotted for 4 s with Whatman #1 filter paper and then plunge-frozen in liquid ethane with a Mark IV Vitrobot (ThermoFisher) at 4 C and 100% humidity.
3D Reconstruction
Reconstruction MethodSINGLE PARTICLE
Number of Particles598571
Reported Resolution (Å)3.6
Resolution MethodFSC 0.143 CUT-OFF
Other DetailsNon-Uniform (NU) refinement was performed on the higher resolution 3D class. The resulting 3.6 A consensus density resembled previous sGC structures i ...Non-Uniform (NU) refinement was performed on the higher resolution 3D class. The resulting 3.6 A consensus density resembled previous sGC structures in the extended, NO-bound state. Other refinement strategies were attempted, but did not lead to higher resolution global map densities. To improve local resolution of the domains of CYR715-bound sGC, local refinement was also performed. Separate masks were created for each domain, and local refinement as implemented in cryoSPARC was used to improve the resolution of the catalytic and H-NOX domains of the global map. The subsequent local refinement resulted in 3.5 A and 3.4 A maps for the H-NOX and catalytic domains respectively. These maps were then combined with the consensus map to create the composite map herein.
Refinement Type
Symmetry TypePOINT
Map-Model Fitting and Refinement
Id1
Refinement SpaceREAL
Refinement ProtocolFLEXIBLE FIT
Refinement Target
Overall B Value
Fitting Procedure
DetailsRefinement was performed using iterative rounds of Phenix real space refinement and manual modeling in Coot. Phenix refinement was performed for separ ...Refinement was performed using iterative rounds of Phenix real space refinement and manual modeling in Coot. Phenix refinement was performed for separate domains of the model using the higher-resolution local maps of those domains.
Data Acquisition
Detector TypeGATAN K3 (6k x 4k)
Electron Dose (electrons/Å**2)1.25
Imaging Experiment1
Date of Experiment
Temperature (Kelvin)
Microscope ModelTFS KRIOS
Minimum Defocus (nm)500
Maximum Defocus (nm)1500
Minimum Tilt Angle (degrees)
Maximum Tilt Angle (degrees)
Nominal CS2.7
Imaging ModeBRIGHT FIELD
Specimen Holder ModelFEI TITAN KRIOS AUTOGRID HOLDER
Nominal Magnification
Calibrated Magnification
SourceFIELD EMISSION GUN
Acceleration Voltage (kV)300
Imaging Details
EM Software
TaskSoftware PackageVersion
PARTICLE SELECTIONcryoSPARC
IMAGE ACQUISITIONEPU
CTF CORRECTIONcryoSPARC
MODEL FITTINGUCSF ChimeraX
INITIAL EULER ASSIGNMENTcryoSPARC
FINAL EULER ASSIGNMENTcryoSPARC
CLASSIFICATIONcryoSPARC
RECONSTRUCTIONcryoSPARC
MODEL REFINEMENTPHENIX1.21.1_5286
MODEL REFINEMENTCoot
Image Processing
CTF Correction TypeCTF Correction DetailsNumber of Particles SelectedParticle Selection Details
PHASE FLIPPING AND AMPLITUDE CORRECTION1226641Autopicking was used to produce a stack of 2,299,895 particles. Particles showing poor alignment or broken complexes were removed using a series of 2D classification steps, leaving a particle stack of 902,997 particles that resembled sGC dimers.