PDB-5ofo: Cryo EM structure of the E. coli disaggregase ClpB (BAP form, DWB...

Basic information

• Entry: Database: PDB / ID: 5ofo
• Title: Cryo EM structure of the E. coli disaggregase ClpB (BAP form, DWB mutant), in the ATPgammaS state, bound to the model substrate casein
• Components: Chaperone protein ClpB,ATP-dependent Clp protease ATP-binding subunit ClpA,Chaperone protein ClpB
• Keywords: CHAPERONE / disaggregase / ClpB / AAA

Function / homology

Function:

endopeptidase Clp complex / protein quality control for misfolded or incompletely synthesized proteins / ATP-dependent peptidase activity / protein unfolding / cellular response to heat / response to heat / protein refolding / response to oxidative stress / ATP hydrolysis activity / proteolysis / ATP binding / identical protein binding / membrane / cytosol / cytoplasm

Domain/homology:

ATP-dependent Clp protease ATP-binding subunit ClpA / Chaperonin ClpB / ClpA/B, conserved site 2 / Chaperonins clpA/B signature 2. / ClpA/B, conserved site 1 / Chaperonins clpA/B signature 1. / ClpA/ClpB, AAA lid domain / AAA lid domain / Clp amino terminal domain, pathogenicity island component / : / Clp, repeat (R) domain / Clp repeat (R) domain profile. / Clp, N-terminal domain superfamily / ClpA/B family / Clp ATPase, C-terminal / AAA domain (Cdc48 subfamily) / C-terminal, D2-small domain, of ClpB protein / C-terminal, D2-small domain, of ClpB protein / ATPase family associated with various cellular activities (AAA) / ATPase, AAA-type, core / ATPases associated with a variety of cellular activities / AAA+ ATPase domain / P-loop containing nucleoside triphosphate hydrolase

Component:

PHOSPHOTHIOPHOSPHORIC ACID-ADENYLATE ESTER / ATP-dependent Clp protease ATP-binding subunit ClpA / Chaperone protein ClpB

• Biological species: Escherichia coli (E. coli)
• Method: ELECTRON MICROSCOPY / single particle reconstruction / cryo EM / Resolution: 4.6 Å
• Authors: Deville, C. / Carroni, M. / Franke, K.B. / Topf, M. / Bukau, B. / Mogk, A. / Saibil, H.R.
• Citation: Journal: Sci Adv / Year: 2017; Title: Structural pathway of regulated substrate transfer and threading through an Hsp100 disaggregase.; Authors: Célia Deville / Marta Carroni / Kamila B Franke / Maya Topf / Bernd Bukau / Axel Mogk / Helen R Saibil / ; Abstract: Refolding aggregated proteins is essential in combating cellular proteotoxic stress. Together with Hsp70, Hsp100 chaperones, including ClpB, form a powerful disaggregation machine that threads aggregated polypeptides through the central pore of tandem adenosine triphosphatase (ATPase) rings. To visualize protein disaggregation, we determined cryo-electron microscopy structures of inactive and substrate-bound ClpB in the presence of adenosine 5'--(3-thiotriphosphate), revealing closed AAA+ rings with a pronounced seam. In the substrate-free state, a marked gradient of resolution, likely corresponding to mobility, spans across the AAA+ rings with a dynamic hotspot at the seam. On the seam side, the coiled-coil regulatory domains are locked in a horizontal, inactive orientation. On the opposite side, the regulatory domains are accessible for Hsp70 binding, substrate targeting, and activation. In the presence of the model substrate casein, the polypeptide threads through the entire pore channel and increased nucleotide occupancy correlates with higher ATPase activity. Substrate-induced domain displacements indicate a pathway of regulated substrate transfer from Hsp70 to the ClpB pore, inside which a spiral of loops contacts the substrate. The seam pore loops undergo marked displacements, along with ordering of the regulatory domains. These asymmetric movements suggest a mechanism for ATPase activation and substrate threading during disaggregation.

History

Deposition	Jul 11, 2017	Deposition site: PDBE / Processing site: PDBE
Revision 1.0	Aug 16, 2017	Provider: repository / Type: Initial release
Revision 1.1	Aug 23, 2017	Group: Database references / Category: citation Item: _citation.page_first / _citation.page_last / _citation.pdbx_database_id_PubMed / _citation.title
Revision 1.2	Aug 21, 2019	Group: Data collection / Category: em_software / Item: _em_software.name
Revision 1.3	Oct 23, 2019	Group: Data collection / Other / Category: atom_sites / cell Item: _atom_sites.fract_transf_matrix[1][1] / _atom_sites.fract_transf_matrix[2][2] / _atom_sites.fract_transf_matrix[3][3] / _cell.Z_PDB
Revision 1.4	Nov 6, 2019	Group: Data collection / Database references / Category: pdbx_database_related / Item: _pdbx_database_related.content_type
Revision 1.5	May 8, 2024	Group: Data collection / Database references / Category: chem_comp_atom / chem_comp_bond / database_2 Item: _database_2.pdbx_DOI / _database_2.pdbx_database_accession

Assembly

Deposited unit

C: Chaperone protein ClpB,ATP-dependent Clp protease ATP-binding subunit ClpA,Chaperone protein ClpB

F: Chaperone protein ClpB,ATP-dependent Clp protease ATP-binding subunit ClpA,Chaperone protein ClpB

E: Chaperone protein ClpB,ATP-dependent Clp protease ATP-binding subunit ClpA,Chaperone protein ClpB

D: Chaperone protein ClpB,ATP-dependent Clp protease ATP-binding subunit ClpA,Chaperone protein ClpB

B: Chaperone protein ClpB,ATP-dependent Clp protease ATP-binding subunit ClpA,Chaperone protein ClpB

A: Chaperone protein ClpB,ATP-dependent Clp protease ATP-binding subunit ClpA,Chaperone protein ClpB

hetero molecules

Summary:

• 589 kDa, 6 polymers

Component details:

	Theoretical mass	Number of molelcules
Total (without water)	589,489	17
Polymers	583,733	6
Non-polymers	5,756	11
Water	0	0

1

Summary:

• Idetical with deposited unit
• defined by author&software
• Evidence: gel filtration, Complex stable by gel filtration and stable on EM grids

Symmetry operations:

Type	Name	Symmetry operation	Number
identity operation	1_555		1

Calculated values:

Buried area	47030 Å2
ΔGint	-48 kcal/mol
Surface area	192730 Å2
Method	PISA

Components

#1: Protein

C F E D B A
Chaperone protein ClpB,ATP-dependent Clp protease ATP-binding subunit ClpA,Chaperone protein ClpB / Heat shock protein F84.1

Details:

Mass: 97288.914 Da / Num. of mol.: 6
Source method: isolated from a genetically manipulated source
Source: (gene. exp.) Escherichia coli (strain K12) (bacteria), (gene. exp.) Escherichia coli (E. coli)
Strain: K12 / Gene: clpB, htpM, b2592, JW2573, clpA, lopD, b0882, JW0866 / Production host: Escherichia coli (E. coli) / References: UniProt: P63284, UniProt: P0ABH9

#2: Chemical

C-901 C-902 F-901 F-902 E-901 E-902 D-901 D-902 B-901 B-902 A-901
ChemComp-AGS / PHOSPHOTHIOPHOSPHORIC ACID-ADENYLATE ESTER / ATP-GAMMA-S / ADENOSINE 5'-(3-THIOTRIPHOSPHATE) / ADENOSINE 5'-(GAMMA-THIOTRIPHOSPHATE) / ADENOSINE-5'-DIPHOSPHATE MONOTHIOPHOSPHATE

Details:

Mass: 523.247 Da / Num. of mol.: 11 / Source method: obtained synthetically / Formula: C₁₀H₁₆N₅O₁₂P₃S / Comment: ATP-gamma-S, energy-carrying molecule analogue*YM

Experimental details

Experiment

• Experiment: Method: ELECTRON MICROSCOPY
• EM experiment: Aggregation state: PARTICLE / 3D reconstruction method: single particle reconstruction

Sample preparation

• Component: Name: ClpB, BAP form, double walker B mutant / Type: COMPLEX / Entity ID: #1 / Source: RECOMBINANT
• Molecular weight: Value: 0.57 MDa / Experimental value: NO
• Source (natural): Organism: Escherichia coli (E. coli)
• Source (recombinant): Organism: Escherichia coli (E. coli)
• Buffer solution: pH: 7.4

Buffer component

ID	Conc.	Name	Formula	Buffer-ID
1	25 mmol/L	tris	TrisHCl	1
2	25 mmol/L	sodium chloride	NaCl	1
3	10 mmol/L	magnesium chloride	MgCl2	1
4	2 mmol/L	adenosine 5'-O-(3-thio)triphosphate	ATPgammaS	1
5	1 mmol/L	dithiothreitol	DTT	1

• Specimen: Conc.: 0.7 mg/ml / Embedding applied: NO / Shadowing applied: NO / Staining applied: NO / Vitrification applied: YES
• Specimen support: Grid material: COPPER / Grid mesh size: 400 divisions/in. / Grid type: Agar lacey carbon
• Vitrification: Instrument: FEI VITROBOT MARK III / Cryogen name: ETHANE / Chamber temperature: 295 K

Electron microscopy imaging

• Experimental equipment: Model: Titan Krios / Image courtesy: FEI Company
• Microscopy: Model: FEI TITAN KRIOS
• Electron gun: Electron source: FIELD EMISSION GUN / Accelerating voltage: 300 kV / Illumination mode: FLOOD BEAM
• Electron lens: Mode: BRIGHT FIELD / Nominal defocus max: 3000 nm / Nominal defocus min: 1000 nm
• Specimen holder: Cryogen: NITROGEN / Specimen holder model: FEI TITAN KRIOS AUTOGRID HOLDER
• Image recording: Electron dose: 1 e/Ų / Detector mode: COUNTING / Film or detector model: GATAN K2 SUMMIT (4k x 4k)
• Image scans: Sampling size: 5 µm / Movie frames/image: 50

Processing

• Software: Name: PHENIX / Version: 1.11.1_2575: / Classification: refinement

EM software

ID	Name	Version	Category	Details
1	Gautomatch		particle selection
2	EPU		image acquisition
4	CTFFIND	4	CTF correction	for CTF estimation
7	iMODFIT		model fitting
8	Flex-EM		model fitting
10	RELION	2	initial Euler assignment
11	RELION	2	final Euler assignment
12	RELION	2	classification
13	RELION	2	3D reconstruction
14	PHENIX	1.11.1	model refinement

• CTF correction: Type: PHASE FLIPPING AND AMPLITUDE CORRECTION
• Particle selection: Num. of particles selected: 500000
• Symmetry: Point symmetry: C₁ (asymmetric)
• 3D reconstruction: Resolution: 4.6 Å / Resolution method: FSC 0.143 CUT-OFF / Num. of particles: 230000 / Symmetry type: POINT
• Atomic model building: Protocol: FLEXIBLE FIT / Space: REAL / Target criteria: Local correlation coefficient; Details: Initial models of the monomer were generated using MODELLER v9.17 with previously determined crystal structures of ClpB or ClpB domains as templates (PDB ids 4CIU, 1QVR, 4HSE and 4LJ9). The crystal structure of E. coli ClpB (4CIU) was used as a main template, the crystal structure of T. thermophilus (1QVR) was used to model positions of the NTD and the crystal structures of AAA1 and AAA2 of E. coli ClpB (4HSE and 4LJ9) were used to model the pore loops disordered in other crystal structures. Initial rigid body fitting of the monomers in the map was manually done in Chimera using the Fit-in-Map tool. iMODFIT was used for fitting involving large domain motions. FlexEM was then used for refinement of secondary structures and loops in the map. Quality and improvement of the fit was assessed with TEMPy using the Segment based Manders Overlap Coefficient (SMOC) scores and segment based cross correlation scores. Ridig body fitting of ATPgammaS (structure extracted from PDB id 3EIH) into the nucleotide biding sides was manually done in Chimera using the Fit-in-Map tool. The target map for fitting of ATPgammaS was the difference map between experimental map and map generated using the nucleotide-free protein model revealing nucleotide densities. A round of real-space refinement was performed in phenix using energy minimization to fix the model's geometry and clashes.

Refine LS restraints

Refine-ID	Type	Dev ideal	Number
ELECTRON MICROSCOPY	f_bond_d	0.008	33963
ELECTRON MICROSCOPY	f_angle_d	1.112	45806
ELECTRON MICROSCOPY	f_dihedral_angle_d	6.985	21099
ELECTRON MICROSCOPY	f_chiral_restr	0.058	5160
ELECTRON MICROSCOPY	f_plane_restr	0.008	5999