PDB-8f4x: Top-down design of protein architectures with reinforcement learning

Basic information

• Entry: Database: PDB / ID: 8f4x
• Title: Top-down design of protein architectures with reinforcement learning
• Components: RC_I_1-H11
• Keywords: DE NOVO PROTEIN / nanoparticle / capsid / oligomer / de novo design / rosetta / cryoEM / reinforcement learning
• Biological species: synthetic construct (others)
• Method: ELECTRON MICROSCOPY / single particle reconstruction / cryo EM / Resolution: 3.01 Å
• Authors: Borst, A.J. / Baker, D.

Funding support

United States, 1items

Organization	Grant number	Country
Howard Hughes Medical Institute (HHMI)		United States

• Citation: Journal: Science / Year: 2023; Title: Top-down design of protein architectures with reinforcement learning.; Authors: Isaac D Lutz / Shunzhi Wang / Christoffer Norn / Alexis Courbet / Andrew J Borst / Yan Ting Zhao / Annie Dosey / Longxing Cao / Jinwei Xu / Elizabeth M Leaf / Catherine Treichel / Patrisia Litvicov / Zhe Li / Alexander D Goodson / Paula Rivera-Sánchez / Ana-Maria Bratovianu / Minkyung Baek / Neil P King / Hannele Ruohola-Baker / David Baker / ; Abstract: As a result of evolutionary selection, the subunits of naturally occurring protein assemblies often fit together with substantial shape complementarity to generate architectures optimal for function in a manner not achievable by current design approaches. We describe a "top-down" reinforcement learning-based design approach that solves this problem using Monte Carlo tree search to sample protein conformers in the context of an overall architecture and specified functional constraints. Cryo-electron microscopy structures of the designed disk-shaped nanopores and ultracompact icosahedra are very close to the computational models. The icosohedra enable very-high-density display of immunogens and signaling molecules, which potentiates vaccine response and angiogenesis induction. Our approach enables the top-down design of complex protein nanomaterials with desired system properties and demonstrates the power of reinforcement learning in protein design.

History

Deposition	Nov 11, 2022	Deposition site: RCSB / Processing site: RCSB
Revision 1.0	May 10, 2023	Provider: repository / Type: Initial release

Assembly

Deposited unit

0: RC_I_1-H11

1: RC_I_1-H11

2: RC_I_1-H11

3: RC_I_1-H11

4: RC_I_1-H11

5: RC_I_1-H11

6: RC_I_1-H11

7: RC_I_1-H11

8: RC_I_1-H11

9: RC_I_1-H11

A: RC_I_1-H11

B: RC_I_1-H11

C: RC_I_1-H11

D: RC_I_1-H11

E: RC_I_1-H11

F: RC_I_1-H11

G: RC_I_1-H11

H: RC_I_1-H11

I: RC_I_1-H11

J: RC_I_1-H11

K: RC_I_1-H11

L: RC_I_1-H11

M: RC_I_1-H11

N: RC_I_1-H11

O: RC_I_1-H11

P: RC_I_1-H11

Q: RC_I_1-H11

R: RC_I_1-H11

S: RC_I_1-H11

T: RC_I_1-H11

U: RC_I_1-H11

V: RC_I_1-H11

W: RC_I_1-H11

X: RC_I_1-H11

Y: RC_I_1-H11

Z: RC_I_1-H11

a: RC_I_1-H11

b: RC_I_1-H11

c: RC_I_1-H11

d: RC_I_1-H11

e: RC_I_1-H11

f: RC_I_1-H11

g: RC_I_1-H11

h: RC_I_1-H11

i: RC_I_1-H11

j: RC_I_1-H11

k: RC_I_1-H11

l: RC_I_1-H11

m: RC_I_1-H11

n: RC_I_1-H11

o: RC_I_1-H11

p: RC_I_1-H11

q: RC_I_1-H11

r: RC_I_1-H11

s: RC_I_1-H11

t: RC_I_1-H11

u: RC_I_1-H11

v: RC_I_1-H11

w: RC_I_1-H11

x: RC_I_1-H11

Summary:

• 466 kDa, 60 polymers

Component details:

	Theoretical mass	Number of molelcules
Total (without water)	465,898	60
Polymers	465,898	60
Non-polymers	0	0
Water	0

1

Summary:

• Idetical with deposited unit
• defined by author
• Evidence: electron microscopy, negative stain EM, cryoEM

Symmetry operations:

Type	Name	Symmetry operation	Number
identity operation	1_555		1

Components

#1: Protein

0 1 2 3 4 5 6 7 8 9 A B C D E F G H I ...
RC_I_1-H11

Details:

Mass: 7764.962 Da / Num. of mol.: 60
Source method: isolated from a genetically manipulated source
Source: (gene. exp.) synthetic construct (others) / Production host: Escherichia coli (E. coli)

Experimental details

Experiment

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

Sample preparation

• Component: Name: RC_I_1-H11 / Type: COMPLEX / Entity ID: all / Source: RECOMBINANT
• Source (natural): Organism: Escherichia coli (E. coli)
• Source (recombinant): Organism: Escherichia coli (E. coli)
• Buffer solution: pH: 7.5
• Specimen: Conc.: 0.8 mg/ml / Embedding applied: NO / Shadowing applied: NO / Staining applied: NO / Vitrification applied: YES
• Specimen support: Details: Thin layer of continuous carbon / Grid type: Quantifoil R2/2
• Vitrification: Cryogen name: ETHANE

Electron microscopy imaging

• Microscopy: Model: TFS GLACIOS
• Electron gun: Electron source: FIELD EMISSION GUN / Accelerating voltage: 200 kV / Illumination mode: FLOOD BEAM
• Electron lens: Mode: BRIGHT FIELDBright-field microscopy / Nominal defocus max: 1700 nm / Nominal defocus min: 800 nm
• Image recording: Electron dose: 59 e/Ų / Detector mode: COUNTING / Film or detector model: GATAN K2 SUMMIT (4k x 4k)

Processing

• Software: Name: PHENIX / Version: 1.16_3549: / Classification: refinement

EM software

ID	Name	Version	Category
7	Rosetta		model fitting
8	MDFF		model fitting
9	PHENIX		model fitting
11	cryoSPARC	3.2	initial Euler assignment
12	cryoSPARC	3.2	final Euler assignment
15	Rosetta		model refinement
16	MDFF		model refinement
17	PHENIX		model refinement

• CTF correction: Type: NONE
• Particle selection: Num. of particles selected: 433599
• 3D reconstruction: Resolution: 3.01 Å / Resolution method: FSC 0.143 CUT-OFF / Num. of particles: 153765 / Symmetry type: POINT

Refine LS restraints

Refine-ID	Type	Dev ideal	Number
ELECTRON MICROSCOPY	f_bond_d	0.004	33120
ELECTRON MICROSCOPY	f_angle_d	0.451	44520
ELECTRON MICROSCOPY	f_dihedral_angle_d	2.544	21000
ELECTRON MICROSCOPY	f_chiral_restr	0.033	5040
ELECTRON MICROSCOPY	f_plane_restr	0.003	6000