Supramolecular tholos-like architecture constituted by archaeal proteins without functional annotation

Maho Yagi-Utsumi,Jimin Park,Jooyoung Lee,Hiroki Watanabe,Kazuyoshi Murata,Keehyoung Joo,Raymond N Burton‐Smith ,Rintaro Inoue,Tatsuya Suzuki,Atsuji Kodama,Arunima Sikdar,Takayuki Uchihashi,Masaaki Sugiyama,Kentaro Ishii,Susumu Uchiyama,Chihong Song,Hirokazu Yagi,Tadashi Satoh,Toshiya Kozai,Koichi Kato

doi:10.1038/s41598-020-58371-2

Abstract

Euryarchaeal genomes encode proteasome-assembling chaperone homologs, PbaA and PbaB, although archaeal proteasome formation is a chaperone-independent process. Homotetrameric PbaB functions as a proteasome activator, while PbaA forms a homopentamer that does not interact with the proteasome. Notably, PbaA forms a complex with PF0014, an archaeal protein without functional annotation. In this study, based on our previous research on PbaA crystal structure, we performed an integrative analysis of the supramolecular structure of the PbaA/PF0014 complex using native mass spectrometry, solution scattering, high-speed atomic force microscopy, and electron microscopy. The results indicated that this highly thermostable complex constitutes ten PbaA and ten PF0014 molecules, which are assembled into a dumbbell-shaped structure. Two PbaA homopentameric rings correspond to the dumbbell plates, with their N-termini located outside of the plates and C-terminal segments left mobile. Furthermore, mutant PbaA lacking the mobile C-terminal segment retained the ability to form a complex with PF0014, allowing 3D modeling of the complex. The complex shows a five-column tholos-like architecture, in which each column comprises homodimeric PF0014, harboring a central cavity, which can potentially accommodate biomacromolecules including proteins. Our findings provide insight into the functional roles of Pba family proteins, offering a novel framework for designing functional protein cages.

Highlights

Small-angle X-ray scattering (SAXS)-based high-throughput structural analysis of proteins from P. furiosus revealed that PbaA interacts with PF0014, an archaeal protein without functional annotation, forming a massive complex with a radius of gyration of 55.0 Å16
In this study, we attempted the structural characterization of the PbaA/PF0014 complex using an integrative biophysical approach implementing high-speed atomic force field microscopy (HS-AFM), native mass spectrometry (MS), electron microscopy (EM), and solution X-ray and neutron scattering
We prepared PbaA and PF0014 as bacterially expressed recombinant proteins with an N-terminal hexahistidine tag. Equimolar mixtures of these proteins were subjected to size-exclusion chromatography (SEC)-small-angle X-ray scattering (SAXS), which revealed a high-molecular weight species with an estimated radius of gyration (Rg) of 54.6 Å and maximum dimension (Dmax) of 165 Å (Fig. 1A–D and Supplementary Figure S1)

Summary

Introduction

Small-angle X-ray scattering (SAXS)-based high-throughput structural analysis of proteins from P. furiosus revealed that PbaA interacts with PF0014, an archaeal protein without functional annotation, forming a massive complex with a radius of gyration of 55.0 Å16. This protein is conserved in Euryarchaeota species and shares no sequence similarity with the proteasomal subunits, suggesting its functional role independent of the proteasome[17]. In this study, we attempted the structural characterization of the PbaA/PF0014 complex using an integrative biophysical approach implementing high-speed atomic force field microscopy (HS-AFM), native mass spectrometry (MS), electron microscopy (EM), and solution X-ray and neutron scattering

Methods

Results

Conclusion