Direct visualization of dynamic structures of protein disaggregation molecular machines

Direct visualization of dynamic structures of protein disaggregation molecular machines
Snapshots (upper panels) and schematics (lower panels) of the ClpB closed rings from the movie obtained by HS-AFM. The closed rings are classified into round, spiral and twisted-half-spiral. A bar on upper left panel designates a scale of 2 nm. Credit: NINS/IMS

ClpB, an ATP-fueled protein molecular machine, disentangles and reactivates aggregated proteins. By using high-speed atomic force microscopy, conformational dynamics of ClpB were visualized for the first time. ClpB forms open- and closed-ring, and the closed-ring was further classified into three forms: round, spiral, and twisted half-spiral. These structures transformed each other during ATPase-cycle to perform protein disaggregation. This research will help to treat protein aggregations, which are related to various diseases and cause problems in industry.

When proteins are exposed stresses like a heat shock, they lose their native structure and form toxic insoluble aggregations. Bacterial molecular chaperone ClpB and its yeast homologue Hsp104 have an ability to disentangle and reactivate the aggregated proteins. ClpB forms hexameric ring structure and its protomer consists of two ATPase cores, AAA1 and AAA2, and two additional domains, N-domain and M-domain. Using the chemical energy of ATP hydrolysis, ClpB ring threads the aggregated proteins through its central pore to disentangle them. The disaggregation activity of ClpB is regulated by the rod-shaped M-domains surrounding the periphery of ClpB ring. However, the molecular-level mechanisms, such as how ATP binding and hydrolysis change the ClpB structure and how the changes induce disaggregation, are not known. Although the three-dimensional structure of ClpB/Hsp104 has been determined by X-ray crystallography and cryo-electron microscopic single-particle analysis, information about the dynamics of individual molecules were required to understand the mechanism.

By using a high-speed (HS-AFM), Uchihashi and co-workers succeeded in observing structural changes of ClpB molecules with a 100-ms temporal resolution for the first time. In the presence of ATP, ClpB forms hexameric closed- and open-ring (Fig. 1). The number of subunits in the ring and the polymorphism of the ring structures were further confirmed by native mass spectrometry and negative-staining electron microscopy analysis, respectively. During the HS-AFM observation, these two conformations converted each other, and the higher the ATP concentration, the greater the population of the closed ring. In addition, closed rings were further classified into "round" whose height was almost uniform, "spiral" in which the height changed continuously like a spiral staircase, and "twisted-half-spiral" in which two half-spiral structures faced each other (Fig. 1). The twisted-half-spiral conformation suggested that the hexameric ring consisted of two trimers. This was also supported by sedimentation velocity analytical ultracentrifugation. These three conformations also converted each other, and it turned out that the higher the ATP concentration, the higher the frequency of the conversions. These observations revealed that the ATP binding induced the closed ring formation and its hydrolysis caused significant structural changes between the round, the spiral, and the twisted-half-spiral conformations.

From the observations of ClpB mutants that were inhibited ATP binding or hydrolysis on the AAA1 and/or the AAA2, individual roles of these two domains on the structural dynamics were clarified. ATP binding to the AAA1 induces oligomerization of ClpB, and the hexameric state was stabilized by ATP binding to the AAA2. The structural changes between the round, the spiral, and the twisted-half-spiral forms were caused by ATP hydrolysis at AAA2 (Fig. 2). Moreover, the mutual structural changes of the closed rings were drastically decreased in an M-domain mutant that lost disaggregation activity but retained ATPase activity suggesting that the structural changes played an important role in the disaggregation reaction.

Direct visualization of dynamic structures of protein disaggregation molecular machines
Schematic drawings of the mutual structural changes of the closed rings are shown. The structures converted in an ATPase-cycle dependent manner. Credit: NINS/IMS

Protein aggregation is closely related to various diseases including Alzheimer's disease. The formation of aggregation is also problematic in the use of proteins in medical and industrial fields. The results of this research have a potential to contribute to treatment of such diseases and/or maintenance of useful proteins. Furthermore, ClpB belongs to AAA+ protein family that contains various important proteins contributing to such as DNA replication, membrane fusion, protein degradation, and circadian clock maintenance. The members of this family shared AAA+ domains as ATPase cores, and the results of this research can be expected to lead to elucidation of the common mechanism of these AAA+ family proteins.

More information: Takayuki Uchihashi et al, Dynamic structural states of ClpB involved in its disaggregation function, Nature Communications (2018). DOI: 10.1038/s41467-018-04587-w

Journal information: Nature Communications

Provided by National Institutes of Natural Sciences

Citation: Direct visualization of dynamic structures of protein disaggregation molecular machines (2018, June 1) retrieved 19 April 2024 from https://phys.org/news/2018-06-visualization-dynamic-protein-disaggregation-molecular.html
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.

Explore further

How a molecular motor untangles protein

32 shares

Feedback to editors