Menu

Close

Refolding activity of bacterial Hsp90 in vivo reveals ancient chaperoning function

Tania Moran Luengo, Toveann Ahlnas, Anna T. Hoekstra, Celia R. Berkers, Matthias P. Mayer, Stefan G.D. Rudiger

Preprint posted on November 05, 2018 https://www.biorxiv.org/content/early/2018/11/05/462549

Why the need for Hsp90? Clever experiments reveal the importance of this chaperone in refolding proteins after heat shock in E. coli.

Selected by Tessa Sinnige

Categories: biochemistry

Background

Protein folding inside the living cell is assisted by molecular chaperones. Many of these are called heat shock proteins, since they are not only involved in aiding protein folding after synthesis, but are also upregulated upon heat stress in order to refold denatured proteins, and prevent misfolding and aggregation (1). Whereas the function and mechanisms of heat shock proteins such as Hsp70 have been well characterised, the function of Hsp90 is less clear. Hsp90 is highly abundant both in prokaryotes and eukaryotes, signifying its conserved and critical cellular role. Previously, the Rüdiger lab showed that Hsp90 is required to alleviate the folding block caused by Hsp70, which actually can prevent refolding by binding to and occluding critical hydrophobic sites in the substrate (2). In the current preprint, the authors address the question under which cellular circumstances bacterial Hsp90 is required for efficient folding.

 

Results

To assess protein folding in E. coli, the authors established an elegant assay based on the recombinant expression of luciferase, which produces light only when correctly folded. Hsp90 inhibitors were added either before luciferase expression was induced, or at the onset of a heat shock that left most of the luciferase unfolded (Figure A). Surprisingly, inhibiting Hsp90 just before the synthesis of luciferase was initiated did not have a large effect, showing that the role of this chaperone in the de novo folding is limited. Conversely, adding the inhibitors after a period of luciferase expression and just before the heat shock had a more dramatic effect, strongly decreasing the fraction of active luciferase in a dose-dependent manner (Figure B). This effect could be extended from luciferase to the native E. coli proteome, given that Hsp90 inhibition just before heat shock led to a larger proportion of endogenous proteins that misfolded and aggregated, as judged from SDS-PAGE band intensities of the supernatant and pellet fractions.

 

A) Design of the assay. B) Effect of varying concentrations of the Hsp90 inhibitor geldanamycin on luciferase refolding after heat shock. Reproduced from figure 2AB of the preprint under a CC-BY-NC-ND 4.0 International license.

 

The authors furthermore suggest that Hsp90 may stabilise the folded state of proteins, based on the observation that inhibition of Hsp90 before the start of luciferase synthesis resulted in less recovery after a brief heat shock. Finally, they hypothesised that Hsp90 may promote protein folding in the cell by reducing the overall energy consumption which would be especially important under conditions of cellular stress, and indeed they were able to show by mass spectrometry that less ATP is consumed overall if Hsp90 is added to the Hsp70 system in a reconstituted assay for luciferase refolding.

 

Why I chose this preprint

I really like the elegant experimental design and clear-cut results presented in this study, leading to concrete advances in our understanding of the function of Hsp90. The authors took a similar approach in their previous paper (2) and it is great to see that they were able to extend this to the in vivo environment provided by the humble model organism E. coli. In these times of continuous technological advances, big data and what not, this type of science is refreshing and I would like to see more of it!

 

Questions

The authors convincingly show that the global E. coli proteome depends on Hsp90 for efficient refolding after heat shock, and that the effect of Hsp90 on initial luciferase folding is rather modest. However, could it be that a subset of E. coli proteins may depend on Hsp90 for de novo folding, as has been shown in eukaryotes (1)?

Related to this, I can imagine that the ‘unfolded proteome’ of newly synthesized proteins may differ from that of denatured proteins after heat shock, which will be the less thermodynamically stable proteins. Could the authors speculate if this may influence Hsp90 dependence, i.e. if the set of heat-denatured proteins may contain more Hsp90 clients?

With respect to the authors’ previous findings, would it be possible that higher Hsp70 levels induced by the heat shock increase the demand for Hsp90 to alleviate the folding block?

I would also like to ask about the suggestion that Hsp90 stabilises the native state, based on the increased sensitivity after a brief heat shock to Hsp90 inhibition from the start of the assay. Assuming that chaperones do not change the native state of a protein compared to spontaneous folding, I would think the thermodynamic stability of folded luciferase itself would remain the same whether or not Hsp90 is inhibited. Could it just be an additive effect of the slight influence on de novo folding (which still went down to 75% at high inhibitor concentrations) combined with the reduced refolding after heat shock? Or were the data (in figure 4 of the preprint) normalised to the luciferase activity before the heat shock for each of the inhibitor concentrations?

Finally, more generally, could the authors comment on which of their findings they expect to apply to eukaryotes as well, and some of the potential differences?

 

References

  1. Kim, Y. E., Hipp, M. S., Bracher, A., Hayer-Hartl, M., and Ulrich Hartl, F. (2013) Molecular Chaperone Functions in Protein Folding and Proteostasis. Annu. Rev. Biochem.82, 323–355.
  2. Morán Luengo, T., Kityk, R., Mayer, M. P., and Rüdiger, S. G. D. (2018) Hsp90 Breaks the Deadlock of the Hsp70 Chaperone System. Mol. Cell70, 545–552.

 

Posted on: 22nd November 2018

Read preprint (No Ratings Yet)




  • Have your say

    Your email address will not be published. Required fields are marked *

    This site uses Akismet to reduce spam. Learn how your comment data is processed.

    Sign up to customise the site to your preferences and to receive alerts

    Register here

    Also in the biochemistry category:

    The autophagic membrane tether ATG2A transfers lipids between membranes

    Shintaro Maeda, Chinatsu Otomo, Takanori Otomo



    Selected by Sandra Malmgren Hill

    LTK is an ER-resident receptor tyrosine kinase that regulates secretion

    Federica G. Centonze, Veronika Reiterer, Karsten Nalbach, et al.



    Selected by Nicola Stevenson

    1

    Plant photoreceptors and their signaling components compete for binding to the ubiquitin ligase COP1 using their VP-peptide motifs

    Kelvin Lau, Roman Podolec, Richard Chappuis, et al.



    Selected by Martin Balcerowicz

    HIV-1 Gag specifically restricts PI(4,5)P2 and cholesterol mobility in living cells creating a nanodomain platform for virus assembly

    C. Favard, J. Chojnacki, P. Merida, et al.



    Selected by Amberley Stephens

    Aqueous synthesis of a small-molecule lanthanide chelator amenable to copper-free click chemistry

    Stephanie Cara Bishop, Robert Winefield, Asokan Anbanandam, et al.



    Selected by Zhang-He Goh

    Hepatocyte-specific deletion of Pparα promotes NASH in the context of obesity

    Marion Regnier, Arnaud Polizzi, Sarra Smati, et al.



    Selected by Pablo Ranea Robles

    Microfluidic protein isolation and sample preparation for high resolution cryo-EM

    Claudio Schmidli, Stefan Albiez, Luca Rima, et al.



    Selected by David Wright

    ENDOSOMAL MEMBRANE TENSION CONTROLS ESCRT-III-DEPENDENT INTRA-LUMENAL VESICLE FORMATION

    Vincent Mercier, Jorge Larios, Guillaume Molinard, et al.



    Selected by Nicola Stevenson

    1

    Dynamic Aha1 Co-Chaperone Binding to Human Hsp90

    Javier Oroz, Laura J Blair, Markus Zweckstetter



    Selected by Reid Alderson

    1

    A DNA-based voltmeter for organelles

    Anand Saminathan, John Devany, Kavya S Pillai, et al.



    Selected by Robert Mahen

    1

    Structures of the Otopetrin Proton Channels Otop1 and Otop3

    Kei Saotome, Bochuan Teng, Che Chun (Alex) Tsui, et al.



    Selected by David Wright

    Inactive USP14 and inactive UCHL5 cause accumulation of distinct ubiquitinated proteins in mammalian cells

    Jayashree Chadchankar, Victoria Korboukh, Peter Doig, et al.



    Selected by Mila Basic

    S-acylated Golga7b stabilises DHHC5 at the plasma membrane to regulate desmosome assembly and cell adhesion.

    Keith T Woodley, Mark O Collins



    Selected by Abagael Lasseigne

    3

    A complex containing lysine-acetylated actin inhibits the formin INF2

    Mu A, Tak Shun Fung, Arminja N. Kettenbach, et al.



    Selected by Laura McCormick

    1

    Super-resolution Molecular Map of Basal Foot Reveals Novel Cilium in Airway Multiciliated Cells

    Quynh Nguyen, Zhen Liu, Rashmi Nanjundappa, et al.



    Selected by Robert Mahen

    Atlas of Subcellular RNA Localization Revealed by APEX-seq

    Furqan M Fazal, Shuo Han, Pornchai Kaewsapsak, et al.

    AND

    Proximity RNA labeling by APEX-Seq Reveals the Organization of Translation Initiation Complexes and Repressive RNA Granules

    Alejandro Padron, Shintaro Iwasaki, Nicholas Ingolia



    Selected by Christian Bates
    Close