Ultrastructural localisation of protein interactions using conditionally stable nanobodies.

Ultrastructural localisation of protein interactions using conditionally stable nanobodies.

We describe the development and application of a suite of modular tools for high-resolution detection of proteins and intracellular protein complexes by electron microscopy (EM). Conditionally stable GFP- and mCherry-binding nanobodies (termed csGBP and csChBP, respectively) are characterized using...

Full description

Bibliographic Details
Main Authors: Nicholas Ariotti, James Rae, Nichole Giles, Nick Martel, Emma Sierecki, Yann Gambin, Thomas E Hall, Robert G Parton
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2018-04-01
Series:PLoS Biology
Online Access:https://doi.org/10.1371/journal.pbio.2005473
id doaj-3a04581909f74553b2a9b43340be88b5
record_format Article
spelling doaj-3a04581909f74553b2a9b43340be88b52021-07-02T16:29:00ZengPublic Library of Science (PLoS)PLoS Biology1544-91731545-78852018-04-01164e200547310.1371/journal.pbio.2005473Ultrastructural localisation of protein interactions using conditionally stable nanobodies.Nicholas AriottiJames RaeNichole GilesNick MartelEmma SiereckiYann GambinThomas E HallRobert G PartonWe describe the development and application of a suite of modular tools for high-resolution detection of proteins and intracellular protein complexes by electron microscopy (EM). Conditionally stable GFP- and mCherry-binding nanobodies (termed csGBP and csChBP, respectively) are characterized using a cell-free expression and analysis system and subsequently fused to an ascorbate peroxidase (APEX) enzyme. Expression of these cassettes alongside fluorescently labelled proteins results in recruitment and stabilisation of APEX, whereas unbound APEX nanobodies are efficiently degraded by the proteasome. This greatly simplifies correlative analyses, enables detection of less-abundant proteins, and eliminates the need to balance expression levels between fluorescently labelled and APEX nanobody proteins. Furthermore, we demonstrate the application of this system to bimolecular complementation ('EM split-fluorescent protein'), for localisation of protein-protein interactions at the ultrastructural level.https://doi.org/10.1371/journal.pbio.2005473
collection DOAJ
language English
format Article
sources DOAJ
author Nicholas Ariotti
James Rae
Nichole Giles
Nick Martel
Emma Sierecki
Yann Gambin
Thomas E Hall
Robert G Parton
spellingShingle Nicholas Ariotti
James Rae
Nichole Giles
Nick Martel
Emma Sierecki
Yann Gambin
Thomas E Hall
Robert G Parton
Ultrastructural localisation of protein interactions using conditionally stable nanobodies.
PLoS Biology
author_facet Nicholas Ariotti
James Rae
Nichole Giles
Nick Martel
Emma Sierecki
Yann Gambin
Thomas E Hall
Robert G Parton
author_sort Nicholas Ariotti
title Ultrastructural localisation of protein interactions using conditionally stable nanobodies.
title_short Ultrastructural localisation of protein interactions using conditionally stable nanobodies.
title_full Ultrastructural localisation of protein interactions using conditionally stable nanobodies.
title_fullStr Ultrastructural localisation of protein interactions using conditionally stable nanobodies.
title_full_unstemmed Ultrastructural localisation of protein interactions using conditionally stable nanobodies.
title_sort ultrastructural localisation of protein interactions using conditionally stable nanobodies.
publisher Public Library of Science (PLoS)
series PLoS Biology
issn 1544-9173
1545-7885
publishDate 2018-04-01
description We describe the development and application of a suite of modular tools for high-resolution detection of proteins and intracellular protein complexes by electron microscopy (EM). Conditionally stable GFP- and mCherry-binding nanobodies (termed csGBP and csChBP, respectively) are characterized using a cell-free expression and analysis system and subsequently fused to an ascorbate peroxidase (APEX) enzyme. Expression of these cassettes alongside fluorescently labelled proteins results in recruitment and stabilisation of APEX, whereas unbound APEX nanobodies are efficiently degraded by the proteasome. This greatly simplifies correlative analyses, enables detection of less-abundant proteins, and eliminates the need to balance expression levels between fluorescently labelled and APEX nanobody proteins. Furthermore, we demonstrate the application of this system to bimolecular complementation ('EM split-fluorescent protein'), for localisation of protein-protein interactions at the ultrastructural level.
url https://doi.org/10.1371/journal.pbio.2005473
work_keys_str_mv AT nicholasariotti ultrastructurallocalisationofproteininteractionsusingconditionallystablenanobodies
AT jamesrae ultrastructurallocalisationofproteininteractionsusingconditionallystablenanobodies
AT nicholegiles ultrastructurallocalisationofproteininteractionsusingconditionallystablenanobodies
AT nickmartel ultrastructurallocalisationofproteininteractionsusingconditionallystablenanobodies
AT emmasierecki ultrastructurallocalisationofproteininteractionsusingconditionallystablenanobodies
AT yanngambin ultrastructurallocalisationofproteininteractionsusingconditionallystablenanobodies
AT thomasehall ultrastructurallocalisationofproteininteractionsusingconditionallystablenanobodies
AT robertgparton ultrastructurallocalisationofproteininteractionsusingconditionallystablenanobodies
_version_ 1721326560531709952

Similar Items