Advanced Fluorescence Microscopy to Study Plasma Membrane Protein Dynamics

Membrane protein dynamics is of great importance for living organisms. The precise localization of proteins composing a synapse on the membrane facing a nerve terminus is essential for proper functioning of the nervous system. In muscle fibers, the nicotinic acetylcholine is densely packed under the...

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Bibliographic Details
Main Author: Piguet, Joachim
Format: Doctoral Thesis
Language:English
Published: Ecole Polytechnique Fédérale de Lausanne (EPFL), Switzerland 2010
Subjects:
Online Access:http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-178147
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record_format oai_dc
collection NDLTD
language English
format Doctoral Thesis
sources NDLTD
topic fluorescence
microscopy
plasma membrane
membrane proteins
membrane proteins diffusion
single-molecule imaging
single-molecule tracking
pentameric ligand-gated ion channels
nicotinic acetylcholine receptor
serotonin receptor
synapse
neuromuscular junction
post-synaptic scaffold
rapsyn
myopathies
fluorescent proteins
Förster resonance energy transfer
FRET imaging
protein-protein interactions
protein trafficking
photo-activatable proteins
spellingShingle fluorescence
microscopy
plasma membrane
membrane proteins
membrane proteins diffusion
single-molecule imaging
single-molecule tracking
pentameric ligand-gated ion channels
nicotinic acetylcholine receptor
serotonin receptor
synapse
neuromuscular junction
post-synaptic scaffold
rapsyn
myopathies
fluorescent proteins
Förster resonance energy transfer
FRET imaging
protein-protein interactions
protein trafficking
photo-activatable proteins
Piguet, Joachim
Advanced Fluorescence Microscopy to Study Plasma Membrane Protein Dynamics
description Membrane protein dynamics is of great importance for living organisms. The precise localization of proteins composing a synapse on the membrane facing a nerve terminus is essential for proper functioning of the nervous system. In muscle fibers, the nicotinic acetylcholine is densely packed under the motor nerve termini. A receptor associated protein, rapsyn, acts as a linker between the receptor and the other components of the synaptic suramolecular assembly. Advances in fluorescence microscopy have allowed to measure the behavior of a single receptor in the cell membrane. In this work single-molecule microscopy was used to track the motion of ionotropic acetylcholine (nAChR) and serotonin (5HT3R) receptors in the plasma membrane of cells. We present methods for measuring single-molecule diffusion and their analysis. Single molecule tracking has shown a high dependence of acetylcholine receptors diffusion on its associated protein rapsyn. Comparing muscle cells that either express rapsyn or are devoid of it, we found that rapsyn plays an important role on receptor immobilization. A three-fold increase of receptor mobility was observed in muscle cells devoid of rapsyn. However, in these cells, a certain fraction of immobilized receptors was also found immobile. Furthermore, nAChR were strongly confined in membrane domains of few tens of nanometers. This showed that membrane composition and membrane associated proteins influence on receptor localization. During muscle cell differentiation, the fraction of immobile nAChR diminished along with the decreasing nAChR and stable rapsyn expression levels. The importance of rapsyn in nAChR immobilization has been further confirmed by measurements in HEK 293 cells, where co-expression of rapsyn increased immobilization of the receptor. nAChR is a ligand-gated ion-channel of the Cys-loop family. In mammals, members of this receptor family share general structural and functional features. They are homo- or hetero-pentamers and form a membrane-spanning ion channel. Subunits have three major regions, an extracellular ligand binding domain, a transmembrane channel and a large intracellular loop. 5HT3R was used as a model to study the effect of this loop on receptor mobility. Single-molecule tracking experiments on receptors with progressively larger deletions in the intracellular loop did not show a dependence of the size of the loop on the diffusion coefficient of mobile receptors. However, two regions were identified to play a role in receptor mobility by changing the fractions of immobile and directed receptors. Interestingly, a prokaryotic homologue of cys-loop receptors, ELIC, devoid of a large cytoplasmic loop was found to be immobile or to show directed diffusion similar as the wild-type 5HT3R. The scaffolding protein rapsyn stabilizes nAChR clusters in a concentration dependent manner. We have measured the density and self-interactions of rapsyn using FRET microscopy. Point-mutations of rapsyn, known to provoke myopathies, destabilized rapsyn self-interactions. Rapsyn-N88K, and R91L were found at high concentration in the cytoplasm suggesting that this modification disturbs membrane association of rapsyn. A25V was found to accumulate in the endoplasmic reticulum. Fluorescent tools to measure intracellular concentration of calcium ions are of great value to study the function of neurons. Rapsyn is highly abundant at the neuromuscular junction and thus is a genuine synaptic marker. A fusion protein of rapsyn with a genetically encoded ratiometric calcium sensor has been made to probe synapse activity. This thesis has shown that the combined use of biologically relevant system and modern fluorescence microscopy techniques deliver important information on pLGIC behaviour in the cell membrane. === <p>QC 20151217</p>
author Piguet, Joachim
author_facet Piguet, Joachim
author_sort Piguet, Joachim
title Advanced Fluorescence Microscopy to Study Plasma Membrane Protein Dynamics
title_short Advanced Fluorescence Microscopy to Study Plasma Membrane Protein Dynamics
title_full Advanced Fluorescence Microscopy to Study Plasma Membrane Protein Dynamics
title_fullStr Advanced Fluorescence Microscopy to Study Plasma Membrane Protein Dynamics
title_full_unstemmed Advanced Fluorescence Microscopy to Study Plasma Membrane Protein Dynamics
title_sort advanced fluorescence microscopy to study plasma membrane protein dynamics
publisher Ecole Polytechnique Fédérale de Lausanne (EPFL), Switzerland
publishDate 2010
url http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-178147
work_keys_str_mv AT piguetjoachim advancedfluorescencemicroscopytostudyplasmamembraneproteindynamics
_version_ 1718154173225107456
spelling ndltd-UPSALLA1-oai-DiVA.org-kth-1781472015-12-18T05:00:49ZAdvanced Fluorescence Microscopy to Study Plasma Membrane Protein DynamicsengPiguet, JoachimEcole Polytechnique Fédérale de Lausanne (EPFL), SwitzerlandLausanne : EPFL2010fluorescencemicroscopyplasma membranemembrane proteinsmembrane proteins diffusionsingle-molecule imagingsingle-molecule trackingpentameric ligand-gated ion channelsnicotinic acetylcholine receptorserotonin receptorsynapseneuromuscular junctionpost-synaptic scaffoldrapsynmyopathiesfluorescent proteinsFörster resonance energy transferFRET imagingprotein-protein interactionsprotein traffickingphoto-activatable proteinsMembrane protein dynamics is of great importance for living organisms. The precise localization of proteins composing a synapse on the membrane facing a nerve terminus is essential for proper functioning of the nervous system. In muscle fibers, the nicotinic acetylcholine is densely packed under the motor nerve termini. A receptor associated protein, rapsyn, acts as a linker between the receptor and the other components of the synaptic suramolecular assembly. Advances in fluorescence microscopy have allowed to measure the behavior of a single receptor in the cell membrane. In this work single-molecule microscopy was used to track the motion of ionotropic acetylcholine (nAChR) and serotonin (5HT3R) receptors in the plasma membrane of cells. We present methods for measuring single-molecule diffusion and their analysis. Single molecule tracking has shown a high dependence of acetylcholine receptors diffusion on its associated protein rapsyn. Comparing muscle cells that either express rapsyn or are devoid of it, we found that rapsyn plays an important role on receptor immobilization. A three-fold increase of receptor mobility was observed in muscle cells devoid of rapsyn. However, in these cells, a certain fraction of immobilized receptors was also found immobile. Furthermore, nAChR were strongly confined in membrane domains of few tens of nanometers. This showed that membrane composition and membrane associated proteins influence on receptor localization. During muscle cell differentiation, the fraction of immobile nAChR diminished along with the decreasing nAChR and stable rapsyn expression levels. The importance of rapsyn in nAChR immobilization has been further confirmed by measurements in HEK 293 cells, where co-expression of rapsyn increased immobilization of the receptor. nAChR is a ligand-gated ion-channel of the Cys-loop family. In mammals, members of this receptor family share general structural and functional features. They are homo- or hetero-pentamers and form a membrane-spanning ion channel. Subunits have three major regions, an extracellular ligand binding domain, a transmembrane channel and a large intracellular loop. 5HT3R was used as a model to study the effect of this loop on receptor mobility. Single-molecule tracking experiments on receptors with progressively larger deletions in the intracellular loop did not show a dependence of the size of the loop on the diffusion coefficient of mobile receptors. However, two regions were identified to play a role in receptor mobility by changing the fractions of immobile and directed receptors. Interestingly, a prokaryotic homologue of cys-loop receptors, ELIC, devoid of a large cytoplasmic loop was found to be immobile or to show directed diffusion similar as the wild-type 5HT3R. The scaffolding protein rapsyn stabilizes nAChR clusters in a concentration dependent manner. We have measured the density and self-interactions of rapsyn using FRET microscopy. Point-mutations of rapsyn, known to provoke myopathies, destabilized rapsyn self-interactions. Rapsyn-N88K, and R91L were found at high concentration in the cytoplasm suggesting that this modification disturbs membrane association of rapsyn. A25V was found to accumulate in the endoplasmic reticulum. Fluorescent tools to measure intracellular concentration of calcium ions are of great value to study the function of neurons. Rapsyn is highly abundant at the neuromuscular junction and thus is a genuine synaptic marker. A fusion protein of rapsyn with a genetically encoded ratiometric calcium sensor has been made to probe synapse activity. This thesis has shown that the combined use of biologically relevant system and modern fluorescence microscopy techniques deliver important information on pLGIC behaviour in the cell membrane. <p>QC 20151217</p>Doctoral thesis, monographinfo:eu-repo/semantics/doctoralThesistexthttp://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-178147doi:10.5075/epfl-thesis-4869application/pdfinfo:eu-repo/semantics/openAccess