Identification and function of conformational dynamics in the multidomain GTPase dynamin

Identification and function of conformational dynamics in the multidomain GTPase dynamin

Vesicle release upon endocytosis requires membrane fission, catalyzed by the large GTPase dynamin. Dynamin contains five domains that together orchestrate its mechanochemical activity. Hydrogen–deuterium exchange coupled with mass spectrometry revealed global nucleotide‐ and membrane‐binding‐depende...

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Veröffentlicht in:The EMBO journal 2016-02, Vol.35 (4), p.443-457
Hauptverfasser: Srinivasan, Saipraveen, Dharmarajan, Venkatasubramanian, Reed, Dana Kim, Griffin, Patrick R, Schmid, Sandra L
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Sprache:eng
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Catalysis
Cell Line
centronuclear myopathy
clathrin-mediated endocytosis
Deuterium
Dynamins - chemistry
Dynamins - genetics
Dynamins - metabolism
EMBO20
EMBO40
Enzymes
Fluorescence Resonance Energy Transfer
Guanosine Triphosphate - metabolism
Humans
hydrogen-deuterium exchange
Hydrolysis
Intracellular Membranes - metabolism
Ligands
Magnetic Resonance Spectroscopy
Mass spectrometry
membrane fission
Membranes
Mutant Proteins - chemistry
Mutant Proteins - genetics
Mutant Proteins - metabolism
Mutation
pleckstrin homology domain
Protein Conformation
Protein folding
Protein Multimerization
Sequence Deletion
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container_issue 4
container_start_page 443
container_title The EMBO journal
container_volume 35
creator Srinivasan, Saipraveen
Dharmarajan, Venkatasubramanian
Reed, Dana Kim
Griffin, Patrick R
Schmid, Sandra L
description Vesicle release upon endocytosis requires membrane fission, catalyzed by the large GTPase dynamin. Dynamin contains five domains that together orchestrate its mechanochemical activity. Hydrogen–deuterium exchange coupled with mass spectrometry revealed global nucleotide‐ and membrane‐binding‐dependent conformational changes, as well as the existence of an allosteric relay element in the α2 S helix of the dynamin stalk domain. As predicted from structural studies, FRET analyses detect large movements of the pleckstrin homology domain (PHD) from a ‘closed’ conformation docked near the stalk to an ‘open’ conformation able to interact with membranes. We engineered dynamin constructs locked in either the closed or open state by chemical cross‐linking or deletion mutagenesis and showed that PHD movements function as a conformational switch to regulate dynamin self‐assembly, membrane binding, and fission. This PHD conformational switch is impaired by a centronuclear myopathy‐causing disease mutation, S619L, highlighting the physiological significance of its role in regulating dynamin function. Together, these data provide new insight into coordinated conformational changes that regulate dynamin function and couple membrane binding, oligomerization, and GTPase activity during dynamin‐catalyzed membrane fission. Synopsis Dynamin‐catalyzed membrane fission requires long‐range nucleotide and/or membrane binding‐induced conformational changes and domain rearrangements that are identified and functionally characterized in this study. Ligand‐induced conformational changes in dynamin were identified by HDX‐MS. An allosteric relay helix, α2 S , transmits conformational information from the G domain to the membrane and vice versa. FRET analyses reveal conformational switches of the PH domain. When locked in a closed conformation, the PH domain acts in an auto‐inhibitory fashion to regulate membrane binding and assembly. The PH domain conformational switch is impaired in the centronuclear myopathy‐causing mutant Dyn2S619L. Graphical Abstract Dynamin‐catalyzed membrane fission requires long‐range nucleotide and/or membrane binding‐induced conformational changes and domain rearrangements that are identified and functionally characterized in this study.
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This PHD conformational switch is impaired by a centronuclear myopathy‐causing disease mutation, S619L, highlighting the physiological significance of its role in regulating dynamin function. Together, these data provide new insight into coordinated conformational changes that regulate dynamin function and couple membrane binding, oligomerization, and GTPase activity during dynamin‐catalyzed membrane fission. Synopsis Dynamin‐catalyzed membrane fission requires long‐range nucleotide and/or membrane binding‐induced conformational changes and domain rearrangements that are identified and functionally characterized in this study. Ligand‐induced conformational changes in dynamin were identified by HDX‐MS. An allosteric relay helix, α2 S , transmits conformational information from the G domain to the membrane and vice versa. FRET analyses reveal conformational switches of the PH domain. 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This PHD conformational switch is impaired by a centronuclear myopathy‐causing disease mutation, S619L, highlighting the physiological significance of its role in regulating dynamin function. Together, these data provide new insight into coordinated conformational changes that regulate dynamin function and couple membrane binding, oligomerization, and GTPase activity during dynamin‐catalyzed membrane fission. Synopsis Dynamin‐catalyzed membrane fission requires long‐range nucleotide and/or membrane binding‐induced conformational changes and domain rearrangements that are identified and functionally characterized in this study. Ligand‐induced conformational changes in dynamin were identified by HDX‐MS. An allosteric relay helix, α2 S , transmits conformational information from the G domain to the membrane and vice versa. FRET analyses reveal conformational switches of the PH domain. 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Dynamin contains five domains that together orchestrate its mechanochemical activity. Hydrogen–deuterium exchange coupled with mass spectrometry revealed global nucleotide‐ and membrane‐binding‐dependent conformational changes, as well as the existence of an allosteric relay element in the α2 S helix of the dynamin stalk domain. As predicted from structural studies, FRET analyses detect large movements of the pleckstrin homology domain (PHD) from a ‘closed’ conformation docked near the stalk to an ‘open’ conformation able to interact with membranes. We engineered dynamin constructs locked in either the closed or open state by chemical cross‐linking or deletion mutagenesis and showed that PHD movements function as a conformational switch to regulate dynamin self‐assembly, membrane binding, and fission. This PHD conformational switch is impaired by a centronuclear myopathy‐causing disease mutation, S619L, highlighting the physiological significance of its role in regulating dynamin function. Together, these data provide new insight into coordinated conformational changes that regulate dynamin function and couple membrane binding, oligomerization, and GTPase activity during dynamin‐catalyzed membrane fission. Synopsis Dynamin‐catalyzed membrane fission requires long‐range nucleotide and/or membrane binding‐induced conformational changes and domain rearrangements that are identified and functionally characterized in this study. Ligand‐induced conformational changes in dynamin were identified by HDX‐MS. An allosteric relay helix, α2 S , transmits conformational information from the G domain to the membrane and vice versa. FRET analyses reveal conformational switches of the PH domain. When locked in a closed conformation, the PH domain acts in an auto‐inhibitory fashion to regulate membrane binding and assembly. The PH domain conformational switch is impaired in the centronuclear myopathy‐causing mutant Dyn2S619L. Graphical Abstract Dynamin‐catalyzed membrane fission requires long‐range nucleotide and/or membrane binding‐induced conformational changes and domain rearrangements that are identified and functionally characterized in this study.</abstract><cop>London</cop><pub>Blackwell Publishing Ltd</pub><pmid>26783363</pmid><doi>10.15252/embj.201593477</doi><tpages>15</tpages><oa>free_for_read</oa></addata></record>
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subjects Catalysis
Cell Line
centronuclear myopathy
clathrin-mediated endocytosis
Deuterium
Dynamins - chemistry
Dynamins - genetics
Dynamins - metabolism
EMBO20
EMBO40
Enzymes
Fluorescence Resonance Energy Transfer
Guanosine Triphosphate - metabolism
Humans
hydrogen-deuterium exchange
Hydrolysis
Intracellular Membranes - metabolism
Ligands
Magnetic Resonance Spectroscopy
Mass spectrometry
membrane fission
Membranes
Mutant Proteins - chemistry
Mutant Proteins - genetics
Mutant Proteins - metabolism
Mutation
pleckstrin homology domain
Protein Conformation
Protein folding
Protein Multimerization
Sequence Deletion
title Identification and function of conformational dynamics in the multidomain GTPase dynamin
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