Tryptophan-Tryptophan energy migration as a tool to follow apoflavodoxin folding

Tryptophan-Tryptophan energy migration as a tool to follow apoflavodoxin folding

Submolecular details of Azotobacter vinelandii apoflavodoxin (apoFD) (un)folding are revealed by time-resolved fluorescence anisotropy using wild-type protein and variants lacking one or two of apoFD's three tryptophans. ApoFD equilibrium (un)folding by guanidine hydrochloride follows a three-state model: native unfolded intermediate. In native protein, W128 is a sink for Förster resonance energy transfer (FRET). Consequently, unidirectional FRET with a 50-ps transfer correlation time occurs from W167 to W128. FRET from W74 to W167 is much slower (6.9 ns). In the intermediate, W128 and W167 have native-like geometry because the 50-ps transfer time is observed. However, non-native structure exists between W74 and W167 because instead of 6.9 ns the transfer correlation time is 2.0 ns. In unfolded apoFD this 2.0-ns transfer correlation time is also detected. This decrease in transfer correlation time is a result of W74 and W167 becoming solvent accessible and randomly oriented toward one another. Apparently W74 and W167 are near-natively separated in the folding intermediate and in unfolded apoFD. Both tryptophans may actually be slightly closer in space than in the native state, even though apoFD's radius increases substantially upon unfolding. In unfolded apoFD the 50-ps transfer time observed for native and intermediate folding states becomes 200 ps as W128 and W167 are marginally further separated than in the native state. Apparently, apoFD's unfolded state is not a featureless statistical coil but contains well-defined substructures. The approach presented is a powerful tool to study protein folding.

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Main Authors: Visser, N.V., Westphal, A.H., van Hoek, A., van Mierlo, C.P.M., Visser, A.J.W.G., van Amerongen, H.
Format: Article/Letter to editor biblioteca
Language:English
Subjects:azotobacter-vinelandii apoflavodoxin, backbone dynamics, flavin fluorescence, flavodoxin-ii, fluorescence depolarization, glutathione-reductase, hydrogen-exchange, lipoamide dehydrogenase, protein-structure, refractive-index,
Online Access:https://research.wur.nl/en/publications/tryptophan-tryptophan-energy-migration-as-a-tool-to-follow-apofla
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spelling dig-wur-nl-wurpubs-3710462024-06-25 Visser, N.V. Westphal, A.H. van Hoek, A. van Mierlo, C.P.M. Visser, A.J.W.G. van Amerongen, H. Article/Letter to editor Biophysical Journal 95 (2008) ISSN: 0006-3495 Tryptophan-Tryptophan energy migration as a tool to follow apoflavodoxin folding 2008 Submolecular details of Azotobacter vinelandii apoflavodoxin (apoFD) (un)folding are revealed by time-resolved fluorescence anisotropy using wild-type protein and variants lacking one or two of apoFD's three tryptophans. ApoFD equilibrium (un)folding by guanidine hydrochloride follows a three-state model: native unfolded intermediate. In native protein, W128 is a sink for Förster resonance energy transfer (FRET). Consequently, unidirectional FRET with a 50-ps transfer correlation time occurs from W167 to W128. FRET from W74 to W167 is much slower (6.9 ns). In the intermediate, W128 and W167 have native-like geometry because the 50-ps transfer time is observed. However, non-native structure exists between W74 and W167 because instead of 6.9 ns the transfer correlation time is 2.0 ns. In unfolded apoFD this 2.0-ns transfer correlation time is also detected. This decrease in transfer correlation time is a result of W74 and W167 becoming solvent accessible and randomly oriented toward one another. Apparently W74 and W167 are near-natively separated in the folding intermediate and in unfolded apoFD. Both tryptophans may actually be slightly closer in space than in the native state, even though apoFD's radius increases substantially upon unfolding. In unfolded apoFD the 50-ps transfer time observed for native and intermediate folding states becomes 200 ps as W128 and W167 are marginally further separated than in the native state. Apparently, apoFD's unfolded state is not a featureless statistical coil but contains well-defined substructures. The approach presented is a powerful tool to study protein folding. en application/pdf https://research.wur.nl/en/publications/tryptophan-tryptophan-energy-migration-as-a-tool-to-follow-apofla 10.1529/biophysj.108.132001 https://edepot.wur.nl/41031 azotobacter-vinelandii apoflavodoxin backbone dynamics flavin fluorescence flavodoxin-ii fluorescence depolarization glutathione-reductase hydrogen-exchange lipoamide dehydrogenase protein-structure refractive-index Wageningen University & Research
institution WUR NL
collection DSpace
country Países bajos
countrycode NL
component Bibliográfico
access En linea
databasecode dig-wur-nl
tag biblioteca
region Europa del Oeste
libraryname WUR Library Netherlands
language English
topic azotobacter-vinelandii apoflavodoxin
backbone dynamics
flavin fluorescence
flavodoxin-ii
fluorescence depolarization
glutathione-reductase
hydrogen-exchange
lipoamide dehydrogenase
protein-structure
refractive-index
azotobacter-vinelandii apoflavodoxin
backbone dynamics
flavin fluorescence
flavodoxin-ii
fluorescence depolarization
glutathione-reductase
hydrogen-exchange
lipoamide dehydrogenase
protein-structure
refractive-index
spellingShingle azotobacter-vinelandii apoflavodoxin
backbone dynamics
flavin fluorescence
flavodoxin-ii
fluorescence depolarization
glutathione-reductase
hydrogen-exchange
lipoamide dehydrogenase
protein-structure
refractive-index
azotobacter-vinelandii apoflavodoxin
backbone dynamics
flavin fluorescence
flavodoxin-ii
fluorescence depolarization
glutathione-reductase
hydrogen-exchange
lipoamide dehydrogenase
protein-structure
refractive-index
Visser, N.V.
Westphal, A.H.
van Hoek, A.
van Mierlo, C.P.M.
Visser, A.J.W.G.
van Amerongen, H.
Tryptophan-Tryptophan energy migration as a tool to follow apoflavodoxin folding
description Submolecular details of Azotobacter vinelandii apoflavodoxin (apoFD) (un)folding are revealed by time-resolved fluorescence anisotropy using wild-type protein and variants lacking one or two of apoFD's three tryptophans. ApoFD equilibrium (un)folding by guanidine hydrochloride follows a three-state model: native unfolded intermediate. In native protein, W128 is a sink for Förster resonance energy transfer (FRET). Consequently, unidirectional FRET with a 50-ps transfer correlation time occurs from W167 to W128. FRET from W74 to W167 is much slower (6.9 ns). In the intermediate, W128 and W167 have native-like geometry because the 50-ps transfer time is observed. However, non-native structure exists between W74 and W167 because instead of 6.9 ns the transfer correlation time is 2.0 ns. In unfolded apoFD this 2.0-ns transfer correlation time is also detected. This decrease in transfer correlation time is a result of W74 and W167 becoming solvent accessible and randomly oriented toward one another. Apparently W74 and W167 are near-natively separated in the folding intermediate and in unfolded apoFD. Both tryptophans may actually be slightly closer in space than in the native state, even though apoFD's radius increases substantially upon unfolding. In unfolded apoFD the 50-ps transfer time observed for native and intermediate folding states becomes 200 ps as W128 and W167 are marginally further separated than in the native state. Apparently, apoFD's unfolded state is not a featureless statistical coil but contains well-defined substructures. The approach presented is a powerful tool to study protein folding.
format Article/Letter to editor
topic_facet azotobacter-vinelandii apoflavodoxin
backbone dynamics
flavin fluorescence
flavodoxin-ii
fluorescence depolarization
glutathione-reductase
hydrogen-exchange
lipoamide dehydrogenase
protein-structure
refractive-index
author Visser, N.V.
Westphal, A.H.
van Hoek, A.
van Mierlo, C.P.M.
Visser, A.J.W.G.
van Amerongen, H.
author_facet Visser, N.V.
Westphal, A.H.
van Hoek, A.
van Mierlo, C.P.M.
Visser, A.J.W.G.
van Amerongen, H.
author_sort Visser, N.V.
title Tryptophan-Tryptophan energy migration as a tool to follow apoflavodoxin folding
title_short Tryptophan-Tryptophan energy migration as a tool to follow apoflavodoxin folding
title_full Tryptophan-Tryptophan energy migration as a tool to follow apoflavodoxin folding
title_fullStr Tryptophan-Tryptophan energy migration as a tool to follow apoflavodoxin folding
title_full_unstemmed Tryptophan-Tryptophan energy migration as a tool to follow apoflavodoxin folding
title_sort tryptophan-tryptophan energy migration as a tool to follow apoflavodoxin folding
url https://research.wur.nl/en/publications/tryptophan-tryptophan-energy-migration-as-a-tool-to-follow-apofla
work_keys_str_mv AT vissernv tryptophantryptophanenergymigrationasatooltofollowapoflavodoxinfolding
AT westphalah tryptophantryptophanenergymigrationasatooltofollowapoflavodoxinfolding
AT vanhoeka tryptophantryptophanenergymigrationasatooltofollowapoflavodoxinfolding
AT vanmierlocpm tryptophantryptophanenergymigrationasatooltofollowapoflavodoxinfolding
AT visserajwg tryptophantryptophanenergymigrationasatooltofollowapoflavodoxinfolding
AT vanamerongenh tryptophantryptophanenergymigrationasatooltofollowapoflavodoxinfolding
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