Structural basis of the green–blue color switching in proteorhodopsin as determined by NMR spectroscopy
Structural basis of the green–blue color switching in proteorhodopsin as determined by NMR spectroscopy
Proteorhodopsins (PRs) found in marine microbes are the most abundant retinal-based photoreceptors on this planet. PR variants show high levels of environmental adaptation, as their colors are tuned to the optimal wavelength of available light. The two major green and blue subfamilies can be interconverted through a L/Q point mutation at position 105. Here we reveal the structural basis behind this intriguing color-tuning effect. High-field solid-state NMR spectroscopy was used to visualize structural changes within green PR directly within the lipid bilayer upon introduction of the green–blue L105Q mutation. The observed effects are localized within the binding pocket and close to retinal carbons C14 and C15. Subsequently, magic-angle spinning (MAS) NMR spectroscopy with sensitivity enhancement by dynamic nuclear polarization (DNP) was applied to determine precisely the retinal structure around C14–C15. Upon mutation, a significantly stretched C14–C15 bond, deshielding of C15, and a slight alteration of the retinal chain’s out-of-plane twist was observed. The L105Q blue switch therefore acts locally on the retinal itself and induces a conjugation defect between the isomerization region and the imine linkage. Consequently, the S0–S1 energy gap increases, resulting in the observed blue shift. The distortion of the chromophore structure also offers an explanation for the elongated primary reaction detected by pump–probe spectroscopy, while chemical shift perturbations within the protein can be linked to the elongation of late-photocycle intermediates studied by flash photolysis. Besides resolving a long-standing problem, this study also demonstrates that the combination of data obtained from high-field and DNP-enhanced MAS NMR spectroscopy together with time-resolved optical spectroscopy enables powerful synergies for in-depth functional studies of membrane proteins.
17578-17590
Mao, Jiafei
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Do, Nhu-Nguyen
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Scholz, Frank
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Reggie, Lenica
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Mehler, Michaela
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Lakatos, Andrea
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Ong, Yean-Sin
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Ullrich, Sandra J.
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Brown, Lynda J.
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Brown, Richard C. D.
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Becker-Baldus, Johanna
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Wachtveitl, Josef
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Glaubitz, Clemens
99f5e847-e6fd-4783-bc60-054bf0e15661
17 December 2014
Mao, Jiafei
edacb8e9-ad60-4b98-8b95-d2069cf6590f
Do, Nhu-Nguyen
80d77481-bfe0-4c30-a589-b6da44feb787
Scholz, Frank
e3535313-9163-4f00-801d-176fe3023efc
Reggie, Lenica
58d55662-669a-4138-89c5-6d17dac23110
Mehler, Michaela
1542ef93-5644-4dbf-84ff-c1980fdb40d6
Lakatos, Andrea
ab2ca1f1-2710-4422-9ff4-ff74c64a2be9
Ong, Yean-Sin
2a31f34b-ccd6-4980-8bd7-d762f3fb39ed
Ullrich, Sandra J.
9e95ec33-9f9a-4022-989c-e396771b9781
Brown, Lynda J.
75aa95fa-5d27-46a7-9dbe-0f465a664f5b
Brown, Richard C. D.
21ce697a-7c3a-480e-919f-429a3d8550f5
Becker-Baldus, Johanna
6563d44b-d7aa-4e93-b7c2-57b95f8a0f1d
Wachtveitl, Josef
b33cef4d-67a0-4804-b0f7-90c408a33a05
Glaubitz, Clemens
99f5e847-e6fd-4783-bc60-054bf0e15661
Mao, Jiafei, Do, Nhu-Nguyen, Scholz, Frank, Reggie, Lenica, Mehler, Michaela, Lakatos, Andrea, Ong, Yean-Sin, Ullrich, Sandra J., Brown, Lynda J., Brown, Richard C. D., Becker-Baldus, Johanna, Wachtveitl, Josef and Glaubitz, Clemens
(2014)
Structural basis of the green–blue color switching in proteorhodopsin as determined by NMR spectroscopy.
Journal of the American Chemical Society, 136 (50), .
(doi:10.1021/ja5097946).
Abstract
Proteorhodopsins (PRs) found in marine microbes are the most abundant retinal-based photoreceptors on this planet. PR variants show high levels of environmental adaptation, as their colors are tuned to the optimal wavelength of available light. The two major green and blue subfamilies can be interconverted through a L/Q point mutation at position 105. Here we reveal the structural basis behind this intriguing color-tuning effect. High-field solid-state NMR spectroscopy was used to visualize structural changes within green PR directly within the lipid bilayer upon introduction of the green–blue L105Q mutation. The observed effects are localized within the binding pocket and close to retinal carbons C14 and C15. Subsequently, magic-angle spinning (MAS) NMR spectroscopy with sensitivity enhancement by dynamic nuclear polarization (DNP) was applied to determine precisely the retinal structure around C14–C15. Upon mutation, a significantly stretched C14–C15 bond, deshielding of C15, and a slight alteration of the retinal chain’s out-of-plane twist was observed. The L105Q blue switch therefore acts locally on the retinal itself and induces a conjugation defect between the isomerization region and the imine linkage. Consequently, the S0–S1 energy gap increases, resulting in the observed blue shift. The distortion of the chromophore structure also offers an explanation for the elongated primary reaction detected by pump–probe spectroscopy, while chemical shift perturbations within the protein can be linked to the elongation of late-photocycle intermediates studied by flash photolysis. Besides resolving a long-standing problem, this study also demonstrates that the combination of data obtained from high-field and DNP-enhanced MAS NMR spectroscopy together with time-resolved optical spectroscopy enables powerful synergies for in-depth functional studies of membrane proteins.
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e-pub ahead of print date: 21 November 2014
Published date: 17 December 2014
Organisations:
Organic Chemistry: Synthesis, Catalysis and Flow
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Local EPrints ID: 383961
URI: http://eprints.soton.ac.uk/id/eprint/383961
ISSN: 0002-7863
PURE UUID: 5d530b04-16fa-454d-9abb-c83c59df98fb
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Date deposited: 01 Dec 2015 13:44
Last modified: 15 Mar 2024 02:59
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Author:
Jiafei Mao
Author:
Nhu-Nguyen Do
Author:
Frank Scholz
Author:
Lenica Reggie
Author:
Michaela Mehler
Author:
Andrea Lakatos
Author:
Yean-Sin Ong
Author:
Sandra J. Ullrich
Author:
Johanna Becker-Baldus
Author:
Josef Wachtveitl
Author:
Clemens Glaubitz
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