Ancestral protein reconstruction and circular permutation for improving the stability and dynamic range of FRET sensors

Ben E. Clifton; Jason H. Whitfield; Inmaculada Sanchez-Romero; Michel K. Herde; Christian Henneberger; Harald Janovjak; Colin J. Jackson

doi:10.1007/978-1-4939-6940-1_5

Ancestral protein reconstruction and circular permutation for improving the stability and dynamic range of FRET sensors

Ben E. Clifton, Jason H. Whitfield, Inmaculada Sanchez-Romero, Michel K. Herde, Christian Henneberger, Harald Janovjak, Colin J. Jackson^*

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

7 Citations (Scopus)

Abstract

Small molecule biosensors based on Förster resonance energy transfer (FRET) enable small molecule signaling to be monitored with high spatial and temporal resolution in complex cellular environments. FRET sensors can be constructed by fusing a pair of fluorescent proteins to a suitable recognition domain, such as a member of the solute-binding protein (SBP) superfamily. However, naturally occurring SBPs may be unsuitable for incorporation into FRET sensors due to their low thermostability, which may preclude imaging under physiological conditions, or because the positions of their N- and C-termini may be suboptimal for fusion of fluorescent proteins, which may limit the dynamic range of the resulting sensors. Here, we show how these problems can be overcome using ancestral protein reconstruction and circular permutation. Ancestral protein reconstruction, used as a protein engineering strategy, leverages phylogenetic information to improve the thermostability of proteins, while circular permutation enables the termini of an SBP to be repositioned to maximize the dynamic range of the resulting FRET sensor. We also provide a protocol for cloning the engineered SBPs into FRET sensor constructs using Golden Gate assembly and discuss considerations for in situ characterization of the FRET sensors.

Original language	English
Title of host publication	Methods in Molecular Biology
Publisher	Humana Press Inc.
Pages	71-87
Number of pages	17
DOIs	https://doi.org/10.1007/978-1-4939-6940-1_5
Publication status	Published - 2017

Publication series

Name	Methods in Molecular Biology
Volume	1596
ISSN (Print)	1064-3745

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10.1007/978-1-4939-6940-1_5

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Clifton, B. E., Whitfield, J. H., Sanchez-Romero, I., Herde, M. K., Henneberger, C., Janovjak, H., & Jackson, C. J. (2017). Ancestral protein reconstruction and circular permutation for improving the stability and dynamic range of FRET sensors. In Methods in Molecular Biology (pp. 71-87). (Methods in Molecular Biology; Vol. 1596). Humana Press Inc.. https://doi.org/10.1007/978-1-4939-6940-1_5

@inbook{b27c699724a64bdf9d2fb91540279b05,

title = "Ancestral protein reconstruction and circular permutation for improving the stability and dynamic range of FRET sensors",

abstract = "Small molecule biosensors based on F{\"o}rster resonance energy transfer (FRET) enable small molecule signaling to be monitored with high spatial and temporal resolution in complex cellular environments. FRET sensors can be constructed by fusing a pair of fluorescent proteins to a suitable recognition domain, such as a member of the solute-binding protein (SBP) superfamily. However, naturally occurring SBPs may be unsuitable for incorporation into FRET sensors due to their low thermostability, which may preclude imaging under physiological conditions, or because the positions of their N- and C-termini may be suboptimal for fusion of fluorescent proteins, which may limit the dynamic range of the resulting sensors. Here, we show how these problems can be overcome using ancestral protein reconstruction and circular permutation. Ancestral protein reconstruction, used as a protein engineering strategy, leverages phylogenetic information to improve the thermostability of proteins, while circular permutation enables the termini of an SBP to be repositioned to maximize the dynamic range of the resulting FRET sensor. We also provide a protocol for cloning the engineered SBPs into FRET sensor constructs using Golden Gate assembly and discuss considerations for in situ characterization of the FRET sensors.",

keywords = "Ancestral protein reconstruction, Biosensor, Circular permutation, Fluorescence, F{\"o}rster resonance energy transfer, Phylogenetic analysis, Protein engineering, Thermostability",

author = "Clifton, {Ben E.} and Whitfield, {Jason H.} and Inmaculada Sanchez-Romero and Herde, {Michel K.} and Christian Henneberger and Harald Janovjak and Jackson, {Colin J.}",

note = "Publisher Copyright: {\textcopyright} Springer Science+Business Media LLC 2017.",

year = "2017",

doi = "10.1007/978-1-4939-6940-1_5",

language = "English",

series = "Methods in Molecular Biology",

publisher = "Humana Press Inc.",

pages = "71--87",

booktitle = "Methods in Molecular Biology",

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Clifton, BE, Whitfield, JH, Sanchez-Romero, I, Herde, MK, Henneberger, C, Janovjak, H & Jackson, CJ 2017, Ancestral protein reconstruction and circular permutation for improving the stability and dynamic range of FRET sensors. in Methods in Molecular Biology. Methods in Molecular Biology, vol. 1596, Humana Press Inc., pp. 71-87. https://doi.org/10.1007/978-1-4939-6940-1_5

Ancestral protein reconstruction and circular permutation for improving the stability and dynamic range of FRET sensors. / Clifton, Ben E.; Whitfield, Jason H.; Sanchez-Romero, Inmaculada et al.
Methods in Molecular Biology. Humana Press Inc., 2017. p. 71-87 (Methods in Molecular Biology; Vol. 1596).

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

TY - CHAP

T1 - Ancestral protein reconstruction and circular permutation for improving the stability and dynamic range of FRET sensors

AU - Clifton, Ben E.

AU - Whitfield, Jason H.

AU - Sanchez-Romero, Inmaculada

AU - Herde, Michel K.

AU - Henneberger, Christian

AU - Janovjak, Harald

AU - Jackson, Colin J.

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N2 - Small molecule biosensors based on Förster resonance energy transfer (FRET) enable small molecule signaling to be monitored with high spatial and temporal resolution in complex cellular environments. FRET sensors can be constructed by fusing a pair of fluorescent proteins to a suitable recognition domain, such as a member of the solute-binding protein (SBP) superfamily. However, naturally occurring SBPs may be unsuitable for incorporation into FRET sensors due to their low thermostability, which may preclude imaging under physiological conditions, or because the positions of their N- and C-termini may be suboptimal for fusion of fluorescent proteins, which may limit the dynamic range of the resulting sensors. Here, we show how these problems can be overcome using ancestral protein reconstruction and circular permutation. Ancestral protein reconstruction, used as a protein engineering strategy, leverages phylogenetic information to improve the thermostability of proteins, while circular permutation enables the termini of an SBP to be repositioned to maximize the dynamic range of the resulting FRET sensor. We also provide a protocol for cloning the engineered SBPs into FRET sensor constructs using Golden Gate assembly and discuss considerations for in situ characterization of the FRET sensors.

AB - Small molecule biosensors based on Förster resonance energy transfer (FRET) enable small molecule signaling to be monitored with high spatial and temporal resolution in complex cellular environments. FRET sensors can be constructed by fusing a pair of fluorescent proteins to a suitable recognition domain, such as a member of the solute-binding protein (SBP) superfamily. However, naturally occurring SBPs may be unsuitable for incorporation into FRET sensors due to their low thermostability, which may preclude imaging under physiological conditions, or because the positions of their N- and C-termini may be suboptimal for fusion of fluorescent proteins, which may limit the dynamic range of the resulting sensors. Here, we show how these problems can be overcome using ancestral protein reconstruction and circular permutation. Ancestral protein reconstruction, used as a protein engineering strategy, leverages phylogenetic information to improve the thermostability of proteins, while circular permutation enables the termini of an SBP to be repositioned to maximize the dynamic range of the resulting FRET sensor. We also provide a protocol for cloning the engineered SBPs into FRET sensor constructs using Golden Gate assembly and discuss considerations for in situ characterization of the FRET sensors.

KW - Ancestral protein reconstruction

KW - Biosensor

KW - Circular permutation

KW - Fluorescence

KW - Förster resonance energy transfer

KW - Phylogenetic analysis

KW - Protein engineering

KW - Thermostability

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DO - 10.1007/978-1-4939-6940-1_5

M3 - Chapter

T3 - Methods in Molecular Biology

SP - 71

EP - 87

BT - Methods in Molecular Biology

PB - Humana Press Inc.

ER -

Ancestral protein reconstruction and circular permutation for improving the stability and dynamic range of FRET sensors

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