Using Intrinsic Fluorescence to Measure Protein Stability Upon Thermal and Chemical Denaturation

Nathalia Varejão; David Reverter

doi:10.1007/978-1-0716-2784-6_16

Using Intrinsic Fluorescence to Measure Protein Stability Upon Thermal and Chemical Denaturation

Nathalia Varejão^*, David Reverter

^*Corresponding author for this work

Research output: Chapter in Book › Chapter › Research › peer-review

3 Citations (Scopus)

Abstract

Understanding how point mutations affect the performance of protein stability has been the focus of several studies all over the years. Intrinsic fluorescence is commonly used to follow protein unfolding since during denaturation, progressive redshifts on tryptophan fluorescence emission are observed. Since the unfolding process (achieved by chemical or physical denaturants) can be considered as two-state N➔D, it is possible to utilize the midpoint unfolding curves (fU = 50%) as a parameter to evaluate if the mutation destabilizes wild-type protein. The idea is to determine the [D]_1/2 or T_m values from both wild type and mutant and calculate the difference between them. Positive values indicate the mutant is less stable than wild type.

Original language	English
Title of host publication	Methods in Molecular Biology
Pages	229-241
Number of pages	13
Volume	2581
DOIs	https://doi.org/10.1007/978-1-0716-2784-6_16
Publication status	Published - 23 Nov 2022

Publication series

Name	Methods in Molecular Biology
Volume	2581

Keywords

Intrinsic fluorescence
Protein domains
Protein stability
Site-directed mutagenesis

Access to Document

10.1007/978-1-0716-2784-6_16

Cite this

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title = "Using Intrinsic Fluorescence to Measure Protein Stability Upon Thermal and Chemical Denaturation",

abstract = "Understanding how point mutations affect the performance of protein stability has been the focus of several studies all over the years. Intrinsic fluorescence is commonly used to follow protein unfolding since during denaturation, progressive redshifts on tryptophan fluorescence emission are observed. Since the unfolding process (achieved by chemical or physical denaturants) can be considered as two-state N➔D, it is possible to utilize the midpoint unfolding curves (fU = 50%) as a parameter to evaluate if the mutation destabilizes wild-type protein. The idea is to determine the [D]1/2 or Tm values from both wild type and mutant and calculate the difference between them. Positive values indicate the mutant is less stable than wild type.",

keywords = "Intrinsic fluorescence, Protein domains, Protein stability, Site-directed mutagenesis",

author = "Nathalia Varej{\~a}o and David Reverter",

note = "Publisher Copyright: {\textcopyright} 2023, The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.",

year = "2022",

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doi = "10.1007/978-1-0716-2784-6_16",

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T1 - Using Intrinsic Fluorescence to Measure Protein Stability Upon Thermal and Chemical Denaturation

AU - Varejão, Nathalia

AU - Reverter, David

PY - 2022/11/23

Y1 - 2022/11/23

N2 - Understanding how point mutations affect the performance of protein stability has been the focus of several studies all over the years. Intrinsic fluorescence is commonly used to follow protein unfolding since during denaturation, progressive redshifts on tryptophan fluorescence emission are observed. Since the unfolding process (achieved by chemical or physical denaturants) can be considered as two-state N➔D, it is possible to utilize the midpoint unfolding curves (fU = 50%) as a parameter to evaluate if the mutation destabilizes wild-type protein. The idea is to determine the [D]1/2 or Tm values from both wild type and mutant and calculate the difference between them. Positive values indicate the mutant is less stable than wild type.

AB - Understanding how point mutations affect the performance of protein stability has been the focus of several studies all over the years. Intrinsic fluorescence is commonly used to follow protein unfolding since during denaturation, progressive redshifts on tryptophan fluorescence emission are observed. Since the unfolding process (achieved by chemical or physical denaturants) can be considered as two-state N➔D, it is possible to utilize the midpoint unfolding curves (fU = 50%) as a parameter to evaluate if the mutation destabilizes wild-type protein. The idea is to determine the [D]1/2 or Tm values from both wild type and mutant and calculate the difference between them. Positive values indicate the mutant is less stable than wild type.

KW - Intrinsic fluorescence

KW - Protein domains

KW - Protein stability

KW - Site-directed mutagenesis

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DO - 10.1007/978-1-0716-2784-6_16

M3 - Chapter

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AN - SCOPUS:85142700534

VL - 2581

T3 - Methods in Molecular Biology

SP - 229

EP - 241

BT - Methods in Molecular Biology

ER -

Using Intrinsic Fluorescence to Measure Protein Stability Upon Thermal and Chemical Denaturation

Abstract

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Estudios estructurales y funcionales de los mecanismos de regulación de la via de sumo/ubiquitina

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Using Intrinsic Fluorescence to Measure Protein Stability Upon Thermal and Chemical Denaturation

Abstract

Publication series

Keywords

Access to Document

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Estudios estructurales y funcionales de los mecanismos de regulación de la via de sumo/ubiquitina

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