The role of local and remote amino acid substitutions for optimizing fluorescence in bacteriophytochromes: A case study on iRFP.

David Buhrke,Nico Herder,Franz-Josef Schmitt,Francisco Velazquez Escobar,Anke Keidel,Neslihan N Tavraz,Peter Hildebrandt,Thomas Friedrich,Luisa Sauthof,Mario Willoweit,Svea Wilkening,Maria-Andrea Mroginski,Tillmann Utesch

doi:10.1038/srep28444

David Buhrke, Nico Herder + Show 11 more

Open Access

https://doi.org/10.1038/srep28444

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Journal: Scientific Reports	Publication Date: Jun 22, 2016
Citations: 19	License type: CC BY 4.0

Affiliation: Technische Universität Berlin

Abstract

Bacteriophytochromes are promising tools for tissue microscopy and imaging due to their fluorescence in the near-infrared region. These applications require optimization of the originally low fluorescence quantum yields via genetic engineering. Factors that favour fluorescence over other non-radiative excited state decay channels are yet poorly understood. In this work we employed resonance Raman and fluorescence spectroscopy to analyse the consequences of multiple amino acid substitutions on fluorescence of the iRFP713 benchmark protein. Two groups of mutations distinguishing iRFP from its precursor, the PAS-GAF domain of the bacteriophytochrome P2 from Rhodopseudomonas palustris, have qualitatively different effects on the biliverdin cofactor, which exists in a fluorescent (state II) and a non-fluorescent conformer (state I). Substitution of three critical amino acids in the chromophore binding pocket increases the intrinsic fluorescence quantum yield of state II from 1.7 to 5.0% due to slight structural changes of the tetrapyrrole chromophore. Whereas these changes are accompanied by an enrichment of state II from ~40 to ~50%, a major shift to ~88% is achieved by remote amino acid substitutions. Additionally, an increase of the intrinsic fluorescence quantum yield of this conformer by ~34% is achieved. The present results have important implications for future design strategies of biofluorophores.

Highlights

Straightforward, since the photochemical conversion for BV-binding phytochromes of less than 10%12 is still low compared to the non-radiative excited-state decay pathways
We focused on three highly conserved AAs in the chromophore-binding pocket (CBP), Asp[202], Ile[203], and Tyr[258], which in iRFP are replaced by Thr, Val, and Phe, respectively
The impact of substituting D202 and Y258 on the structure of the chromophore pocket has been recently analysed for the Pr state of the chromophore-binding domain CBD-DR15 of the Deinococcus radiodurans bacteriophytochrome (AA numbering refers to P2PG)

Summary

Introduction

Straightforward, since the photochemical conversion for BV-binding phytochromes of less than 10%12 is still low compared to the non-radiative excited-state decay pathways. Promising results were obtained by genetic engineering of the chromophore-binding domain of RpBphP2, which produced an efficient phytofluor denoted iRFP71311,14 (termed iRFP for brevity ) This variant differs from the truncated wild-type (WT) protein RpBphP2 (including only the GAF and PAS domains, termed P2PG in the following) by a total of 13 mutations. These substitutions resulted in a Фfl of 5.9% compared to 0.7% for P2PG. For the iRFP-T202D/F258Y variant, the error in the intensity determination was too large due to a close overlap of the respective bands (Fig. 5, left) and a very low intensity of the conformer I component ( denoted as “n.a.” =not applicable)

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Conclusion