Nonlinear optical properties of photosensory core modules of monomeric and dimeric bacterial phytochromes

Diana Galiakhmetova; Aleksandr Koviarov; Viktor Dremin; Tatjana Gric; Dmitrii Stoliarov; Andrei Gorodetsky; Marios Maimaris; Daria Shcherbakova; Mikhail Baloban; Vladislav Verkhusha; Sergei G. Sokolovski; Edik Rafailov

doi:10.1002/pro.70118

Nonlinear optical properties of photosensory core modules of monomeric and dimeric bacterial phytochromes

Diana Galiakhmetova^*, Aleksandr Koviarov, Viktor Dremin, Tatjana Gric, Dmitrii Stoliarov, Andrei Gorodetsky, Marios Maimaris, Daria Shcherbakova, Mikhail Baloban, Vladislav Verkhusha, Sergei G. Sokolovski, Edik Rafailov

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Near-infrared (NIR) fluorescent proteins and optogenetic tools derived from bacterial phytochromes' photosensory core modules (PCMs) operate within the first (NIR-I) tissue transparency window under single-photon activation. Leveraging two-photon (2P) light in the second transparency window (NIR-II) for photoswitching bacterial phytochromes between Pr and Pfr absorption states offers significant advantages, including enhanced tissue penetration, spatial resolution, and signal-to-noise ratio. However, 2P photoconversion of bacterial phytochromes remains understudied. Here, we study the non-linear Pr to Pfr photoconversion's dependence on irradiation wavelength (1180-1360 nm) and energy fluence (41-339 mJ/cm 2) for the PCM of DrBphP bacterial phytochrome. Our findings reveal substantially higher photoconversion efficiency for the engineered monomeric DrBphP-PCM (73%) compared to the natural dimeric DrBphP-PCM (57%). Molecular mechanical calculations, based on experimentally determined 2P absorption cross-section coefficients for the monomer (167 GM) and dimer (170 GM), further verify these results. We demonstrate both short- (SWE) and long-wavelength excitation (LWE) fluorescence of the Soret band using 405 and 810-890 nm laser sources, respectively. Under LWE, fluorescence emission (724 nm) exhibits saturation at a peak power density of 1.5 GW/cm 2. For SWE, we observe linear degradation of fluorescence for both DrBphP-PCMs, decreasing by 32% as the temperature rises from 19 to 38°C. Conversely, under LWE, the monomeric DrBphP-PCM's brightness increases up to 182% (at 37°C), surpassing the dimeric form's fluorescence rise by 39%. These findings establish the monomeric DrBphP-PCM as a promising template for developing NIR imaging and optogenetic probes operating under the determined optimal parameters for its 2P photoconversion and LWE fluorescence.

Original language	English
Article number	e70118
Number of pages	14
Journal	Protein Science
Volume	34
Issue number	5
Early online date	18 Apr 2025
DOIs	https://doi.org/10.1002/pro.70118
Publication status	Published - May 2025

Bibliographical note

Copyright © 2025 The Author(s). Protein Science published by Wiley Periodicals LLC on behalf of The Protein Society. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

Keywords

bacterial phytocrome
DrBphP
Near-infrared fluorescent protein (iRFP)
long-wavelength excitation
two-photon photoconversation

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10.1002/pro.70118Licence: CC BY 4.0

Protein Science - 2025 - Galiakhmetova - Nonlinear optical properties of photosensory core modules of monomeric and dimeric
Copyright © 2025 The Author(s). Protein Science published by Wiley Periodicals LLC on behalf of The Protein Society. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.
Final published version, 22.9 MBLicence: CC BY 4.0

Cite this

@article{a5e58e3729ab45b78528b06c42cdcea0,

title = "Nonlinear optical properties of photosensory core modules of monomeric and dimeric bacterial phytochromes",

abstract = "Near-infrared (NIR) fluorescent proteins and optogenetic tools derived from bacterial phytochromes' photosensory core modules (PCMs) operate within the first (NIR-I) tissue transparency window under single-photon activation. Leveraging two-photon (2P) light in the second transparency window (NIR-II) for photoswitching bacterial phytochromes between Pr and Pfr absorption states offers significant advantages, including enhanced tissue penetration, spatial resolution, and signal-to-noise ratio. However, 2P photoconversion of bacterial phytochromes remains understudied. Here, we study the non-linear Pr to Pfr photoconversion's dependence on irradiation wavelength (1180-1360 nm) and energy fluence (41-339 mJ/cm 2) for the PCM of DrBphP bacterial phytochrome. Our findings reveal substantially higher photoconversion efficiency for the engineered monomeric DrBphP-PCM (73%) compared to the natural dimeric DrBphP-PCM (57%). Molecular mechanical calculations, based on experimentally determined 2P absorption cross-section coefficients for the monomer (167 GM) and dimer (170 GM), further verify these results. We demonstrate both short- (SWE) and long-wavelength excitation (LWE) fluorescence of the Soret band using 405 and 810-890 nm laser sources, respectively. Under LWE, fluorescence emission (724 nm) exhibits saturation at a peak power density of 1.5 GW/cm 2. For SWE, we observe linear degradation of fluorescence for both DrBphP-PCMs, decreasing by 32% as the temperature rises from 19 to 38°C. Conversely, under LWE, the monomeric DrBphP-PCM's brightness increases up to 182% (at 37°C), surpassing the dimeric form's fluorescence rise by 39%. These findings establish the monomeric DrBphP-PCM as a promising template for developing NIR imaging and optogenetic probes operating under the determined optimal parameters for its 2P photoconversion and LWE fluorescence. ",

keywords = "bacterial phytocrome, DrBphP, Near-infrared fluorescent protein (iRFP), long-wavelength excitation, two-photon photoconversation",

author = "Diana Galiakhmetova and Aleksandr Koviarov and Viktor Dremin and Tatjana Gric and Dmitrii Stoliarov and Andrei Gorodetsky and Marios Maimaris and Daria Shcherbakova and Mikhail Baloban and Vladislav Verkhusha and Sokolovski, {Sergei G.} and Edik Rafailov",

note = "Copyright {\textcopyright} 2025 The Author(s). Protein Science published by Wiley Periodicals LLC on behalf of The Protein Society. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.",

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T1 - Nonlinear optical properties of photosensory core modules of monomeric and dimeric bacterial phytochromes

AU - Galiakhmetova, Diana

AU - Koviarov, Aleksandr

AU - Dremin, Viktor

AU - Gric, Tatjana

AU - Stoliarov, Dmitrii

AU - Gorodetsky, Andrei

AU - Maimaris, Marios

AU - Shcherbakova, Daria

AU - Baloban, Mikhail

AU - Verkhusha, Vladislav

AU - Sokolovski, Sergei G.

AU - Rafailov, Edik

N1 - Copyright © 2025 The Author(s). Protein Science published by Wiley Periodicals LLC on behalf of The Protein Society. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

PY - 2025/5

Y1 - 2025/5

N2 - Near-infrared (NIR) fluorescent proteins and optogenetic tools derived from bacterial phytochromes' photosensory core modules (PCMs) operate within the first (NIR-I) tissue transparency window under single-photon activation. Leveraging two-photon (2P) light in the second transparency window (NIR-II) for photoswitching bacterial phytochromes between Pr and Pfr absorption states offers significant advantages, including enhanced tissue penetration, spatial resolution, and signal-to-noise ratio. However, 2P photoconversion of bacterial phytochromes remains understudied. Here, we study the non-linear Pr to Pfr photoconversion's dependence on irradiation wavelength (1180-1360 nm) and energy fluence (41-339 mJ/cm 2) for the PCM of DrBphP bacterial phytochrome. Our findings reveal substantially higher photoconversion efficiency for the engineered monomeric DrBphP-PCM (73%) compared to the natural dimeric DrBphP-PCM (57%). Molecular mechanical calculations, based on experimentally determined 2P absorption cross-section coefficients for the monomer (167 GM) and dimer (170 GM), further verify these results. We demonstrate both short- (SWE) and long-wavelength excitation (LWE) fluorescence of the Soret band using 405 and 810-890 nm laser sources, respectively. Under LWE, fluorescence emission (724 nm) exhibits saturation at a peak power density of 1.5 GW/cm 2. For SWE, we observe linear degradation of fluorescence for both DrBphP-PCMs, decreasing by 32% as the temperature rises from 19 to 38°C. Conversely, under LWE, the monomeric DrBphP-PCM's brightness increases up to 182% (at 37°C), surpassing the dimeric form's fluorescence rise by 39%. These findings establish the monomeric DrBphP-PCM as a promising template for developing NIR imaging and optogenetic probes operating under the determined optimal parameters for its 2P photoconversion and LWE fluorescence.

AB - Near-infrared (NIR) fluorescent proteins and optogenetic tools derived from bacterial phytochromes' photosensory core modules (PCMs) operate within the first (NIR-I) tissue transparency window under single-photon activation. Leveraging two-photon (2P) light in the second transparency window (NIR-II) for photoswitching bacterial phytochromes between Pr and Pfr absorption states offers significant advantages, including enhanced tissue penetration, spatial resolution, and signal-to-noise ratio. However, 2P photoconversion of bacterial phytochromes remains understudied. Here, we study the non-linear Pr to Pfr photoconversion's dependence on irradiation wavelength (1180-1360 nm) and energy fluence (41-339 mJ/cm 2) for the PCM of DrBphP bacterial phytochrome. Our findings reveal substantially higher photoconversion efficiency for the engineered monomeric DrBphP-PCM (73%) compared to the natural dimeric DrBphP-PCM (57%). Molecular mechanical calculations, based on experimentally determined 2P absorption cross-section coefficients for the monomer (167 GM) and dimer (170 GM), further verify these results. We demonstrate both short- (SWE) and long-wavelength excitation (LWE) fluorescence of the Soret band using 405 and 810-890 nm laser sources, respectively. Under LWE, fluorescence emission (724 nm) exhibits saturation at a peak power density of 1.5 GW/cm 2. For SWE, we observe linear degradation of fluorescence for both DrBphP-PCMs, decreasing by 32% as the temperature rises from 19 to 38°C. Conversely, under LWE, the monomeric DrBphP-PCM's brightness increases up to 182% (at 37°C), surpassing the dimeric form's fluorescence rise by 39%. These findings establish the monomeric DrBphP-PCM as a promising template for developing NIR imaging and optogenetic probes operating under the determined optimal parameters for its 2P photoconversion and LWE fluorescence.

KW - bacterial phytocrome

KW - DrBphP

KW - Near-infrared fluorescent protein (iRFP)

KW - long-wavelength excitation

KW - two-photon photoconversation

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U2 - 10.1002/pro.70118

DO - 10.1002/pro.70118

M3 - Article

C2 - 40248855

SN - 0961-8368

VL - 34

JO - Protein Science

JF - Protein Science

IS - 5

M1 - e70118

ER -

Nonlinear optical properties of photosensory core modules of monomeric and dimeric bacterial phytochromes

Abstract

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Keywords

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