Application of Amber Suppression To Study the Role of Tyr M210 in Electron Transfer in Rhodobacter sphaeroides Photosynthetic Reaction Centers

Khoi N. Tran; Kaitlyn M. Faries; Nikki Cecil Macasinag Magdaong; Irimpan I. Mathews; Jared B. Weaver; Jacob M. Kirsh; Dewey Holten; Christine Kirmaier; Steven G. Boxer

doi:10.1021/acs.jpcb.5c00082

Application of Amber Suppression To Study the Role of Tyr M210 in Electron Transfer in Rhodobacter sphaeroides Photosynthetic Reaction Centers

Khoi N. Tran
, Kaitlyn M. Faries
, Nikki Cecil Macasinag Magdaong
, Irimpan I. Mathews
, Jared B. Weaver
, Jacob M. Kirsh
, Dewey Holten
, Christine Kirmaier
, Steven G. Boxer

Department of Chemistry

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

Abstract

The initial light-induced electron transfer (ET) steps in the bacterial photosynthetic reaction center (RC) have been extensively studied and provide a paradigm for connecting structure and function. Although RCs have local pseudo-C₂ symmetry, ET only occurs along the A branch of chromophores. Tyrosine M210 is a key symmetry-breaking residue adjacent to bacteriochlorophyll B_A that bridges the primary electron donor P and the bacteriopheophytin acceptor H_A. We used amber suppression to incorporate phenylalanine variants with different electron-withdrawing/-donating capabilities at the position M210. X-ray data generally reveal no appreciable structural changes due to the mutations. P* decay and P⁺H_A^- formation are multiexponential (∼2 to 9, ∼10 to 60, and ∼100 to 300 ps) and temperature dependent. The 1020 nm transient-absorption band of P⁺B_A^- is barely resolved for a few variants at 295 K and for none at 77 K. The results indicate a change from two-step ET for wild-type RCs to the dominance of one-step superexchange ET for the mutants. Resonance Stark spectroscopy reveals that the free energy of P⁺B_A^- changes by −57 to +66 meV among the phenylalanine variants. Because P⁺B_A^- apparently lies above P* in all phenylalanine variants, the perturbations primarily affect the energy denominator for superexchange mixing. The findings deepen insight into primary ET in the bacterial RC.

Original language	English
Pages (from-to)	3317-3333
Number of pages	17
Journal	Journal of Physical Chemistry B
Volume	129
Issue number	13
DOIs	https://doi.org/10.1021/acs.jpcb.5c00082
State	Published - Apr 3 2025

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Tran, K. N., Faries, K. M., Magdaong, N. C. M., Mathews, I. I., Weaver, J. B., Kirsh, J. M., Holten, D., Kirmaier, C., & Boxer, S. G. (2025). Application of Amber Suppression To Study the Role of Tyr M210 in Electron Transfer in Rhodobacter sphaeroides Photosynthetic Reaction Centers. Journal of Physical Chemistry B, 129(13), 3317-3333. https://doi.org/10.1021/acs.jpcb.5c00082

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title = "Application of Amber Suppression To Study the Role of Tyr M210 in Electron Transfer in Rhodobacter sphaeroides Photosynthetic Reaction Centers",

abstract = "The initial light-induced electron transfer (ET) steps in the bacterial photosynthetic reaction center (RC) have been extensively studied and provide a paradigm for connecting structure and function. Although RCs have local pseudo-C2 symmetry, ET only occurs along the A branch of chromophores. Tyrosine M210 is a key symmetry-breaking residue adjacent to bacteriochlorophyll BA that bridges the primary electron donor P and the bacteriopheophytin acceptor HA. We used amber suppression to incorporate phenylalanine variants with different electron-withdrawing/-donating capabilities at the position M210. X-ray data generally reveal no appreciable structural changes due to the mutations. P* decay and P+HA- formation are multiexponential (∼2 to 9, ∼10 to 60, and ∼100 to 300 ps) and temperature dependent. The 1020 nm transient-absorption band of P+BA- is barely resolved for a few variants at 295 K and for none at 77 K. The results indicate a change from two-step ET for wild-type RCs to the dominance of one-step superexchange ET for the mutants. Resonance Stark spectroscopy reveals that the free energy of P+BA- changes by −57 to +66 meV among the phenylalanine variants. Because P+BA- apparently lies above P* in all phenylalanine variants, the perturbations primarily affect the energy denominator for superexchange mixing. The findings deepen insight into primary ET in the bacterial RC.",

author = "Tran, \{Khoi N.\} and Faries, \{Kaitlyn M.\} and Magdaong, \{Nikki Cecil Macasinag\} and Mathews, \{Irimpan I.\} and Weaver, \{Jared B.\} and Kirsh, \{Jacob M.\} and Dewey Holten and Christine Kirmaier and Boxer, \{Steven G.\}",

note = "Publisher Copyright: {\textcopyright} 2025 American Chemical Society.",

year = "2025",

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day = "3",

doi = "10.1021/acs.jpcb.5c00082",

language = "English",

volume = "129",

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AU - Tran, Khoi N.

AU - Faries, Kaitlyn M.

AU - Magdaong, Nikki Cecil Macasinag

AU - Mathews, Irimpan I.

AU - Weaver, Jared B.

AU - Kirsh, Jacob M.

AU - Holten, Dewey

AU - Kirmaier, Christine

AU - Boxer, Steven G.

PY - 2025/4/3

Y1 - 2025/4/3

N2 - The initial light-induced electron transfer (ET) steps in the bacterial photosynthetic reaction center (RC) have been extensively studied and provide a paradigm for connecting structure and function. Although RCs have local pseudo-C2 symmetry, ET only occurs along the A branch of chromophores. Tyrosine M210 is a key symmetry-breaking residue adjacent to bacteriochlorophyll BA that bridges the primary electron donor P and the bacteriopheophytin acceptor HA. We used amber suppression to incorporate phenylalanine variants with different electron-withdrawing/-donating capabilities at the position M210. X-ray data generally reveal no appreciable structural changes due to the mutations. P* decay and P+HA- formation are multiexponential (∼2 to 9, ∼10 to 60, and ∼100 to 300 ps) and temperature dependent. The 1020 nm transient-absorption band of P+BA- is barely resolved for a few variants at 295 K and for none at 77 K. The results indicate a change from two-step ET for wild-type RCs to the dominance of one-step superexchange ET for the mutants. Resonance Stark spectroscopy reveals that the free energy of P+BA- changes by −57 to +66 meV among the phenylalanine variants. Because P+BA- apparently lies above P* in all phenylalanine variants, the perturbations primarily affect the energy denominator for superexchange mixing. The findings deepen insight into primary ET in the bacterial RC.

AB - The initial light-induced electron transfer (ET) steps in the bacterial photosynthetic reaction center (RC) have been extensively studied and provide a paradigm for connecting structure and function. Although RCs have local pseudo-C2 symmetry, ET only occurs along the A branch of chromophores. Tyrosine M210 is a key symmetry-breaking residue adjacent to bacteriochlorophyll BA that bridges the primary electron donor P and the bacteriopheophytin acceptor HA. We used amber suppression to incorporate phenylalanine variants with different electron-withdrawing/-donating capabilities at the position M210. X-ray data generally reveal no appreciable structural changes due to the mutations. P* decay and P+HA- formation are multiexponential (∼2 to 9, ∼10 to 60, and ∼100 to 300 ps) and temperature dependent. The 1020 nm transient-absorption band of P+BA- is barely resolved for a few variants at 295 K and for none at 77 K. The results indicate a change from two-step ET for wild-type RCs to the dominance of one-step superexchange ET for the mutants. Resonance Stark spectroscopy reveals that the free energy of P+BA- changes by −57 to +66 meV among the phenylalanine variants. Because P+BA- apparently lies above P* in all phenylalanine variants, the perturbations primarily affect the energy denominator for superexchange mixing. The findings deepen insight into primary ET in the bacterial RC.

UR - https://www.scopus.com/pages/publications/105002033403

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JO - Journal of Physical Chemistry B

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ER -

Application of Amber Suppression To Study the Role of Tyr M210 in Electron Transfer in Rhodobacter sphaeroides Photosynthetic Reaction Centers

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