Excited State Vibrational Dynamics Reveals a Photocycle That Enhances the Photostability of the TagRFP-T Fluorescent Protein.
Atsushi YabushitaChia-Yun ChengYing Kuan KoTakayoshi KobayashiIzumi IwakuraRalph JimenezPublished in: The journal of physical chemistry. B (2024)
High photostability is a desirable property of fluorescent proteins (FPs) for imaging, yet its molecular basis is poorly understood. We performed ultrafast spectroscopy on TagRFP and its 9-fold more photostable variant TagRFP-T (TagRFP S158T) to characterize their initial photoreactions. We find significant differences in their electronic and vibrational dynamics, including faster excited-state proton transfer and transient changes in the frequency of the v 520 mode in the excited electronic state of TagRFP-T. The frequency of v 520 , which is sensitive to chromophore planarity, downshifts within 0.58 ps and recovers within 0.87 ps. This vibrational mode modulates the distance from the chromophore phenoxy to the side chain of residue N143, which we suggest can trigger cis/trans photoisomerization. In TagRFP, the dynamics of v 520 is missing, and this FP therefore lacks an important channel for chromophore isomerization. These dynamics are likely to be a key mechanism differentiating the photostability of the two FPs.
Keyphrases
- energy transfer
- density functional theory
- molecular dynamics simulations
- quantum dots
- living cells
- electron transfer
- computed tomography
- single molecule
- raman spectroscopy
- amino acid
- molecular dynamics
- protein protein
- brain injury
- label free
- contrast enhanced
- mass spectrometry
- cerebral ischemia
- binding protein
- blood brain barrier