ABSTRACT
The photosynthetic reaction center (RC) converts light energy into electrochemical energy. The RC of heliobacteria (hRC) is a primitive homodimeric RC containing 58 bacteriochlorophylls and 2 chlorophyll as. The chlorophyll serves as the primary electron acceptor (Chl a-A0) responsible for light harvesting and charge separation. The single-molecule spectroscopy of Chl a-A0 can be used to investigate heterogeneities of the RC photochemical function, though the low fluorescence quantum yield (0.1%) makes it difficult. Here, we show the fluorescence excitation spectroscopy of individual Chl a-A0s in single hRCs at 6 K. The fluorescence quantum yield and absorption cross section of Chl a-A0 increase 2- and 4-fold, respectively, compared to those at room temperature. The two Chl a-A0s in single hRCs are identified as two distinct peaks in the fluorescence excitation spectrum, exhibiting different excitation polarization dependences. The spectral changes caused by photobleaching indicate the energy transfer across subunits in the hRC.
ABSTRACT
We prepared a pair with a visible-absorbing donor dye and a near-infrared fluorescing acceptor dye. The donor and the acceptor were covalently linked close enough for Förster resonance energy transfer to occur. Under cryogenic conditions at 1.7 K, we observed the fluorescence excitation spectra of the individual pairs in a water matrix. We tested one rhodamine, two Bodipy, and one carbopyronine derivatives as the donor. Among these donors, Bodipy derivatives show the narrowest spectral width of the individuals with respect to the ensemble width. Thus, Bodipy dyes were favorable as the donor for the spectral selection of individual pairs. At 1.7 K, from the several Bodipy-acceptor pairs in the diffraction-limited volume, an individual pair was selected by the fluorescence excitation spectrum of the donor. The spectrally selected pair was localized using the near-infrared fluorescence of the acceptor.
