Absorption, steady-state, and time-resolved fluorescence measurements have been performed on laurdan dissolved either in white viscous apolar solvents or in ethanol as a function of temperature. The heterogeneity of the absorption spectra in white oils or in ethanol is consistent with semiempirical calculations performed previously on Prodan. From steady-state and time-resolved fluorescence measurements in apolar media, an excited state reaction is evidenced. The bimodal lifetime distribution determined from the maximum entropy method (MEM) analysis is attributed to the radiative deexcitation of a "locally excited" (LE) state and of a "charge transfer" (CT) state, whereas a very short component (20 ps), the sign and the amplitude of which depend on the emission wavelength, is attributed to the kinetics of the interconvertion reaction. The observation of an isoemissive point in the temperature range from -50 degrees C to -110 degrees C in ethanol suggests an interconvertion between two average excited-state populations: unrelaxed and solvent-relaxed CT states. A further decrease in temperature (-190 degrees C), leading to frozen ethanol, induces an additional and important blue shift. This low temperature spectrum is partly attributed to the radiative deexcitation of the LE state. Time-resolved emission spectra (TRES) measurements at -80 degrees C in the ethanol liquid phase show a large spectral shift of approximately 2500 cm(-1) (stabilization energy of the excited state: 7.1 kcal x M(-1)). The time-dependent fluorescence shift (TDFS) is described for its major part by a nanosecond time constant. The initial part of the spectral shift reveals, however, a subnanosecond process that can be due to fast internal solvent reorientation and/or to intramolecular excited-state reactions. These two relaxation times are also detected in the analysis of the fluorescence decays in the middle range of emission energy. The activation energy of the longest process is approximately 3 kcal x M(-1). At -190 degrees C, one subnanosecond and one nanosecond excited-state reactions are also evidenced. They are likely due to intramolecular rearrangements after the excitation, leading to the CT state and not to solvent relaxation, which is severely hindered in these temperature conditions. Therefore, both intramolecular and solvent relaxations are responsible for the large Stokes shift displayed by this probe as a function of solvent polarity. A possible scheme is proposed for the deexcitation pathway, taking into account the kinetics observed in these different solvents.
In iron limitation conditions, Pseudomonas aeruginosa secretes a major fluorescent siderophore named pyoverdin (PaA). PaA has an extremely high affinity for Fe(3+) but also chelates other ions such as Al(3+) and Ga(3+) with a lower affinity. The transfer of PaA-Fe(3+) across the outer membrane of the bacteria is mediated by the receptor FpvA, a TonB-dependent outer membrane transport protein. FpvA binds the iron-free and iron-loaded forms of pyoverdin with similar affinities, but only PaA-Fe(3+) is taken up by the cell, suggesting that FpvA adopts different conformations depending on its loading status. We used time-resolved fluorescence spectroscopy to characterize the different forms of FpvA-PaA in vitro. We showed that the FpvA-PaA complex adopts two different conformations depending on how it was prepared (formed in vitro or in vivo prior to purification). The dihydroquinoline moiety of both conformers is fully protonated, or coordinated by protein charged groups, but the polarity of its environment, its solvent accessibility, and its rotational dynamics are much slower when the FpvA-PaA complex is formed in vivo than in vitro. In the presence of Ga(3+) or Al(3+) ions, the solvent accessibility and mobility of the dihydroquinoline moiety in the two FpvA-PaA complexes are intermediate between those observed for the metal-free ones. In addition, the Förster resonance energy transfer kinetics from FpvA tryptophan residues to the PaA chromophore differs from one complex to the other, revealing differences in one or more of the donor-acceptor topologies.
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