Coherent exciton coupling in fluorescent protein dimers probed by two-photon polarization ratio

Abstract

Coherent excitonic coupling of two chromophores in a dimer of a GFP-analogue, VenusA206, was discovered previously by using circular dichroism and a combination of photon antibunching and fluorescence correlation spectroscopy. To further elucidate this effect, here we use a new approach based on the measurements of two-photon polarization ratio (Ω) as a function of excitation wavelength. Theoretically, Ω depends on the angle between the vectors of absorption transition dipole moment and permanent dipole moment change upon excitation. Generally, excitonic coupling of two chromophores should provide a change of this angle. We measured Ω for the tandem dimer of Venus (tdV) with two chromophores per protein chain and, as a control - for the tandem dimer with one of the chromophores knocked out by point mutation (tdVx). Compared to tdVx, we observe in tdV a significant increase of Ω in the red side of the pure electronic transition and a significant decrease of Ω in the blue side. At the same time, the two-photon absorption spectra of the two systems virtually coincide. Our observations are consistent with a model where only a minority of dimers are coupled coherently and the two permanent dipoles are oriented in an oblique head-to-head arrangement with an angle ∼400 between them. For multiphoton microscopy applications, it is interesting to investigate if the coherently coupled GFP dimer can provide a cooperative enhancement of the two-photon cross section, i.e., absorb stronger than two uncoupled monomers. This possibility can come from the “motional narrowing” of excitonic transition and will be discussed.