00374nas a2200121 4500008004100000245005400041210005400095100001100149700001900160700001600179700002000195856003700215 2019 eng d00aPhoto Switching of Protein Dynamical Collectivity0 aPhoto Switching of Protein Dynamical Collectivity1 aXu, M.1 aGeorge, D., K.1 aJimenez, R.1 aMarkelz, A., G. uhttps://arxiv.org/abs/1906.0089301399nas a2200169 4500008004500000020002200045245007600067210006900143260001900212520086600231653001301097100001501110700001901125700001601144700002001160856004901180 2014 Engldsh a978-1-4799-3877-300aProbing the Stability of Fluorescent Proteins by Terahertz Spectroscopy0 aProbing the Stability of Fluorescent Proteins by Terahertz Spect aNew YorkbIeee3 a
The higher transmission through tissues of long wavelength light motivates the development of fluorescent proteins with excitation shifted to the red. However red fluorescent proteins (RFPs) are more susceptible to photobleaching than their shorter wavelength counterparts. In particular RFPs are more susceptible to photobleaching [1]. A possible reason for this is a decrease in the structural stability of the beta barrel. Measurements of structural stability include atomic root mean squared displacement <x(2)> measured by the X-ray B-factor and neutron quasi elastic scattering. To date, X-ray measurements of RFP's do not indicate a structural stability change and systematic scattering studies have not been performed. Using THz dielectric response we examine if the picosecond structural flexibility decreases with increasing FP stability.
10adynamics1 aXu, M., Y.1 aGeorge, D., K.1 aJimenez, R.1 aMarkelz, A., G. uhttps://markelz.physics.buffalo.edu/node/245