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Anisotropické optické vlastnosti fluorescentních proteinů
Rybakova, Olga ; Lazar, Josef (advisor) ; Hof, Martin (referee)
Fluorescent proteins (FPs) are the workhorses of biological molecular imaging. Important imaging modalities (such as polarization microscopy or FRET imaging) exploit anisotropic optical properties of fluorescent proteins. In this thesis, we present the results of our polarization microscopy and X-ray diffraction experiments on FP crystals, as well as mathematical interpretation of these results, yielding information on the directionality of one- and two-photon absorption within the investigated fluorescent protein molecules. For the anisotropy of one-photon absorption, we determine the transition dipole moment (TDM) orientations in three representative fluorescent proteins. Validation with available quantum mechanical predictions values and an experimentally determined TDM orientation of the GFP gives confidence to the results obtained. For the two-photon absorption, we first test our hypothesis that two-photon absorptivity tensors of representative FPs exhibit vector-like behaviour and then examine the applicability of this simplification as a basis for the interpretation of our two-photon polarization microscopy data.
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Anisotropické optické vlastnosti fluorescentních proteinů
Rybakova, Olga ; Lazar, Josef (advisor) ; Hof, Martin (referee)
Fluorescent proteins (FPs) are the workhorses of biological molecular imaging. Important imaging modalities (such as polarization microscopy or FRET imaging) exploit anisotropic optical properties of fluorescent proteins. In this thesis, we present the results of our polarization microscopy and X-ray diffraction experiments on FP crystals, as well as mathematical interpretation of these results, yielding information on the directionality of one- and two-photon absorption within the investigated fluorescent protein molecules. For the anisotropy of one-photon absorption, we determine the transition dipole moment (TDM) orientations in three representative fluorescent proteins. Validation with available quantum mechanical predictions values and an experimentally determined TDM orientation of the GFP gives confidence to the results obtained. For the two-photon absorption, we first test our hypothesis that two-photon absorptivity tensors of representative FPs exhibit vector-like behaviour and then examine the applicability of this simplification as a basis for the interpretation of our two-photon polarization microscopy data.
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Simulation of processes in cellular membranes
Timr, Štěpán ; Jungwirth, Pavel (advisor) ; Pittner, Jiří (referee)
Probing orientations of fluorescent molecules embedded in or attached to cell membranes has a great potential to reveal information on membrane structure and processes occurring in living cells. In this thesis, we first describe one- and two-photon linear dichroism measurements on a fluorescent probe embedded in a phospholipid membrane with a well- defined lipid composition. On the basis of experimental data, we determine the distribution of the angle between the one-photon transition dipole moment of the probe and the membrane normal. At the same time, we perform molecular dynamics simulations of the fluorescent probe and quantum calculations of its one-photon and two-photon absorption properties. By comparing the orientational distribution gained from experiments with that predicted by simulations, we test the ability of linear dichroism measurements to report on the orientation of a fluorescent molecule in a lipid membrane. We also examine the applicability of molecular simulations as a basis for the interpretation of experimental data.
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