Fluorescence resonance energy transfer studies of protein interactions /

Martin, Sarah Friede.

January 2008

Thesis (Ph.D.) - University of St Andrews, May 2008.

Kinetika fotochromních reakcí v tenkých polymerních filmech / Kinetics of photochromic reactions in thin polymeric layers

Zeman, Vojtěch

January 2008

The thesis is aimed to the study of spiropyrane behavior in polymeric matrix of poly(N-vinylkarbazole) (PVK) and poly[2-methoxy-5-(3´,7´-dimethyloctyloxy)-1,4-fenylenvinylene)] (MDMO-PPV). The photochromic transformation of spiropyrane to its isomeric merocyanine form (SPMC) was studied by absorption and emission spectroscopy. It was found, that photochromic reaction is markedly dependent on the environment. In the PVK polymer, which don’t absorb in the visible region, a high yield of photochromic reaction was achieved. Both, absorption and emission spectrums were observed for this system. From the measurement of time dependencies of the fotochromic reaction, the activation energy of the reverse reaction was determined. A different behavior, particularly in emissive spectrums, was found for the MDMO-PPV polymer doped with spiropyrane. Instead of formation of new band of merocyanine, decrease of the polymer fluorescence was observed. Subsequently, we studied the interaction between the polymeric matrix and the photochromic spiropyrane using fluorescence quenching method. On the basis of energy transfer theory, a critical radius of the fluorescence quenching sphere in solution and in solid was determined.

Fluorescence resonance energy transfer studies of protein interactions

Martin, Sarah Friede

January 2008

This thesis presents an investigation of fluorescence resonance energy transfer (FRET) as a reporting signal for protein-protein interactions. Quantitative optical assays to measure protein binding, conjugation and deconjugation are developed and results validated by conventional biochemical techniques. The optical techniques developed provide fast, cheap, quantitative and accurate alternatives to conventional methods. Fluorescent protein fluorophores ECFP and Venus-EYFP were chosen as they are a non-interfering FRET pair and provide an inexpensive and convenient cloning-based labelling method. The small ubiquitin-like modifier SUMO and the SUMOylation pathway leading to its conjugation to target proteins is investigated as a model system. These assays are hence particularly relevant to research on post-translational modification and ubiquitin systems. In protein-protein binding assays we utilise both steady-state and time-resolved FRET detection to measure the equilibrium binding constant of the well-characterised pair SUMO1 and Ubc9. An assay in multi-well plate format is also presented, which uniquely enables repeat measurements under varying conditions and under the addition of further substances. The multi-protein binding interactions of the SUMOylation pathway including RanBP2 are analysed in binding inhibition assays. Our results clarify the role of RanBP2: a covalent SUMO1-Ubc9 link is required for the formation of a trimeric complex, although mutual binding sites are present on all three proteins. Furthermore, the binding of SUMO1 and Ubc9 is disrupted by RanBP2, which may be an essential step in transferring SUMO1 to its target protein. A FRET-based kinetic study of this conjugation process to RanGAP1 is presented. An assay to monitor the deconjugation of SUMO1 by specific proteases is established using a doubly-tagged SUMO construct. This enables a quantitative analysis of protease and substrate specificity based on real-time kinetic data, a characterisation of crude cell extracts and a high-throughput screen for protease inhibitors using FRET. A screen of the National Cancer Institute (NIC) diversity set for SenP1 inhibition reveals nine suitable compounds, which are potential anti-cancer drugs. The results of two further projects, the study of protein-protein binding by measuring small refractive index changes and the autofluorescence of normal and neoplastic cervical tissue models are also presented. In the latter, principal component analysis was used to systematically identify emission regions of significant variation between samples, enabling discrimination between healthy and pre-cancerous tissue models.

572.072

Blends of Polydioctylfluorene (PFO) with polymeric and monomeric energy acceptors: correlation of fluorescence energy transfer and film morphology in breath figures and films

Nguyen, Vu Anh

13 May 2008

Fluorescence energy transfer from poly(9,9-dioctylfluorene) to polymeric energy acceptors that include head-to-tail regioregular poly(3-hexylthiophene or P3HT) and poly(2-methoxy-5(2 -ethylhexyloxy)-1,4-phenylenevinylene) or MEH-PPV and monomeric acceptor meso-tetraphenylporphyrin or TPP was studied and correlated with the underlying morphology when the donor-acceptor blends were prepared as drop-coated films or breath-figure structures. It was found that the phase-separate morphology in films and breath figures was influenced by a number of factors, including material transport dynamics, solubility of the blend components in a solvent, interaction of the solvent with the substrate, and the diffusion rate of the blend components.

P3HT

MEH-PPV

PFO

Phase separation

Breath figures

Fluorescence energy transfer

TPP

Conjugated polymers

Electroluminescent devices

Optoelectronics

Thin films

Energy transfer

Phase partition