Abstract EN:

Single-molecule-like spectroscopy plays a major role in many domains, from fundamental physics to biology. In this framework, my dissertation focuses on instrumental and theoretical developments of two biological-related applications. The first experiment aims at characterizing the dynamics of calcium binding by the fluorescent calcium probe Oregon-green Bapta5N commonly employed in cell signaling analysis. To achieve it, I have developed an experimental set-up of fluorescence correlation spectroscopy that exhibits sensitivity close to that of single-molecule detection. Either monophotonic or biphotonic excitations can be used. I have investigated the several aspects of the photophysics of the probe and evaluated the interest and limitations of such an approach for future in-vivo measurements. The second one is devoted to the development of a semi-quantitative Fluorescent In-Situ Hybridization (FISH) technique for mapping gene expression in the adult drosophila brain. Two difficulties have to be solved. First, we succeeded in obtaining reproducible results with drosophila adult brain. Secondly, while most of the FISH protocols are not quantitative since they need a strong enzymatic, we achieved semi-quantitative detection of RNA probes. I will present results on a new approach for which enzymatic detection is replaced by a sensitive detection and a protocol which reduces autofluorescence contribution. Results will be presented for several genes in adult drosophila brain to validate the methods as well as an interesting application on a mental retardation disease. To conclude, I show that the method exhibits a single RNA sensitivity which opens the way to new applications