Novel spectroscopic probes of sunscreens, initial excited-state structural dynamics and DNA photodamage

Oladepo, Sulayman

06 1900

This thesis discusses developing new tools to probe DNA damage resulting from photoinduced chemical processes and probing the initial excited-state structural dynamics of nucleic acids and sunscreen agents. The results of this thesis show that UV resonance Raman spectroscopy (UVRRS) is an information-rich probe of chemical compositions in in situ analysis of sunscreen formulations. The results indicate that 244-nm excited UV resonance Raman spectra can provide a limit of detection of 0.23% w/w of sunscreen active ingredients (AIs), far below typical active ingredient (AI) concentrations in sunscreen formulations. UVRRS was used to probe the photostability of sunscreens, by determining the initial excited-state structural dynamics of Benzophenone-3 (BZ3), a common sunscreen active ingredient. Only minor excited-state structural distortions were obtained, based on the low displacement values, suggesting an inherently stable molecule. The largest structural change occurs along the carbonyl stretch, suggesting a strong interaction with the methanol solvent and a dissipative decay path for the molecule. Similarly, to gain an insight into how the structure of nucleic acids determine their photochemistry, UVRRS was used to probe the initial excited-state structural dynamics of 9-methyladenine (9-MeA). As for BZ3, the initial excited-state structural dynamics obtained for 9-MeA, are low, and much lower than for pyrimidine bases, providing a strong evidence for the photochemical stability of this purine base analog, compared to pyrimidines. Since DNA does not exist in isolation in cells, the role of a UV-absorbing amino acid, tryptophan, in UV-induced DNA photodamage was explored using molecular beacons (MBs) to detect the damage. The results indicate that tryptophan protective effects on DNA far outweighs their photodamage potential. However, MBs are expensive and they have some technical limitations, despite their exquisite sensitivity. Therefore, a new DNA damage detection method was developed based on smart probes (SPs). These probes are shown to be sensitive and sequence specific for detecting DNA photodamage.

Spectroscopic probes

Smart probes

Molecular beacons

DNA damage

Sunscreens

Excited-state structural dynamics

Novel spectroscopic probes of sunscreens, initial excited-state structural dynamics and DNA photodamage

Oladepo, Sulayman

Unknown Date

No description available.

Spectroscopic probes

Smart probes

Molecular beacons

DNA damage

Sunscreens

Excited-state structural dynamics

Conception et développement de bras réactifs auto-immolables pour la synthèse de sondes pro-fluorescentes : applications à la détection de peptidases dans un contexte in-vivo / Design and development of self-immolative spacers for the synthesis of pro-fluorescent probes : application to the in-vivo dedection of peptidases

Meyer, Yves

04 November 2010

L'objectif de cette thèse est la conception et le développement de bras espaceurs auto-immolables originaux situés entre le substrat peptidique et un fluorophore à phénol. Une première partie de ces travaux porte sur le développement de bras réactifs auto-immolables adaptés à la détection d'exopeptidases et à leur application pour la synthèse de sondes destinées à l'imagerie in-vivo de la caspase 3, une enzime impliquée dans le processus apoptotique. La seconde partie de ce travail relate les efforts effectués afin d'étendre l'utilisation des bras réactifs auto-immolables à la détection des endopeptidases, notamment les MMPs, une famille d'enzimes fortement impliquée dans la progression cancéreuse. / The aim of this PhD work is the design and development of novel self-immolative species linking a peptide susbstrate to a phenolic fluorophore. A first part was dedicated to the development of self-immolative linkers for exopeptidases detection and their incorporation in caspase 3 probes to stain the apoptotic process. A second part was devoted to the extension of the strategy to endopeptidases, especially MMPs, an enzyme family mainly involved in cancer progression.

Pro-fluorescence

Bras réactif auto-immolable

Imagerie optique

Sondes intelligentes

Sondes activables

Sondes fluorescentes proches infra-rouge

Pro-fluorescence

Self-immolative linker

Optical imaging

Smart probes

Activable probes

Near-infrared fluorescent probes

Synthèse de sondes chémiluminescentes et profluorescentes pour des applications en imagerie in vivo / Synthesis of chemiluminescent and profluorogenic probes for in vivo imaging

Grandclaude, Virgile

23 September 2011

L’imagerie moléculaire optique joue maintenant un rôle essentiel dans le diagnostic pré-clinique et le développement de médicaments. En effet, c’est un outil précieux dans la détection et le suivi de cellules vivantes que ce soit en utilisant de simples agents de marquage ou des sondes plus développées, dites « intelligentes » et activées uniquement par une interaction spécifique avec le bio-analyte ciblé. Ce travail de thèse a consisté à développer des outils synthétiques innovants afin d’optimiser les paramètres physico-chimiques et les propriétés optiques des sondes luminescentes. Ceci dans le but de répondre à la problématique complexe de l’imagerie dans le contexte in vivo. Nous avons notamment travaillé sur des aspects de pro-fluorescence et de chémiluminescence. De nouveaux pro-fluorophores à phénol basés sur une architecture originale de type bis-coumarinique ont été développés. De plus, nous avons mis en place une méthode d’hydrosolubilisation généralisable aux fluorophores à phénol de type coumarine et xanthène. Nos recherches en chémiluminescence ont permis la synthèse de nouveaux chémiluminophores couplés à des fluorophores organiques afin d‘augmenter l’efficacité d’émission de chémiluminescence dans le rouge. Enfin, nos travaux ont permis de mettre en place les premières « cassettes » chémiluminescentes basées sur une architecture de type 1,2-dioxétane. / Optical molecular imaging is now playing a pivotal role both in pre-clinical diagnosis and drug development. Indeed, this is a valuable tool for the real time detection and monitoring of living cells either through the use of structurally simple labels or more recently by means of sophisticated fluorescent probes, called “smart” probes and only activatable upon specific interaction with the targeted bio-analyte. The aim of this PhD work was the design of new synthetic tools aimed at optimizing physico-chemical and optical properties of fluorescent probes intended for challenging in vivo imaging applications. We have focused on the pro-fluorescence and chemiluminescence approaches. New phenol-based pro-fluorophores have been developed by using an original bis-coumarinic scaffold. In the context of the chemistry of fluorophores, we have also investigated a general method for the water-solubilisation of phenol-based fluorophore belonging to the coumarin and xanthene families. Our research in chemiluminescence has led the synthesis of new chemiluminophores covalently linked to fluorescent organic dyes aimed at increasing the emission efficiency in the red region of such chemiluminophores. Thus, the first chemiluminescent “energy transfer cassettes” based on a 1,2-dioxetane scaffold have been obtained.

Imagerie moléculaire optique

Imagerie in vivo

Onde pro-fluorescente

Chémiluminescence

Sondes intelligentes

1,2-dioxétane

Cassettes à transfert d’énergie

Optical molecular imaging

In vivo imaging

Fluorogenic probes

Chemiluminescence

Smart probes

1,2-dioxetane

Energy transfer cassettes