Photoremovable protecting groups for carbonyl compounds of biological interest

Resumen

The solar spectrum is composed of a wide range of electromagnetic radiations which have different impacts on life on earth. Among them, those belonging to the ultraviolet region are of utmost importance when we refer to photobiology, since they can interact with biomolecules through both direct and photosensitized processes. As a result, these biomolecules can undergo modifications that do not always have beneficial effects. In this context, photoinduced DNA damage is of great relevance as it is closely related to the increasing incidence of skin cancer. Therefore, it is necessary both to investigate the mechanisms involved in these processes and to develop new strategies to avoid them. In this Thesis these issues have been addressed through the development and use of photolabile protecting groups (PPG). The first part of this Thesis involves the development of new PPG based on solar filters. Once released, these PPG offer the advantage of acting as ultraviolet shields. In this context, Chapter 3 looks into the photophysical and photochemical properties of those systems formed by avobenzone as PPG of carboxylic acids, more specifically ketoprofen (KP) and naproxen (NPX). In this study, the influence on the photorelease process of the relative energetic location of the avobenzone triplet manifold in its diketo form, 3AB(K)*, with respect to that of its caged compound, is duly analyzed by means of molecular modeling and spectroscopic techniques. Following this same line of work, a new PPG capable of releasing oxybenzone (OB) solar filter along with carbonyl compounds has been developed in Chapter 4. The second part of this Thesis focuses on the "Trojan Horse" concept, which establishes that certain DNA lesions can act as endogenous photosensitizers, thus generating new lesions in their neighborhood. In this context, in Chapter 5 the photosensitizing properties of two oxidatively generated DNA damages, namely 5-formyluracil (ForU) and 5-formylcytosine (ForC), have been studied by means of experimental and theoretical approaches. Here, special emphasis has been placed on unraveling their capacity to photoinduce the formation of cyclobutane pyrimidine dimers (CPD). Finally, in Chapter 6 a new synthetic alternative for the incorporation of ForU into oligodeoxynucleotides (ODN) has been developed. Due to the instability of the aldehyde group, this synthesis is generally carried out by incorporating a precursor which is subsequently converted into ForU by the action of an oxidative agent. On the contrary, in the new approach, the aldehyde is protected with a PPG, so that once inserted into the ODN, the aldehyde is selectively released through the use of light. This work entails a step forward in the study of the photosensitizing properties of ForU, offering a new tool for their evaluation within the DNA environment.