Signal-on/signal-off bead-based assays for the multiplexed monitoring of base excision repair activities by flow cytometry.

As the support of all living kingdoms' genetic information, the integrity of the DNA biomolecule must be preserved. To that goal, cells have evolved specific DNA repair pathways to thwart a large diversity of chemical substances and radiations that alter the DNA structure and lead to the development of pathologies such as cancers or neurodegenerative diseases. When dysregulated, activity rates of various actors of DNA repair can play a key role in carcinogenesis as well as in drugs resistance or hypersensitivity mechanisms. For the last 10 years, new complementary treatments have aimed at targeting specific enzymes responsible for such resistances. It is therefore crucial for biomedical research and clinical diagnosis to develop fast and sensitive tools able to measure the activity rate of DNA repair enzymes. In this work, a new assay for measuring enzymatic activities using microbeacons (µBs) is expounded. µB refers to microsphere functionalized by hairpin-shaped nucleic acid probes containing a single site-specific lesion in the stem and modified with chromophores. Following the processing of the lesion by the targeted protein, µB is cleaved and either lights off (signal-off strategy) or on (signal-on), depending on the use of fluorescent or profluorescent probes, respectively. After an optimization phase of the assay, we reported the combined analysis of restriction enzyme, AP-endonuclease, and DNA N-glycosylase by real-time monitoring followed by a flow cytometry measurement. As proofs of concept, we demonstrated the potential of the biosensor for highlighting DNA repair inhibitors and discriminating cell lines from their enzymatic activities.

'Click'-xylosides as initiators of the biosynthesis of glycosaminoglycans: Comparison of mono-xylosides with xylobiosides.

Different mono-xylosides and their corresponding xylobiosides obtained by a chemo-enzymatic approach featuring various substituents attached to a triazole ring were probed as priming agents for glycosaminoglycan (GAG) biosynthesis in the xylosyltransferase-deficient pgsA-745 Chinese hamster ovary cell line. Xylosides containing a hydrophobic aglycone moiety were the most efficient priming agents. Mono-xylosides induced higher GAG biosynthesis in comparison with their corresponding xylobiosides. The influence of the degree of polymerization of the carbohydrate part on the priming activity was investigated through different experiments. We demonstrated that in case of mono-xylosides, the cellular uptake as well as the affinity and the catalytic efficiency of ß-1,4-galactosyltransferase 7 were higher than for xylobiosides. Altogether, these results indicate that hydrophobicity of the aglycone and degree of polymerization of glycone moiety were critical factors for an optimal priming activity for GAG biosynthesis.