Lithium as a disease-modifying agent for prion diseases.

Prion diseases still remain incurable despite multiple efforts to develop a treatment. Therefore, it is important to find strategies to at least reduce the symptoms. Lithium has been considered as a neuroprotective agent for years, and the objective of this preclinical study was to evaluate the efficacy of lithium delivered as a water-in-oil microemulsion (Aonys®). This delivery system allows using low doses of lithium and to avoid the toxicity observed in chronic treatments. C57BL/6J mice were intracranially inoculated with ME7 prion-infected brain homogenates and then were treated with lithium from day 90 post inoculation until their death. Lithium was administered at traditional doses (16 mg/kg/day) by the gavage route and at lower doses (40 or 160 µg/kg/day; Aonys®) by the rectal mucosa route. Low doses of lithium (Aonys®) improved the survival of prion-inoculated mice, and also decreased vacuolization, astrogliosis, and neuronal loss compared with controls (vehicle alone). The extent of the protective effects in mice treated with low-dose lithium was comparable or even higher than what was observed in mice that received lithium at the traditional dose. These results indicate that lithium administered using this innovative delivery system could represent a potential therapeutic approach not only for prion diseases but also for other neurodegenerative diseases.

Data from a targeted proteomics approach to discover biomarkers in saliva for the clinical diagnosis of periodontitis.

This study focused on the search for new biomarkers based on liquid chromatography-multiple reaction monitoring (LC-MRM) proteomics profiling of whole saliva from patients with periodontitis compared to healthy subjects. The LC-MRM profiling approach is a new and innovative method that has already been validated for the absolute and multiplexed quantification of biomarkers in several diseases. The dataset for this study was produced using LC-MRM to monitor protein levels in a multiplex assay, it provides clinical information on salivary biomarkers of periodontitis. The data presented here is an extension of our recently published research article (Mertens et al., 2017) [1].

Gene and cell therapy for prion diseases.

Prion diseases are neurodegenerative disorders characterized by the accumulation of an abnormal prion protein named PrP(Sc). PrP(Sc) results from the post-translational conformational modification of the host-encoded protein PrP(C). To date there is no treatment for this inexorably fatal disease. Hence, a major focus of research consists in the identification of new molecules that could interfere with in vivo prion propagation. Promising therapeutic approaches to block the production of PrP(Sc) are based on PrP RNA interference, passive or active immunization, dominant negative inhibition of PrP(Sc) formation, as well as inhibition of interactions between PrP(Sc) and other cofactors. Although these anti-prion molecules can be directly administered in vivo, the process to produce and purify them in high quantity is often challenging and expensive. An alternative strategy consists in the development of gene therapy systems of delivery. Importantly, the diagnosis of prion disease in humans remains difficult and often leaves a short therapeutic window after the appearance of the first clinical signs. As serious damages to the brain generally occur before clinical symptoms manifest, an ideal therapeutic strategy must target not only the formation of toxic aggregates, but also the brain destruction already incurred. This could be achieved by combining gene therapy with cell therapy. In this review we have chosen to highlight the multiple targets and potential gene or cell replacement therapeutic approaches. This review also presents the evidence for the transplantation of stem cells as well as the combination of cell and gene therapy as promising strategies against prion diseases.