Objective 1: What controls the generation of prion infectivity?
We optimized the whole genome wide siRNA screening to identify the genes that modulate the expression of cellular prion protein (PrPC), which we believe will be a game changer in prion research. Currently, we are working on elucidating the mechanisms associated with the remainder of the hits in regulating PrPC expression. A manuscript detailing this work is in preparation.
The aim of the second part of Objective 1 is to identify genes involved in maintaining a productive prion infection and their shedding into extracellular milieu. We have identified 161 genes to specifically effect prions without altering the levels of PrPC. Validation experiments are carried out in other prion infected cell lines. This will be followed by mechanistic elucidation of pathways involved in generation and maintenance of prions from the obtained hits.
Objective 2: How do prions damage the brain?
We have characterized the mechanism associated with biogenesis of vacuoles in prion infection. A manuscript detailing this is currently being revised for submission.
The second part of Objective 2 was to set up a CRISPR platform and perform synthetic lethality screens to identify genes essential for prion induced toxicity. We have now completed amplification, quality control and lentivirus packaging of the CRISPR libraries. Cells used in Objective 1 were chosen for the purpose of the synthetic lethality screen. We estimate that the primary screen and validations will be completed by the first quarter of 2021.
Objective 3: What is the role of PrPC in cellular physiology?
We have validated the authentic phenotypes and more specifically the electrophysiological phenotypes associated with prion protein ablation using the newly generated ZH3 mice (co-isogenic prion protein ablated mice). Furthermore, we have elucidated the mechanistic details of the authentic electrophysiological phenotypes. We have also uncovered the details of how the N terminus of prion protein (also called flexible tail; FT) is involved in maintenance of myelin in peripheral nerves by identifying the receptor to which FT binds on Schwann cells and initiates promyelination signaling. We are currently performing structural studies of the receptor and ligand interactions as a continuation of the project.
The work on Objective 3 has directly resulted in a number of publications:
• Küffer, Alexander; Lakkaraju, Asvin K. K; Mogha, Amit; Petersen, Sarah C; Airich, Kristina; Doucerain, Cédric; Marpakwar, Rajlakshmi; Bakirci, Pamela; Senatore, Assunta; Monnard, Arnaud; Schiavi, Carmen; Nuvolone, Mario; Grosshans, Bianka; Hornemann, Simone; Bassilana, Frederic; Monk, Kelly R; Aguzzi, Adriano (2016). The prion protein is an agonistic ligand of the G protein-coupled receptor Adgrg6. Nature, 536(7617):464-468.
• Nuvolone, Mario; Hermann, Mario; Sorce, Silvia; Russo, Giancarlo; Tiberi, Cinzia; Schwarz, Petra; Minikel, Eric; Sanoudou, Despina; Pelczar, Pawel; Aguzzi, Adriano (2016). Strictly co-isogenic C57BL/6J-Prnp−/−mice: A rigorous resource for prion science. Journal of Experimental Medicine, 213(3):313-327.
• Nuvolone, Mario; Sorce, Silvia; Paolucci, Marta; Aguzzi, Adriano (2017). Extended characterization of the novel co-isogenic C57BL/6J Prnp−/− mouse line. Amyloid, 24(Suppl 1):36-37.
Overall, our interdisciplinary research strategy spanning from screening platforms to biochemistry to mouse genetics has helped us to gain new insights and critical understanding of the functioning of the prion protein in health and disease.
