CRISPR-Cas9-mediated somatic correction of a one-base deletion in the Ugt1a gene ameliorates hyperbilirubinemia in Crigler-Najjar syndrome mice.

(AAV)-mediated episomal gene replacement therapy for monogenic liver disorders is currently limited in pediatric settings due to the loss of vector DNA, associated with hepatocyte duplication during liver growth. Genome editing is a promising strategy leading to a permanent and specific genome modification that is transmitted to daughter cells upon proliferation. Using genome targeting, we previously rescued neonatal lethality in mice with Crigler-Najjar syndrome. This rare monogenic disease is characterized by severe neonatal unconjugated hyperbilirubinemia, neurological damage, and death. Here, using the CRISPR-Staphylococcus aureus Cas9 (SaCas9) platform, we edited the disease-causing mutation present in the Ugt1a locus of these mice. Newborn mice were treated with two AAV8 vectors: one expressing the SaCas9 and single guide RNA, and the other carrying the Ugt1a homology regions with the corrected sequence, while maintained in a temporary phototherapy setting rescuing mortality. We observed a 50% plasma bilirubin reduction that remained stable for up to 6 months. We then tested different Cas9:donor vector ratios, with a 1:5 ratio showing the greatest efficacy in lowering plasma bilirubin, with partial lethality rescue when more severe, lethal conditions were applied. In conclusion, we reduced plasma bilirubin to safe levels and partially rescued neonatal lethality by correcting the mutant Ugt1a1 gene of a Crigler-Najjar mouse model.

Endogenous PP2A inhibitor CIP2A degradation by chaperone-mediated autophagy contributes to the antitumor effect of mitochondrial complex I inhibition.

Combined inhibition of oxidative phosphorylation (OXPHOS) and glycolysis has been shown to activate a PP2A-dependent signaling pathway, leading to tumor cell death. Here, we analyze highly selective mitochondrial complex I or III inhibitors in vitro and in vivo to elucidate the molecular mechanisms leading to cell death following OXPHOS inhibition. We show that IACS-010759 treatment (complex I inhibitor) induces a reactive oxygen species (ROS)-dependent dissociation of CIP2A from PP2A, leading to its destabilization and degradation through chaperone-mediated autophagy. Mitochondrial complex III inhibition has analogous effects. We establish that activation of the PP2A holoenzyme containing B56δ regulatory subunit selectively mediates tumor cell death, while the arrest in proliferation that is observed upon IACS-010759 treatment does not depend on the PP2A-B56δ complex. These studies provide a molecular characterization of the events subsequent to the alteration of critical bioenergetic pathways and help to refine clinical studies aimed to exploit metabolic vulnerabilities of tumor cells.