Restoring ornithine transcarbamylase (OTC) activity in an OTC‐deficient mouse model using LUNAR‐OTC mRNA

Abstract Ornithine transcarbamylase (OTC) catalyses the reaction from ornithine to citrulline in the urea cycle. Ornithine transcarbamylase deficiency (OTCD) results in episodes of hyperammonemia. Arcturus Therapeutics developed a lipid nanoparticle (LNP)‐encapsulated OTC‐mRNA (LUNAR‐OTC) that results in a replacement enzyme and is currently undergoing clinical trials. In this study, the efficacy of LUNAR OTC‐mRNA drug in the spfash mouse model was examined by measuring the OTC enzyme activity and protein expression in the liver and plasma of OTC‐mRNA‐treated mice. Using purified citrulline‐D4 as the substrate improved the sensitivity of the OTC activity assay and allowed us to quantify the ornithine‐D4 product from the mouse plasma samples. OTC activity in the liver showed a clear dose response: The lowest dose, 0.3 mg/kg, resulted in higher activity than that of the untreated group, and the highest dose, 3 mg/kg, resulted in completely restored OTC activity in the liver. OTC activity in plasma was also dose‐dependent. A clear positive correlation between the OTC activity in the liver and that in the plasma suggests that the plasma OTC activity assay may serve as a surrogate for measuring OTC activity in liver biopsy samples. In addition, the OTC protein expression levels correlated well with the OTC activity in liver samples, but there was no quantifiable OTC protein in the plasma samples. This finding suggests that the sensitivity of the OTC activity assay is superior to that of the protein expression assay. Overall, the results of this study suggest that the OTC activity assay described here can be used as a clinical pharmacodynamic endpoint to measure the effectiveness of OTCD treatment

Immune modulatory nanoparticle therapeutics for intracerebral glioma

BACKGROUND: Previously we showed therapeutic efficacy of unprotected miR-124 in preclinical murine models of glioblastoma, including in heterogeneous genetically engineered murine models by exploiting the immune system and thereby negating the need for direct tumor delivery. Although these data were promising, to implement clinical trials, we required a scalable formulation that afforded protection against circulatory RNases. METHODS: We devised lipid nanoparticles that encapsulate and protect the miRs from degradation and provide enhanced delivery into the immune cell compartment and tested in vivo antitumor effects. RESULTS: Treatment with nanoparticle-encapsulated miR-124, LUNAR-301, demonstrated a median survival exceeding 70 days, with an associated reversal of tumor-mediated immunosuppression and induction of immune memory. In both canine and murine models, the safety profile of LUNAR-301 was favorable. CONCLUSIONS: For the first time, we show that nanoparticles can direct a therapeutic response by targeting intracellular immune pathways. Although shown in the context of gliomas, this therapeutic approach would be applicable to other malignancies

Hepatocyte-specific activity of TSC22D4 triggers progressive NAFLD by impairing mitochondrial function.

OBJECTIVE: Fibrotic organ responses have recently been identified as long-term complications in diabetes. Indeed, insulin resistance and aberrant hepatic lipid accumulation represent driving features of progressive non-alcoholic fatty liver disease (NAFLD), ranging from simple steatosis and non-alcoholic steatohepatitis (NASH) to fibrosis. Effective pharmacological regimens to stop progressive liver disease are still lacking to-date. METHODS: Based on our previous discovery of transforming growth factor beta-like stimulated clone (TSC)22D4 as a key driver of insulin resistance and glucose intolerance in obesity and type 2 diabetes, we generated a TSC22D4-hepatocyte specific knockout line (TSC22D4-HepaKO) and exposed mice to control or NASH diet models. Mechanistic insights were generated by metabolic phenotyping and single-nuclei RNA sequencing. RESULTS: Hepatic TSC22D4 expression was significantly correlated with markers of liver disease progression and fibrosis in both murine and human livers. Indeed, hepatic TSC22D4 levels were elevated in human NASH patients as well as in several murine NASH models. Specific genetic deletion of TSC22D4 in hepatocytes led to reduced liver lipid accumulation, improvements in steatosis and inflammation scores and decreased apoptosis in mice fed a lipogenic MCD diet. Single-nuclei RNA sequencing revealed a distinct TSC22D4-dependent gene signature identifying an upregulation of mitochondrial-related processes in hepatocytes upon loss of TSC22D4. An enrichment of genes involved in the TCA cycle, mitochondrial organization, and triglyceride metabolism underscored the hepatocyte-protective phenotype and overall decreased liver damage as seen in mouse models of hepatocyte-selective TSC22D4 loss-of-function. CONCLUSIONS: Together, our data uncover a new connection between targeted depletion of TSC22D4 and intrinsic metabolic processes in progressive liver disease. Hepatocyte-specific reduction of TSC22D4 improves hepatic steatosis and promotes hepatocyte survival via mitochondrial-related mechanisms thus paving the way for targeted therapies