Nonclinical safety assessment of an mRNA Covid-19 vaccine candidate following repeated administrations and biodistribution.

Messenger RNA (mRNA) vaccines have demonstrated efficacy against Severe Acute Respiratory Syndrome Coronavirus-2 (SARS-CoV-2) in humans. mRNA technology holds tremendous potential for rapid control and prevention of emergencies due to its flexibility with respect to production, application, and design for an efficacious and safe use in humans. We assessed the toxicity and biodistribution of MRT5500, an mRNA vaccine encoding for the full-length of the SARS-CoV-2 spike protein and delivered by lipid nanoparticles (LNPs) containing a novel ionizable lipid, Lipid-1 in preclinical animal models. In the repeated dose toxicity study, rabbits received three intramuscular (IM) injections of MRT5500 at 3-week interval followed by a 4-week observation period. In an exploratory biodistribution study in mice receiving a single IM injection of an mRNA encoding luciferase encapsulated in an LNP containing Lipid-1, the expression of the luciferase protein was monitored in vivo and ex vivo at several time points. In the regulatory biodistribution study in rabbits receiving a single IM injection of MRT5500, the quantification of the mRNA and the ionizable Lipid-1 were monitored in the same organs and time points as in the exploratory biodistribution study. MRT5500 was safe and well-tolerated with a transient acute phase response/inflammation and an expected vaccine-related immunological response, typical of those observed following a vaccine administration. The biodistribution data demonstrated that the mRNA and Lipid-1 components of the vaccine formulations were mainly detected at the injection site and in the draining lymph nodes. These results support the use of MRT5500 and its deployment into clinical trials.

Nonclinical safety evaluation of a novel ionizable lipid for mRNA delivery.

mRNA vaccines hold tremendous potential in disease control and prevention for their flexibility with respect to production, application, and design. Recent breakthroughs in mRNA vaccination would have not been possible without major advances in lipid nanoparticles (LNPs) technologies. We developed an LNP containing a novel ionizable cationic lipid, Lipid-1, and three well known excipients. An in silico toxicity hazard assessment for genotoxicity, a genotoxicity assessment, and a dose range finding toxicity study were performed to characterize the safety profile of Lipid-1. The in silico toxicity hazard assessment, utilizing two prediction systems DEREK and Leadscope, did not find any structural alert for mutagenicity and clastogenicity, and prediction in the statistical models were all negative. In addition, applying a read-across approach a structurally very similar compound was tested negative in two in vitro assays confirming the low genotoxicity potential of Lipid-1. A dose range finding toxicity study in rabbits, receiving a single intramuscular injection of either different doses of an mRNA encoding Influenza Hemagglutinin H3 antigen encapsulated in the LNP containing Lipid-1 or the empty LNP, evaluated local tolerance and systemic toxicity during a 2-week observation period. Only rabbits exposed to the vaccine were able to develop a specific IgG response, indicating an appropriate vaccine take. The vaccine was well tolerated up to 250 µg mRNA/injection, which was defined as the No Observed Adverse Effect Level (NOAEL). These results support the use of the LNP containing Lipid-1 as an mRNA delivery system for different vaccine formulations and its deployment into clinical trials.

Evaluation of safety and immuno-efficacy of a next generation live-attenuated yellow fever vaccine in cynomolgus macaques.

The increased demand for yellow fever (YF) vaccines over the last decade, along with insufficient availability of specific pathogen-free embryonated eggs required for timely vaccine production, has led to global YF vaccine shortages. A new live-attenuated YF vaccine candidate (generically referred to as vYF) cloned from a YF-VAX® vaccine (YF-17D vaccine) substrain adapted for growth in Vero cells cultured in serum-free media is currently in development. Here, we assessed the safety and immunogenicity of vYF, and its protective activity upon virulent challenge with wild-type yellow fever virus (YFV) Asibi, compared to licensed YF-17D vaccines in the translational cynomolgus macaque model. vYF was well tolerated with no major safety concerns. Vaccine-related safety observations were limited to minimal/minor microscopic findings at the injection sites and in the draining lymph nodes, consistent with expected stimulation of the immune system. vYF induced early differential expression of genes involved in antiviral innate immunity previously described in humans vaccinated with YF-17D vaccines, as well as YFV-specific IgM and IgG antibodies, high and sustained YFV neutralizing antibody titers from Day 14 up to at least Day 258 post-immunization, IgM+ and IgG+ memory B cells from Day 14 up to at least Day 221 post-vaccination, and Th1 interferon (IFN)-γ and interleukin (IL)-2 secreting effector and memory T cells. Additionally, vYF provided effective resistance to virulent challenge with wild-type YFV Asibi including complete protection against YFV-induced mortality, pathology, dysregulation of blood and liver soluble biomarkers, and a significant reduction in viremia and viral load to the limit of detection. These NHP data suggest that vYF would provide protection against YFV infection in practice, at least similar to that achieved with currently marketed YF-17D vaccines.