Messenger RNA (mRNA) has emerged as a new category of therapeutic agent to prevent and treat various diseases. To function in vivo, mRNA requires safe, effective and stable delivery systems that protect the nucleic acid from degradation and that allow cellular uptake and mRNA release. Lipid nanoparticles have successfully entered the clinic for the delivery of mRNA; in particular, lipid nanoparticle–mRNA vaccines are now in clinical use against coronavirus disease 2019 (COVID-19), which marks a milestone for mRNA therapeutics. In this Review, we discuss the design of lipid nanoparticles for mRNA delivery and examine physiological barriers and possible administration routes for lipid nanoparticle–mRNA systems. We then consider key points for the clinical translation of lipid nanoparticle–mRNA formulations, including good manufacturing practice, stability, storage and safety, and highlight preclinical and clinical studies of lipid nanoparticle–mRNA therapeutics for infectious diseases, cancer and genetic disorders. Finally, we give an outlook to future possibilities and remaining challenges for this promising technology.
Sepsis, a condition caused by severe infections, affects more than 30 million people worldwide every year and remains the leading cause of death in hospitals 1,2 . Moreover, antimicrobial resistance has become an additional challenge in the treatment of sepsis 3 , and thus, alternative therapeutic approaches are urgently needed 2,3 . Here, we show that adoptive transfer of macrophages containing antimicrobial peptides linked to cathepsin B in the lysosomes (MACs) can be applied for the treatment of multi-drug resistant (MDR) bacteria-induced sepsis in mice with immunosuppression. The MACs are constructed by transfection of vitamin C lipid nanoparticles (V C LNPs) that deliver antimicrobial peptide and cathepsin B (AMP-CatB) mRNA.
SARS-CoV-2 vaccines based on inactivated live virus, recombinant viral vector, mRNA, DNA, and recombinant protein are currently in clinical trials. [6] Among these agents, an mRNA-based vaccine candidate quickly entered the clinical trial, because of the fast process for developing and manufacturing mRNA. [7] In order to express an antigen effectively, an mRNA requires several essential components, including 5′ cap, 5′ untranslated region (5′ UTR), antigen-encoding sequence, 3′ untranslated region (3′ UTR), and the poly adenylated tail. [8] Among these components, the 5′ UTR and 3′ UTR are unique regulators for protein translation. [9] The design and selection of 5′ UTR and 3′ UTR are critically important to ensure the sufficient production of antigens and efficacious vaccination. [10]
Messenger RNA (mRNA) therapeutics have been explored to treat various genetic disorders. Lipid-derived nanomaterials are currently one of the most promising biomaterials that mediate effective mRNA delivery. However, efficiency and safety of this nanomaterial-based mRNA delivery remains a challenge for clinical applications. Here, we constructed a series of lipid-like nanomaterials (LLNs), named functionalized TT derivatives (FTT), for mRNA-based therapeutic applications in vivo. After screenings on the materials, we identified FTT5 as a lead material for efficient delivery of long mRNAs, such as human factor VIII (hFVIII) mRNA (~4.5 kb) for expression of hFVIII protein in hemophilia A mice. Moreover, FTT5 LLNs demonstrated high percentage of base editing on PCSK9 in vivo at a low dose of base editor mRNA (~5.5 kb) and single guide RNA. Consequently, FTT nanomaterials merit further development for mRNA-based therapy.
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