Lipid Nanoparticle Systems for the Delivery of Messenger RNA
In recent years, messenger RNA (mRNA) has come into the spotlight as a versatile therapeutic with the potential to prevent and treat a staggering array of diseases. Billions of
dollars have been invested into the commercial development of mRNA drugs, with ongoing clinical trials focused on vaccines (for example, influenza and Zika viruses) and cancer immunotherapy (for example, myeloma, leukemia, and glioblastoma). Although significant progress has been made in the design of in vitro transcribed mRNA that retains potency while minimizing unwanted immune responses, the widespread use of mRNA drugs requires the development of safe and effective drug delivery vehicles. Unfortunately, delivery vehicle development has been stymied by an inadequate understanding of how the molecular properties
of a vehicle confer efficacy. Recently, it was found that a class of lipid-like materials, known as lipidoids, can be
formulated into lipid nanoparticles (LNPs) that potently deliver a variety of nucleic acids in vitro and in vivo. Here, we investigate the use of these materials for the delivery of messenger RNA both in a variety of cell types and in mice. By synthesizing a library of 400 lipidoids, we show
that the material chemistry has a large impact on the mRNA delivery efficacy in vitro. Using a smaller library of 11 lipidoids, we show that LNPs formulated from these materials potently deliver mRNA to a variety of organs in mice. The two most potent materials from the library,
306O10 and 306Oi10, have 10-carbon tails and identical molecular weights, and vary only in that the 306O10 tail is straight and the 306Oi10 tail has a one-carbon branch. Remarkably, this small difference in structure conferred a 10-fold improvement in 306Oi10 efficacy. The enhanced potency of this branched-tail lipidoid was attributed to its strong surface ionization upon entry into the endosomal compartment of target cells. We also show that delivery of the top LNP, 306Oi10, enabled higher levels of protein
expression than two gold standard lipids, C12-200 and DLin-MC3-DMA in mice. We also demonstrate that this material is sufficiently potent to encapsulate and deliver three mRNAs of varying lengths within the same formulation. Furthermore, 306Oi10 co-delivered Cas9 mRNA
and single guide RNAs (sgRNAs), facilitating CRISPR-mediated gene editing in the livers of mice. Intravenous delivery of this material also did not significantly increase serum cytokine or IgG levels, nor did it cause liver toxicity, as determined by histology. Finally, we explore the impact of mRNA nucleoside modifications on resultant protein
expression in mice. Specifically, we probe the influence of the delivery vehicle on the efficacy of mRNA modifications by delivering a variety of modified mRNAs using four LNPs which target either the liver, spleen, or lungs. We demonstrate that the delivery vehicle has a large impact on
the efficacy of modified mRNAs. We also show that the majority of protein expression enhancement occurs in the spleen due to enhanced transfection as well as increased translation in cells in this organ.
dollars have been invested into the commercial development of mRNA drugs, with ongoing clinical trials focused on vaccines (for example, influenza and Zika viruses) and cancer immunotherapy (for example, myeloma, leukemia, and glioblastoma). Although significant progress has been made in the design of in vitro transcribed mRNA that retains potency while minimizing unwanted immune responses, the widespread use of mRNA drugs requires the development of safe and effective drug delivery vehicles. Unfortunately, delivery vehicle development has been stymied by an inadequate understanding of how the molecular properties
of a vehicle confer efficacy. Recently, it was found that a class of lipid-like materials, known as lipidoids, can be
formulated into lipid nanoparticles (LNPs) that potently deliver a variety of nucleic acids in vitro and in vivo. Here, we investigate the use of these materials for the delivery of messenger RNA both in a variety of cell types and in mice. By synthesizing a library of 400 lipidoids, we show
that the material chemistry has a large impact on the mRNA delivery efficacy in vitro. Using a smaller library of 11 lipidoids, we show that LNPs formulated from these materials potently deliver mRNA to a variety of organs in mice. The two most potent materials from the library,
306O10 and 306Oi10, have 10-carbon tails and identical molecular weights, and vary only in that the 306O10 tail is straight and the 306Oi10 tail has a one-carbon branch. Remarkably, this small difference in structure conferred a 10-fold improvement in 306Oi10 efficacy. The enhanced potency of this branched-tail lipidoid was attributed to its strong surface ionization upon entry into the endosomal compartment of target cells. We also show that delivery of the top LNP, 306Oi10, enabled higher levels of protein
expression than two gold standard lipids, C12-200 and DLin-MC3-DMA in mice. We also demonstrate that this material is sufficiently potent to encapsulate and deliver three mRNAs of varying lengths within the same formulation. Furthermore, 306Oi10 co-delivered Cas9 mRNA
and single guide RNAs (sgRNAs), facilitating CRISPR-mediated gene editing in the livers of mice. Intravenous delivery of this material also did not significantly increase serum cytokine or IgG levels, nor did it cause liver toxicity, as determined by histology. Finally, we explore the impact of mRNA nucleoside modifications on resultant protein
expression in mice. Specifically, we probe the influence of the delivery vehicle on the efficacy of mRNA modifications by delivering a variety of modified mRNAs using four LNPs which target either the liver, spleen, or lungs. We demonstrate that the delivery vehicle has a large impact on
the efficacy of modified mRNAs. We also show that the majority of protein expression enhancement occurs in the spleen due to enhanced transfection as well as increased translation in cells in this organ.
History
Date
2019-05-02Degree Type
- Dissertation
Department
- Chemical Engineering
Degree Name
- Doctor of Philosophy (PhD)