Lipid nanoparticle structure and delivery route during pregnancy dictates mRNA potency, immunogenicity, and health in the mother and offspring

Abstract

AbstractTreating pregnancy-related disorders is exceptionally challenging because many small molecule drugs on the market may cause maternal and fetal toxicity. This potential danger has hindered the development and clinical evaluation of new drugs for several decades. Lipid nanoparticle (LNP)-based RNA therapies with high delivery efficacy, favorable immune response, and minimal transplacental transport can quell maternal-fetal toxicity concerns and propel the development of pregnancy-safe drugs. To this extent, we report potent LNP structures that robustly deliver mRNA to maternal organs and placenta. Using structure-function analysis, we show that LNP efficacy is influenced by the polyamine headgroup, and toxicity is governed by the acrylate tail. Our lead nanoparticle shows robust protein expression via multiple clinically relevant administration routes in pregnant mice. In the placenta, it transfects trophoblasts, endothelial cells, and immune cells. Further, by varying ionizable lipid structure, we demonstrate that LNP immunogenicity affects organ expression and pup health during pregnancy. Immunogenic LNPs show lower efficacy in lymphoid organs in an IL-1β dependent manner in pregnant mice. Further, pro-inflammatory immune responses provoke the infiltration of adaptive immune cells in the placenta and restrict pup growth after birth. Together, our results provide a mechanistic basis for designing safe and potent LNPs that can be administered during pregnancy.