Polyethylene glycol (PEG)-conjugated lipid has significantly contributed to the success of three approved lipid nanoparticles (LNP)-delivered therapeutics, particularly two COVID-19 mRNA vaccines. It is known that some PEG derivatives could elicit anti-PEG antibodies and subsequently form "antigen-antibody" complexes with newly injected PEGylated agents, leading to pharmacokinetic changes, reduced therapeutic efficacy and even hypersensitivity reactions. With the large-scale vaccination of mRNA vaccines, it has become an imminent task to elucidate the possible PEG-associated immunological effects induced by clinically relevant LNP. Up to date there are only four related studies, all of which are clinical observations emphasizing on the changes of PEG-specific antibodies upon injection of mRNA vaccines. Unfortunately, contradictory and inconclusive data were obtained due to significant person-to-person and study-to-study variabilities. To clarify the PEG-associated immunological effects of clinically relevant LNP in a model system with least "noise", we initiated an animal study using the PEGylated LNP of BNT162b2 (with the largest number of recipients) as a representative LNP and simulated the clinical practice. Through designing a series of time points and three doses correlated with the PEG amount contained in three approved LNP-based drugs, we demonstrated that generation and changes of anti-PEG IgM and IgG were time- and dose-dependent. Unexpectedly, our data revealed that unlike other PEG derivatives belonging to thymus-independent antigens (TI-Ag), PEGylated LNP not only induced isotype switch and production of anti-PEG IgG, but caused immune memory, leading to rapid enhancement and longer lasting time of both anti-PEG IgM and IgG upon repeated injection. Importantly, pharmacokinetic studies discovered that initial injection of PEGylated LNP accelerated the blood clearance of subsequently injected LNP. These findings will refresh our understandings on PEGylated LNP and possible other PEG derivatives, and may lead to optimization of both premarket guidelines and clinical protocols of PEGylated LNP-delivered therapeutics.
Deciphering the regulatory network for human naive and primed pluripotency is of fundamental theoretical and applicable significance. Here, by combining quantitative proteomics, phosphoproteomics, and acetylproteomics analyses, we revealed RNA processing and translation as the most differentially regulated processes between naive and primed human embryonic stem cells (hESCs). Although glycolytic primed hESCs rely predominantly on the eukaryotic initiation factor 4E (eIF4E)-mediated cap-dependent pathway for protein translation, naive hESCs with reduced mammalian target of rapamycin complex (mTORC1) activity are more tolerant to eIF4E inhibition, and their bivalent metabolism allows for translating selective mRNAs via both eIF4E-dependent and eIF4E-independent/ eIF4A2-dependent pathways to form a more compact naive proteome. Globally up-regulated proteostasis and down-regulated post-translational modifications help to further refine the naive proteome that is compatible with the more rapid cycling of naive hESCs, where CDK1 plays an indispensable coordinative role. These findings may assist in better understanding the unrestricted lineage potential of naive hESCs and in further optimizing conditions for future clinical applications
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