Poly(aspartic acid)-Based Polymeric Nanoparticle for Local and Systemic mRNA Delivery

Park, Youngrong; Moses, Abraham S.; Demessie, Ananiya A.; Singh, Prem; Lee, Hyelim; Korzun, Tetiana; Taratula, Olena; Alani, Adam W.G.; Taratula, Oleh

doi:10.1021/acs.molpharmaceut.2c00738

Cited by 9 publications

(7 citation statements)

References 51 publications

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“…Our work indicated that VLSs were capable of not only transfecting 293 encoding GFP or the S1 protein, was expressed dynamically in local tissue (Supplementary Fig. 4), similar to what has been reported for mRNA vaccines 20 . Interestingly, the rate of S1 antigen colocalization with DCs or macrophages in local tissue in mice in the VLS group was greater than that in mice in the mRNA-or protein-alone groups (Fig.…”

Section: Vlss Enable Cell Transfection and Target Ace2/dc-sign Moleculessupporting

confidence: 84%

Virus-like structures for combination antigen protein mRNA vaccination

Zhang,

Li,

Zeng

et al. 2024

Nat. Nanotechnol.

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Improved vaccination requires better delivery of antigens and activation of the natural immune response. Here we report a lipid nanoparticle system with the capacity to carry antigens, including mRNA and proteins, which is formed into a virus-like structure by surface decoration with spike proteins, demonstrating application against SARS-CoV-2 variants. The strategy uses S1 protein from Omicron BA.1 on the surface to deliver mRNA of S1 protein from XBB.1. The virus-like particle enables specific augmentation of mRNAs expressed in human respiratory epithelial cells and macrophages via the interaction the surface S1 protein with ACE2 or DC-SIGN receptors. Activation of macrophages and dendritic cells is demonstrated by the same receptor binding. The combination of protein and mRNA increases the antibody response in BALB/c mice compared with mRNA and protein vaccines alone. Our exploration of the mechanism of this robust immunity suggests it might involve cross-presentation to diverse subsets of dendritic cells ranging from activated innate immune signals to adaptive immune signals.

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Section: Vlss Enable Cell Transfection and Target Ace2/dc-sign Moleculessupporting

confidence: 84%

Virus-like structures for combination antigen protein mRNA vaccination

Zhang,

Li,

Zeng

et al. 2024

Nat. Nanotechnol.

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“…Intravenous injection of PEGylated poly(aspartic acid) could achieve pulmonary targeted mRNA transfection with increased cell viability compared to non‐PEGylated nanoparticles. [ 82 ] This PEGylated poly(aspartic acid) nanoparticle could be a potential lung‐targeted therapy for the local disease.…”

Section: Materials Development For Nucleic Acid Pulmonary Deliverymentioning

confidence: 99%

Recent Progress in Nucleic Acid Pulmonary Delivery toward Overcoming Physiological Barriers and Improving Transfection Efficiency

Wang,

Bu,

Dai

et al. 2024

Advanced Science

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Pulmonary delivery of therapeutic agents has been considered the desirable administration route for local lung disease treatment. As the latest generation of therapeutic agents, nucleic acid has been gradually developed as gene therapy for local diseases such as asthma, chronic obstructive pulmonary diseases, and lung fibrosis. The features of nucleic acid, specific physiological structure, and pathophysiological barriers of the respiratory tract have strongly affected the delivery efficiency and pulmonary bioavailability of nucleic acid, directly related to the treatment outcomes. The development of pharmaceutics and material science provides the potential for highly effective pulmonary medicine delivery. In this review, the key factors and barriers are first introduced that affect the pulmonary delivery and bioavailability of nucleic acids. The advanced inhaled materials for nucleic acid delivery are further summarized. The recent progress of platform designs for improving the pulmonary delivery efficiency of nucleic acids and their therapeutic outcomes have been systematically analyzed, with the application and the perspectives of advanced vectors for pulmonary gene delivery.

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“…Yum et al [ 175 ] synthesized PASP (DET/CHE) with a cyclohexyl ethyl (CHE) group, which caused significant mRNA expression in the lungs and even demonstrated mRNA transfection efficiency nearly 10 times higher than lipid materials commonly used on the market. Park et al [ 176 ] found that PEG-modified PASP (DET) (with a PEG/polymer ratio of 1:1) can induce mRNA expression in the lungs, but caution should be exercised as high PEG content may decrease the efficiency of mRNA delivery after intravenous injection. mRNA transduction and translation in the lungs were completely absent when the PEG/polymer ratio was 10:1.…”

Section: Mrna Nps: Targeting Design Strategies For Different Tissuesmentioning

confidence: 99%

mRNA nanodelivery systems: targeting strategies and administration routes

Yuan,

Han,

Liang

et al. 2023

Biomater Res

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With the great success of coronavirus disease (COVID-19) messenger ribonucleic acid (mRNA) vaccines, mRNA therapeutics have gained significant momentum for the prevention and treatment of various refractory diseases. To function efficiently in vivo and overcome clinical limitations, mRNA demands safe and stable vectors and a reasonable administration route, bypassing multiple biological barriers and achieving organ-specific targeted delivery of mRNA. Nanoparticle (NP)-based delivery systems representing leading vector approaches ensure the successful intracellular delivery of mRNA to the target organ. In this review, chemical modifications of mRNA and various types of advanced mRNA NPs, including lipid NPs and polymers are summarized. The importance of passive targeting, especially endogenous targeting, and active targeting in mRNA nano-delivery is emphasized, and different cellular endocytic mechanisms are discussed. Most importantly, based on the above content and the physiological structure characteristics of various organs in vivo, the design strategies of mRNA NPs targeting different organs and cells are classified and discussed. Furthermore, the influence of administration routes on targeting design is highlighted. Finally, an outlook on the remaining challenges and future development toward mRNA targeted therapies and precision medicine is provided. Graphical Abstract

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Poly(aspartic acid)-Based Polymeric Nanoparticle for Local and Systemic mRNA Delivery

Cited by 9 publications

References 51 publications

Virus-like structures for combination antigen protein mRNA vaccination

Virus-like structures for combination antigen protein mRNA vaccination

Recent Progress in Nucleic Acid Pulmonary Delivery toward Overcoming Physiological Barriers and Improving Transfection Efficiency

mRNA nanodelivery systems: targeting strategies and administration routes

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