Endosomal Size and Membrane Leakiness Influence Proton Sponge-Based Rupture of Endosomal Vesicles

Vermeulen, Lotte; Brans, Toon; Samal, Sangram Keshari; Dubruel, Peter; Demeester, Jo; Smedt, Stefaan C. De; Braeckmans, Kevin

doi:10.1021/acsnano.7b07583

Cited by 155 publications

(152 citation statements)

References 56 publications

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“…25 Other studies indicate that the actual mechanism could be much more complex than the classical proton sponge effect and may depend on fusion with the endosomal membrane and additional factors, such as the endosome size, membrane leakiness, late endosome formation, Rab7A localization on the surface of endosomes, and activation of mTORC1 for downstream signaling for protein synthesis. 26,27 Materials Used for Non-viral mRNA Delivery Ionizable Lipids. One well-studied class of non-viral mRNA delivery agents includes the cationic or ionizable lipids and lipid-like materials.…”

Section: Materials For Mrna Delivery Structural Aspects Of Materials Dmentioning

confidence: 99%

Delivering the Messenger: Advances in Technologies for Therapeutic mRNA Delivery

et al. 2019

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mRNA has broad potential as a therapeutic. Current clinical efforts are focused on vaccination, protein replacement therapies, and treatment of genetic diseases. The clinical translation of mRNA therapeutics has been made possible through advances in the design of mRNA manufacturing and intracellular delivery methods. However, broad application of mRNA is still limited by the need for improved delivery systems. In this review, we discuss the challenges for clinical translation of mRNA-based therapeutics, with an emphasis on recent advances in biomaterials and delivery strategies, and we present an overview of the applications of mRNA-based delivery for protein therapy, gene editing, and vaccination. mRNA holds the potential to revolutionize vaccination, protein replacement therapies, and the treatment of genetic diseases. Since the first pre-clinical studies in the 1990s, 1 significant progress in the clinical translation of mRNA therapeutics has been made through advances in the design of mRNA manufacturing and intracellular delivery methods. 2 The translatability and stability of mRNA as well as its immunostimulatory activity are the key factors to be optimized for specific therapeutic application. 3 Increased translation and stability can be affected by many regions of the RNA. mRNA 5 0 and 3 0 UTRs are responsible for recruiting RNA-binding proteins and microRNAs, and they can profoundly affect translational activity. 2,4 The modification of rare codons in protein-coding sequences with synonymous frequently occurring codons, so-called codon optimization, can result in order-of-magnitude changes in expression levels. 5,6 Modification of the 5 0 mRNA cap can also enhance mRNA translation by inhibiting RNA decapping and improving resistance to enzymatic degradation. 7 Chemical modification of RNA bases can be used to modify mRNA immunostimulatory activity. 8,9 The importance of immunostimulation can depend on the application, 10 and, in some cases, it may actually improve performance, as in the case of vaccines. 11Finally, methods and vehicles for intracellular delivery remain the major barrier to the broad application of mRNA therapeutics. 12 With some exceptions, the intracellular delivery of mRNA is generally more challenging than that of small oligonucleotides, and it requires encapsulation into a delivery nanoparticle, in part due to the significantly larger size of mRNA molecules (300-5,000 kDa, 1-15 kb) as compared to other types of RNAs (small interfering RNAs [siRNAs], 14 kDa; antisense oligonucleotides [ASOs], 4-10 kDa). 10,13 In this review, we discuss the challenges for clinical translation of mRNAbased therapeutics, with an emphasis on recent advances in biomaterials and delivery strategies, and we present an overview of the applications of mRNA-based delivery for protein therapy, gene editing, and vaccination. Materials for mRNA Delivery Structural Aspects of Material DesignAmong the many barriers to function, mRNA must cross the cell membrane in order to reach the cytoplasm (Figure 1). The cell me...

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Section: Materials For Mrna Delivery Structural Aspects Of Materials Dmentioning

confidence: 99%

Delivering the Messenger: Advances in Technologies for Therapeutic mRNA Delivery

et al. 2019

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“…[ 64 ] Recently, a report indicated that both endosomal size and membrane leakiness resulting from a difference in cell lines affected the proton sponge‐based endosomal rupture, providing important clues toward further improvement of this escape strategy. [ 65 ] The major concerns for the use of polycationic agents are toxicity‐induced acute inflammation, hemolysis, cell necrosis, apoptosis, [ 66 ] and low cytosol delivery, which result from the strong interaction between the polycationic agent and cell membranes. In addition, polycationic agents also have high nondegradability and suffer from low dissociation of the cargo from the complex in the cells due to robust interactions between the cargo and the polycation.…”

Section: Cytosolic Delivery Via Endosomal Escapementioning

confidence: 99%

Nanocarrier‐Mediated Cytosolic Delivery of Biopharmaceuticals

Xing

Wang

et al. 2020

Adv Funct Materials

111

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Biopharmaceuticals have emerged to play a vital role in disease treatment and have shown promise in the rapidly expanding pharmaceutical market due to their high specificity and potency. However, the delivery of these biologics is hindered by various physiological barriers, owing primarily to the poor cell membrane permeability, low stability, and increased size of biologic agents. Since many biological drugs are intended to function by interacting with intracellular targets, their delivery to intracellular targets is of high relevance. In this review, the authors summarize and discuss the use of nanocarriers for intracellular delivery of biopharmaceuticals via endosomal escape and, especially, the routes of direct cytosolic delivery by means including the caveolae‐mediated pathway, contact release, intermembrane transfer, membrane fusion, direct translocation, and membrane disruption. Strategies with high potential for translation are highlighted. Finally, the authors conclude with the clinical translation of promising carriers and future perspectives.

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“…Viral vectors typically yield high transduction efficiencies, but their use is expensive, labor-intensive, and associated with significant safety issues [17,18]. While lipid-based and polymer-based nanoparticles can be safer alternatives, efficient transfection is often hindered by poor uptake, e.g., in blood and immune cells [14], limited endosomal escape [19,20], and delayed unpacking of the cargo molecules from the carriers in the cytosol [21]. In addition, these synthetic carriers can typically only be used with specific cargo molecules (e.g., nucleic acids) and cell types [22].…”

Section: Introductionmentioning

confidence: 99%

Gold Nanoparticle-Mediated Photoporation Enables Delivery of Macromolecules over a Wide Range of Molecular Weights in Human CD4+ T Cells

et al. 2019

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The modification of CD4+ T cells with exogenous nucleic acids or proteins is a critical step in several research and therapeutic applications, such as HIV studies and cancer immunotherapies. However, efficient cell transfections are not always easily achieved when working with these primary hard-to-transfect cells. While the modification of T cells is typically performed by viral transduction or electroporation, their use is associated with safety issues or cytotoxicity. Vapor nanobubble (VNB) photoporation with sensitizing gold nanoparticles (AuNPs) has recently emerged as a new technology for safe and flexible cell transfections. In this work, we evaluated the potential of VNB photoporation as a novel technique for the intracellular delivery of macromolecules in primary human CD4+ T cells using fluorescent dextrans as model molecules. Our results show that VNB photoporation enables efficient delivery of fluorescent dextrans of 10 kDa in Jurkat (>60% FD10+ cells) as well as in primary human CD4+ T cells (±40% FD10+ cells), with limited cell toxicity (>70% cell viability). We also demonstrated that the technique allows the delivery of dextrans that are up to 500 kDa in Jurkat cells, suggesting its applicability for the delivery of biological macromolecules with a wide range of molecular weights. Altogether, VNB photoporation represents a promising technique for the universal delivery of macromolecules in view of engineering CD4+ T cells for use in a wide variety of research and therapeutic applications.

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Endosomal Size and Membrane Leakiness Influence Proton Sponge-Based Rupture of Endosomal Vesicles

Cited by 155 publications

References 56 publications

Delivering the Messenger: Advances in Technologies for Therapeutic mRNA Delivery

Delivering the Messenger: Advances in Technologies for Therapeutic mRNA Delivery

Nanocarrier‐Mediated Cytosolic Delivery of Biopharmaceuticals

Gold Nanoparticle-Mediated Photoporation Enables Delivery of Macromolecules over a Wide Range of Molecular Weights in Human CD4+ T Cells

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