Interfacing Coacervates with Membranes: From Artificial Organelles and Hybrid Protocells to Intracellular Delivery

Lu, Tiemei; Javed, Salil; Bonfio, Claudia; Spruijt, Evan

doi:10.1002/smtd.202300294

Cited by 9 publications

(8 citation statements)

References 119 publications

(190 reference statements)

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“…For instance, coacervate or DNA/hydrogel systems interfaced with lipid membranes can be combined to enhance functionality. 26–28…”

Section: Body Of Molecular Robotsmentioning

confidence: 99%

Lipid vesicle-based molecular robots

Peng,

Iwabuchi,

Izumi

et al. 2024

Lab Chip

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“…For instance, coacervate or DNA/hydrogel systems interfaced with lipid membranes can be combined to enhance functionality. 26–28…”

Section: Body Of Molecular Robotsmentioning

confidence: 99%

Lipid vesicle-based molecular robots

Peng,

Iwabuchi,

Izumi

et al. 2024

Lab Chip

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show abstract

“…When coacervates are introduced into the cytosol, they have the potential to disrupt normal intracellular processes by interacting with the cell membrane . This interaction holds significance in various cellular processes, such as signal transduction, long-distance RNA transport, waste disposal mechanisms, and protein storage . Coacervates can influence the membrane by affecting its fluidity, inducing deformation, and causing budding .…”

Section: Complex Coacervates For Mrna Delivery: Overview and Advantagesmentioning

confidence: 99%

“…34 Coacervates can influence the membrane by affecting its fluidity, inducing deformation, and causing budding. 34 The extent of wetting between coacervate droplets and membranes depends on their composition and interactions, resulting in non-wetting, partial wetting, or complete wetting states. 34 Moreover, macromolecular crowding has been found to impact liquid−liquid phase separation in a polyuridylic acid (polyU)/spermine complex coacervate system.…”

Section: ■ Introductionmentioning

confidence: 99%

“…33 This interaction holds significance in various cellular processes, such as signal transduction, long-distance RNA transport, waste disposal mechanisms, and protein storage. 34 Coacervates can influence the membrane by affecting its fluidity, inducing deformation, and causing budding. 34 The extent of wetting between coacervate droplets and membranes depends on their composition and interactions, resulting in non-wetting, partial wetting, or complete wetting states.…”

Section: ■ Introductionmentioning

confidence: 99%

“…34 The extent of wetting between coacervate droplets and membranes depends on their composition and interactions, resulting in non-wetting, partial wetting, or complete wetting states. 34 Moreover, macromolecular crowding has been found to impact liquid−liquid phase separation in a polyuridylic acid (polyU)/spermine complex coacervate system. The formation of coacervate droplets is influenced by excluded volume and preferential interactions, which impact the secondary structure/condensation of polyU molecules associated with spermine.…”

Section: ■ Introductionmentioning

confidence: 99%

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Complex Coacervates as a Promising Vehicle for mRNA Delivery: A Comprehensive Review of Recent Advances and Challenges

Forenzo,

Larsen

2023

Mol. Pharmaceutics

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Messenger RNA (mRNA)-based therapies have gained significant attention, following the successful deployment of mRNA-based COVID-19 vaccines. Compared with traditional methods of genetic modification, mRNA-based therapies offer several advantages, including a lower risk of genetic mutations, temporary and controlled therapeutic gene expression, and a shorter production time, which facilitates rapid responses to emerging health challenges. Moreover, mRNA-based therapies have shown immense potential in treating a wide range of diseases including cancers, immune diseases, and neurological disorders. However, the current limitations of non-viral vectors for efficient and safe delivery of mRNA therapies, such as low encapsulation efficiency, potential toxicity, and limited stability, necessitate the exploration of novel strategies to overcome these challenges and fully realize the potential of mRNA-based therapeutics. Coacervate-based delivery systems have recently emerged as promising strategies for enhancing mRNA delivery. Coacervates, which are formed by the aggregation of two or more macromolecules, have shown great potential in delivering a wide range of therapeutics due to their ability to form a separated macromolecular-rich fluid phase in an aqueous environment. This phase separation enables the entrapment and protection of therapeutic agents from degradation as well as efficient cellular uptake and controlled release. Additionally, the natural affinity of coacervates for mRNA molecules presents an excellent opportunity for enhancing mRNA delivery to targeted cells and tissues, making coacervate-based delivery systems an attractive option for mRNA-based therapies. This review highlights the limitations of current strategies for mRNA delivery and the advantages of coacervate-based delivery systems to enable mRNA therapeutics. Coacervates protect mRNA from enzymatic degradation and enhance cellular uptake, leading to sustained and controlled gene expression. Despite their promising properties, the specific use of coacervates as mRNA delivery vehicles remains underexplored. This review aims to provide a comprehensive overview of coacervate-mediated delivery of mRNA, exploring the properties and applications of different coacervating agents as well as the challenges and optimization strategies involved in mRNA encapsulation, release, stability, and translation via coacervate-mediated delivery. Through a comprehensive analysis of recent advancements and recommended future directions, our review sheds light on the promising role of coacervate-mediated delivery for RNA therapeutics, highlighting its potential to enable groundbreaking applications in drug delivery and gene therapy.

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Photoswitchable Endocytosis of Biomolecular Condensates in Giant Vesicles

Mangiarotti,

Aleksanyan,

Siri

et al. 2024

Advanced Science

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Interactions between membranes and biomolecular condensates can give rise to complex phenomena such as wetting transitions, mutual remodeling, and endocytosis. In this study, light‐triggered manipulation of condensate engulfment is demonstrated using giant vesicles containing photoswitchable lipids. UV irradiation increases the membrane area, which can be stored in nanotubes. When in contact with a condensate droplet, the UV light triggers rapid condensate endocytosis, which can be reverted by blue light. The affinity of the protein‐rich condensates to the membrane and the reversibility of the engulfment processes is quantified from confocal microscopy images. The degree of photo‐induced engulfment, whether partial or complete, depends on the vesicle excess area and the relative sizes of vesicles and condensates. Theoretical estimates suggest that utilizing the light‐induced excess area to increase the vesicle‐condensate adhesion interface is energetically more favorable than the energy gain from folding the membrane into invaginations and tubes. The overall findings demonstrate that membrane‐condensate interactions can be easily and quickly modulated via light, providing a versatile system for building platforms to control cellular events and design intelligent drug delivery systems for cell repair.

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Interfacing Coacervates with Membranes: From Artificial Organelles and Hybrid Protocells to Intracellular Delivery

Cited by 9 publications

References 119 publications

Lipid vesicle-based molecular robots

Lipid vesicle-based molecular robots

Complex Coacervates as a Promising Vehicle for mRNA Delivery: A Comprehensive Review of Recent Advances and Challenges

Photoswitchable Endocytosis of Biomolecular Condensates in Giant Vesicles

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