Transmembrane signaling by a synthetic receptor in artificial cells

Søgaard, Ane Bretschneider; Pedersen, Andreas Bøtker; Løvschall, Kaja Borup; Monge, Pere; Jakobsen, Josefine; Džabbarova, Leila; Nielsen, Line F.; Stevanovic, Sandra; Walther, Raoul; Zelikin, Alexander N.

doi:10.1038/s41467-023-37393-0

Cited by 14 publications

(10 citation statements)

References 45 publications

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“…This capability opens up numerous applications, including targeted drug delivery systems that respond to specific signals within the body and biosensors capable of imaging . In the pursuit of mimicking these intricate biological processes, artificial cell research has made significant strides, particularly in the development of multicompartment vesicles. , Compared to single compartmentalization, multicompartmentalization allows for spatiotemporal control over complex reactions, such as signal amplification or noise filtering . Therefore, understanding and replicating the spatiotemporal aspects of signal transduction in multicompartmentalized artificial cells not only advances our knowledge of basic biological processes but also facilitates the development of more sophisticated synthetic systems in diverse biomedical and biotechnological applications.…”

Section: Artificial Cell Applicationsmentioning

confidence: 99%

Multicompartment Synthetic Vesicles for Artificial Cell Applications

Shin,

Jang

2024

ACS Appl. Eng. Mater.

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This review explores the cutting-edge development of multicompartment synthetic vesicles designed for artificial cell applications, drawing inspiration from the complex compartmentalization inherent in living cells. It delves into the recent advancements in engineering vesicles equipped with both membranous and membraneless organelles (vesicles-in-vesicles and coacervates-invesicles), offering a detailed examination of the methodologies and materials employed. This paper highlights the critical role of these multicompartment vesicles in simulating cellular microenvironments and functions, facilitating the spatial and temporal segregation of biochemical processes, such as signal transduction, gene expression, ATP synthesis, and energy production. Moreover, this review outlines potential future directions, emphasizing the importance of these vesicles in the evolution of artificial cells with a focus on their application in creating more sophisticated biomimetic systems.

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Section: Artificial Cell Applicationsmentioning

confidence: 99%

Multicompartment Synthetic Vesicles for Artificial Cell Applications

Shin,

Jang

2024

ACS Appl. Eng. Mater.

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“…What is more, when these biological units are exploited in non-conventional ways or when non-biological units are integrated, additional interesting functions can be integrated 198 . Examples of this include DNA origami nanopores 199 , transmembrane signal transducers built from synthetic chemicals 200 – 202 , magnetotactic behaviour endowed by encapsulated magnetic nanoparticles 203 and photo-inducible release enabled by photopolymerisable lipids 204 . In the following sections, some of these extra potential functionalities are highlighted.…”

Section: Beyond Rbcs: Adding More Functionalitymentioning

confidence: 99%

Artificial cells for in vivo biomedical applications through red blood cell biomimicry

Waeterschoot,

Gosselé,

Lemež

et al. 2024

Nat Commun

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Recent research in artificial cell production holds promise for the development of delivery agents with therapeutic effects akin to real cells. To succeed in these applications, these systems need to survive the circulatory conditions. In this review we present strategies that, inspired by the endurance of red blood cells, have enhanced the viability of large, cell-like vehicles for in vivo therapeutic use, particularly focusing on giant unilamellar vesicles. Insights from red blood cells can guide modifications that could transform these platforms into advanced drug delivery vehicles, showcasing biomimicry’s potential in shaping the future of therapeutic applications.

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“…The highest achievement of our prior reports was the artificial receptor-mediated transmembrane activation of a chemical zymogen in the void of a liposome, a simplified syncell. [15] In this work, we engineer syncells in which artificial signaling culminates in the activation of transcription. To achieve this, we developed chemical zymogens for the creatine kinase and for the T7 polymerase.…”

Section: Introductionmentioning

confidence: 99%

“…In pursuit of syncells with adaptive responsive behavior, we turned from the challenging implementation of natural signaling to the engineering of artificial signaling pathways. This approach required the development of both, artificial receptors for transmembrane signaling [ 15 ] and artificial enzyme activation pathways, [ 16 ] for downstream intracellular signaling. To this end, we developed transmembrane signaling using tools of organic chemistry whereby exofacial receptor activation resulted in the release of a secondary messenger to the interior of a syncell.…”

Section: Introductionmentioning

confidence: 99%

Chemical Zymogens and Transmembrane Activation of Transcription in Synthetic Cells

Andersen,

Pedersen,

Jørgensen

et al. 2023

Advanced Materials

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In this work, synthetic cells equipped with an artificial signaling pathway that connects an extracellular trigger event to the activation of intracellular transcription are engineered. Learning from nature, this is done via an engineering of responsive enzymes, such that activation of enzymatic activity can be triggered by an external biochemical stimulus. Reversibly deactivated creatine kinase to achieve triggered production of adenosine triphosphate, and a reversibly deactivated nucleic acid polymerase for on‐demand synthesis of RNA are engineered. An extracellular, enzyme‐activated production of a diffusible zymogen activator is also designed. The key achievement of this work is that the importance of cellularity is illustrated whereby the separation of biochemical partners is essential to resolve their incompatibility, to enable transcription within the confines of a synthetic cell. The herein designed biochemical pathway and the engineered synthetic cells are arguably primitive compared to their natural counterpart. Nevertheless, the results present a significant step toward the design of synthetic cells with responsive behavior, en route from abiotic to life‐like cell mimics.

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Transmembrane signaling by a synthetic receptor in artificial cells

Cited by 14 publications

References 45 publications

Multicompartment Synthetic Vesicles for Artificial Cell Applications

Multicompartment Synthetic Vesicles for Artificial Cell Applications

Artificial cells for in vivo biomedical applications through red blood cell biomimicry

Chemical Zymogens and Transmembrane Activation of Transcription in Synthetic Cells

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