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1. The all-E. coliTXTL toolbox 3.0: new capabilities of a cell-free synthetic biology platform

   https://doi.org/10.1093/synbio/ysab017  

   Garenne, David; Thompson, Seth; Brisson, Amaury; Khakimzhan, Aset; Noireaux, Vincent (August 2021, Synthetic Biology)

   null (Ed.)

   Abstract The new generation of cell-free gene expression systems enables the prototyping and engineering of biological systems in vitro over a remarkable scope of applications and physical scales. As the utilization of DNA-directed in vitro protein synthesis expands in scope, developing more powerful cell-free transcription–translation (TXTL) platforms remains a major goal to either execute larger DNA programs or improve cell-free biomanufacturing capabilities. In this work, we report the capabilities of the all-E. coli TXTL toolbox 3.0, a multipurpose cell-free expression system specifically developed for synthetic biology. In non-fed batch-mode reactions, the synthesis of the fluorescent reporter protein eGFP (enhanced green fluorescent protein) reaches 4 mg/ml. In synthetic cells, consisting of liposomes loaded with a TXTL reaction, eGFP is produced at concentrations of >8 mg/ml when the chemical building blocks feeding the reaction diffuse through membrane channels to facilitate exchanges with the outer solution. The bacteriophage T7, encoded by a genome of 40 kb and ∼60 genes, is produced at a concentration of 1013 PFU/ml (plaque forming unit/ml). This TXTL system extends the current cell-free expression capabilities by offering unique strength and properties, for testing regulatory elements and circuits, biomanufacturing biologics or building synthetic cells. 

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2. Engineering Functional Membrane–Membrane Interfaces by InterSpy

   https://doi.org/10.1002/smll.202202104  

   Moghimianavval, Hossein; Patel, Chintan; Mohapatra, Sonisilpa; Hwang, Sung‐Won; Kayikcioglu, Tunc; Bashirzadeh, Yashar; Liu, Allen P.; Ha, Taekjip (May 2022, Small)

   Abstract Engineering synthetic interfaces between membranes has potential applications in designing non‐native cellular communication pathways and creating synthetic tissues. Here, InterSpy is introduced as a synthetic biology tool consisting of a heterodimeric protein engineered to form and maintain membrane–membrane interfaces between apposing synthetic as well as cell membranes through the SpyTag/SpyCatcher interaction. The inclusion of split fluorescent protein fragments in InterSpy allows tracking of the formation of a membrane–membrane interface and reconstitution of functional fluorescent protein in the space between apposing membranes. First, InterSpy is demonstrated by testing split protein designs using a mammalian cell‐free expression (CFE) system. By utilizing co‐translational helix insertion, cell‐free synthesized InterSpy fragments are incorporated into the membrane of liposomes and supported lipid bilayers with the desired topology. Functional reconstitution of split fluorescent protein between the membranes is strictly dependent on SpyTag/SpyCatcher. Finally, InterSpy is demonstrated in mammalian cells by detecting fluorescence reconstitution of split protein at the membrane–membrane interface between two cells each expressing a component of InterSpy. InterSpy demonstrates the power of CFE systems in the functional reconstitution of synthetic membrane interfaces via proximity‐inducing proteins. This technology may also prove useful where cell‐cell contacts and communication are recreated in a controlled manner using minimal components. 

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3. Targeted RNA condensation in living cells via genetically encodable triplet repeat tags

   https://doi.org/10.1093/nar/gkad621  

   Xue, Zhaolin; Ren, Kewei; Wu, Rigumula; Sun, Zhining; Zheng, Ru; Tian, Qian; Ali, Ahsan Ausaf; Mi, Lan; You, Mingxu (July 2023, Nucleic Acids Research)

   Abstract Living systems contain various membraneless organelles that segregate proteins and RNAs via liquid–liquid phase separation. Inspired by nature, many protein-based synthetic compartments have been engineered in vitro and in living cells. Here, we introduce a genetically encoded CAG-repeat RNA tag to reprogram cellular condensate formation and recruit various non-phase-transition RNAs for cellular modulation. With the help of fluorogenic RNA aptamers, we have systematically studied the formation dynamics, spatial distributions, sizes and densities of these cellular RNA condensates. The cis- and trans-regulation functions of these CAG-repeat tags in cellular RNA localization, life time, RNA–protein interactions and gene expression have also been investigated. Considering the importance of RNA condensation in health and disease, we expect that these genetically encodable modular and self-assembled tags can be widely used for chemical biology and synthetic biology studies. 

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4. Cell-free expressed membraneless organelles sequester RNA in synthetic cells

   https://doi.org/10.1101/2023.04.03.535479  

   Robinson, Abbey O; Lee, Jessica; Cameron, Anders; Keating, Christine D; Adamala, Katarzyna P (April 2023, bioRxiv)

   Abstract Compartments within living cells create specialized microenvironments, allowing for multiple reactions to be carried out simultaneously and efficiently. While some organelles are bound by a lipid bilayer, others are formed by liquid-liquid phase separation, such as P-granules and nucleoli. Synthetic minimal cells have been widely used to study many natural processes, including organelle formation. Here we describe a synthetic cell expressing RGG-GFP-RGG, a phase-separating protein derived from LAF-1 RGG domains, to form artificial membraneless organelles that can sequester RNA and reduce protein expression. We create complex microenvironments within synthetic cell cytoplasm and introduce a tool to modulate protein expression in synthetic cells. Engineering of compartments within synthetic cells furthers understanding of evolution and function of natural organelles, as well as it facilitates the creation of more complex and multifaceted synthetic life-like systems. 

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5. Small protein modules dictate prophage fates during polylysogeny

   https://doi.org/10.1038/s41586-023-06376-y  

   Silpe, Justin E.; Duddy, Olivia P.; Johnson, Grace E.; Beggs, Grace A.; Hussain, Fatima A.; Forsberg, Kevin J.; Bassler, Bonnie L. (August 2023, Nature)

   Abstract Most bacteria in the biosphere are predicted to be polylysogens harbouring multiple prophages^1–5. In studied systems, prophage induction from lysogeny to lysis is near-universally driven by DNA-damaging agents⁶. Thus, how co-residing prophages compete for cell resources if they respond to an identical trigger is unknown. Here we discover regulatory modules that control prophage induction independently of the DNA-damage cue. The modules bear little resemblance at the sequence level but share a regulatory logic by having a transcription factor that activates the expression of a neighbouring gene that encodes a small protein. The small protein inactivates the master repressor of lysis, which leads to induction. Polylysogens that harbour two prophages exposed to DNA damage release mixed populations of phages. Single-cell analyses reveal that this blend is a consequence of discrete subsets of cells producing one, the other or both phages. By contrast, induction through the DNA-damage-independent module results in cells producing only the phage sensitive to that specific cue. Thus, in the polylysogens tested, the stimulus used to induce lysis determines phage productivity. Considering the lack of potent DNA-damaging agents in natural habitats, additional phage-encoded sensory pathways to lysis likely have fundamental roles in phage–host biology and inter-prophage competition. 

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