Controlling Secretion in Artificial Cells with a Membrane AND Gate

Hilburger, Claire E.; Jacobs, Miranda L.; Lewis, Kamryn; Peruzzi, Justin A.; Kamat, Neha P.

doi:10.1021/acssynbio.8b00435

“…When we increased the hemolysin concentration from 62 to 100 nM, we observed no apparent change in FRAP recovery rate. The addition of cholesterol and oleic acid could increase the recovery rate of the FI, as reported previously [ 35 , 36 ]. In addition, this FRAP experiment was particularly challenging because the laser irradiation triggered oil flow, destabilizing the droplets.…”

Section: Resultssupporting

confidence: 80%

Microfluidic Formation of Honeycomb-Patterned Droplets Bounded by Interface Bilayers via Bimodal Molecular Adsorption

Fujiwara

¹

,

Shoji

²

,

Watanabe

³

et al. 2020

View full text Add to dashboard Cite

Assembled water-in-oil droplets bounded by lipid bilayers are used in synthetic biology as minimal models of cell tissue. Microfluidic devices successfully generate monodispersed droplets and assemble them via droplet interface bilayesr (DIB) formation. However, a honeycomb pattern of DIB-bounded droplets, similar to epithelial tissues, remains unrealized because the rapid DIB formation between the droplets hinders their ability to form the honeycomb pattern. In this paper, we demonstrate the microfluidic formation of a honeycomb pattern of DIB-bounded droplets using two surfactants with different adsorption rates on the droplet surface. A non-DIB forming surfactant (sorbitan monooleate, Span 80) was mixed with a lipid (1,2-dioleoyl-sn-glycero-3-phosphocholine, PC), whose adsorption rate on the droplet surface and saturated interfacial tension were lower than those of Span 80. By changing the surfactant composition, we established the conditions under which the droplets initially form a honeycomb pattern and subsequently adhere to each other via DIB formation to minimize the interfacial energy. In addition, the reconstituted membrane protein nanopores at the DIBs were able to transport molecules. This new method, using the difference in the adsorption rates of two surfactants, allows the formation of a honeycomb pattern of DIB-bounded droplets in a single step, and thus facilitates research using DIB-bounded droplet assemblies.

show abstract

“…Biochemical products synthesized within vesicles as a result of fusion could further expand the functionality of vesicles by generating useful protein products. These protein products could include pore‐forming proteins to release and deliver cargo, or surface antigens that enable sensing of and interactions with the surrounding environment. Ultimately, DNA‐mediated vesicle fusion coupled with the cell‐free synthesis of biological molecules should expand the possible functions of vesicle‐based materials, enabling enhanced sensing, delivery, and biomanufacturing capabilities.…”

Section: Discussionmentioning

confidence: 99%

Barcoding Biological Reactions with DNA‐Functionalized Vesicles

Peruzzi

¹

,

Jacobs

²

,

Vu

³

et al. 2019

Self Cite

View full text Add to dashboard Cite

Targeted vesicle fusion is a promising approach to selectively control interactions between vesicle compartments and would enable the initiation of biological reactions in complex aqueous environments. Here, we explore how two features of vesicle membranes, DNA tethers and phase‐segregated membranes, promote fusion between specific vesicle populations. Membrane phase‐segregation provides an energetic driver for membrane fusion that increases the efficiency of DNA‐mediated fusion events. The orthogonality provided by DNA tethers allows us to direct fusion and delivery of DNA cargo to specific vesicle populations. Vesicle fusion between DNA‐tethered vesicles can be used to initiate in vitro protein expression to produce model soluble and membrane proteins. Engineering orthogonal fusion events between DNA‐tethered vesicles provides a new strategy to control the spatiotemporal dynamics of cell‐free reactions, expanding opportunities to engineer artificial cellular systems.

show abstract

“…Research Articles deliver cargo, [6,74,75] or surface antigens that enable sensing of and interactions with the surrounding environment. Ultimately,D NA-mediated vesicle fusion coupled with the cellfree synthesis of biological molecules should expand the possible functions of vesicle-based materials,e nabling enhanced sensing,d elivery,a nd biomanufacturing capabilities.…”

Section: Angewandte Chemiementioning

confidence: 99%

Barcoding Biological Reactions with DNA‐Functionalized Vesicles

Peruzzi

¹

,

Jacobs

²

,

Vu

³

et al. 2019

Self Cite

View full text Add to dashboard Cite

Targeted vesicle fusion is a promising approach to selectively control interactions between vesicle compartments and would enable the initiation of biological reactions in complex aqueous environments. Here, we explore how two features of vesicle membranes, DNA tethers and phase‐segregated membranes, promote fusion between specific vesicle populations. Membrane phase‐segregation provides an energetic driver for membrane fusion that increases the efficiency of DNA‐mediated fusion events. The orthogonality provided by DNA tethers allows us to direct fusion and delivery of DNA cargo to specific vesicle populations. Vesicle fusion between DNA‐tethered vesicles can be used to initiate in vitro protein expression to produce model soluble and membrane proteins. Engineering orthogonal fusion events between DNA‐tethered vesicles provides a new strategy to control the spatiotemporal dynamics of cell‐free reactions, expanding opportunities to engineer artificial cellular systems.

show abstract

Controlling Secretion in Artificial Cells with a Membrane AND Gate

Cited by 41 publications

References 40 publications

Microfluidic Formation of Honeycomb-Patterned Droplets Bounded by Interface Bilayers via Bimodal Molecular Adsorption

Microfluidic Formation of Honeycomb-Patterned Droplets Bounded by Interface Bilayers via Bimodal Molecular Adsorption

Barcoding Biological Reactions with DNA‐Functionalized Vesicles

Barcoding Biological Reactions with DNA‐Functionalized Vesicles

Contact Info

Product

Resources

About