The engineering of artificial cellular nanosystems using synthetic biology approaches

Wu, Fan; Tan, Cheemeng

doi:10.1002/wnan.1265

Cited by 31 publications

(24 citation statements)

References 111 publications

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“…Artificial cells have minimal functionalities and structural components compared to natural cells, and are assembled bottom-up by encapsulating the necessary elements into either biological or fully synthetic enclosing membranes [7]. Artificial cells can therefore contain genetic information, the related molecular machineries for their transcription, translation, and replication, and all the required specialized molecules and structures.…”

Section: Enabling Technologies and Challengesmentioning

confidence: 99%

The internet of Bio-Nano things

Pierobon²,

et al. 2015

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Section: Enabling Technologies and Challengesmentioning

confidence: 99%

The internet of Bio-Nano things

Pierobon²,

et al. 2015

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“…The use of aHL as a tool to selectively permeabilize membranes with a pore of known morphology has become quite widespread, finding application in such fields as the construction of artificial cellular systems and single molecule sensing. [30][31][32][33] Spontaneous insertion from detergent micelles and liposomes Ion channels and transporters, which may be more intriguing subjects for characterization using DIBs, do not typically have a water soluble form such as the aHL monomer. 25 Purifying integral membrane proteins for in vitro study requires an amphiphile such as a detergent micelle or a lipid nanostructure (e.g.…”

Section: Incorporating Proteins Into Dibs Spontaneous Insertion From mentioning

confidence: 99%

Probing membrane protein properties using droplet interface bilayers

Allen-Benton

Findlay

Booth

2019

Exp Biol Med (Maywood)

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Integral membrane proteins comprise a large proportion of drug targets, yet are challenging to study in vitro due to their amphiphilic nature. Conducting useful functional in vitro studies requires an artificial membrane that can mimic the lipid environment of the biogenic membrane. Droplet interface bilayer technology provides a method to form artificial bilayers with a robustness and physicochemical complexity that has not previously been possible, facilitating more sophisticated in vitro studies of membrane proteins. This mini-review examines functional studies of membrane proteins that utilize droplet interface bilayers to date and comments on possible directions of future research. Observations from our own laboratory regarding the study of a flippase protein in droplet interface bilayers are also presented. Impact statement The paper presents a comprehensive review of integral membrane protein studies utilizing droplet interface bilayers. Droplet interface bilayers are a novel method of constructing artificial lipid bilayers with enhanced stability and physicochemical complexity compared to existing methods. Their unique morphology also suggests applications in the construction of synthetic biological systems and protocells. As well as serving as a guide to in vitro membrane protein functional studies using droplet interface bilayers in the literature to date, a novel in vitro study of a flippase protein in a droplet interface bilayer is presented.

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“…Venter Institute announced that they successfully produced a synthetic cell controlled by human-made DNA (Gibson et al 2010;Wu & Tan 2014). Although the practical aims of this work are ostensibly to develop better ways to clean polluted water, speed up vaccine production and so on, one can imagine how the techniques involved, might, in principle, eventually allow scientists to produce humans free of undesirable genes, produce humans with multiple copies of certain desirable genes, or even produce humans with entirely new genes aimed at extending the natural life span of humankind.…”

Section: Artificial Lifementioning

confidence: 99%

What Does it Mean to be Human? Life, Death, Personhood and the Transhumanist Movement

Doyle¹

2018

Anticipation Science

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This dissertation addresses various aspects of the question "What does it mean to be human?", approaching the issue from biological, philosophical and ethical perspectives. The discussion focuses primarily on the philosophical and ethical implications of the transhumanist movement, an intellectual community seeking to favorably transform the human organism via the safe deployment of interventions such as genetic engineering and pharmacologic enhancement. Following a review of bioethical principles, the dissertation begins by examining the notion of "personhood" in philosophical, historical and biological contexts. Next, the possibility that developments in neuropharmacology might ultimately lead to an artificial paradise free of the negative aspects of the human condition (but without the often destructive effects of today's mood altering drugs) is considered. A philosophical difficulty related to the existentialist notion of "authenticity" in such a "mood optimized" synthetic existence is identified. © © U Un ni iv ve er rs si it ty y o of f P Pr re et to or ri ia a iv This discussion is followed by a rather technical exposition on the occasional difficulties of establishing when a person is alive or dead, particularly in the setting of "brain death". A number of philosophical flaws with the notion of brain death as it is used currently are presented. The discussion then considers some of the philosophical issues raised by the possibility of human cryonic suspension. A distinction is made between the information preserved in a person's brain and the substrate used to hold that information. Implications for personhood are also discussed, as well as a number of related ethical issues. Finally, objections raised by "bioconservative" critics of transhumanism are critically examined and found to be for the most part unconvincing, frequently relying on emotion and intuition rather than on evidence, logic and reason.

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The engineering of artificial cellular nanosystems using synthetic biology approaches

Cited by 31 publications

References 111 publications

The internet of Bio-Nano things

The internet of Bio-Nano things

Probing membrane protein properties using droplet interface bilayers

What Does it Mean to be Human? Life, Death, Personhood and the Transhumanist Movement

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