Environmental Galenics: large-scale fortification of extant microbiomes with engineered bioremediation agents

de Lorenzo, Víctor

doi:10.1098/rstb.2021.0395

Cited by 22 publications

(19 citation statements)

References 182 publications

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“…A habitual disregard of what is involved in scale-up is an Achilles’ heel of the whole field. It is one thing to have a smart genetic construct showing a spectacular phenotype in a Petri dish or small bioreactor for a short period of time but a very different thing to have the same at an industrial or even global scale and following rigorous implementation standards. Going from one dimension to the other makes the whole difference between a merely intellectual exercise and a truly transformative development .…”

Section: Hope Versus Hypementioning

confidence: 99%

“…In the modern sense, the scientific and technical field universally known now as Synthetic Biology (SynBio) first took off a little more than 20 years ago in bacteria and yeast (Figure ) and, although it soon reached plants, animals, and cell-free systems, it remains largely microbe-centric. − Notwithstanding this constraint, nothing in biology since the double helix and recombinant DNA revolutions has captured more scientific, philosophical, government, and investor interest than SynBio. − Nor has any other field generated such a vast speculative secondary literature on how it could transform everything from manufacturing, agriculture, and medicine to ecosystems, earth’s climate, and space travel, plus resurrect the Pleistocene paleofauna. − Along the way, much has been promised, implicitly or explicitly. Here, we argue that a good deal of this promise may not be fulfilled unless SynBio stays anchored to its engineering foundations, i.e., applies science, math, and art to design and build workable solutions to real problems.…”

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confidence: 99%

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Synthetic Biology─High Time to Deliver?

Hanson

2023

ACS Synth. Biol.

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Synthetic biology (SynBio) has attracted like no other recent development the attention not only of Life Science researchers and engineers but also of intellectuals, technology think-tanks, and private and public investors. This is largely due to its promise to propel biotechnology beyond its traditional realms in medicine, agriculture, and environment toward new territories historically dominated by the chemical and manufacturing industries�but now claimed to be amenable to complete biologization. For this to happen, it is crucial for the field to remain true to its foundational engineering drive, which relies on mathematics and quantitative tools to construct practical solutions to real-world problems. This article highlights several SynBio themes that, in our view, come with somewhat precarious promises that need to be tackled. First, SynBio must critically examine whether enough basic information is available to enable the design or redesign of life processes and turn biology from a descriptive science into a prescriptive one. Second, unlike circuit boards, cells are built with soft matter and possess inherent abilities to mutate and evolve, even without external cues. Third, the field cannot be presented as the one technical solution to many grave world problems and so must avoid exaggerated claims and hype. Finally, SynBio should pay heed to public sensitivities and involve social science in its development and growth, and thus change the technology narrative from sheer domination of the living world to conversation and win-win partnership.

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Section: Hope Versus Hypementioning

confidence: 99%

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confidence: 99%

Synthetic Biology─High Time to Deliver?

Hanson

2023

ACS Synth. Biol.

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“…In a stepwise scale-up, the efficacy and safety of engineered biological catalysts could first be tested in a laboratory before moving into mesocosms and finally contained ecosystems, before considering a deployment in the environment. [95] This tested deployment would aim to minimize the risks associated with releasing genetically enhanced microorganisms, while still enabling the spread of the bioremediation agents in the environment (Figure 2).…”

Section: Containment or Spread Of Genetically Enhanced Microbes For B...mentioning

confidence: 99%

Taking Synthetic Biology to the Seas: From Blue Chassis Organisms to Marine Aquaforming

Borzyskowski

2023

ChemBioChem

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Oceans cover 71 % of Earth's surface and are home to hundreds of thousands of species, many of which are microbial. Knowledge about marine microbes has strongly increased in the past decades due to global sampling expeditions, and hundreds of detailed studies on marine microbial ecology, physiology, and biogeochemistry. However, the translation of this knowledge into biotechnological applications or synthetic biology approaches using marine microbes has been limited so far. This review highlights key examples of marine bacteria in synthetic biology and metabolic engineering, and outlines possible future work based on the emerging marine chassis organisms Vibrio natriegens and Halomonas bluephagenesis. Furthermore, the valorization of algal polysaccharides by genetically enhanced microbes is presented as an example of the opportunities and challenges associated with blue biotechnology. Finally, new roles for marine synthetic biology in tackling pressing global challenges, including climate change and marine pollution, are discussed.

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“…Adding an extra function such as secreting a polymer that can enhance water retention, even at low levels, could generate a systems-level improvement and move away the location of an undesirable ecological shift. In general, the potential of microbial biotechnology could be expanded across all the scales outlined in figure 2 , with microorganisms at the core of novel strategies [ 126 ]. The idea that synthetic biology can be a helpful (and even necessary) tool to protect biodiversity has been further actively discussed in conservation goals [ 75 , 113 ] within marine biology.…”

Section: Biodiversity Adaptation and Engineeringmentioning

confidence: 99%

Ecological complexity and the biosphere: the next 30 years

Solé

Levin

2022

Phil. Trans. R. Soc. B

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Global warming, habitat loss and overexploitation of limited resources are leading to alarming biodiversity declines. Ecosystems are complex adaptive systems that display multiple alternative states and can shift from one to another in abrupt ways. Some of these tipping points have been identified and predicted by mathematical and computational models. Moreover, multiple scales are involved and potential mitigation or intervention scenarios are tied to particular levels of complexity, from cells to human–environment coupled systems. In dealing with a biosphere where humans are part of a complex, endangered ecological network, novel theoretical and engineering approaches need to be considered. At the centre of most research efforts is biodiversity, which is essential to maintain community resilience and ecosystem services. What can be done to mitigate, counterbalance or prevent tipping points? Using a 30-year window, we explore recent approaches to sense, preserve and restore ecosystem resilience as well as a number of proposed interventions (from afforestation to bioengineering) directed to mitigate or reverse ecosystem collapse. The year 2050 is taken as a representative future horizon that combines a time scale where deep ecological changes will occur and proposed solutions might be effective. This article is part of the theme issue ‘Ecological complexity and the biosphere: the next 30 years’.

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Environmental Galenics: large-scale fortification of extant microbiomes with engineered bioremediation agents

Cited by 22 publications

References 182 publications

Synthetic Biology─High Time to Deliver?

Synthetic Biology─High Time to Deliver?

Taking Synthetic Biology to the Seas: From Blue Chassis Organisms to Marine Aquaforming

Ecological complexity and the biosphere: the next 30 years

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