Systems-informed genome mining for electroautotrophic microbial production

Abel, Anthony J.; Hilzinger, Jacob M.; Arkin, Adam P.; Clark, Douglas S.

doi:10.1101/2020.12.07.414987

Cited by 5 publications

(4 citation statements)

References 86 publications

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“…We sought to make acoustic proteins widely useful in in vivo biological research and potential clinical applications by developing ARGs that, when expressed heterologously in either bacteria or mammalian cancer cell lines, could produce GVs with strong non-linear ultrasound contrast and enable long-term expression under physiological conditions. We used a genomic mining approach-previously applied to improving fluorescent proteins [11][12][13][14] , opsins [15][16][17] , Cas proteins [18][19][20][21][22] and other biotechnology tools [23][24][25][26][27][28] -to identify ARGs with improved properties, which we subsequently optimized through genetic engineering. By cloning and screening 15 distinct polycistronic operons chosen from a diverse set of 288 GV-expressing species representing a broad phylogeny, we identified two GV gene clusters-from Serratia sp.…”

Section: Articlementioning

confidence: 99%

Genomically mined acoustic reporter genes for real-time in vivo monitoring of tumors and tumor-homing bacteria

et al. 2023

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Ultrasound allows imaging at a much greater depth than optical methods, but existing genetically encoded acoustic reporters for in vivo cellular imaging have been limited by poor sensitivity, specificity and in vivo expression. Here we describe two acoustic reporter genes (ARGs)—one for use in bacteria and one for use in mammalian cells—identified through a phylogenetic screen of candidate gas vesicle gene clusters from diverse bacteria and archaea that provide stronger ultrasound contrast, produce non-linear signals distinguishable from background tissue and have stable long-term expression. Compared to their first-generation counterparts, these improved bacterial and mammalian ARGs produce 9-fold and 38-fold stronger non-linear contrast, respectively. Using these new ARGs, we non-invasively imaged in situ tumor colonization and gene expression in tumor-homing therapeutic bacteria, tracked the progression of tumor gene expression and growth in a mouse model of breast cancer, and performed gene-expression-guided needle biopsies of a genetically mosaic tumor, demonstrating non-invasive access to dynamic biological processes at centimeter depth.

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Section: Articlementioning

confidence: 99%

Genomically mined acoustic reporter genes for real-time in vivo monitoring of tumors and tumor-homing bacteria

et al. 2023

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“…Light-independent, lithoautotrophy can fix carbon by relying on chemically provided reducing power. On Mars, this could either directly be electricity through microbial electrosynthesis in bio-electrochemical systems (Moscoviz et al, 2016;Abel et al, 2020;Chen et al, 2020a), or indirectly by means of hydrogen or (organoautotrophically) formate, both of which can also be generated electrochemically (Kracke et al, 2020;Abel and Clark, 2021). Use of other electron donors like, e.g., sulphide, sulphur and iron (II) is theoretically possible, but technically less feasible (crustal materials from Mars are in principle able to support lithotrophic growth (Milojevic et al, 2021), but mining and purifying these in quantities that could support biotechnological processes is likely not viable).…”

Section: From Autotrophy To Heterotrophy-impact On Process Parameters and Complexitymentioning

confidence: 99%

Choice of Microbial System for In-Situ Resource Utilization on Mars

Averesch

2021

Front. Astron. Space Sci.

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Various microbial systems have been explored for their applicability to in-situ resource utilisation (ISRU) on Mars and suitability to leverage Martian resources and convert them into useful chemical products. Considering only fully bio-based solutions, two approaches can be distinguished, which comes down to the form of carbon that is being utilized: (a) the deployment of specialised species that can directly convert inorganic carbon (atmospheric CO2) into a target compound or (b) a two-step process that relies on independent fixation of carbon and the subsequent conversion of biomass and/or complex substrates into a target compound. Due to the great variety of microbial metabolism, especially in conjunction with chemical support-processes, a definite classification is often difficult. This can be expanded to the forms of nitrogen and energy that are available as input for a biomanufacturing platform. To provide a perspective on microbial cell factories that may be suitable for Space Systems Bioengineering, a high-level comparison of different approaches is conducted, specifically regarding advantages that may help to extend an early human foothold on the red planet.

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“…Electromicrobial production (EMP) could enable highly efficient production of carbon-neutral drop-in biofuels. EMP is a broadly-encompassing term for a group of technologies that aim to combine electricity and microbial metabolism for conversion of simple molecules like CO2, CO, HCOO -, and N2 into complex, energy dense molecules like food and biofuels [7][8][9][10][11][12][13][14][15][16] . EMP includes technologies like microbes that assimilate electrochemically-reduced CO2 like formate 14,17 ; H2-oxidizing, CO2-fixing systems like the Bionic Leaf 18,19 ; microbe-semiconductor hybrids 20 ; and microbes that can directly absorb electricity through processes like extracellular electron uptake (EEU) 8,21,22 .…”

Section: Introductionmentioning

confidence: 99%

Efficiency Estimates for Electromicrobial Production of Branched-chain Hydrocarbons

Sheppard

Specht

Barstow

2023

Preprint

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Electromicrobial production is a process where microorganisms use electricity as a charge and energy source for the production of complex molecules, often from starting compounds as simple as CO2. The aviation industry is in need for sustainable fuel alternatives that can meet their requirements of high-altitude performance while also meeting 21stcentury carbon emissions standards. The electromicrobial production of jet fuel components with CO2-derived carbon provides a unique opportunity to generate jet fuel blends that are compatible with modern engines with net-neutral carbon emissions. In this study, we analyze the pathways necessary to generate single- and multi-branched-chain hydrocarbonsin vivoutilizing both extracellular electron uptake (EEU) and H2-oxidation as methods for electron delivery, the Calvin cycle for CO2-fixation and the ADO decarboxylation pathway. We find the maximum electrical-to-fuel energy conversion efficiencies for single- and multi-branched chain hydrocarbons areand. Utilizing this information, as well as previously collected predictions on straight-chain alkane and terpenoid biosynthesis, we calculate the efficiency of electromicrobial production of jet fuel blends containing straight-chain, branched-chain, and terpenoid components. Increasing the fraction of branched-chain alkanes in the blend from zero to 47% only lowers the electrical energy conversion efficiency fromto.

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Systems-informed genome mining for electroautotrophic microbial production

Cited by 5 publications

References 86 publications

Genomically mined acoustic reporter genes for real-time in vivo monitoring of tumors and tumor-homing bacteria

Genomically mined acoustic reporter genes for real-time in vivo monitoring of tumors and tumor-homing bacteria

Choice of Microbial System for In-Situ Resource Utilization on Mars

Efficiency Estimates for Electromicrobial Production of Branched-chain Hydrocarbons

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