Production of biopolymer precursors beta-alanine and L-lactic acid from CO2 with metabolically versatile Rhodococcus opacus DSM 43205

Salusjärvi, Laura; Ojala, Leo; Peddinti, Gopal; Lienemann, Michael; Jouhten, Paula; Pitkänen, Juha-Pekka; Toivari, Mervi

doi:10.3389/fbioe.2022.989481

Cited by 9 publications

(4 citation statements)

References 71 publications

(98 reference statements)

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“…One novel approach for regenerating reducing power could be supplementing Rhococcus cultures with hydrogen (perhaps from a hydrogen-producing microorganism). Our results con rm expression and differential oxidation of a cytoplasmic [NiFe(Se)]hydrogenase [75][76][77].…”

Section: Discussionsupporting

confidence: 69%

A Redox Proteomics Approach for Decoding Lignin to Lipid Conversion by Rhodococci

Li,

Gluth,

Feng

et al. 2023

Preprint

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Background: Rhodococciare studied for their bacterial ligninolytic capabilities and proclivity to accumulate lipids. Lignin utilization is a resource intensive process requiring a variety of redox active enzymes and cofactors. Studying both protein abundance and regulation helps decode the metabolic rewiring that stymies lignin to lipid conversion in these bacteria. Herein, a redox proteomics approach was applied to investigate a fundamental driver of carbon catabolism and lipid anabolism: redox balance. Results: In this study, the importance of redox balance as it relates to nutrient availability is demonstrated from an unique angle by employing a modified bottom-up proteomics workflow to acquire a general relationship between protein abundance and protein redox states. In support of this, a previously demonstrated consortium of Rhodococcus strains was grown on glucose vs. lignin under nitrogen limitation, which is generally conducive to lipid accumulation. Global proteomics results affirm downregulation of enzymes involved in sugar catabolism and upregulation of those involved in lignin degradation and aromatics catabolism compared to glucose-fed cultures. Several enzymes in the lipid biosynthetic pathways were downregulated, whereas many involved in β-oxidation were upregulated. Interestingly, proteins involved in oxidative stress response were also upregulated perhaps in response to lignin degradation and aromatics catabolism, which require oxygen and reactive oxygen species. Enzymes displaying little-to-no change in abundance but differences in protein cysteine oxidation (i.e. redox state) were observed in various pathways for carbon utilization (e.g., β‑ketoadipate pathway), fatty acid and lipid metabolism, as well as nitrogen metabolism (e.g., purine scavenging/synthesis), suggesting potential redox-dependent regulation beyond protein expression. Conclusions: Efficient lipid production requires a steady carbon and energy flux while balancing fundamental requirements for enzyme production and cell maintenance. For lignin, we theorize that this balance is difficult to establish due to resource expenditure for enzyme production and oxidative stress response. This is supported by significant changes to protein abundances and protein cysteine oxidation in various pathways.

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Section: Discussionsupporting

confidence: 69%

A Redox Proteomics Approach for Decoding Lignin to Lipid Conversion by Rhodococci

Li,

Gluth,

Feng

et al. 2023

Preprint

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“…R. ruber C208 and R. erythropolis DCL14 can degrade solid polyolefins and paraffin wax, respectively (16)(17)(18). R. opacus MR11 encodes a functional Calvin-Benson-Bassham cycle and a hydrogenase cluster that enables fully autotrophic growth (19), and several plant-associated R. qingshengii isolates either produce plant growth regulators or fix inorganic nitrogen (20,21). Importantly, these genera are easily maintained in the laboratory under aerobic and mesophilic conditions, and they do not require specialized growth media nor handling precautions.…”

Section: Introductionmentioning

confidence: 99%

A modular toolkit for environmentalRhodococcus, Gordonia, andNocardiaenables complex metabolic manipulation

Jansen,

Alameri,

Wei

et al. 2024

Preprint

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Soil-dwelling Actinomycetes are a diverse and ubiquitous component of the global microbiome, but largely lack genetic tools comparable to those available in model species such asE. coliorPseudomonas putida, posing a fundamental barrier to their characterization and utilization as hosts for biotechnology. To address this, we have developed a modular plasmid assembly framework along with a series of genetic control elements for the previously genetically intractable Gram-positive environmental isolateRhodococcus ruberC208 and demonstrate conserved functionality in diverse environmental isolates ofRhodococcus, NocardiaandGordonia. This toolkit encompasses Mycobacteriale origins of replication, broad-host range antibiotic resistance markers, transcriptional and translational control elements, fluorescent reporters, a tetracycline-inducible system, and a counter-selectable marker. We use this toolkit to interrogate the carotenoid biosynthesis pathway inRhodococcus erythropolisN9T-4, a weakly carotenogenic environmental isolate and engineer higher pathway flux towards the keto-carotenoid canthaxanthin. This work establishes several new genetic tools for environmental Mycobacteriales and provides a synthetic biology framework to support the design of complex genetic circuits in these species.IMPORTANCESoil-dwelling Actinomycetes, particularly the Mycobacteriales, include both diverse new hosts for sustainable biomanufacturing and emerging opportunistic pathogens.Rhodococcus, GordoniaandNocardiaare three abundant genera with particularly flexible metabolisms and untapped potential for natural product discovery. Among these,Rhodococcus ruberC208 was shown to degrade polyethylene,Gordonia paraffinivoranscan assimilate carbon from solid hydrocarbons, andNocardia neocaledoniensis(and many otherNocardia) possesses dual isoprenoid biosynthesis pathways. Many species accumulate high levels of carotenoid pigments, indicative of highly active isoprenoid biosynthesis pathways which may be harnessed for fermentation of terpenes and other commodity isoprenoids. Modular genetic toolkits have proven valuable for both fundamental and applied research in model organisms, but such tools are lacking for most Actinomycetes. Our suite of genetic tools and DNA assembly framework were developed for broad functionality and to facilitate rapid prototyping of genetic constructs in these organisms.

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“…Such in situ water electrolysis mitigates the mass transfer limitation of hydrogen gas to the medium ( Nangle et al, 2017 ). Utilizing genetically engineerable HOB (e.g., Cupriavidus necator H16 and Rhodococcus opacus DSM 43205) offers significant flexibility to the system and expands the range of possible products ( Liu et al, 2016 ; Nyyssölä et al, 2021 ; Salusjärvi et al, 2022 ). To date, HBI systems have successfully produced chemicals including biofuels, fatty acids, biopolymers (and their precursors), biofertilizers, and dietary compounds ( Torella et al, 2015 ; Liu et al, 2016 ; Brigham, 2019 ; Nyyssölä et al, 2021 ; Salusjärvi et al, 2022 ; Wu et al, 2022 ).…”

Section: Introductionmentioning

confidence: 99%

“…Utilizing genetically engineerable HOB (e.g., Cupriavidus necator H16 and Rhodococcus opacus DSM 43205) offers significant flexibility to the system and expands the range of possible products (Liu et al, 2016;Nyyssölä et al, 2021;Salusjärvi et al, 2022). To date, HBI systems have successfully produced chemicals including biofuels, fatty acids, biopolymers (and their precursors), biofertilizers, and dietary compounds (Torella et al, 2015;Liu et al, 2016;Brigham, 2019;Nyyssölä et al, 2021;Salusjärvi et al, 2022;Wu et al, 2022). However, for this technology to be a viable option for CO 2 utilization, it is necessary to improve its energy and economic efficiencies.…”

Section: Introductionmentioning

confidence: 99%

Enrichment of halotolerant hydrogen-oxidizing bacteria and production of high-value-added chemical hydroxyectoine using a hybrid biological–inorganic system

Feng,

Kazama,

et al. 2023

Front. Microbiol.

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Hybrid biological–inorganic (HBI) systems show great promise as CO2 conversion platforms combining CO2 fixation by hydrogen-oxidizing bacteria (HOB) with water splitting. Herein, halotolerant HOB were enriched using an HBI system with a high-ionic-strength medium containing 180 mM phosphate buffer to identify new biocatalysts. The reactors were inoculated with samples from saline environments and applied with a voltage of 2.0 V. Once an increase in biomass was observed with CO2 consumption, an aliquot of the medium was transferred to a new reactor. After two successive subcultures, Achromobacter xylosoxidans strain H1_3_1 and Mycolicibacterium mageritense strain H4_3_1 were isolated from the reactor media. Genome sequencing indicated the presence of genes for aerobic hydrogen-oxidizing chemolithoautotrophy and synthesis of the compatible solute hydroxyectoine in both strains. Furthermore, both strains produced hydroxyectoine in the reactors under the high-ionic-strength condition, suggesting the potential for new HBI systems using halotolerant HOB to produce high-value-added chemicals.

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Production of biopolymer precursors beta-alanine and L-lactic acid from CO2 with metabolically versatile Rhodococcus opacus DSM 43205

Cited by 9 publications

References 71 publications

A Redox Proteomics Approach for Decoding Lignin to Lipid Conversion by Rhodococci

A Redox Proteomics Approach for Decoding Lignin to Lipid Conversion by Rhodococci

A modular toolkit for environmentalRhodococcus, Gordonia, andNocardiaenables complex metabolic manipulation

Enrichment of halotolerant hydrogen-oxidizing bacteria and production of high-value-added chemical hydroxyectoine using a hybrid biological–inorganic system

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