Synthesis Gas (Syngas)-Derived Medium-Chain-Length Polyhydroxyalkanoate Synthesis in Engineered Rhodospirillum rubrum

Heinrich, Daniel; Raberg, Matthias; Fricke, Philipp Moritz; Kenny, Shane T.; Morales-Gamez, Laura; Babu, Ramesh; O’Connor, Kevin E.; Steinbüchel, Alexander

doi:10.1128/aem.01744-16

Cited by 46 publications

(16 citation statements)

References 55 publications

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“…Secondly, R. rubrum can produce PHAs composed of both short-and medium-chain-length monomers, while most bacteria just produce PHAs that are either short chain (C 3 to C 5 ) or medium chain (C 6 to C 14 ) [22]. irdly, it can use a variety of different carbon sources, even the toxic gas CO which is the major components of syngas [23].…”

Section: Introductionmentioning

confidence: 99%

Poly(3-hydroxybutyrate-co-3-hydroxyvalerate) Production by Rhodospirillum rubrum Using a Two-Step Culture Strategy

Liu

Zhao

Diao

et al. 2019

Journal of Chemistry

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Polyhydroxyalkanoates (PHAs) are microbially synthesized biopolyesters which have attracted great attentions as a new biological material, potential alternative to traditional fossil fuel-based plastic due to their biodegradability and biocompatibility. Poly-3-hydroxybutyrate (PHB) and poly-(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) are the most common members of PHAs. In this study, the nonsulfur and facultatively phototrophic bacterium Rhodospirillum rubrum was cultivated to accumulate PHA by a two-step culture strategy. Gas chromatography (GC), gas chromatography-mass spectrometry (GC-MS), and nuclear magnetic resonance spectroscopy (NMR) analyses showed that PHAs synthesized from fructose was PHBV, in which the 3HV content was 46.5 mol%, which means the better mechanical property. The molecular weight, distribution, and thermal features were characterized by gel permeation chromatography (GPC), differential scanning calorimeter (DSC), and thermo gravimetric analysis (TGA), respectively. The low PDI of 1.08 revealed the narrow and evenly molar mass distribution which shows the stable features. The high melting temperature and their other physical properties implied their potential applications. The traditional process of producing PHBV involves related carbon sources such as valeric acid. However, our study clearly described a new medium formula with fructose and a complete fermentation method to produce PHBV with a high 3HV faction and low molecular distribution.

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Section: Introductionmentioning

confidence: 99%

Poly(3-hydroxybutyrate-co-3-hydroxyvalerate) Production by Rhodospirillum rubrum Using a Two-Step Culture Strategy

Liu

Zhao

Diao

et al. 2019

Journal of Chemistry

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“…To assess and enhance growth of R. eutropha H16 in CO-containing atmospheres, cells of the wild type and of recombinant strains were initially cultivated aerobically with 30% (by volume) of an artificial syngas mixture. This gas mixture consisted of (by volume) 40% CO, 40% H 2, 10% CO 2 and 10% N 2 , and resembled syngas compositions, which were previously used in academic studies and were actually obtained from gasification of biomass (Bridgewater, 1995;Heinrich et al, 2016;Revelles et al, 2016). To improve the utilization of syngas, of which CO is a major component, seven cox genes of O. carboxidovorans OM5 were heterologously expressed in R. eutropha H16.…”

Section: Resultsmentioning

confidence: 99%

Studies on the aerobic utilization of synthesis gas (syngas) by wild type and recombinant strains of Ralstonia eutropha H16

Heinrich

Raberg

Steinbüchel

2017

Microbial Biotechnology

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SummaryThe biotechnical platform strain Ralstonia eutropha H16 was genetically engineered to express a cox subcluster of the carboxydotrophic Oligotropha carboxidovorans OM5, including (i) the structural genes coxM, ‐S and ‐L, coding for an aerobic carbon monoxide dehydrogenase (CODH) and (ii) the genes coxD, ‐E, ‐F and ‐G, essential for the maturation of CODH. The cox Oc genes expressed under control of the CO 2‐inducible promoter PL enabled R. eutropha to oxidize CO to CO 2 for the use as carbon source, as demonstrated by 13 CO experiments, but the recombinant strains remained dependent on H2 as external energy supply. Therefore, a synthetic metabolism, which could be described as ‘carboxyhydrogenotrophic’, was established in R. eutropha. With this extension of the bacterium's substrate range, growth in CO‐, H2‐ and CO 2‐containing artificial synthesis gas atmosphere was enhanced, and poly(3‐hydroxybutyrate) synthesis was increased by more than 20%.

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“…Methanotrophic bacteria can remove a significant amount of methane, which has been applied in the production of materials and bioremediation in recent years . The gaseous substrate utilizers can utilize syngas to synthesize ethanol, acetate, 2,3‐butanediol, and PHA in bioprocessing . As gas is the only C‐source for those gaseous utilizers, there is a minor possibility of contamination during the process .…”

Section: Next‐generation Industrial Biotechnologymentioning

confidence: 99%

Next‐Generation Industrial Biotechnology‐Transforming the Current Industrial Biotechnology into Competitive Processes

Chen

2019

Biotechnology Journal

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The chemical industry has made a contribution to modern society by providing cost‐competitive products for our daily use. However, it now faces a serious challenge regarding environmental pollutions and greenhouse gas emission. With the rapid development of molecular biology, biochemistry, and synthetic biology, industrial biotechnology has evolved to become more efficient for production of chemicals and materials. However, in contrast to chemical industries, current industrial biotechnology (CIB) is still not competitive for production of chemicals, materials, and biofuels due to their low efficiency and complicated sterilization processes as well as high‐energy consumption. It must be further developed into “next‐generation industrial biotechnology” (NGIB), which is low‐cost mixed substrates based on less freshwater consumption, energy‐saving, and long‐lasting open continuous intelligent processing, overcoming the shortcomings of CIB and transforming the CIB into competitive processes. Contamination‐resistant microorganism as chassis is the key to a successful NGIB, which requires resistance to microbial or phage contaminations, and available tools and methods for metabolic or synthetic biology engineering. This review proposes a list of contamination‐resistant bacteria and takes Halomonas spp. as an example for the production of a variety of products, including polyhydroxyalkanoates under open‐ and continuous‐processing conditions proposed for NGIB.

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Synthesis Gas (Syngas)-Derived Medium-Chain-Length Polyhydroxyalkanoate Synthesis in Engineered Rhodospirillum rubrum

Cited by 46 publications

References 55 publications

Poly(3-hydroxybutyrate-co-3-hydroxyvalerate) Production by Rhodospirillum rubrum Using a Two-Step Culture Strategy

Poly(3-hydroxybutyrate-co-3-hydroxyvalerate) Production by Rhodospirillum rubrum Using a Two-Step Culture Strategy

Studies on the aerobic utilization of synthesis gas (syngas) by wild type and recombinant strains of Ralstonia eutropha H16

Next‐Generation Industrial Biotechnology‐Transforming the Current Industrial Biotechnology into Competitive Processes

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