Exploiting microbial hyperthermophilicity to produce an industrial chemical, using hydrogen and carbon dioxide

Abstract: Microorganisms can be engineered to produce useful products, including chemicals and fuels from sugars derived from renewable feedstocks, such as plant biomass. An alternative method is to use low potential reducing power from nonbiomass sources, such as hydrogen gas or electricity, to reduce carbon dioxide directly into products. This approach circumvents the overall low efficiency of photosynthesis and the production of sugar intermediates. Although significant advances have been made in manipulating microor… Show more

“…The resulting PCR products were digested with AscI and SphI, and then ligated into plasmid pGL007 (14) to make plasmids pMB403SLP and pMB404SLP. Plasmid pMB407SLP for construction of strain A ( Fig.…”

“…P. furiosus was recently metabolically engineered to generate end products other than acetate in a temperature-controlled manner without the need for chemical inducers. Lactate was produced from glucose, and 3-hydroxypropionate was produced from carbon dioxide and glucose, using heterologously expressed enzymes encoded by foreign genes obtained from microbes that grow near 75°C (13,14). At 98°C, the foreign enzymes were inactive and the engineered P. furiosus strains generated acetate, but near 70°C, the engineered strains produced either lactate or 3-hydroxypropionate instead.…”

Single gene insertion drives bioalcohol production by a thermophilic archaeon

“…The resulting PCR products were digested with AscI and SphI, and then ligated into plasmid pGL007 (14) to make plasmids pMB403SLP and pMB404SLP. Plasmid pMB407SLP for construction of strain A ( Fig.…”

“…P. furiosus was recently metabolically engineered to generate end products other than acetate in a temperature-controlled manner without the need for chemical inducers. Lactate was produced from glucose, and 3-hydroxypropionate was produced from carbon dioxide and glucose, using heterologously expressed enzymes encoded by foreign genes obtained from microbes that grow near 75°C (13,14). At 98°C, the foreign enzymes were inactive and the engineered P. furiosus strains generated acetate, but near 70°C, the engineered strains produced either lactate or 3-hydroxypropionate instead.…”

Single gene insertion drives bioalcohol production by a thermophilic archaeon

“…Hereto, in recent years a few attempts have been made, such as the introduction of the complete natural 3‐hydroxypropionate bi‐cycle in Escherichia coli by the Silver laboratory, which did not yet yield a completely functional pathway (Mattozzi et al ., 2013). In the Adams laboratory, a section of the natural 3‐hydroxypropionate/4‐hydroxybutyrate cycle was successfully introduced in the heterotrophic thermophile Pyrococcus furiosus ; however, this short section is insufficient to support complete autotrophic growth (Keller et al ., 2013). …”

A warm welcome for alternative CO₂ fixation pathways in microbial biotechnology

“…Each sub-pathway was found to be functional, which provided a basis for the potential synthesis of CO2-fixing E. coli. In the same year, Keller et al expressed a part of the 3-hydroxypropionate/4-hydroxybutyrate cycle from the archaea Metallosphaera sedula (optimum growth temperature of 73°C) in another archaea Pyrococcus furiosus (optimum growth temperature of 100°C) (Keller et al, 2013). This engineered strain can synthesize a valuable industrial chemical, 3-hydroxypropionic acid, from CO2, using hydrogen as the energy source.…”

Synthetic biology for CO2 fixation