This invention is an improved method of robust and scalable production of precursors of active cannabinoids, including geranyl pyrophosphate (GPP) and/or cannabigerolic acid (CBGA), in a methylotrophic yeast host cell. The improved methods incorporate a polypeptide encoding an Erg20 variant (F98W/N128W) into a methylotrophic yeast host cell, for example Pichia pastoris (Komagataella phaffii), that biases the natural production of FPP and GPP towards GPP, a precursor to the intermediate CBGA, crucial to the synthesis of active cannabinoids.

The invention pertains to a method for synthesizing a product of interest by culturing a microalgal cell producing the product of interest in the dark in a culture medium comprising an organic acid as a fixed carbon source, wherein the microalgal cell is a facultative heterotroph. The product of interest can be a microalgal biomass, a pigment, terpene, recombinant molecule, biogas, or a precursor thereof. In an embodiment, the culture medium comprises urea as a primary source of nitrogen. In one embodiment, the microalgal cell belongs to the order Chlamydomonadales. A method of identifying and isolating a microalgal cell having a preferred characteristic that is suitable for synthesis of a product of interest is also provided, the method comprising identifying and isolating a non-mutagenized or recombinant microalgal cell from a microalgal culture using a fluorescence activated cell sorting technique and/or a phototaxic response.

The present invention relates to novel nucleic acid sequences encoding bacterial xylose isomerases that upon transformation of a eukaryotic microbial host cell, such as yeast, to confer to the host cell the ability of isomerising xylose to xylulose. The nucleic acid sequences encode xylose isomerases that originate from bacteria such as Eubacterium sp., Clostridium cellulosi and others. The invention further relates to fermentation processes wherein the transformed host cells ferment a xylose-containing medium to produce ethanol or other fermentation products.

The present disclosure relates to recombinant microorganisms having an improved ethylene producing ability, methods of producing the same, and methods of producing ethylene. A benefit of the recombinant microorganisms and the methods disclosed herein can include increased production of ethylene from microbial cultures. An additional benefit can be the use of carbon dioxide to produce bio-ethylene useful as a feedstock for the production of plastics, textiles, and chemical materials, and for use in other applications. Another benefit of the methods and systems disclosed herein can include reduction of excess carbon dioxide from the environment.

Methods for biosynthesising hydrocarbons from a gaseous substrate in non-naturally occurring acetogens as well as non-naturally occurring acetogens for production of hydrocarbons are provided.

The present application relates to recombinant microorganisms useful in the biosynthesis of monoethylene glycol (MEG) or glycolic acid (GA), or MEG and one or more co-product, from one or more pentose and/or hexose sugars. Also provided are methods of producing MEG (or GA), or MEG (or GA) and one or more co-product, from one or more pentose and/or hexose sugars using the recombinant microorganisms, as well as compositions comprising the recombinant microorganisms and/or the products MEG (or GA), or MEG and one or more co-product.

The disclosure relates to methods of capturing carbon by microbial fermentation of a gaseous substrate comprising CO into one or more first products which, in turn, may be incorporated into an article of manufacture or one or more second products. Further, the disclosure relates to improving carbon capture and/or efficiency.

Described herein are genetically-engineered organisms comprising synthetic operons for the production of isoprenoids, carotenoids, and retinoids, optimized for use in a hydrocarbonoclastic organism, and methods for the synthesis and extraction of isoprenoids in a biofilm bioreactor comprising the genetically-engineered organisms.

The invention provides non-natural microbial organisms containing enzymatic pathways and/or metabolic modifications for enhancing carbon flux through acetyl-CoA, or oxaloacetate and acetyl-CoA. Embodiments of the invention include microbial organisms having a pathway to acetyl-CoA and oxaloacetate that includes phosphoketolase (a PK pathway). The organisms also have either (i) a genetic modification that enhances the activity of the non-phosphotransferase system (non-PTS) for sugar uptake, and/or (ii) a genetic modification(s) to the organism's electron transport chain (ETC) that enhances efficiency of ATP production, that enhances availability of reducing equivalents or both. The microbial organisms can optionally include (iii) a genetic modification that maintains, attenuates, or eliminates the activity of a phosphotransferase system (PTS) for sugar uptake. The enhanced carbon flux through acetyl-CoA and oxaloacetate can be used for production of a bioderived compound, and the microbial organisms can further include a pathway capable of producing the bioderived compound.

The disclosure provides genetically engineered C1-fixing microorganisms capable of producing nanobodies. Additionally, the disclosure provides engineered microorganisms comprising one or more disrupted genes to strategically divert carbon flux away from nonessential or undesirable products towards products and/or co-products of interest. The disclosure enables co-production of useful chemicals from gaseous substrates.