A bio-derived polymer matrix composite originating from a single wastewater stream and a method for the production of such bio-derived polymer matrix composites from a single wastewater stream are herein disclosed. The process disclosed allows production of both the bio-derived polymer matrix and the additive, the main constituents of the composite, at the same time from a unique wastewater stream source. In a preferred embodiment, this invention is applied but not limited to the production of a polyhydroxyalkanoate (PHA) composite from a single olive mill wastewater (OMW) stream. An application of such composites is represented by but not limited to the use as materials to make agricultural items.

The present invention relates to a process for extraction of bioplastic from bioplastic-producing microbial cells, comprising the steps of: A. providing bioplastic producing microbial cells comprising bioplastic; B. providing bacterial cells selected from the species Bacillus pumilus; C. extracting the bioplastic by admixing the bioplastic-producing microbial cells of step A and the bacterial cells of step B and allowing reaction. The present invention further relates to the process of producing monomers from said bioplastics by depolymerization.

The invention relates to a nano-biohybrid organism (or nanorg) comprising one of at least seven different core-shell quantum dots (QDs) or gold nanoparticle clusters, with excitations ranging from ultraviolet to near-infrared energies, couple with targeted enzyme sites in bacteria. When illuminated by light, these QDs drive the renewable production of biofuel molecules and chemicals using carbon-dioxide (CO.sub.2), water, and nitrogen (from air) as substrates. Nanorgs catalyze light-induced air-water-CO.sub.2 reduction with a high turnover number (TON) of approximately 10.sup.6-10.sup.8 (mols of product per mol of cells) to biofuels such as isopropanol (IPA), butane diol, gasoline additives, gasoline substitutes, 2,3-butanediol (BDO), C11-C15 methyl ketones (MKs), and hydrogen (H2); Sand chemicals such as formic acid (FA), ammonia (NH.sub.3), ethylene (C.sub.2H.sub.4), and degradable bioplastics, e.g. polyhydroxybutyrate (PHB). These nanorg cells function as nano-microbial factories powered by light.

The invention relates to a nano-biohybrid organism (or nanorg) comprising one of at least seven different core-shell quantum dots (QDs) or gold nanoparticle clusters, with excitations ranging from ultraviolet to near-infrared energies, couple with targeted enzyme sites in bacteria. When illuminated by light, these QDs drive the renewable production of biofuel molecules and chemicals using carbon-dioxide (CO.sub.2), water, and nitrogen (from air) as substrates. Nanorgs catalyze light-induced air-water-CO.sub.2 reduction with a high turnover number (TON) of approximately 10.sup.6-10.sup.8 (mols of product per mol of cells) to biofuels such as isopropanol (IPA), butane diol, gasoline additives, gasoline substitutes, 2,3-butanediol (BDO), C11-C15 methyl ketones (MKs), and hydrogen (H2); Sand chemicals such as formic acid (FA), ammonia (NH.sub.3), ethylene (C.sub.2H.sub.4), and degradable bioplastics, e.g. polyhydroxybutyrate (PHB). These nanorg cells function as nano-microbial factories powered by light.

Embodiments of the invention relate generally to methods to generate microorganisms and/or microorganism cultures that exhibit the ability to produce polyhydroxyalkanoates (PHA) from carbon sources at high efficiencies. In several embodiments, preferential expression of, or preferential growth of microorganisms utilizing certain metabolic pathways, enables the high efficiency PHA production from carbon-containing gases or materials. Several embodiments relate to the microorganism cultures, and/or microorganisms isolated therefrom.

Systems and methods are provided for cost effective biosynthesis of polyhydroxyalkanoates (PHA) that have desirable material properties similar to petrochemically derived plastics. Synthesis takes place intracellularly in extreme halophiles grown in saline conditions that selectively reduces contamination from other microbes. The industrial scale PHA production systems use low-cost organic waste feedstocks, spent medium treatment and recycling and enzyme recovery and reuse for efficiency and reduced cost compared to existing processes.

A protein hydrolysate composition derived from a microorganism, such as a chemoautotrophic microorganism, and methods of preparing and using the same are provided. The protein hydrolysate composition may be produced sustainably through fixation of carbon dioxide from biogenic or atmospheric sources. The protein hydrolysate composition finds use in supplementing culture media for serum-free culturing of animal cells as well as for growing other types of cells such as probiotics and lactic acid bacteria. Thus, the present disclosure provides sustainable, humane processes for culturing cells for pharmaceutical and nutraceutical application as well as for human consumption as a food ingredient or product, including cultured meat.

Provided a method for separating PHA and PHA prepared therefrom. The method comprises the following steps: subjecting a PHA fermentation broth to solid-liquid separation to obtain a thallus precipitate; breaking cell walls of the thallus precipitate, and subjecting obtained wall-broken products to a plate and frame filtration to obtain PHA; a filter cloth for the plate and frame filtration is pre-coated with a PHA layer. The method adopts a plate and frame separation to replace the traditional centrifugal separation to prepare PHA, and the PHA layer is pre-coated on the filter cloth for the plate and frame filtration, thereby overcome the defects in the prior art such as high cost and operational difficulty caused by adopting multiple centrifugal separations; in addition, the method of the present disclosure also exhibits the advantages of high recovery rate of PHA and high purity of the prepared PHA product.

Provided is a transformed microorganism that has a polyhydroxyalkanoate synthase gene and in which expression of a minD gene is enhanced. Also provided is a transformed microorganism that has a polyhydroxyalkanoate synthase gene and in which expression of a minC gene and a minD gene is enhanced. In this transformed microorganism, expression of a minE gene may be enhanced or reduced. Also provided is a method of producing a PHA, the method including the step of culturing any of the transformed microorganisms in the presence of a carbon source.

A process for bio-1,3-butanediol purification from a fermentation broth includes the steps of: (a) subjecting the fermentation broth to separation, (b) subjecting the product obtained in step (a) to treatment with ion-exchange resins, (c) subjecting the product obtained in step (b) to a first evaporation, (d) subjecting the product obtained in step (c) to a second evaporation; and (e) subjecting the product obtained in step (d) to a third evaporation, obtaining purified bio-1,3-butanediol. The purified bio-1,3-butanediol can be used to produce bio-1,3-butadiene. Bio-1,3-butadiene can be used as a monomer or as an intermediate to produce elastomers and (co)polymers.