The present disclosure relates to the production of cannabinoids in yeast. In as aspect there is provided a genetically modified yeast comprising: one or more GPP producing genes and optionally, one or more GPP pathway genes; two or more olivetolic acid producing genes; one or more cannabinoid precursor or cannabinoid producing genes; one or more Hexanoyl-CoA producing genes, and at least 5% dry weight of fatty acids or fats.

Described are compositions and methods relating to yeast having a genetic mutation that results in decreased amounts of Cdc42 effector proteins, resulting in increased alcohol and lysine production. Such yeast is well-suited for use commercial alcohol production to increase yields and to increase the value of Such yeast is well-suited for use commercial alcohol production to increase yields and to increase the value of amino-acid-containing, fermentation-co-products.

The present invention relates to the fields of genetic engineering and fermentation engineering, and provides a Candida utilis double gene co-expression strain for hydrolyzing protein components in kitchen waste, in which the Candida utilis double gene co-expression strain is constructed by integrating carboxypeptidases and endoprotease genes through a Candida utilis expression vector onto a Candida utilis genome. The present invention further provides a Candida utilis double gene co-expression strain capable of degrading kitchen waste, specifically degrading the protein components in the kitchen waste, and decomposing and transforming the proteins into small peptides and amino acids.

Disclosed herein are recombinant host cells and methods capable of producing a tyramine containing hydroxycinnamic acid amide compounds, derivatives and extracts. Some embodiments provided include, for example, consumable products containing the tyramine containing hydroxycinnamic acid amide produced by the recombinant host cells. Some embodiments provided herein are methods for producing a tyramine containing hydroxycinnamic acid amide or hydroxycinnamic acid amide derivative.

Characterization of the binding dynamics at the interface between any two proteins that specifically interact plays a role in myriad biomedical applications. The methods disclosed herein provide for the high-throughput characterization of the specific interaction at the interface between two protein binding partners and the identification of functionally significant mutations of one or both protein binding partners. For example, the methods disclosed herein may be useful for epitope and paratope mapping of an antibody-antigen pair, which is useful for the discovery and development of novel therapies, vaccines, diagnostics, among other biomedical applications.

The disclosure discloses a genetically engineered strain for producing porcine myoglobin and fermentation and purification thereof, and belongs to the technical field of genetic engineering. The disclosure realizes efficient secretion and expression of porcine myoglobin by integrating the gene of porcine myoglobin in P. pastoris. On this basis, optimization of the medium and culture conditions of recombinant P. pastoris can significantly increase the titer of porcine myoglobin, so that the titer can reach 285.42 mg/L under fermenter conditions. In addition, by creatively adding different concentrations of ammonium sulfate to fermentation broth step by step, the purity of myoglobin obtained by final concentration is up to 88.0%, and the purification rate is up to 66.1%. The disclosure realizes efficient expression and high purification of porcine myoglobin from various steps such as synthesis, fermentation and purification of porcine myoglobin, and provides broad prospects for industrial production of porcine myoglobin.

The present inventors confirmed that when a brazzein expression recombinant vector for high expression of brazzein in Saccharomyces cerevisiae was prepared and a S. cerevisiae strain Y2805 was transformed with the recombinant vector, the expression level of brazzein was particularly high, thereby completing an optimal expression system for mass-producing brazzein. Further, when the brazzein expression system is cultured under the optimal culture conditions according to the present invention, the amount of brazzein produced is further increased, the purification process is simple, and costs are reduced. Therefore, it is expected that the brazzein expression system according to the present invention can be widely used for mass-producing and commercializing brazzein, which is a sweet protein.

Characterization of the binding dynamics at the interface between any two proteins that specifically interact plays a role in myriad biomedical applications. The methods disclosed herein provide for the high-throughput characterization of the specific interaction at the interface between two protein binding partners and the identification of functionally significant mutations of one or both protein binding partners. For example, the methods disclosed herein may be useful for epitope and paratope mapping of an antibody-antigen pair, which is useful for the discovery and development of novel therapies, vaccines, diagnostics, among other biomedical applications.

Provided herein are methods of using a nucleic acid construct as a selectable marker. The nucleic acid construct comprises an isolated β-galactosidase expression cassette comprising a nucleic acid sequence encoding the amino-terminal fragment of β-galactosidase operably linked to a promoter. Also provided are isolated vectors comprising the β-galactosidase expression cassette, methods of generating the isolated vector, and kits comprising the isolated vector.

Provided herein are membrane enveloped virus-like particles (VLPs), and methods of use and synthesis thereof. In particular, yeast-cell-derived VLPs are provided that comprise surface-displayed glycoproteins and/or multiple virally-derived proteins.