This invention relates to the bioproduction of substituted or unsubstituted phenylacetaldehyde, 2-phenylethanol, phenylacetic acid or phenylethylamine by subjecting a starting material comprising glucose, L-phenylalanine, substituted L-phenylalanine, styrene or substituted styrene to a plurality of enzyme catalyzed chemical transformations in a one-pot reaction system, using recombinant microbial cells overexpressing the enzymes. To produce phenylacetaldehyde from styrene, the cells are modified to overexpress styrene monooxygenase (SMO) and styrene oxide isomerase (SOI). To produce phenylacetic acid from styrene, SMO, SOI and aldehyde dehydrogenase are overexpressed. Alternatively, to produce 2-phenylethanol, SMO, SOI and aldehyde reductase or alcohol dehydrogenase are overexpressed, while to produce phenylethylamine, SMO, SOI and transaminase are overexpressed.

Provided is a microorganism that is able to produce 2-phenylethanol at a high concentration, and a method of efficiently producing 2-phenylethanol by using a saccharide as a raw material.

Provided is a coryneform bacterium transformant in which a shikimate pathway is activated, and further, a gene that encodes an enzyme having phenylpyruvate decarboxylase activity is introduced in such a manner that the gene can be expressed.

Also provided is a 2-phenylethanol producing method that includes causing the coryneform bacterium transformant according to the present disclosure to react in water containing a saccharide.

The present invention relates to a recombinant strain for producing shikimic acid, in which a target gene that regulates the asymmetric cell division and target genes that regulate the shikimic acid production are expressed The target gene that regulates the asymmetric cell division includes cytoskeletal protein PopZ coding gene popZ, and the target genes that regulate the shikimic acid production include DAHP synthase coding gene aroG, 3-dehydroquinate synthase coding gene aroB, and transketolase coding gene tktA. The recombinant strain of the present invention realizes the de novo synthesis of shikimic acid using glucose as a substrate, with a low cost. After fermentation with the strain in a 7.5 L fermentor, the highest production of shikimic acid is 88.1 g/L, the yield is 0.33 g/g, and the production intensity of shikimic acid is 1.1 g/L/h.

A method of producing para-hydroxybenzoic acid (pHBA) or a derivative thereof includes culturing the recombinant microorganism in a fermentation broth, wherein said recombinant microorganism comprising a genetically engineered pathway expressing at least one nucleic acid sequence encoding a polypeptide selected from: an exogenous chorismate pyruvate lyase of EC 5.4.4.2 or EC 4.1.3.40; an exogenous 3-deoxy-D-arabino-heptulosonate-7-phosphate (DAHP) synthase of EC 4.1.2.15, or EC 2.5.1.54; an exogenous shikimate kinase of EC 2.7.1.71; or an exogenous 3-dehydroquinate dehydratase (DHQ) of EC 4.2.1.10; adding a carbon source to the fermentation broth; and isolating the pHBA from the fermentation broth.

Disclosed herein are methods for production of 2-phenylethanol by microbial fermentation of substrates comprising carbon monoxide and/or carbon dioxide and further disclosed are genetically modified microorganisms for use in such methods. Additionally, the processes disclosed herein are improved methods of 2-PE production that alleviate dependence on natural and petrochemical processes.

The present disclosure describes the engineering of microbial cells for fermentative production of tyramine and provides novel engineered microbial cells and cultures, as well as related tyramine production methods.

Provided are compositions and methods for compound discovery. Modified yeast that have their endogenous yeast shikimate pathway disrupted or deleted, and replaced with homologous pathway genes from one or more distinct organisms, are provided and used in assays of test agents. The homologous pathway genes are designed to supplement the disrupted or deleted shikimate pathway genes. The assays are designed to identify whether or not the test agents can interfere with the function of enzymes in the shikimate pathway from organisms that are distinct from the yeast avatar hosts. In embodiments, the disruption/deletion of the yeast endogenous shikimate pathway results in the yeast being incapable of producing chorismic acid.

This invention relates to the bioproduction of substituted or unsubstituted phenylacetaldehyde, 2-phenylethanol, phenylacetic acid or phenylethylamine by subjecting a starting material comprising glucose, L-phenylalanine, substituted L-phenylalanine, styrene or substituted styrene to a plurality of enzyme catalyzed chemical transformations in a one-pot reaction system, using recombinant microbial cells overexpressing the enzymes. To produce phenylacetaldehyde from styrene, the cells are modified to overexpress styrene monooxygenase (SMO) and styrene oxide isomerase (SOI). To produce phenylacetic acid from styrene, SMO, SOI and aldehyde dehydrogenase are overexpressed. Alternatively, to produce 2-phenylethanol, SMO, SOI and aldehyde reductase or alcohol dehydrogenase are overexpressed, while to produce phenylethylamine, SMO, SOI and transaminase are overexpressed.

The present disclosure describes the engineering of microbial cells for fermentative production of tyramine and provides novel engineered microbial cells and cultures, as well as related tyramine production methods.

Provided are compositions and methods for compound discovery. Modified yeast that have their endogenous yeast shikimate pathway disrupted or deleted, and replaced with homologous pathway genes from one or more distinct organisms, are provided and used in assays of test agents. The homologous pathway genes are designed to supplement the disrupted or deleted shikimate pathway genes. The assays are designed to identify whether or not the test agents can interfere with the function of enzymes in the shikimate pathway from organisms that are distinct from the yeast avatar hosts. In embodiments, the disruption/deletion of the yeast endogenous shikimate pathway results in the yeast being incapable of producing chorismic acid.