Provided are efficient catalyst of engineered enzymes and an economical enzymatic reaction solution to solve the problems in the current production process of L-tyrosine and its derivatives. The method of the invention has the advantages of high product concentration, mild reaction conditions, simple purification process, simple operation, environmental friendliness, and easy industrial scale-up. Thus, it has good industrial application prospects.

Certain embodiments provide a method for preparing a biochemical product (e.g., phenol, catechol, or muconic acid, or a salt thereof). For example, such methods include contacting a recombinant host having two or more recombinant pathways with a fermentable carbon source and growing the recombinant cell for a time sufficient to synthesize the product. In certain embodiments, each recombinant pathway: 1) is capable of producing the same final biochemical product; 2) comprises at least one gene encoding a polypeptide; 3) is derived from a different endogenous metabolite as its immediate precursor; and 4) converges to the same final product or the same intermediate metabolite.

The present disclosure is directed to methods for proteome engineering cells such that cell-free extracts prepared from such engineered cells can be modified to have metabolic flux directed to a metabolism of interest. In addition, methods for producing cell-free extracts with directed metabolism, cell-free extracts and kits that contain cell-free extracts are also disclosed.

The present disclosure discloses a production method of Danshensu, belonging to the technical field of bioengineering. The present disclosure constructs a novel genetic engineering strain co-expressed by three enzymes, which can be applied to the production of optically pure 3-(3,4-dihydroxyphenyl)-2-hydroxypropionic acid. All of the (D/L)--hydroxycarboxylic acid dehydrogenase selected by the present disclosure have the characteristics of poor substrate specificity and strong optical specificity, and can produce optically pure D-danshensu and L-danshensu. Further, the production efficiency of the recombinant strain is improved by knocking out or enhancing the expression of a related gene on the E. coli genome to promote substrate transport and reduce product decomposition. The method for producing Danshensu and -ketoglutaric acid by using the transformation of the recombinant strain according to the present disclosure is simple, has easily available raw materials, few impurities, and has good industrial application prospects.

Certain embodiments provide a method for preparing a biochemical product (e.g., phenol, catechol, or muconic acid, or a salt thereof). For example, such methods include contacting a recombinant host having two or more recombinant pathways with a fermentable carbon source and growing the recombinant cell for a time sufficient to synthesize the product. In certain embodiments, each recombinant pathway: 1) is capable of producing the same final biochemical product; 2) comprises at least one gene encoding a polypeptide; 3) is derived from a different endogenous metabolite as its immediate precursor; and 4) converges to the same final product or the same intermediate metabolite.

The present disclosure discloses a production method of Danshensu, belonging to the technical field of bioengineering. The present disclosure constructs a novel genetic engineering strain co-expressed by three enzymes, which can be applied to the production of optically pure 3-(3,4-dihydroxyphenyl)-2-hydroxypropionic acid. All of the (D/L)--hydroxycarboxylic acid dehydrogenase selected by the present disclosure have the characteristics of poor substrate specificity and strong optical specificity, and can produce optically pure D-danshensu and L-danshensu. Further, the production efficiency of the recombinant strain is improved by knocking out or enhancing the expression of a related gene on the E. coli genome to promote substrate transport and reduce product decomposition. The method for producing Danshensu and -ketoglutaric acid by using the transformation of the recombinant strain according to the present disclosure is simple, has easily available raw materials, few impurities, and has good industrial application prospects.

The present invention provides a method for producing an aromatic compound such as salicylic acid and a derivative thereof with high productivity using a microorganism. The present invention provides: a method for producing a microorganism having a sugar metabolic pathway modified, including suppressing the expression of a gene encoding a phosphotransferase system enzyme of the microorganism, suppressing the expression of a gene encoding pyruvate kinase of the microorganism, and introducing, into the microorganism, one or more genes encoding an enzyme that enables the microorganism to synthesize an aromatic compound from chorismic acid or isochorismic acid; a modified microorganism obtained by the method; and a method for producing an aromatic compound and a derivative thereof, including culturing the microorganism, and recovering an aromatic compound or the like from the culture.

Provided are efficient catalyst of engineered enzymes and an economical enzymatic reaction solution to solve the problems in the current production process of L-tyrosine and its derivatives. The method of the invention has the advantages of high product concentration, mild reaction conditions, simple purification process, simple operation, environmental friendliness, and easy industrial scale-up. Thus, it has good industrial application prospects.