The present disclosure provides regulatable biocircuit systems. Such systems provide modular and tunable protein expression systems in support of the discovery and development of therapeutic modalities. In particular, the present application is directed to fusion proteins comprising a fragment of human human carbonic anhydrase 2 and a chimeric antigen receptor (CAR). The activity of the destabilizing domain can be regulated by externally administered agents.

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.

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 invention relates to Actinomycetales strains for the improved formation of acarbose. Provided are Actinomycetales strains which are engineered to overexpress dTDP-D-glucose-4,6-dehydratase (AcbB) and/or uridyltransferase (GtaB). Also provided are Actinomycetales strains which are engineered to have a reduced or absent expression of the small carbohydrate binding protein (Cgt) and/or a reduced or absent expression of genes which are essential for carotenoid synthesis. Also provided are tools, methods and means to generate these strains.

The present invention relates to Actinomycetales strains for the improved formation of acarbose. Provided are Actinomycetales strains which are engineered to overexpress dTDP-D-glucose-4,6-dehydratase (AcbB) and/or uridyltransferase (GtaB). Also provided are Actinomycetales strains which are engineered to have a reduced or absent expression of the small carbohydrate binding protein (Cgt) and/or a reduced or absent expression of genes which are essential for carotenoid synthesis. Also provided are tools, methods and means to generate these strains.

A microorganism is transformed to be capable of producing guanidinoacetic acid (GAA). A method can be used for the fermentative production of GAA using such a microorganism. A corresponding method can be used for the fermentative production of creatine.

The present invention provides a means for accurately discriminating whether an onion is an onion with no pungent taste and/or tear-inducing property. The present invention relates to a method of discriminating traits of an onion, comprising a first determination step of determining presence of the nucleotide sequence of SEQ ID NO:1 corresponding to alliinase gene 1 in a nucleic acid derived from the onion, and a second determination step of determining presence of the nucleotide sequence of SEQ ID NO:2 corresponding to alliinase gene 2, wherein the onion is discriminated to be an onion with no pungent taste and/or tear-inducing property if the presence of the nucleotide sequence of SEQ ID NO:1 is not determined in the first determination step and the presence of the nucleotide sequence of SEQ ID NO:2 is determined in the second determination step.

Provided is a method of producing and isolating a diamine produced by microbial fermentation that minimizes undesirable salt formation to provide a lower cost process.

Provided is a method of producing and isolating a diamine produced by microbial fermentation that minimizes undesirable salt formation to provide a lower cost process.

The present disclosure relates to genetically engineered host cells and methods of producing a lipid-derived compound by employing such host cells. In particular embodiments, the host cell includes a first mutant gene encoding a cytoplasmic tRNA thiolation protein. Optionally, the host cell can include other mutant genes for decreasing fatty alcohol catabolism, decreasing re-importation of secreted fatty alcohol, or displaying other useful characteristics, as described herein.