The present invention provides engineered tyrosine ammonia-lyase (TAL) polypeptides and compositions thereof. In some embodiments, the engineered TAL polypeptides have been optimized to provide enhanced catalytic activity while reducing sensitivity to proteolysis and increasing tolerance to acidic pH levels. The invention also provides methods for utilization of the compositions comprising the engineered TAL polypeptides for therapeutic and industrial purposes.

The present invention is in the field of genetically modified enzyme and microorganism comprising such a modified enzyme for the production of raspberry ketone or zingerone. The modified enzyme is a polyketide synthase (PKS) issued or derived from a wild type PKS. The modified PKS has the capability to produce vanillylidene acetone from feruloyl-CoA and/or 4-hydroxybenzalacetone from 4-coumaroyl-CoA in a more effective way as compared to wild type BAS or wild type PmPKS, in particular in recombinant bacteria strains.

The present invention relates to the field of the production of phenylpropanoid compounds, especially that of genetically modified strains for the production of phenylpropanoid compounds. In particular, the invention relates to a genetically modified strain of Pseudomonas putida comprising a mutated AroF-I gene encoding 3-deoxy-D-arabino-heptulosonate-7-phosphate (DAHP), and to the use thereof for the synthesis of phenylpropanoid compounds, in particular coumaric acid or frambinone.

Aspects of the disclosure relate to aromatic amino acid ammonia lyases (ALs), phenylalanine ammonia lyases (PALs), and tyrosine ammonia lyase (TALs), including engineered enzymes, and their use in catalyzing chemical reactions.

The present invention relates to the field involved in the production of phenylbutanone or phenylbutanone derivative compounds, such as frambinone or zingerone, and in particular strains genetically modified to express a benzalacetone reductase.

Disclosed is a technique for constructing optogenetic amplifier and inverter circuits utilizing transcriptional activator/repressor pairs, in which expression of the transcriptional activator or repressor, respectively, is controlled by light-controlled transcription factors. This system is demonstrated utilizing the quinic acid regulon system from Neurospora crassa, or Q System, a transcriptional activator/repressor system. This is also demonstrated utilizing the galactose regulon from Saccharomyces cerevisiae, or GAL System. Such optogenetic amplifier circuits enable multi-phase microbial fermentations, in which different light schedules are applied in each phase to dynamically control different metabolic pathways for the production of proteins, fuels or chemicals. The orthogonal nature of the Q and GAL systems enable the co-expression of amplifier and inverter circuits to simultaneously amplify and invert the response of light-controlled transcriptional controls over different sets of genes in the same cell.