Provided herein are methods of treating a subject having a disease or disorder associated with a PAH gene mutation. The methods generally comprise administering to the subject a therapeutically effective does of a recombinant adeno-associated virus (rAAV) that can express a phenylalanine hydroxylase (PAH) polypeptide in a cell and thereby restore PAH gene function in the subject.

Provided herein are adeno-associated virus (AAV) compositions that can restore phenylalanine hydroxylase (PAH) gene function in cell. Also provided are methods of use of the AAV compositions, and packaging systems for making the AAV compositions.

This disclosure relates to mRNA therapy for the treatment of hyperphenylalaninemias such as phenylketonuria (PKU). mRNAs for use in the invention, when administered in vivo, encode human phenylalanine hydroxylase (PAH), functional fragments thereof (e.g., those comprising the catalytic domain or the catalytic domain and the tetramerization domains), and fusion proteins comprising PAH. mRNAs of the invention are preferably encapsulated in lipid nanoparticles (LNPs) to effect efficient delivery to cells and/or tissues in subjects, when administered thereto. mRNA therapies of the invention increase and/or restore deficient levels of PAH expression and/or activity in subjects. mRNA therapies of the invention further decrease abnormal accumulation of phenylalanine associated with deficient PAH activity in subjects.

Described herein are recombinant microbial host cells comprising biosynthetic pathways and their use in producing oxidation products and downstream products, e.g., melatonin and related compounds, as well as enzyme variants, nucleic acids, vectors and methods useful for preparing and using such cells. In specific aspects, the present invention relates to monooxygenases, e.g., amino acid hydroxylases, with a modified cofactor-dependency, and to enzyme variants and microbial cells providing for an improved supply of cofactors.

Described herein are recombinant microbial host cells comprising biosynthetic pathways and their use in producing oxidation products and downstream products, e.g., melatonin and related compounds, as well as enzyme variants, nucleic acids, vectors and methods useful for preparing and using such cells. In specific aspects, the present invention relates to monooxygenases, e.g., amino acid hydroxylases, with a modified cofactor-dependency, and to enzyme variants and microbial cells providing for an improved supply of cofactors.

Described herein are recombinant microbial host cells comprising biosynthetic pathways and their use in producing oxidation products and downstream products, e.g., melatonin and related compounds, as well as enzyme variants, nucleic acids, vectors and methods useful for preparing and using such cells. In specific aspects, the present invention relates to monooxygenases, e.g., amino acid hydroxylases, with a modified cofactor-dependency, and to enzyme variants and microbial cells providing for an improved supply of cofactors.

This invention provides a range of translatable messenger UNA (mUNA) molecules. The mUNA molecules can be translated in vitro and in vivo to provide an active polypeptide or protein, or to provide an immunization agent or vaccine component. The mUNA molecules can be used as an active agent to express an active polypeptide or protein in cells or subjects. Among other things, the mUNA molecules are useful in methods for treating rare diseases.

A lentiviral vector system for expressing a lentiviral particle is disclosed. The lentiviral vector system includes a therapeutic vector. The lentiviral vector system produces a lentiviral particle for upregulating PAH expression in the cells of a subject afflicted with phenylketonuria (PKU).

Disclosed herein are compositions comprising adipogenic cells that are useful for the treatment, prevention, or amelioration of diseases or disorders.

This disclosure provides vectors and strategies for increasing the efficiency of gene therapy in hepatocytes. The efficiency of the delivery of a corrected gene or wild type gene is improved through the use of delivery to hepatocytes via intrahepatic (parenchyma) administration or administration via the portal vein. In addition, the corrected gene or wild type gene is delivered using an isolated exogenous nucleic acid comprising a promoter that is specifically expressed in hepatocytes. These methods and isolated exogenous nucleic acids are useful to correct gene defects in the liver such as inherited diseases of the liver.