A method and vectors for controlling blood glucose levels in a mammal are disclosed. In one embodiment, the method comprises the steps of: treating the hepatocyte cells of a patient with a first, second or third vector, wherein the first vector comprises a promoter enhancer, glucose inducible regulatory elements, a liver-specific promoter, a gene encoding human insulin with modified peptidase and an albumin 3′UTR and lacks an HGH intron, wherein the second vector comprises an HGH intron, glucose inducible regulatory elements, a liver-specific promoter, a gene encoding human insulin with modified peptidase site and an albumin 3′UTR and lacks a promoter enhancer, wherein the third vector comprises an HGH intron, glucose inducible regulatory elements, a liver-specific promoter, a gene encoding human insulin with modified peptidase site, an albumin 3′UTR and a promoter enhancer and observing the patient's insulin levels, wherein the patient's insulin levels are controlled.

A method and vectors for controlling blood glucose levels in a mammal are disclosed. In one embodiment, the method comprises the steps of: treating the hepatocyte cells of a patient with a first, second or third vector, wherein the first vector comprises a promoter enhancer, glucose inducible regulatory elements, a liver-specific promoter, a gene encoding human insulin with modified peptidase and an albumin 3′UTR and lacks an HGH intron, wherein the second vector comprises an HGH intron, glucose inducible regulatory elements, a liver-specific promoter, a gene encoding human insulin with modified peptidase site and an albumin 3′UTR and lacks a promoter enhancer, wherein the third vector comprises an HGH intron, glucose inducible regulatory elements, a liver-specific promoter, a gene encoding human insulin with modified peptidase site, an albumin 3′UTR and a promoter enhancer and observing the patient's insulin levels, wherein the patient's insulin levels are controlled.

Provided are genetically engineered induced pluripotent stem cells (iPSCs) and derivative cells thereof expressing a chimeric antigen receptor (CAR) and methods of using the same. Also provided are compositions, polypeptides, vectors, and methods of manufacturing.

Described are DNA molecules which can be transcribed into an mRNA harbouring novel UTR sequences combining the advantages of being extremely short and at the same time allowing for high translation efficiencies of RNA molecules containing them. Further, described are vectors comprising such a DNA molecule and to host cells comprising such a vector. Moreover, described are corresponding RNA molecules containing such UTRs. Further, described in a pharmaceutical composition comprising the described RNA molecule are optionally a pharmaceutically acceptable carrier as well as to the use of the described UTRs for translating a coding region of an RNA molecule into a polypeptide or a protein encoded by said coding region.

Provided is a polynucleotide the polynucleotide can be used as a WXRE transcriptional regulatory element used to increase the protein expression level of a protein expression system. A protein expression vector or a protein expression systems comprising the above-mentioned WXRE transcriptional regulatory element as well as the use thereof are also provided. The use of the WXRE transcriptional regulatory element can increase the expression level of a heterologous protein greatly with its biological activity unchanged.

Aspects of the disclosure relate to compositions and methods for treating hereditary hearing loss and/or vision loss, for example, due to Usher syndrome, Type 3A. In some embodiments, the disclosure provides a recombinant adeno-associated virus comprising: (i) an AAV-S capsid protein, and (ii) an isolated nucleic acid comprising a transgene (e.g., a transgene for expressing a clarin-1 protein). The present disclosure also provides methods of treating hereditary hearing loss and/or vision loss (e.g., Usher Syndrome, Type 3A) using the same.

The disclosure relates generally to bacteria that have been modified to have increased oxalate degrading activity, pharmaceutical compositions including the bacteria, and methods of treating disorders associated with an elevated amount of oxalate, e.g., hyperoxaluria.

A nucleic acid molecule including at least one expression control sequence having an Internal Ribosomal Entry Site (IRES) sequence, at least one coding region, and optionally multiple adenosines or thymidines upstream of the at least one expression control sequence is disclosed as an expression system. Besides, a recombinant expression vector including the nucleic acid molecule and pharmaceutical or medicinal use of the nucleic acid molecule are disclosed.

Provided herein are genetic circuits and encoded RNA transcripts that produce an output molecule in response to an RNA cleavage event that removes a degradation signal. In some embodiments, the genetic circuits described herein may be used for detecting RNA cleaver activities (e.g., in a cell). Methods of using the genetic circuits described herein in diagnostic or therapeutic applications are also provided.

Provided herein are nucleic acids, recombinant adeno-associated viral particles, compositions and methods related to treating Friedreich's ataxia. In some examples, the nucleic acids, recombinant adeno-associated viral particles, compositions and methods involve us of a FXN coding sequence, a truncated FXN 3′ UTR, and a prompter.