The invention provides inducible promoter systems and their components incorporating components of a tetracycline operon. By coordinating expression of different transcriptional units in these systems as a result of selection of promoters and/or linking the units into the same DNA molecule, these systems can achieve higher levels of expression of coding segments of interest, increased differential levels of expression between on- and off-states, and/or greater responsiveness to inducing agents than conventional systems.

The present invention relates to methods and compositions for treating, ameliorating or preventing a disease or disorder in a subject by introducing into cells of the subject a therapeutic gene switch construct that controls expression of one or more therapeutic products.

A self-regulating gene expression construct comprises a single promoter in operative association with a repressor sequence (e.g., bacterial repressor lacI or gaiR), operator sequence(s) responsive to the expressed repressor protein, and a transgene. A dual-regulating construct comprises a single promoter controlling expression of a bacterial repressor sequence and a transgene, and which, in the presence of a first inducer molecule, transcribes the transgene and repressor; and a ribozyme in association with an aptamer sequence, the aptamer sequence capable of interacting with a second inducer molecule to terminate mRNA degradation by the ribozyme. Also provided are recombinant vectors or viruses containing the self-regulating or dual self-regulating constructs and cells containing the vectors. Such compositions are useful in methods of treating a diseases using gene therapy.

This invention generally relates to a composition and method of using recombinant microRNAs (miRNA) and their hairpin-like precursors (pre-miRNA) as therapeutic drugs for treating Alzheimer's diseases (AD). More specifically, the present invention relates to the use of man-made miRNA miR-302 precursors (pre-miR-302) for AD therapy in humans. These pre-miR-302 molecules can be mass produced in prokaryotes as a form of DNA expression-competent DNA vectors and/or hairpin-like RNAs. As prokaryotic cells do not transcribe or process hairpin-like RNAs, the present invention also teaches a method for expressing pre-miRNAs in prokaryotes, i.e. pro-miRNA, using a novel hairpin-like RNA transcription mechanism newly found in prokaryotes. Additionally, since miR-302 is a well-known embryonic stem cell (ESC)-specific factor in humans, our novel findings of this invention can be further used to advance the designs and development of novel regenerative medicine for treating many other ageing-related degenerative diseases, such as Parkinson's diseases, osteoporosis, diabetes, and cancers.

The disclosure herein relates to engineered biosensor-containing bacteria, which is bacteria that contain at least one biosensor circuit, and uses thereof. A biosensor circuit can comprise an essential gene of the bacteria operably linked to an inducible promoter. Additionally, the bacteria can be engineered to be deficient in the endogenous copy of the at least one essential gene.

The disclosure herein relates to engineered biosensor-containing bacteria, which is bacteria that contain at least one biosensor circuit, and uses thereof. A biosensor circuit can comprise an essential gene of the bacteria operably linked to an inducible promoter. Additionally, the bacteria can be engineered to be deficient in the endogenous copy of the at least one essential gene.

Inducible promoters for the coordinated expression of at least one heterologous gene in yeast and methods of using them are disclosed. In particular, the invention relates to sets of inducible promoters derived from S. cerevisiae and related species that can be induced in the presence of nonfermentable carbon sources.

The present invention relates generally to mutagenesis of target genes that takes advantage of the natural mutagenic capabilities of B cells, and enhances those capabilities by bringing the process of diversification under control. The invention provides a method for rapidly and inducibly generating point mutations and other types of diversification in expressed genes, such as antibody genes. This method can be coupled with selection to identify B cell clones that produce, for example, antibodies of high affinity or specificity. The diversification process can be modulated, accelerated, halted, switched between methods of mutagenesis and the like. The modulation of diversification in accordance with the invention is both inducible and reversible. The invention provides a means of rapid and feasible development of a repertoire of variant immunoglobulins and other polypeptides.

The invention provides for systems, methods, and compositions for altering expression of target gene sequences and related gene products. Provided are structural information on the Cas protein of the CRISPR-Cas system, use of this information in generating modified components of the CRISPR complex, vectors and vector systems which encode one or more components or modified components of a CRISPR complex, as well as methods for the design and use of such vectors and components. Also provided are methods of directing CRISPR complex formation in eukaryotic cells and methods for utilizing the CRISPR-Cas system. In particular the present invention comprehends optimized functional CRISPR-Cas enzyme systems.

The invention relates to methods of altering expression of a genomic locus of interest or specifically targeting a genomic locus of interest in an animal cell, which may involve contacting the genomic locus with a non-naturally occurring or engineered composition that includes a deoxyribonucleic acid (DNA) binding polypeptide having a N-terminal capping region, a DNA binding domain comprising at least five or more Transcription activator-like effector (TALE) monomers and at least one or more half-monomers specifically ordered to target the genomic locus of interest, and a C-terminal capping region, wherein the polypeptide includes at least one or more effector domains, and wherein the polypeptide is encoded by and translated from a codon optimized nucleic acid molecule so that the polypeptide preferentially binds to the DNA of the genomic locus.