The present disclosure provides a nucleic acid sequence for regulating the transcription of a nucleic acid fragment of interest, wherein the nucleic acid sequence comprises at least 2 copies of TetO-operator sequences capable of binding to a transactivator rtTA regulatable by tetracycline or a derivative thereof, and 1 copy of minimal promoter sequence containing a TATA box sequence, and at least 1 copy of a CuO-operator sequence capable of binding to a transcription repressor CymR regulatable by cumate. The present disclosure also provides a vector and a host cell containing the nucleic acid sequence, and a method for inducing the expression of a nucleic acid fragment of interest in a host cell.

The present invention relates to the production and use of covalently closed circular (ccc) recombinant plasmids, and more particularly to vector modifications that improve expression of said DNA molecules in the target organism.

The present disclosure relates generally to methods and compositions for transferring a genetic circuit from one prokaryotic cell (“donor cell”) to another prokaryotic cell (“recipient cell” or “target cell” which are used interchangeably herein). More specifically, the present disclosure relates to prokaryotic donor cells comprising (i) a genetic circuit of interest and (ii) one or more expressed transcriptional repressor proteins and the use of said donor cells in the efficient transfer of the genetic circuit into a prokaryotic recipient cell. The genetic circuit includes nucleic acid sequences encoding a RNA molecule or protein of interest.

The present invention provides expression vectors for use in an inducible coexpression system, capable of controlled induction of expression of each gene product.

A self-reconfiguring genome uses a cassette having operons or DNA sequences that code for guide RNA, reverse transcriptase, donor RNA, and a CRISPR cleavage enzyme. A self-reconfiguring genome may be based on lambda recombineering of in situ generated oligonucleotides. A method for programmable self-modification of a cellular genome includes transcribing guide RNA from a self-reconfiguring cassette, associating the transcribed guideRNA with the CRISPR enzyme, intercalating a region of complimentary sequence within an integration site of the genome, cutting upstream of a PAM site within the integration site; transcribing the donorRNA, translating donorRNA to double-stranded DNA, and recombining the double-stranded DNA via homologous recombination at the cut site of the integration site. A set of cascadable and multiplexable genetic logic gates with a universal RNA input/output based on single-strand annealing or non-homologous end joining, comprises transcription promoters or terminators, homologous regions, DNA sequences, RNA, and enzymes from the CRISPR system.

Control Devices are disclosed including RNA destabilizing elements (RDE), RNA control devices, and destabilizing elements (DE) combined with Chimeric Antigen Receptors (CARs) or other transgenes in eukaryotic cells. Multicistronic vectors are also disclosed for use in engineering host eukaryotic cells with the CARs and transgenes under the control of the control devices. These control devices can be used to optimize expression of CARs in the eukaryotic cells so that, for example, effector function is optimized. CARs and transgene payloads can also be engineered into eukaryotic cells so that the transgene payload is expressed and delivered after stimulation of the CAR on the eukaryotic cell.

The invention, in part, relates to assessing interactions between gene transcription enhancers and gene transcription repressor, identifying agents that modulate transcription, and use of methods and identified agents to prevent and treat diseases and conditions, such as cancers.

The technology described herein is directed to inducible and repressible polypeptides and polypeptide systems. In particular, described herein are split sequence-specific nucleases and split recombinases that are linked to drug-inducible or drug-repressible dimerization domains. In some embodiments, the polypeptides comprise sequestering domains and/or have their expression controlled by an inducible promoter. In multiple aspects described herein are polynucleotides, vectors, cells, and pharmaceutical compositions comprising said polypeptides or polypeptide systems. Also described herein are methods of using said polypeptide systems to modulate the expression of a target polypeptide or to treat a subject in need of a cell therapy.

Disclosed herein include methods, compositions, and kits suitable for use in imaging of in situ gene expression. There are provided, in some embodiments, viral vector compositions. Disclosed herein includes a single viral vector comprising one or more gas vesicle assembly (GVA) gene(s) encoding one or more GVA protein(s), and one or more gas vesicle structural (GVS) gene(s) encoding one or more GVS protein(s). The one or more GVA protein(s) and the one or more GVS protein(s) can be capable of forming gas vesicles (GVs) upon expression in a cell.

Provided are compositions, including products of manufacture and kits, and methods, for remotely-controlled and non-invasive manipulation of intracellular nucleic acid expression, genetic processes, function and activity in live cells such as a T cell, a primary T cell, a B cell, a monocyte, a macrophage, a dendritic cell or a natural killercell in vivo, for example, including activating, adding functions or changing or adding specificities for an immune cell, for monitoring physiologic processes, for the correction of pathological processes and for the control of therapeutic outcomes. Provided are tamoxifen-gated photoactivatable split-Cre recombinase optogenetic systems, called TamPA-Cre, that feature high spatiotemporal control to control or alter cell activities in vivo, for example, to limit the activity of a Chimeric Antigen Receptor (CAR)-expressing cell such as an immune cell and its activity at a tumor site for immunotherapy applications.