A method, system, and apparatus for treating a patient with HIV. A vector can be modified from a thymidine kinase gene. The modified vector is expressed in the presence of tat RNA. The modified vector is then package and delivered to HIV-infected cells. The replication of HIV is inhibited by eliminating infected cells in the presence of Ganciclovir. Modified cells are then selected utilizing transient tat RNA transfection and GFP expression. Vector-modified stem cells are then selected for transplantation back into the patient, thereby producing a normal immune system in the patient when the modified vector remains dormant in the absence of HIV tat.

Disclosed are nanoparticles that are introduced into cells and express a specific protein and a manufacturing method thereof. More particularly, the present invention relates to mRNA nanoparticles, which increase the expression of a specific protein capable of stimulating the cellular immune system to induce cellular immune responses and are thus applicable to treat a variety of diseases, do not require passage across the nuclear envelope because a desired gene is delivered not as plasmid DNA itself but in the form of mRNA, thus improving the efficiency of protein expression, and the nanoparticles are generated through a one-step process with a relatively small amount of plasmid DNA via rolling circle transcription (RCT), thereby providing a simple and economical process for gene delivery. The present invention is also concerned with such mRNA nanoparticles.

This invention provides nanoparticles containing protein-polynucleotide complexes and methods of manufacture and methods of their use. These particles, when administered to a subject in need, are capable of delivering these complexes to target cells and target intracellular locations where they can perform a therapeutic function. In some embodiments, this therapeutic function includes gene editing, induction of gene skipping, and regulation of gene expression. The instant nanoparticles are generally formed by designing and synthesizing the polynucleotide to according to its intended function, combining it with a protein selected for its substrate specificity and enzymatic function in a manner to form a polynucleotide-protein complex, encapsulating the complexes by dispersion into a water-insoluble surfactant system, optionally adding a targeting ligand, and stabilizing the nanoparticles by crystallization of the ligand to the surface of the nanoparticles.

The methods, processes, and systems described herein include identifying an epitope of a peptide that may elicit an immune response in a subject. Often the methods, systems and processes may include designing and producing a composition comprising an epitope of a peptide identified using the methods or processes described herein.

Provided herein are DNA origami devices useful in the targeted delivery of biologically active entities to specific cell populations.

Disclosed herein are compositions and methods for modulating the production of a protein in a target cell. The compositions and methods disclosed herein are capable of ameliorating diseases associated with protein or enzyme deficiencies.

Engineered transcriptional activator-like effectors (TALEs) are versatile tools for genome manipulation with applications in research and clinical contexts. One current drawback of TALEs is that the 5′ nucleotide of the target is specific for thymine (T). TALE domains with alternative 5′ nucleotide specificities could expand the scope of DNA target sequences that can be bound by TALEs. Another drawback of TALEs is their tendency to bind and cleave off-target sequence, which hampers their clinical application and renders applications requiring high-fidelity binding unfeasible. This disclosure provides methods and strategies for the continuous evolution of proteins comprising DNA-binding domains, e.g., TALE domains. In some aspects, this disclosure provides methods and strategies for evolving such proteins under positive selection for a desired DNA-binding activity and/or under negative selection against one or more undesired (e.g., off-target) DNA-binding activities. Some aspects of this disclosure provide engineered TALE domains and TALEs comprising such engineered domains, e.g., TALE nucleases (TALENs), TALE transcriptional activators, TALE transcriptional repressors, and TALE epigenetic modification enzymes, with altered 5′ nucleotide specificities of target sequences. Engineered TALEs that target ATM with greater specificity are also provided.

It is described in vitro methods for expanding, detecting or isolating rare populations of antigen specific memory T cells. It is also described an in vitro method for obtaining a genetically modified memory T cell population. Uses of cells so obtained are also disclosed.

The present disclosure provides compositions which shown preferential targeting or delivery of a nucleic acid composition to a particular organ. In some embodiments, the composition comprises a steroid or sterol, an ionizable cationic lipid, a phospholipid, a PEG lipid, and a permanently cationic lipid which may be used to deliver a nucleic acid.

As an inhalation powder medicine excellent in dispersibility, pulmonary delivery, and deposition, there is provided an inhalation powder medicine, containing: an active ingredient in at least a part of the porous hollow spherical particles that are capable of being dispersed and crushed into smaller particles by inspiration and capable of swelling when the porous hollow spherical particles absorb moisture, wherein the smaller particles are also capable of swelling when the smaller particles absorb moisture.