An expression vector containing appropriate mitochondrion-targeting sequences (MTS) and appropriate 3′UTR sequences provides efficient and stable delivery of a mRNA encoding a protein (CDS) to the mitochondrion of a mammalian cell. The MTS and 3′UTR sequences guide the CDS mRNA from the nuclear compartment of the cell to mitochondrion-bound polysomes, where the CDS is translated. This provides an efficient translocation of a mature functional protein into the mitochondria. A method of targeting mRNA expressed in the nuclear compartment of a mammalian cell to the mitochondrion is also provided. The vector and methods can be used to treat defects in mitochondrial function.

Compositions and methods are provided for creating and promoting biallelic targeted modifications to genomes within cells and for producing non-human animals comprising the modified genomes. Also provided are compositions and methods for modifying a genome within a cell that is heterozygous for an allele to become homozygous for that allele. The methods make use of Cas proteins and two or more guide RNAs that target different locations within the same genomic target locus. Also provided are methods of identifying cells with modified genomes.

In order to develop tools and methods useful in a variety of applications, including the research and development of medical treatments which involve the modification of collagen protein and use of the same, the present invention provides a modified collagen protein expressed in a transformed cell and capable of forming collagen fibers outside of the cell, wherein the transformation is performed by introducing, into the cell, polynucleotides coding the modified collagen protein.

The invention relates to nucleic acid constructs for expression in mice for the production of heavy chain only antibodies and V.sub.H domains, transgenic mice, related methods and uses.

A non-human animal model for neurodegenerative and/or inflammatory diseases is provided, which non-human animal comprises a disruption in a C9ORF72 locus. In particular, non-human animals described herein comprise a deletion of an entire coding sequence of a C9ORF72 locus. Methods of identifying therapeutic candidates that may be used to prevent, delay or treat one or more neurodegenerative (e.g., amyotrophic lateral sclerosis (ALS, also referred to as Lou Gehrig's disease) and frontotemporal dementia (FTD)), autoimmune and/or inflammatory diseases (e.g., SLE, glomerulonephritis) are also provided.

Disclosed are compositions, methods, and kits for modifying DNA within cells as well as compositions and methods for modifying gene expression in a cell. In particular, the invention generally relates to compositions, methods, and kits for DNA editing using single-stranded DNA. Compositions and methods for modifying gene expression using artificial microRNAs (amiRNA) are also contemplated.

The present disclosure relates to expansion and activation of T cells. In an aspect, the present disclosure relates to expansion and activation of γδ T cells that may be used for transgene expression. In another aspect, the disclosure relates to expansion and activation of γδ T cells while depleting α- and/or β-TCR positive cells. T cell populations comprising expanded γδ T cell and depleted or reduced α- and/or β-TCR positive cells are also provided for by the instant disclosure. The disclosure further provides for methods of using the disclosed T cell populations.

The disclosure in some aspects relates to recombinant adeno-associated viruses having distinct tissue targeting capabilities. In some aspects, the disclosure relates to gene transfer methods using the recombinant adeno-associated viruses. In some aspects, the disclosure relates to isolated AAV capsid proteins and isolated nucleic acids encoding the same.

The present disclosure relates to genetically modified non-human animals expressing human or chimeric (e.g., humanized) Thrombopoietin (THPO), and methods of use thereof.

The present disclosure relates to an advanced in vivo reprogramming system and a cell conversion method using same. The reprogramming system of the present disclosure comprises a start cell marker promoter, a pluripotency-maintaining gene protein, an amino acid isolation peptide, Cre recombinase, a target cell marker promoter, LoxP, and a gene encoding a fluorescent protein, does not require cell fixation in order to confirm cell conversion, enables real-time monitoring in a living cell state, and may be used both in vitro and in vivo. Therefore, the present disclosure is expected to be widely used in the biological and medical fields.