Disclosed herein are lentiviral vector transduction efficiency assays for gene therapy treatments. Also disclosed herein are methods for measuring transduction efficiency of a lentiviral vector.

The present disclosure provides methods and compositions of modulating expression of a target nucleic acid in a eukaryotic cell. The methods include providing to the cell a guide RNA complementary to the target nucleic acid sequence, providing to the cell a fusion protein, wherein the fusion protein comprises a nuclease null Cas9 protein and a transcriptional effector domain, wherein the nuclease null Cas9 protein interacts with the guide RNA and binds to the target nucleic acid sequence in a site specific manner and wherein the transcriptional effector domain modulates expression of the target nucleic acid.

The present disclosure provides compounds comprising modified oligonucleotides for use in CRISPR. In certain embodiments, such modified oligonucleotides provide improved properties of crRNA. In certain embodiments, such modified oligonucleotides provide improved properties of scrRNA.

In certain embodiments methods of treating X-Linked Hyper-IgM Syndrome (XHIM) in a mammal am provided where the methods comprise: i) providing differentiated T cells and/or stem/progenitor cells from the mammal; ii) performing a targeted insertion of a corrective CD40L cDNA at the CD40LG gene locus in said cells to provide a corrected CD40LG gene wherein said targeted insertion places said corrective CD40L cDNA downstream and operably linked to the endogenous CD40LG enhancer/promoter, and iii) introducing said cells into said mammal where said corrected CD40LG gene is expressed in a physiologically regulated manner.

The present disclosure provides methods and compositions for genetically modifying lymphocytes, for example T cells and/or NK cells. In some embodiments, the methods include reaction mixtures, and resulting cell formulations, that are created using whole blood, or a component thereof that is not a PBMC, and additionally comprise T cells and recombinant retroviral particles having polynucleotides that encode a CAR. In some embodiments, modified lymphocytes are reintroduced into a subject subcutaneously. In some embodiments, polynucleotides that provide T cells the ability to regulate cell survival and proliferation in response to binding to a CAR, are provided.

The invention concerns a multicistronic nucleic acid, in particular an isolated multicistronic nucleic acid, comprising: A) a sequence comprising successively: A1) a sequence encoding the light chain variable domain of an antibody of interest, fused in the frame with A2) a sequence encoding the constant region of the light chain of an immunoglobulin Ig; and B) a sequence comprising successively: B1) a sequence encoding the heavy chain variable domain of said antibody of interest, fused in the frame with B2) a sequence encoding the constant regions of the heavy chain of an immunoglobulin Ig′ in secretory form; B3) an intronic sequence of the gene of the heavy chain of said immunoglobulin Ig′, said intronic sequence comprising an internal 5′ splice site enabling the splicing of said intronic sequence B3) and a secretory-specific poly(A) (p AS) signal from the 3′ terminal exon of said gene; B4) a sequence, in frame with sequence B1), encoding the transmembrane and cytoplasmic domains M1 and M2 of the immunoglobulin Ig′ BCR, wherein said sequence B4) comprises, between the coding sequences of the M1 and M2 domains, an intronic sequence containing a splice site enabling the splicing of said intronic sequence between the M1 and M2 domains coding sequences; and B5) a membrane-anchored specific poly(A) signal (p AM), after the stop codon of the M2 domain, wherein the multicistronic nucleic acid enables the co-expression of the sequences A and B into separate proteins.

A potent short hairpin RNA (shRNA734) directed to human Hypoxanthine Guanine Phosphoribosyltransferase (HPRT) improves the rate of gene-modified stem cell engraftment by a conditioning and in vivo selection strategy to confer resistance to a clinically available guanine analog antimetabolite, 6TG, for efficient positive selection of gene-modified stem cells. Uses for polynucleotides comprising the shRNA734 include methods for knocking down HPRT in a cell, for conferring resistance to a guanine analog antimetabolite in a cell, for producing selectable genetically modified cells, for selecting cells genetically modified with a gene of interest from a plurality of cells, for removing cells genetically modified with a gene of interest from a plurality of cells, and for treating a subject infected with HIV.

The present invention relates to a chimeric antigen receptor comprising at least the following components: a) a peptidic structure capable of binding to a ligand; b) an extracellular spacing structure; c) a transmembrane domain; d) none or at least one co-stimulatory domain; and e) at least a TCR-derived activatory domain
whereby a second TCR-derived activatory domain comprises the amino acid sequence RKGQRDLY (SEQ ID NO:1), which is capable to bind the lymphocyte specific Src kinase in a phosphorylation independent manner and its use in vectors for transducing T cells which are useful in the treatment of diseases, in particular tumors.

Disclosed herein are antibodies or antigen binding fragments thereof that specifically bind human CD8. Also disclosed are fusion proteins comprising a Henipavirus glycoprotein G and CD8 antibodies for targeting and transducing cells expressing CD8. Viral vectors and other compositions containing the fusion proteins, as well as methods of using the fusion proteins, are also disclosed.

The present disclosure provides chimeric antigen receptors (CARs), and nucleic acids comprising nucleotide sequences encoding the CARs, that bind to HER2, and conditionally active biologic (CAB) CARs that bind to HER2. The present disclosure provides cells genetically modified to produce the CARs, delivery suspensions comprising these genetically modified cells, and methods for making such cells. The CARs of the present disclosure can be used in various methods, which are also provided, including methods for activating immune cells under certain conditions, and methods for performing adoptive cell therapy such as CAR therapy, for example CAR therapy against cancer.