Disclosed are methods of identifying immunosuppressive T.sub.R1 regulatory T cells, including in methods of diagnosing the presence of immune tolerance, methods of producing immunosuppressive regulatory T cells, and methods of eliciting immune tolerance in a subject. These methods include screening T cells to detect Eomes.sup.+IL-10.sup.+ T cells or expressing recombinant Eomes in T cell populations to generate immunosuppressive regulatory T cells.

Embodiments disclosed herein are directed to engineered CRISPR-Cas effector proteins that comprise at least one modification compared to an unmodified CRISPR-Cas effector protein that enhances binding of the of the CRISPR complex to the binding site and/or alters editing preference as compared to wild type. In certain example embodiments, the CRISPR-Cas effector protein is a Type V effector protein. In certain other example embodiments, the Type V effector protein is Cpf1. Embodiments disclosed herein are directed to viral vectors for delivery of CRISPR-Cas effector proteins, including Cpf1. In certain example embodiments, the vectors are designed so as to allow packaging of the CRISPR-Cas effector protein within a single vector. There is also an increased interest in the design of compact promoters for packing and thus expressing larger transgenes for targeted delivery and tissue-specificity. Thus, in another aspect certain embodiments disclosed herein are directed to delivery vectors, constructs, and methods of delivering larger genes for systemic delivery.

The present application relates to the field of immunotherapy, more particularly to the field of adoptive cell therapy (ACT). Here, shRNAs designed to downregulate CD52 are proposed. Also proposed are polynucleotides, vectors encoding the shRNA and cells expressing such shRNAs, alone or in combination with a chimeric antigen receptor (CAR). These cells are particularly suitable for use in immunotherapy, especially in combination with immunosuppressive therapies directed against CD52, as is particularly envisaged in allogeneic therapy. The invention provides methods of increasing the efficacy of a T cell therapy in a patient in need thereof. Further, strategies to treat diseases such as cancer using these cells are also provided. The engineered immune cells, such as T-cells or natural killer (NK) cells, expressing such CARs are particularly suitable for treating lymphomas, multiple myeloma and leukemia.

An engineered immune cell, which expresses (i) a cell surface molecule that specifically recognizes a ligand, (ii) an exogenous interleukin, and (iii) an exogenous Flt3L, XCL2, and/or XCL1; the engineered immune cell can be used for treating cancer, infection, or autoimmune diseases; and compared with a traditional engineered immune cell, the engineered immune cell has significantly improved tumor killing activity.

The present invention relates to granzyme B variants with increased protease activities and/or increased resistance against inhibitors; polynucleotides encoding the granzyme B variants; cells expressing the granzyme B variants; pharmaceutical compositions containing cells expressing the granzyme B variants; and pharmaceutical compositions containing the granzyme B variants. In some embodiments, the pharmaceutical compositions may be used in combination with cells expressing chimera receptors and/or antigen-binding molecules.

Methods of treating a cancer in a patient are provided. The methods can include obtaining a tumor sample from a patient, detecting whether CCNG1 gene expression is present in the tumor sample, diagnosing the patient with a CCNG1 inhibitor-responsive cancer when the presence of CCNG1 gene expression in the tumor sample is detected, and/or administering an effective amount of a CCNG1 inhibitor to the diagnosed patient. CCNG1 inhibitors can include a viral vector having a binding peptide that is configured to bind one or more signature (SIG) elements of an invading tumor and at least one cytocidal gene. CCNG1 inhibitors including cell penetrating peptides are also provided.

Methods and compositions are provided for delivery of a polynucleotide encoding a gene of interest, typically an antigen, to a dendritic cell (DC). The virus envelope comprises a DC-SIGN specific targeting molecule. The methods and related compositions can be used to treat patients suffering from a wide range of conditions, including infection, such as HIV/AIDS, and various types of cancers.

The present invention relates to vectors and their use to develop host cell lines for production of a protein of interest, and in particular to vectors which utilize a weak promoter to drive a selectable marker.

The invention provides compositions and methods for performing mammalian cell genetics, e.g., genetic screens, using near-haploid cells. The invention further provides genes and gene products isolated using the inventive methods and methods of use thereof.

An object of the present invention is to provide CAR-expressing T cells that coexpress a chimeric antigen receptor (CAR) and a T cell immune function-enhancing factor and have a high immunity-inducing effect and antitumor activity, and to provide a CAR expression vector for the preparation of the CAR-expressing T cells.

A CAR expression vector comprises a nucleic acid encoding a chimeric antigen receptor (CAR) and a nucleic acid encoding a T cell immune function-enhancing factor, wherein the nucleic acid encoding an immune function-enhancing factor is a nucleic acid encoding interleukin-7 and a nucleic acid encoding CCL19, a nucleic acid encoding a dominant negative mutant of SHP-1, or a nucleic acid encoding a dominant negative mutant of SHP-2, or a CAR-expressing T cell introduced with the CAR expression vector are prepared.