When a cancer patient is administered an anti-cancer therapy targeting a lineage specific cell-surface antigen (e.g., CD33 (Siglec-3), CLL-1, CD123, CD327 (Siglec-6), and/or CD312 (EMR2)), e.g., in the form of an immunotherapeutic agent, the therapy can deplete not only cancer cells expressing the lineage-specific cell-surface antigen, but also noncancerous cells expressing the lineage-specific cell-surface antigen in an on-target, off tumor effect. This disclosure provides, e.g., novel cells having a modification (e.g., insertion or deletion) in an endogenous lineage-specific cell-surface antigen (e.g., CD33 (Siglec-3), CLL-1, CD123, CD327 (Siglec-6), and/or CD312 (EMR2)) gene. The disclosure also provides compositions, e.g., gRNAs, that can be used to make such a modification.

The invention provides methods and compositions for administration of allogeneic lymphocytes as an exogenous source of CD4+ T cell help for endogenous, tumor-reactive CD8+ T cells.

The invention provides improved compositions and methods for the treatment of solid cancers.

The disclosure relates generally to methods and compositions for performing bone marrow transplants using a non-myeloablative chemotherapeutic agent and chemotherapeutic-resistant cells. Using the methods and compositions described herein, a patient's bone marrow may be reconstituted and the patient avoids adverse side effects, including myeloablation and/or an impaired immune system.

Provided herein are humanized mouse models and methods for determining whether administration of engineered immune cell therapies likely elicit cytokine release syndrome and/or determining the efficacy of an anti-disease therapy. Further, the models provided herein may be used to test the efficacy of different anti-CRS therapies.

Methods of using soluble tandem selectin glycoprotein ligand (TSGL) and TSGL fusion proteins, such as TSGL-Ig, in combination with T cell activation therapies or an adoptive cell transfer (ACT) therapy.

The present disclosure provides distinct therapeutic populations of cells that form a pharmaceutical composition useful in hematopoietic stem/progenitor cell transplant. For example, the present disclosure provides a therapeutic population of cells, comprising an enriched population of hematopoietic stem/progenitor cells, memory T cells, regulatory T cells, and wherein the population of cells is depleted of nave conventional -T cells. The present disclosure further provides methods of treatment using the therapeutic population of cells. In other embodiments, the present disclosure provides methods of producing a therapeutic population of cells.

The present invention provides methods for inducing tolerance and/or suppressing an immune response to an antigen by passing a cell suspension containing an anucleate cell through a constriction, wherein the constriction deforms the cell thereby causing a perturbation of the cell such that an antigen and/or tolerogenic factor enters the cell. In some embodiments, the anucleate cell is delivered to an individual and the antigen is delivered to and processed in a tolerogenic environment to induce tolerance and/or suppress an immune response to the antigen.

Methods of preventing or treating autoimmune disease are disclosed. In some cases, subjects with having or at risk of developing autoimmune disease are identified as possessing one or more autoimmunity-susceptibility HLA alleles at one or more HLA loci. In many cases, the HLA loci are selected from Class I and Class II loci, for example Class I A, B, and C, and Class II DQ, DR, and DP. In many cases, subjects suffering from or at risk of developing an autoimmune disease may be administered a plurality engineered autologous HSCs modified to carry and express a variant susceptibility allele having at least one mutation in the antigen binding cleft that alters antigen binding and/or specificity of that variant HLA molecule. In many embodiments, the engineered HSCs are CD34+ immune cells that express one or more modified HLA proteins.

The invention discloses novel RAR gamma selective agonists used in the treatment of cancer. The invention also discloses administration of RAR gamma selective agonists to mammals, including humans for the purpose of selectively activating RAR gamma receptor and treat cancer by way of activating tumor infiltrating lymphocytes.