Abstract: Provided are engineered cells for adoptive therapy, including T cells. Also provided are methods and compositions for engineering and producing the cells, compositions containing the cells, and method for their administration to subjects. In some embodiments, the cells, such as T cells, contain genetically engineered antigen receptors that specifically bind to antigens, such as a chimeric antigen receptor (CAR). In some embodiments, the cells, such as a CAR-expressing T cell, contains an agent that is capable of reducing an inhibitory effect by repressing and/or disrupting a gene in an engineered cell, such as a gene involved in inhibiting the immune response. In some embodiments, features of the cells and methods provide for increased or improved activity, efficacy and/or persistence.

Abstract: Provided are engineered cells for adoptive therapy, including NK cells and T cells. Also provided are compositions for engineering and producing the cells, compositions containing the cells, and methods for their administration to subjects. In some aspects, features of the cells and methods provide specificity and/or efficacy. In some embodiments, the cells contain genetically engineered antigen receptors that specifically bind to antigens, such as chimeric antigen receptors (CARs) and costimulatory receptors. In some embodiments, the cells include receptors targeting multiple antigens. In some embodiments, the cells include repression of one or more gene product, for example, by disruption of a gene encoding the gene product. In some embodiments, a gene encoding an antigen recognized by the engineered antigen receptor is disrupted, reducing the likelihood of targeting of the engineered cells.

Abstract: The present disclosure relates in some aspects to methods, cells, and compositions for preparing cells and compositions for genetic engineering and cell therapy. Provided in some embodiments are streamlined cell preparation methods, e.g., for isolation, processing, incubation, and genetic engineering of cells and populations of cells. Also provided are cells and compositions produced by the methods and methods of their use. The cells can include immune cells, such as T cells, and generally include a plurality of isolated T cell populations or types. In some aspects, the methods are capable of preparing of a plurality of different cell populations for adoptive therapy using fewer steps and/or resources and/or reduced handling compared with other methods.

Abstract: Provided are methods for administering multiple doses of cells, such as T cells, to subjects for cell therapy. Also provided are compositions and articles of manufacture for use in the methods. The cells generally express recombinant receptors such as chimeric receptors, e.g., chimeric antigen receptors (CARs) or other transgenic receptors such as T cell receptors (TCRs). The methods generally involve administering a first and at least one consecutive dose of the cells. Timing of the doses relative to one another, and/or size of the doses, in some embodiments provide various advantages such as lower or reduced toxicity and improved efficacy, for example, due to increased exposure of the subject to the administered cells. In some embodiments, the first dose is a relatively low dose, such as one that reduces tumor or disease burden, thereby improving the efficacy of consecutive or subsequent doses, and the consecutive dose is a consolidating dose.

Abstract: Provided are ROR1 binding molecules, including anti-ROR1 antibodies, including antibody fragments such as variable heavy chain (VH) regions, single-chain fragments, and chimeric receptors including the antibodies, such as chimeric antigen receptors (CARs). In some embodiments, the antibodies specifically bind to ROR1. Among the antibodies are human antibodies, including those that compete for binding to ROR1 with reference antibodies, such as a non-human reference antibody. Also provided are genetically engineered cells expressing the chimeric receptors, and uses of the binding molecules and cells adoptive cell therapy.

Abstract: Provided are polynucleotides containing a modified PRE having a variant X gene that includes one or more stop codons not present in an unmodified, such as wild-type, hepatitis X gene. Also provided are polynucleotides containing a modified PRE having a variant X gene that includes one or more degradation sequences not present in an unmodified, such as wild-type, hepatitis X gene. The modified PRE can be operably linked to a nucleic acid encoding a recombinant protein. Also provided are expression cassettes, viral vectors and cells containing the polynucleotides, and compositions and methods of use thereof.

Abstract: Provided are methods for multiple administrations of cells for adoptive cell therapy, and for administering cells to subjects having received prior administrations, and compositions and articles of manufacture for use in the methods. The cells generally express recombinant molecules such as recombinant receptors, e.g., chimeric antigen receptors (CARs) and/or other transgenic receptors. The methods can involve administering cells expressing a first or prior receptor(s) and cells expressing a second or subsequent receptor(s), the second or subsequent receptor(s) being distinct from the first, and which generally do not express the first receptor, and/or administering the cells expressing the second receptor to a subject having received the first administration.

Abstract: Provided are CD19 binding molecules, including anti-CD19 antibodies, including antibody fragments such as single-chain fragments, and chimeric receptors including the antibodies, such as chimeric antigen receptors (CARs). Among the antibodies are human antibodies, including those that compete for binding to CD19 with reference antibodies, such as murine antibodies. In some embodiments, the antibodies display similar functional properties to the reference antibodies, such as comparable binding affinities and/or competitive inhibition properties. Also provided are genetically engineered cells expressing the chimeric receptors, and uses of the binding molecules and cells adoptive cell therapy.

Abstract: Provided are methods, systems, and kits for cell processing, e.g., for therapeutic use, such as for adoptive cell therapy. The provided methods include transduction methods, in which cells and virus are incubated under conditions that result in transduction of the cells with a viral vector. The incubation in some embodiments is carried out in an internal cavity of a generally rigid centrifugal chamber, such as a cylindrical chamber made of hard plastic, the cavity of which may have a variable volume. The methods include other processing steps, including those carried out in such a chamber, including washing, selection, isolation, culture, and formulation. In particular, the disclosure relates to method providing advantages over available processing methods, such as available methods for large-scale processing. Such advantages include, for example, reduced cost, streamlining, increased efficacy, increased safety, and increased reproducibility among different subjects and conditions.