Genetically engineered hematopoietic cells such as hematopoietic stem cells having one or more genetically edited genes of lineage-specific cell-surface proteins and therapeutic uses thereof, either alone or in combination with immune therapy that targets the lineage-specific cell-surface proteins.

The present disclosure provides 2-in-1 zinc finger nuclease variants and methods of treating and/or preventing a lysosomal storage disorder using said zinc finger nuclease variants.

The present disclosure generally relates to therapies involving immune effector cells such as T cells engineered to express antigen receptors such as T cell receptors (TCRs) or chimeric antigen receptors (CARs). It is demonstrated herein that such antigen receptor-engineered immune effector cells may be generated in vitro/ex vivo as well as in vitro by delivering nucleic acid encoding an antigen receptor for genetic modification to cells using particles comprising the nucleic acid and a targeting molecule for targeting the immune effector cells, wherein the targeting molecule is a designed ankyrin repeat protein (DARPin). In particular, DARPins are described herein which are high-affinity binders for CDS binding to the CDS receptor on human and non-human primate (NHP) cells. Nanoparticles functionalized with CD8− targeting DARPins (CDS-DARPin) can deliver genes exclusively and specifically to human CD8.sup.+ T cells in vitro and in vivo.

Disclosed are cells that have stably integrated into their genomes exogenous nucleic acid sequences, such as transgenes, within or proximal to the integration site of a sequence comprising at least part of an endogenous retrovirus (ERV) or a LTR-retrotransposon (LTR-RT), or instead of a sequence encompassing an ERV or a LTR-RT that is part or was part of the genome of the cell, as well as method of producing and using such cells. Advantageously, a high level and/or stable production of the transgene expression product(s) can be achieved. Transgene integration and expression may be furthered by modulating the DNA repair pathways of the cell, e.g., by transiently expressing a gene encoding a protein that forms part of a DNA repair pathway during transgene integration.

The invention relates to logic-gate-based Type II or Type V CRISPR-Cas constructs and methods for modifying gene expression using the CRISPR-Cas constructs and CRISPR-Cas effector proteins.

The disclosure is directed to compositions and methods comprising genetically engineered fibroblasts for inhibiting progression of a cancerous tumor.

Disclosed herein are cartridges for transfecting cells and/or generating clonal populations of cells comprising: a) a first compartment configured for performing cell transfection, wherein the first compartment comprises a first inlet configured for introduction of a cell sample; b) a second compartment configured for performing cell selection, wherein an inlet of the second compartment is operably coupled to an outlet of the first compartment, and wherein the second compartment further comprises at least one optically-transparent wall and an outlet that is operably coupled to an intermediate cell removal port; and c) a third compartment configured for performing cell expansion, wherein an inlet of the third compartment is operably coupled to the outlet of the second compartment.

RNA-guided programmable cytosine and adenine base editors are a powerful class of genome editing tool for the introduction of localized base transitions without generating a double-stranded DNA break. Base editors (BE) have an optimal window of activity relative to the PAM recognized by the Cas9 enzyme and these constructs are strand selective. Here we demonstrate that fusion of a programmable DNA-binding domain (pDBD) or another Cas9 orthologue to spCas9-BE, we can produce an RNA-programmable Cas9-BE-pDBD chimera or Cas9-BE-Cas9 chimeras with dramatically improved activities and increased targeting range. Cas9-pDBD or Cas9-Cas9 fusion base editors display an expanded targeting repertoire and achieve highly specific genome editing, which can be tailored to achieve extremely precise genome editing at nearly any genomic locus.

Methods for manufacturing genetically engineered T cells expressing a chimeric antigen receptor (CAR), such as a CAR that binds human CD19, BCMA, or CD70, and having multiple additional gene edits, for example, a disrupted Regnase-1 gene, a disrupted TGFBRII gene, a disrupted TRAC gene, a disrupted β2M gene, or a combination thereof, using CRISPR/Cas gene editing systems.

The present invention relates to methods for developing engineered T-cells for immunotherapy that are non-alloreactive. The present invention relates to methods for modifying T-cells by inactivating both genes encoding T-cell receptor and an immune checkpoint gene to unleash the potential of the immune response. This method involves the use of specific rare cutting endonucleases, in particular TALE-nucleases (TAL effector endonuclease) and polynucleotides encoding such polypeptides, to precisely target a selection of key genes in T-cells, which are available from donors or from culture of primary cells. The invention opens the way to standard and affordable adoptive immunotherapy strategies for treating cancer and viral infections.