Disclosed herein are methods for identifying immunomodulatory genes. In some embodiments, the method comprises of screening a candidate gene comprising: a) expressing an exogenous cellular receptor, or a functional portion thereof, in a plurality of immune cells; b) introducing into said plurality of immune cells: i. a guiding polynucleic acid, or a nucleic acid encoding said guiding polynucleic acid, wherein said guiding polynucleic acid targets said candidate gene; and ii. an exogenous nuclease, or a nucleic acid encoding said exogenous nuclease; thereby generating a plurality of engineered immune cells comprising a genomic disruption in said candidate gene; c) contacting said plurality of engineered immune cells with a plurality of cells expressing a cognate antigen of said exogenous cellular receptor or a functional portion thereof, thereby performing an in vitro assay; and d) determining a readout of said in vitro assay.

HTP genomic engineering platform for improving filamentous fungal cells that is computationally driven and integrates molecular biology, automation, and advanced machine learning protocols. This integrative platform utilizes a suite of HTP molecular tool sets to create HTP genetic design libraries, which are derived from, inter alia, scientific insight and iterative pattern recognition. Methods can be carried out within optofluidic devices.

Synthetic auxotrophs with one or more ligand-dependent essential gene functions and methods of production that can be used for biosafety. The ligand-dependent function of an essential gene product can be produced by a series of mutations in the ORF of an essential gene; N, C, or insertional fusions of ligand-binding domains with essential genes or an engineered ligand-dependent intein splicing to alter essential gene function. A positive and/or negative selection can be used to identify auxotrophs from created mutant libraries. The positive selection is performed by growing a mutant library in conditions where growth or viability depends on the function of mutagenized essential genes. The negative selection eliminates constitutively growing cells that do not require a ligand for growth by growing the library in the absence of complementing ligand and in conditions where growing cells are eliminated. Desirable phenotypes are collected after the selections.

The invention encompasses compositions, kits and methods for modifying bacteria, preferably naturally occurring bacteria, in situ. These can be used to treat, prevent or cure microbiome-associated diseases or disorders by modulating the molecules expressed and/or secreted by bacterial populations of the microbiome in a specific manner. The genomic modifications can modify the interactions between part or all of these populations and the host in a way that decreases their deleterious potential on host health. The compositions, kits and methods of the invention do not result in the direct death of these populations or a direct significant inhibition of their growth. The invention further includes methods for screening for genetic modifications in the bacteria, for determining the efficiency of vectors at inducing these genetic mutations, and for determining the effects of these mutations on bacterial growth.

In one aspect, the present disclosure provides a method for identifying treatment targets relating to tumors. In another aspect, the present disclosure provides a method for identifying biomarkers and molecular features of normal and cancer cells.

The present invention relates to a partition library which comprises a plurality of partitions which are useful for the analysis of the transcriptional response of a CAR to a target antigen. Further, the present invention relates to assays for the analysis of the transcriptional response of a CAR to a target antigen. The present invention also relates to kits comprising the plurality of partitions.

The present invention relates to a partition library which comprises a plurality of partitions which are useful for the analysis of the transcriptional response of a CAR to a target antigen. Further, the present invention relates to assays for the analysis of the transcriptional response of a CAR to a target antigen. The present invention also relates to kits comprising the plurality of partitions.

Embodiments disclosed herein are directed to a new genetic perturbation and screening method that combines advantages of pooled perturbation with imaging assays for complex phenotypes. Specifically, the method may be used to screen pooled genomic perturbations to identify phenotypes and to identify perturbed genes at the single-cell level using optical barcodes. A major advantage offered by this approach is the ability to screen for any cellular phenotype that can be identified by high-resolution microscopy—including live-cell phenotypes, protein localization, or highly multiplexed expression profile and mRNA localization by RNA-FISH—in conjunction with a large array of genetic perturbations applied as a pool in a single test volume.

Cas-protein-ready tau bio sensor cells, CRISPR/Cas synergistic activation mediator (SAM)-ready tau biosensor cells, and methods of making and using such cells to screen for genetic vulnerability associated with tau aggregation are provided.

The invention in various aspects provides for magnetic enrichment and/or expansion of antigen-specific T cells, allowing for identification and characterization of antigen-specific T cells and their T cell receptors (TCRs) for therapeutic and/or diagnostic purposes, as well as providing for production of antigen-specific engineered T cells for therapy. Incubation of paramagnetic nano-aAPCs in the presence of a magnetic field, either during enrichment and/or expansion steps, activates T cells through magnetic clustering of paramagnetic particles on the T cell surface.