Project description:We performed in vivo CRISPR screen of Toxoplasma targeting ROP/GRA genes to identify in vivo fitness genes in WT and Ifngr1-deficient mice.

Project description:We performed in vivo CRISPR screen of Toxoplasma targeting endomembrane and nucleus-related genes to identify in vivo fitness genes in WT and Ifngr1-deficient mice.

Project description:In vivo CRISPR screens for Toxoplasma using metabolism sublibrary in WT and Ifngr1-deficient mice

Project description:In vivo CRISPR screens for Toxoplasma using endomembrane-nucleus sublibrary in WT and Ifngr1-deficient mice

Project description:In vivo CRISPR screens for Toxoplasma using ROP/GRA sublibrary in WT and Ifngr1-deficient mice

Project description:We performed in vivo CRISPR screens of Toxoplasma targeting hyperLOPIT-unassigened genes during mouse infection.

Project description:We performed in vivo CRISPR screens of Toxoplasma targeting genes with hyperLOPIT-unassigened subcellular localisation during mouse infection.

Project description:In vivo CRISPR screens for Toxoplasma hyperLOPIT-unassigened proteins_2

Project description:In vivo CRISPR screens for Toxoplasma hyperLOPIT-unassigened proteins_1

Project description:The ability to perturb genes in human cells is crucial for elucidating gene function and holds great potential for finding therapeutic targets for diseases such as cancer. To extend the catalog of human core and context- dependent fitness genes, we have developed a high-complexity second-generation genome-scale CRISPR-Cas9 gRNA library and applied it to fitness screens in five human cell lines. Using an improved Bayesian analytical approach, we consistently discover 5-fold more fitness genes than were previously observed. We present a list of 1,580 human core fitness genes and describe their general properties. Moreover, we demonstrate that context-dependent fitness genes accurately recapitulate pathway-specific genetic vulnerabilities induced by known oncogenes and reveal cell-type-specific dependencies for specific receptor tyrosine kinases, even in oncogenic KRAS backgrounds. Thus, rigorous identification of human cell line fitness genes using a high-complexity CRISPR-Cas9 library affords a high-resolution view of the genetic vulnerabilities of a cell. Additional data can be found at tko.ccbr.utoronto.ca RNAseq of five human cell lines with Cas9 knock-ins.