Project description:Glioblastoma (GBM) is the most prevalent primary malignant brain tumor, containing self-renewing stem-like GBM stem cells (GSCs) that have been a focus of immunotherapies. Chimeric antigen receptor (CAR) T cell therapy has shown evidence of clinical activity, but overall limited responses in patients with GBMs. Here, we interrogated molecular determinants of CAR T cell-mediated GBM killing through whole-genome CRISPR screens in both CAR T cells and patient-derived GSCs. CRISPR screening of CAR T cells identified dependencies for their effector functions, including TLE4 and IKZF2. Targeted knockout of these genes in CAR T cells robustly enhanced antitumor efficacy against GBM patient-derived xenografts (PDXs). Bulk and single cell-RNA sequencing of edited CAR T cells revealed transcriptional profiles of superior effector function and inhibited exhaustion responses. Reciprocal screening of GSCs identified genes essential for their susceptibility to CAR-mediated killing, including RELA and NPLOC4, the knockout of which altered the tumor-immune signaling axis and increased responsiveness of CAR therapy. Overall, CRISPR screening of CAR T cells and GSCs are promising strategies to discover avenues and inform potential combinatorial approaches for enhancing CAR T cell therapeutic efficacy against GBM, and can be extended to reveal key mediators of immunotherapy responses across solid tumors.

Project description:Glioblastoma (GBM) is the most prevalent primary malignant brain tumor, containing self-renewing stem-like GBM stem cells (GSCs) that have been a focus of immunotherapies. Chimeric antigen receptor (CAR) T cell therapy has shown evidence of clinical activity, but overall limited responses in patients with GBMs. Here, we interrogated molecular determinants of CAR T cell-mediated GBM killing through whole-genome CRISPR screens in both CAR T cells and patient-derived GSCs. CRISPR screening of CAR T cells identified dependencies for their effector functions, including TLE4 and IKZF2. Targeted knockout of these genes in CAR T cells robustly enhanced antitumor efficacy against GBM patient-derived xenografts (PDXs). Bulk and single cell-RNA sequencing of edited CAR T cells revealed transcriptional profiles of superior effector function and inhibited exhaustion responses. Reciprocal screening of GSCs identified genes essential for their susceptibility to CAR-mediated killing, including RELA and NPLOC4, the knockout of which altered the tumor-immune signaling axis and increased responsiveness of CAR therapy. Overall, CRISPR screening of CAR T cells and GSCs are promising strategies to discover avenues and inform potential combinatorial approaches for enhancing CAR T cell therapeutic efficacy against GBM, and can be extended to reveal key mediators of immunotherapy responses across solid tumors.

Project description:Glioblastoma (GBM) is the most prevalent primary malignant brain tumor, containing self-renewing stem-like GBM stem cells (GSCs) that have been a focus of immunotherapies. Chimeric antigen receptor (CAR) T cell therapy has shown evidence of clinical activity, but overall limited responses in patients with GBMs. Here, we interrogated molecular determinants of CAR T cell-mediated GBM killing through whole-genome CRISPR screens in both CAR T cells and patient-derived GSCs. CRISPR screening of CAR T cells identified dependencies for their effector functions, including TLE4 and IKZF2. Targeted knockout of these genes in CAR T cells robustly enhanced antitumor efficacy against GBM patient-derived xenografts (PDXs). Bulk and single cell-RNA sequencing of edited CAR T cells revealed transcriptional profiles of superior effector function and inhibited exhaustion responses. Reciprocal screening of GSCs identified genes essential for their susceptibility to CAR-mediated killing, including RELA and NPLOC4, the knockout of which altered the tumor-immune signaling axis and increased responsiveness of CAR therapy. Overall, CRISPR screening of CAR T cells and GSCs are promising strategies to discover avenues and inform potential combinatorial approaches for enhancing CAR T cell therapeutic efficacy against GBM, and can be extended to reveal key mediators of immunotherapy responses across solid tumors.

Project description:Systematic discovery of CRISPR-boosted CAR T cell immunotherapies

Project description:Natural killer (NK) cells are an innate immune cell type that serves at the first level of defense against pathogens and cancer. NK cells have clinical potential; However, multiple current limitations exist that naturally hinder the successful implementation of NK cell therapy against cancer, including their effector function, persistence, and tumor infiltration. To unbiasedly identify genes underlying critical NK cell characteristics against cancer, we perform functional mapping of tumor infiltrating NK (TINK) cells by both in vivo AAV-CRISPR screens and single-cell sequencing. We establish a strategy with AAV-SleepingBeauty(SB)-CRISPR screening leveraging a focused high-density sgRNA library, and perform four independent in vivo tumor infiltration screens of primary NK cells in mouse models of melanoma, breast cancer, pancreatic cancer, and glioblastoma. In parallel, we characterize single-cell transcriptomic landscapes of tumor-infiltrating NK cells, which identifies previously unexplored sub-populations of NK cells with distinct expression profiles, a shift from immature to mature NK (mNK) cells in the tumor microenvironment (TME), and decreased expression of mature marker genes in mNK cells. CALHM2, a calcium homeostasis modulator previously not linked to NK function, emerges as a convergent hit from both CRISPR screen and single-cell data. CALHM2 knockout NK cells show enhancement of in vitro cytotoxicity and in vivo tumor infiltration in both mouse primary NK and human chimeric antigen receptor (CAR)-NK cells. Re-introduction of CALHM2 mRNA reverses CALHM2 knockout phenotype of NK cytotoxicity and degranulation. Importantly, in a solid tumor model that is completely resistant to adoptive cell therapy of unmodified CAR-NK cells, CALHM2 knockout CAR-NK cells show potent in vivo anti-tumor efficacy. Human primary NK cell study with multiple donors reveals that CALHM2 knockout enhances cytotoxicity, degranulation and cytokine production of NK cells. Transcriptomics profiling of human primary NK cells reveal multiple enriched pathways of downstream genes upon CALHM2 knockout in both baseline and stimulated conditions. These data identify endogenous cellular genetic checkpoints that naturally limit NK cell function, and pinpoint CALHM2 as a key factor in which genetic modification can be engineered to enhance NK cell-based immunotherapies.

Project description:Natural killer (NK) cells are an innate immune cell type that serves at the first level of defense against pathogens and cancer. NK cells have clinical potential; However, multiple current limitations exist that naturally hinder the successful implementation of NK cell therapy against cancer, including their effector function, persistence, and tumor infiltration. To unbiasedly identify genes underlying critical NK cell characteristics against cancer, we perform functional mapping of tumor infiltrating NK (TINK) cells by both in vivo AAV-CRISPR screens and single-cell sequencing. We establish a strategy with AAV-SleepingBeauty(SB)-CRISPR screening leveraging a focused high-density sgRNA library, and perform four independent in vivo tumor infiltration screens of primary NK cells in mouse models of melanoma, breast cancer, pancreatic cancer, and glioblastoma. In parallel, we characterize single-cell transcriptomic landscapes of tumor-infiltrating NK cells, which identifies previously unexplored sub-populations of NK cells with distinct expression profiles, a shift from immature to mature NK (mNK) cells in the tumor microenvironment (TME), and decreased expression of mature marker genes in mNK cells. CALHM2, a calcium homeostasis modulator previously not linked to NK function, emerges as a convergent hit from both CRISPR screen and single-cell data. CALHM2 knockout NK cells show enhancement of in vitro cytotoxicity and in vivo tumor infiltration in both mouse primary NK and human chimeric antigen receptor (CAR)-NK cells. Re-introduction of CALHM2 mRNA reverses CALHM2 knockout phenotype of NK cytotoxicity and degranulation. Importantly, in a solid tumor model that is completely resistant to adoptive cell therapy of unmodified CAR-NK cells, CALHM2 knockout CAR-NK cells show potent in vivo anti-tumor efficacy. Human primary NK cell study with multiple donors reveals that CALHM2 knockout enhances cytotoxicity, degranulation and cytokine production of NK cells. Transcriptomics profiling of human primary NK cells reveal multiple enriched pathways of downstream genes upon CALHM2 knockout in both baseline and stimulated conditions. These data identify endogenous cellular genetic checkpoints that naturally limit NK cell function, and pinpoint CALHM2 as a key factor in which genetic modification can be engineered to enhance NK cell-based immunotherapies.

Project description:Natural killer (NK) cells are an innate immune cell type that serves at the first level of defense against pathogens and cancer. NK cells have clinical potential; However, multiple current limitations exist that naturally hinder the successful implementation of NK cell therapy against cancer, including their effector function, persistence, and tumor infiltration. To unbiasedly identify genes underlying critical NK cell characteristics against cancer, we perform functional mapping of tumor infiltrating NK (TINK) cells by both in vivo AAV-CRISPR screens and single-cell sequencing. We establish a strategy with AAV-SleepingBeauty(SB)-CRISPR screening leveraging a focused high-density sgRNA library, and perform four independent in vivo tumor infiltration screens of primary NK cells in mouse models of melanoma, breast cancer, pancreatic cancer, and glioblastoma. In parallel, we characterize single-cell transcriptomic landscapes of tumor-infiltrating NK cells, which identifies previously unexplored sub-populations of NK cells with distinct expression profiles, a shift from immature to mature NK (mNK) cells in the tumor microenvironment (TME), and decreased expression of mature marker genes in mNK cells. CALHM2, a calcium homeostasis modulator previously not linked to NK function, emerges as a convergent hit from both CRISPR screen and single-cell data. CALHM2 knockout NK cells show enhancement of in vitro cytotoxicity and in vivo tumor infiltration in both mouse primary NK and human chimeric antigen receptor (CAR)-NK cells. Re-introduction of CALHM2 mRNA reverses CALHM2 knockout phenotype of NK cytotoxicity and degranulation. Importantly, in a solid tumor model that is completely resistant to adoptive cell therapy of unmodified CAR-NK cells, CALHM2 knockout CAR-NK cells show potent in vivo anti-tumor efficacy. Human primary NK cell study with multiple donors reveals that CALHM2 knockout enhances cytotoxicity, degranulation and cytokine production of NK cells. Transcriptomics profiling of human primary NK cells reveal multiple enriched pathways of downstream genes upon CALHM2 knockout in both baseline and stimulated conditions. These data identify endogenous cellular genetic checkpoints that naturally limit NK cell function, and pinpoint CALHM2 as a key factor in which genetic modification can be engineered to enhance NK cell-based immunotherapies.

Project description:Chimeric antigen receptor-T cell (CAR-T) therapy in T cell malignancies faces fratricide, T cell aplasia, and product contamination. We developed an universal anti-CD7 CAR-T cells in which TRAC, CD7 and HLA-II were disrupted, while E-cadherin (a NK cell inhibitory molecule) was introduced, to mitigate graft versus host disease (GvHD), fratricide and rejection. Furthermore, we designed a subtle receptor, bbzg-CAR, comprising not only conventional domains (anti-CD7 scFv, 4-1BB co-stimulatory domain, and CD3ζ signaling domain), but also the intracellular domain of common γ chain. Bbzg-CAR-T exerted anti-tumor effects superior to those of conventional universal CAR-T cells. In adoptive therapy for relapsed/refractory (r/r) patients, no dose-limiting toxicity, GvHD, immune effector cell-associated neurotoxicity or severe cytokine release syndrome (grade≥3) was observed. Nine patients (82%) showed objective response with, complete response rates of 75% and 33.3% in r/r leukemia and lymphoma respectively. Preliminary safety and efficacy of this universal CAR-T product was achieved in CD7+ malignancies.

Project description:CRISPR knockout screens have accelerated the discovery of important cancer genetic dependencies. However, traditional CRISPR-Cas9 screens are limited in their ability to assay the function of redundant or duplicated genes. Paralogs in multi-gene families constitute two-thirds of the protein-coding genome, so this blind spot is the rule, not the exception. To overcome the limitations of single gene CRISPR knockout screens, we developed paired guide RNAs for Paralog gENetic interaction mapping (pgPEN), a pooled CRISPR/Cas9 approach which targets over a thousand duplicated human paralogs in single knockout and double knockout configurations. We applied pgPEN to two cell lineages and discovered that over 10% of human paralogs exhibit synthetic lethality in at least one cellular context. We recovered known synthetic lethal paralogs such as MAP2K1/MAP2K2, important drug targets such as CDK4/CDK6, and numerous other synthetic lethal pairs such as CCNL1/CCNL2. In addition, we identified ten tumor suppressive paralog pairs whose compound loss promotes cell growth. These findings identify a large number of previously unidentified essential gene families and nominate new druggable targets for oncology drug discovery.

Project description:Genome-wide CRISPR screens aid researchers in discovering genes that function across a broad range of cellular mechanisms. Loss-of-function screens are particularly useful for identifying essential genes through loss of cell fitness measurements. However, loss-of-function screens are more challenging compared to gain-of-function screens due to the limited dynamic range of decreased sgRNA sequence detection. Here we describe Guide-Only control CRISPR (GO-CRISPR), an improved loss-of-function screening workflow, and its companion software package, Toolset for the Ranked Analysis of GO-CRISPR Screens (TRACS; https://github.com/developerpiru/TRACS). We demonstrate a typical GO-CRISPR workflow in a non-proliferative 3D spheroid model of dormant high grade serous ovarian cancer. We compare the results from our GO-CRISPR screen and demonstrate the discovery of novel pathways that were not possible using the currently established CRISPR screening method.