Project description:Antigenic cancer persister cells survive direct T cell attack

Project description:Antigenic cancer persister cells survive direct T cell attack

Project description:The genetic circuits that allow cancer cells to evade destruction by the host immune system remain poorly understood. To identify a phenotypically robust core set of genes and pathways that facilitate cancer cell-intrinsic evasion to cytotoxic T lymphocyte (CTL)-mediated killing, we performed genome-wide CRISPR screens across a panel of genetically diverse cancer models cultured in the presence of CTLs. We uncovered a core set of 182 genes whose individual perturbation leads to either cancer cell sensitivity or resistance to CTL toxicity. Systematic exploration of our dataset using genetic co-similarity reveals the hierarchical and coordinated nature by which genes and pathways act to orchestrate intrinsic CTL evasion, with discrete functional modules controlling the interferon response and tumor necrosis factor alpha (TNFa)-induced cytotoxicity emerging as dominant sub-phenotypes. Our data establish a central role for previously identified negative regulators of the Type II interferon response (e.g. Ptpn2, Socs1, Adar1) in mediating intrinsic CTL evasion and demonstrate a requirement for the lipid droplet related gene Fitm2 for maintaining cell fitness upon exposure to interferon gamma (IFNg). Additionally, we identify the autophagy pathway as a conserved mediator of cancer intrinsic CTL evasion, required to resist cytokine-mediated cytotoxicity caused by IFNg and TNFa. By mapping cytokine- and CTL-based genetic interactions, as well as in vivo CRISPR screens, we illuminate the pleiotropic nature by which autophagy acts to orchestrate intrinsic CTL evasion and highlight the importance of our observed effects within the tumor microenvironment. Collectively, our data expands our appreciation of the genetic circuits that contribute to cancer intrinsic immune evasion, highlighting the importance of leveraging systematic functional genomics approaches for furthering our understanding of this biology.

Project description:The genetic circuits that allow cancer cells to evade destruction by the host immune system remain poorly understood. To identify a phenotypically robust core set of genes and pathways that facilitate cancer cell-intrinsic evasion to cytotoxic T lymphocyte (CTL)-mediated killing, we performed genome-wide CRISPR screens across a panel of genetically diverse cancer models cultured in the presence of CTLs. We uncovered a core set of 182 genes whose individual perturbation leads to either cancer cell sensitivity or resistance to CTL toxicity. Systematic exploration of our dataset using genetic co-similarity reveals the hierarchical and coordinated nature by which genes and pathways act to orchestrate intrinsic CTL evasion, with discrete functional modules controlling the interferon response and tumor necrosis factor alpha (TNFa)-induced cytotoxicity emerging as dominant sub-phenotypes. Our data establish a central role for previously identified negative regulators of the Type II interferon response (e.g. Ptpn2, Socs1, Adar1) in mediating intrinsic CTL evasion and demonstrate a requirement for the lipid droplet related gene Fitm2 for maintaining cell fitness upon exposure to interferon gamma (IFNg). Additionally, we identify the autophagy pathway as a conserved mediator of cancer intrinsic CTL evasion, required to resist cytokine-mediated cytotoxicity caused by IFNg and TNFa. By mapping cytokine- and CTL-based genetic interactions, as well as in vivo CRISPR screens, we illuminate the pleiotropic nature by which autophagy acts to orchestrate intrinsic CTL evasion and highlight the importance of our observed effects within the tumor microenvironment. Collectively, our data expands our appreciation of the genetic circuits that contribute to cancer intrinsic immune evasion, highlighting the importance of leveraging systematic functional genomics approaches for furthering our understanding of this biology.

Project description:The genetic circuits that allow cancer cells to evade destruction by the host immune system remain poorly understood. To identify a phenotypically robust core set of genes and pathways that facilitate cancer cell-intrinsic evasion to cytotoxic T lymphocyte (CTL)-mediated killing, we performed genome-wide CRISPR screens across a panel of genetically diverse cancer models cultured in the presence of CTLs. We uncovered a core set of 182 genes whose individual perturbation leads to either cancer cell sensitivity or resistance to CTL toxicity. Systematic exploration of our dataset using genetic co-similarity reveals the hierarchical and coordinated nature by which genes and pathways act to orchestrate intrinsic CTL evasion, with discrete functional modules controlling the interferon response and tumor necrosis factor alpha (TNFa)-induced cytotoxicity emerging as dominant sub-phenotypes. Our data establish a central role for previously identified negative regulators of the Type II interferon response (e.g. Ptpn2, Socs1, Adar1) in mediating intrinsic CTL evasion and demonstrate a requirement for the lipid droplet related gene Fitm2 for maintaining cell fitness upon exposure to interferon gamma (IFNg). Additionally, we identify the autophagy pathway as a conserved mediator of cancer intrinsic CTL evasion, required to resist cytokine-mediated cytotoxicity caused by IFNg and TNFa. By mapping cytokine- and CTL-based genetic interactions, as well as in vivo CRISPR screens, we illuminate the pleiotropic nature by which autophagy acts to orchestrate intrinsic CTL evasion and highlight the importance of our observed effects within the tumor microenvironment. Collectively, our data expands our appreciation of the genetic circuits that contribute to cancer intrinsic immune evasion, highlighting the importance of leveraging systematic functional genomics approaches for furthering our understanding of this biology.

Project description:The genetic circuits that allow cancer cells to evade destruction by the host immune system remain poorly understood. To identify a phenotypically robust core set of genes and pathways that facilitate cancer cell-intrinsic evasion to cytotoxic T lymphocyte (CTL)-mediated killing, we performed genome-wide CRISPR screens across a panel of genetically diverse cancer models cultured in the presence of CTLs. We uncovered a core set of 182 genes whose individual perturbation leads to either cancer cell sensitivity or resistance to CTL toxicity. Systematic exploration of our dataset using genetic co-similarity reveals the hierarchical and coordinated nature by which genes and pathways act to orchestrate intrinsic CTL evasion, with discrete functional modules controlling the interferon response and tumor necrosis factor alpha (TNFa)-induced cytotoxicity emerging as dominant sub-phenotypes. Our data establish a central role for previously identified negative regulators of the Type II interferon response (e.g. Ptpn2, Socs1, Adar1) in mediating intrinsic CTL evasion and demonstrate a requirement for the lipid droplet related gene Fitm2 for maintaining cell fitness upon exposure to interferon gamma (IFNg). Additionally, we identify the autophagy pathway as a conserved mediator of cancer intrinsic CTL evasion, required to resist cytokine-mediated cytotoxicity caused by IFNg and TNFa. By mapping cytokine- and CTL-based genetic interactions, as well as in vivo CRISPR screens, we illuminate the pleiotropic nature by which autophagy acts to orchestrate intrinsic CTL evasion and highlight the importance of our observed effects within the tumor microenvironment. Collectively, our data expands our appreciation of the genetic circuits that contribute to cancer intrinsic immune evasion, highlighting the importance of leveraging systematic functional genomics approaches for furthering our understanding of this biology.

Project description:Cytotoxic T lymphocytes (CTL) kill malignant and infected cells via cytotoxic proteins such as granzyme B (GzmB) that are released into the immunological synapse in the form of ~110 nm supramolecular attack particles (SMAPs). However, it is not known where SMAPs are stored in the cell and how they are released. To address this, we utilized knock-in mice to label fusogenic cytotoxic granules with synaptobrevin2-mRFP. We identified two classes of fusion-competent granules, single core granules (SCG) and multi core granules (MCG), with different diameter, morphology, and protein composition. Functional analyses demonstrate that both classes of granules fuse with the plasma membrane at the IS. SCG fusion resulted in rapid dispersal of GzmB. MCG labelled with the SMAP marker thrombospondin-1 and their fusion events resulted in deposition of SMAPs. The CTL attack strategy thus includes SCG fusion to disperse immediately active cytotoxic proteins and parallel MCG fusion to deposit concentrated latent SMAPs onto the target.

Project description:Induction of cell death represents a primary goal of most anti-cancer treatments. Despite the efficacy of such approaches, a small population of “persisters” develop evasion strategies to therapy-induced cell death. While previous studies have identified mechanisms of resistance to apoptosis, the mechanisms by which persisters dampen other forms of cell death, such as pyroptosis, remain to be elucidated. Pyroptosis is a form of inflammatory cell death that involves formation of membrane pores, ion gradient imbalance, water inflow and membrane rupture. Herein, we investigate mechanisms by which cancer persisters resist pyroptosis, survive, then proliferate in the presence of tyrosine kinase inhibitors (TKI). Lung, prostate and esophageal cancer persister cells remaining after treatments exhibited several hallmarks indicative of pyroptosis resistance. The inflammatory attributes of persisters included chronic activation of inflammasome, STING, and type I interferons. Comprehensive metabolomic characterization uncovered that TKI-induced pyroptotic persisters display high methionine consumption and excessive taurine production. Elevated methionine flux or exogenous taurine maintained plasma membrane integrity via osmolyte-mediated effects. Increased dependency on methionine flux decreased the level of one carbon metabolism intermediate S-(5'-adenosyl)-L-homocysteine, a determinant of cell methylation capacity. The consequent increase in methylation potential induced DNA hypermethylation of genes regulating metal ion balance and intrinsic immune response. This enabled thwarting TKI resistance by using the hypomethylating agent decitabine. In summary, the evolution of resistance to pyroptosis can occur via a stepwise process of physical acclimation and epigenetic changes without existing or recurrent mutations. 

Project description:Mycobacterium tuberculosis (MTB) generates phenotypic diversity to persist and survive the harsh conditions encountered during infection. MTB avoids immune effectors and antibacterial killing by entering into distinct physiological states. The surviving cells, persisters, are a major barrier to the timely and relapse-free treatment of tuberculosis (TB). We present for the first time, PerSort, a method to isolate and characterize persisters in the absence of antibiotic, or other pressure. We demonstrate the value of PerSort to isolate translationally dormant cells that pre-exist in small numbers within Mycobacterium spp. cultures growing under optimal conditions, but which dramatically increased in proportion under stress conditions. The translationally dormant subpopulation exhibited multidrug tolerance and regrowth properties consistent with persister cells. Furthermore, PerSort enabled single-cell transcriptional profiling that provided evidence that the translationally dormant persisters were generated through a variety of mechanisms, including vapC30, mazF, and relA/spoT overexpression. Finally, we demonstrate that notwithstanding the varied mechanisms by which the persister cells were generated, they converge on a similar low oxygen metabolic state that was reversed through activation of respiration to rapidly eliminate persisters fostered under host-relevant stress conditions. We conclude that PerSort provides a new tool to study MTB persisters, enabling targeted strategies to improve and shorten the treatment of TB.

Project description:Persisters represent a small bacterial population that is dormant and that survives under antibiotic treatment without experiencing genetic adaptation. Persisters are also considered one of the major reasons for recalcitrant chronic bacterial infections. Although several mechanisms of persister formation have been proposed, it is not clear how cells enter the dormant state in the presence of antibiotics or how persister cell formation can be effectively controlled. A fatty acid compound, cis-2-decenoic acid, was reported to decrease persister formation as well as revert the dormant cells to a metabolically active state. We reasoned that some fatty acid compounds may be effective in controlling bacterial persistence because they are known to benefit host immune systems. This study investigated persister cell formation by pathogens that were exposed to nine fatty acid compounds during antibiotic treatment. We found that three medium chain unsaturated fatty acid ethyl esters (ethyl trans-2-decenoate, ethyl trans-2-octenoate, and ethyl cis-4-decenoate) decreased the level of Escherichia coli persister formation up to 110-fold when cells were exposed to ciprofloxacin or ampicillin antibiotics. RNA sequencing analysis and gene deletion persister studies elucidated that these fatty acids inhibit bacterial persistence by regulating antitoxin HipB. A similar persister cell reduction was observed for pathogenic E. coli EDL933, Pseudomonas aeruginosa PAO1, and Serratia marcescens ICU2-4 strains. This study demonstrates that fatty acid ethyl esters can be used to disrupt bacterial dormancy to combat persistent infectious diseases.