Project description:Transcription of the mitochondrial genome results in the generation of double stranded RNA. Escape of mitochondrial double stranded RNA (mtdsRNA) into the cytosol is harmful and functions as a class of damage associated molecular pathogen (DAMP) that elicits activation of an MDA5 driven anti-viral response in cells [PMID:30046113,38955468]. To mitigate the deleterious consequences of excess cytosolic mtdsRNA, mammalian cells rely on the mitochondria localized exonuclease polynucleotide phosphorylase (PNPase) to degrade excess mtdsRNA [PMID:20691904,38955468]. Little is known about the role of PNPase in cancer or the cellular consequences that PNPase inhibition and cytosolic mtdsRNA have on tumour cells. Here, we demonstrate that PNPase inactivation in a therapy-resistant Kras-driven, Lkb1 (KL) mutant genetically engineered mouse model (GEMM) of lung cancer resulted in a significant extension in overall survival of mice and reduced tumour cell proliferation. PNPase loss activated a robust interferon-stimulated viral mimicry response in lung tumours that triggered reprograming of lipid metabolism and upregulation of lipid droplet biogenesis in tumour cells. Tumours that escaped PNPase loss transformed into fatty lesions characterized by a massive accumulation of lipid droplets enriched for polyunsaturated fatty acids (PUFAs). Importantly, PNPase null KL tumours were highly sensitive to ferroptosis, a non-canonical form of cell death, which resulted in the near complete clearance of tumours from the lung of mice. Similarly, human lung and pancreatic tumour cells were equally sensitive to targeted pharmacological inhibition of PNPase in combination with ferroptosis induction. These findings identify PNPase as a critical regulator of tumour fate through control of mitochondrial regulated innate immunity and lipid droplet biogenesis, uncovering a new therapeutic vulnerability that may be exploited in therapy resistant lung and pancreatic tumours..

Project description:Background: KRAS mutation is one of the most common oncogenic drivers in NSCLC, however, the response to immunotherapy is heterogeneous owing to the distinct co-occurring genomic alterations. KRAS/LKB1 co-mutated lung adenocarcinoma displays poor response to PD-1 blockade whereas the mechanism remains undetermined. Methods: We explored the specific characteristics of tumor microenvironment (TME) in KL tumors using syngeneic KRASG12DLKB1-/-(KL) and KRASG12DTP53-/- (KP) lung cancer mouse models. The impact of focal adhesion kinase (FAK) inhibitor on KL lung tumors was investigated in vitro and in vivo through evaluation of both KL cell lines and KL lung cancer mouse models. Results: We identified KL tumors as “immune-cold” tumors with excessive extracellular matrix (ECM) collagen deposition that formed a physical barrier to block the infiltration of CD8+T cells. Mechanistically, abundant activated cancer-associated fibroblasts (CAFs) resulted from FAK activation contributed to the formation of the unique TME of KL tumors. FAK inhibition with a small molecular inhibitor could remodel the TME by inhibiting CAFs activation, decreasing collagen deposition and further facilitating the infiltration of anti-tumor immune cells, including CD8+ T cells, DC cells and M1-like macrophages into tumors, hence, converting “immune-cold” KL tumors into “immune-hot” tumors. The combined FAK inhibitor and PD-1 blockade therapy synergistically retarded primary and metastatic tumor growth of KL tumors.Conclusions: Our study identified FAK as a promising intervention target for KL tumors and provided basis for the combination of FAK inhibitor with PD-1 blockade in the management of KL lung cancers.

Project description:Cancer cells heavily rely on nicotinamide adenine dinucleotide phosphate (NADPH) to counteract oxidative stress and facilitate reductive biosynthesis. One crucial route for NADPH production operates through the oxidative pentose phosphate pathway, with a pivotal step at glucose-6-phosphate dehydrogenase (G6PD). This study delves into the repercussions of G6PD ablation on the development of lung tumors driven by the KRAS oncogene and deficient in LKB1 (KL). The research involved comparing the growth of KL lung tumors with or without G6PD, revealing a significant inhibition of KL lung tumor growth upon G6PD loss. Subsequently, RNA-seq analysis was employed to identify the alterations in gene expression following G6PD deletion, providing insights into the underlying mechanisms.

Project description:Knockout or inhibition of glutathione peroxidase 4 (GPX4) induces ferroptosis which has been proposed as a potential therapeutic strategy for cancer. Here we unexpectedly found that inducible knockout of GPX4 in tumor cells significantly promotes non-small cell lung cancer (NSCLC) progression in the autochthonous KrasLSL-G12D/+Lkb1fl/fl (KL) and KrasLSL-G12D/+Tp53fl/fl (KP) mouse models, whereas inducible overexpression of GPX4 in tumor cells had an opposite effect. Mechanistically, knockout of GPX4 in tumor cells results in the accumulation of triacylglycerol (TAG) that was stored in lipid droplets in tumor cells and the efflux of TAG that induces ferroptosis of macrophages in the tumor microenvironment (TME), thereby igniting an immunoinhibitory TME characterized by the dysfunction of anti-tumor T cells and the decrease of antigen-presenting macrophages. Consistently, treatment with liprostatin-1 or inducible overexpression of GPX4 in tumor cells significantly rescues the ferroptosis of macrophages and ignites the activation of T cells in the TME, thereby inhibiting NSCLC progression. These findings highlight a previously uncharacterized role of tumor cell-specific GPX4 in NSCLC progression by modulating TAG metabolism in the TME and provide potential therapeutic strategies for NSCLC.

Project description:KRAS proto-oncogene, GTPase (KRAS)-liver kinase B1 (LKB1)-mutant (KL) non-small cell lung cancer (NSCLC), characterized by a profoundly immunosuppressive tumor microenvironment (TME), is highly resistant to immune checkpoint inhibitors (ICIs). Despite their high tumor mutation burden, KL tumors exhibit low programmed cell death ligand 1 (PD-L1) expression, reduced immune cell infiltration, and suppressed immune signaling pathways. Through systematic genomic analyses, we found that LKB1 loss suppresses dipeptidyl peptidase 4 (DPP4) expression and activity in KRAS-mutant lung cancer. Therefore, we evaluated the therapeutic potential of restoring DPP4 function to improve the immune response in KL lung cancer using patient-derived tumor samples and syngeneic mouse models. Restoration of DPP4 expression reprogrammed the TME and significantly increased immune-related gene signatures, including those involved in T cell migration and natural killer (NK) cell activation. Indeed, DPP4 restoration in three-dimensional microfluidic models enhanced NK cell chemotaxis and activity in targeting tumor spheroids. Furthermore, DPP4 restoration in syngeneic KL murine models synergized with anti-PD-1 therapy to achieve significant tumor regression. These findings suggest that LKB1 loss suppresses DPP4 expression, contributing to the immunosuppressive characteristics of the TME in KL-NSCLC cells, whereas, restoring DPP4 expression promotes NK cell recruitment, facilitates immune activation, and enhances the effects of anti-PD-1 therapy. These results highlight DPP4 as a key immune modulator and a promising therapeutic target, offering a novel strategy to overcome immune resistance and enhance immunotherapy outcomes in this challenging subset of lung cancer.

Project description:Ferroptosis is a new type of programmed cell death induced by iron-dependent lipid peroxidation that has been linked to several malignancies, including non-small cell lung cancer (NSCLC). Finding ferroptosis-associated genes is extremely helpful for guiding and improving ferroptosis-based anti-tumor therapy. To explore ferroptosis-associated genes, we treated A549 cells with DMSO, RSL3 alone, or co-treated with Fer-1 for 24h. Lung cancer-associated transcript 1 (LUCAT1) was identified as a novel ferroptosis suppressor via RNA-seq analysis.

Project description:Transposable elements (TEs) comprising nearly 50% of the genome are generally silenced by epigenetic mechanisms. Epigenetic anti-cancer drugs can lead to their re-expression, however, the role of TEs in tumorigenesis is unknown. Here, we demonstrate that TEs and their activation of a viral mimicry response plays an important tumor suppressive role in inflammation. We discovered that both patients and mice with colitis express TEs that lead to a viral mimicry response. Interestingly, this response inhibits stemness of cancer-initiating cells. Further activation of viral mimicry by DNA hypomethylation inhibits tumorigenesis. Conversely, knockout of the anti-viral signaling protein MAVS promotes tumorigenesis and reverses the anti-tumor effect of DNA hypomethylation, confirming a tumor suppressive role of viral mimicry. Consistent with this finding, patients with colitis-associated dysplasia show decreased expression of TEs and interferon-related genes. These findings suggest that activation of viral mimicry inhibits stemness and plays a key tumor suppressive role in inflammation.

Project description:Loss of function mutations in SMARCB1 are prevalent in pediatric atypical teratoid rhabdoid tumors (ATRTs) and confer an oncogenic dependency on EZH2, providing a compelling rationale for treating these genetically defined cancers via EZH2 inhibition (EZH2i). EZH2i results in tumor regression in SMARCB1-deficient tumors in preclinical studies, but the molecular mechanism has not been fully elucidated. Here we found that the sensitivity of SMARCB1-deficient tumors to EZH2i is associated with the viral mimicry response that depends on both double-stranded RNA (dsRNA) and cytoplasmic DNA sensing pathways. Unlike other epigenetic therapies targeting transcriptional repressors, viral mimicry by EZH2i in SMARCB1-deficient tumors is not triggered by crypt initiation of endogenous retroelements, but rather mediated by increased expression of genes enriched for intronic inverted-repeat Alu (IR-Alu) elements. Interestingly, we found that interferon-stimulated genes (ISGs) are highly enriched for dsRNA-forming intronic IR-Alu elements, suggesting a positive feedback loop whereby interferon response leads to dsRNA formation from intronic ISGs and activation of viral mimicry. Moreover, EZH2i in ATRT cells also enhances the expression of full-length LINE-1 elements, leading to genomic instability and cGAS/STING response in a process dependent on reverse transcriptase activity. Supporting this mechanism, co-depletion of dsRNA sensing and cytoplasmic DNA sensing completely rescues the viral mimicry response to EZH2i in SMARCB1-deficient tumors.

Project description:Loss of function mutations in SMARCB1 are prevalent in pediatric atypical teratoid rhabdoid tumors (ATRTs) and confer an oncogenic dependency on EZH2, providing a compelling rationale for treating these genetically defined cancers via EZH2 inhibition (EZH2i). EZH2i results in tumor regression in SMARCB1-deficient tumors in preclinical studies, but the molecular mechanism has not been fully elucidated. Here we found that the sensitivity of SMARCB1-deficient tumors to EZH2i is associated with the viral mimicry response that depends on both double-stranded RNA (dsRNA) and cytoplasmic DNA sensing pathways. Unlike other epigenetic therapies targeting transcriptional repressors, viral mimicry by EZH2i in SMARCB1-deficient tumors is not triggered by crypt initiation of endogenous retroelements, but rather mediated by increased expression of genes enriched for intronic inverted-repeat Alu (IR-Alu) elements. Interestingly, we found that interferon-stimulated genes (ISGs) are highly enriched for dsRNA-forming intronic IR-Alu elements, suggesting a positive feedback loop whereby interferon response leads to dsRNA formation from intronic ISGs and activation of viral mimicry. Moreover, EZH2i in ATRT cells also enhances the expression of full-length LINE-1 elements, leading to genomic instability and cGAS/STING response in a process dependent on reverse transcriptase activity. Supporting this mechanism, co-depletion of dsRNA sensing and cytoplasmic DNA sensing completely rescues the viral mimicry response to EZH2i in SMARCB1-deficient tumors.

Project description:Epigenetic therapies that alter DNA- and/or histone modifications facilitate transcription of immunogenic repetitive elements that cull cancer cells through ‘viral mimicry’ responses. Paradoxically, cancer-initiating events that include functional inactivation of canonical tumor suppressor proteins also facilitate transcription of repetitive elements. Contributions of repetitive element transcription towards cancer initiation, and the mechanisms by which cancer cells evade lethal viral mimicry responses during tumor initiation remain poorly understood. In this report, we characterize patient-derived premalignant lesions of the fallopian tube along with syngeneic mouse models of epithelial ovarian cancer to explore the earliest events of tumorigenesis following loss of the p53 tumor suppressor protein. We report that p53 loss disrupts constitutive heterochromatin to permit transcription of immunogenic repetitive elements capable of activating viral mimicry responses. While acute viral mimicry activation diminishes cell fitness, chronic viral mimicry activation following p53 loss promotes epigenetic reprogramming that increases tolerance of cytosolic nucleic acids and diminishes cellular immunogenicity as a pro-survival adaptation. This selection process we describe as ‘viral mimicry conditioning’ can be partially attenuated by the reverse transcriptase inhibitor 3TC to delay spontaneous tumorigenesis. Altogether, these results reveal that viral mimicry conditioning following p53 loss selects for diminished cell immunogenicity to promote immune evasion upon cancer initiation. Disruption of viral mimicry conditioning during cancer initiation may represent a pharmacological target for early cancer interception.