Lung cancer is the leading cause of death worldwide. Adenocarcinomas, the most common histological subtype of non-small cell lung cancer (NSCLC), are frequently associated with activating mutations in the epidermal growth factor receptor (EGFR) gene. Although these patients often respond clinically to the EGFR tyrosine kinase inhibitors erlotinib and gefitinib, relapse inevitably occurs, suggesting the development of escape mechanisms that promote cell survival. Using a loss-of-function, whole genome shRNA screen, we identified that the canonical Wnt pathway contributes to the maintenance of NSCLC cells during EGFR inhibition, particularly the poly-ADP-ribosylating enzymes tankyrase 1 and 2 that positively regulate canonical Wnt signaling. Inhibition of tankyrase and various other components of the Wnt pathway with shRNAs or small molecules significantly increased the efficacy of EGFR inhibitors both in vitro and in vivo. Our findings therefore reveal a critical role for tankyrase and the canonical Wnt pathway in maintaining lung cancer cells during EGFR inhibition. Targeting the Wnt-tankyrase-β-catenin pathway together with EGFR inhibition may improve clinical outcome in patients with NSCLC.
Purpose The emergence of EGFR-inhibitors such as gefitinib, erlotinib and osimertinib has provided novel treatment opportunities in EGFR-driven non-small cell lung cancer (NSCLC). However, most patients with EGFR-driven cancers treated with these inhibitors eventually relapse. Recent efforts have identified the canonical Wnt pathway as a mechanism of protection from EGFR-inhibition and that inhibiting tankyrase, a key player in this pathway, is a potential therapeutic strategy for the treatment of EGFR-driven tumors. Experimental Design We performed a preclinical evaluation of tankyrase inhibitor AZ1366 in combination with multiple EGFR-inhibitors across NSCLC lines, characterizing its anti-tumor activity, impingement on canonical Wnt signaling and effects on gene expression. We performed pharmacokinetic (PK) and pharmacodynamic (PD) profiling of AZ1366 in mice and evaluated its therapeutic activity in an orthotopic NSCLC model. Results In combination with EGFR-inhibitors, AZ1366 synergistically suppressed proliferation of multiple NSCLC lines and amplified global transcriptional changes brought about by EGFR-inhibition. Its ability to work synergistically with EGFR inhibition coincided with its ability to modulate the canonical Wnt pathway. PK and PD profiling of AZ1366-treated orthotopic tumors demonstrated clinically-relevant serum drug levels and intratumoral target inhibition. Finally, co-administration of an EGFR inhibitor and AZ1366 provided better tumor control and improved survival for Wnt-responsive lung cancers in an orthotopic mouse model. Conclusions Tankyrase inhibition is a potent route of tumor control in EGFR-dependent NSCLC with confirmed dependence on canonical Wnt signaling. These data strongly support further evaluation of tankyrase inhibition as a co-treatment strategy with EGFR inhibition in an identifiable subset of EGFR-driven NSCLC.
Patients with lung cancers harboring anaplastic lymphoma kinase (ALK) gene fusions benefit from treatment with ALK kinase inhibitors but acquired resistance inevitably arises. A better understanding of proximal ALK signaling mechanisms may identify sensitizers to ALK inhibitors that disrupt the balance between pro-survival and pro-apoptotic effector signals. Using affinity purification coupled with mass spectrometry in an ALK fusion lung cancer cell line (H3122), we generated an ALK signaling network and investigated signaling activity using tyrosine phosphoproteomics. We identified a network of 464 proteins composed of subnetworks with differential response to ALK inhibitors. A small hairpin RNA screen targeting 407 proteins in this network revealed 64 and 9 proteins whose loss sensitized cells to crizotinib and alectinib, respectively. Among these, knocking down fibroblast growth factor receptor substrate 2 (FRS2) or coiled-coil and C2 domain-containing protein 1A (CC2D1A, both scaffolding proteins, sensitized multiple ALK fusion cell lines to the ALK inhibitors crizotinib and alectinib. Collectively, our data provides a resource that enhances our understanding of signaling and drug resistance networks consequent to ALK fusions, and identifies potential targets to improve the efficacy of ALK inhibitors in patients.
Adenoviral vectors expressing Cre recombinase are commonly used to initiate tumor formation in murine lung cancer models. While these vectors are designed to target genetic recombination to lung epithelial cells, adenoviruses can infect additional cell types that potentially influence tumor development. Our goal was to explore the consequences of adenoviral-mediated alveolar macrophage (AM) transduction in a Kras-initiated lung tumor model. As expected, treatment of animals harboring the KrasLSL-G12D allele and an inducible green fluorescence protein (GFP) tracking allele with an adenoviral vector expressing Cre recombinase under the control of the cytomegalovirus (CMV) promoter (Ad5-CMV-Cre), caused GFP-positive lung adenocarcinomas. Surprisingly, however, up to 70% of the total GFP+ cells were AM, and GFP+ AM could be detected 6 months after tumor initiation, and transduced AM demonstrated Kras activation and increased proliferation. In contrast, recombination was not detected in other immune cell populations and AM recombination could be eliminated by tumor initiation with an adenovirus expressing Cre recombinase under the control of the surfactant protein C (SPC) promoter. In addition, AM isolated from KrasLSL-G12D animals and transduced by Ad5-CMV-Cre ex vivo displayed prolonged survival in vitro and increased the growth of murine lung adenocarcinoma CMT/167 cells when co-injected in an orthotopic flank model. Given the importance of the immune system in tumor development and progression, inadvertent AM transduction by Ad5-CMV-Cre merits careful consideration during lung cancer model selection particularly if studies evaluating the tumor-immune interactions are planned.
Aging is a major risk factor in increased lung cancer incidence. While most research has focused on age-associated mutation accumulation to explain the late-life increase in cancer incidence, there are tissue environmental forces that both impede and promote cancer evolution. Just as organismal evolution is known to be driven by environmental changes, cellular (somatic) evolution in our bodies is similarly driven by changes in tissue environments. Environmental change promotes selection for new phenotypes that are adaptive to the new context. In our tissues, aging or insult-driven alterations in tissues drives selection for adaptive mutations, and some of these mutations can confer malignant phenotypes. Chronic, low-level inflammation has been associated with aging, termed inflammaging, yet how age-associated changes in lung tissue microenvironments contribute to increased lung cancer incidence has remained largely unknown. Since chronic inflammation has been shown to contribute to tumor development, we hypothesized that inflammaging contributes to increased oncogenic adaptation in the lung. Using either viral delivery of CRISPR constructs to mediate EML4-ALK translocations or ectopic expression of KRAS-G12D, we showed increased adenoma formation in old mice. Importantly, in the EML4-ALK model, we showed that the overexpression of alpha-1 antitrypsin (AAT) in old mice resulted in lower adenoma counts compared to their old wild type counterparts. Flow cytometric analysis of immune cells isolated from bronchoalveolar fluid of young and old mice showed an altered immune landscape, such as increased neutrophils, gamma delta T cells, and Foxp3+ regulatory T cells. Furthermore, analysis of the single-cell RNAseq data from Tabula Muris Consortium demonstrated increased exhaustion markers in the CD8+ T cells and regulatory T cells. Separately, Gene Set Enrichment Analysis (GSEA) of the differential gene expressions of lung epithelial cells isolated from young and old mice revealed enriched pathways related to immune activation and inflammatory response, and immune-suppression markers. Lastly, bulk RNA-seq from lungs of young, old, and old mice overexpressing AAT revealed increased immune cell exhaustion markers and that the overexpression of AAT partially reversed this increase. Finally, analysis of Genotype-Tissue Expression (GTEx) data comparing gene expressions in lungs of young and old humans similarly showed enriched pathways related to immune activation and increased T cell exhaustion markers in the elderly. In addition, using deconvolution methods CiberSort and xCell, we demonstrated altered innate and adaptive immune cell populations, for example, increased neutrophils and regulatory T cells, that are associated with advanced age, similar to aging mice. In conclusion, we showed that there is an exhausted immune microenvironment in aging lungs, that inflammation contributes to the increased tumor initiation, and that decreasing inflammation could decrease the lung tumor incidence by reactivating the immune system. Citation Format: Shi Biao Chia, Catherine Pham-Danis, Hannah Scarborough, Nathaniel Little, Etienne P. Danis, Andrew E. Goodspeed, Charles Dinarello, James DeGregori. Altered immune landscape in aging lungs contributes to malignant evolution [abstract]. In: Proceedings of the AACR Special Conference on the Evolutionary Dynamics in Carcinogenesis and Response to Therapy; 2022 Mar 14-17. Philadelphia (PA): AACR; Cancer Res 2022;82(10 Suppl):Abstract nr A026.
Why do we get cancer? Why is cancer highly associated with old age? Of course, aging is associated with the accumulation of more mutations, and some of these mutations can contribute to cancer phenotypes. But we now understand that carcinogenesis is much more complex than originally appreciated. In particular, there are tissue environmental forces that both impede and promote cancer evolution. Just as organismal evolution is known to be driven by environmental changes, cellular (somatic) evolution in our bodies is similarly driven by changes in tissue environments, whether caused by the normal process of aging, by lifestyle choices or by extrinsic exposures. Environmental change promotes selection for new phenotypes that are adaptive to the new context. In our tissues, aging or insult-driven alterations in tissues drives selection for adaptive mutations, and some of these mutations can confer malignant phenotypes. We have been using mouse models of cancer initiation, mathematical models of cellular evolution, and analyses of human tissue samples to better understand the evolutionary forces that control somatic cell evolution and thus cancer risk. We have shown that aging and inflammation dependent changes in tissue environments dramatically dictate whether cancer-causing mutations are advantageous to stem cells in our tissues, starting the cells down the path to cancer. Our studies have focused on cancer initiation within the hematopoietic system and the lung. These studies have also uncovered molecular explanations for mutation-driven adaptation to aged and inflammatory tissue environments. In all, these studies indicate that strategies to prevent or treat cancers will need to incorporate interventions that alter tissue microenvironments. While we largely cannot prevent mutation accumulation through our lives, we do have the ability to manipulate tissue environments so as to change the evolutionary trajectories of cells with cancer-causing mutations. Citation Format: Catherine Pham-Danis, Andrii Rozhok, Hannah Scarborough, Nathaniel Little, Curtis Henry, Travis Nemkov, Kirk Hansen, James DeGregori. In the light of evolution: Why do we get more cancers in old age? [abstract]. In: Proceedings of the AACR Virtual Special Conference on Tumor Heterogeneity: From Single Cells to Clinical Impact; 2020 Sep 17-18. Philadelphia (PA): AACR; Cancer Res 2020;80(21 Suppl):Abstract nr IA13.
Why do we get cancer? Why is cancer highly associated with old age? Of course, aging is associated with the accumulation of more mutations, and some of these mutations can contribute to cancer phenotypes. But we now understand that carcinogenesis is much more complex than originally appreciated. In particular, there are tissue environmental forces that both impede and promote cancer evolution. Just as organismal evolution is known to be driven by environmental changes, cellular (somatic) evolution in our bodies is similarly driven by changes in tissue environments, whether caused by the normal process of aging, by lifestyle choices or by extrinsic exposures. Environmental change promotes selection for new phenotypes that are adaptive to the new context. In our tissues, aging or insult-driven alterations in tissues drives selection for adaptive mutations, and some of these mutations can confer malignant phenotypes. We have been using mouse models of cancer initiation, mathematical models of cellular evolution, and analyses of human tissue samples to better understand the evolutionary forces that control somatic cell evolution and thus cancer risk. We have shown that aging and inflammation dependent changes in tissue environments dramatically dictate whether cancer-causing mutations are advantageous to stem cells in our tissues, starting the cells down the path to cancer. Our studies have focused on cancer initiation within the hematopoietic system and the lung. These studies have also uncovered molecular explanations for mutation-driven adaptation to aged and inflammatory tissue environments. In all, these studies indicate that strategies to prevent or treat cancers will need to incorporate interventions that alter tissue microenvironments. Citation Format: James DeGregori, Catherine Pham-Danis, Andrii I Rozhok, Edward J. Evans, Fabio Marongiu, Hannah Scarborough, Curtis J. Henry. Aging, tissue ecology, and the evolution of cancer within us [abstract]. In: Proceedings of the AACR Special Conference on the Evolutionary Dynamics in Carcinogenesis and Response to Therapy; 2022 Mar 14-17. Philadelphia (PA): AACR; Cancer Res 2022;82(10 Suppl):Abstract nr IA012.
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