Project description:Approximately 15% of all lung cancer cases are small cell lung cancer (SCLC), which originates from neuroendocrine cells lining the airways (bronchi) of the lung. SCLC is known for its aggressive nature and swift growth, resulting in a five-year survival rate of around 6%. Understanding the genetic pathways that drive tumor development remains an ongoing challenge. In our study, we employed an in vivo multiplexed approach, known as Tuba-seq, to investigate the impact of the functional loss of 18 putative tumor suppressors. Our screening unveiled Pten and Keap1 as top candidates; knocking out either one promoted both tumor initiation and progression. We identified the Keap1/Cul3/Nrf2 pathway as a pivotal regulator for SCLC development, particularly in regulating the susceptibility of SCLC to ferroptosis. Our work not only established an in vivo multiplexed approach for assessing the role of tumor suppressors in SCLC but also uncovers a previously unappreciated role of Keap1 in SCLC.

Project description:Here, using a quantitative autochthonous mouse model system and performing iterative in vivo functional screens (mainly with programmable multiplexed CRISPR/Cas9-induced genotypes via ultra-deep sequencing of DNA barcoded tumors: Tuba-seq), we uncover genetic and biochemical changes that enable efficient lung tumor initiation in the absence of oncogene alterations. Through the generation of hundreds of diverse combinatorial tumor suppressor alterations, we demonstrate that inactivation of suppressors of the RAS/MAPK and PI3K pathways allows for stepwise and efficient acquisition of growth advantage that can drive the development of oncogene-negative lung adenocarcinoma. Furthermore, we demonstrate that oncogene-negative tumors with activated RAS/MAPK and PI3K pathways are vulnerable to pharmacological inhibition of these signaling axes.

Project description:RNA-seq, LCM sequencing, and Tuba-seq data for the article titled, "A multiplexed in vivo gene knockout approach to identify cancer drivers in small cell lung cancer." This SuperSeries is composed of the SubSeries listed below.

Project description:Cancer-derived loss-of-function mutations in the KEAP1 tumor suppressor gene stabilize the NRF2 transcription factor, resulting in a pro-survival gene expression program that alters cellular metabolism and neutralizes oxidative stress. In a previous study of KEAP1 mutations observed in lung cancer, we classified 40% of the mutations as ‘superbinders’ (superbinders). These mutants bind and ubiquitylate NRF2 but do not promote NRF2 degradation. Here, we further investigated the molecular mechanism(s) driving the superbinder phenotype. BioID-based quantitative proteomic analysis of the R320Q and R470C superbinder mutations revealed increased co-complexed NRF2 without significant alteration to other KEAP1-associated proteins, including CUL3, VCP, and several ubiquitin receptors within the proteasome lid. Dynamic simulation modeling and limited proteolysis analyses suggest that superbinder mutations stabilize residues in KEAP1 that contact NRF2. In cells, KEAP1 R320Q and R470C mutants co-localize with NRF2, p62/SQSTM1 and polyubiquitin in spherical clusters that rapidly fuse and dissolve; KEAP1-NRF2 localization to these clusters requires p62. Expression of R320Q and R470C in lung cancer cells provided resistance to the reactive oxygen species-inducing drug bleomycin. We present a model wherein superbinder mutations alter the conformational dynamics of the KEAP1-NRF2 complex to alter the cycling of KEAP1 between open and closed conformations, thus inhibiting NRF2 degradation.

Project description:Small cell lung cancer (SCLC) is an aggressive subtype of lung cancer whose biology is still poorly understood. Using a multiplexed inhibitor beads assay, we identified active kinases in SCLC. Among those, we found that PKA is critical for the expansion of SCLC in culture and in vivo. PKA promotes the neuroendocrine epithelial state associated with SCLC tumor-initiating cells. Phosphoproteomics analyses identify ~200 PKA substrates and show that PKA controls multiple facets of SCLC growth. Notably, the PP2A phosphatase counteracts the oncogenic effects of PKA, and PP2A activators inhibit SCLC as single agents and with chemotherapy. Our data uncover key signaling networks in SCLC and indicate that targeting the PKA/PP2A pathway may help inhibit this lethal neuroendocrine cancer.

Project description:KEAP1 is a substrate adaptor protein for a CUL3-based E3 ubiquitin ligase. Ubiquitylation and degradation of the antioxidant transcription factor NRF2 is considered the primary function of KEAP1; however, few other KEAP1 substrates have been identified. Because KEAP1 is altered in a number of human pathologies and has been proposed as a potential therapeutic target therein, we sought to better understand KEAP1 through systematic identification of its substrates. Towards this goal, we combined parallel affinity capture proteomics and candidate-based approaches. Substrate-trapping proteomics yielded NRF2 and the related transcription factor NRF1 as KEAP1 substrates. Our targeted investigation of KEAP1 interacting proteins revealed MCM3, an essential subunit of the replicative DNA helicase, as a new substrate. We show that MCM3 is ubiquitylated by the KEAP1-CUL3-RBX1 complex in cells and in vitro. Using ubiquitin remnant profiling, we identify the sites of KEAP1-dependent ubiquitylation in MCM3, and these sites are on predicted exposed surfaces of the MCM2-7 complex. Unexpectedly, we determined that KEAP1 does not regulate total MCM3 protein stability or subcellular localization. Our analysis of a KEAP1 targeting motif in MCM3 suggests MCM3 is a point of direct contact between KEAP1 and the MCM hexamer. Moreover, KEAP1 associates with chromatin in a cell cycle-dependent fashion with kinetics similar to the MCM2-7 complex. KEAP1 is thus poised to affect MCM2-7 dynamics or function rather than MCM3 abundance. Together, these data establish new functions for KEAP1 within the nucleus and identify MCM3 as a novel substrate of the KEAP1-CUL3-RBX1 E3 ligase.

Project description:A multiplexed in vivo gene knockout approach to identify cancer drivers in small cell lung cancer [SCLC Tuba-seq]

Project description:Non-small cell lung cancers (NSCLCs) harbor thousands of passenger events that hide genetic drivers. Even highly recurrent events in NSCLC, such as mutations in PTEN, EGFR, KRAS, and ALK, are only detected in, at most, 30% of patients. Thus, many unidentified low-penetrant events are causing a significant portion of lung cancers. To detect low-penetrance drivers of NSCLC a forward genetic screen was performed in mice using the Sleeping Beauty (SB) DNA transposon as a random mutagen to generate lung tumors in a Pten deficient background. SB mutations coupled with Pten deficiency were sufficient to produce lung tumors in 29% of mice. Pten deficiency alone, without SB mutations, resulted in lung tumors in 11% of mice, while the rate in control mice was ~3%. In addition, thyroid cancer and other carcinomas as well as the presence of bronchiolar and alveolar epithelialization in mice deficient for Pten were also identified. Analysis of common transposon insertion sites identified 76 candidate cancer driver genes. These genes are frequently dysregulated in human lung cancers and implicate several signaling pathways. Cullin3 (Cul3), a member of an ubiquitin ligase complex that plays a role in the oxidative stress response pathway, was identified in the screen and evidence demonstrates that Cul3 functions as a tumor suppressor HumanHT-12 v4 Expression BeadChip Kit for human A549 lung adenocarcinoma cells with CUL3, PTEN, CUL3 and PTEN or no knockdown. A549 cells were stably transfected under Puromycin or Hygromycin selection to knockdown PTEN (SA Biosystems) or CUL3 (Open Biosystems) shRNAs. RNA was extracted in triplicate from each condition and used for microarray

Project description:Small-cell lung cancer (SCLC) is the most fatal form of lung cancer. Intra-tumoral heterogeneity, marked by neuroendocrine (NE) and non-neuroendocrine (non-NE) cell states, defines SCLC, but the drivers of SCLC plasticity are poorly understood. To map the landscape of SCLC tumor microenvironment (TME), we apply spatially resolved transcriptomics and quantitative mass spectrometry-based proteomics to metastatic SCLC tumors obtained via rapid autopsy. The phenotype and overall composition of non-malignant cells in the tumor microenvironment (TME) exhibits substantial variability, closely mirroring the tumor phenotype, suggesting TME-driven reprogramming of NE cell states. We identify cancer-associated fibroblasts (CAF) as a crucial element of SCLC TME heterogeneity, contributing to immune exclusion, and predicting an exceptionally poor prognosis. Together, our work provides the first comprehensive map of SCLC tumor and TME ecosystems, emphasizing their pivotal role in SCLCs adaptable nature, opening possibilities for re-programming the intercellular communications that shape SCLC tumor states.

Project description:Cancer genome sequencing has uncovered substantial complexity in the mutational landscape of tumors. Given this complexity, experimental approaches are necessary to establish the impact of combinations of genetic alterations on tumor biology and to uncover genotype-dependent effects on drug sensitivity. In lung adenocarcinoma, EGFR mutations co-occur with many putative tumor suppressor gene alterations, however the extent to which these alterations contribute to tumor growth and their response to therapy in vivo has not been explored experimentally. By integrating a novel mouse model of oncogenic EGFR-driven Trp53-deficient lung adenocarcinoma with multiplexed CRISPR–Cas9-mediated genome editing and tumor barcode sequencing, we quantified the effects of inactivation of ten putative tumor suppressor genes. Inactivation of Apc, Rb1, or Rbm10 most strongly promoted tumor growth. Unexpectedly, inactivation of Lkb1 or Setd2 – which were the strongest drivers of tumor growth in an oncogenic Kras-driven model – reduced EGFR-driven tumors growth. These results were consistent with the relative frequency of these tumor suppressor gene alterations in human EGFR and KRAS-driven lung adenocarcinomas. Furthermore, Keap1 inactivation reduced the sensitivity of tumors to osimertinib in the EGFRL858R;p53flox/flox model. Importantly, in human EGFR/TP53 mutant lung adenocarcinomas, mutations in the KEAP1 pathway correlated with decreased time on tyrosine kinase inhibitor treatment. Our study highlights how genetic alterations can have dramatically different biological consequences depending on the oncogenic context and that the fitness landscape can shift upon drug treatment.