Project description:Next-generation sequencing has revolutionized cancer biology by accelerating the unbiased discovery of novel mutations across human cancers. Transforming such discoveries into a conceptual framework of cancer progression requires narrowing the vast number of mutations down to the driver elements, and further reducing these to mutations that govern cancer progression as opposed to tumor initiation. By integrating next-generation RNA-sequencing (RNA-seq) with in vivo selection, we devise an approach that identifies a series of novel recurrent non-synonymous amino acid mutations that are enriched in metastatic breast cancer cells and predicted to significantly alter protein function. These mutations, found in PANX1, RBFA, REST, KRIT1 and ZSWIM6, are detected at higher frequencies in the transcriptomes of two patients’ highly metastatic sub-lines relative to their poorly metastatic parental lines. We functionally characterize the cellular and molecular roles of one of these mutations—a nonsense alteration that yields a truncated pannexin-1 (PANX11-89) plasma membrane megachannel subunit—in metastatic progression. PANX11-89 interacts with full-length PANX1 and augments PANX1 channel activity to promote the survival of cancer cells as they are mechanically deformed. Protection from deformation-induced cell death requires PANX1 channels to release ATP, which acts as a cell autonomous survival signal during mechanical stress. Functional characterization of additional nonsense and missense PANX1 mutations detected in epithelial cancers of the colon, lung, and prostate reveals that these mutants also enhance PANX1-mediated ATP release. In vivo testing of one such truncating mutation detected in a metastatic colorectal tumor also enhances early survival, dissemination and liver metastatic colonization by human colon cancer cells. Finally, pharmacological inhibition of PANX1 inhibits breast cancer metastasis, implicating PANX1 as a novel therapeutic target in cancer. Our findings reveal that ATP release through mechanosensitive PANX1 channels enables cancer cells to overcome a major metastasis suppressive barrier—deformation-induced death in the microvasculature. To systematically identify base-pair mutations present in metastatic cells that may drive cancer progression, we performed whole-transcriptome RNA-sequencing (RNA-seq) of in vivo-selected, highly metastatic human breast cancer cell sub-lines, CN-LM1A and MDA-LM2, as well as the CN34 and MDA-MB-231 parental lines from which they were derived. To minimize the false positive rate and allow for subsequent statistical analysis, we sequenced biological replicates of each cell line. Mutations conferring enhanced metastatic capacity should be enriched in the transcriptomes of highly metastatic cells relative to their less metastatic parental populations.

Project description:MSI (Microsatellite Instability) colorectal cancer (CRC) show improved survival, are less prone to metastasis and show poor response to chemotherapy (compared to MSS tumors). The underlying reasons for these characteristics are still not understood and no specific therapeutic approach for MSI colon tumours (15% of CRC overall) has yet been developed. The MSI process is oncogenic when it affects DNA repeat sequences that have a functional role, e.g. Small Coding Repeats (SCR). MSI also frequently affects Long Non-Coding Repeats (LNCR) in tumour DNA. In contrast to SCR, only a few LNCR are endowed with biological activity. Consequently, this area has received very little attention. Our group recently identified HSP110 mutant chaperone protein in MSI CRC that was generated by somatic deletion of a LNCR. Of interest, HSP110 mutant (due to exon skipping) have anti-oncogenic properties and the survival of MSI CRC patients receiving chemotherapy is positively associated with HSP110 mutations in tumour DNA. The aim of the current project is to identify additional clinically relevant MSI-associated splicing aberrations due to mutations in LNCR located in splice acceptor sites. The four main steps are as follows: 1. To identify exon/intron sites affected by aberrant splicing events due to MSI in CRC . All RNASeq data will be exploited to identify recurrent splicing aberrations (mostly exon skipping) that occur specifically in MSI colon tumours; 2. To investigate for possible functional links between MSI and any detected aberrant splicing events . All specific aberrant splicing events detected by RNAseq in MSI CRC samples will be first confirmed (quantitative RT-PCR) in order to eliminate false positive cases. For validated exon candidates, the allelic profiles of adjacent intronic LNCR will be analysed (PCR and fluorescence genotyping) in CRC cell lines and primary tumours (MSI and MSS), as well as in matching normal mucosa samples in order to assess their polymorphic status; 3. To identify splicing events and LNCR mutations with clinical relevance in MSI CRC patients . All LNCR with a confirmed role in gene splicing in MSI CRC will be analysed. The clinical relevance of candidate genes will be assessed using multivariate survival regression models for Relapse- Free Survival, with interaction terms (response to chemotherapy); 4. To initiate functional studies on a limited number of clinically relevant, cancer-related genes whose splicing is perturbed in MSI cancer cells, and to develop biological tools to simplify screening in future clinical assays Similar to HSP110, we will focus on 4 or 5 mutant proteins that are promising drug therapeutic targets. Functional assays will be developed to further elucidate their role in the pathophysiology of MSI tumours. We also aim to develop biological tools for these candidate genes, such as the detection of wild-type or mutant proteins by immunohistochemistry.

Project description:Previous studies demonstrated that splicing factor mutations are recurrent events in hematopoietic malignancies with both clinical and functional implications. However, their aberrant splicing patterns in acute myeloid leukemia remain largely unexplored. In this study we characterized mutations in SRSF2, U2AF1 and SF3B1, the most commonly mutated splicing factors. In our clinical analysis of 2678 patients, splicing factor mutations showed inferior relapse-free and overall survival, however, these mutations did not represent independent prognostic markers. RNA-sequencing of 246 and independent validation in 177 patients revealed an isoform expression profile highly characteristic for each individual mutation, with several isoforms showing a strong dysregulation. By establishing a custom differential splice junction usage pipeline, we accurately detected aberrant splicing in splicing factor mutated samples. A large proportion of differentially used junctions were novel, including several junctions in leukemia associated genes. In SRSF2(P95H) mutants we further explored the possibility of a cascading effect through the dysregulation of the splicing pathway. Furthermore, we observed a validated impact on overall survival for two junctions overused in SRSF2(P95H) mutants. We conclude that splicing factor mutations do not represent independent prognostic markers. However, they do have genome-wide consequences on gene splicing leading to dysregulated isoform expression of several genes

Project description:Background: Lung cancer is the leading cause of cancer related death worldwide. Over the past 15 years no major improvement of survival rates could be accomplished. The recently discovered histone methyltransferase KMT9 as epigenetic regulator of prostate tumor growth has now raised hopes of enabling new cancer therapies. In this study we aimed to identify the function of KMT9 in lung cancer which has remained elusive so far. Methods: We linked full transcriptome and proteome analyses of A549 lung adenocarcinoma cells using RNA-Seq and mass spectrometry with functional cell culture, real-time proliferation and flow cytometry assays. Results: KMT9 is expressed in lung cancer tissue and cell lineswith high levels of KMT9 correlating with poor patient survival. We identified 460 overlapping genes and proteins that are deregulated upon knock-down of KMT9alpha in A549 cells. These genes cluster with proliferation, cell cycle and cell death gene sets as well as with subcellular organelles in gene ontology analysis. Knock-down of KMT9alpha inhibits lung cancer cell proliferation and induces non-apoptotic cell death in A549 cells. Conclusions: The novel histone methyltransferase KMT9 is crucial for proliferation and survival of lung cancer cells harboring various mutations. Small molecule inhibitors targeting KMT9 therefore should be further examined as potential milestones in modern epigenetic lung cancer therapy.

Project description:Next-generation sequencing has revolutionized cancer biology by accelerating the unbiased discovery of novel mutations across human cancers. Transforming such discoveries into a conceptual framework of cancer progression requires narrowing the vast number of mutations down to the driver elements, and further reducing these to mutations that govern cancer progression as opposed to tumor initiation. By integrating next-generation RNA-sequencing (RNA-seq) with in vivo selection, we devise an approach that identifies a series of novel recurrent non-synonymous amino acid mutations that are enriched in metastatic breast cancer cells and predicted to significantly alter protein function. These mutations, found in PANX1, RBFA, REST, KRIT1 and ZSWIM6, are detected at higher frequencies in the transcriptomes of two patients’ highly metastatic sub-lines relative to their poorly metastatic parental lines. We functionally characterize the cellular and molecular roles of one of these mutations—a nonsense alteration that yields a truncated pannexin-1 (PANX11-89) plasma membrane megachannel subunit—in metastatic progression. PANX11-89 interacts with full-length PANX1 and augments PANX1 channel activity to promote the survival of cancer cells as they are mechanically deformed. Protection from deformation-induced cell death requires PANX1 channels to release ATP, which acts as a cell autonomous survival signal during mechanical stress. Functional characterization of additional nonsense and missense PANX1 mutations detected in epithelial cancers of the colon, lung, and prostate reveals that these mutants also enhance PANX1-mediated ATP release. In vivo testing of one such truncating mutation detected in a metastatic colorectal tumor also enhances early survival, dissemination and liver metastatic colonization by human colon cancer cells. Finally, pharmacological inhibition of PANX1 inhibits breast cancer metastasis, implicating PANX1 as a novel therapeutic target in cancer. Our findings reveal that ATP release through mechanosensitive PANX1 channels enables cancer cells to overcome a major metastasis suppressive barrier—deformation-induced death in the microvasculature.

Project description:Splicing alterations are very common in cancer and might affect disease initiation and progression. In several cancers, mutations in splicing factor genes are responsible for aberrant splicing. We show that certain aggressive cancers, such as pediatric T-cell acute lymphoblastic leukemia (T-ALL), have an alternative mechanism for aberrant splicing that involves post-translational regulation of the splicing machinery via deubiquitination. We initially demonstrated that T-ALL presents with extensive exon skipping events affecting proteasomal transcripts, cell cycle and epigenetic regulators. Performing an unbiased genetic screen study for RNA binding proteins, we showed that the serine/arginine-rich splicing factor (SRSF) proteins, controlling exon skipping are critical for T-ALL survival. In our effort to dissect mechanisms of aberrant regulation of SRSF proteins, we focused on the pro-oncogenic deubiquitinase ubiquitin-specific peptidase 7 (USP7) to show it regulates the levels of the SRSF proteins at the post-translational level via active deubiquitination. We further demonstrated that USP7 inhibitors can change the splicing landscape and block T-ALL growth. Our drug studies show that decrease of the levels of SRSF proteins splicing inhibitors sensitize cells to the clinically used splicing inhibitor H3B-8800. Driven by our molecular findings on aberrant splicing of proteasomal transcripts, we demonstrate that H3B-8800 could act synergistically with proteasome inhibitors, paving the way for new therapeutic schemes in pediatric leukemia. Collectively this study provides the proof-of-principle for regulation of splicing factors independently of mutations and via deubiquitination and suggests new therapeutic modalities and combinations in cancer.

Project description:Despite the high prevalence and poor outcome of patients with metastatic lung cancer, the mechanisms of tumour progression and metastasis remain largely uncharacterized. We modelled human lung adenocarcinoma, which frequently harbours activating point mutations in KRAS1 and inactivation of the p53-pathway2, using conditional alleles in mice3-5. Lentiviral-mediated somatic activation of oncogenic Kras and deletion of p53 in the lung epithelial cells of KrasLSL-G12D/+;p53flox/flox mice initiates lung adenocarcinoma development4. Although tumours are initiated synchronously by defined genetic alterations, only a subset become malignant, suggesting that disease progression requires additional alterations. Identification of the lentiviral integration sites allowed us to distinguish metastatic from non-metastatic tumours and determine the gene expression alterations that distinguish these tumour types. Cross-species analysis identified the NK-2 related homeobox transcription factor Nkx2-1 (Ttf-1/Titf1) as a candidate suppressor of malignant progression. In this mouse model, Nkx2-1-negativity is pathognomonic of high-grade poorly differentiated tumours. Gain- and loss-of-function experiments in cells derived from metastatic and non-metastatic tumours demonstrated that Nkx2-1 controls tumour differentiation and limits metastatic potential in vivo. Interrogation of Nkx2-1 regulated genes, analysis of tumours at defined developmental stages, and functional complementation experiments indicate that Nkx2-1 constrains tumours in part by repressing the embryonically-restricted chromatin regulator Hmga2. While focal amplification of NKX2-1 in a fraction of human lung adenocarcinomas has focused attention on its oncogenic function6-9, our data specifically link Nkx2-1 downregulation to loss of differentiation, enhanced tumour seeding ability, and increased metastatic proclivity. Thus, the oncogenic and suppressive functions of Nkx2-1 in the same tumour type substantiate its role as a dual function lineage factor. 23 cell lines derived from primary tumor or metastasis. 6 samples analyzed to determine the effect of Nkx2-1 knockdown on gene expression

Project description:RBM5, a regulator of alternative splicing of apoptotic genes, and its close homologues, RBM6 and RBM10, are RNA binding proteins frequently deleted or mutated in lung cancer. We report that RBM5/6 and RBM10 antagonistically regulate the proliferative capacity of cancer cells and display distinct positional effects in alternative splicing regulation. We identify the Notch pathway regulator NUMB as a key target of these factors in the control of cell proliferation. NUMB alternative splicing, which is frequently altered in lung cancer, can regulate colony and xenograft tumor formation and its modulation recapitulates or antagonizes the effects of RBM5, 6 and 10 in cell colony formation. RBM10 mutations identified in lung cancer cells disrupt NUMB splicing regulation to promote cell growth. Our results reveal a key genetic circuit in the control of cancer cell proliferation. CLIP-Seq analysis of RBM5, RBM6 and RBM10, with 2 biological replicates and one non-specific control for each protein.

Project description:RBM5, a regulator of alternative splicing of apoptotic genes, and its close homologues, RBM6 and RBM10, are RNA binding proteins frequently deleted or mutated in lung cancer. We report that RBM5/6 and RBM10 antagonistically regulate the proliferative capacity of cancer cells and display distinct positional effects in alternative splicing regulation. We identify the Notch pathway regulator NUMB as a key target of these factors in the control of cell proliferation. NUMB alternative splicing, which is frequently altered in lung cancer, can regulate colony and xenograft tumor formation and its modulation recapitulates or antagonizes the effects of RBM5, 6 and 10 in cell colony formation. RBM10 mutations identified in lung cancer cells disrupt NUMB splicing regulation to promote cell growth. Our results reveal a key genetic circuit in the control of cancer cell proliferation. RNA from 3 biological replicates of knockdowns of RBM5, 6 and 10 and a control set were used. Changes between the control and knockdowns were measured based on using a splice-junction array (Affymetrix HJAY).

Project description:Oncogenic STAT3 functions are known in various malignancies. We found that STAT3 plays an unexpected tumor suppressive role in KRAS-mutant non-small-cell-lung cancer (NSCLC). In mice, tissue-specific inactivation of Stat3 resulted in increased Kras (G12D)-driven NSCLC initiation and malignant progression leading to markedly reduced survival. Clinically, low STAT3 expression levels correlate with poor survival in human lung adenocarcinoma patients with smoking history. Consistently, KRAS-mutant lung tumors showed reduced STAT3 levels. Mechanistically, we show that STAT3 controls NFκB-induced IL-8-expression by sequestering NFκB in the cytoplasm while IL-8 in turn regulates myeloid tumor infiltration and tumor vascularization thereby promoting tumor progression. These results identify a novel STAT3-NFκB-IL-8 axis in KRAS-mutant NSCLC with therapeutic and prognostic relevance WT: Control lung; KRAS: Lung tumors expressing KRAS G12D; KRAS STAT3 KO: Lung tumors expressing KRAS G12D- STAT3 deficient; tumors of four mice pooled per sample