The recurrent architecture of tumour initiation, progression and drug sensitivity

Califano, Andrea; Alvarez, Mariano J.

doi:10.1038/nrc.2016.124

Cited by 177 publications

(195 citation statements)

References 136 publications

(246 reference statements)

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“…Consistent with the recently proposed tumor checkpoint model (15), we elucidated a modular and hierarchical 10-protein architecture, responsible for the implementation of an aggressive neuroblastoma subtype (MYCNA) associated with aberrant activity of MYCN/MYC proteins. Experimental validation of these MR proteins confirmed their enrichment in MYCNA-subtype specific essential genes and their ability to regulate each other, as well as MYCNA-signature genes, through multiple autoregulatory loops, thus establishing their role as bona fide master regulators.…”

Section: Discussionsupporting

confidence: 77%

“…We have proposed that the stability of tumor-related phenotypes is controlled by tightly auto-regulated MR protein modules (tumor checkpoints) that mechanistically regulate the transcriptional state of the cancer cell (9, 15). To test this hypothesis, we assessed the ability of MYCNA-specific MRs to mechanistically regulate each other, as well as the MYCNA-subtype transcriptional signature.…”

Section: Resultsmentioning

confidence: 99%

“…MR proteins have been shown to elicit either essentiality or synthetic lethality in several cancers (8–16). Critically, aberrant activity of tumor checkpoint MRs arises from one or more genetic alterations in their upstream pathways (14, 17), thus providing a rationale for the heterogeneous mutational landscape of tumors with highly similar transcriptional states (15). MR proteins have been shown to represent critical molecular tumor vulnerabilities that can be effectively targeted pharmacologically in several human malignancies (10, 11, 16, 18, 19), thus providing novel therapeutic opportunities.…”

Section: Introductionmentioning

confidence: 99%

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Cross-Cohort Analysis Identifies a TEAD4–MYCN Positive Feedback Loop as the Core Regulatory Element of High-Risk Neuroblastoma

et al. 2018

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High-risk neuroblastomas show a paucity of recurrent somatic mutations at diagnosis. As a result, the molecular basis for this aggressive phenotype remains elusive. Recent progress in regulatory network analysis helped us elucidate disease-driving mechanisms downstream of genomic alterations, including recurrent chromosomal alterations. Our analysis identified three molecular subtypes of high-risk neuroblastomas, consistent with chromosomal alterations, and identified subtype-specific master regulator (MR) proteins that were conserved across independent cohorts. A 10–protein transcriptional module – centered around a TEAD4 ↔ MYCN positive-feedback loop – emerged as the regulatory driver of the high-risk subtype associated with MYCN amplification. Silencing of either gene collapsed MYCN-amplified (MYCNAmp) neuroblastoma transcriptional hallmarks and abrogated viability in vitro and in vivo. Consistently, TEAD4 emerged as a robust prognostic marker of poor survival, with activity independent of the canonical Hippo pathway transcriptional co-activators, YAP and TAZ. These results suggest novel therapeutic strategies for the large subset of MYCN deregulated neuroblastomas.

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Section: Discussionsupporting

confidence: 77%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Cross-Cohort Analysis Identifies a TEAD4–MYCN Positive Feedback Loop as the Core Regulatory Element of High-Risk Neuroblastoma

et al. 2018

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“…The pattern of multiple activation reported by KUO et al [19] is reminiscent of the presence of a potential "master regulator," as recently described by CALIFANO and ALVAREZ [31] in cancer literature. This approach seems to be working for cancer, a disease with a complex genetic background.…”

mentioning

confidence: 66%

Severe asthma: phenotyping to endotyping or vice versa?

2017

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“…Gene regulatory network analysis is capable of elucidating master regulator proteins involved in bottlenecks of the transcriptional programs [53]. Theoretically, these master regulator proteins play a central role in the transcriptional architecture of the tumor by canalizing the upstream effects of oncogenic driver mutations and other aberrant signals to the rest of the network downstream.…”

Section: Drug Repositioningmentioning

confidence: 99%

Pancreas Cancer Precision Treatment Using Avatar Mice from a Bioinformatics Perspective

Perales-Patón

Piñeiro-Yáñez²,

Tejero³

et al. 2017

Public Health Genomics

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Pancreatic ductal adenocarcinoma (PDAC) is a leading cause of cancer-related death among solid malignancies. Unfortunately, PDAC lethality has not substantially decreased over the past 20 years. This aggressiveness is related to the genomic complexity and heterogeneity of PDAC, but also to the absence of an effective screening for the detection of early-stage tumors and a lack of efficient therapeutic options. Therefore, there is an urgent need to improve the arsenal of anti-PDAC drugs for an effective treatment of these patients. Patient-derived xenograft (PDX) mouse models represent a promising strategy to personalize PDAC treatment, offering a bench testing of candidate treatments and helping to select empirical treatments in PDAC patients with no therapeutic targets. Moreover, bioinformatics-based approaches have the potential to offer systematic insights into PDAC etiology predicting putatively actionable tumor-specific genomic alterations, identifying novel biomarkers and generating disease-associated gene expression signatures. This review focuses on recent efforts to individualize PDAC treatments using PDX models. Additionally, we discuss the current understanding of the PDAC genomic landscape and the putative druggable targets derived from mutational studies. PDAC molecular subclassifications and gene expression profiling studies are reviewed as well. Finally, latest bioinformatics methodologies based on somatic variant detection and prioritization, in silico drug response prediction, and drug repositioning to improve the treatment of advanced PDAC tumors are also covered.

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The recurrent architecture of tumour initiation, progression and drug sensitivity

Cited by 177 publications

References 136 publications

Cross-Cohort Analysis Identifies a TEAD4–MYCN Positive Feedback Loop as the Core Regulatory Element of High-Risk Neuroblastoma

Cross-Cohort Analysis Identifies a TEAD4–MYCN Positive Feedback Loop as the Core Regulatory Element of High-Risk Neuroblastoma

Severe asthma: phenotyping to endotyping or vice versa?

Pancreas Cancer Precision Treatment Using Avatar Mice from a Bioinformatics Perspective

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