Mutational processes shape the landscape of TP53 mutations in human cancer

Giacomelli, Andrew O.; Yang, Xiaoping; Lintner, Robert E.; McFarland, James M.; Duby, Marc; Kim, Jaegil; Howard, Thomas P.; Takeda, David Y.; Ly, Seav Huong; Kim, Eejung; Gannon, Hugh S.; Hurhula, Brian; Sharpe, Ted; Goodale, Amy; Fritchman, Briana; Steelman, Scott; Vázquez, Francisca; Tsherniak, Aviad; Aguirre, Andrew J.; Doench, John G.; Piccioni, Federica; Roberts, Charles W.M.; Meyerson, Matthew; Getz, Gad; Johannessen, Cory M.; Root, David E.; Hahn, William C.

doi:10.1038/s41588-018-0204-y

Cited by 420 publications

(481 citation statements)

References 52 publications

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“…Outcomes were reported as the relative enrichment (Z score) of individual variants under the selective conditions, which again allowed comparison to the output of the model. In a conservative approach to infer LOF, the cut‐off selected was −0.21 for etoposide assays, which showed the best separation between silent and common cancer missense variants as reported in the published data (Figure f in Giacomelli et al, ).…”

Section: Methodsmentioning

confidence: 88%

“…Variants classified as pathogenic or likely pathogenic by the model were associated with earlier age of cancer onset (including a greater proportion of pediatric cancers), and were enriched in Classic LFS probands and depleted in a cohort of cancer-free women over 70 years. When compared to the output of reported functional assays, the majority of variants classified as pathogenic or likely pathogenic were nonfunctional in transactivation yeast assays (Kato et al, 2003), showed disruption of antiproliferative function/LOF (Giacomelli et al, 2018;Kotler et al, 2018), or reduced activity in the mammalian clonogenic survival assays developed in this study.…”

Section: Discussionmentioning

confidence: 95%

“…Giacomelli et al, also performed a recent systematic analysis of almost all possible single nucleotide variants in the full length TP53 sequence, using different conditions in a human cell model to independently assess the fitness advantage conferred by loss‐of‐function (LOF). Outcomes were reported as the relative enrichment (Z score) of individual variants under the selective conditions, which again allowed comparison to the output of the model.…”

Section: Methodsmentioning

confidence: 99%

“…3.3 | Clinical information correlates with variant pathogenicity assigned using the quantitative model (Kato et al, 2003) 54.6% ≤20% activity 1.1% ≤20% activity Antiproliferative function (Kotler et al, 2018) 76.7% disruptive function 3.6% disruptive function LOF (Giacomelli et al, 2018) 74.4% LOF 11.1% LOF Clonogenic survival assays 90.9% disrupted function 0% disrupted function ClinVar 87.1% "P" or "LP" 0% "P" or "LP" than VUS was assigned, were classified as P/LP. The discordant variant was p.Asn235Ser, with functional transactivation class and 55 alleles in gnomAD.…”

Section: Validation Of the Quantitative Model Outputsmentioning

confidence: 99%

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A quantitative model to predict pathogenicity of missense variants in the TP53 gene

et al. 2019

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Germline pathogenic variants in the TP53 gene cause Li‐Fraumeni syndrome, a condition that predisposes individuals to a wide range of cancer types. Identification of individuals carrying a TP53 pathogenic variant is linked to clinical management decisions, such as the avoidance of radiotherapy and use of high‐intensity screening programs. The aim of this study was to develop an evidence‐based quantitative model that integrates independent in silico data (Align‐GVGD and BayesDel) and somatic to germline ratio (SGR), to assign pathogenicity to every possible missense variant in the TP53 gene. To do this, a likelihood ratio for pathogenicity (LR) was derived from each component calibrated using reference sets of assumed pathogenic and benign missense variants. A posterior probability of pathogenicity was generated by combining LRs, and algorithm outputs were validated using different approaches. A total of 730 TP53 missense variants could be assigned to a clinically interpretable class. The outputs of the model correlated well with existing clinical information, functional data, and ClinVar classifications. In conclusion, these quantitative outputs provide the basis for individualized assessment of cancer risk useful for clinical interpretation. In addition, we propose the value of the novel SGR approach for use within the ACMG/AMP guidelines for variant classification.

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Section: Methodsmentioning

confidence: 88%

Section: Discussionmentioning

confidence: 95%

Section: Methodsmentioning

confidence: 99%

Section: Validation Of the Quantitative Model Outputsmentioning

confidence: 99%

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A quantitative model to predict pathogenicity of missense variants in the TP53 gene

et al. 2019

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“…TP53 is one of the most well‐studied tumor‐suppressor genes. However, TP53 mutations or deletions are present in nearly 50% of human cancers and primarily result in impaired tumor‐suppressor function . Our bioinformatic studies showed that PSLNR was significantly involved in the regulation of cell proliferation, apoptosis, and the p53 signaling pathway.…”

Section: Discussionmentioning

confidence: 80%

A novel androgen‐reduced prostate‐specific lncRNA, PSLNR, inhibits prostate‐cancer progression in part by regulating the p53‐dependent pathway

et al. 2019

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Background Prostate cancer (PCa) is one of the most common cancers in males in China. Long noncoding RNAs (lncRNAs) reportedly play crucial roles in human cancer progression in many studies. However, the molecular mechanisms underlying PCa progression remain unclear. Materials and Methods We investigated the lncRNA transcriptome using publicly available RNA‐sequencing data to identify prostate‐specific lncRNAs. Then, the chromatin immunoprecipitation (ChIP) assay identified lncRNA with a direct binding to androgen receptor (AR), hereafter denoted as PSLNR. Quantitative real‐time polymerase chain reaction analysis and Western blot analysis were performed to detect the expression of p53 signaling‐related genes after overexpression PSLNR. The effects of overexpression of PSLNR on cell proliferation, cell cycle, and cell apoptosis were assessed by using CCK‐8 and flow cytometric analysis. We then detected the expression of PSLNR in tissues. Result We reported a novel androgen‐reduced prostate‐specific lncRNA, PSLNR, that inhibited PCa progression via the p53‐dependent pathway. By analyzing the NOCODE data set, we reported that PSLNR was specifically expressed in the prostate, suggesting the potential of PSLNR as a biomarker for PCa treatment. The AR pathway was also confirmed to be an upstream regulation signaling pathway of PSLNR by transcriptionally regulating its expression in androgen‐dependent PCa cells. PSLNR also significantly inhibited PCa proliferation by inducing cell apoptosis in a p53‐dependent manner. Thus, PSLNR may be a candidate diagnosis and therapeutic target for PCa. Conclusions Our study revealed for the first time a novel androgen‐reduced prostate‐specific lncRNA, PSLNR, which inhibited PCa progression via the p53‐dependent pathway, suggesting that PSLNR may be a candidate diagnosis and therapeutic target for PCa.

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Understanding oncogenicity of cancer driver genes and mutations in the cancer genomics era

2020

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One of the key challenges of cancer biology is to catalogue and understand the somatic genomic alterations leading to cancer. Although alternative definitions and search methods have been developed to identify cancer driver genes and mutations, analyses of thousands of cancer genomes return a remarkably similar catalogue of around 300 genes that are mutated in at least one cancer type. Yet, many features of these genes and their role in cancer remain unclear, first and foremost when a somatic mutation is truly oncogenic. In this review, we first summarize some of the recent efforts in completing the catalogue of cancer driver genes. Then, we give an overview of different aspects that influence the oncogenicity of somatic mutations in the core cancer driver genes, including their interactions with the germline genome, other cancer driver mutations, the immune system, or their potential role in healthy tissues. In the coming years, this research holds promise to illuminate how, when, and why cancer driver genes and mutations are really drivers, and thereby move personalized cancer medicine and targeted therapies forward.

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Mutational processes shape the landscape of TP53 mutations in human cancer

Cited by 420 publications

References 52 publications

A quantitative model to predict pathogenicity of missense variants in the TP53 gene

A quantitative model to predict pathogenicity of missense variants in the TP53 gene

A novel androgen‐reduced prostate‐specific lncRNA, PSLNR, inhibits prostate‐cancer progression in part by regulating the p53‐dependent pathway

Understanding oncogenicity of cancer driver genes and mutations in the cancer genomics era

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