The Impact of Mutant p53 in the Non-Coding RNA World

Agostino, Silvia Di

doi:10.3390/biom10030472

Cited by 21 publications

(23 citation statements)

References 103 publications

(207 reference statements)

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“…Mutant p53 in conjunction with the YAP/TEAD transcription-competent complex is involved in an upregulation of a circular form of oncogenic PVT1 [253]. The currently known interrelations of mutant p53 with several oncogenic ncRNAs are representative examples of a still limited but rapidly expanding knowledge of the interplay of the main driver oncoproteins with ncRNAs [254]. This knowledge will surely grow significantly in the nearby future as over 30 thousand lncRNAs alone are found in a typical human transcriptome.…”

Section: Non-coding Rnas (Micro Rnas and Long Non-codong Rnas)mentioning

confidence: 99%

“…Noticing that broader mechanisms of ncRNA deregulation in cancer are crossing over to other targetable oncogenic pathways could help in making the ncRNA targeting more robust. For example, the mentioned CMYC or mutant p53 effects on the activity and maturation of wide miRNA populations [252,254] can be theoretically co-targeted along with selected oncomiRs.…”

Section: Non-coding Rnas (Micro Rnas and Long Non-codong Rnas)mentioning

confidence: 99%

See 1 more Smart Citation

A Driver Never Works Alone—Interplay Networks of Mutant p53, MYC, RAS, and Other Universal Oncogenic Drivers in Human Cancer

Grzes

Oroń

Staszczak

et al. 2020

Cancers

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The knowledge accumulating on the occurrence and mechanisms of the activation of oncogenes in human neoplasia necessitates an increasingly detailed understanding of their systemic interactions. None of the known oncogenic drivers work in isolation from the other oncogenic pathways. The cooperation between these pathways is an indispensable element of a multistep carcinogenesis, which apart from inactivation of tumor suppressors, always includes the activation of two or more proto-oncogenes. In this review we focus on representative examples of the interaction of major oncogenic drivers with one another. The drivers are selected according to the following criteria: (1) the highest frequency of known activation in human neoplasia (by mutations or otherwise), (2) activation in a wide range of neoplasia types (universality) and (3) as a part of a distinguishable pathway, (4) being a known cause of phenotypic addiction of neoplastic cells and thus a promising therapeutic target. Each of these universal oncogenic factors—mutant p53, KRAS and CMYC proteins, telomerase ribonucleoprotein, proteasome machinery, HSP molecular chaperones, NF-κB and WNT pathways, AP-1 and YAP/TAZ transcription factors and non-coding RNAs—has a vast network of molecular interrelations and common partners. Understanding this network allows for the hunt for novel therapeutic targets and protocols to counteract drug resistance in a clinical neoplasia treatment.

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Section: Non-coding Rnas (Micro Rnas and Long Non-codong Rnas)mentioning

confidence: 99%

Section: Non-coding Rnas (Micro Rnas and Long Non-codong Rnas)mentioning

confidence: 99%

A Driver Never Works Alone—Interplay Networks of Mutant p53, MYC, RAS, and Other Universal Oncogenic Drivers in Human Cancer

Grzes

Oroń

Staszczak

et al. 2020

Cancers

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show abstract

“…Mutp53 interacts with many different proteins other than transcription factors, including tumor suppressors and oncogenic proteins, to affect their functions. Additionally, mutp53 regulates expression of many noncoding RNAs, including microRNAs (miRNAs), circular RNAs (circRNAs), and long noncoding RNAs (lncRNA), to exert its GOF activities ( Liu et al., 2017a ; Di Agostino, 2020 ). In this review, we summarize recent advances in studies on mutp53 GOF in cancer and mutp53-targeted cancer therapies.…”

Section: Introductionmentioning

confidence: 99%

Gain-of-function mutant p53 in cancer progression and therapy

Zhang

Liu

et al. 2020

Journal of Molecular Cell Biology

217

151

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p53 is a key tumor suppressor, and loss of p53 function is frequently a prerequisite for cancer development. The p53 gene is the most frequently mutated gene in human cancers; p53 mutations occur in > 50% of all human cancers and in almost every type of human cancers. Most of p53 mutations in cancers are missense mutations, which produce the full-length mutant p53 (mutp53) protein with only one amino acid difference from wild-type p53 protein. In addition to loss of the tumor suppressive function of wild-type p53, many mutp53 proteins acquire new oncogenic activities independently of wild-type p53 to promote cancer progression, termed gain-of-function (GOF). Mutp53 protein often accumulates to very high levels in cancer cells, which is critical for its GOF. Given the high mutation frequency of the p53 gene and the GOF activities of mutp53 in cancer, therapies targeting mutp53 have attracted great interest. Further understanding the mechanisms underlying mutp53 protein accumulation and GOF will help develop effective therapies treating human cancers containing mutp53. In this review, we summarize the recent advances in the studies on mutp53 regulation and GOF as well as therapies targeting mutp53 in human cancers.

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“…It is thus of great interest that we show that the role of YAP1 as an upstream transcriptional regulator of RPL23, at least in part, are mediated by the regulation of RPL23 expression in HeLa cells. The p53 mutation, which loses tumor suppressive functions and gains tumor-promoting activities (79), was reported to be associated with aggressive growth and increased recurrence rates for certain tumors (80). Here, we showed that RPL23 increased the expression of mutant p53 in HeLa cells.…”

Section: Discussionmentioning

confidence: 56%

Novel insights into the mechanisms by which lncRNAHOTAIR regulates migration and invasion in HeLa cells

Zheng

Liu

Fan³

et al. 2020

Preprint

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Background HOTAIR, as one of the few well-studied oncogenic lncRNAs, is involved in human tumorigenesis and is dysregulated in most human cancers. The transcription co-activator factor YAP1 is broadly expressed in many tissues, and promotes cancer metastasis and progression. However, the precise biological roles of HOTAIR and YAP1 in cancer cells remain unclear. Methods The expression levels of HOTAIR and YAP1 were measured by quantitative PCR (qPCR), immunoblotting. Wound-healing and transwell assays were used to examine the invasive abilities of HeLa cells. Luciferase reporter assays and CHIP were used to determine how YAP1 regulates RPL23. A xenograft mouse mode was used to assess the correlation between HOTAIR and YAP1 in vivo. Result In this study, we showed that HOTAIR regulates H3K27 histone modification in the promoter of miR-200a to mediate miR-200a expression byrecruiting EZH2. YAP1, as a potential target gene of miR-200a, aggravated the effects of miR-200a on the migration and invasion of HeLa cells. YAP1 activated the transcription of RPL23, which is a novel target of YAP1 transcriptional regulation. Agreement with this, the expression of YAP1 and RPL23 was dramatically decreased after injecting HeLa cells transfected with siHOTAIR in a xenograft mouse model. Conclusion These elucidates that HOTAIR, as an oncogenic lncRNA, recruits EZH2 to reduce miR-200a-3p expression via H3k27 trimethylation in the miR-200a-3p promoter. As a target gene of miR-200a-3p,YAP1 then promotes the migration and invasion of HeLa cells by mediating the downstream transcription of RPL23 which normally functions as a cancer-promoting factor. Accordingly, we propose a novel model of the molecular mechanism by which HOTAIR promotes the migration and invasion of cancer cells involving the miR-200a-3p/YAP1/RPL23 axis.

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The Impact of Mutant p53 in the Non-Coding RNA World

Cited by 21 publications

References 103 publications

A Driver Never Works Alone—Interplay Networks of Mutant p53, MYC, RAS, and Other Universal Oncogenic Drivers in Human Cancer

A Driver Never Works Alone—Interplay Networks of Mutant p53, MYC, RAS, and Other Universal Oncogenic Drivers in Human Cancer

Gain-of-function mutant p53 in cancer progression and therapy

Novel insights into the mechanisms by which lncRNAHOTAIR regulates migration and invasion in HeLa cells

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