Literature DB >> 24526114

Revisiting p53 for cancer-specific chemo- and radiotherapy: ten years after.

Jason M Beckta1, Syed Farhan Ahmad1, Hu Yang2, Kristoffer Valerie3.   

Abstract

Despite intense studies, highly effective therapeutic strategies against cancer have not yet been fully exploited, because few true cancer-specific targets have been identified. Most modalities, perhaps with the exception of radiation therapy, target proliferating cells, which are also abundant in normal tissues. Thus, most current cancer treatments have significant side effects. More than 10 years ago, the tumor suppressor p53 was first explored as a cancer-specific target. At the time, the approach was to introduce a normal p53 gene into mutant p53 (mp53) tumor cells to induce cell cycle arrest and apoptosis. However, this strategy did not hold up and mostly failed in subsequent clinical studies. Recent research developments have now returned p53 to the limelight. Several studies have reported that mutant or null p53 tumor cells undergo apoptosis more easily than genetically matched, normal p53 counterparts when inhibiting a specific stress kinase in combination with standard chemotherapy or when exposed to an ataxia-telangiectasia mutated (ATM) kinase inhibitor and radiation, thus achieving true cancer specificity in animal tumor models. This short review highlights several of these recent studies, discusses possible mechanism(s) for mp53-mediated "synthetic lethality," and the implications for cancer therapy.

Entities:  

Keywords:  ATM; DNA damage response; DNA repair; MAPKAP kinase 2; p38

Mesh:

Substances:

Year:  2014        PMID: 24526114      PMCID: PMC3979907          DOI: 10.4161/cc.28108

Source DB:  PubMed          Journal:  Cell Cycle        ISSN: 1551-4005            Impact factor:   4.534


  36 in total

Review 1.  The hallmarks of cancer.

Authors:  D Hanahan; R A Weinberg
Journal:  Cell       Date:  2000-01-07       Impact factor: 41.582

2.  p53 protects from replication-associated DNA double-strand breaks in mammalian cells.

Authors:  Anuradha Kumari; Niklas Schultz; Thomas Helleday
Journal:  Oncogene       Date:  2004-03-25       Impact factor: 9.867

3.  DNA damage induces p53-dependent BRCA1 nuclear export.

Authors:  Zhihui Feng; Lisa Kachnic; Junran Zhang; Simon N Powell; Fen Xia
Journal:  J Biol Chem       Date:  2004-04-15       Impact factor: 5.157

4.  Increase of spontaneous intrachromosomal homologous recombination in mammalian cells expressing a mutant p53 protein.

Authors:  P Bertrand; D Rouillard; A Boulet; C Levalois; T Soussi; B S Lopez
Journal:  Oncogene       Date:  1997-03-06       Impact factor: 9.867

5.  BLM helicase-dependent transport of p53 to sites of stalled DNA replication forks modulates homologous recombination.

Authors:  Sagar Sengupta; Steven P Linke; Remy Pedeux; Qin Yang; Julie Farnsworth; Susan H Garfield; Kristoffer Valerie; Jerry W Shay; Nathan A Ellis; Bohdan Wasylyk; Curtis C Harris
Journal:  EMBO J       Date:  2003-03-03       Impact factor: 11.598

6.  Induction of p53-regulated genes and tumor regression in lung cancer patients after intratumoral delivery of adenoviral p53 (INGN 201) and radiation therapy.

Authors:  Stephen G Swisher; Jack A Roth; Ritsuko Komaki; Jian Gu; J Jack Lee; Marshall Hicks; Jae Y Ro; Waun K Hong; James A Merritt; Kamaran Ahrar; N Edward Atkinson; Arlene M Correa; Marcelo Dolormente; Linda Dreiling; Adel K El-Naggar; Frank Fossella; Rhodette Francisco; Bonnie Glisson; Susan Grammer; Roy Herbst; Armando Huaringa; Bonnie Kemp; Fadlo R Khuri; Jonathan M Kurie; Zhongxio Liao; Timothy J McDonnell; Rudolfo Morice; Frank Morello; Reginald Munden; Vassiliki Papadimitrakopoulou; Katherine M W Pisters; Joe B Putnam; Arcenio J Sarabia; Thomas Shelton; Craig Stevens; Daniel M Shin; William R Smythe; Ara A Vaporciyan; Garrett L Walsh; Min Yin
Journal:  Clin Cancer Res       Date:  2003-01       Impact factor: 12.531

Review 7.  Why did p53 gene therapy fail in ovarian cancer?

Authors:  Alain G Zeimet; Christian Marth
Journal:  Lancet Oncol       Date:  2003-07       Impact factor: 41.316

Review 8.  p53 mutations in human cancers.

Authors:  M Hollstein; D Sidransky; B Vogelstein; C C Harris
Journal:  Science       Date:  1991-07-05       Impact factor: 47.728

9.  p53 is linked directly to homologous recombination processes via RAD51/RecA protein interaction.

Authors:  H W Stürzbecher; B Donzelmann; W Henning; U Knippschild; S Buchhop
Journal:  EMBO J       Date:  1996-04-15       Impact factor: 11.598

Review 10.  p53-Based cyclotherapy: exploiting the 'guardian of the genome' to protect normal cells from cytotoxic therapy.

Authors:  B Rao; S Lain; A M Thompson
Journal:  Br J Cancer       Date:  2013-11-14       Impact factor: 7.640
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  11 in total

1.  Three-dimensional microenvironment confers enhanced sensitivity to doxorubicin by reducing p53-dependent induction of autophagy.

Authors:  L R Gomes; A T Vessoni; C F M Menck
Journal:  Oncogene       Date:  2015-01-26       Impact factor: 9.867

2.  Melatonin Modulation of Radiation-Induced Molecular Changes in MCF-7 Human Breast Cancer Cells.

Authors:  Carolina Alonso-González; Cristina González-Abalde; Javier Menéndez-Menéndez; Alicia González-González; Virginia Álvarez-García; Alicia González-Cabeza; Carlos Martínez-Campa; Samuel Cos
Journal:  Biomedicines       Date:  2022-05-07

3.  Suberoyl bis-hydroxamic acid enhances cytotoxicity induced by proteasome inhibitors in breast cancer cells.

Authors:  Xinmiao Yang; Zeliang Shi; Ning Zhang; Zhouluo Ou; Shen Fu; Xichun Hu; Zhenzhou Shen
Journal:  Cancer Cell Int       Date:  2014-11-12       Impact factor: 5.722

Review 4.  Molecular chess? Hallmarks of anti-cancer drug resistance.

Authors:  Ian A Cree; Peter Charlton
Journal:  BMC Cancer       Date:  2017-01-05       Impact factor: 4.430

5.  Induction of p53-Independent Apoptosis and G1 Cell Cycle Arrest by Fucoidan in HCT116 Human Colorectal Carcinoma Cells.

Authors:  Hye Young Park; Shin-Hyung Park; Jin-Woo Jeong; Dahye Yoon; Min Ho Han; Dae-Sung Lee; Grace Choi; Mi-Jin Yim; Jeong Min Lee; Do-Hyung Kim; Gi-Young Kim; Il-Whan Choi; Suhkmann Kim; Heui-Soo Kim; Hee-Jae Cha; Yung Hyun Choi
Journal:  Mar Drugs       Date:  2017-05-30       Impact factor: 5.118

6.  β2-AR activation induces chemoresistance by modulating p53 acetylation through upregulating Sirt1 in cervical cancer cells.

Authors:  Hongyu Chen; Wei Zhang; Xiang Cheng; Liang Guo; Shuai Xie; Yuanfang Ma; Ning Guo; Ming Shi
Journal:  Cancer Sci       Date:  2017-06-14       Impact factor: 6.716

Review 7.  Melatonin as a Radio-Sensitizer in Cancer.

Authors:  Carolina Alonso-González; Alicia González; Javier Menéndez-Menéndez; Carlos Martínez-Campa; Samuel Cos
Journal:  Biomedicines       Date:  2020-07-27

Review 8.  Evaluating the Remote Control of Programmed Cell Death, with or without a Compensatory Cell Proliferation.

Authors:  Xixi Dou; Lichan Chen; Mingjuan Lei; Lucas Zellmer; Qingwen Jia; Peixue Ling; Yan He; Wenxiu Yang; Dezhong Joshua Liao
Journal:  Int J Biol Sci       Date:  2018-10-19       Impact factor: 6.580

9.  Screening candidate microRNA-mRNA regulatory pairs for predicting the response to chemoradiotherapy in rectal cancer by a bioinformatics approach.

Authors:  Qiliang Peng; Junjia Zhu; Peipei Shen; Wenyan Yao; Yu Lei; Li Zou; Yingying Xu; Yuntian Shen; Yaqun Zhu
Journal:  Sci Rep       Date:  2017-09-12       Impact factor: 4.379

Review 10.  Insights of Crosstalk between p53 Protein and the MKK3/MKK6/p38 MAPK Signaling Pathway in Cancer.

Authors:  Lorenzo Stramucci; Angelina Pranteda; Gianluca Bossi
Journal:  Cancers (Basel)       Date:  2018-05-03       Impact factor: 6.639
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