Literature DB >> 12014832

Stress-induced premature senescence: from biomarkers to likeliness of in vivo occurrence.

Olivier Toussaint1, José Remacle, Jean-François Dierick, Thierry Pascal, Christophe Frippiat, Véronique Royer, Joao Pedro Magalhacs, Stéphanie Zdanov, Florence Chainiaux.   

Abstract

The similarities between the biomarkers of stress-induced premature senescence and replicative senescence are reviewed. The possibility of existence of 'molecular scars', i.e. long-term changes observed after subcytotoxic stress and not observed in replicative senescence, is considered. Lastly, the likeliness of existence of stress-induced premature senescence in vivo is discussed. The possible effects on normal and pathological tissue ageing are predicted.

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Year:  2002        PMID: 12014832     DOI: 10.1023/a:1015226524335

Source DB:  PubMed          Journal:  Biogerontology        ISSN: 1389-5729            Impact factor:   4.277


  11 in total

1.  Mild heat stress stimulates 20S proteasome and its 11S activator in human fibroblasts undergoing aging in vitro.

Authors:  Rasmus Beedholm; Brian F C Clark; Suresh I S Rattan
Journal:  Cell Stress Chaperones       Date:  2004-03       Impact factor: 3.667

2.  Repression of the SUMO-specific protease Senp1 induces p53-dependent premature senescence in normal human fibroblasts.

Authors:  Kristin E Yates; Gregory A Korbel; Michael Shtutman; Igor B Roninson; Daniel DiMaio
Journal:  Aging Cell       Date:  2008-07-24       Impact factor: 9.304

3.  Modeling the salivary cortisol profile in population research: the multi-ethnic study of atherosclerosis.

Authors:  Brisa N Sánchez; Meihua Wu; Trivellore E Raghunathan; Ana V Diez-Roux
Journal:  Am J Epidemiol       Date:  2012-10-25       Impact factor: 4.897

Review 4.  Mnk kinase pathway: Cellular functions and biological outcomes.

Authors:  Sonali Joshi; Leonidas C Platanias
Journal:  World J Biol Chem       Date:  2014-08-26

5.  Quantitative model of cell cycle arrest and cellular senescence in primary human fibroblasts.

Authors:  Sascha Schäuble; Karolin Klement; Shiva Marthandan; Sandra Münch; Ines Heiland; Stefan Schuster; Peter Hemmerich; Stephan Diekmann
Journal:  PLoS One       Date:  2012-08-07       Impact factor: 3.240

6.  Replicative senescence of mesenchymal stem cells causes DNA-methylation changes which correlate with repressive histone marks.

Authors:  Anne Schellenberg; Qiong Lin; Herdit Schüler; Carmen M Koch; Sylvia Joussen; Bernd Denecke; Gudrun Walenda; Norbert Pallua; Christoph V Suschek; Martin Zenke; Wolfga Wagner
Journal:  Aging (Albany NY)       Date:  2011-09       Impact factor: 5.682

7.  Identification of senescence-associated circular RNAs (SAC-RNAs) reveals senescence suppressor CircPVT1.

Authors:  Amaresh C Panda; Ioannis Grammatikakis; Kyoung Mi Kim; Supriyo De; Jennifer L Martindale; Rachel Munk; Xiaoling Yang; Kotb Abdelmohsen; Myriam Gorospe
Journal:  Nucleic Acids Res       Date:  2017-04-20       Impact factor: 16.971

8.  ATF3 represses PINK1 gene transcription in lung epithelial cells to control mitochondrial homeostasis.

Authors:  Marta Bueno; Judith Brands; Lauren Voltz; Kaitlin Fiedler; Brenton Mays; Claudette St Croix; John Sembrat; Rama K Mallampalli; Mauricio Rojas; Ana L Mora
Journal:  Aging Cell       Date:  2018-01-24       Impact factor: 9.304

9.  MicroRNA: Implications for Alzheimer Disease and other Human CNS Disorders.

Authors:  Olivier C Maes; Howard M Chertkow; Eugenia Wang; Hyman M Schipper
Journal:  Curr Genomics       Date:  2009-05       Impact factor: 2.236

10.  Nuclear DNA methylation and chromatin condensation phenotypes are distinct between normally proliferating/aging, rapidly growing/immortal, and senescent cells.

Authors:  Jin Ho Oh; Arkadiusz Gertych; Jian Tajbakhsh
Journal:  Oncotarget       Date:  2013-03
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