Literature DB >> 23336757

End-of-life cell cycle arrest contributes to stochasticity of yeast replicative aging.

Joe R Delaney1, Annie Chou, Brady Olsen, Daniel Carr, Christopher Murakami, Umema Ahmed, Sylvia Sim, Elroy H An, Anthony S Castanza, Marissa Fletcher, Sean Higgins, Mollie Holmberg, Jessica Hui, Monika Jelic, Ki-Soo Jeong, Jin R Kim, Shannon Klum, Eric Liao, Michael S Lin, Winston Lo, Hillary Miller, Richard Moller, Zhao J Peng, Tom Pollard, Prarthana Pradeep, Dillon Pruett, Dilreet Rai, Vanessa Ros, Jennifer Schleit, Alex Schuster, Minnie Singh, Benjamin L Spector, George L Sutphin, Adrienne M Wang, Brian M Wasko, Helen Vander Wende, Brian K Kennedy, Matt Kaeberlein.   

Abstract

There is growing evidence that stochastic events play an important role in determining individual longevity. Studies in model organisms have demonstrated that genetically identical populations maintained under apparently equivalent environmental conditions display individual variation in life span that can be modeled by the Gompertz-Makeham law of mortality. Here, we report that within genetically identical haploid and diploid wild-type populations, shorter-lived cells tend to arrest in a budded state, while cells that arrest in an unbudded state are significantly longer-lived. This relationship is particularly notable in diploid BY4743 cells, where mother cells that arrest in a budded state have a shorter mean life span (25.6 vs. 35.6) and larger coefficient of variance with respect to individual life span (0.42 vs. 0.32) than cells that arrest in an unbudded state. Mutations that cause genomic instability tend to shorten life span and increase the proportion of the population that arrest in a budded state. These observations suggest that randomly occurring damage may contribute to stochasticity during replicative aging by causing a subset of the population to terminally arrest prematurely in the S or G2 phase of the cell cycle.
© 2013 Federation of European Microbiological Societies. Published by Blackwell Publishing Ltd. All rights reserved.

Entities:  

Mesh:

Year:  2013        PMID: 23336757      PMCID: PMC3960949          DOI: 10.1111/1567-1364.12030

Source DB:  PubMed          Journal:  FEMS Yeast Res        ISSN: 1567-1356            Impact factor:   2.796


  58 in total

1.  Images in experimental gerontology. A senescent yeast mother cell.

Authors:  R Nestelbacher; P Laun; M Breitenbach
Journal:  Exp Gerontol       Date:  1999-11       Impact factor: 4.032

2.  Homologous recombination is responsible for cell death in the absence of the Sgs1 and Srs2 helicases.

Authors:  S Gangloff; C Soustelle; F Fabre
Journal:  Nat Genet       Date:  2000-06       Impact factor: 38.330

3.  hpr1Delta affects ribosomal DNA recombination and cell life span in Saccharomyces cerevisiae.

Authors:  Robert J Merker; Hannah L Klein
Journal:  Mol Cell Biol       Date:  2002-01       Impact factor: 4.272

4.  pH neutralization protects against reduction in replicative lifespan following chronological aging in yeast.

Authors:  Christopher Murakami; Joe R Delaney; Annie Chou; Daniel Carr; Jennifer Schleit; George L Sutphin; Elroy H An; Anthony S Castanza; Marissa Fletcher; Sarani Goswami; Sean Higgins; Mollie Holmberg; Jessica Hui; Monika Jelic; Ki-Soo Jeong; Jin R Kim; Shannon Klum; Eric Liao; Michael S Lin; Winston Lo; Hillary Miller; Richard Moller; Zhao J Peng; Tom Pollard; Prarthana Pradeep; Dillon Pruett; Dilreet Rai; Vanessa Ros; Alex Schuster; Minnie Singh; Benjamin L Spector; Helen Vander Wende; Adrienne M Wang; Brian M Wasko; Brady Olsen; Matt Kaeberlein
Journal:  Cell Cycle       Date:  2012-08-08       Impact factor: 4.534

5.  Ribosome deficiency protects against ER stress in Saccharomyces cerevisiae.

Authors:  Kristan K Steffen; Mark A McCormick; Kim M Pham; Vivian L MacKay; Joe R Delaney; Christopher J Murakami; Matt Kaeberlein; Brian K Kennedy
Journal:  Genetics       Date:  2012-02-29       Impact factor: 4.562

6.  The short life span of Saccharomyces cerevisiae sgs1 and srs2 mutants is a composite of normal aging processes and mitotic arrest due to defective recombination.

Authors:  M McVey; M Kaeberlein; H A Tissenbaum; L Guarente
Journal:  Genetics       Date:  2001-04       Impact factor: 4.562

7.  Sir2 deletion prevents lifespan extension in 32 long-lived mutants.

Authors:  Joe R Delaney; George L Sutphin; Ben Dulken; Sylvia Sim; Jin R Kim; Brett Robison; Jennifer Schleit; Christopher J Murakami; Daniel Carr; Elroy H An; Eunice Choi; Annie Chou; Marissa Fletcher; Monika Jelic; Bin Liu; Daniel Lockshon; Richard M Moller; Diana N Pak; Qi Peng; Zhao J Peng; Kim M Pham; Michael Sage; Amrita Solanky; Kristan K Steffen; Mitsuhiro Tsuchiya; Scott Tsuchiyama; Simon Johnson; Chris Raabe; Yousin Suh; Zhongjun Zhou; Xinguang Liu; Brian K Kennedy; Matt Kaeberlein
Journal:  Aging Cell       Date:  2011-10-03       Impact factor: 9.304

8.  Requirement of NAD and SIR2 for life-span extension by calorie restriction in Saccharomyces cerevisiae.

Authors:  S J Lin; P A Defossez; L Guarente
Journal:  Science       Date:  2000-09-22       Impact factor: 47.728

Review 9.  Replicative and chronological aging in Saccharomyces cerevisiae.

Authors:  Valter D Longo; Gerald S Shadel; Matt Kaeberlein; Brian Kennedy
Journal:  Cell Metab       Date:  2012-07-03       Impact factor: 27.287

10.  The Saccharomyces cerevisiae WRN homolog Sgs1p participates in telomere maintenance in cells lacking telomerase.

Authors:  F B Johnson; R A Marciniak; M McVey; S A Stewart; W C Hahn; L Guarente
Journal:  EMBO J       Date:  2001-02-15       Impact factor: 11.598
View more
  16 in total

1.  High-throughput analysis of yeast replicative aging using a microfluidic system.

Authors:  Myeong Chan Jo; Wei Liu; Liang Gu; Weiwei Dang; Lidong Qin
Journal:  Proc Natl Acad Sci U S A       Date:  2015-07-13       Impact factor: 11.205

Review 2.  Microfluidic technologies for yeast replicative lifespan studies.

Authors:  Kenneth L Chen; Matthew M Crane; Matt Kaeberlein
Journal:  Mech Ageing Dev       Date:  2016-03-23       Impact factor: 5.432

3.  Inactivation of yeast Isw2 chromatin remodeling enzyme mimics longevity effect of calorie restriction via induction of genotoxic stress response.

Authors:  Weiwei Dang; George L Sutphin; Jean A Dorsey; Gabriel L Otte; Kajia Cao; Rocco M Perry; Jennifer J Wanat; Dimitra Saviolaki; Christopher J Murakami; Scott Tsuchiyama; Brett Robison; Brian D Gregory; Michiel Vermeulen; Ramin Shiekhattar; F Brad Johnson; Brian K Kennedy; Matt Kaeberlein; Shelley L Berger
Journal:  Cell Metab       Date:  2014-05-08       Impact factor: 27.287

4.  A programmable fate decision landscape underlies single-cell aging in yeast.

Authors:  Yang Li; Yanfei Jiang; Julie Paxman; Richard O'Laughlin; Stephen Klepin; Yuelian Zhu; Lorraine Pillus; Lev S Tsimring; Jeff Hasty; Nan Hao
Journal:  Science       Date:  2020-07-17       Impact factor: 47.728

5.  A Comprehensive Analysis of Replicative Lifespan in 4,698 Single-Gene Deletion Strains Uncovers Conserved Mechanisms of Aging.

Authors:  Mark A McCormick; Joe R Delaney; Mitsuhiro Tsuchiya; Scott Tsuchiyama; Anna Shemorry; Sylvia Sim; Annie Chia-Zong Chou; Umema Ahmed; Daniel Carr; Christopher J Murakami; Jennifer Schleit; George L Sutphin; Brian M Wasko; Christopher F Bennett; Adrienne M Wang; Brady Olsen; Richard P Beyer; Theodor K Bammler; Donna Prunkard; Simon C Johnson; Juniper K Pennypacker; Elroy An; Arieanna Anies; Anthony S Castanza; Eunice Choi; Nick Dang; Shiena Enerio; Marissa Fletcher; Lindsay Fox; Sarani Goswami; Sean A Higgins; Molly A Holmberg; Di Hu; Jessica Hui; Monika Jelic; Ki-Soo Jeong; Elijah Johnston; Emily O Kerr; Jin Kim; Diana Kim; Katie Kirkland; Shannon Klum; Soumya Kotireddy; Eric Liao; Michael Lim; Michael S Lin; Winston C Lo; Dan Lockshon; Hillary A Miller; Richard M Moller; Brian Muller; Jonathan Oakes; Diana N Pak; Zhao Jun Peng; Kim M Pham; Tom G Pollard; Prarthana Pradeep; Dillon Pruett; Dilreet Rai; Brett Robison; Ariana A Rodriguez; Bopharoth Ros; Michael Sage; Manpreet K Singh; Erica D Smith; Katie Snead; Amrita Solanky; Benjamin L Spector; Kristan K Steffen; Bie Nga Tchao; Marc K Ting; Helen Vander Wende; Dennis Wang; K Linnea Welton; Eric A Westman; Rachel B Brem; Xin-Guang Liu; Yousin Suh; Zhongjun Zhou; Matt Kaeberlein; Brian K Kennedy
Journal:  Cell Metab       Date:  2015-10-08       Impact factor: 27.287

6.  The Natural Variation in Lifespans of Single Yeast Cells Is Related to Variation in Cell Size, Ribosomal Protein, and Division Time.

Authors:  Georges E Janssens; Liesbeth M Veenhoff
Journal:  PLoS One       Date:  2016-12-01       Impact factor: 3.240

Review 7.  Evidence for the hallmarks of human aging in replicatively aging yeast.

Authors:  Georges E Janssens; Liesbeth M Veenhoff
Journal:  Microb Cell       Date:  2016-06-20

8.  Rb analog Whi5 regulates G1 to S transition and cell size but not replicative lifespan in budding yeast.

Authors:  Matthew M Crane; Mitsuhiro Tsuchiya; Ben W Blue; Jared D Almazan; Kenneth L Chen; Siobhan R Duffy; Alexandra Golubeva; Annaiz M Grimm; Alison M Guard; Shauna A Hill; Ellen Huynh; Ryan M Kelly; Michael Kiflezghi; Hyunsung D Kim; Mitchell Lee; Ting-I Lee; Jiayi Li; Bao M G Nguyen; Riley M Whalen; Feng Y Yeh; Mark McCormick; Brian K Kennedy; Joe R Delaney; Matt Kaeberlein
Journal:  Transl Med Aging       Date:  2019-10-31

9.  Buffering the pH of the culture medium does not extend yeast replicative lifespan.

Authors:  Brian M Wasko; Daniel T Carr; Herman Tung; Ha Doan; Nathan Schurman; Jillian R Neault; Joey Feng; Janet Lee; Ben Zipkin; Jacob Mouser; Edward Oudanonh; Tina Nguyen; Torin Stetina; Anna Shemorry; Mekedes Lemma; Matt Kaeberlein
Journal:  F1000Res       Date:  2013-10-15

Review 10.  Quasi-programmed aging of budding yeast: a trade-off between programmed processes of cell proliferation, differentiation, stress response, survival and death defines yeast lifespan.

Authors:  Anthony Arlia-Ciommo; Amanda Piano; Anna Leonov; Veronika Svistkova; Vladimir I Titorenko
Journal:  Cell Cycle       Date:  2014       Impact factor: 4.534
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.