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Naturally occurring p16Ink4a-positive cells shorten healthy lifespan

Author

Listed:
  • Darren J. Baker

    (Mayo Clinic College of Medicine)

  • Bennett G. Childs

    (Mayo Clinic College of Medicine)

  • Matej Durik

    (Mayo Clinic College of Medicine)

  • Melinde E. Wijers

    (Mayo Clinic College of Medicine)

  • Cynthia J. Sieben

    (Mayo Clinic College of Medicine)

  • Jian Zhong

    (Mayo Clinic College of Medicine)

  • Rachel A. Saltness

    (Mayo Clinic College of Medicine)

  • Karthik B. Jeganathan

    (Mayo Clinic College of Medicine)

  • Grace Casaclang Verzosa

    (Mayo Clinic College of Medicine)

  • Abdulmohammad Pezeshki

    (Mayo Clinic College of Medicine)

  • Khashayarsha Khazaie

    (Mayo Clinic College of Medicine)

  • Jordan D. Miller

    (Mayo Clinic College of Medicine)

  • Jan M. van Deursen

    (Mayo Clinic College of Medicine
    Mayo Clinic College of Medicine)

Abstract

Cellular senescence, a stress-induced irreversible growth arrest often characterized by expression of p16Ink4a (encoded by the Ink4a/Arf locus, also known as Cdkn2a) and a distinctive secretory phenotype, prevents the proliferation of preneoplastic cells and has beneficial roles in tissue remodelling during embryogenesis and wound healing. Senescent cells accumulate in various tissues and organs over time, and have been speculated to have a role in ageing. To explore the physiological relevance and consequences of naturally occurring senescent cells, here we use a previously established transgene, INK-ATTAC, to induce apoptosis in p16Ink4a-expressing cells of wild-type mice by injection of AP20187 twice a week starting at one year of age. We show that compared to vehicle alone, AP20187 treatment extended median lifespan in both male and female mice of two distinct genetic backgrounds. The clearance of p16Ink4a-positive cells delayed tumorigenesis and attenuated age-related deterioration of several organs without apparent side effects, including kidney, heart and fat, where clearance preserved the functionality of glomeruli, cardio-protective KATP channels and adipocytes, respectively. Thus, p16Ink4a-positive cells that accumulate during adulthood negatively influence lifespan and promote age-dependent changes in several organs, and their therapeutic removal may be an attractive approach to extend healthy lifespan.

Suggested Citation

  • Darren J. Baker & Bennett G. Childs & Matej Durik & Melinde E. Wijers & Cynthia J. Sieben & Jian Zhong & Rachel A. Saltness & Karthik B. Jeganathan & Grace Casaclang Verzosa & Abdulmohammad Pezeshki &, 2016. "Naturally occurring p16Ink4a-positive cells shorten healthy lifespan," Nature, Nature, vol. 530(7589), pages 184-189, February.
  • Handle: RePEc:nat:nature:v:530:y:2016:i:7589:d:10.1038_nature16932
    DOI: 10.1038/nature16932
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    Cited by:

    1. Ross J. Hill & Nazareno Bona & Job Smink & Hannah K. Webb & Alastair Crisp & Juan I. Garaycoechea & Gerry P. Crossan, 2024. "p53 regulates diverse tissue-specific outcomes to endogenous DNA damage in mice," Nature Communications, Nature, vol. 15(1), pages 1-16, December.
    2. Jina Yun & Simon Hansen & Otto Morris & David T. Madden & Clare Peters Libeu & Arjun J. Kumar & Cameron Wehrfritz & Aaron H. Nile & Yingnan Zhang & Lijuan Zhou & Yuxin Liang & Zora Modrusan & Michelle, 2023. "Senescent cells perturb intestinal stem cell differentiation through Ptk7 induced noncanonical Wnt and YAP signaling," Nature Communications, Nature, vol. 14(1), pages 1-19, December.
    3. Yinsheng Wu & Lixu Tang & Han Huang & Qi Yu & Bicheng Hu & Gang Wang & Feng Ge & Tailang Yin & Shanshan Li & Xilan Yu, 2023. "Phosphoglycerate dehydrogenase activates PKM2 to phosphorylate histone H3T11 and attenuate cellular senescence," Nature Communications, Nature, vol. 14(1), pages 1-21, December.
    4. Imanol Duran & Joaquim Pombo & Bin Sun & Suchira Gallage & Hiromi Kudo & Domhnall McHugh & Laura Bousset & Jose Efren Barragan Avila & Roberta Forlano & Pinelopi Manousou & Mathias Heikenwalder & Domi, 2024. "Detection of senescence using machine learning algorithms based on nuclear features," Nature Communications, Nature, vol. 15(1), pages 1-20, December.
    5. Gorshkov, Vyacheslav & Privman, Vladimir & Libert, Sergiy, 2016. "Lattice percolation approach to 3D modeling of tissue aging," Physica A: Statistical Mechanics and its Applications, Elsevier, vol. 462(C), pages 207-216.
    6. Damien Maggiorani & Oanh Le & Véronique Lisi & Séverine Landais & Gaël Moquin-Beaudry & Vincent Philippe Lavallée & Hélène Decaluwe & Christian Beauséjour, 2024. "Senescence drives immunotherapy resistance by inducing an immunosuppressive tumor microenvironment," Nature Communications, Nature, vol. 15(1), pages 1-15, December.
    7. Yudong Fu & Fan Jiang & Xiao Zhang & Yingyi Pan & Rui Xu & Xiu Liang & Xiaofen Wu & Xingqiang Li & Kaixuan Lin & Ruona Shi & Xiaofei Zhang & Dominique Ferrandon & Jing Liu & Duanqing Pei & Jie Wang & , 2024. "Perturbation of METTL1-mediated tRNA N7- methylguanosine modification induces senescence and aging," Nature Communications, Nature, vol. 15(1), pages 1-21, December.
    8. Moh’d Mohanad Al-Dabet & Khurrum Shahzad & Ahmed Elwakiel & Alba Sulaj & Stefan Kopf & Fabian Bock & Ihsan Gadi & Silke Zimmermann & Rajiv Rana & Shruthi Krishnan & Dheerendra Gupta & Jayakumar Manoha, 2022. "Reversal of the renal hyperglycemic memory in diabetic kidney disease by targeting sustained tubular p21 expression," Nature Communications, Nature, vol. 13(1), pages 1-17, December.
    9. Ines Sturmlechner & Chance C. Sine & Karthik B. Jeganathan & Cheng Zhang & Raul O. Fierro Velasco & Darren J. Baker & Hu Li & Jan M. Deursen, 2022. "Senescent cells limit p53 activity via multiple mechanisms to remain viable," Nature Communications, Nature, vol. 13(1), pages 1-14, December.
    10. Madison L. Doolittle & Dominik Saul & Japneet Kaur & Jennifer L. Rowsey & Stephanie J. Vos & Kevin D. Pavelko & Joshua N. Farr & David G. Monroe & Sundeep Khosla, 2023. "Multiparametric senescent cell phenotyping reveals targets of senolytic therapy in the aged murine skeleton," Nature Communications, Nature, vol. 14(1), pages 1-20, December.
    11. Xu Zhang & Vesselina M. Pearsall & Chase M. Carver & Elizabeth J. Atkinson & Benjamin D. S. Clarkson & Ethan M. Grund & Michelle Baez-Faria & Kevin D. Pavelko & Jennifer M. Kachergus & Thomas A. White, 2022. "Rejuvenation of the aged brain immune cell landscape in mice through p16-positive senescent cell clearance," Nature Communications, Nature, vol. 13(1), pages 1-17, December.
    12. Toshiyuki Ko & Seitaro Nomura & Shintaro Yamada & Kanna Fujita & Takanori Fujita & Masahiro Satoh & Chio Oka & Manami Katoh & Masamichi Ito & Mikako Katagiri & Tatsuro Sassa & Bo Zhang & Satoshi Hatsu, 2022. "Cardiac fibroblasts regulate the development of heart failure via Htra3-TGF-β-IGFBP7 axis," Nature Communications, Nature, vol. 13(1), pages 1-17, December.
    13. Carlos Anerillas & Allison B. Herman & Rachel Munk & Amanda Garrido & Kwan-Wood Gabriel Lam & Matthew J. Payea & Martina Rossi & Dimitrios Tsitsipatis & Jennifer L. Martindale & Yulan Piao & Krystyna , 2022. "A BDNF-TrkB autocrine loop enhances senescent cell viability," Nature Communications, Nature, vol. 13(1), pages 1-17, December.
    14. Jie Sun & Ming Wang & Yaqi Zhong & Xuan Ma & Shimin Sun & Chenzhong Xu & Linyuan Peng & Guo Li & Liting Zhang & Zuojun Liu & Ding Ai & Baohua Liu, 2022. "A Glb1-2A-mCherry reporter monitors systemic aging and predicts lifespan in middle-aged mice," Nature Communications, Nature, vol. 13(1), pages 1-13, December.
    15. Cox, Lynne S., 2022. "Therapeutic approaches to treat and prevent age-related diseases through understanding the underlying biological drivers of ageing," The Journal of the Economics of Ageing, Elsevier, vol. 23(C).

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