Senolytic-Resistant Senescent Cells Have a Distinct SASP Profile and Functional Impact: The Path to Developing Senosensitizers

  1. Utkarsh Tripathi
  2. Masayoshi Suda
  3. Vagisha Kulshreshtha
  4. Bryan T. Piatkowski
  5. Allyson K. Palmer
  6. Nino Giorgadze
  7. Christina Inman
  8. Nathan Gasek
  9. Ming Xu
  10. Kurt O. Johnson
  11. Tamar Pirtskhalava
  12. Selim Chaib
  13. Larissa P. G. Langhi Prata
  14. Yi Zhu
  15. Renuka Kandhaya-Pillai
  16. Stefan G. Tullius
  17. Saranya P Wyles
  18. Rambabu Majji
  19. Hari Krishna Yalamanchili
  20. David B. Allison
  21. Tamar Tchkonia
  22. James L. Kirkland
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Abstract

The senescent cell (SC) fate is linked to aging, multiple disorders and diseases, and physical dysfunction. Senolytics, agents that selectively eliminate 30-70% of SCs, act by transiently disabling the senescent cell anti-apoptotic pathways (SCAPs), which defend those SCs that are pro-apoptotic and pro-inflammatory from their own senescence-associated secretory phenotype (SASP). Consistent with this, a JAK/STAT inhibitor, Ruxolitinib, which attenuates the pro-inflammatory SASP of senescent human preadipocytes, caused them to become “senolytic-resistant”. Administering senolytics to obese mice selectively decreased abundance of the subset of SCs that is pro-inflammatory. In cell cultures, the 30-70% of human senescent preadipocytes or human umbilical vein endothelial cells (HUVECs) that are senolytic-resistant (to Dasatinib or Quercetin, respectively) had increased p16INK4a, p21CIP1, senescence-associated β-galactosidase (SAβgal), γH2AX, and proliferative arrest similarly to the total SC population (comprising senolytic-sensitive <underline>plus</underline> -resistant SCs). However, the SASP of senolytic-resistant SCs entailed less pro-inflammatory/ apoptotic factor production, induced less inflammation in non-senescent cells, and was equivalent or richer in growth/ fibrotic factors. Senolytic-resistant SCs released less mitochondrial DNA (mtDNA) and more highly expressed the anti-inflammatory immune evasion signal, glycoprotein non-melanoma-B (GPNMB). Transplanting senolytic-resistant SCs intraperitoneally into younger mice caused less physical dysfunction than transplanting the total SC population. Because Ruxolitinib attenuates SC release of pro-apoptotic SASP factors, while pathogen-associated molecular pattern factors (PAMPs) can amplify the release of these factors rapidly (acting as “senosensitizers”), senolytic-resistant and senolytic-sensitive SCs appear to be interconvertible.

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