Autoimmune-like CD8⁺ T Cell Responses Drive Atherosclerotic Plaque Instability and Predict Cardiovascular Events

  1. Jonathan Noonan
  2. Nicholas Borcherding
  3. Sander W. van der Laan
  4. Nicholas A. Gherardin
  5. Moustafa I Morsy
  6. Joshua I. Gray
  7. Lisa M. Domke
  8. Anna M.D. Watson
  9. Angela Huang
  10. Anastasia Barbaro-Wahl
  11. Shania A. Prijaya
  12. Marcel Michla
  13. Zahra Elahi
  14. Yilu Huang
  15. Nalin H. Dayawansa
  16. Viktoria Bongcaron
  17. Aidan P.G. Walsh
  18. Prerna Sharma
  19. Ana Maluenda
  20. Peter Kanellakis
  21. Gabriella E. Farrugia
  22. Man-Kit Sam Lee
  23. Andrew J. Murphy
  24. Ian K. Hsu
  25. Alexander R. Pinto
  26. Chad J. Johnson
  27. Yung-Chih Chen
  28. Eleanor Eddy
  29. Mélanie Le Page
  30. Thomas M. Lovelock
  31. Judy Wang
  32. Michael Bourke
  33. Zafreen Rahman
  34. Vincent Varley
  35. Joseph Kilby
  36. Lorena Zentilin
  37. Mauro Giacca
  38. James D. McFadyen
  39. Michal M. Mokry
  40. Gerard Pasterkamp
  41. Xiaowei Wang
  42. Luciano Martelotto
  43. Danika L. Hill
  44. Thomas D. Otto
  45. Robert A. Benson
  46. Alex Bobik
  47. Pasquale Maffia
  48. Megan K.L. MacLeod
  49. Thodur Vasudevan
  50. Axel Kallies
  51. Karlheinz Peter
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Abstract

Background and aims

Atherosclerotic plaque rupture is a major cause of myocardial infarction and stroke. However, the precise drivers of plaque destabilisation remain elusive. We hypothesised that antigen-driven, autoimmune-like T cell responses are central to the destabilisation and rupture of atherosclerotic plaques.

Methods

To dissect T cell responses specifically in unstable compared to stable plaques, we leveraged near-infrared autofluorescence (NIRAF) imaging–guided dissection of human carotid plaques. We also used our tandem stenosis model reflecting plaque instability as seen in patients to differentiate between unstable and stable plaques in mice. To explore T cell involvement, we studied T cell differentiation states and T cell receptor (TCR) repertoires by single-cell multi-omics. Then, testing if antigen-driven CD8 + T cell responses drive plaque instability in mice, we applied a combination of AAV8-PCSK9-induced atherosclerosis, tandem stenosis and TCR transgenic mice. Finally, we leveraged data from the AtheroExpress Biobank Study to link T cell immunity to histology-defined instability and cardiovascular outcomes.

Results

T cell responses in unstable versus stable atherosclerosis were distinct. Unstable human plaques contained highly expanded, autoimmune-like CD8⁺ T cells with markedly increased cytotoxic signatures, reduced exhaustion and distinct clonal repertoires compared to stable regions. Most plaque CD8⁺ T cells exhibited a pronounced tissue-resident transcriptional program. Moreover, the transcriptional signature of these plaque resident T cells was distinct from multiple other human tissues. Autoimmune-like cytotoxic and tissue-resident CD8 + T cell responses were also evident in murine atherosclerosis, where restricting the activation of antigen-driven CD8 + T cells prevented plaque destabilisation. Importantly, analysis of carotid endarterectomy samples from >1000 patients identified that intraplaque cytotoxic CD8⁺ T cell gene signatures strongly correlated with histological instability and predicted future strokes.

Conclusions

Integrated human, murine and clinical analyses demonstrate that autoimmune-like, cytotoxic CD8⁺ T cell responses are central drivers of plaque instability and major cardiovascular events. Targeting pathogenic CD8⁺ T cell responses may thus offer a compelling immunomodulatory strategy to stabilise plaques and reduce the risks of stroke and myocardial infarction.

Graphical Abstract

Key Question

Rupture of unstable atherosclerotic plaques is a typical cause of myocardial infarction and stroke. To understand the underlying cause and to prevent plaque rupture, we addressed the central hypothesis that autoimmune-like T cell responses drive plaque destabilisation and rupture.

Key Findings

CD8 + T cells are clonally expanded with increased cytotoxic signatures in unstable versus stable plaques (mice and humans) and require antigen recognition to drive plaque instability. Cytotoxic CD8 + T cell signatures in excised plaques correlate with increased future cardiovascular events.

Take Home Message

Autoimmune-like adaptive immune reactions, dominated by CD8 + T cells, are a major driver of plaque instability/rupture. Therefore, targeting pathogenic CD8⁺ T cell responses offers a compelling immunomodulatory strategy to stabilise plaques and reduce the risk of myocardial infarction and stroke.

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  1. Version published to 10.64898/2026.04.26.720043 on bioRxiv