Utility of Plasma Cell-free Chromatin Immunoprecipitation to Detect Cardiac Allograft Rejection

  1. Moon Kyoo Jang
  2. Oladele Oluwayiose
  3. Neelam Redekar
  4. Temesgen E Andargie
  5. Woojin Park
  6. Muhtadi Alnababteh
  7. Tom Hill
  8. Kellie Phipps
  9. Hyesik Kong
  10. Xin Tian
  11. Helen I Luikart
  12. Michael A Solomon
  13. Palak Shah
  14. Hannah A Valantine
  15. Kiran Khush
  16. Sean Agbor-Enoh
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Abstract

Background

Antibody-mediated rejection (AMR) remains the major risk factor for allograft loss across all solid organ transplantation. Unfortunately, its diagnosis relies on biopsy, an invasive gold standard that often sample unaffected allograft tissue leading to missed diagnosis. Plasma donor-derived cell-free DNA (dd-cfDNA) is noninvasive biomarker that has high sensitivity but low specificity for AMR diagnosis. This proof-of-concept study assessed the utility of cell-free chromatin immunoprecipitation (cfChIP) as a surrogate for gene expression to detect cardiac AMR and the associated pathobiology.

Methods

The discovery GRAfT multicenter cohort of heart transplant patients ( NCT02423070 ) identified AMR, acute cellular rejection (ACR), and stable controls based on biopsy and dd-cfDNA results. Plasma cfChIP-sequencing was performed to identify peaks, associated genes and pathobiological pathways. Plasma from an external cohort (GTD, NCT01985412 ) was also analyzed to verify pathways identified. Digital droplet PCR (ddPCR) assays targeting differential regions were constructed to test the diagnostic performance of cfDNA to detect AMR/ACR from stable controls (rejection-specific assays) or AMR from ACR (AMR-specific assays).

Results

The cohort included 21 AMR, 28 ACR, and 45 stable controls from GRAfT and GTD, and 23 healthy controls. cfChIP detected expected active genes, including housekeeping genes and gene targets of transplant immunosuppressive drugs but not inactive genes. Unsupervised clustering of the discovery GRAfT cohort assigned 95% of samples correctly as AMR, ACR or stable control. Differential analysis identified pathobiological pathways of AMR such as neutrophil degranulation and complement activation. The pathways were consistent in GTD samples. Rejection-specific assays detected AMR/ACR from controls with AUC of 0.78 - 0.95. AMR-specific assays detected AMR from ACR with AUC of 0.71 - 0.85, sensitivities of 0.73 - 0.94 and specificities of 0.73 - 0.80.

Conclusion

This study provides valuable preliminary data supporting the use of cfChIP to detect AMR and the associated pathobiological pathways.

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  1. Version published to 10.1101/2025.03.04.25323391v1 on medRxiv