Genome-wide association study reveals two novel genetic loci associated with chronic lung allograft dysfunction

  1. Simon Brocard
  2. Vincent Mauduit
  3. Martin Morin
  4. Léo Boussamet
  5. Nayane dos Santos Brito Silva
  6. Axelle Durand
  7. Pierre Halitim
  8. Benjamin Renaud-Picard
  9. Benjamin Coiffard
  10. Xavier Demant
  11. Loïc Falque
  12. Jérome Le Pavec
  13. Antoine Roux
  14. Thomas Villeneuve
  15. Christiane Knoop
  16. Claire Merveilleux
  17. Mathilde Salpin
  18. Nicolas Carlier
  19. Pierre Antoine Gourraud
  20. Antoine Magnan
  21. David Lair
  22. Laureline Berthelot
  23. Mario Südholt
  24. Nicolas Vince
  25. Adrien Tissot
  26. Sophie Limou
  27. COLT consortium
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Abstract

Background

Chronic lung allograft dysfunction (CLAD) leads to declining respiratory function and high mortality, representing the main barrier to long-term survival in lung transplantation (LT). We performed the first genome-wide association study (GWAS) investigating donor’s and recipient’s genetic factors associated with CLAD.

Method

We genotyped 392 donor-recipient pairs from the multicentric Cohort in Lung Transplantation. We tested 4.5 million SNPs for association with CLAD using multivariable logistic regression models corrected for age, sex, initial disease and genetic ancestry. Three levels of explanatory variables were separately considered to conduct GWAS: donors-only, recipients-only, and donor-recipient mismatches. We also ran HLA-centric analyses using the same models.

Results

Our analysis confirmed the deleterious impact of HLA allelic and epitopic mismatches on CLAD risk, mostly driven by class I HLA (p=0.004). No significant associations with CLAD were found for donors’ genotypes or donor-recipient non-HLA mismatches. We highlighted two independent recipient’s loci associated with CLAD, including one protective signal (0.39 in CLAD vs 0.66 in non-CLAD recipients, p-value=5.05×10 -7 , q-value=0.017, OR=0.35) encompassing the PLXDC2 gene, and one risk signal (0.66 in CLAD vs 0.38 in non-CLAD recipients, p-value=9.86×10 -7 , q-value=0.017, OR=2.83) encompassing the ZNF518A/BLNK genes. These non-coding SNPs are putative regulatory variants of gene expression. Importantly, our single-cell RNA-sequencing showed a down-regulation of PLXDC2 in monocytes and lung epithelium in CLAD vs healthy controls (p≤2.0×10 -16 ).

Conclusion

This first LT GWAS revealed two candidate loci from the recipient’s genome, both biologically relevant for CLAD pathogenesis. Our study calls for larger LT genomic initiatives to increase power for signal discovery.

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  1. Version published to 10.1101/2025.11.05.25339596 on medRxiv