Dynamic and prognostic proteomic associations with FEV 1 decline in chronic obstructive pulmonary disease

  1. Lisa Ruvuna
  2. Kahkeshan Hijazi
  3. Daniel E. Guzman
  4. Claire Guo
  5. Joseph Loureiro
  6. Edward Khokhlovich
  7. Melody Morris
  8. Ma’en Obeidat
  9. Katherine A. Pratte
  10. Katarina M. DiLillo
  11. Sunita Sharma
  12. Katerina Kechris
  13. Antonio Anzueto
  14. Igor Barjaktarevic
  15. Eugene R. Bleecker
  16. Richard Casaburi
  17. Alejandro Comellas
  18. Christopher B. Cooper
  19. Dawn L. DeMeo
  20. Marilyn Foreman
  21. Eric L. Flenaugh
  22. MeiLan K. Han
  23. Nicola A. Hanania
  24. Craig P. Hersh
  25. Jerry A. Krishnan
  26. Wassim W. Labaki
  27. Fernando J. Martinez
  28. Wanda K. O’Neal
  29. Robert Paine
  30. Stephen P. Peters
  31. Prescott G. Woodruff
  32. J Michael Wells
  33. Christine H. Wendt
  34. Kelly B. Arnold
  35. R. Graham Barr
  36. Jeffrey L. Curtis
  37. Debby Ngo
  38. Russell P. Bowler
  39. SPIROMICS, COPDGene and MESA-Lung Investigators
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Abstract

Rationale

Identification and validation of circulating biomarkers for lung function decline in COPD remains an unmet need.

Objective

Identify prognostic and dynamic plasma protein biomarkers of COPD progression.

Methods

We measured plasma proteins using SomaScan from two COPD-enriched cohorts, the Subpopulations and Intermediate Outcomes Measures in COPD Study (SPIROMICS) and Genetic Epidemiology of COPD (COPDGene), and one population-based cohort, Multi-Ethnic Study of Atherosclerosis (MESA) Lung. Using SPIROMICS as a discovery cohort, linear mixed models identified baseline proteins that predicted future change in FEV 1 (prognostic model) and proteins whose expression changed with change in lung function (dynamic model). Findings were replicated in COPDGene and MESA-Lung. Using the COPD-enriched cohorts, Gene Set Enrichment Analysis (GSEA) identified proteins shared between COPDGene and SPIROMICS. Metascape identified significant associated pathways.

Measurements and Main Results

The prognostic model found 7 significant proteins in common (p < 0.05) among all 3 cohorts. After applying false discovery rate (adjusted p < 0.2), leptin remained significant in all three cohorts and growth hormone receptor remained significant in the two COPD cohorts. Elevated baseline levels of leptin and growth hormone receptor were associated with slower rate of decline in FEV 1 . Twelve proteins were nominally but not FDR significant in the dynamic model and all were distinct from the prognostic model. Metascape identified several immune related pathways unique to prognostic and dynamic proteins.

Conclusion

We identified leptin as the most reproducible COPD progression biomarker. The difference between prognostic and dynamic proteins suggests disease activity signatures may be different from prognosis signatures.

Article activity feed

  1. Version published to 10.1101/2024.08.07.24311507v1 on medRxiv