Distinct Type 1 Immune Networks Underlie the Severity of Restrictive Lung Disease after COVID-19 (preprint)

The variable etiology of persistent breathlessness after COVID-19 have confounded efforts to decipher the immunopathology of lung sequelae. Here, we analyzed hundreds of cellular and molecular features in the context of discrete pulmonary phenotypes to define the systemic immune landscape of post-COVID lung disease. Cluster analysis of lung physiology measures highlighted two phenotypes of restrictive lung disease that differed by their impaired diffusion and severity of fibrosis. Machine learning revealed marked CCR5+CD95+ CD8+ T-cell perturbations in mild-to-moderate lung disease, but attenuated T-cell responses hallmarked by elevated CXCL13 in more severe disease. Distinct sets of cells, mediators, and autoantibodies distinguished each restrictive phenotype, and differed from those of patients without significant lung involvement. These differences were reflected in divergent T-cell-based type 1 networks according to severity of lung disease. Our findings, which provide an immunological basis for active lung injury versus advanced disease after COVID-19, might offer new targets for treatment.

Reduction in circulating monocytes correlates with persistent post-COVID pulmonary fibrosis in multi-omic comparison of long-haul COVID and IPF (preprint)

Rationale: Up to 30% of COVID-19 patients experience persistent sequelae, including dyspnea, restrictive physiology, and early radiographic signs of pulmonary fibrosis (PF). The mechanisms that provoke post-COVID progressive PF are poorly understood, and biomarkers to identify at-risk patients are urgently needed. Methods: We evaluated a cohort of 14 symptomatic COVID survivors with impaired respiratory function and imaging worrisome for developing PF, including bilateral reticulation, traction bronchiectasis and/or honeycombing, and compared these to Idiopathic Pulmonary Fibrosis (IPF) patients and age-matched controls without respiratory disease. We performed single-cell RNA-sequencing and multiplex immunostaining on peripheral blood mononuclear cells collected at the COVID-19 patients first visit after ICU discharge. Six months later, symptoms, restriction and PF improved in some (Early-Resolving COVID PF), but persisted in others (Late-Resolving COVID PF). Results: Circulating monocytes were significantly reduced in Late-Resolving COVID PF patients compared to Early-Resolving COVID PF and non-diseased controls. Monocyte abundance correlated with pulmonary function tests FVC and DLCO. Differential expression analysis revealed MHC-II class molecules were upregulated on the CD8 T cells of Late-Resolving COVID PF patients but downregulated in monocytes. IPF patients had a similar decrease in monocyte abundance and marked decrease in monocyte HLA-DR protein expression compared to Late-Resolving COVID PF patients. Conclusion: Circulating monocyte abundance may distinguish between patients whose post-COVID PF resolves or persists. Furthermore, fibrotic progression coincided with decreases in HLA-DR expression on monocytes, a phenotype previously associated with dampened antigen stimulation and severe respiratory failure.