Immune and epithelial determinants of age-related risk and alveolar injury in fatal COVID-19
Michael Chait, Mine M. Yilmaz, Shanila Shakil, Amy W. Ku, Pranay Dogra, Thomas J. Connors, Peter A. Szabo, Joshua I. Gray, Steven B. Wells, Masaru Kubota, Rei Matsumoto, Maya M.L. Poon, Mark E. Snyder, Matthew R. Baldwin, Peter A. Sims, Anjali Saqi, Donna L. Farber, Stuart P. Weisberg
Michael Chait, Mine M. Yilmaz, Shanila Shakil, Amy W. Ku, Pranay Dogra, Thomas J. Connors, Peter A. Szabo, Joshua I. Gray, Steven B. Wells, Masaru Kubota, Rei Matsumoto, Maya M.L. Poon, Mark E. Snyder, Matthew R. Baldwin, Peter A. Sims, Anjali Saqi, Donna L. Farber, Stuart P. Weisberg
View: Text | PDF
Research Article Aging COVID-19

Immune and epithelial determinants of age-related risk and alveolar injury in fatal COVID-19

Abstract

Respiratory failure in COVID-19 is characterized by widespread disruption of the lung’s alveolar gas exchange interface. To elucidate determinants of alveolar lung damage, we performed epithelial and immune cell profiling in lungs from 24 COVID-19 autopsies and 43 uninfected organ donors ages 18–92 years. We found marked loss of type 2 alveolar epithelial (T2AE) cells and increased perialveolar lymphocyte cytotoxicity in all fatal COVID-19 cases, even at early stages before typical patterns of acute lung injury are histologically apparent. In lungs from uninfected organ donors, there was also progressive loss of T2AE cells with increasing age, which may increase susceptibility to COVID-19–mediated lung damage in older individuals. In the fatal COVID-19 cases, macrophage infiltration differed according to the histopathological pattern of lung injury. In cases with acute lung injury, we found accumulation of CD4+ macrophages that expressed distinctly high levels of T cell activation and costimulation genes and strongly correlated with increased extent of alveolar epithelial cell depletion and CD8+ T cell cytotoxicity. Together, our results show that T2AE cell deficiency may underlie age-related COVID-19 risk and initiate alveolar dysfunction shortly after infection, and we define immune cell mediators that may contribute to alveolar injury in distinct pathological stages of fatal COVID-19.

Authors

Michael Chait, Mine M. Yilmaz, Shanila Shakil, Amy W. Ku, Pranay Dogra, Thomas J. Connors, Peter A. Szabo, Joshua I. Gray, Steven B. Wells, Masaru Kubota, Rei Matsumoto, Maya M.L. Poon, Mark E. Snyder, Matthew R. Baldwin, Peter A. Sims, Anjali Saqi, Donna L. Farber, Stuart P. Weisberg

×

Figure 3

Distinct profiles of alveolar epithelial cell loss associated with lung tissue pathology in fatal COVID-19.

Options: View larger image (or click on image) Download as PowerPoint
Distinct profiles of alveolar epithelial cell loss associated with lung ...
(A) Dual-chromogen staining in alveolar lungs for nuclear TTF-1 (brown) and cytoplasmic Napsin-A (red) with hematoxylin counterstain (blue). Shown are representative original magnification 40× fields from 2 uninfected controls (left), early COVID-19 mortality cases without ALI (middle), and late COVID-19 mortality cases with ALI (right). (B and C) Dot plots depicting type 2 alveolar epithelial cell density (T2AE, TTF-1+Napsin-A+) (B, left) and type 1 alveolar epithelial cell density (T1AE, TTF-1+Napsin-A) (C, left) in the controls (n = 17) compared with the COVID-19 mortality cases with (n = 15) and without (n = 9) ALI (indicated on the x axis). Also shown are the T2AE (B, right) and T1AE (C, right) cell densities plotted against the symptomatic interval. The best-fit line with 95% confidence bands and R2 and P values were calculated using simple linear regression analysis. Black scale bar: 50 μm. Solid arrow, T1AE cells; double arrow, T2AE cells; single arrow, macrophages. Error bars show median and interquartile range. **P < 0.01, ***P < 0.001, ****P < 0.0001.