ABSTRACT
COVID-19 convalescents often experience persistent symptoms such as fatigue, neurologic complications or dyspnea, often referred to as "long COVID". To elucidate molecular mechanisms underlying ongoing dyspnea in COVID-19 convalescents, we analyzed single-cell RNA sequencing data from nasal swabs collected during acute infection, and three, six and twelve months post infection together with matching healthy controls. Patients with and without persisting symptoms and with varying severity during the acute phase were included. Post infection, we observed a time-dependent decrease in immune cells. Transcriptional analysis of nasal epithelial cells provided evidence of an impaired cilia assembly, organization and function in COVID-19 convalescents with dyspnea compared to healthy controls and convalescents without ongoing respiratory symptoms. Moreover, differences in the differentiation trajectories of ciliated cells were evident between patients with and without dyspnea, with less diverse differentiation endpoints in the dyspnea patients than in healthy controls or convalescents without respiratory impairment. Overall, our analyses revealed a potential deficiency of ciliated cells in COVID-19 convalescents with dyspnea compared to convalescents without ongoing respiratory symptoms or compared with healthy controls. Ciliated cells clear the lung from particles and mucus. If these cells are functionally impaired, pathogens remain in the airways, causing respiratory problems and infections. Thus, it is reasonable to assume, that impaired ciliated cell function contributes to the persistent respiratory symptoms seen in COVID-19 convalescents.