Characterization of SARS-CoV-2 ORF6 deletion variants detected in a nosocomial cluster during routine genomic surveillance, Lyon, France

ABSTRACT

Through routine genomic surveillance of the novel SARS-CoV-2 virus (n=229 whole genome sequences), 2 different frameshifting deletions were newly detected in the open reading frame (ORF) 6, starting at the same position (27267). While the 26-nucleotide deletion variant was only found in one sample in March 2020, the 34-nucleotide deletion variant was found within a single geriatric hospital unit in 5/9 patients sequenced and one health care worker with samples collected between April 2nd and 9th, 2020. Both the presence of the 34-nucleotide deletion variant limited to this unit and the clustering of the corresponding whole genome sequences by phylogeny analysis strongly suggested a nosocomial transmission between patients. Interestingly, prolonged viral excretion of the 34-nucleotide deletion variant was identified in a stool sample 14 days after initial diagnosis for one patient. Clinical data revealed no significant difference in disease severity between patients harboring the wild-type or the 34-nucleotide deletion variants. The in vitro infection of the two deletion variants on primate endothelial kidney cells (BGM) and human lung adenocarcinoma cells (Calu-3) yielded comparable replication kinetics with the wild-type strain. Furthermore, high viral loads were found in vivo regardless of the presence or absence of the ORF6 deletion. Our study highlights the transmission and replication capacity of two newly described deletion variants in the same ORF6 region. ImportanceWhile the SARS-CoV-2 genome has remained relatively stable since its emergence in the human population, genomic deletions are an evolutionary pattern previously described for the related SARS-CoV. Real-time genomic monitoring of the circulating variants is paramount to detect strain prevalence and transmission dynamics. Given the role of ORF6 in interferon modulation, further characterization, such as mechanistic interactions and interferon monitoring in patients, is crucial in understanding the viral-host factors driving disease evolution.