ABSTRACT
Predicting pathogenicity of Omicron sub-variants is critical for assessing disease dynamics and developing public health strategies. As an important virulence factor, SARS-CoV-2 envelope protein (2-E) causes cell death and acute respiratory distress syndrome (ARDS)-like pathological damages. Evaluation of 2-E mutations might offer clues to pathogenicity forecast. Here, the frequency and cell lethality of 92 mutations of 2-E in five early "variants of concern" (VOCs, Alpha, Beta, Gamma, Delta, and Omicron BA.1, BA.2, BA.3, BA.4, and BA.5) were analyzed, which could be divided into three classes. Most (87) mutations belong to Class I, no obvious frequency changes. Class II consists of 2 mutations, exhibiting enhanced cell lethality but decreased frequency. The rest 3 mutations in Class III were characterized by attenuated cell lethality and increased frequency. Remarkably, the Class II mutations are always observed in the VOCs with high disease severity while the Class III mutations are highly conserved in the VOCs with weakened pathogenicity. For example, P71L, the most lethal mutation, dropped to nearly 0.00% in the milder Omicrons from 99.12% in Beta, while the less lethal mutation T9I, sharply increased to 99.70% in BA.1 and is highly conserved in BA.1-5. Accordingly, we proposed that some key 2-E mutations are pathogenicity markers of the virus. Notably, the highly contagious Omicron XBB retained T9I also. In addition, XBB gained a new dominant-negative mutation T11A with frequency 90.52%, exhibiting reduced cell lethality, cytokine induction and viral production capabilities in vitro, and particularly weakened lung damages in mice. No mutations with enhanced cell lethality were observed in XBB. These clues imply a further weakened pathogenicity of XBB among Omicron sub-variants.
Subject(s)
Respiratory Distress Syndrome , DeathABSTRACT
SARS-CoV-2 Omicron variant is highly transmissible and extensive morbidity, which has raised concerns for antiviral therapy. In addition, the molecular basis for the attenuated pathogenicity and replication capacity of Omicron remains elusive. Here, we report for the first time that a high-frequency mutation T9I on 2-E of SARS-CoV-2 variant Omicron forms a non-selective ion channel with abolished calcium permeability and reduced acid sensitivity compared to the WT channel. In addition, T9I caused less cell death and a weaker cytokine production. The channel property changes might be responsible for the Omicron variant releases less efficiently and induces a comparatively lower level of cell damage in the infected cells. Our study gives valuable insights into key features of the Omicron variant, further supporting 2-E is a promising drug target against SARS-CoV-2 and providing critical information for the COVID-19 treatment.