SARS-CoV-2 Unrevealed: Ultrastructural and Nanomechanical Analysis

The ongoing outbreak of the severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) started in late 2019 and spread across the world, infecting millions of people, with over 3.3 million deaths worldwide. To fight back the virus, it is necessary to understand how the main structures work, especially those responsible for the virus infectivity pathogenicity. Here, using the most advanced atomic force microscopy techniques, SARS-CoV-2 viral particles were analyzed, with a special focus on their ultrastructure, adsorption conformation, and nanomechanical behavior. The results uncovered the aspects of the organization and the spatial distribution of the proteins on the surface of the viral particles. It also showed the compliant behavior of the membrane and ability to recover from mechanical injuries. At least three layers composing the membrane and their thickness were measured, protecting the virus from external stress. This study provides new insight into the ultrastructure of SARS-CoV-2 particles at the nanoscale, offering new prospects that could be employed for mapping viral surfaces. The understanding of the viruses' capacity to survive mechanical disruptions at any level and their ability to recover from such injuries can shed a light on the structure-function relationship and help us to find targets for drug action, especially for this virus that, to this day, has no course of treatment approved.

Automated summary

This study utilized advanced atomic force microscopy techniques to analyze SARS-CoV-2 viral particles, focusing on their ultrastructure, adsorption conformation, and nanomechanical behavior. The results revealed the organization and spatial distribution of proteins on the viral particles' surface, as well as the membrane's compliant behavior and ability to recover from mechanical injuries. The study also identified at least three layers composing the membrane that protect the virus from external stress.