'Spider web' mechanism traps and kills viruses

Immunologists at Canada’s McMaster University have discovered a mechanism that acts like a spider web — trapping and killing pathogens such as influenza or SARS-CoV-2.

The researchers found that white blood cells called neutrophils explode when they bind to such pathogens coated in antibodies and release DNA outside of the cell, creating a sticky tangle which acts as a trap.

Published in the Proceedings of the National Academy of Science, the findings are significant because little is understood about how antibodies neutralise viruses in the respiratory tract.

The discovery has implications for vaccine design and delivery, including aerosol and nasal spray technologies that could help the body head off infections before they have a chance to take hold.

“Vaccines can produce these antibodies that are present in our lungs, which are the first type of antibody to see viruses like flu or COVID-19, which infect our lungs and respiratory tracts,” said study lead author Associate Professor Matthew Miller.

“Mechanisms that can stop the infection at the site where it enters our body can prevent the spread and serious complications.”

By comparison, injectable vaccines are designed to bolster antibodies in the blood, but those antibodies are not as prevalent at the sites where infection begins.

“We should be thinking carefully about next-generation COVID-19 vaccines that could be administered in the respiratory tract to stimulate antibodies. We don’t have many candidates right now that are focused on raising the mucosal response,” said graduate student and lead author Hannah Stacey.

“If you want a lot of these antibodies that are really abundant in blood, then injections make the most sense, but if you want antibodies that are abundant in the respiratory tract, then a spray or an aerosol makes sense,” she said.

Researchers caution that while the body’s spider-web mechanism has the potential to be hugely beneficial, it can cause harm too, including inflammation and further illness when the web formation is uncontrollable.

They point to the early waves of the pandemic, prior to vaccinations, when these neutrophil extracellular traps, or NETs, were found in some patients’ lungs, and had made their breathing more difficult.

“An immune response that is meant to protect you can end up harming you if it’s not properly controlled,” Miller explained. “It’s important to understand the balance of the immune system. If you have a lot of these antibodies before you get infected, they are likely going to protect you, but if the infection itself stimulates a lot of those antibodies, it might be harmful.”

Image caption: McMaster expert and lead author of this study Matt Miller and graduate student Hannah Stacey. Credit: McMaster University.