Discoveries from the Benaroya Research Institute at Virginia Mason (BRI) have identified a new cellular protection pathway that targets a common vulnerability in several different pandemic viruses, and collaborators at Case Western Reserve University, Boston University School of Medicine and MRIGlobal have shown that this pathway can protect cells from infection by Ebola virus and coronaviruses, like SARS-CoV-2.
Published today in Science, these new findings provide a better understanding of cellular mechanisms involved in viral resistance that can inform future treatments and therapies for viral infectious diseases.
The research illuminates a completely new role for the two genes identified and a unique approach to inhibiting virus fusion and entry into human cells--getting us one step closer to the next generation of antiviral therapies.
Researchers used a transposon-mediated gene-activation screen to search for new genes that can prevent infection by Ebola virus. This new screening strategy--that serves as a blueprint for uncovering resistance mechanism against other dangerous pathogens-- found that the gene MHC class II transactivator (CIITA) induces resistance in human cell lines by activating the expression of a second gene, CD74.
One form of CD74, known as p41, disrupts the processing of proteins on the coat of the Ebola virus protein by cellular proteases called Cathepsins. This prevents entry of the virus into the cell and infection. CD74 p41 also blocked the Cathepsin-dependent entry pathway of coronaviruses, including SARS-CoV-2.
Uncovering these new cellular protection pathways is incredibly important for understanding how we disrupt or change the virus infection cycle to elicit better protection against viruses like Ebola or SARS-CoV-2. And our new strategy helps us find mechanisms that have eluded conventional genetic screens."
Adam Lacy-Hulbert, PhD., Study Lead Author and Principal Investigator, Benaroya Research Institute
The findings illustrate a new role for genes previously thought to be involved in more conventional T cell and B cell mediated immune responses. For example, CIITA was understood as important for communication between immune cells, but it had not previously been seen as a way for cells to defend themselves against viruses.
"As a virologist, I am excited not just about what this means for Ebola virus, but about the broader implications for other viruses," said Anna Bruchez, Ph.D., Instructor in Pathology, Case Western Reserve University and co-author on the study.
"Many viruses, including coronaviruses, use cathepsin proteases to help them infect cells. Fortunately, when SARS-CoV-2 emerged, I had recently moved to Case Western, and was able to use their specialized BSL3 laboratories to show the CD74 pathway also blocked endosomal entry by this virus. Thus, this anti-viral mechanism has evolved to work against many different viruses."
"We really don't understand the cellular mechanisms that block viral infections which has limited our ability to effectively respond to pandemics, including this year's coronavirus," said Lynda M. Stuart, M.D., Ph.D., Deputy Director, Bill & Melinda Gates Foundation, BRI Affiliate Investigator and co-author on the study.
"We really need therapies that can block all viruses, including unknown future pathogens. To do that we need to find common pathways that viruses target and then develop approaches to block those vulnerabilities."
"Our work demonstrates one way in which cells can be modified to do this, and we hope that our insights will open up new avenues for scientists developing therapies and interventions to treat viral infectious diseases that impact millions of lives around the world."
Bruchez, A., et al. (2020) MHC class II transactivator CIITA induces cell resistance to Ebola virus and SARS-like coronaviruses. Science. doi.org/10.1126/science.abb3753