2 min readScientists Discover How Hepatitis C ‘Ghosts’ Our Immune System
Dublin, Ireland — Scientists from Trinity College Dublin have discovered how the highly infectious and sometimes deadly Hepatitis C virus (HCV) “ghosts” our immune system and remains undiagnosed in many people. They report their findings today [Wednesday June 5th] in the international FASEB journal.
HCV’s main route of transmission is via infected blood but over the past 40 years it has accidentally been given to many patients across the world via infected blood products. The virus replicates particularly well in the liver, and the damage it causes makes it a leading cause of liver disease worldwide.
Even though HCV can be deadly, initial infection is rarely accompanied by any obvious clinical symptoms for reasons that have – until now – remained unknown. As a result, it often goes undiagnosed for the first 6-12 months following infection.
If left untreated HCV spreads throughout the liver, stimulating a low-level inflammatory response. Over several months, these mild responses – accompanied by subsequent liver repair – result in fibrotic scarring of the liver. The liver’s main job is to filter out toxins, but during HCV infection the build-up of fibrotic, non-functioning liver tissue, results in reduced liver function. Without a fully functioning liver, one major side-effect is the build-up of toxins, often referred to as “jaundice”. If patients do not realise they are infected with HCV, their first noticeable symptoms are the side-effects of liver fibrosis (such as jaundice).
While the majority of HCV infections are now treatable with new medicines, early detection would avoid the damaging progression to liver disease. Therefore, a group of scientists led by Assistant Professor in Immunology at Trinity, Nigel Stevenson, set out to understand how the virus avoids being discovered for months after infection.
HCV suppresses the immune response
Under normal circumstances, our cells communicate with each other with molecules called cytokines, which work by activating specific cascades of other molecules within our cells called signalling pathways. These cytokines and their signalling pathways trigger the expression of hundreds of molecules within our cells to increase inflammation and anti-viral activity. This immune response is capable of killing and clearing viral infections from our cells and bodies.
Uncontrolled inflammation would be dangerous, however, so to ensure our immune response to infection is appropriately regulated, several cytokine signalling pathways are controlled by immune regulators called “Suppressor Of Cytokine Signalling (SOCS)” regulators. After a period of time following an initial response, pro-inflammatory cytokine signalling pathways are shut down by SOCS.
The Trinity scientists found that HCV “ghosts” our immune response, by triggering our own SOCS regulators; a specific part of the virus is responsible for increasing a specific SOCS molecule – in both liver and immune cells.
Dr. Stevenson said: “We’ve discovered that HCV hijacks this regulatory process by causing the expression of SOCS in our cells. By increasing the expression of SOCS, HCV basically dulls the normal immune response to viral infection. Without a strong signal our body’s cells cannot then mount an effective inflammatory and anti-viral response that clears infection.”
“This ability shields HCV from our body’s normal, effective anti-viral immune response and creates a perfect environment in which to survive, replicate and infect other cells. Many diseases are mediated by increasing the inflammatory response to an inappropriately high level, but in this case it is the lack of adequate inflammation that enables HCV to go undiagnosed, leaving it free to rapidly replicate and infect other cells.”
Article adapted from a Trinity College Dublin news release.
Publication: The hepatitis C virus (HCV) protein, p7, suppresses inflammatory responses to tumor necrosis factor (TNF)-α via signal transducer and activator of transcription (STAT)3 and extracellular signal-regulated kinase (ERK)–mediated induction of suppressor of cytokine signaling (SOCS)3. Orla Convery et al. FASEB Journal (2019): Click here to view.