The ubiquitous human herpesvirus 6 may play a critical role in impeding the brain’s ability to repair itself in diseases like multiple sclerosis.
The findings, which appear in the journal Scientific Reports, may help explain the differences in severity in symptoms that many people with the disease experience.
“While latent HHV-6—which can be found in cells throughout the brain—has been associated with demyelinating disorders like multiple sclerosis it has not been clear what role, if any, it plays in these diseases,” says coauthor Margot Mayer-Proschel, an associate professor at the University of Rochester Medical Center department of biomedical genetics.
“These findings show that, while in the process of hiding from the immune system, the virus produces a protein that has the potential to impair the normal ability of cells in the brain to repair damaged myelin.”
It is estimated that more than 80 percent of people have been exposed to HHV-6 at some point during their early childhood. HHV-6 is the most common human herpesvirus and infections that occur during childhood often go unnoticed but the virus can cause roseola, which is characterized by a fever and rash in infants. A much smaller number—one percent of people—have congenital HHV-6, where a single copy of the virus is acquired through either the father’s sperm or mother’s egg and is passed on to the developing child.
While the immune system fights off the most active forms of the infection, the virus never truly leaves our bodies and can reactivate later in life. The herpesvirus 6 accomplishes this form of latency by integrating itself into our genetic code and thus hiding in cells and evading the immune system.
One of the first studies to show an association between latent HHV-6 infection and demyelinating disorders took place in 2003. The researchers noted that HHV-6 genetic code could be found in the brain cells of individuals with severe forms of multiple sclerosis.
Viruses have long been suspected to contribute to multiple sclerosis, a disorder in which the body’s own immune system attacks and destroys myelin—the fatty tissue that insulates the connections between nerve cells. However, while the 2003 study indicated that the herpes virus played some role in multiple sclerosis, it has subsequently become clear that the virus is unlikely to trigger the disease.
The researchers in the current paper took a new approach and asked instead whether the virus could have an impact on a critical support cell found in the brain called oligodendrocyte progenitor cells (OPCs). These cells play an important role in maintaining the brain’s supply of myelin. When myelin is lost to disease, age, or injury, OPCs are activated, migrate to where they are needed, and mature into myelin-producing cells which repair the damage.
The researchers examined the impact of the latent HHV-6 on the activity of human OPCs, which was possible through the work of Chris Proschel, a coauthor of the paper with expertise in the generation of human OPCs. One of the ways the virus stays hidden in cells is by expressing a protein called U94 that helps it keep its place in the human DNA and remain undetected from the immune system. By studying human cells and transplanting human OPCs into animal models, the team discovered that when U94 was expressed in OPCs, the cells stopped migrating to where they were needed.
What is still not fully understood is the relationship between the extent of the viral infection in the brain and the severity of diseases like multiple sclerosis and other demyelinating diseases such as leukodystrophies and Vanishing White Matter disease. For example, do the number of infected cells need to reach a certain threshold before OPC function is impeded? Are individuals who have congenital HHV-6 more vulnerable to severe forms of these diseases?
“More research is needed to understand by which mechanisms the virus impedes the function of OPCs and what impact this has on the progression of these diseases,” says Mayer-Proschel. “But it is clear that HHV-6, while not necessarily the cause of demyelinating diseases, is limiting the ability of the brain to repair damage to myelin thereby potentially accelerating the progression of these diseases.”
Additional coauthors are from URMC and Harvard Medical School. Funding came from the National Multiple Sclerosis Society, the New York State Department of Health, and the Link Foundation.
Source: University of Rochester