Chickenpox and shingles virus lying dormant in your neurons can reactivate and increase your risk of stroke

New research identified a potential reason why.
Sign up for the Freethink Weekly newsletter!
A collection of our favorite stories straight to your inbox

Over 90% of the world population has the virus that causes chickenpox lying dormant in their nervous system. Most people contract the varicella zoster virus, or VZV, when they get chickenpox as children. For around a third of these people, this same virus will reactivate years later and cause shingles, also called herpes zoster.

While most people are familiar with the painful rash that VZV causes for shingles, a wide spectrum of other complications can also occur even without visible skin symptoms. Among the most severe is stroke, in particular ischemic stroke, which occurs when the blood supply to the brain is restricted by narrowing arteries or blocked by a clot. 

People with shingles have an approximately 80% higher risk of stroke than those without the disease, and this risk stays elevated for up to a year after the rash has resolved. Stroke risk is nearly doubled for those with the rash on their face, and tripled for those under the age of 40.

The mechanism behind this long-term stroke risk is mostly unknown. Some researchers have proposed that direct infection of the arteries may be the cause. However, some features of VZV infections suggest that this is not the full picture. A common theme of VZV infections is chronic inflammation that spreads beyond the original infection site, which can persist for weeks to months after the virus is no longer detectable and presumably dormant again.

I am a neurovirologist, and my lab studies how VZV contributes to neurological disorders such as stroke and dementia. In our recently published research, we found that VZV reactivation triggers the formation of cellular sacs, or exosomes, carrying proteins that contribute to blood clotting and inflammation. An increase in these proteins may lead to an increased risk in stroke.

Exosomes carry blood clotting proteins

Exosomes are small vesicles, or fluid-filled sacs, made inside cells throughout the body. They’re like duffle bags that carry cargo, such as proteins and nucleic acids, from the cell to distant tissues. Although critical for essential biological functions like communication between cells, exosomes can also play a key role in disease progression and are drug targets for many diseases.

We wanted to see whether shingles patients develop exosomes that carry proteins involved in blood clotting, increasing their risk of stroke. So we isolated exosomes from the blood of 13 patients at time of shingles rash and compared them to exosomes isolated from healthy donors. 

When we analyzed the contents of these exosomes, we found that shingles patients had nine times higher levels of clotting proteins than healthy patients. Moreover, we found the exosomes of shingles patients still had elevated levels of these proteins three months after their initial rash.

To functionally confirm that the contents of these exosomes can induce clotting, we exposed platelets – cell fragments involved in blood clotting – of healthy people to exosomes from either shingles patients or healthy people. We found that exposing platelets to shingles exosomes triggered them to clump together and form aggregates with other types of blood cells, as they would in forming a blood clot.

These findings suggest that exosomes may be a potential mechanism for how the varicella zoster virus increases stroke risk for shingles patients.

Exosomes (marked by the white arrow) can carry a variety of molecules out of a cell. IBM Research/FlickrCC BY-ND

Considering stroke with shingles

A Food and Drug Administration-approved vaccine to prevent shingles, Shingrix, is available for adults age 50 and older and immunocompromised adults age 18 and older. However, those at highest risk of stroke are under the age of 40 and are ineligible for Shingrix. A large group of these individuals were likely not vaccinated for chickenpox as children, as the chickenpox vaccine was only approved in the U.S. in 1995 and uptake by adults was quite low at the time. While vaccination with the chickenpox vaccine significantly reduces the risk of shingles, it is still possible for a latent infection to reactivate and cause the disease.

While our study provides evidence for a potential way that shingles can cause an increased risk of stroke during and soon after infection, further research on how long this risk persists is needed. We are conducting follow-up studies to evaluate how long patients may have an increased tendency to form blood clots after their shingles infection has resolved. These longitudinal studies will also examine whether exosomes can be used as a biomarker to monitor stroke risk after shingles.

Meanwhile, we hope that our findings may provide a potential target for treatment development, and encourage people to get vaccinated for shingles.

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Sign up for the Freethink Weekly newsletter!
A collection of our favorite stories straight to your inbox
Related
How cryopreservation could end death as we know it
The technology could one day allow people with terminal illnesses to go into “hibernation” until a cure is found.
Has the US reached “peak obesity”?
A CDC survey suggests America’s obesity rate may be falling. Is this a turning point in the obesity epidemic? Or just a temporary plateau?
The exciting research that may cure Parkinson’s 
GeneCode is developing a drug it hopes won’t just alleviate Parkinson’s symptoms but also protect and restore patient’s neural health.
How smart devices helped me unlock hidden health wins
By measuring many different body metrics, smart health devices can help support the mental game as much as the physical fitness gains.
Ray Kurzweil explains how AI makes radical life extension possible
Life expectancy gains in developed countries have slowed in recent decades, but AI may be poised to transform medicine as we know it.
Up Next
partial reprogramming
Subscribe to Freethink for more great stories