New study identifies two proteins that may contribute to stroke recurrence

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Contact:

Jillian McKoy ,jpmckoy@bu.edu

Michael Saunders, msaunder@bu.edu

Jarka Meleszkiewicz, jarka.meleszkiewicz@bristol.ac.uk

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New Study Identifies Two Proteins That May Contribute to Stroke Recurrence

The study discovered genetic markers in inflammation that may be related to a second stroke or other major cardiovascular event following a stroke. These findings could help identify drug targets to mitigate stroke-related disability and mortality.

People who experience an arterial ischemic stroke (AIS) or transient ischemic stroke (TIA) are at an increased risk of suffering a second stroke or other major adverse cardiovascular event (MACE), making it critically important to identify risk factors and treatments to prevent these subsequent occurrences. 

A new study led by Boston University School of Public Health (BUSPH), the National Institute for Health and Care Research (NIHR) Bristol Biomedical Research Centre (Bristol BRC), and Veteran’s Affairs Boston Healthcare System (VA Boston), has identified new genetic and molecular risk factors that may reveal new pathways for treating patients after they experience their first stroke.

Published in Stroke, a journal of the American Heart Association, the study identified CCL27 and TNFRSF14, two proteins that are associated with subsequent MACE, but not initial strokes. These proteins are known to activate inflammation, which plays a key role in the development of strokes and many chronic conditions and diseases. The findings suggest that inflammation is a contributing factor to MACE outcomes among people after they have their first stroke.

“While previous studies have found associations between inflammation and incident AIS/MACE, our study found that these causal proteins may also have a role in subsequent MACE, which could lead to potential novel drug targets,” says study co-lead author Nimish Adhikari, a PhD student in biostatistics at BUSPH and VA Boston. The study was also co-led by Andrew Elmore, senior research associate in health data science at NIHR Bristol BRC. 

Utilizing genetic information and medical history data from two large biobanks, the VA’s Million Veteran Program and UK Biobank, the research team conducted ancestry-specific genome-wide association studies (GWAS) to find associations between DNA and incident and subsequent AIS and MACE. 

GWAS are typically performed to determine whether individuals have had a medical event for the first time, but applying this method to subsequent MACE events could shed novel insights about stroke progression, information that would be valuable for therapeutic drug identification, the researchers say. 

In total, the researchers examined 93,422 individuals who had an incident stroke, among which 51,929 had subsequent MACE and 45,120 had subsequent AIS. 

In population specific analyses, they observed two significant genetic variants: rs76472767, near gene RNF220 on chromosome 1 in the African ancestry GWAS for subsequent MACE, and rs13294166, near gene LINC01492 on chromosome 9 in the same ancestry GWAS for subsequent AIS.

“We used that data to find if there were certain molecules that were associated with either incident or subsequent states,” says Elmore. “From that, we were able to identify a link between certain molecules that play a part in inflammation and these stroke and MACE outcomes.” 

While the prevalence of stroke has declined worldwide over the last three decades, it is still the second-leading cause of death and third-leading cause of disability across the globe, and it remains a significant public health issue. Stroke also continues to disproportionately affect populations among racial, ethnic, socioeconomic, and geographical lines, furthering health inequities in both high- and low-income countries. Identifying novel drug targets for new therapeutic interventions that thwart stroke progression could save millions of people from experiencing stroke-related disability and mortality.

It’s unknown if targeting other modifiable risk factors for stroke could also offer pathways for effective treatment after someone experiences their first stroke.

“We are looking forward to extending this research to other cardiometabolic outcomes beyond stroke,” says co-senior and corresponding author Gina Peloso, associate professor of biostatistics at BUSPH.

Lavinia Paternoster, associate professor in genetic epidemiology at NIHR Bristol BRC and Bristol Medical School, and Kelly Cho, director of data science and analytics at the division of population health and data science, VA Boston Healthcare System and associate professor of medicine at Mass General Brigham, Harvard Medical School, are also co-senior authors.

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About Boston University School of Public Health

Founded in 1976, Boston University School of Public Health is one of the top ten ranked schools of public health in the world. It offers master's- and doctoral-level education in public health. The faculty in six departments conduct policy-changing public health research around the world, with the mission of improving the health of populations—especially the disadvantaged, underserved, and vulnerable—locally and globally.

About the National Institute for Health and Care Research

The mission of the National Institute for Health and Care Research (NIHR) is to improve the health and wealth of the nation through research. We do this by:

• Funding high quality, timely research that benefits the NHS, public health and social care;
• Investing in world-class expertise, facilities and a skilled delivery workforce to translate discoveries into improved treatments and services;
• Partnering with patients, service users, carers and communities, improving the relevance, quality and impact of our research;
• Attracting, training and supporting the best researchers to tackle complex health and social care challenges;
• Collaborating with other public funders, charities and industry to help shape a cohesive and globally competitive research system;
• Funding applied global health research and training to meet the needs of the poorest people in low and middle income countries.

NIHR is funded by the Department of Health and Social Care. Its work in low and middle income countries is principally funded through UK Aid from the UK government.

About NIHR Bristol Biomedical Research Centre

NIHR Bristol Biomedical Research Centre’s (BRC) innovative biomedical research takes science from the laboratory bench or computer and develops it into new drugs, treatments or health advice. Its world-leading scientists work on many aspects of health, from the role played by individual genes and proteins to analyzing large collections of data on hundreds of thousands of people. Bristol BRC is unique among the NIHR’s 20 BRCs across England, thanks to its expertise in ground-breaking population health research.

About the Division of Population Health and Data Science, VA Boston Healthcare System

VA Boston Healthcare System conducts research to discover knowledge, develop VA scientists and health care leaders, and create innovations that advance health care for Veterans and the nation. The Division of Population Health and Data Science at the Massachusetts Veterans Epidemiology Research and Information Collaborative, VA Boston serves as a national resource to foster population health research in the VA. It consists of multiple national centers and programs funded by the VA Office of Research and Development including the Boston Cooperative Studies Program Epidemiology Center, the Million Veteran Program Coordinating Center and Centralized Interactive Phenomics Resource (CIPHER) Program.