Stroke is a major cause of death and serious long-term disability in the world. The Centers for Disease Control and Prevention (CDC) estimates that annually more than 795,000 United States residents have a stroke.
One particular protein is the final executioner of events that result in the death of brain cells during stroke, revealed researchers from UT Southwestern Medical Center and their collaborators. This finding could ultimately lead to new ways to protect against brain damage.
‘The protein, macrophage migration inhibitory factor (MIF), breaks the cell's DNA, resulting in brain cell death.’
AdvertisementResearchers discovered that the protein, macrophage migration inhibitory factor (MIF), breaks the cell's DNA, resulting in brain cell death.
The Department of Neurology and Neurotherapeutics is part of UT Southwestern's Peter O'Donnell Jr. Brain Institute, a comprehensive initiative dedicated to better understanding the basic molecular workings of the brain and applying these discoveries to the prevention and treatment of brain diseases and injuries.
The study, which appears online in Science, outlines three possible ways to manipulate MIF to protect brain tissue during a stroke - and possibly in other brain-damaging conditions such as Alzheimer's, Parkinson's, and Huntington's diseases, although this study examined only stroke.
Lead author Dr. Yingfei Wang, Assistant Professor of Pathology and of Neurology and Neurotherapeutics at UT Southwestern, screened thousands of human proteins to find 160 that could be the culprits behind stroke-induced cell death. Eventually, the researchers were able to narrow the field to just one - MIF, a protein long known for its roles in immunity and inflammation.
"The MIF protein was identified in the 1960s, but the function we found related to DNA damage in the cell's nucleus after stroke is brand new," Dr. Wang said.
The MIF finding is the final piece in a puzzle that collaborating researchers at Johns Hopkins University have been carefully assembling for years to reveal the process by which brain cells die. This work was started in the labs of research partners Dr. Ted Dawson, Director of the Institute for Cell Engineering at the Johns Hopkins University School of Medicine, and Dr. Valina Dawson, Professor of Neurology at Johns Hopkins, where Dr. Wang began her work as a postdoctoral researcher and continued it as a collaboration between UT Southwestern and Johns Hopkins.
Despite their very different causes and symptoms, brain injury, stroke, and Alzheimer's, Parkinson's, and Huntington's diseases have a shared mechanism involving a distinct form of "programmed" brain cell death called parthanatos, researchers said. The name comes from the personification of death in Greek mythology, and PARP, an enzyme involved in the cell death process.
"I can't overemphasize what an important form of cell death it is; it plays a role in almost all forms of cellular injury," said Dr. Dawson, whose research group has spent years delineating each of the links in the parthanatos chain of events and the roles of the proteins involved.
The researchers are working to identify chemical compounds that could block MIF's actions and possibly protect brain cells from damage.