News Release

UNC scientists identify sticky protein in sickle cell red blood cells

Peer-Reviewed Publication

University of North Carolina Health Care

CHAPEL HILL -- New research from the University of North Carolina at Chapel Hill reveals why red blood cells from people with sickle cell disease are stickier than healthy red cells, pointing the way to potential new treatments for sickle cell disease. The study shows that a protein found on the surface of immature red blood cells, or reticulocytes, is responsible for those cells' adhesion to blood vessel walls.

Reticulocytes are found at considerably higher levels in the blood of sickle cell patients than healthy patients, and so the likelihood of sticky patches or blockages forming on a blood vessel wall is greatly increased. The blockages lead to problems including strokes, pneumonia, recurring infections and painful episodes known as crises that often require hospitalization.

The new findings appear in the Oct. 8 issue of the Journal of Biological Chemistry.

The work of Dr. Julia Brittain provides new clues to better controlling stickiness of sickle red blood cells, said Dr. Leslie Parise, professor and vice chair of pharmacology at UNC's School of Medicine. Brittain is a postdoctoral fellow in Parise's laboratory.

"It was previously thought that sickle red blood cells lodged in blood vessels because they're sickle-shaped, more rigid and just became physically stuck," said Brittain, the study's co-author. "But while the physical lodging is a component, an equally important component is that sickle red blood cells are simply stickier."

Brittain and her co-authors showed that the cell-surface protein Alpha-4Beta-1 is activated by another cell-surface protein, CD47, and that Alpha-4Beta-1 was responsible for sickle red blood cell adhesion to a blood vessel wall protein called thrombospondin.

CD47 binds to and is activated by soluble, blood-borne thrombospondin, which is found elevated in sickle cell patients and which initiates an atypical signaling cascade inside the red blood cells. This aberrant signaling ultimately culminates in the activation of Alpha-4Beta-1 and an increase in red blood cells sticking to the blood vessel wall, said Brittain.

"Even though sickle cell patients are particularly vulnerable to blocked blood vessels, the signaling mechanisms identified in sickle reticulocytes seem to be present in reticulocytes found in other anemic patients as well," said Brittain. "Our current thinking is that these results may benefit patients suffering from a number of anemias and not just sickle cell disease" The UNC study also identified where Alpha-4Beta-1 binds to thrombospondin.

"This knowledge opens the door to possible therapies. Inhibitors of the class of proteins to which Alpha-4Beta-1 belongs, the integrins, are being tested for use in diseases such as Crohn's disease, and these inhibitors are now attractive and rational therapies for sickle cell disease," said Parise.

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Along with Brittain and Parise, co-authors are Dr. Kenneth I. Ataga, research instructor in the department of medicine, and Dr. Eugene P. Orringer, professor of medicine and executive associate dean for faculty affairs in the School of Medicine.

Dr. Jaewon Han, an investigator from the Scripps Research Institute, collaborated with the UNC researchers on this study.

Funding was provided by National Institutes of Health grants and performed in collaboration with the Duke-UNC Comprehensive Sickle Cell Center.

Note: Contact Parise at 919-966-2238 or parise@med.unc.edu.
Contact Brittain at 919-962-1058 or julia_brittain@med.unc.edu.

School of Medicine contact: Les Lang, 919-843-9687 or llang@med.unc.edu.


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