Best News Network

Early developmental gene can cause deadly aneurysms

Mutations of a gene that regulates formation of blood vessels in the brain of vertebrates can lead to potentially deadly aneurysms in adults, Yale School of Medicine researchers report in the December issue of Nature Medicine.

Saccular brain aneurysms affect nearly 3% of the human population. If they rupture, it can cause subarachnoid hemorrhage, the deadliest type of intracranial hemorrhage. Approximately 500,000 hemorrhagic strokes are reported annually worldwide; nearly one in four victims die before reaching the hospital.

Predicting who might be vulnerable to such inherited forms of intracranial aneurysms, however, has been notoriously difficult. And until now, researchers have had difficulty identifying the genes that might trigger an increased risk of aneurysms in adults.

In the new study, researchers from the Yale’s departments of neurosurgery, genetics, and cardiovascular medicine identified the role of a gene, named PPIL4, in intracranial aneurysms. The gene is known to play a crucial role in creating blood vessels in the developing vertebrate brain.

For the study, the group analyzed the genomes of more than 300 patients with intracranial aneurysms and found significant increase of PPIL4 mutations compared with the general population.

The Yale team was led by three co-corresponding authors: Murat Gunel, the Nixdorf German Professor and chair of the Department of Neurosurgery; Stefania Nicoli, an associate professor of internal medicine and genetics and co-director of the Yale Cardiovascular Research Center in Cardiology; and Ketu Mishra-Gorur, a research scientist.

“Identifying inherited forms of intracranial aneurysms that have large effect sizes have been difficult to identify,” Gunel said. “We are very excited to report such mutations in the PPIL4 gene, providing a unique insight on how these deadly lesions form.”

Unruptured aneursyms cause no symptoms and are hard to detect in normal clinical exams, which makes it difficult to identify individuals who could benefit from early treatment.

“The disease has never been associated with a developmental defect and this gene is like a time machine that allows us to look back and find the origins of the aneurysms,” said Nicoli. “It is only one piece of the puzzle, but one that dramatically changes how we look at the disease.”

In addition to the genetic discovery of PPIL4, the group demonstrated that a novel PPIL4-Wnt signaling pathway is essential for brain vessel development and integrity.

“Studies like ours not only provide a genetic and mechanistic window into disease pathogenesis but present a remarkable potential for new pathways in IA screening, early diagnosis, and treatment,” Mishra-Gorur said.

Tanyeri Barak, an associate research scientist in neurosurgery in Gunel’s lab, and Emma Ristori, a postdoctoral fellow at the Yale Cardiovascular Research Center in Cardiology, are co-first authors. Other Yale authors include Gulhan Adife Ercan-Sencicek and Andrew Prendergast.

Story Source:

Materials provided by Yale University. Original written by Bill Hathaway. Note: Content may be edited for style and length.

Stay connected with us on social media platform for instant update click here to join our  Twitter, & Facebook

We are now on Telegram. Click here to join our channel (@TechiUpdate) and stay updated with the latest Technology headlines.

For all the latest Health News Click Here 

 For the latest news and updates, follow us on Google News

Read original article here

Denial of responsibility! NewsAzi is an automatic aggregator around the global media. All the content are available free on Internet. We have just arranged it in one platform for educational purpose only. In each content, the hyperlink to the primary source is specified. All trademarks belong to their rightful owners, all materials to their authors. If you are the owner of the content and do not want us to publish your materials on our website, please contact us by email – [email protected]. The content will be deleted within 24 hours.