Experts show genetic basis of facial changes in Down Syndrome

Described in a paper published today in Development, the researchers found that having a third copy of the gene Dyrk1a and at least three other genes were responsible for these changes taking place in development – called craniofacial dysmorphology – which involve shortened back-to-front length and widened diameter of the head.

Affecting 1 in 800 live births, Down Syndrome is known as a ‘gene dosage disorder’ – meaning that it involves changes in the number of copies of a gene. People with Down Syndrome have three copies of chromosome 21 instead of two. Having three copies of certain genes on this chromosome causes aspects typical of Down Syndrome, but it’s not yet known which genes are responsible.

Using genetic engineering, teams led by Victor Tybulewicz of the Francis Crick Institute and Elizabeth Fisher of University College London created mouse strains with duplications of three regions on mouse chromosome 16, which mimics having a third chromosome 21. The mice show lots of traits associated with Down Syndrome, including changes in the shape of the face and skull.

Previous research has linked a gene called Dyrk1a to aspects of Down Syndrome, so the researchers wanted to test how it impacted craniofacial dysmorphology.

Now working with Professor Jeremy Green’s group at King’s College London, they showed that mice with an extra copy of Dyrk1a had a reduced number of cells in the bones at the front of the skull and in the face. Also, cartilaginous joints at the base of the skull called synchondroses were abnormally fused together. These effects were partly reversed when the third copy of Dyrk1a was removed, showing that three copies of Dyrk1a are necessary to cause these changes in the skull.

The researchers believe that having a third copy of Dyrk1a hinders the growth of neural crest cells that are needed to form the bones at the front of the skull.

In addition to Dyrk1a, the research showed that three other genes also contribute to the changes in the skull, but more research is needed to confirm their identity.

Victor Tybulewicz, Group Leader of the Down Syndrome Laboratory at the Crick, who worked with first author Yushi Redhead, said: “There’s currently limited treatments for the aspects of Down Syndrome which have a negative impact on people’s health, like congenital heart conditions and cognitive impairment, so it’s essential we work out which genes are important.

“Understanding the genetics involved in the development of the head and face gives us clues to other aspects of Down Syndrome like heart conditions. Because Dyrk1a is so key for craniofacial dysmorphology, it’s highly likely that it’s involved in other changes in Down Syndrome too.”

Researchers at King’s College London used shape-measuring tools to map the changing skull shape of the mice. These showed changes in skull shape that were remarkably similar to those seen in people with Down Syndrome.

Jeremy Green, Professor of Developmental Biology at King’s College London, said: “With the help of great collaborators at the University of Calgary in Canada and a medical imaging software group here at King’s, we were able to apply both quite traditional and some very novel methods for comparing complex anatomical shapes. These were sensitive enough to pick up differences even at foetal stages. This helped us pin down not only the locations of genes that cause Down Syndrome but also get clues as to how those genes cause the differences that they do.”

This research forms part of an ongoing project to understand the genetics of Down Syndrome. The researchers will next aim to identify the genes involved in heart defects and in cognitive impairment, bringing us a step closer to understanding how to develop targeted treatments for aspects of Down Syndrome which impact health.