Cleft
Lip and Palate Research…is there a TMJ connection???
TMJ is
a complex disorder involving many overlapping and related disorders. Therefore research on such a disorder as
Cleft Palate may unlock some of the mysteries of TMJ as well. The following article involves genetic
research which is becoming more common among TMJ researchers as well.
NIH News
National
and Craniofacial Research
(NIDCR)
http://www.nidcr.nih.gov/
RESEARCHERS REPORT NEW GENE
TEST FOR ISOLATED CLEFT LIP AND
PALATE
Researchers report they now can predict whether some parents
are more likely than others to have a second child with the “isolated” form of
cleft lip and palate, one of the world’s most common birth defects, according
to results of a study published this week in the “New England Journal of
Medicine”. The research was supported in part by the National Institute of
Dental and Craniofacial Research and the National Institute of Environmental
Health Sciences, part of the National Institutes of Health.
The authors say their latest gene test applies to about 12
percent of isolated cleft lip and palate, or babies born with clefts only and
no other birth defects. Last year, the authors and their colleagues reported
that mutations in another gene account for about 2 percent of all cases of
isolated clefts, meaning researchers in the field now can collectively screen
for about 15 percent of isolated cleft lip and palate, an
impossibility just a few years ago.
Isolated clefts account for 70 percent of all cleft lip and palate.
In the latest paper, the scientists report a so-called “haplotype” gene test, one of the first of its kind in
medicine. A haplotype is the sum of several recurring
variations in the usual DNA sequence of a species that are spaced out, like
signposts, along a gene or chromosome. In this case, they found that distinct
combinations of sequence variations in and around the gene IRF6 correlated with
an increased chance that a child would be born with a cleft. IRF6, which
encodes a gene-activating protein called a transcription factor, plays a role
during development in orchestrating the normal formation of the lips, palate,
skin, and genitalia.
“This study shows that we’ve reached a point where it’s
possible to take blood samples from parents, test certain genes, and determine
whether their risk for a second child with cleft lip or palate is, say, 1 or 20
percent,” said Jeffrey Murray, M. D., a scientist at the
According to
The challenge has been how to move the field forward. Isolated clefts arise during fetal
development from a dynamic and still poorly understood interplay of genes,
diet, and environmental factors, and current research
tools cannot adequately cut through the complexity.
One productive inroad has been to isolate genes linked to “syndromic” cleft lip and palate, hoping some might also
play a role in causing the isolated condition. Syndromic
cleft lip and palate refers to babies born with clefts that are accompanied
with other birth defects. There are over 150 of these syndromes, and,
collectively, they account for about 30 percent of all cleft lip and palate.
Two years ago, Murray and colleagues Brian Schutte and Shinji Kondo hit the jackpot when they found
the IRF6 gene plays a role in causing Van der Woude syndrome (VWS), the most common of the syndromic conditions. The discovery marked a potentially
important lead because, about 15 percent of people with VWS have malformations
that are clinically indistinguishable from isolated cleft lip and palate,
suggesting the gene might be involved in both types of clefting.
While studying the structure of IRF6, the group noticed a
sequence variation that they thought might play a role in causing isolated
clefts. Such variations, called single nucleotide polymorphisms, or SNPs, occur about every 1,000 bases in our DNA and are
generally considered to be harmless.
What interested them about this specific SNP is it caused an
amino acid change, substituting an isoleucine for the
normal valine, precisely where the IRF6 protein attaches
to other substrates. They reasoned the isoleucine
insertion might somehow hamstring the protein’s normal biological activities
during tissue and organ development. Fueling their suspicions was the fact that
the normal valine is tightly conserved from fish to
humans, meaning if the valine was trivial, species
along the evolutionary ladder might have altered it with greater frequency.
“The change wasn’t going to cause the condition by itself,
because we already had found it in lots of people who didn’t have clefts,” said
Theresa Zucchero, a member of
To test their hypothesis, Zucchero
and colleagues turned to their collaborators in
The researchers found that the isoleucine
variation was indeed present at a low but measurable level in all of the
populations. This allowed the group to ask the next question: Was their
original hypothesis correct?
To their complete surprise, the answer was no. “What we
found is that the valine was over transmitted in
those with clefts,” said
“What we strongly believe is happening is the valine serves as a marker for some other mutation nearby
within the gene that’s really doing the deed,” he continued. “In a sense, the valine is hitchhiking with the actual mutation.”
At this point, the researchers stepped back and looked more
broadly at the gene and flanking regions of the chromosome. They identified a total of 36 SNPs, both inside and outside the gene, and nine of these
variations seemed to be associated with clefting.
“These individual variations, or SNPs can be
assembled into a haplotype,” said Mary Marazita, Ph.D., a statistician at the
Based on a detailed analysis of 1,316 families, the
scientists estimated that the risk of parents with this haplotype
having a second child with isolated cleft lip and palate is about 12 percent.
As the researchers noted, their estimate is based on their analysis of the
families and cannot be generalized to the broader public.
“For a complex trait like cleft lip and palate, this is a
nice step forward because there may be dozens of genes that contribute to the
condition,” said