The findings are based on detailed studies of five people missing a
small fragment of their genome and suffering from a mysterious syndrome
of craniofacial features, visual anomalies and developmental delays. When those patient observations were coupled to analyses of the
anatomical defects in genetically altered zebrafish embryos, the
researchers were able to identify the contribution specific genes made
to the pathology, demonstrating a powerful tool that can now be applied
to unraveling many other complex and rare human genetic conditions. The findings are broadly important for human genetic disorders because
copy-number variants (CNVs) -- fragments of the genome that are either
missing or existing in extra copies -- are quite common in the genome.
But their precise contribution to diseases has been difficult to
determine because CNVs can affect the function of many genes
simultaneously. "Because a CNV can perturb many genes, it is difficult to know which of
them is responsible," said Nicholas Katsanis, a professor of cell
biology who directs the Center for Human Disease Modeling and the Task
Force for Neonatal Genomics at Duke University. Last year, Katsanis and his colleagues found that they could trace
recurrent copy-number variants and dissect the consequences of each
perturbed gene to particular features in patients. The new study goes
one step further by showing that they can also do this in more
challenging cases, when CNVs differ in size from one individual to the
next. In this case, "each person has his or her own private deletion or
duplication," he said, with the potential to affect a different number
of genes. The researchers showed that partially overlapping microdeletions found
in the human patients include a region that contains three genes. By
manipulating those genes in zebrafish, first one at a time and then in
combination, they were able to connect the genes to specific features of
the human syndrome. One of the study's first authors, post-doctoral
researcher Christelle Golzio, recalled what it was like to see the
characteristics of those human patients reflected in their laboratory
fish for the first time. "The zebrafish had coloboma," she said, referring to holes in the iris
or other parts of of the eye seen in these patients. "It was clear cut."
Similar to the patients with the deletions, the zebrafish embryos also
had kidney defects, small heads and defects in the development of the
skeleton of the face. "This is a faster, cheaper, more efficient method to study and decipher
copy-number variants, and the zebrafish model looks pretty robust in
terms of recapitulating what the physicians observe in people," Golzio
said. The findings also show just how complicated the consequences of
copy-number variants can be. In some instances, the abnormalities seen
in both patients and the fish were tied to copy number changes to
individual genes, as that gene's "dosage" varied. At the same time,
other characteristics were only observed when those genetic aberrations
were combined, a pattern that would be nearly impossible to see in
studies of humans themselves. In principle, the researchers say they can now examine the role of
copy-number variants in any human syndrome, so long as the condition is
associated with features that are measurable in the fish. "We will need to study lots of CNVs to find the edges of our
capabilities," Katsanis said. "As we add this layer of dissection and
interpretation, we will have prediction, diagnosis and the beginnings of
biological understanding."
Source:Duke University.
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