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Spectrum: Autism Research News

Online tool can predict effects of genetic variants

by  /  21 March 2012
THIS ARTICLE IS MORE THAN FIVE YEARS OLD

This article is more than five years old. Autism research — and science in general — is constantly evolving, so older articles may contain information or theories that have been reevaluated since their original publication date.

Jigsaw puzzle: Genetic variants can disrupt a regulatory process that removes some stretches of the genetic message that codes for protein.

Researchers have developed a tool that can predict whether DNA mutations are likely to alter RNA splicing, a process that modifies the sequence of mRNA, the genetic message that codes for protein. The results were published 10 February in Bioinformatics, and the tool is freely available online1.

Protein structure is also influenced by RNA splicing, a normal cellular process in which pieces of mRNA, called introns, are removed and the remainder, dubbed exons, are spliced back together. This process is regulated by proteins that bind near splice sites, which sit at the boundaries between introns and exons. When mutations affect RNA splicing, the corresponding protein can be altered.

In a study published last summer, researchers looked at more than 4,000 six-base-pair stretches of DNA, dubbed hexamers, in 300-base-pair regions around splice sites in the human genome2. They chose hexamers because the regulatory proteins that bind to splice sites are most likely to bind to them, the researchers say.

The researchers then determined where specific hexamers are most likely to occur, and created a map showing the likelihood that a given hexamer would be present a certain distance away from a splice site. Hexamers that frequently cluster in a specific location are highly likely to regulate splicing when at that site, the study found.

The researchers then developed a measure to determine whether a point mutation is likely to alter the predicted location of one of these hexamers. Mutations that shift the predicted location are more likely to disrupt splicing than those that do not, the study found. This is true for mutations already known to affect splicing, the study also found. Using shifts in the location of the hexamers to predict their impact on splicing suggests that 22 percent of known disease-causing mutations may affect splicing.

In the new study, the same researchers used these results to construct an online tool that can predict whether a point mutation is likely to have an effect on RNA splicing in the human, chimpanzee, rhesus monkey, mouse, rat, dog, cat, chicken, guinea pig, frog and zebrafish genomes.

References:

1: Lim K.H. and W. Fairbrother Bioinformatics Epub ahead of print (2012) PubMed

2: Lim K.H. et al. Proc. Natl. Acad. Sci. USA 108, 11093-11098 (2011) PubMed