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Jan. 20, 2012 Research Highlight Chemistry

Decoding DNA’s annotations

A chemical probe that can differentiate between chemical tags adorning DNA could provide insights into how nature switches genes on and off

Image of Sp1 peptide probe and DNA Figure 1: The Sp1 peptide probe (left) binds a DNA strand (right) and reveals the presence of an epigenetic marker that is a methyl group (purple). © 2012 Akimitsu Okamoto

In the currently hot research area known as ‘epigenetics’, researchers are discovering that offspring inherit much more from their parents than just their genes. Individuals also inherit detailed instructions on how to use the genetic sequence coded in their DNA via small chemical, or epigenetic, markers that decorate DNA strands. The markers can activate some genes and switch off others. Epigeneticists are racing to decode the roles of different markers; but, first, they must develop the ability to read them. A new chemical probe, developed by a research team led by Akimitsu Okamoto at the RIKEN Advanced Science Institute, Wako, is showing promise as an analytical tool to assist this quest1.

The team’s probe can differentiate between two epigenetic markers—methyl and hydroxymethyl markers—that differ by the presence of a single oxygen atom. Methyl groups, one of the first epigenetic markers discovered, are known to inactivate gene expression; ‘demethylation’, or removal of a methyl group from the DNA, allows gene expression to restart.

“We know the mechanism of DNA methylation, but nobody knows the mechanism of DNA demethylation,” Okamoto explains. One possibility is that the body converts the methyl marker into a hydroxymethyl group, as the first step in the process of removing it, in preparation to reactivate a gene. However, current tests cannot distinguish between the two epigenetic markers, preventing that theory from being tested.

The chemical probe developed by Okamoto and colleagues is based on a peptide called Sp1, which is known to bind to DNA. The researchers previously modified the structure of Sp1 so that it adheres strongly only to DNA strands incorporating a methyl marker (Fig. 1). They then showed that if the peptide binds to a DNA strand, it reveals the presence of the methyl group2.

In their latest study, the researchers showed that modified Sp1 will not bind to DNA when the methyl group is converted to a hydroxymethyl—thereby allowing them to tell the two groups apart. The extra oxygen atom in the hydroxymethyl group disrupts the interaction between the peptide and the DNA, so the two cease to adhere together.

Okamoto and his colleagues are now planning to modify the peptide to detect an even wider range of epigenetic markers, which will allow the study of their role in gene expression. “Our next step is to develop the methods for effective sequencing and detection of DNA containing cytosine, 5-methylcytosine, 5-hydroxymethylcytosine, 5-formylcytosine, and 5-carboxycytosine,” Okamoto says.

References

  • 1. Nomura, A., Sugizaki, K., Yanagisawa, H. & Okamoto, A. Discrimination between 5-hydroxymethlcytosine and 5-methylcytosine by a chemically designed peptide. Chemical Communications 47, 8277–8279 (2011). doi: 10.1039/C1CC12131F
  • 2. Nomura, A. & Okamoto, A. Phosphopeptides designed for 5-methylcytosine recognition. Biochemistry 50, 3376–3385 (2011). doi: 10.1021/bi102053d

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