Aptamers For Small Molecules | October 6, 2014 Issue - Vol. 92 Issue 40 | Chemical & Engineering News
Volume 92 Issue 40 | p. 8 | News of The Week
Issue Date: October 6, 2014

Aptamers For Small Molecules

Biosensors: Strategy for designing custom oligonucleotides could lead to biosensors for small metabolites
Department: Science & Technology | Collection: Life Sciences
News Channels: Biological SCENE
Keywords: aptamers, nucleic acids, biosensors, small molecules
A new method selects aptamers that bind a complex of a synthetic receptor (blue) and a small molecule (red).
Credit: Milan Stojanovic
Top, a ribbon, a c-shaped blue blob, and a red ovoid. Bottom, the blue blob is engulfing the red ovoid and the ribbon is wrapped around it.
A new method selects aptamers that bind a complex of a synthetic receptor (blue) and a small molecule (red).
Credit: Milan Stojanovic

Aptamers—folded oligonucleotides designed to bind a ligand of interest—are often used to make biosensors. But finding high-affinity, selective aptamers for very small molecules such as simple sugars or amino acids can be tough because such molecules often lack functional groups for the aptamers to grab onto. Researchers at Columbia University have found a way around this problem. The resulting aptamers could be used to make sensitive biosensors that can, for example, detect the low concentrations of glucose found in hypoglycemic individuals.

Researchers typically screen libraries of aptamers to select ones that bind an isolated small molecule. Instead, Milan N. Stojanovic, Tilla S. Worgall, and coworkers select aptamers that recognize complexes of synthetic receptors bound to those molecules (Nat. Chem. 2014, DOI: 10.1038/nchem.2058). In this way, they developed one set of aptamers that differentiates the sugars glucose, fructose, and galactose and another set of aptamers that distinguishes the amino acids phenylalanine, tryptophan, and tyrosine.

To identify the sugar-specific aptamers, they selected nucleic acid sequences that bind complexes of the sugars with a boronic acid-containing receptor. For the amino acids, they used an organometallic rhodium complex as the receptor. “The method is truly general in that almost any organic receptor can have its selectivity and affinity improved,” Stojanovic says.

The sensors could have important clinical applications. The glucose sensor, for example, is suitable for measuring the low glucose levels associated with hypoglycemia. The researchers also used the phenylalanine aptamer to measure the amino acid in human serum. Sensors based on the aptamer could give individuals with the metabolic disorder phenylketonuria a way to monitor their phenylalanine levels.

The researchers are using the method to develop aptamers for other tough-to-distinguish targets, such as lipids. They are also looking for aptamers that can detect the branched-chain amino acids valine, leucine, and isoleucine.

The method “will significantly expand our ability to develop aptamers for diverse small-molecule targets,” says Yingfu Li, an aptamer expert at McMaster University in Hamilton, Ontario.

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