Sulay D. Jhaveri

In vitro selection of signaling aptamers

Reagentless biosensors that can directly transduce molecular recognition to optical signals should potentiate the development of sensor arrays for a wide variety of analytes. Nucleic acid aptamers that bind ligands tightly and specifically can be readily selected, but may prove difficult to adapt to biosensor applications. We have therefore attempted to develop selection methods that couple the broad molecular recognition properties of aptamers with signal transduction. Anti-adenosine aptamers were selected from a pool that was skewed to contain very few fluoresceinated uridines. The primary family of aptamers showed a doubling of relative fluorescence intensity at saturating concentrations of a cognate analyte, ATP, and could sense ATP concentrations as low as 25 μM. A single uridine was present in the best signaling aptamer. Surprisingly, other dyes could substitute for fluorescein and still specifically signal the presence of ATP, indicating that the single uridine functioned as a general “switch” for transducing molecular recognition to optical signals.

In vitro selection of phosphorothiolated aptamers

A pool of RNA molecules that contained exclusively phosphorothioate internucleoside linkages was used as a starting point for the selection of aptamers that bind to basic fibroblast growth factor (bFGF), and appear to act as heparin mimics.

In Vitro Selection of RNA Aptamers to a Protein Target by Filter Immobilization

This unit describes the selection of aptamers from a pool of single-stranded RNA by binding to a protein target. Aptamers generated from this selection experiment can potentially function as protein inhibitors, and may find applications as therapeutic or diagnostic reagents. A pool of dsDNA is used to generate a ssRNA pool, which is mixed with the protein target. Bound complexes are separated from unbound reagents by filtration, and the RNA:protein complexes are amplified by a combination of reverse transcription, PCR, and in vitro transcription.

Combinatorial methods: aptamers and aptazymes

Combinatorial methods have been used to generate nucleic acid molecules with specific characteristics. Aptamers are nucleic acid binding species, and can be modified to directly transduce molecular recognition to optical signals. Aptazymes are allosteric or effector-activated ribyzymes. We have designed or selected aptazymes that are responsive to a variety of ligands. In particular, we have selected a ribozyme ligase that is activated 10,000-fold in the presence of an oligonucleotide effector, and have designed ligases that are up to 1,600-fold dependent on small molecule effectors. Even in those instances where designed constructs were initially unresponsive, we have been able to use selection to optimize their response characteristics.

In vitro selection of RNA aptamers to a protein target by filter immobilization.

In vitro selection of RNA aptamers that bind to a protein target is detailed in the protocols presented in this unit. Aptamers generated from these types of selection experiments can potentially function as protein inhibitors, and are often used as diagnostic or therapeutic reagents.