C H Lin1, W Wang, R A Jones, D J Patel. 1. Cellular Biochemistry and Biophysics Program, Memorial Sloan-Kettering Cancer Center, New York, NY 10021, USA.
Abstract
BACKGROUND: In vitro selection has identified DNA aptamers that target cofactors, amino acids, peptides and proteins. Structure determination of such ligand-DNA aptamer complexes should elucidate the details of adaptive DNA structural transitions, binding-pocket architectures and ligand recognition. We have determined the solution structure of the complex of a DNA aptamer containing a guanine-rich 18-residue hairpin loop that binds L-argininamide with approximately 100 microM affinity. RESULTS: The DNA aptamer generates its L-argininamide-binding pocket by adaptive zippering up the 18-residue loop through formation of Watson-Crick pairs, mismatch pairs and base triples, while maximizing stacking interactions. Three of the four base triples involve minor-groove recognition through sheared G.A mismatch formation. The unique fold is also achieved through positioning of an adenine residue deep within the minor groove and through nestling of a smaller loop within the larger loop on complex formation. The accessibility to the unique L-argininamide-binding pocket is restricted by a base pair that bridges across one side of the major-groove-binding site. The guanidinium group of the bound L-argininamide aligns through intermolecular hydrogen-bond formation with the base edges of nonadjacent guanine and cytosine residues while being sandwiched between the planes of nonadjacent guanine residues. CONCLUSIONS: The available structures of L-arginine/L-argininamide bound to their DNA and RNA targets define the common principles and patterns associated with molecular recognition, as well as the diversity of intermolecular hydrogen-bonding alignments associated with the distinct binding pockets.
BACKGROUND: In vitro selection has identified DNA aptamers that target cofactors, amino acids, peptides and proteins. Structure determination of such ligand-DNA aptamer complexes should elucidate the details of adaptive DNA structural transitions, binding-pocket architectures and ligand recognition. We have determined the solution structure of the complex of a DNA aptamer containing a guanine-rich 18-residue hairpin loop that binds L-argininamide with approximately 100 microM affinity. RESULTS: The DNA aptamer generates its L-argininamide-binding pocket by adaptive zippering up the 18-residue loop through formation of Watson-Crick pairs, mismatch pairs and base triples, while maximizing stacking interactions. Three of the four base triples involve minor-groove recognition through sheared G.A mismatch formation. The unique fold is also achieved through positioning of an adenine residue deep within the minor groove and through nestling of a smaller loop within the larger loop on complex formation. The accessibility to the unique L-argininamide-binding pocket is restricted by a base pair that bridges across one side of the major-groove-binding site. The guanidinium group of the bound L-argininamide aligns through intermolecular hydrogen-bond formation with the base edges of nonadjacent guanine and cytosine residues while being sandwiched between the planes of nonadjacent guanine residues. CONCLUSIONS: The available structures of L-arginine/L-argininamide bound to their DNA and RNA targets define the common principles and patterns associated with molecular recognition, as well as the diversity of intermolecular hydrogen-bonding alignments associated with the distinct binding pockets.
Authors: Clement Sester; Jordan A J McCone; Anindita Sen; Jan Vorster; Joanne E Harvey; Justin M Hodgkiss Journal: Biophys J Date: 2022-04-26 Impact factor: 3.699