posted on 2015-12-17, 02:33authored byJoanna Sztuba-Solinska, Shilpa R. Shenoy, Peter Gareiss, Lauren
R. H. Krumpe, Stuart
F. J. Le Grice, Barry R. O’Keefe, John S. Schneekloth
Identifying
small molecules that selectively bind to structured
RNA motifs remains an important challenge in developing potent and
specific therapeutics. Most strategies to find RNA-binding molecules
have identified highly charged compounds or aminoglycosides that commonly
have modest selectivity. Here we demonstrate a strategy to screen
a large unbiased library of druglike small molecules in a microarray
format against an RNA target. This approach has enabled the identification
of a novel chemotype that selectively targets the HIV transactivation
response (TAR) RNA hairpin in a manner not dependent on cationic charge.
Thienopyridine 4 binds to and stabilizes the TAR hairpin
with a Kd of 2.4 μM. Structure–activity
relationships demonstrate that this compound achieves activity through
hydrophobic and aromatic substituents on a heterocyclic core, rather
than cationic groups typically required. Selective 2′-hydroxyl
acylation analyzed by primer extension (SHAPE) analysis was performed
on a 365-nucleotide sequence derived from the 5′ untranslated
region (UTR) of the HIV-1 genome to determine global structural changes
in the presence of the molecule. Importantly, the interaction of compound 4 can be mapped to the TAR hairpin without broadly disrupting
any other structured elements of the 5′ UTR. Cell-based anti-HIV
assays indicated that 4 inhibits HIV-induced cytopathicity
in T lymphocytes with an EC50 of 28 μM, while cytotoxicity
was not observed at concentrations approaching 1 mM.