Modifying the specificity of an RNA backbone contact.

The interaction between the MS2 bacteriophage coat protein homodimer and its cognate RNA hairpin is facilitated by 21 different RNA-protein contacts. In one of these contacts, the 2'-hydroxyl group at ribose -5 of the RNA acts as a hydrogen bond donor to Glu63 in one subunit of the protein. Previous experiments showed that substitution of ribose -5 with deoxyribose resulted in a 24-fold decrease in binding affinity between RNA and protein. Using a protein where the two MS2 monomers were fused to increase stability, the contribution of this contact to the overall binding affinity was investigated by site-directed mutagenesis. When Glu63 was substituted with glutamine, aspartate, or alanine, the binding affinity of the hairpin for the protein was weakened by 12 to 100-fold, similar to that observed with deoxyribose at position -5. However, the specificity of the three mutant proteins for RNAs with various modifications at the 2'-position of ribose -5 differed dramatically. While the Glu63Asp protein resembled the wild-type protein in preferring the 2'-hydroxyl group over a proton or a bulky 2'-substituent, both the Glu63Ala and Glu63Gln proteins preferred bulky 2'-substituents over the 2'-hydroxyl group by more than 100-fold. These experiments emphasize the ease with which the specificity of a protein-nucleic acid interaction can be changed at thermodynamically important sites.

Evaluation of methylphosphonates as analogs for detecting phosphate contacts in RNA-protein complexes.

The well-studied interaction between the MS2 coat protein and its cognate hairpin was used to test the utility of the methylphosphonate linkage as a phosphate analog. A nitrocellulose filter binding assay was used to measure the change in binding affinity upon introduction of a single methylphosphonate stereoisomer at 13 different positions in the RNA hairpin. Comparing these data to the available crystal structure of the complex shows that all phosphates that are in proximity to the protein show a weaker binding affinity when substituted with a phosphorothioate and control positions show no change. However, in two cases, a methylphosphonate isomer either increased or decreased the binding affinity where no interaction can be detected in the crystal structure. It is possible that methylphosphonate substitutions at these positions affect the structure or flexibility of the hairpin. The utility of the methylphosphonate substitution is compared to phosphate ethylation and phosphorothioate substitution experiments previously performed on the same system.

Using phosphorothioate-substituted RNA to investigate the thermodynamic role of phosphates in a sequence specific RNA-protein complex.

Part of the binding affinity and specificity in RNA-protein complexes is often contributed by contacts between the protein and backbone phosphates that are held in position by the RNA structure. This study focuses on the well-characterized interaction between a dimer of the MS2 coat protein and a small RNA hairpin. Using a short oligoribonucleotide which contains all the necessary sequence elements required for tight protein binding, a single phosphorothioate linkage was introduced at 13 different positions. In each case, the R(P) and S(P) stereoisomers were separated and their affinities to the MS2 coat protein were determined. Comparison of these biochemical data with the crystal structure of the protein-hairpin complex indicates that introduction of a phosphorothioate only affects binding at sites where a protein-phosphate contact is observed in the crystal structure. This means that phosphorothioate-containing oligoribonucleotides should also be useful for mapping phosphate contacts in RNA-protein complexes for which no crystal structure is available.

A thermodynamic analysis of the sequence-specific binding of RNA by bacteriophage MS2 coat protein.

Most mutations in the sequence of the RNA hairpin that specifically binds MS2 coat protein either reduce the binding affinity or have no effect. However, one RNA mutation, a uracil to cytosine change in the loop, has the unusual property of increasing the binding affinity to the protein by nearly 100-fold. Guided by the structure of the protein-RNA complex, we used a series of protein mutations and RNA modifications to evaluate the thermodynamic basis for the improved affinity: The tight binding of the cytosine mutation is due to (i) the amino group of the cytosine residue making an intra-RNA hydrogen bond that increases the propensity of the free RNA to adopt the structure seen in the complex and (ii) the increased affinity of hydrogen bonds between the protein and a phosphate two bases away from the cytosine residue. The data are in good agreement with a recent comparison of the cocrystal structures of the two complexes, where small differences in the two structures are seen at the thermodynamically important sites.