Solution structure of the complex formed by the two N-terminal RNA-binding domains of nucleolin and a pre-rRNA target

Kinetic analysis of the role of the tyrosine 13, phenylalanine 56 and glutamine 54 network in the U1A/U1 hairpin II interaction

The A protein of the U1 small nuclear ribonucleoprotein particle, interacting with its stem-loop RNA target (U1hpII), is frequently used as a paradigm for RNA binding by recognition motif domains (RRMs). U1A/U1hpII complex formation has been proposed to consist of at least two steps: electrostatically mediated alignment of both molecules followed by locking into place, based on the establishment of close-range interactions. The sequence of events between alignment and locking remains obscure. Here we examine the roles of three critical residues, Tyr13, Phe56 and Gln54, in complex formation and stability using Biacore. Our mutational and kinetic data suggest that Tyr13 plays a more important role than Phe56 in complex formation. Mutational analysis of Gln54, combined with molecular dynamics studies, points to Arg52 as another key residue in association. Based on our data and previous structural and modeling studies, we propose that electrostatic alignment of the molecules is followed by hydrogen bond formation between the RNA and Arg52, and the sequential establishment of interactions with loop bases (including Tyr13). A quadruple stack, sandwiching two bases between Phe56 and Asp92, would occur last and coincide with the rearrangement of a C-terminal helix that partially occludes the RRM surface in the free protein.

Survey of the year 2004 commercial optical biosensor literature

The year 2004 represents a milestone for the biosensor research community: in this year, over 1000 articles were published describing experiments performed using commercially available systems. The 1038 papers we found represent an approximately 10% increase over the past year and demonstrate that the implementation of biosensors continues to expand at a healthy pace. We evaluated the data presented in each paper and compiled a 'top 10' list. These 10 articles, which we recommend every biosensor user reads, describe well-performed kinetic, equilibrium and qualitative/screening studies, provide comparisons between binding parameters obtained from different biosensor users, as well as from biosensor- and solution-based interaction analyses, and summarize the cutting-edge applications of the technology. We also re-iterate some of the experimental pitfalls that lead to sub-optimal data and over-interpreted results. We are hopeful that the biosensor community, by applying the hints we outline, will obtain data on a par with that presented in the 10 spotlighted articles. This will ensure that the scientific community at large can be confident in the data we report from optical biosensors.

Structure Determination of Protein⧸RNA Complexes by NMR

Structure determination of protein?RNA complexes in solution provides unique insights into factors that are involved in protein/RNA recognition. Here, we review the methodology used in our laboratory to overcome the challenges of protein?RNA structure determination by nuclear magnetic resonance (NMR). We use as two examples complexes recently solved in our laboratory, the nucleolin RBD12/b2NRE and Rnt1p dsRBD/snR47h complexes. Topics covered are protein and RNA preparation, complex formation, identification of the protein/RNA interface, protein and RNA resonance assignment, intermolecular NOE assignment, and structure calculation and analysis.

Contributions of the RNA-binding and linker domains and RNA structure to the specificity and affinity of the nucleolin RBD12/NRE interaction

Nucleolin is a multidomain phosphoprotein involved in ribosome biogenesis. In vitro selection and binding studies with pre-rRNA fragments have shown that the first two RNA-binding domains (RBDs) in nucleolin (RBD12) recognize the consensus sequence (U/G)CCCG(A/G) in the context of a stem-loop structure (nucleolin-recognition element = NRE). Structural studies of nucleolin RBD12 in complex with an in vitro selected NRE (sNRE) and a natural pre-rRNA NRE (b2NRE) have revealed that sequence-specific binding of the consensus NRE is achieved in a similar manner in both complexes using residues in both RBDs as well as the linker connecting them. Using fluorescence anisotropy (FA) and nuclear magnetic resonance (NMR), we demonstrate the importance of the linker for NRE affinity by showing that only the individual RBDs with the linker attached retain the ability to specifically bind, albeit weakly, to sNRE and b2NRE. Binding of RBD1 and RBD2 to the NREs in trans is not detected even when one of the RBDs has the linker attached, which suggests that the linker also contributes to the affinity by tethering the two RBDs. To determine if binding of nucleolin RBD12 to natural NREs is dependent on a specific RNA stem-loop structure, as was the case for the sNRE, we conducted FA and NMR binding assays with nucleolin RBD12 and a single-stranded NRE. The results show that nucleolin RBD12 sequence-specifically binds a single-stranded NRE with an affinity similar to that for b2NRE, indicating that a stem-loop structure is not required for the nucleolin RBD12/pre-rRNA NRE interaction.