[Identification of Ribosomal Protein L1-Binding Sites in Thermus thermophilus and Thermotoga maritima mRNAs].

The conserved two-domain ribosomal protein (r-protein) L1 is a structural part of the L1 stalk of the large ribosomal subunit and regulates the translation of the operon that comprises its own gene. The regulatory properties of the bacterial r-protein L1 have only been studied in detail for Escherichia coli; however, there were no such studies for other bacteria, in particular, Thermus thermophilus and Thermotoga maritima, which are more evolutionarily ancient. It is known that domain I of the r-protein L1 might have regulatory properties of the whole protein. The aim of this study was to identify regulatory sites on the mRNA of T. thermophilus and T. maritima that interact with r-proteins L1, as well as with their domains I from the same organisms. An analysis of the mRNA of the L11 operon T. thermophilus showed the presence of one potential binding site of the L1 r-protein, two such regions were found also in the mRNA sequence of the L11 operon of T. maritima. The dissociation constants for the L1 proteins from T. thermophilus and T. maritima and their domains I with mRNA fragments from the same organisms that contain the supposed L1-binding sites were determined by surface plasmon resonance. It has been shown that the ribosomal proteins L1 as their domains I bind specific fragments of mRNA from the same organisms that may suggest regulatory activity of the L1 protein in the T. thermophilus and T. maritima and conservatism of the principles of L1-RNA interactions.

Designed Regular Tetragon-Shaped RNA-Protein Complexes with Ribosomal Protein L1 for Bionanotechnology and Synthetic Biology.

RNA nanotechnology has been established by employing the molecular architecture of RNA structural motifs. Here, we report two designed RNA-protein complexes (RNPs) composed of ribosomal protein L1 (RPL1) and its RNA-binding motif that are square-shaped nano-objects. The formation and the shape of the objects were confirmed by gel electrophoresis analysis and atomic force microscopy, respectively. Any protein can be attached to the RNA via a fusion protein with RPL1, indicating that it can be used as a scaffold for loading a variety of functional proteins or for building higher-order structures. In summary, the RNP object will serve as a useful tool in the fields of bionanotechnology and synthetic biology. Moreover, the RNP interaction enhances the RNA stability against nucleases, rendering these complexes stable in cells.

Protein-RNA affinity of ribosomal protein L1 mutants does not correlate with the number of intermolecular interactions.

Ribosomal protein L1, as part of the L1 stalk of the 50S ribosomal subunit, is implicated in directing tRNA movement through the ribosome during translocation. High-resolution crystal structures of four mutants (T217V, T217A, M218L and G219V) of the ribosomal protein L1 from Thermus thermophilus (TthL1) in complex with a specific 80 nt fragment of 23S rRNA and the structures of two of these mutants (T217V and G219V) in the RNA-unbound form are reported in this work. All mutations are located in the highly conserved triad Thr-Met-Gly, which is responsible for about 17% of all protein-RNA hydrogen bonds and 50% of solvent-inaccessible intermolecular hydrogen bonds. In the mutated proteins without bound RNA the RNA-binding regions show substantial conformational changes. On the other hand, in the complexes with RNA the structures of the RNA-binding surfaces in all studied mutants are very similar to the structure of the wild-type protein in complex with RNA. This shows that formation of the RNA complexes restores the distorted surfaces of the mutant proteins to a conformation characteristic of the wild-type protein complex. Domain I of the mutated TthL1 and helix 77 of 23S rRNA form a rigid body identical to that found in the complex of wild-type TthL1 with RNA, suggesting that the observed relative orientation is conserved and is probably important for ribosome function. Analysis of the complex structures and the kinetic data show that the number of intermolecular contacts and hydrogen bonds in the RNA-protein contact area does not correlate with the affinity of the protein for RNA and cannot be used as a measure of affinity.