Claude Sauter

Structure of transfer RNAs: similarity and variability

Transfer RNAs (tRNAs) are ancient molecules whose origin goes back to the beginning of life on Earth. Key partners in the ribosome‐translation machinery, tRNAs read genetic information on messenger RNA and deliver codon specified amino acids attached to their distal 3′‐extremity for peptide bond synthesis on the ribosome. In addition to this universal function, tRNAs participate in a wealth of other biological processes and undergo intricate maturation events. Our understanding of tRNA biology has been mainly phenomenological, but ongoing progress in structural biology is giving a robust physico‐chemical basis that explains many facets of tRNA functions. Advanced sequence analysis of tRNA genes and their RNA transcripts have uncovered rules that underly tRNA 2D folding and 3D L‐shaped architecture, as well as provided clues about their evolution. The increasing number of X‐ray structures of free, protein‐ and ribosome‐bound tRNA, reveal structural details accounting for the identity of the 22 tRNA families (one for each proteinogenic amino acid) and for the multifunctionality of a given family. Importantly, the structural role of post‐transcriptional tRNA modifications is being deciphered. On the other hand, the plasticity of tRNA structure during function has been illustrated using a variety of technical approaches that allow dynamical insights. The large range of structural properties not only allows tRNAs to be the key actors of translation, but also sustain a diversity of unrelated functions from which only a few have already been pinpointed. Many surprises can still be expected. WIREs RNA 2012, 3:37–61. doi: 10.1002/wrna.103

A supersaturation wave of protein crystallization

A microgravity protein crystallization experiment is described in which the existence of a supersaturation wave traveling across a diffusion-reaction system is experimentally demonstrated for the first time. The self-organized dynamics of the experimental setup were used to implement a crystallization technique able to search automatically through the crystallization parameter space for optimum nucleation and growth conditions. The crystals obtained by this automatic optimization produced the highest quality X-ray diffraction data ever collected from the model protein used in the experiment.

Crystal structure of 3WJ core revealing divalent ion-promoted thermostability and assembly of the Phi29 hexameric motor pRNA

The bacteriophage phi29 DNA packaging motor, one of the strongest biological motors characterized to date, is geared by a packaging RNA (pRNA) ring. When assembled from three RNA fragments, its three-way junction (3WJ) motif is highly thermostable, is resistant to 8 M urea, and remains associated at extremely low concentrations in vitro and in vivo. To elucidate the structural basis for its unusual stability, we solved the crystal structure of this pRNA 3WJ motif at 3.05 Å. The structure revealed two divalent metal ions that coordinate 4 nt of the RNA fragments. Single-molecule fluorescence resonance energy transfer (smFRET) analysis confirmed a structural change of 3WJ upon addition of Mg²⁺. The reported pRNA 3WJ conformation is different from a previously published construct that lacks the metal coordination sites. The phi29 DNA packaging motor contains a dodecameric connector at the vertex of the procapsid, with a central pore for DNA translocation. This portal connector serves as the foothold for pRNA binding to procapsid. Subsequent modeling of a connector/pRNA complex suggests that the pRNA of the phi29 DNA packaging motor exists as a hexameric complex serving as a sheath over the connector. The model of hexameric pRNA on the connector agrees with AFM images of the phi29 pRNA hexamer acquired in air and matches all distance parameters obtained from cross-linking, complementary modification, and chemical modification interference.

Crystallization of biological macromolecules using agarose gel

Gellified media prevent convection and crystal sedimentation, and provide an attractive growth environment for optimising biological crystals. Agarose gels are particularly easy to use and they are compatible with most of the common crystallization methods. They also offer new possibilities like counter-diffusion techniques. This paper gives a brief overview of their general properties and presents an application of a counter-diffusion setup combining agarose gel and capillaries to the crystallization of proteins and protein / nucleic acid complexes.

Crystal growth of proteins, nucleic acids, and viruses in gels.

Medium-sized single crystals with perfect habits and no defect producing intense and well-resolved diffraction patterns are the dream of every protein crystallographer. Crystals of biological macromolecules possessing these characteristics can be prepared within a medium in which mass transport is restricted to diffusion. Chemical gels (like polysiloxane) and physical gels (such as agarose) provide such an environment and are therefore suitable for the crystallisation of biological macromolecules. Instructions for the preparation of each type of gel are given to urge crystal growers to apply diffusive media for enhancing crystallographic quality of their crystals. Examples of quality enhancement achieved with silica and agarose gels are given. Results obtained with other substances forming gel-like media (such as lipidic phases and cellulose derivatives) are presented. Finally, the use of gels in combination with capillary tubes for counter-diffusion experiments is discussed. Methods and techniques implemented with proteins can also be applied to nucleic acids and nucleoprotein assemblies such as viruses.

Additives for the crystallization of proteins and nucleic acids

Numerous molecules have been described in literature as additives that were indispensable either for nucleation or growth of macromolecular crystals. In some cases, such additives were shown to improve the quality of the X-ray diffraction and to extend diffraction limits. We have investigated the effects of more than fifty compounds, belonging to several chemical families, on the crystallization of four model proteins (hen and turkey egg-white lysozymes, thaumatin, and aspartyl-tRNA synthetase from Thermus thermophilus). In addition, we have studied the crystallization of a ribonucleic acid from yeast, the transfer RNA specific for phenylalanine in the presence of synthetic polyamines. Crystals grown in the presence of the additives were optically evaluated and X-ray diffraction analyses were performed on selective crystals to compare their space group, cell parameters, and diffraction limit with those of controls. Whereas no changes in space group nor cell parameters were observed for the model proteins, significant improvements in diffraction limit were found when the transfer RNA was crystallized with certain synthetic polyamines.

Characterization of protein and virus crystals by quasi-planar wave X-ray topography: a comparison between crystals grown in solution and in agarose gel

Quasi-planar wave reflection profile and X-ray topography studies have been done to characterize the mosaicity of solution- and gel-grown crystals of three proteins, turkey egg-white (TEW) lysozyme, thaumatin, and a bacterial aspartyl-tRNA synthetase (AspRS) as well as of one virus, tomato bushy stunt virus (TBSV). These materials are representative of a large range of molecular weight, overall particle shapes, crystals habits, packings, and solvent contents. Measurements of the full-width at half-maximum (FWHM) of reflections show that these different crystals have all a weak mosaicity. Topographs display the same features as those of the well-studied hen egg-white (HEW) lysozyme crystals: misorientation generated at the seed level for TEW lysozyme or thaumatin crystals and/or strains at growth sector boundaries for AspRS crystals. No growth defects are evidenced for TBSV crystals. For the study of crystals diffracting at lower resolution (AspRS and virus), a less absorbant sample holder, which facilitates crystal positioning in the X-ray beam, has been developed. The results obtained for solution- and gel-grown crystals do not show important differences. However, for TEW lysozyme and thaumatin crystals, one notices a larger dispersion of results in the solution case and an overall tendency for improved reproducibility of quality for gel-grown crystals.

Structural insights into protein-only RNase P complexed with tRNA

RNase P is the essential activity removing 5′-leader sequences from transfer RNA precursors. RNase P was always associated with ribonucleoprotein complexes before the discovery of protein-only RNase P enzymes called PRORPs (PROteinaceous RNase P) in eukaryotes. Here we provide biophysical and functional data to understand the mode of action of PRORP enzymes. Activity assays and footprinting experiments show that the anticodon domain of transfer RNA is dispensable, whereas individual residues in D and TψC loops are essential for PRORP function. PRORP proteins are characterized in solution and a molecular envelope is derived from small-angle X-ray scattering. Conserved residues are shown to be involved in the binding of one zinc atom to PRORP. These results facilitate the elaboration of a model of the PRORP/transfer RNA interaction. The comparison with the ribonucleoprotein RNase P/transfer RNA complex suggests that transfer RNA recognition by PRORP proteins is similar to that by ribonucleoprotein RNase P.

Towards atomic resolution with crystals grown in gel: the case of thaumatin seen at room temperature.

One reason for introducing a gel in the crystallization medium of proteins is its ability to reduce convection in solution. This can lead to better nucleation and growth conditions, and to crystals having enhanced diffraction properties. We report here the X‐ray characterization at room temperature of high‐quality crystals of the intensely sweet thaumatin prepared in a sodium tartrate solution gelified with 0.15% (m/v) agarose. Using a synchrotron radiation, these crystals diffracted to a previously unachieved resolution. A diffraction dataset was collected from four crystals at a resolution of 1.2 Å with a Rsym of 3.6% and a completeness of 99%. Refinement was carried out to a final crystallographic R‐factor of 12.0%. The quality of the electron density map allowed for the observation of fine structural details in the protein and its solvation shell. Crystallization in gel might be used more generally to improve the quality of macromolecular crystals. Advantages provided by the gelified medium in the frame of structural studies are emphasized. Proteins 2002;48:146–150.

Structural Insights Into Viral Determinants of Nematode Mediated Grapevine Fanleaf Virus Transmission.

Many animal and plant viruses rely on vectors for their transmission from host to host. Grapevine fanleaf virus (GFLV), a picorna-like virus from plants, is transmitted specifically by the ectoparasitic nematode Xiphinema index. The icosahedral capsid of GFLV, which consists of 60 identical coat protein subunits (CP), carries the determinants of this specificity. Here, we provide novel insight into GFLV transmission by nematodes through a comparative structural and functional analysis of two GFLV variants. We isolated a mutant GFLV strain (GFLV-TD) poorly transmissible by nematodes, and showed that the transmission defect is due to a glycine to aspartate mutation at position 297 (Gly297Asp) in the CP. We next determined the crystal structures of the wild-type GFLV strain F13 at 3.0 Å and of GFLV-TD at 2.7 Å resolution. The Gly297Asp mutation mapped to an exposed loop at the outer surface of the capsid and did not affect the conformation of the assembled capsid, nor of individual CP molecules. The loop is part of a positively charged pocket that includes a previously identified determinant of transmission. We propose that this pocket is a ligand-binding site with essential function in GFLV transmission by X. index. Our data suggest that perturbation of the electrostatic landscape of this pocket affects the interaction of the virion with specific receptors of the nematodes feeding apparatus, and thereby severely diminishes its transmission efficiency. These data provide a first structural insight into the interactions between a plant virus and a nematode vector.