Maria Garber

The structure of elongation factor G in complex with GDP: conformational flexibility and nucleotide exchange

BACKGROUND Elongation factor G (EF-G) catalyzes the translocation step of translation. During translocation EF-G passes through four main conformational states: the GDP complex, the nucleotide-free state, the GTP complex, and the GTPase conformation. The first two of these conformations have been previously investigated by crystallographic methods. RESULTS The structure of EF-G-GDP has been refined at 2.4 A resolution. Comparison with the nucleotide-free structure reveals that, upon GDP release, the phosphate-binding loop (P-loop) adopts a closed conformation. This affects the position of helix CG, the switch II loop and domains II, IV and V. Asp83 has a conformation similar to the conformation of the corresponding residue in the EF-Tu/EF-Ts complex. The magnesium ion is absent in EF-G-GDP. CONCLUSIONS The results illustrate that conformational changes in the P-loop can be transmitted to other parts of the structure. A comparison of the structures of EF-G and EF-Tu suggests that EF-G, like EF-Tu, undergoes a transition with domain rearrangements. The conformation of EF-G-GDP around the nucleotide-binding site may be related to the mechanism of nucleotide exchange.

Structure of the L1 protuberance in the ribosome.

The L1 protuberance of the 50S ribosomal subunit is implicated in the release/disposal of deacylated tRNA from the E site. The apparent mobility of this ribosomal region has thus far prevented an accurate determination of its three-dimensional structure within either the 50S subunit or the 70S ribosome. Here we report the crystal structure at 2.65 Å resolution of ribosomal protein L1 from Sulfolobus acidocaldarius in complex with a specific 55-nucleotide fragment of 23S rRNA from Thermus thermophilus. This structure fills a major gap in current models of the 50S ribosomal subunit. The conformations of L1 and of the rRNA fragment differ dramatically from those within the crystallographic model of the T. thermophilus 70S ribosome. Incorporation of the L1–rRNA complex into the structural models of the T. thermophilus 70S ribosome and the Deinococcus radiodurans 50S subunit gives a reliable representation of most of the L1 protuberance within the ribosome.

Crystal structure of the S15-rRNA complex.

In bacterial ribosomes, the small (30S) ribosomal subunit is composed of 16S rRNA and 21 distinct proteins. Ribosomal protein S15 is of particular interest because it binds primarily to 16S rRNA and is required for assembly of the small subunit and for intersubunit association, thus representing a key element in the assembly of a whole ribosome. Here we report the 2.8 Å resolution crystal structure of the highly conserved S15–rRNA complex. Protein S15 interacts in the minor groove with a G-U/G-C motif and a three-way junction. The latter is constrained by a conserved base triple and stacking interactions, and locked into place by magnesium ions and protein side chains, mainly through interactions with the unique three-dimensional geometry of the backbone. The present structure gives insights into the dual role of S15 in ribosome assembly and translational regulation.

Structure of Pseudomonas aeruginosa Hfq protein.

The structure of the Hfq protein from Pseudomonas aeruginosa was determined using two different ionic conditions. In both cases the molecules formed identical hexameric rings, but some variations in the crystal packing were revealed. Hfq belongs to the family of Sm/LSm proteins, the members of which can form hexameric as well as heptameric rings. Comparative analysis of known structures of this protein family shows that the fragment of the Sm-fold responsible for oligomerization is strongly structurally conserved. In the heptameric ring, three conserved hydrogen bonds between beta-strands of adjacent molecules hold together the monomers, whereas in the hexameric rings of Hfq an additional conserved inaccessible hydrogen bond between neighbouring monomers is observed.

The crystal structure of ribosomal protein L22 from Thermus thermophilus: insights into the mechanism of erythromycin resistance

BACKGROUND . The ribosomal protein L22 is one of five proteins necessary for the formation of an early folding intermediate of the 23S rRNA. L22 has been found on the cytoplasmic side of the 50S ribosomal subunit. It can also be labeled by an erythromycin derivative bound close to the peptidyl-transfer center at the interface side of the 50S subunit, and the amino acid sequence of an erythromycin-resistant mutant is known. Knowing the structure of the protein may resolve this apparent conflict regarding the location of L22 on the ribosome. RESULTS . The structure of Thermus thermophilus L22 was solved using X-ray crystallography. L22 consists of a small alpha+beta domain and a protruding beta hairpin that is 30 A long. A large part of the surface area of the protein has the potential to be involved in interactions with rRNA. A structural similarity to other RNA-binding proteins is found, possibly indicating a common evolutionary origin. CONCLUSIONS . The extensive surface area of L22 has the characteristics of an RNA-binding protein, consistent with its role in the folding of the 23S rRNA. The erythromycin-resistance conferring mutation is located in the protruding beta hairpin that is postulated to be important in L22-rRNA interactions. This region of the protein might be at the erythromycin-binding site close to the peptidyl transferase center, whereas the opposite end may be exposed to the cytoplasm.

Ribosomal proteins and elongation factors

Structural work on the translation machinery has recently undergone rapid progress. It is now known that six out of nine ribosomal proteins have an RNA-binding fold, and two domains of elongation factors Tu and G have very similar folds. In addition, the complex of EF-Tu with a GTP analogue and Phe-tRNA(Phe) has a structure that overlaps exceedingly well with that of EF-G-GDP. These findings obviously have functional implications.

Ribosomal protein L1 recognizes the same specific structural motif in its target sites on the autoregulatory mRNA and 23S rRNA

The RNA-binding ability of ribosomal protein L1 is of profound interest since the protein has a dual function as a ribosomal protein binding rRNA and as a translational repressor binding its mRNA. Here, we report the crystal structure of ribosomal protein L1 in complex with a specific fragment of its mRNA and compare it with the structure of L1 in complex with a specific fragment of 23S rRNA determined earlier. In both complexes, a strongly conserved RNA structural motif is involved in L1 binding through a conserved network of RNA–protein H-bonds inaccessible to the solvent. These interactions should be responsible for specific recognition between the protein and RNA. A large number of additional non-conserved RNA–protein H-bonds stabilizes both complexes. The added contribution of these non-conserved H-bonds makes the ribosomal complex much more stable than the regulatory one.

Ribosomal proteins: Structure, function, and evolution

The question concerning reasons for the variety of ribosomal proteins that arose for more than 40 years ago is still open. Ribosomes of modern organisms contain 50–80 individual proteins. Some are characteristic for all domains of life (universal ribosomal proteins), whereas others are specific for bacteria, archaea, or eucaryotes. Extensive information about ribosomal proteins has been obtained since that time. However, the role of the majority of ribosomal proteins in the formation and functioning of the ribosome is still not so clear. Based on recent data of experiments and bioinformatics, this review presents a comprehensive evaluation of structural conservatism of ribosomal proteins from evolutionarily distant organisms. Considering the current knowledge about features of the structural organization of the universal proteins and their intermolecular contacts, a possible role of individual proteins and their structural elements in the formation and functioning of ribosomes is discussed. The structural and functional conservatism of the majority of proteins of this group suggests that they should be present in the ribosome already in the early stages of its evolution.

Translation termination factor aRF1 from the archaeon Methanococcus jannaschii is active with eukaryotic ribosomes.

Class‐1 translation termination factors (release factors (RFs)) from Eukarya (eRF1) and Archaea (aRF1) exhibit a high degree of amino acid sequence homology and share many common motifs. In contrast to eRF1, function(s) of aRF1 have not yet been studied in vitro. Here, we describe for the first time the cloning and expression in Escherichia coli of the gene encoding the peptide chain RF from the hyperthermophilic archaeon Methanococcus jannaschii (MjaRF1). In an in vitro assay with mammalian ribosomes, MjaRF1, which was overproduced in E. coli, was active as a RF with all three termination codon‐containing tetraplets, demonstrating the functional resemblance of aRF1 and eRF1. This observation confirms the earlier prediction that eRF1 and aRF1 form a common structural–functional eRF1/aRF1 protein family, originating from a common ancient ancestor.

Structure of ribosomal protein TL5 complexed with RNA provides new insights into the CTC family of stress proteins

The crystal structure of Thermus thermophilus ribosomal protein TL5 in complex with a fragment of Escherichia coli 5S rRNA has been determined at 2.3 A resolution. The protein consists of two domains. The structure of the N-terminal domain is close to the structure of E. coli ribosomal protein L25, but the C-terminal domain represents a new fold composed of seven beta-strands connected by long loops. TL5 binds to the RNA through its N-terminal domain, whereas the C-terminal domain is not included in this interaction. Cd(2+) ions, the presence of which improved the crystal quality significantly, bind only to the protein component of the complex and stabilize the protein molecule itself and the interactions between the two molecules in the asymmetric unit of the crystal. The TL5 sequence reveals homology to the so-called general stress protein CTC. The hydrophobic cores which stabilize both TL5 domains are highly conserved in CTC proteins. Thus, all CTC proteins may fold with a topology close to that of TL5.