Rajendra K. Agrawal

A ratchet-like inter-subunit reorganization of the ribosome during translocation.

The ribosome is a macromolecular assembly that is responsible for protein biosynthesis following genetic instructions in all organisms. It is composed of two unequal subunits: the smaller subunit binds messenger RNA and the anticodon end of transfer RNAs, and helps to decode the mRNA; and the larger subunit interacts with the amino-acid-carrying end of tRNAs and catalyses the formation of the peptide bonds. After peptide-bond formation, elongation factor G (EF-G) binds to the ribosome, triggering the translocation of peptidyl-tRNA from its aminoacyl site to the peptidyl site, and movement of mRNA by one codon. Here we analyse three-dimensional cryo-electron microscopy maps of the Escherichia coli 70S ribosome in various functional states, and show that both EF-G binding and subsequent GTP hydrolysis lead to ratchet-like rotations of the small 30S subunit relative to the large 50S subunit. Furthermore, our finding indicates a two-step mechanism of translocation: first, relative rotation of the subunits and opening of the mRNA channel following binding of GTP to EF-G; and second, advance of the mRNA/(tRNA)2 complex in the direction of the rotation of the 30S subunit, following GTP hydrolysis.

Solution structure of the E. coli 70S ribosome at 11.5 A resolution.

Over 73,000 projections of the E. coli ribosome bound with formyl-methionyl initiator tRNAf(Met) were used to obtain an 11.5 A cryo-electron microscopy map of the complex. This map allows identification of RNA helices, peripheral proteins, and intersubunit bridges. Comparison of double-stranded RNA regions and positions of proteins identified in both cryo-EM and X-ray maps indicates good overall agreement but points to rearrangements of ribosomal components required for the subunit association. Fitting of known components of the 50S stalk base region into the map defines the architecture of the GTPase-associated center and reveals a major change in the orientation of the alpha-sarcin-ricin loop. Analysis of the bridging connections between the subunits provides insight into the dynamic signaling mechanism between the ribosomal subunits.

EF-G-dependent GTP hydrolysis induces translocation accompanied by large conformational changes in the 70S ribosome

Cryo-electron microscopy has been used to visualize elongation factor G (EF-G) on the 70S ribosome in GDP and GTP states. GTP hydrolysis is required for binding of all the domains of EF-G to the pretranslocational complex and for the completion of translocation. In addition, large conformational changes have been identified in the ribosome. The head of the 30S subunit shifts toward the L1 protein side, and the L7/L12 stalk becomes bifurcated upon EF-G binding. Upon GTP hydrolysis, the bifurcation is reversed and an arc-like connection is formed between the base of the stalk and EF-G.

Cryo-EM reveals an active role for aminoacyl-tRNA in the accommodation process.

During the elongation cycle of protein biosynthesis, the specific amino acid coded for by the mRNA is delivered by a complex that is comprised of the cognate aminoacyl‐tRNA, elongation factor Tu and GTP. As this ternary complex binds to the ribosome, the anticodon end of the tRNA reaches the decoding center in the 30S subunit. Here we present the cryo‐ electron microscopy (EM) study of an Escherichia coli 70S ribosome‐bound ternary complex stalled with an antibiotic, kirromycin. In the cryo‐EM map the anticodon arm of the tRNA presents a new conformation that appears to facilitate the initial codon–anticodon interaction. Furthermore, the elbow region of the tRNA is seen to contact the GTPase‐associated center on the 50S subunit of the ribosome, suggesting an active role of the tRNA in the transmission of the signal prompting the GTP hydrolysis upon codon recognition.

Structure of the Mammalian Mitochondrial Ribosome Reveals an Expanded Functional Role for Its Component Proteins

The mitochondrial ribosome is responsible for the biosynthesis of protein components crucial to the generation of ATP in the eukaryotic cell. Because the protein:RNA ratio in the mitochondrial ribosome (approximately 69:approximately 31) is the inverse of that of its prokaryotic counterpart (approximately 33:approximately 67), it was thought that the additional and/or larger proteins of the mitochondrial ribosome must compensate for the shortened rRNAs. Here, we present a three-dimensional cryo-electron microscopic map of the mammalian mitochondrial 55S ribosome carrying a tRNA at its P site, and we find that instead, many of the proteins occupy new positions in the ribosome. Furthermore, unlike cytoplasmic ribosomes, the mitochondrial ribosome possesses intersubunit bridges composed largely of proteins; it has a gatelike structure at its mRNA entrance, perhaps involved in recruiting unique mitochondrial mRNAs; and it has a polypeptide exit tunnel that allows access to the solvent before the exit site, suggesting a unique nascent-polypeptide exit mechanism.

Study of the Structural Dynamics of the E. coli 70S Ribosome Using Real-Space Refinement

Cryo-EM density maps showing the 70S ribosome of E. coli in two different functional states related by a ratchet-like motion were analyzed using real-space refinement. Comparison of the two resulting atomic models shows that the ribosome changes from a compact structure to a looser one, coupled with the rearrangement of many of the proteins. Furthermore, in contrast to the unchanged inter-subunit bridges formed wholly by RNA, the bridges involving proteins undergo large conformational changes following the ratchet-like motion, suggesting an important role of ribosomal proteins in facilitating the dynamics of translation.

Direct Visualization of A-, P-, and E-Site Transfer RNAs in the Escherichia coli Ribosome

Transfer RNA (tRNA) molecules play a crucial role in protein biosynthesis in all organisms. Their interactions with ribosomes mediate the translation of genetic messages into polypeptides. Three tRNAs bound to the Escherichia coli 70S ribosome were visualized directly with cryoelectron microscopy and three-dimensional reconstruction. The detailed arrangement of A- and P-site tRNAs inferred from this study allows localization of the sites for anticodon interaction and peptide bond formation on the ribosome.

[19] Preparation of functional ribosomal complexes and effect of buffer conditions on tRNA positions observed by cryoelectron microscopy

Publisher Summary This chapter discusses the isolation of the ribosomes and the preparation of functional complexes and provides an overview of the possibilities for analyzing ribosomal complexes. It summarizes and discusses the results of recent cryoelectron microscopy studies that reflect the effect of buffer conditions. Studies have established that the ribosome has three transfer RNA (tRNA) binding sites, but 3-D cryo-electron microscopy (EM) has revealed five different tRNA positions on the ribosome, classified as A, P, P/E, E, and E2. The occupancy of some of these positions strongly depends on the buffer conditions used and the charge state of the tRNA. In the presence of the polyamine buffer, mimicking the in vivo conditions, only occupancy of A, P, and E sites are observed in complexes of the initiating and elongating ribosomes. The procedure described in the chapter for the small-scale isolation of tightly coupled ribosomes yields highly active and intact ribosomes, an important prerequisite for the preparation of functional complexes. The chapter describes the isolation of ribosomal subunits that can be used to prepare reassociated ribosomes. Reassociated ribosomes show a more efficient tRNA binding as compared to tightly coupled ribosomes, because the saturation of tRNA binding is reached at molar ratios slightly above stoichiometric ones. This can be attributed to at least two factors: (1) a selective pressure for active particles in the reassociation step and (2) the loss of residual amounts of tRNAs and of mitochondrial RNA (mRNA) fragments.

Three‐dimensional cryo‐electron microscopy localization of EF2 in the Saccharomyces cerevisiae 80S ribosome at 17.5 Å resolution

Using a sordarin derivative, an antifungal drug, it was possible to determine the structure of a eukaryotic ribosome·EF2 complex at 17.5 Å resolution by three‐dimensional (3D) cryo‐electron microscopy. EF2 is directly visible in the 3D map and the overall arrangement of the complex from Saccharomyces cerevisiae corresponds to that previously seen in Escherichia coli. However, pronounced differences were found in two prominent regions. First, in the yeast system the interaction between the elongation factor and the stalk region of the large subunit is much more extensive. Secondly, domain IV of EF2 contains additional mass that appears to interact with the head of the 40S subunit and the region of the main bridge of the 60S subunit. The shape and position of domain IV of EF2 suggest that it might interact directly with P‐site‐bound tRNA.

Modeling a Minimal Ribosome Based on Comparative Sequence Analysis

We have determined the three-dimensional organization of ribosomal RNAs and proteins essential for minimal ribosome function. Comparative sequence analysis identifies regions of the ribosome that have been evolutionarily conserved, and the spatial organization of conserved domains is determined by mapping these onto structures of the 30S and 50S subunits determined by X-ray crystallography. Several functional domains of the ribosome are conserved in their three-dimensional organization in the Archaea, Bacteria, Eucaryotic nuclear, mitochondria and chloroplast ribosomes. In contrast, other regions from both subunits have shifted their position in three-dimensional space during evolution, including the L11 binding domain and the alpha-sarcin-ricin loop (SRL). We examined conserved bridge interactions between the two ribosomal subunits, giving an indication of which contacts are more significant. The tRNA contacts that are conserved were also determined, highlighting functional interactions as the tRNA moves through the ribosome during protein synthesis. To augment these studies of a large collection of comparative structural models sampled from all major branches on the phylogenetic tree, Caenorhabditis elegans mitochondrial rRNA is considered individually because it is among the smallest rRNA sequences known. The C.elegans model supports the large collection of comparative structure models while providing insight into the evolution of mitochondrial ribosomes.