Following the dynamics of changes in solvent accessibility of 16 S and 23 S rRNA during ribosomal subunit association using synchrotron-generated hydroxyl radicals

We have probed the structure and dynamics of ribosomal RNA in the Escherichia coli ribosome using equilibrium and time-resolved hydroxyl radical (OH) RNA footprinting to explore changes in the solvent-accessible surface of the rRNA with single-nucleotide resolution. The goal of these studies is to better understand the structural transitions that accompany association of the 30 S and 50 S subunits and to build a foundation for the quantitative analysis of ribosome structural dynamics during translation. Clear portraits of the subunit interface surfaces for 16 S and 23 S rRNA were obtained by constructing difference maps between the OH protection maps of the free subunits and that of the associated ribosome. In addition to inter-subunit contacts consistent with the crystal structure, additional OH protections are evident in regions at or near the subunit interface that reflect association-induced conformational changes. Comparison of these data with the comparable difference maps of the solvent-accessible surface of the rRNA calculated for the Thermus thermophilus X-ray crystal structures shows extensive agreement but also distinct differences. As a prelude to time-resolved OH footprinting studies, the reactivity profiles obtained using Fe(II)EDTA and X-ray generated OH were comprehensively compared. The reactivity patterns are similar except for a small number of nucleotides that have decreased reactivity to OH generated from Fe(II)EDTA compared to X-rays. These nucleotides are generally close to ribosomal proteins, which can quench diffusing radicals by virtue of side-chain oxidation. Synchrotron X-ray OH footprinting was used to monitor the kinetics of association of the 30 S and 50 S subunits. The rates individually measured for the inter-subunit contacts are comparable within experimental error. The application of this approach to the study of ribosome dynamics during the translation cycle is discussed.     

Dynamic binding of PKA regulatory subunit RI alpha

Recent crystal structures have revealed that regulatory subunit RIalpha of PKA undergoes a dramatic conformational change upon complex formation with the catalytic subunit. Molecular dynamics studies were initiated to elucidate the contributions of intrinsic conformational flexibility and interactions with the catalytic subunit in formation and stabilization of the complex. Simulations of a single RIalpha nucleotide binding domain (NBD), missing cAMP, showed that its C helix spontaneously occupies two distinct conformations: either packed against the nucleotide binding domain as in its cAMP bound structure, or extended into an intermediate form resembling that of the holoenzyme structure. C helix extension was not seen in a simulation of either RIalpha NBD. In a model complex containing both NBDs and the catalytic subunit, well-conserved residues at the interface between the NBDs in the cAMP bound form were found to stabilize the complex through contacts with the catalytic subunit. The model structure is consistent with available experimental data.     

Subunit asymmetry in the three-dimensional structure of a human CuZnSOD mutant found in familial amyotrophic lateral sclerosis.

The X-ray crystal structure of a human copper/zinc superoxide dismutase mutant (G37R CuZnSOD) found in some patients with the inherited form of Lou Gehrig's disease (FALS) has been determined to 1.9 angstroms resolution. The two SOD subunits have distinct environments in the crystal and are different in structure at their copper binding sites. One subunit (subunit[intact]) shows a four-coordinate ligand geometry of the copper ion, whereas the other subunit (subunit[broken]) shows a three-coordinate geometry of the copper ion. Also, subunit(intact) displays higher atomic displacement parameters for backbone atoms ((B) = 30 +/- 10 angstroms2) than subunit(broken) ((B) = 24 +/- 11 angstroms2). This structure is the first CuZnSOD to show large differences between the two subunits. Factors that may contribute to these differences are discussed and a possible link of a looser structure to FALS is suggested.     

Solvent protection of the hammerhead ribozyme in the ground state: evidence for a cation-assisted conformational change leading to catalysis

Tertiary folding of the hammerhead ribozyme has been analyzed by hydroxyl radical footprinting. Three hammerhead constructs with distinct noncore sequences, connectivities, and catalytic properties show identical protection patterns, in which conserved core residues (G5, A6, U7, G8, and A9) and the cleavage site (C17, G1.1, and U1.2) become reproducibly protected from nucleolytic attack by radicals. Metal ion titrations show that all protections appear together, suggesting a single folding event to a common tertiary structure, rather than an ensemble of different folds. The apparent binding constants for folding and catalysis by Mg(2+) are lower than those for Li(+) by 3 orders of magnitude, but in each case the protected sites are identical. For both Mg(2+) and Li(+), the ribozyme folds into the protected tertiary structure at significantly lower cation concentrations than those required for cleavage. The sites of protection include all of the sites of reduced solvent accessibility calculated from two different crystal structures, including both core and noncore nucleotides. In addition, experimentally observed protected sites include additional sequences adjacent to those predicted by the crystal structures, suggesting that the solution structure may be folded into a more compact shape. A 2'-deoxy substitution at G5 abolishes all protection, indicating that the 2'-OH is essential for folding. Together, these results support a model in which low concentrations of metal ions fold the ribozyme into a stable ground state tertiary structure that is similar to the crystallographic structures, and higher concentrations of metal ions support a transient conformational change into the transition state for catalysis. These data do not themselves address the issue as to whether a large- or small-scale conformational change is required for catalysis.     

The central loop of Escherichia coli glutamine synthetase is flexible and functionally passive

Bacterial glutamine synthetases (GSs) are dodecameric aggregates comprised of two face-to-face hexameric rings, which form a cylindrical aqueous channel. Available crystal structures indicate that each subunit provides a 'central loop' that protrudes into this channel. Residues on either side of this loop contribute directly to substrate or metal ion cofactor binding. Although it has been suggested that this conspicuous structural feature may be functionally important, a systematic structure-function analysis of this loop has not been done. Here, we examine the behavior of a cysteine mutant, E165C, which yields inter-subunit disulfide bonds connecting the central loops. The inter-subunit disulfide bonds are readily detected by electrospray ionization mass spectrometry. Based on molecular models, the disulfide bonds would form only if the engineered cysteines on adjacent subunits moved approximately 5 A. Surprisingly, inter-subunit disulfide bonds between the central loops caused no detectable changes in the KMs for glutamate or ATP, nor the KD for either ATP or the transition state analog (L)-methionine sulfoximine (MSOX). Furthermore, covalent and quantitative adduction of the E165C mutant with iodo-acetamido-pyrene yielded nearly fully active enzyme bearing fluorescent pyrene excimers. The relative contribution of pyrene monomers to excimers in the steady state fluorescence is temperature dependent, suggesting thermal equilibrium between loop conformational states. However, the monomer-excimer ratio is independent of ligands such as MSOX, glutamate, or Mn2+. These results validate the suspected flexibility of the central loop, but raise significant doubt about its direct functional role in GS catalysis via conformational switching, including the proposed regulation of GS via ADP-ribosylation within this loop.     

Unexpected plasticity of the quaternary structure of iron-manganese superoxide dismutases

Protein 3D structure can be remarkably robust to the accumulation of mutations during evolution. On the other hand, sometimes a single amino acid substitution can be sufficient to generate dramatic and completely unpredictable structural consequences. In an attempt to rationally alter the preferences for the metal ion at the active site of a member of the Iron/Manganese superoxide dismutase family, two examples of the latter phenomenon were identified. Site directed mutants of SOD from Trichoderma reesei were generated and studied crystallographically together with the wild type enzyme. Despite being chosen for their potential impact on the redox potential of the metal, two of the mutations (D150G and G73A) in fact resulted in significant alterations to the protein quaternary structure. The D150G mutant presented alternative inter-subunit contacts leading to a loss of symmetry of the wild type tetramer, whereas the G73A mutation transformed the tetramer into an octamer despite not participating directly in any of the inter-subunit interfaces. We conclude that there is considerable intrinsic plasticity in the Fe/MnSOD fold that can be unpredictably affected by single amino acid substitutions. In much the same way as phenotypic defects at the organism level can reveal much about normal function, so too can such mutations teach us much about the subtleties of protein structure.     

Crystal structure analysis of the exocytosis-sensitive phosphoprotein, pp63/parafusin (phosphoglucomutase), from Paramecium reveals significant conformational variability.

During exocytosis of dense-core secretory vesicles (trichocysts) in Paramecium, the protein pp63/parafusin (pp63/pf) is transiently dephosphorylated. We report here the structures of two crystal forms of one isoform of this protein which has a high degree of homology with rabbit phosphoglucomutase, whose structure has been reported. As expected, both proteins possess highly similar structures, showing the same four domains forming two lobes with an active-site crevice in between. The two X-ray structures that we report here were determined after crystallization in the presence of sulfate and tartrate, and show the lobes arranged as a closed and an open conformation, respectively. While both conformations possess a bound divalent cation, only the closed (sulfate-bound) conformation shows bound sulfate ions in the "phosphate-transfer site" near the catalytic serine residue and in the "phosphate-binding site". Comparison with the open form shows that the latter dianion is placed in the centre of three arginine residues, one contributed by subunit II and two by subunit IV, suggesting that it causes a contraction of the arginine triangle, which establishes the observed conformational closure of the lobes. It is therefore likely that the closed conformation forms only when a phosphoryl group is bound to the phosphate-binding site. The previously published structure of rabbit phosphoglucomutase is intermediate between these two conformers. Several of the known reversible phosphorylation sites of pp63/pf-1 are at positions critical for transition between the conformations and for binding of the ligands and thus give hints as to possible roles of pp63/pf-1 in the course of exocytosis.     

Magnesium dependence of the amplified conformational switch in the trans-acting hepatitis delta virus ribozyme

The ability of divalent metal ions to participate in both structure formation and catalytic chemistry of RNA enzymes (ribozymes) has made it difficult to separate their cause and effect in ribozyme function. For example, the recently solved crystal structures of precursor and product forms of the cis-cleaving genomic hepatitis delta virus (HDV) ribozyme show a divalent metal ion bound in the active site that is released upon catalysis due to an RNA conformational change. This conformational switch is associated with a repositioning of the catalytically involved base C75 in the active-site cleft, thus controlling catalysis. These findings confirm previous data from fluorescence resonance energy transfer (FRET) on a trans-acting form of the HDV ribozyme that found a global conformational change to accompany catalysis. Here, we further test the conformational switch model by measuring the Mg(2+) dependence of the global conformational change of the trans-acting HDV ribozyme, using circular dichroism and time-resolved FRET as complementary probes of secondary and tertiary structure formation, respectively. We observe significant differences in both structure and Mg(2+) affinity of the precursor and product forms, in the presence and absence of 300 mM Na(+) background. The precursor shortens while the product extends with increasing Mg(2+) concentration, essentially amplifying the structural differences observed in the crystal structures. In addition, the precursor has an approximately 2-fold and approximately 13-fold lower Mg(2+) affinity than the product in secondary and tertiary structure formation, respectively. We also have compared the C75 wild-type with the catalytically inactive C75U mutant and find significant differences in global structure and Mg(2+) affinity for both their precursor and product forms. Significantly, the Mg(2+) affinity of the C75 wild-type is 1.7-2.1-fold lower than that of the C75U mutant, in accord with the notion that C75 is essential for a catalytic conformational change that leads to a decrease in the local divalent metal ion affinity and release of a catalytic metal. Thus, a consistent picture emerges in which divalent metal ions and RNA functional groups are intimately intertwined in affecting structural dynamics and catalysis in the HDV ribozyme.     

Arginine-induced conformational change in the c-ring/a-subunit interface of ATP synthase

The rotational mechanism of ATP synthases requires a unique interface between the stator a subunit and the rotating c-ring to accommodate stability and smooth rotation simultaneously. The recently published c-ring crystal structure of the ATP synthase of Ilyobacter tartaricus represents the conformation in the absence of subunit a. However, in order to understand the dynamic structural processes during ion translocation, studies in the presence of subunit a are required. Here, by intersubunit Cys-Cys cross-linking, the relative topography of the interacting helical faces of subunits a and c from the I. tartaricus ATP synthase has been mapped. According to these data, the essential stator arginine (aR226) is located between the c-ring binding pocket and the cytoplasm. Furthermore, the spatially vicinal residues cT67C and cG68C in the isolated c-ring structure yielded largely asymmetric cross-linking products with aN230C of subunit a, suggesting a small, but significant conformational change of binding-site residues upon contact with subunit a. The conformational change was dependent on the positive charge of the stator arginine or the aR226H substitution. Energy-minimization calculations revealed possible modes for the interaction between the stator arginine and the c-ring. These biochemical results and structural restraints support a model in which the stator arginine operates as a pendulum, moving in and out of the binding pocket as the c-ring rotates along the interface with subunit a. This mechanism allows efficient interaction between subunit a and the c-ring and simultaneously allows almost frictionless movement against each other.     

Crystal Structures of a Group II Chaperonin Reveal the Open and Closed States Associated with the Protein Folding Cycle

Chaperonins are large protein complexes consisting of two stacked multisubunit rings, which open and close in an ATP-dependent manner to create a protected environment for protein folding. Here, we describe the first crystal structure of a group II chaperonin in an open conformation. We have obtained structures of the archaeal chaperonin from Methanococcus maripaludis in both a peptide acceptor (open) state and a protein folding (closed) state. In contrast with group I chaperonins, in which the equatorial domains share a similar conformation between the open and closed states and the largest motions occurs at the intermediate and apical domains, the three domains of the archaeal chaperonin subunit reorient as a single rigid body. The large rotation observed from the open state to the closed state results in a 65% decrease of the folding chamber volume and creates a highly hydrophilic surface inside the cage. These results suggest a completely distinct closing mechanism in the group II chaperonins as compared with the group I chaperonins.     

NMR studies on the substrate-binding domains of the thermosome: structural plasticity in the protrusion region

Group II chaperonins close their cavity with the help of conserved, helical extensions, the so-called protrusions, which emanate from the apical or substrate-binding domains. A comparison of previously solved crystal structures of the apical domains of the thermosome from Thermoplasma acidophilum showed structural plasticity in the protrusion parts induced by extensive packing interactions. In order to assess the influence of the crystal contacts we investigated both the alpha and beta-apical domains (alpha-ADT and beta-ADT) in solution by NMR spectroscopy. Secondary structure assignments and 15N backbone relaxation measurements showed mostly rigid structural elements in the globular parts of the domains, but revealed intrinsic structural disorder and partial helix fraying in the protrusion regions. On the other hand, a beta-turn-motif conserved in archaeal group II chaperonins might facilitate substrate recognition. Our results help us to specify the idea of the open, substrate-accepting state of the thermosome and may provide an additional jigsaw piece in understanding the mode of substrate binding of group II chaperonins.     

Molecular dynamics of the P450cam–Pdx complex reveals complex stability and novel interface contacts

Cytochrome P450cam catalyzes the stereo and regiospecific hydroxylation of camphor to 5‐exo‐hydroxylcamphor. The two electrons for the oxidation of camphor are provided by putidaredoxin (Pdx), a Fe₂S₂ containing protein. Two recent crystal structures of the P450cam–Pdx complex, one solved with the aid of covalent cross‐linking and one without, have provided a structural picture of the redox partner interaction. To study the stability of the complex structure and the minor differences between the recent crystal structures, a 100 nanosecond molecular dynamics (MD) simulation of the cross‐linked structure, mutated in silico to wild type and the linker molecule removed, was performed. The complex was stable over the course of the simulation though conformational changes including the movement of the C helix of P450cam further toward Pdx allowed for the formation of a number of new contacts at the complex interface that remained stable throughout the simulation. While several minor crystal contacts were lost in the simulation, all major contacts that had been experimentally studied previously were maintained. The equilibrated MD structure contained a mixture of contacts resembling both the cross‐linked and noncovalent structures and the newly identified interactions. Finally, the reformation of the P450cam Asp251–Arg186 ion pair in the MD simulation mirrors the ion pair observed in the more promiscuous CYP101D1 and suggests that the Asp251–Arg186 ion pair may be important.     

Evidence for structural integrity in the undecameric c-rings isolated from sodium ATP synthases

The Na(+)-translocating ATP synthases from Ilyobacter tartaricus and Propionigenium modestum contain undecameric c subunit rings of unusual stability. These c(11) rings have been isolated from both ATP synthases and crystallized in two dimensions. Cryo-transmission electron microscopy projection maps of the c-rings from both organisms were identical at 7A resolution. Different crystal contacts were induced after treatment of the crystals with dicyclohexylcarbodiimide (DCCD), which is consistent with the binding of the inhibitor to glutamate 65 in the C-terminal helix on the outside of the ring. The c subunits of the isolated c(11) ring of I.tartaricus were modified specifically by incubation with DCCD with kinetics that were indistinguishable from those of the F(1)F(o) holoenzyme. The reaction rate increased with decreasing pH but was lower in the presence of Na(+). From the pH profile of the second-order rate constants, the pK of glutamate 65 was deduced to be 6.6 or 6.2 in the absence or presence of 0.5mM NaCl, respectively. These pK values are identical with those determined for the F(1)F(o) complex. The results indicate that the isolated c-ring retains its native structure, and that the glutamate 65, including binding sites near the middle of the membrane, are accessible to Na(+) from the cytoplasm through access channels within the c-ring itself.     

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.     

The crystal structure of the "open" and the "closed" conformation of the flexible loop of trypanosomal triosephosphate isomerase

Triosephosphate isomerase has an important loop near the active site which can exist in a "closed" and in an "open" conformation. Here we describe the structural properties of this "flexible" loop observed in two different structures of trypanosomal triosephosphate isomerase. Trypanosomal triosephosphate isomerase, crystallized in the presence of 2.4 M ammonium sulfate, packs as an asymmetric dimer of 54,000 Da in the crystallographic asymmetric unit. Due to different crystal contacts, peptide 167-180 (the flexible loop of subunit-1) is an open conformation, whereas in subunit-2, this peptide (residues 467-480) is in a closed conformation. In the closed conformation, a hydrogen bond exists between the tip of the loop and a well-defined sulfate ion which is bound to the active site of subunit-2. Such an active site sulfate is not present in subunit-1 due to crystal contacts. When the native (2.4 M ammonium sulfate) crystals are transferred to a sulfate-free mother liquor, the flexible loop of subunit-2 adopts the open conformation. From a closed starting model, this open conformation was discovered through molecular dynamics refinement without manual intervention, despite involving C alpha shifts of up to 7 A. The tip of the loop, residues 472, 473, 474, and 475, moves as a rigid body. Our analysis shows that in this crystal form the flexible loop of subunit-2 faces a solvent channel. Therefore the open and the closed conformations of this flexible loop are virtually unaffected by crystal contacts. The actual observed conformation depends only on the absence or presence of a suitable ligand in the active site.     

Tracing the evolution of RNA structure in ribosomes

The elucidation of ribosomal structure has shown that the function of ribosomes is fundamentally confined to dynamic interactions established between the RNA components of the ribosomal ensemble. These findings now enable a detailed analysis of the evolution of ribosomal RNA (rRNA) structure. The origin and diversification of rRNA was studied here using phylogenetic tools directly at the structural level. A rooted universal tree was reconstructed from the combined secondary structures of large (LSU) and small (SSU) subunit rRNA using cladistic methods and considerations in statistical mechanics. The evolution of the complete repertoire of structural ribosomal characters was formally traced lineage-by-lineage in the tree, showing a tendency towards molecular simplification and a homogeneous reduction of ribosomal structural change with time. Character tracing revealed patterns of evolution in inter-subunit bridge contacts and tRNA-binding sites that were consistent with the proposed coupling of tRNA translocation and subunit movement. These patterns support the concerted evolution of tRNA-binding sites in the two subunits and the ancestral nature and common origin of certain structural ribosomal features, such as the peptidyl (P) site, the functional relay of the penultimate stem helix of SSU rRNA, and other structures participating in ribosomal dynamics. Overall results provide a rare insight into the evolution of ribosomal structure.     

Crystal Structures of the Substrate-Bound Forms of Red Chlorophyll Catabolite Reductase: Implications for Site-Specific and Stereospecific Reaction

Red chlorophyll catabolite reductase (RCCR) catalyzes the ferredoxin-dependent reduction of the C20/C1 double bond of red chlorophyll catabolite (RCC), the catabolic intermediate produced in chlorophyll degradation. The crystal structure of substrate-free Arabidopsis thaliana RCCR (AtRCCR) demonstrated that RCCR folds into a characteristic α/β/α sandwich, similar to that observed in the ferredoxin-dependent bilin reductase (FDBR) family. Here we have determined the crystal structures of RCC-bound AtRCCR, RCC-bound F218V AtRCCR, and substrate-free F218V AtRCCR, a mutant protein that produces the stereoisomer of primary fluorescent chlorophyll catabolites at the C1 position. RCC is bound to the pocket between the β-sheet and the C-terminal α-helices, as seen in substrate-bound FDBRs, but RCC binding to RCCR is much looser than substrate binding to FDBRs. The loose binding seems beneficial to the large conformational change in RCC upon reduction. Two conserved acidic residues, Glu154 and Asp291, sandwich the C20/C1 double bond of RCC, suggesting that these two residues are involved in site-specific reduction. The RCC in F218V AtRCCR rotates slightly compared with that in wild type to fill in the space generated by the substitution of Phe218 with valine. Concomitantly, the two carboxy groups of Glu154 and Asp291 move slightly away from the C20/C1 double bond. The geometrical arrangement of RCC and the carboxy groups of Glu154 and Asp291 in RCCR would appear to be essential for the stereospecificity of the RCCR reaction.     

Crystal structures of thermostable xylose isomerases from Thermus caldophilus and Thermus thermophilus: possible structural determinants of thermostability.

The crystal structures of highly thermostable xylose isomerases from Thermus thermophilus (TthXI) and Thermus caldophilus (TcaXI), both with the optimum reaction temperature of 90 degrees C, have been determined by X-ray crystallography. The model of TcaXI has been refined to an R-factor of 17.8 % for data extending to 2.3 A and that of TthXI to 17.1 % for data extending to 2.2 A. The tetrameric arrangement of subunits characterized by the 222-symmetry and the tertiary fold of each subunit in both TcaXI and TthXI are basically the same as in other xylose isomerases. Each monomer is composed of two domains. Domain I (residues 1 to 321) folds into the (beta/alpha)8-barrel. Domain II (residues 322 to 387), lacking beta-strands, makes extensive contacts with domain I of an adjacent subunit. Each monomer of TcaXI contains ten beta-strands, 15 alpha-helices, and six 310-helices, while that of TthXI contains ten beta-strands, 16 alpha-helices, and five 310-helices. Although the electron density does not indicate the presence of bound metal ions in the present models of both TcaXI and TthXI, the active site residues show the conserved structural features. In order to understand the structural basis for thermostability of these enzymes, their structures have been compared with less thermostable XIs from Arthrobacter B3728 and Actinoplanes missouriensis (AXI and AmiXI), with the optimum reaction temperatures of 80 degrees C and 75 degrees C, respectively. Analyses of various factors that may affect protein thermostability indicate that the possible structural determinants of the enhanced thermostability of TcaXI/TthXI over AXI/AmiXI are (i) an increase in ion pairs and ion-pair networks, (ii) a decrease in the large inter-subunit cavities, (iii) a removal of potential deamidation/isoaspartate formation sites, and (iv) a shortened loop.     

Ribosome-small-subunit-dependent GTPase interacts with tRNA-binding sites on the ribosome

RsgA (ribosome-small-subunit-dependent GTPase A, also known as YjeQ) is a unique GTPase in that guanosine triphosphate hydrolytic activity is activated by the small subunit of the ribosome. Disruption of the gene for RsgA from the genome affects the growth of cells, the subunit association of the ribosome, and the maturation of 16S rRNA. To study the interaction of Escherichia coli RsgA with the ribosome, chemical modifications using dimethylsulfate and kethoxal were performed on the small subunit in the presence or in the absence of RsgA. The chemical reactivities at G530, A790, G925, G926, G966, C1054, G1339, G1405, A1413, and A1493 in 16S rRNA were reduced, while those at A532, A923, G1392, A1408, A1468, and A1483 were enhanced, by the addition of RsgA, together with 5′-guanylylimidodiphosphate. Among them, the chemical reactivities at A532, A790, A923, G925, G926, C1054, G1392, A1413, A1468, A1483, and A1493 were not changed when RsgA was added together with GDP. These results indicate that the binding of RsgA induces conformational changes around the A site, P site, and helix 44, and that guanosine triphosphate hydrolysis induces partial conformational restoration, especially in the head, to dissociate RsgA from the small subunit. RsgA has the capacity to coexist with mRNA in the ribosome while it promotes dissociation of tRNA from the ribosome.     

HCV IRES interacts with the 18S rRNA to activate the 40S ribosome for subsequent steps of translation initiation

Previous analyses of complexes of 40S ribosomal subunits with the hepatitis C virus (HCV) internal ribosome entry site (IRES) have revealed contacts made by the IRES with ribosomal proteins. Here, using chemical probing, we show that the HCV IRES also contacts the backbone and bases of the CCC triplet in the 18S ribosomal RNA (rRNA) expansion segment 7. These contacts presumably provide interplay between IRES domain II and the AUG codon close to ribosomal protein S5, which causes a rearrangement of 18S rRNA structure in the vicinity of the universally conserved nucleotide G1639. As a result, G1639 becomes exposed and the corresponding site of the 40S subunit implicated in transfer RNA discrimination can select . These data are the first demonstration at nucleotide resolution of direct IRES–rRNA interactions and how they induce conformational transition in the 40S subunit allowing the HCV IRES to function without AUG recognition initiation factors.