Mapping the ribosomal RNA neighborhood of protein L11 by directed hydroxyl radical probing

Using an L7Ae-Tethered, Hydroxyl Radical-Mediated Footprinting Strategy to Identify and Validate Kink-Turns in RNAs

Kink-turns are important RNA structural modules that facilitate long-range tertiary interactions and form binding sites for members of the L7Ae family of proteins. Present in a wide variety of functional RNAs, kink-turns play key organizational roles in many RNA-based cellular processes, including translation, modification, and tRNA biogenesis. It is important to determine the contribution of kink-turns to the overall architecture of resident RNAs, as these modules dictate ribonucleoprotein (RNP) assembly and function. This chapter describes a site-directed, hydroxyl radical-mediated footprinting strategy that utilizes L7Ae-tethered chemical nucleases to experimentally validate computationally identified kink-turns in any RNA and under a wide variety of conditions. The work plan described here uses the catalytic RNase P RNA as an example to provide a blueprint for using this footprinting method to map RNA-protein interactions in other RNP complexes.

Divalent ions tune the kinetics of a bacterial GTPase center rRNA folding transition from secondary to tertiary structure

Folding of an RNA from secondary to tertiary structure often depends on divalent ions for efficient electrostatic charge screening (nonspecific association) or binding (specific association). To measure how different divalent cations modify folding kinetics of the 60 nucleotide Ecoli rRNA GTPase center, we combined stopped-flow fluorescence in the presence of Mg²⁺, Ca²⁺, or Sr²⁺ together with time-resolved small angle X-ray scattering (SAXS) in the presence of Mg²⁺ to observe the folding process. Immediately upon addition of each divalent ion, the RNA undergoes a transition from an extended state with secondary structure to a more compact structure. Subsequently, specific divalent ions modulate populations of intermediates in conformational ensembles along the folding pathway with transition times longer than 10 msec. Rate constants for the five folding transitions act on timescales from submillisecond to tens of seconds. The sensitivity of RNA tertiary structure to divalent cation identity affects all but the fastest events in RNA folding, and allowed us to identify those states that prefer Mg²⁺ The GTPase center RNA appears to have optimized its folding trajectory to specifically utilize this most abundant intracellular divalent ion.

Dynamics of ribosomes and release factors during translation termination in E. coli

Release factors RF1 and RF2 promote hydrolysis of peptidyl-tRNA during translation termination. The GTPase RF3 promotes recycling of RF1 and RF2. Using single molecule FRET and biochemical assays, we show that ribosome termination complexes that carry two factors, RF1–RF3 or RF2–RF3, are dynamic and fluctuate between non-rotated and rotated states, whereas each factor alone has its distinct signature on ribosome dynamics and conformation. Dissociation of RF1 depends on peptide release and the presence of RF3, whereas RF2 can dissociate spontaneously. RF3 binds in the GTP-bound state and can rapidly dissociate without GTP hydrolysis from termination complex carrying RF1. In the absence of RF1, RF3 is stalled on ribosomes if GTP hydrolysis is blocked. Our data suggest how the assembly of the ribosome–RF1–RF3–GTP complex, peptide release, and ribosome fluctuations promote termination of protein synthesis and recycling of the release factors.

Inside cells, molecular machines called ribosomes make proteins using messenger RNA as a template. However, the template contains more than just the information needed to create the protein. A ‘stop codon’ in the mRNA marks where the ribosome should stop. When this is reached a group of proteins called release factors removes the newly made protein from the ribosome.

Bacteria typically have three types of release factors. RF1 and RF2 recognize the stop codon, and RF3 helps to release RF1 or RF2 from the ribosome so that it can be recycled to produce another protein. It was not fully understood how the release factors interact with the ribosome and how this terminates protein synthesis.

Adio et al. used TIRF microscopy to study individual ribosomes from the commonly studied bacteria species Escherichia coli. This technique allows researchers to monitor movements of the ribosome and record how release factors bind to it. The results of the experiments performed by Adio et al. show that although RF1 and RF2 are very similar to each other, they interact with the ribosome in different ways. In addition, only RF1 relies upon RF3 to release it from the ribosome; RF2 can release itself. RF3 releases RF1 by forcing the ribosome to change shape. RF3 then uses energy produced by the breakdown of a molecule called GTP to help release itself from the ribosome.

Most importantly, the findings presented by Adio et al. highlight that the movements of ribosomes and release factors during termination are only loosely coupled rather than occur in a set order. Other molecular machines are likely to work in a similar way. The results could also help us to understand the molecular basis of several human diseases, such as Duchenne muscular dystrophy and cystic fibrosis, that result from ribosomes not recognizing stop codons in the mRNA.

Dual Targeting of the Protein Methyltransferase PrmA Contributes to Both Chloroplastic and Mitochondrial Ribosomal Protein L11 Methylation in Arabidopsis

Methylation of ribosomal proteins has long been described in prokaryotes and eukaryotes, but our knowledge about the enzymes responsible for these modifications in plants is scarce. The bacterial protein methyltransferase PrmA catalyzes the trimethylation of ribosomal protein L11 (RPL11) at three distinct sites. The role of these modifications is still unknown. Here, we show that PrmA from Arabidopsis thaliana (AtPrmA) is dually targeted to chloroplasts and mitochondria. Mass spectrometry and enzymatic assays indicated that the enzyme methylates RPL11 in plasto- and mitoribosomes in vivo. We determined that the Arabidopsis and Escherichia coli PrmA enzymes share similar product specificity, making trimethylated residues, but, despite an evolutionary relationship, display a difference in substrate site specificity. In contrast to the bacterial enzyme that trimethylates the ε-amino group of two lysine residues and the N-terminal α-amino group, AtPrmA methylates only one lysine in the MAFCK(D/E)(F/Y)NA motif of plastidial and mitochondrial RPL11. The plant enzyme possibly methylates the N-terminus of plastidial RPL11, whereas mitochondrial RPL11 is N-α-acetylated by an unknown acetyltransferase. Lastly, we found that an Arabidopsis prma-null mutant is viable in standard environmental conditions and no molecular defect could be associated with a lack of RPL11 methylation in leaf chloroplasts or mitochondria. However, the conservation of PrmA during the evolution of photosynthetic eukaryotes together with the location of methylated residues at the binding site of translation factors to ribosomes suggests that RPL11 methylation in plant organelles could be involved, in combination with other post-translational modifications, in optimizing ribosome function.

Fluctuations between multiple EF-G-induced chimeric tRNA states during translocation on the ribosome

The coupled translocation of transfer RNA and messenger RNA through the ribosome entails large-scale structural rearrangements, including step-wise movements of the tRNAs. Recent structural work has visualized intermediates of translocation induced by elongation factor G (EF-G) with tRNAs trapped in chimeric states with respect to 30S and 50S ribosomal subunits. The functional role of the chimeric states is not known. Here we follow the formation of translocation intermediates by single-molecule fluorescence resonance energy transfer. Using EF-G mutants, a non-hydrolysable GTP analogue, and fusidic acid, we interfere with either translocation or EF-G release from the ribosome and identify several rapidly interconverting chimeric tRNA states on the reaction pathway. EF-G engagement prevents backward transitions early in translocation and increases the fraction of ribosomes that rapidly fluctuate between hybrid, chimeric and posttranslocation states. Thus, the engagement of EF-G alters the energetics of translocation towards a flat energy landscape, thereby promoting forward tRNA movement.

EF-G enhances the rate of tRNA–mRNA translocation on the ribosome. Here the authors use single-molecule FRET to follow tRNA translocation in real time, identifying new chimeric intermediates and suggesting how EF-G binding and GTP hydrolysis change the energetic landscape of translocation to accelerate forward tRNA movement.

Synchronous tRNA movements during translocation on the ribosome are orchestrated by elongation factor G and GTP hydrolysis

The translocation of tRNAs through the ribosome proceeds through numerous small steps in which tRNAs gradually shift their positions on the small and large ribosomal subunits. The most urgent questions are: (i) whether these intermediates are important; (ii) how the ribosomal translocase, the GTPase elongation factor G (EF-G), promotes directed movement; and (iii) how the energy of GTP hydrolysis is coupled to movement. In the light of recent advances in biophysical and structural studies, we argue that intermediate states of translocation are snapshots of dynamic fluctuations that guide the movement. In contrast to current models of stepwise translocation, kinetic evidence shows that the tRNAs move synchronously on the two ribosomal subunits in a rapid reaction orchestrated by EF-G and GTP hydrolysis. EF-G combines the energy regimes of a GTPase and a motor protein and facilitates tRNA movement by a combination of directed Brownian ratchet and power stroke mechanisms.

Computing H/D-exchange rates of single residues from data of proteolytic fragments

BACKGROUND

Protein conformation and protein/protein interaction can be elucidated by solution-phase Hydrogen/Deuterium exchange (sHDX) coupled to high-resolution mass analysis of the digested protein or protein complex. In sHDX experiments mutant proteins are compared to wild-type proteins or a ligand is added to the protein and compared to the wild-type protein (or mutant). The number of deuteriums incorporated into the polypeptides generated from the protease digest of the protein is related to the solvent accessibility of amide protons within the original protein construct.

RESULTS

In this work, sHDX data was collected on a 14.5 T FT-ICR MS. An algorithm was developed based on combinatorial optimization that predicts deuterium exchange with high spatial resolution based on the sHDX data of overlapping proteolytic fragments. Often the algorithm assigns deuterium exchange with single residue resolution.

CONCLUSIONS

With our new method it is possible to automatically determine deuterium exchange with higher spatial resolution than the level of digested fragments.

The flexible N-terminal domain of ribosomal protein L11 from Escherichia coli is necessary for the activation of stringent factor

The stringent response is activated by the binding of stringent factor to stalled ribosomes that have an unacylated tRNA in the ribosomal aminoacyl-site. Ribosomes lacking ribosomal protein L11 are deficient in stimulating stringent factor. L11 consists of a dynamic N-terminal domain (amino acid residues 1-72) connected to an RNA-binding C-terminal domain (amino acid residues 76-142) by a flexible linker (amino acid residues 73-75). In vivo data show that mutation of proline 22 in the N-terminal domain is important for initiation of the stringent response. Here, six different L11 point and deletion-mutants have been constructed to determine which regions of L11 are necessary for the activation of stringent factor. The different mutants were reconstituted with programmed 70 S(DeltaL11) ribosomes and tested for their ability to stimulate stringent factor in a sensitive in vitro pppGpp synthesis assay. It was found that a single-site mutation at proline 74 in the linker region between the two domains did not affect the stimulatory activity of the reconstituted ribosomes, whereas the single-site mutation at proline 22 reduced the activity of SF to 33% compared to ribosomes reconstituted with wild-type L11. Removal of the entire linker between the N and C-terminal domains or removal of the entire proline-rich helix beginning at proline 22 in L11 resulted in an L11 protein, which was unable to stimulate stringent factor in the ribosome-dependent assay. Surprisingly, the N-terminal domain of L11 on its own activated stringent factor in a ribosome-dependent manner without restoring the L11 footprint in 23 S rRNA in the 50 S subunit. This suggests that the N-terminal domain can activate stringent factor in trans. It is also shown that this activation is dependent on unacylated tRNA.

Supercritical Fluid Chromatography Reduction of Hydrogen/Deuterium Back Exchange in Solution-Phase Hydrogen/Deuterium Exchange with Mass Spectrometric Analysis

The single biggest problem with solution-phase H/D exchange as a mass spectrometric probe of surface exposure in a protein (or protein complex) is back-exchange of H for D after the initial H/D exchange has been quenched. Back-exchange results in loss of pertinent data and also greatly hampers data analysis. Previously, very fast, cold (0-4 degrees C) HPLC was performed to help reduce back-exchange, but calculated back-exchange still averages approximately 30%. In this report, supercritical fluid chromatography replaces HPLC as the desalting/separation technique prior to mass analysis, providing a dramatic reduction in back-exchange compared to the fast, cold HPLC methods.

Mapping the interaction of SmpB with ribosomes by footprinting of ribosomal RNA

In trans-translation transfer messenger RNA (tmRNA) and small protein B (SmpB) rescue ribosomes stalled on truncated or in other ways problematic mRNAs. SmpB promotes the binding of tmRNA to the ribosome but there is uncertainty about the number of participating SmpB molecules as well as their ribosomal location. Here, the interaction of SmpB with ribosomal subunits and ribosomes was studied by isolation of SmpB containing complexes followed by chemical modification of ribosomal RNA with dimethyl sulfate, kethoxal and hydroxyl radicals. The results show that SmpB binds 30S and 50S subunits with 1:1 molar ratios and the 70S ribosome with 2:1 molar ratio. SmpB-footprints are similar on subunits and the ribosome. In the 30S subunit, SmpB footprints nucleotides that are in the vicinity of the P-site facing the E-site, and in the 50S subunit SmpB footprints nucleotides that are located below the L7/L12 stalk in the 3D structure of the ribosome. Based on these results, we suggest a mechanism where two molecules of SmpB interact with tmRNA and the ribosome during trans-translation. The first SmpB molecule binds near the factor-binding site on the 50S subunit helping tmRNA accommodation on the ribosome, whereas the second SmpB molecule may functionally substitute for a missing anticodon stem-loop in tmRNA during later steps of trans-translation.

Characterization of the tRNA and ribosome-dependent pppGpp-synthesis by recombinant stringent factor from Escherichia coli

Stringent factor is a ribosome-dependent ATP:GTP pyrophosphoryl transferase that synthesizes (p)ppGpp upon nutrient deprivation. It is activated by unacylated tRNA in the ribosomal amino-acyl site (A-site) but it is unclear how activation occurs. A His-tagged stringent factor was isolated by affinity-chromatography and precipitation. This procedure yielded a protein of high purity that displayed (a) a low endogenous pyrophosphoryl transferase activity that was inhibited by the antibiotic tetracycline; (b) a low ribosome-dependent activity that was inhibited by the A-site specific antibiotics thiostrepton, micrococcin, tetracycline and viomycin; (c) a tRNA- and ribosome-dependent activity amounting to 4500 pmol pppGpp per pmol stringent factor per minute. Footprinting analysis showed that stringent factor interacted with ribosomes that contained tRNAs bound in classical states. Maximal activity was seen when the ribosomal A-site was presaturated with unacylated tRNA. Less tRNA was required to reach maximal activity when stringent factor and unacylated tRNA were added simultaneously to ribosomes, suggesting that stringent factor formed a complex with tRNA in solution that had higher affinity for the ribosomal A-site. However, tRNA-saturation curves, performed at two different ribosome/stringent factor ratios and filter-binding assays, did not support this hypothesis.

Assembly of the central domain of the 30S ribosomal subunit: roles for the primary binding ribosomal proteins S15 and S8

Assembly of the 30S ribosomal subunit occurs in a highly ordered and sequential manner. The ordered addition of ribosomal proteins to the growing ribonucleoprotein particle is initiated by the association of primary binding proteins. These proteins bind specifically and independently to 16S ribosomal RNA (rRNA). Two primary binding proteins, S8 and S15, interact exclusively with the central domain of 16S rRNA. Binding of S15 to the central domain results in a conformational change in the RNA and is followed by the ordered assembly of the S6/S18 dimer, S11 and finally S21 to form the platform of the 30S subunit. In contrast, S8 is not part of this major platform assembly branch. Of the remaining central domain binding proteins, only S21 association is slightly dependent on S8. Thus, although S8 is a primary binding protein that extensively contacts the central domain, its role in assembly of this domain remains unclear. Here, we used directed hydroxyl radical probing from four unique positions on S15 to assess organization of the central domain of 16S rRNA as a consequence of S8 association. Hydroxyl radical probing of Fe(II)-S15/16S rRNA and Fe(II)-S15/S8/16S rRNA ribonucleoprotein particles reveal changes in the 16S rRNA environment of S15 upon addition of S8. These changes occur predominantly in helices 24 and 26 near previously identified S8 binding sites. These S8-dependent conformational changes are consistent with 16S rRNA folding in complete 30S subunits. Thus, while S8 binding is not absolutely required for assembly of the platform, it appears to affect significantly the 16S rRNA environment of S15 by influencing central domain organization.

Mapping functionally important motifs SPF and GGQ of the decoding release factor RF2 to the Escherichia coli ribosome by hydroxyl radical footprinting. Implications for macromolecular mimicry and structural changes in RF2

The function of the decoding release factor (RF) in translation termination is to couple cognate recognition of the stop codon in the mRNA with hydrolysis of the completed polypeptide from its covalently linked tRNA. For this to occur, the RF must interact with specific A-site components of the active centers within both the small and large ribosomal subunits. In this work, we have used directed hydroxyl radical footprinting to map the ribosomal binding site of the Escherichia coli class I release factor RF2, during translation termination. In the presence of the cognate UGA stop codon, residues flanking the universally conserved (250)GGQ(252) motif of RF2 were each shown to footprint to the large ribosomal subunit, specifically to conserved elements of the peptidyltransferase and GTPase-associated centers. In contrast, residues that flank the putative "peptide anticodon" of RF2, (205)SPF(207), were shown to make a footprint in the small ribosomal subunit at positions within well characterized 16 S rRNA motifs in the vicinity of the decoding center. Within the recently solved crystal structure of E. coli RF2, the GGQ and SPF motifs are separated by 23 A only, a distance that is incompatible with the observed cleavage sites that are up to 100 A apart. Our data suggest that RF2 may undergo gross conformational changes upon ribosome binding, the implications of which are discussed in terms of the mechanism of RF-mediated termination.

Ribosomal proteins at the stalk region modulate functional rRNA structures in the GTPase center

Replacement of the L10.L7/L12 protein complex and L11 in Escherichia coli ribosomes with the respective rat counterparts P0.P1/P2 and eukaryotic L12 causes conversion of ribosomal specificity for elongation factors from prokaryotic elongation factor (EF)-Tu/EF-G to eukaryotic EF (eEF)-1alpha/eEF-2. Here we have investigated the effects of protein replacement on the structure and function of two rRNA domains around positions 1070 and 2660 (sarcin/ricin loop) of 23 S rRNA. Protein replacement at the 1070 region in E. coli 50 S subunits was demonstrated by chemical probing analysis. Binding of rat proteins to the 1070 region caused increased accessibility of the 2660 and 1070 regions to ligands for eukaryotic ribosomes: the ribotoxin pepocin for the 2660 region (E. coli numbering), anti-28 S autoantibody for the 1070 region, and eEF-2 for both regions. Moreover, binding of the E. coli L10.L7/L12 complex and L11 to the 1070 region was shown to be responsible for E. coli ribosomal accessibility to another ribotoxin, gypsophilin. Ribosomal proteins at the 1070 region appear to modulate the structures and functions of the 2660 and 1070 RNA regions in slightly different modes in prokaryotes and eukaryotes.

Mutations in the GTPase center of Escherichia coli 23S rRNA indicate release factor 2-interactive sites

Mutations in the GTPase center of Escherichia coli 23S rRNA were characterized in vivo as UGA-specific nonsense suppressors. Some site-directed mutations did not exhibit suppressor activity and were interspersed among suppressor mutations. Our results demonstrate the involvement of the two adjacent loops of this conserved rRNA structure in UGA-dependent translation termination and, taken with previous in vitro analyses and with consideration of the crystal structure of the GTPase center RNA, indicate that nucleotides 1067, 1093, 1094, and 1095 are sites of interaction with release factor 2.

Localization of L11 protein on the ribosome and elucidation of its involvement in EF-G-dependent translocation

L11 protein is located at the base of the L7/L12 stalk of the 50 S subunit of the Escherichia coli ribosome. Because of the flexible nature of the region, recent X-ray crystallographic studies of the 50 S subunit failed to locate the N-terminal domain of the protein. We have determined the position of the complete L11 protein by comparing a three-dimensional cryo-EM reconstruction of the 70 S ribosome, isolated from a mutant lacking ribosomal protein L11, with the three-dimensional map of the wild-type ribosome. Fitting of the X-ray coordinates of L11-23 S RNA complex and EF-G into the cryo-EM maps combined with molecular modeling, reveals that, following EF-G-dependent GTP hydrolysis, domain V of EF-G intrudes into the cleft between the 23 S ribosomal RNA and the N-terminal domain of L11 (where the antibiotic thiostrepton binds), causing the N-terminal domain to move and thereby inducing the formation of the arc-like connection with the G' domain of EF-G. The results provide a new insight into the mechanism of EF-G-dependent translocation.

Conformational changes induced in the Saccharomyces cerevisiae GTPase-associated rRNA by ribosomal stalk components and a translocation inhibitor

The yeast ribosomal GTPase associated center is made of parts of the 26S rRNA domains II and VI, and a number of proteins including P0, P1alpha, P1beta, P2alpha, P2beta and L12. Mapping of the rRNA neighborhood of the proteins was performed by footprinting in ribosomes from yeast strains lacking different GTPase components. The absence of protein P0 dramatically increases the sensitivity of the defective ribosome to degradation hampering the RNA footprinting. In ribosomes lacking the P1/P2 complex, protection of a number of nucleotides is detected around positions 840, 880, 1100, 1220-1280 and 1350 in domain II as well as in several positions in the domain VI alpha-sarcin region. The protection pattern resembles the one reported for the interaction of elongation factors in bacterial systems. The results exclude a direct interaction of these proteins with the rRNA and are compatible with an increase in the ribosome affinity for EF-2 in the absence of the acidic P proteins. Interestingly, a sordarin derivative inhibitor of EF-2 causes an opposite effect, increasing the reactivity in positions protected by the absence of P1/P2. Similarly, a deficiency in protein L12 exposes nucleotides G1235, G1242, A1262, A1269, A1270 and A1272 to chemical modification, thus situating the protein binding site in the most conserved part of the 26S rRNA, equivalent to the bacterial protein L11 binding site.

Mutations at position A960 of E. coli 23 S ribosomal RNA influence the structure of 5 S ribosomal RNA and the peptidyltransferase region of 23 S ribosomal RNA

The proximity of loop D of 5 S rRNA to two regions of 23 S rRNA, domain II involved in translocation and domain V involved in peptide bond formation, is known from previous cross-linking experiments. Here, we have used site-directed mutagenesis and chemical probing to further define these contacts and possible sites of communication between 5 S and 23 S rRNA. Three different mutants were constructed at position A960, a highly conserved nucleotide in domain II previously crosslinked to 5 S rRNA, and the mutant rRNAs were expressed from plasmids as homogeneous populations of ribosomes in Escherichia coli deficient in all seven chromosomal copies of the rRNA operon. Mutations A960U, A960G and, particularly, A960C caused structural rearrangements in the loop D of 5 S rRNA and in the peptidyltransferase region of domain V, as well as in the 960 loop itself. These observations support the proposal that loop D of 5 S rRNA participates in signal transmission between the ribosome centers responsible for peptide bond formation and translocation.

The 23 S rRNA environment of ribosomal protein L9 in the 50 S ribosomal subunit

Ribosomal protein L9 consists of two globular alpha/beta domains separated by a nine-turn alpha-helix. We examined the rRNA environment of L9 by chemical footprinting and directed hydroxyl radical probing. We reconstituted L9, or individual domains of L9, with L9-deficient 50 S subunits, or with deproteinized 23 S rRNA. A footprint was identified in domain V of 23 S rRNA that was mainly attributable to N-domain binding. Fe(II) was tethered to L9 via cysteine residues introduced at positions along the alpha-helix and in the C-domain, and derivatized proteins were reconstituted with L9-deficient subunits. Directed hydroxyl radical probing targeted regions of domains I, III, IV, and V of 23 S rRNA, reinforcing the view that 50 S subunit architecture is typified by interwoven rRNA domains. There was a striking correlation between the cleavage patterns from the Fe(II) probes attached to the alpha-helix and their predicted orientations, constraining both the position and orientation of L9, as well as the arrangement of specific elements of 23 S rRNA, in the 50 S subunit.

Mapping RNA-protein interactions in ribonuclease P from Escherichia coli using disulfide-linked EDTA-Fe

The protein subunit of Escherichia coli ribonuclease P (which has a cysteine residue at position 113) and its single cysteine-substituted mutant derivatives (S16C/C113S, K54C/C113S and K66C/C113S) have been modified using a sulfhydryl-specific iron complex of EDTA-2- aminoethyl 2-pyridyl disulfide (EPD-Fe). This reaction converts C5 protein, or its single cysteine-substituted mutant derivatives, into chemical nucleases which are capable of cleaving the cognate RNA ligand, M1 RNA, the catalytic RNA subunit of E. coli RNase P, in the presence of ascorbate and hydrogen peroxide. Cleavages in M1 RNA are expected to occur at positions proximal to the site of contact between the modified residue (in C5 protein) and the ribose units in M1 RNA. When EPD-Fe was used to modify residue Cys16 in C5 protein, hydroxyl radical-mediated cleavages occurred predominantly in the P3 helix of M1 RNA present in the reconstituted holoenzyme. C5 Cys54-EDTA-Fe produced cleavages on the 5' strand of the P4 pseudoknot of M1 RNA, while the cleavages promoted by C5 Cys66-EDTA-Fe were in the loop connecting helices P18 and P2 (J18/2) and the loop (J2/4) preceding the 3' strand of the P4 pseudoknot. However, hydroxyl radical-mediated cleavages in M1 RNA were not evident with Cys113-EDTA-Fe, perhaps indicative of Cys113 being distal from the RNA-protein interface in the RNase P holoenzyme. Our directed hydroxyl radical-mediated footprinting experiments indicate that conserved residues in the RNA and protein subunit of the RNase-P holoenzyme are adjacent to each other and provide structural information essential for understanding the assembly of RNase P.

Identification of an RNA-protein bridge spanning the ribosomal subunit interface

The 7.8 angstrom crystal structure of the 70S ribosome reveals a discrete double-helical bridge (B4) that projects from the 50S subunit, making contact with the 30S subunit. Preliminary modeling studies localized its contact site, near the bottom of the platform, to the binding site for ribosomal protein S15. Directed hydroxyl radical probing from iron(II) tethered to S15 specifically cleaved nucleotides in the 715 loop of domain II of 23S ribosomal RNA, one of the known sites in 23S ribosomal RNA that are footprinted by the 30S subunit. Reconstitution studies show that protection of the 715 loop, but none of the other 30S-dependent protections, is correlated with the presence of S15 in the 30S subunit. The 715 loop is specifically protected by binding free S15 to 50S subunits. Moreover, the previously determined structure of a homologous stem-loop from U2 small nuclear RNA fits closely to the electron density of the bridge.