Orientation of ribosome recycling factor in the ribosome from directed hydroxyl radical probing

Ribosome recycling factor (RRF) disassembles posttermination complexes in conjunction with elongation factor EF-G, liberating ribosomes for further rounds of translation. The striking resemblance of its L-shaped structure to that of tRNA has suggested that the mode of action of RRF may be based on mimicry of tRNA. Directed hydroxyl radical probing of 16S and 23S rRNA from Fe(II) tethered to ten positions on the surface of E. coli RRF constrains it to a well-defined location in the subunit interface cavity. Surprisingly, the orientation of RRF in the ribosome differs markedly from any of those previously observed for tRNA, suggesting that structural mimicry does not necessarily reflect functional mimicry.     

Position of eukaryotic initiation factor eIF5B on the 80S ribosome mapped by directed hydroxyl radical probing

Eukaryotic translation initiation factor eIF5B is a ribosome-dependent GTPase that mediates displacement of initiation factors from the 40S ribosomal subunit in 48S initiation complexes and joining of 40S and 60S subunits. Here, we determined eIF5B's position on 80S ribosomes by directed hydroxyl radical cleavage. In the resulting model, eIF5B is located in the intersubunit cleft of the 80S ribosome: domain 1 is positioned near the GTPase activating center of the 60S subunit, domain 2 interacts with the 40S subunit (helices 3, 5 and the base of helix 15 of 18S rRNA and ribosomal protein (rp) rpS23), domain 3 is sandwiched between subunits and directly contacts several ribosomal elements including Helix 95 of 28S rRNA and helix 44 of 18S rRNA, domain 4 is near the peptidyl-transferase center and its helical subdomain contacts rpL10E. The cleavage data also indicate that binding of eIF5B might induce conformational changes in both subunits, with ribosomal segments wrapping around the factor. Some of these changes could also occur upon binding of other translational GTPases, and may contribute to factor recognition.     

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

Ribosomal protein L11 is a highly conserved protein that has been implicated in binding of elongation factors to ribosomes and associated GTP hydrolysis. Here, we have analyzed the ribosomal RNA neighborhood of Escherichia coli L11 in 50 S subunits by directed hydroxyl radical probing from Fe(II) tethered to five engineered cysteine residues at positions 19, 84, 85, 92 and 116 via the linker 1-(p -bromoacetamidobenzyl)-EDTA. Correct assembly of the L11 derivatives was analyzed by incorporating the modified proteins into 50 S subunits isolated from an E. coli strain that lacks L11 and testing for previously characterized L11-dependent footprints in domain II of 23 S rRNA. Hydroxyl radicals were generated from Fe(II) tethered to L11 and sites of cleavage in the ribosomal RNA were detected by primer extension. Strong cleavages were detected within the previously described binding site of L11, in the 1100 region of 23 S rRNA. Moreover, Fe(II) tethered to position 19 in L11 targeted the backbone of the sarcin loop in domain VI while probing from position 92 cleaved the backbone around bases 900 and 2470 in domains II and V, respectively. Fe(II) tethered to positions 84, 85 and 92 also generated cleavages in 5 S rRNA around helix II. These data provide new information about the positions of specific features of 23 S rRNA and 5 S rRNA relative to protein L11 in the 50 S subunit and show that L11 is near highly conserved elements of the rRNA that have been implicated in binding of tRNA and elongation factors to the ribosome.     

The location of protein S8 and surrounding elements of 16S rRNA in the 70S ribosome from combined use of directed hydroxyl radical probing and X-ray crystallography

Ribosomal protein S8, which is essential for the assembly of the central domain of 16S rRNA, is one of the most thoroughly studied RNA-binding proteins. To map its surrounding RNA in the ribosome, we carried out directed hydroxyl radical probing of 16S rRNA using Fe(II) tethered to nine different positions on the surface of protein S8 in 70S ribosomes. Hydroxyl radical-induced cleavage was observed near the classical S8-binding site in the 620 stem, and flanking the other S8-footprinted regions of the central domain at the three-helix junction near position 650 and the 825 and 860 stems. In addition, cleavage near the 5' terminus of 16S rRNA, in the 300 region of its 5' domain, and in the 1070 region of its 3'-major domain provide information about the proximity to S8 of RNA elements not directly involved in its binding. These data, along with previous footprinting and crosslinking results, allowed positioning of protein S8 and its surrounding RNA elements in a 7.8-A map of the Thermus thermophilus 70S ribosome. The resulting model is in close agreement with the extensive body of data from previous studies using protein-protein and protein-RNA crosslinking, chemical and enzymatic footprinting, and genetics.     

Three-dimensional RNA structure refinement by hydroxyl radical probing

Molecular modeling guided by experimentally derived structural information is an attractive approach for three-dimensional structure determination of complex RNAs that are not amenable to study by high-resolution methods. Hydroxyl radical probing (HRP), which is performed routinely in many laboratories, provides a measure of solvent accessibility at individual nucleotides. HRP measurements have, to date, only been used to evaluate RNA models qualitatively. Here we report the development of a quantitative structure refinement approach using HRP measurements to drive discrete molecular dynamics simulations for RNAs ranging in size from 80 to 230 nucleotides. We first used HRP reactivities to identify RNAs that form extensive helical packing interactions. For these RNAs, we achieved highly significant structure predictions given the inputs of RNA sequence and base pairing. This HRP-directed tertiary structure refinement approach generates robust structural hypotheses that are useful for guiding explorations of structure-function inter-relationships in RNA.     

Chemical probing of RNA with the hydroxyl radical at single-atom resolution

While hydroxyl radical cleavage is widely used to map RNA tertiary structure, lack of mechanistic understanding of strand break formation limits the degree of structural insight that can be obtained from this experiment. Here, we determine how individual ribose hydrogens of sarcin/ricin loop RNA participate in strand cleavage. We find that substituting deuterium for hydrogen at a ribose 5′-carbon produces a kinetic isotope effect on cleavage; the major cleavage product is an RNA strand terminated by a 5′-aldehyde. We conclude that hydroxyl radical abstracts a 5′-hydrogen atom, leading to RNA strand cleavage. We used this approach to obtain structural information for a GUA base triple, a common tertiary structural feature of RNA. Cleavage at U exhibits a large 5′ deuterium kinetic isotope effect, a potential signature of a base triple. Others had noted a ribose-phosphate hydrogen bond involving the G 2′-OH and the U phosphate of the GUA triple, and suggested that this hydrogen bond contributes to backbone rigidity. Substituting deoxyguanosine for G, to eliminate this hydrogen bond, results in a substantial decrease in cleavage at G and U of the triple. We conclude that this hydrogen bond is a linchpin of backbone structure around the triple.     

Calculation of the relative geometry of tRNAs in the ribosome from directed hydroxyl-radical probing data

The many interactions of tRNA with the ribosome are fundamental to protein synthesis. During the peptidyl transferase reaction, the acceptor ends of the aminoacyl and peptidyl tRNAs must be in close proximity to allow peptide bond formation, and their respective anticodons must base pair simultaneously with adjacent trinucleotide codons on the mRNA. The two tRNAs in this state can be arranged in two nonequivalent general configurations called the R and S orientations, many versions of which have been proposed for the geometry of tRNAs in the ribosome. Here, we report the combined use of computational analysis and tethered hydroxyl-radical probing to constrain their arrangement. We used Fe(II) tethered to the 5' end of anticodon stem-loop analogs (ASLs) of tRNA and to the 5' end of deacylated tRNA(Phe) to generate hydroxyl radicals that probe proximal positions in the backbone of adjacent tRNAs in the 70S ribosome. We inferred probe-target distances from the resulting RNA strand cleavage intensities and used these to calculate the mutual arrangement of A-site and P-site tRNAs in the ribosome, using three different structure estimation algorithms. The two tRNAs are constrained to the S configuration with an angle of about 45 degrees between the respective planes of the molecules. The terminal phosphates of 3'CCA are separated by 23 A when using the tRNA crystal conformations, and the anticodon arms of the two tRNAs are sufficiently close to interact with adjacent codons in mRNA.     

Position of eukaryotic translation initiation factor eIF1A on the 40S ribosomal subunit mapped by directed hydroxyl radical probing

The universally conserved eukaryotic initiation factor (eIF), eIF1A, plays multiple roles throughout initiation: it stimulates eIF2/GTP/Met-tRNA_i^Met attachment to 40S ribosomal subunits, scanning, start codon selection and subunit joining. Its bacterial ortholog IF1 consists of an oligonucleotide/oligosaccharide-binding (OB) domain, whereas eIF1A additionally contains a helical subdomain, N-terminal tail (NTT) and C-terminal tail (CTT). The NTT and CTT both enhance ribosomal recruitment of eIF2/GTP/Met-tRNA_i^Met, but have opposite effects on the stringency of start codon selection: the CTT increases, whereas the NTT decreases it. Here, we determined the position of eIF1A on the 40S subunit by directed hydroxyl radical cleavage. eIF1A''s OB domain binds in the A site, similar to IF1, whereas the helical subdomain contacts the head, forming a bridge over the mRNA channel. The NTT and CTT both thread under Met-tRNA_i^Met reaching into the P-site. The NTT threads closer to the mRNA channel. In the proposed model, the NTT does not clash with either mRNA or Met-tRNA_i^Met, consistent with its suggested role in promoting the ‘closed’ conformation of ribosomal complexes upon start codon recognition. In contrast, eIF1A-CTT appears to interfere with the P-site tRNA-head interaction in the ‘closed’ complex and is likely ejected from the P-site upon start codon recognition.     

Interaction analysis between tmRNA and SmpB from Thermus thermophilus

Small protein B, SmpB, is a tmRNA-specific binding protein essential for trans-translation. We examined the interaction between SmpB and tmRNA from Thermus thermophilus, using biochemical and NMR methods. Chemical footprinting analyses using full-length tmRNA demonstrated that the sites protected upon SmpB binding are located exclusively in the tRNA-like domain (TLD) of tmRNA. To clarify the SmpB binding sites, we constructed several segments derived from TLD. Optical biosensor interaction analyses and melting profile analyses with mutational studies showed that SmpB efficiently binds to only a 30-nt segment that forms a stem and loop, with the 5' and 3' extensions composed of the D-loop and variable-loop analogues. The conserved sequences, 16UCGA and 319GAC, in the extensions are responsible for the SmpB binding. These results agree with the those visualized by the cocrystal structure of TLD and SmpB from Aquifex aeolicus. In addition, NMR chemical shift mapping analyses, using the 30-nt segment and (15)N-labeled SmpB, revealed the characteristic RNA binding mode. The hydrogen bond pattern around beta2 changes, with the Gly in beta2, which acts as a hinge, showing the largest chemical shift change. It appears that SmpB undergoes structural changes indicating an induced fit upon binding to the specific region of TLD.     

The production of hydroxyl radical from hydrogen peroxide

The formation of hydroxyl radical (OH·) from the oxidation of glutathione, ascorbic acid, NADPH, hydroquinone, catechol, and riboflavin by hydrogen peroxide was studied using a range of enzymes and copper and iron complexes as possible catalysts. Copper-1,10-phenanthroline appears to catalyze the production of OH· from hydrogen peroxide without superoxide radical being formed as an intermediate, and without the involvement of a catalyzed Haber-Weiss (Fenton) reaction. Superoxide radical is involved, however, in the Cu²⁺ -catalyzed decomposition of hydrogen peroxide, and in the oxidation of glutathione by atmospheric oxygen. For this latter oxidation, copper-4,7-dimethyl-1,10-phenanthroline was found to be a much more effective catalyst than the copper complex of 1,10-phenanthroline, which is normally used. Mechanisms for these reactions are proposed, and the toxicological significance of the ability of a variety of biological reductants to provide a prolific source of OH· when oxidized by hydrogen peroxide is discussed.     

Interaction of trigger factor with the ribosome

The trigger factor of Escherichia coli is a prolyl isomerase and a chaperone. It interacts with the ribosome and affects the folding of newly formed protein chains. Therefore, the dynamics of the interactions of trigger factor with the ribosome and with unfolded protein chains should be tailored for this function. Previously, we had found that binding of unfolded proteins to trigger factor is fast and that the lifetime of the complex between these two components is only about 100 ms. Here, we have labeled the trigger factor in its amino-terminal, ribosome-binding domain with a fluorescent dye and investigated how it interacts with the ribosome. We found that this association, as well as the dissociation of the complex, are rather slow processes. The average lifetime of the complex is about 30 seconds (at 20 degrees C). The strong differences in the dynamics of the interactions of trigger factor with the ribosome and with protein substrates might ensure that, on the one hand, trigger factor remains bound to the ribosome while a protein chain is being synthesized, and, on the other hand, allows it to scan the newly formed protein for prolyl bonds that need catalysis of isomerization.     

Directed hydroxyl radical probing of the rRNA neighborhood of ribosomal protein S13 using tethered Fe(II).

Directed hydroxyl radical probing was used to probe the rRNA neighborhood around protein S13 in the 30S ribosomal subunit. The unique cysteine at position 84 of S13 served as a tethering site for attachment of Fe(II)-1-(p-bromoacetamidobenzyl)-EDTA. Derivatized S13 (Fe-C84-S13) was then assembled into 30S ribosomal subunits by in vitro reconstitution with 16S rRNA and a mixture of the remaining 30S subunit proteins. Hydroxyl radicals generated from the tethered Fe(II) resulted in cleavage of the RNA backbone in two localized regions of the 3' major domain of 16S rRNA. One region spans nt 1308-1333 and is close to a site previously crosslinked to S13. A second set of cleavages is found in the 950/1230 helix. Both regions have been implicated in binding of S13 by previous chemical footprinting studies using base-specific chemical probes and solution-based hydroxyl radical probing. These results place both regions of 16S rRNA in proximity to position C84 of S13 in the three-dimensional structure of the 30S ribosomal subunit.     

Light-dependent spin trapping of hydroxyl radical from human erythrocytes.

The generation of reactive oxygen species from human erythrocytes has previously been demonstrated. Furthermore, erythrocytic protoporphyrin IX has been shown to generate superoxide and singlet oxygen when exposed to light. These findings suggest that a component of erythrocytic reactive oxygen species production may be light-dependent. By inhibiting erythrocyte superoxide dismutase, catalase, and glutathione peroxidase with N,N-diethyldithiocarbamate or sodium cyanide, we demonstrate the light-dependent generation of hydroxyl radical in human erythrocytes using spin trapping/Electron Spin Resonance spectroscopy. This finding may be significant in tissues where blood is exposed to light, such as in the eye.     

Reactions of ferrioxamine and desferrioxamine with the hydroxyl radical

Both ferrioxamine and desferrioxamine react with the hydroxyl radical with a second order rate constant equal to 1.3 × 10¹⁰ M^?1 s^?1. Conditions for the use of desferrioxamine as a probe for the role of iron salts in the formation of hydroxyl radicals in biochemical systems are discussed.     

Scavenging of hydroxyl radical by catecholamines

The direct effects of the four catecholamines (CATs), adrenaline (A), noradrenaline (NA), dopamine (D) and isoproterenol (I), on free radicals were investigated using the free radical 2,2‐diphenyl‐1‐picrylhydrazyl (DPPH^?) and hydroxyl radial (HO^?). The CATs examined were found to inhibit the ESR signal intensity of DPPH^? in a dose‐dependent manner over the range 0.1–2.5 mmol/L in the following order: NA > A > I > D, with IC₅₀ = 0.30 ± 0.03 for noradrenaline and IC₅₀ = 0.86 ± 0.02 for dopamine. Hydroxyl radicals were produced using a Fenton reaction in the presence of the spin trap 5,5‐dimethyl‐1‐pyrroline N‐oxide (DMPO), and ESR technique was applied to detect the CATs reactivity toward the radicals. The reaction rates constant (k_r) of CATs with HO^? were found to be in the order of 10⁹ L/mol/s, and the k_r value for noradrenaline was the highest (k_r = 8.4 × 10⁹ L/mol/s). The CATs examined exhibited also a strong decrease in the light emission (62–73% at 1 mmol/L concentration and 79–89% at 2 mmol/L concentration) from a Fenton‐like reaction. These reactions may be relevant to the biological action of these important polyphenolic compounds. Copyright © 2012 John Wiley & Sons, Ltd.     

Asbestos catalyzes hydroxyl and superoxide radical generation from hydrogen peroxide

To understand chemical characteristics of the asbestos minerals which might contribute to tissue damage, the catalytic properties of three different varieties were studied. Using spin trapping techniques it was determined that crocidolite, chrysotile, and amosite asbestos were all able to catalyze the generation of toxic hydroxyl radicals from a normal byproduct of tissue metabolism, hydrogen peroxide. The iron chelator desferroxamine inhibits this reaction, indicating a major role for iron in the catalytic process, and suggesting a possible mechanism by which asbestos toxicity might be reduced.