Effect of ultraviolet irradiation on 30-S ribosomal subunits. Identification of the RNA region crosslinked to protein S7

In vivo assembly of plasmid-expressed ribosomal protein S7 of Thermus thermophilus into Escherichia coli ribosomes and conditions of its overexpression

Researchers still have great difficulty in isolating individual ribosomal proteins from the ribosome in quantities high enough for structural research. To this end, when studying protein S7, we created an E. coli overproducer of the recombinant protein S7 of Thermus thermophilus. The vector for expression was pQE-32 having a strong promoter of E. coli phage T5 and six triplets of His at the 5'-end. This N-terminal six His tag of the fusion protein is responsible for binding to Ni-NTA-resin and allows purifying the protein in one step. The yield of the recombinant protein was 20% and more of the total cellular proteins. In addition we have shown that the recombinant thermophilic protein is incorporated in vivo into the ribosome of E. coli despite the fact that these proteins (thermophilic and mesophilic) have a rather low homology, only 52%. This fact provides a base for the system to study functions of individual proteins.

Topography of the Escherichia coli ribosomal 30S subunit-initiation factor 2 complex

The specific effect of the binding of initiation factor IF2 on E coli 16S rRNA within the [IF2/30S/GTP] complex has been probed by crosslinking experiment with trans-diamminedichloro platinum (II) and by phosphate alkylation with ethylnitrosourea. Several 16S rRNA fragments crosslinked to IF2 have been identified and are mostly located in the head and the lateral protrusion of the 30S subunit. The study of the effect of IF2 binding to the 30S subunit reveals that the factor does not tightly bind to the 16S rRNA and induces both isolated reductions and enhancements of phosphate reactivity in the 16S rRNA. Several of them are located near the binding site of IF2 and weak effects are observed in distant parts of the subunit. These results are discussed in the light of current knowledge of the topographical localization of IF2 with the 30S subunit and of its relation with function.

Two-quantum UV photochemistry of nucleic acids: comparison with conventional low-intensity UV photochemistry and radiation chemistry

The action of high-intensity laser u.v. radiation on nucleic acid molecules and their constituents in vitro and in vivo is compared with the results of low-intensity u.v. photolysis and gamma-radiolysis.

Identification of proteins crosslinked to RNA in 40S ribosomal subunits of Saccharomyces cerevisiae

RNA-protein crosslinks were introduced into the 40S ribosomal subunits from Saccharomyces cerevisiae by mild UV treatment. Proteins crosslinked to the 18S rRNA molecule were separated from free proteins by repeated extraction of the treated subunits and centrifugation in glycerol gradients. After digestion with RNase to remove the RNA molecules, proteins were radio-labeled with 125I and identified by electrophoresis on two-dimensional polyacrylamide gels with carrier total 40S ribosomal proteins and autoradiography. Proteins S2, S7, S13, S14, S17/22/27, and S18 were linked to the 18S rRNA. A shorter period of irradiation resulted in crosslinking of S2 and S17/22/27 only. Several of these proteins were previously demonstrated to be present in ribosomal core particles or early assembled proteins.

UV laser induced RNA-protein crosslinks and RNA chain breaks in tobacco mosaic virus RNA in situ

The efficiency of RNA-protein crosslink and RNA chain break formation under nanosecond or picosecond UV-laser pulse irradiation of tobacco mosaic virus was determined. It was found that on high-intensity UV-laser irradiation the quantum yields of both reactions increase considerably as compared to the usual (low-intensity) UV-irradiation. The RNA-protein crosslink quantum yield was found to be 1.8 x 10(-5) and 1.2 x 10(-4) and that of RNA chain breaks 1.7 x 10(-4) and 8.9 x 10(-4) for nanosecond and picosecond irradiation, respectively.

Probing the assembly of the 3' major domain of 16 S ribosomal RNA. Quaternary interactions involving ribosomal proteins S7, S9 and S19

We have studied the effect of assembly of ribosomal proteins S7, S9 and S19 on the accessibility and conformation of nucleotides in 16 S ribosomal RNA. Complexes formed between 16 S rRNA and S7, S7 + S9, S7 + S19 or S7 + S9 + S19 were subjected to a combination of chemical and enzymatic probes, whose sites of attack in 16 S rRNA were identified by primer extension. The results of this study show that: (1) Protein S7 affects the reactivity of an extensive region in the lower half of the 3' major domain. Inclusion of proteins S9 or S19 with S7 has generally little additional effect on S7-specific protection of the RNA. Clusters of nucleotides that are protected by protein S7 are localized in the 935-945 region, the 950/1230 stem, the 1250/1285 internal loop, and the 1350/1370 stem. (2) Addition of protein S9 in the presence of S7 causes several additional effects principally in two structurally distal regions. We observe strong S9-dependent protection of positions 1278 to 1283, and of several positions in the 1125/1145 internal loop. These findings suggest that interaction of protein S9 with 16 S rRNA results in a structure in which the 1125/1145 and 1280 regions are proximal to each other. (3) Most of the strong S19-dependent effects are clustered in the 950-1050 and 1210-1230 regions, which are joined by base-pairing in the 16 S rRNA secondary structure. The highly conserved 960-975 stemp-loop, which has been implicated in tRNA binding, appears to be destabilized in the presence of S19. (4) Protein S7 causes enhanced reactivity at several sites that become protected upon addition of S9 or S19. This suggests that S7-induced conformational changes in 16 S rRNA play a role in the co-operativity of assembly of the 3' major domain.

A detailed model of the three-dimensional structure of Escherichia coli 16 S ribosomal RNA in situ in the 30 S subunit

A large body of intra-RNA and RNA-protein crosslinking data, obtained in this laboratory, was used to fold the phylogenetically and experimentally established secondary structure of Escherichia coli 16 S RNA into a three-dimensional model. All the crosslinks were induced in intact 30 S subunits (or in some cases in growing E. coli cells), and the sites of crosslinking were precisely localized on the RNA by oligonucleotide analysis. The RNA-protein crosslinking data (including 28 sites, and involving 13 of the 21 30S ribosomal were used to relate the RNA structure to the distribution of the proteins as determined by neutron scattering. The three-dimensional model of the 16 S RNA has overall dimensions of 220 A x 140 A x 90 A, in good agreement with electron microscopic estimates for the 30 S subunit. The shape of the model is also recognizably the same as that seen in electron micrographs, and the positions in the model of bases localized on the 30 S subunit by immunoelectron microscopy (the 5' and 3' termini, the m7G and m6(2)A residues, and C-1400) correspond closely to their experimentally observed positions. The distances between the RNA-protein crosslink sites in the model correlate well with the distances between protein centres of mass obtained by neutron scattering, only two out of 66 distances falling outside the expected tolerance limits. These two distances both involve protein S13, a protein noted for its anomalous behaviour. A comparison with other experimental information not specifically used in deriving the model shows that it fits well with published data on RNA-protein binding sites, mutation sites on the RNA causing resistance to antibiotics, tertiary interactions in the RNA, and a potential secondary structural "switch". Of the sites on 16 S RNA that have been found to be accessible to chemical modification in the 30 S subunit, 87% are at obviously exposed positions in the model. In contrast, 70% of the sites corresponding to positions that have ribose 2'-O-methylations in the eukaryotic 18 S RNA from Xenopus laevis are at non-exposed (i.e. internal) positions in the model. All nine of the modified bases in the E. coli 16 S RNA itself show a remarkable distribution, in that they form a "necklace" in one plane around the "throat" of the subunit. Insertions in eukaryotic 18 S RNA, and corresponding deletions in chloroplast or mammalian mitochondrial ribosomal RNA relative to E. coli 16 S RNA represent distinct sub-domains in the structure.(ABSTRACT TRUNCATED AT 400 WORDS)

Higher-order structure of domain III in Escherichia coli 16S ribosomal RNA, 30S subunit and 70S ribosome

We have investigated in detail the conformation of domain III of 16S rRNA (nucleotides 913-1408), using a variety of chemical and enzymatic structure probes. The sites of reaction were identified by primer extension with reverse transcriptase using appropriate oligodeoxyribonucleotide primers. This study has been done on 16S rRNA in its naked form, in the 30S subunit and in the 70S ribosome. Data obtained with naked RNA broadly confirm the secondary structure model proposed essentially by comparative sequence analysis, and allow identification of nucleotides involved in tertiary interactions. Our results are in reasonably good agreement with structure probing experiments of Moazed et al. [1]. However, several discrepancies have been observed. Within the 30S subunit, a high number of nucleotides become unreactive whereas other nucleotides show an enhanced reactivity. This probably reflects local conformational changes. Interestingly, they are located in strategic regions of the RNA, e.g. around C1400 (involved in tRNA binding) and C1192 (involved in spectinomycin recognition). Results are also discussed together with the topographical localization of the ribosomal proteins in this area. The study on the 70S particle allows identification of regions at the interface of subunits or exposed at the surface of the ribosome.

A three-dimensional model of domain III of the Escherichia coli small ribosomal subunit

A three-dimensional model of domain III (nucleotides 920 to 1395) of the 30S ribosomal subunit of E. coli is proposed. The data used as a guide in folding the secondary structure of the RNA into a tertiary structure are four long range RNA-RNA interactions proposed by us on the basis of experiments performed in this laboratory plus two sets of data from other laboratories: protein-RNA cross-linking sites for proteins S1, S3, S7, S10 and S12, and the interprotein distances determined by neutron scattering. The model is consistent with nearly all of the published experimental findings on the structure of domain III.

trans-Diamminedichloroplatinum(II), a reversible RNA-protein cross-linking agent. Application to the ribosome and to an aminoacyl-tRNA synthetase/tRNA complex

A new approach allowing detection of contact points between RNAs and proteins has been developed using trans-diamminedichloroplatinum(II) as the cross-linking reagent. The advantage of the method relies on the fact that the coordination bonds between platinum and the potential acceptors on proteins and nucleic acids (mainly S of cysteine or methionine residues; N of imidazole rings in histidine residues; N7 of guanine, N1 of adenine, and N3 of cytosine residues) can be reversed, so that the cross-linked oligonucleotides or peptides in contact within a complex can be analyzed directly. The method was worked out with the ribosome from Escherichia coli and the tRNAVal/valyl-tRNA synthetase system from the yeast Saccharomyces cerevisiae. In the first system the platinum approach permitted detection of ribosomal proteins cross-linked to 16S rRNA within the 30S subunits (mainly S18 and to a lower extent S3, S4, S11, and S13/S14); in the second system major oligonucleotides of tRNAVal cross-linked to valyl-tRNA synthetase were detected in the anticodon stem and loop, in the variable loop, and in the 3' terminal amino acid accepting region. These results are discussed in light of the current knowledge on ribosome and tRNAs and of potential applications of the methodology.

Multiple crosslinks of proteins S7 and S9 to domains 3 and 4 of 16S ribosomal RNA in the Escherichia coli 30S particle

RNA-protein cross-links were introduced into Escherichia coli 30S subunits by treatment with 1-ethyl-3(3-dimethylaminopropyl)carbodiimide. 16S rRNA, cross-linked to 30S ribosomal proteins, was isolated and hybridized with seven single-stranded bacteriophage M13-DNA probes. These probes, each carrying an inserted rDNA fragment, were used to select contiguous RNA sections covering domains 3 and 4 (starting at nucleotide 868 and ending at the 3'OH terminus) of the 16S rRNA. The proteins covalently linked to each selected RNA section were identified by two-dimensional polyacrylamide gel electrophoresis. Proteins S7 and S9 were shown to be efficiently cross-linked to multiple sites belonging to both domains.

Multiple crosslinks of proteins S7, S9, S13 to domains 3 and 4 of 16S RNA in the 30S particle

Functionally active 70S ribosomes containing 4-thiouracil in place of uracil (substitution level 2%) were prepared by an in vivo substitution method. RNA-protein crosslinks were introduced by 366 nm photoactivation of 4-thiouracil in the purified 30S subunits. Seven single stranded M13 probes containing rDNA inserts complementary to domains 3 and 4 of 16S RNA were constructed. These inserts approximately 100 nucleotides long starting at nucleotide 868 and ending at the 3' OH terminus were used to select contiguous RNA sections. The proteins covalently linked to each selected RNA section were identified by 2D gel electrophoresis. Proteins S7, S9, S13 were shown to be efficiently crosslinked to multiple sites belonging to both domains.

Three-dimensional arrangement of the Escherichia coli 16 S ribosomal RNA

A model for the arrangement of the Escherichia coli 16 S ribosomal RNA in the 30 S ribosomal subunit is given. This model is based on the 16 S ribosomal RNA secondary structure, intramolecular RNA crosslinking results, protein-RNA interactions, and the locations of proteins within the 30 S subunit. These considerations allow placement of most of the RNA helices in approximate positions. The overall shape (that of an asymmetric Y) is very reminiscent of the description of the shape of the RNA made by direct determinations and is reasonably correlated to the appearance of the 30 S subunit. The identities of the three major secondary-structure domains of the 16 S ribosomal RNA are, for the most part, preserved. In addition, many close contacts between the 5' and middle RNA domains occur in the body of the particle. The 3'-terminal domain is situated in the central part of the model. This position corresponds to the region between the head and the platform structure in the 30 S subunit. The regions that represent the general locations of the messenger RNA and transfer RNA binding sites can be identified in the model.

Photo-induced protein cross-linking to 5S RNA and 28-5.8S RNA within rat-liver 60S ribosomal subunits

Rat liver 60S ribosomal subunits were irradiated with 254-nm ultraviolet light (1.26 X 10(4) quanta/subunit), under conditions which preserved their functional activity. Cross-linked RNA-protein complexes were recovered after unreacted proteins had been removed by repeated acetic acid extractions. Proteins linked to the whole rRNA, to 5S RNA and to 28-5.8 S RNAs were identified by two-dimensional gel electrophoresis after RNA hydrolysis by ribonucleases T1 and A. Our results showed that numerous proteins interact with rRNAs (at least ten with 28-5.8 S RNA, eight with 5S RNA and among these three are common to both) and have been discussed in the light of all the available data.

Ribosomal proteins cross-linked to 28-S and 18-S rRNA separated by sedimentation after ultraviolet irradiation of rat-liver ribosomes

Rat liver 80-S ribosomes, irradiated with 254 nm ultraviolet light for 15-60 min (0.63-2.5 X 10(5) quanta/ribosome), were treated with sodium dodecyl sulfate; 18-S and 28-S RNA fractions were isolated by sucrose density-gradient centrifugation. The protein moieties of the 18-S and 28-S rRNA fractions were labeled with 125I. After digestion of the rRNA fractions with RNase A and T1, the cross-linked proteins were analyzed by two-dimensional acrylamide gel electrophoresis and then autoradiography. Cross-linked proteins were examined further by dodecyl sulfate/acrylamide gel electrophoresis of individual radioactive spots of proteins and their proteolytic peptides on two-dimensional gels. The results showed that S2 and S15 were cross-linked to 18-S rRNA, and L5, L6 and L8 to 28-S rRNA. Similar results were obtained when isolated 40-S or 60-S subunits were irradiated.

The localization of multiple sites on 16S RNA which are cross-linked to proteins S7 and S8 in Escherichia coli 30S ribosomal subunits by treatment with 2-iminothiolane

RNA-protein cross-links were introduced into E. coli 30S ribosomal subunits by reaction with 2-iminothiolane followed by a mild ultraviolet irradiation treatment. After removal of non-reacted protein and partial nuclease digestion of the cross-linked 16S RNA-protein moiety, a number of individual cross-linked complexes could be isolated and the sites of attachment of the proteins to the RNA determined. Protein S8 was cross-linked to the RNA at three different positions, within oligo-nucleotides encompassing positions 629-633, 651-654, and (tentatively) 593-597 in the 16S sequence. Protein S7 was cross-linked within two oligonucleotides encompassing positions 1238-1240, and 1377-1378. In addition, a site at position 723-724 was observed, cross-linked to protein S19, S20 or S21.

A ribonucleoprotein fragment of the 30 S ribosome of E. coli: evidence for long range RNA-RNA interactions

A stable homogeneous ribonucleoprotein fragment of the 30 S ribosomal subunit of E. coli has been prepared by mild nuclease digestion and heating in a constant ionic environment. The fragment contains about half of the 16 S ribosomal RNa and six proteins: S4, S7, S9, S13, S16 and S19. The RNA moiety contains the reported binding sites of all six proteins. After deproteinization, 80% of the RNA migrated as two major electrophoretic bands, which were isolated and sequenced. Each band contained sequences from the 5' and 3' thirds of the 16 S RNA but none from the central third. That these two noncontiguous RNA domains migrated together electrophoretically in Mg++-containing gels after deproteinization constitutes direct evidence that the 16 S RNA is folded in the intact ribosome so as to bring the two domains close together and that there are RNA-RNA interactions between them in the presence of Mg++.

Radiochemical cross-linking between proteins and RNA within 70 S ribosomal particles from E. coli MRE600

In the absence of oxygen, gamma-irradiation produces covalent links between some ribosomal proteins and 16 S RNA to 23 S RNA, within 70 S ribosomes from E. coli MRE600. Under optimal conditions minimizing the structural modifications induced by radiations, in situ formed cross-links appear specific and reflect close RNA-protein contacts. In view of these results, the spatial organization of the 30 S, 50 S subunit interfaces is discussed. In addition, the gamma-irradiation technique reveals that subunit association induces modifications of some protein--RNA interactions.

Study of the interaction between yeast tRNAphe and yeast phenylalanyl-tRNA synthetase by monochromatic ultraviolet irradiation at various wavelengths. Advantages and limits of the method

The interactions between yeast tRNAphe and phenylalanyl-tRNA synthetase were studied by analysis of the covalent adducts obtained upon monochromatic ultraviolet irradiation at different wavelengths (248, 282, 292, 302 and 313 nm). The high extent of inactivation of phenylalanyl-tRNA synthetase, together with the partial modification of tRNA, as well as the peculiar instability of most of the covalent bonds formed upon irradiation constitute severe limitations to the use of the technique and to the interpretation of the results. These disadvantages led us to select an irradiation wavelength of 248 nm and to use only mild isolation procedures allowing a good recovery of the covalent adducts formed. Seven major tryptic peptides of the enzyme were found to be cross-linked to tRNAPhe whereas six major T1-oligonucleotides were covalently linked to the protein, among these, the three cross-linked oligonucleotides previously described by Shoemaker and Schimmel (J. Biol. Chem. 250 (1975) 4440-4444) in the same system. The difference in the number of covalently linked oligonucleotides is discussed in the light of the instability of the covalent linkages. The localization of the six oligonucleotides at the inside of the two branches forming the L-shaped tRNA molecule is similar to that observed in the yeast valine system (Renaud et al., Eur. J. Biochem. 101 (1979) 475-483) and is consistent with the interaction model previously described (Rich and Schimmel, Nucl. Acids Res. 4 (1977) 1649-1665 and Ebel et al. in Transfer RNA: structure, properties and recognition, (1979) pp. 325-343 Cold Spring Harbor Laboratory, NY). The occurrence of covalent cross-linking upon irradiation in the tryptophan absorption band (302 nm) strongly suggests the participation of this residue in the stabilization of the tRNA enzyme complex.

Secondary structure of 16S ribosomal RNA

A secondary structure model for 16S ribosomal RNA which is based on available chemical, enzymatic, and comparative sequence data shows good agreement between constraints dictated by the model and a wide variety of experimental observations. The four major structural domains created by the base-pairing scheme correspond closely to RNA fragments isolated after nuclease digestion in the presence of bound ribosomal proteins. Functionally important sites appear to be located in unpaired regions and are phylogenetically highly conserved.

Identification of a 16-S RNA fragment crosslinked to protein S1 within Escherichia coli ribosomal 30-S subunits by the use of a crosslinking reagent: ethyl 4-azidobenzoylaminoacetimidate

The bifunctional reagent ethyl 4-azidobenzoylaminoacetimidate was used to crosslink specifically ribosomal protein S1 to 16-S RNA within 30-S subunits. The reagent was attached to isolated protein S1. The modified protein was reassociated with protein-S1-depleted 30-S subunits and then crosslinked to the RNA molecule. The covalently bound 16-S RNA-protein S1 complex was isolated and the RNA fragment C-U-A-A-C-G-C-G-U-U-A-A-G-U-C-G-A-C-C-G-C-C-U-G-G-G-G-A-G (positions 861-889) was characterized to be crosslinked to protein S1.

Contact-site cross-linking agents

Contact-site cross-linking agents comprise a heterogeneous grouping of cross-linkers which share the common property of being able to cross-link only very closely juxtaposed residues in macromolecular complexes. We have defined contact-site cross-linking arbitrarily as the covalent joining of residues such that they are constrained to a distance which is equivalent to or less than their closest possible steric approach prior to becoming linked (1). We recognize two classes of contact-site cross-linkers, bridge type and zero-length type. The former, such as formaldehyde, become incorporated during cross-linking as one-atom bridges. The latter, such as the carbodiimides, operate as condensing agents with the result that the cross-linked residues become interjoined directly. Contact-site cross-linkers have been used in several ways as specific probes of both the static and dynamic aspects of macromolecular structure. They can yield precise structural information about macromolecular contacts when actual sites of cross-linking are determined by peptide or nucleotide mapping techniques. In this way exact contacts between histones in the nucleosome, between protein and RNA in the ribosome, and between RNA polymerase and DNA have been determined. Contact-site cross-linkers have also been used to probe the perturbation of contacts following macromolecular conformational changes. Certain histone-histone 'cross-linkable' sites are rendered unreactive after induction of chromatin conformational changes thus serving to localize sites of perturbation.

Feedback regulation of ribosomal protein gene expression in Escherichia coli: structural homology of ribosomal RNA and ribosomal protein MRNA

Certain ribosomal proteins (r proteins) in Escherichia coli, such as S4 and S7, function as feedback repressors in the regulation of r-protein synthesis. These proteins inhibit the translation of their own mRNA. The repressor r proteins so far identified are also known to bind specifically to rRNA at an initial stage in ribosome assembly. We have found structural homology between the S7 binding region on 16S rRNA and a region of the mRNA where S7 acts as a translational repressor. Similarly, there is structural homology between one of the reported S4 binding regions on 16S rRNA and the mRNA target site for S4. The observed homology supports the concept that regulation by repressor r proteins is based on competition between rRNA and mRNA for these proteins and that the same structural features and of the r proteins are used in their interactions with both rRNA and mRNA.

Synthesis of a new reagent, ethyl 4-azidobenzoylaminoacetimidate, and its use for RNA-protein cross-linking within Escherichia coli ribosomal 30-S subunits

A new reagent, ethyl 4-azidobenzoylaminoacetimidate, was prepared in a four-step synthesis starting from 4-aminobenzoic acid. This compound was used to cross-link RNA with proteins within the Escherichia coli 30-S ribosomal subunits. Following the reaction of the imidoester function with protein NH2 groups, photoactivation of the azide binds the other end of the reagent to RNA. The cross-linked proteins were labelled with 125I and identified by bidimensional gel electrophoresis. Proteins S3, S4, S5, S7, S9, S17, S18, and in a lower and more variable yield, S12, S13, S14 and S16 were bound to 16-S RNA. These results were confirmed by isolating cross-linked protein-oligonucleotide complexes from 30-S subunits containing 32P-labelled RNA.

Identification of binding sites of turnip yellow mosaic virus protein and RNA by crosslinks induced in situ

Turnip yellow mosaic virus RNA and protein could be crosslinked in situ by ultraviolet irradiation at pH 4.8 but not at pH 7.3, and by bisulphite treatment at pH 7.3. Crosslinked peptides could be located in the primary structure of the viral coat protein. Three regions were bound covalently by ultraviolet irradiation, and two of these three regions were bound also by bisulphite treatment. The yield of the crosslinking reaction could be high, indicating that almost all protein subunits of each virion reacted with the viral RNA. The crosslinked peptides contain most of the acidic and basic amino acids of the protein, often associated into pairs of opposite charge. Implications for the folding of the RNA into the virion and for models of RNA--protein interactions are discussed.