Functional topography of human ribosomes as studied by affinity labeling with reactive mRNA analogs.

Derivatives of 5'-32P labeled (pU)3 an (pU)6 bearing 4-(N-2-chloroethyl-N-methylamino)benzylmethylamine residue attached to 5'-phosphate via phosphamide bond and (Up)5U[32P]pC and (Up)11U[32P]pC bearing 4-(N-2-chloroethyl-N-methylamino)benzyl residue attached to 3'-end via benzylidene bond were applied for the affinity labeling of 80S ribosomes from human placenta in the presence of a cognate tRNA. The derivatives of 32P-labeled pAUG and pAUGU3 analogous to the 5'-phosphamides of (pU)n were used for affinity labeling of 40S subunits in the presence of ternary complex eIF-2.GTP.Met-tRNA(f). The sites of the reagents' attachment to 18S ribosomal RNA were identified by blot-hybridization of the modified 18S rRNA with restriction fragments of the corresponding rDNA. They were found to be located within positions 976-1057 for (pU)6 and pAUGU3 derivatives and within 976-1164 for (pU)3 and pAUG ones. The sites of 18S rRNA modification with the derivatives of (Up)5UpC and (Up)11UpC were found within positions 1610-1869 at 3'-end of the molecule. All the sites identified here are located presumably within highly conserved parts of the eukaryotic small subunit rRNA secondary structure.     

The proteins of the messenger RNA binding site of Escherichia coli ribosomes.

Oligo(U) derivatives with [14C]-4-(N-2-chloroethyl-N-methylamino)benzaldehyde attached to 3'-end cis-diol group via acetal bond, p(Up)n-1UCHRCl as well as with [14C]-4-(N-2-chloroethyl-N-methylamino)benzylamine attached to 5'-phosphate via amide bond, ClRCH2NHpU(pU)6 were used to modify 70S E. coli ribosomes near mRNA binding centre. Within ternary complex with ribosome and tRNAPhe all reagents covalently bind to ribosome the extent of modification being 0.1-0.4 mole/mole 70S. p(Up)n-1UCHRCl alkylates either 30S (n=5,7) or both subunits (n=6,8). rRNA is preferentially modified within 30S subunit. ClRCH2NHpU(pU)6 alkylates both subunits the proteins being mainly modified. The distribution of the label among proteins differ for various reagents. S4, S5, S7, S9, S11, S13, S15, S18 and S21 are found to be alkylated within 30S subunit, proteins L1, L2, L6, L7/L12, L19, L31 and L32 are modified in the 50S subunit. Most proteins modified within 30S subunit are located at the "head" of this subunit and proteins modified within 50S subunit are located at the surface of the contact between this subunit and the "head" of 30S subunit at the model of Stoffler.     

Affinity modification of the 40S subparticle from human placenta with derivatives of pAUG and pAUGU3]

Affinity labeling of 40S subunits from human placenta with 4-(N-2-chloroethyl-N-methylamino)benzylmethyl-[32P]phosphoamide s of oligoribonucleotides pAUG and pAUGU3 was studied. Covalent attachment of these derivatives to 40S subunits within the complexes with 40S subunits, formed in the presence of Met-tRNAf.eIF-2.GTP, was detected. Both rRNA and ribosomal proteins were modified. Fragments of 18S rRNA, containing sites of the reagent attachment were identified: 1058-1164 for pAUG derivative and 976-1057--for pAUG and pAUGU3 ones. The data obtained allowed to conclude that the presence of the neighbouring codon at the A-site, regardless of the presence of the tRNA in it, affects significantly the arrangement of the trinucleotide template in the codon-anticodon interaction region. The large subunit does not cause significant alterations in the structural organization of the codon-anticodon interaction region.     

Ribosomal protein-dependent orientation of the 16 S rRNA environment of S15

Ribosomal protein S15 binds specifically to the central domain of 16 S ribosomal RNA (16 S rRNA) and directs the assembly of four additional proteins to this domain. The central domain of 16 S rRNA along with these five proteins form the platform of the 30 S subunit. Previously, directed hydroxyl radical probing from Fe(II)-S15 in small ribonucleoprotein complexes was used to study assembly of the central domain of 16 S rRNA. Here, this same approach was used to understand the 16 S rRNA environment of Fe(II)-S15 in 30 S subunits and to determine the ribosomal proteins that are involved in forming the mature S15-16 S rRNA environment. We have identified additional sites of Fe(II)-S15-directed cleavage in 30S subunits compared to the binary complex of Fe(II)-S15/16 S rRNA. Along with novel targets in the central domain, sites within the 5' and 3' minor domains are also cleaved. This suggests that during the course of 30S subunit assembly these elements are positioned in the vicinity of S15. Besides the previously determined role for S8, roles for S5, S6+S18, and S16 in altering the 16 S rRNA environment of S15 were established. These studies reveal that ribosomal proteins can alter the assembly of regions of the 30 S subunit from a considerable distance and influence the overall conformation of this ribonucleoprotein particle.     

Crosslinking of ribosomal protein S18 to 16 S RNA in E.coli ribosomal 30 S subunits by the use of a reversible crosslinking agent: trans-diamminedichloroplatinum(II)

We have previously developed [(1987) Biochemistry 26, 5200-5208] the use of trans-diamminedichloroplatinum(II) to induce reversible RNA-protein crosslinks in the ribosomal 30 S subunit. Protein S18 and, to a lesser extent, proteins S13/S14, S11, S4 and S3 could be crosslinked to the 16 S rRNA. The aim of the present work was to identify the crosslinking sites of protein S18. Three sites could be detected: a major one located in region 825-858, and two others located in regions 434-500 and 233-297. This result is discussed in the light of current knowledge of the topographical localization of S18 in the 30 S subunit and of its relation with function.     

Intermolecular base-paired interaction between complementary sequences present near the 3'' ends of 5S rRNA and 18S (16S) rRNA might be involved in the reversible association of ribosomal subunits.

Highly conserved sequences present at an identical position near the 3' ends of eukaryotic and prokaryotic 5S rRNAs are complementary to the 5' strand of the m2(6)A hairpin structure near the 3' ends of 18S rRNA and 16S rRNA, respectively. The extent of base-pairing and the calculated stabilities of the hybrids that can be constructed between 5S rRNAs and the small ribosomal subunit RNAs are greater than most, if not all, RNA-RNA interactions that have been implicated in protein synthesis. The existence of complementary sequences in 5S rRNA and small ribosomal subunit RNA, along with the previous observation that there is very efficient and selective hybridization in vitro between 5S and 18S rRNA, suggests that base-pairing between 5S rRNA in the large ribosomal subunit and 18S (16S) rRNA in the small ribosomal subunit might be involved in the reversible association of ribosomal subunits. Structural and functional evidence supporting this hypothesis is discussed.     

Nucleotides of 18S rRNA surrounding mRNA codons at the human ribosomal A, P, and E sites: a crosslinking study with mRNA analogs carrying an aryl azide group at either the uracil or the guanine residue

The 18S rRNA environment of the mRNA at the decoding site of human 80S ribosomes has been studied by cross-linking with derivatives of hexaribonucleotide UUUGUU (comprising Phe and Val codons) that carried a perfluorophenylazide group either at the N7 atom of the guanine or at the C5 atom of the 5'-terminal uracil residue. The location of the codons on the ribosome at A, P, or E sites has been adjusted by the cognate tRNAs. Three types of complexes have been obtained for each type derivative, namely, (1) codon UUU and Phe-tRNAPhe at the P site (codon GUU at the A site), (2) codon UUU and tRNAPhe at the P site and PheVal-tRNAVal at the A site, and (3) codon GUU and Val-tRNAVal at the P site (codon UUU at the E site). This allowed the placement of modified nucleotides of the mRNA analog at positions -3, +1, or +4 on the ribosome. Mild UV irradiation resulted in tRNA-dependent crosslinking of the mRNA analogs to the 18S rRNA. Nucleotide G961 crosslinked to mRNA position -3, nucleotide G1207 to position +1, and A1823 together with A1824 to position +4. All of these nucleotides are located in the most strongly conserved regions of the small subunit RNA structure, and correspond to nucleotides G693, G926, G1491, and A1492 of bacterial 16S rRNA. Three of them (with the exception of G1491) had been found earlier at the 70S ribosomal decoding site. The similarities and differences between the 16S and 18S rRNA decoding sites are discussed.     

The ribosomal neighbourhood of the central fold of tRNA: cross-links from position 47 of tRNA located at the A, P or E site.

The naturally occurring nucleotide 3-(3-amino-3-carboxy-propyl)uridine (acp3U) at position 47 of tRNA(Phe) from Escherichia coli was modified with a diazirine derivative and bound to ribosomes in the presence of suitable mRNA analogues under conditions specific for the ribosomal A, P or E sites. After photo-activation at 350 nm the cross-links to ribosomal proteins and RNA were identified by our standard procedures. In the 30S subunit protein S19 (and weakly S9 and S13) was the target of cross-linking from tRNA at the A site, S7, S9 and S13 from the P site and S7 from the E site. Similarly, in the 50S subunit L16 and L27 were cross-linked from the A site, L1, L5, L16, L27 and L33 from the P site and L1 and L33 from the E site. Corresponding cross-links to rRNA were localized by RNase H digestion to the following areas: in 16S rRNA between positions 687 and 727 from the P and E sites, positions 1318 and 1350 (P site) and 1350 and 1387 (E site); in the 23S rRNA between positions 865 and 910 from the A site, 1845 and 1892 (P site), 1892 and 1945 (A site), 2282 and 2358 (P site), 2242 and 2461 (P and E sites), 2461 and 2488 (A site), 2488 and 2539 (all three sites) and 2572 and 2603 (A and P sites). In most (but not all) cases, more precise localizations of the cross-link sites could be made by primer extension analysis.     

Study of the mRNA-binding region of ribosomes at different steps of translation. II. Affinity modification of Escherichia coli ribosomes by benzylidene derivative of AUGU6 in the 70S initiation complex

2',3'-O-(4-[N-(2-chloroethyl)-N-methylamino]) benzylidene derivative of AUGU6 was used for identification of the proteins in the region of the mRNA-binding centre of E. coli ribosomes. This derivative alkylated ribosomes (preferentially 30S ribosomal) with high efficiency within the 70S initiation complex. In both 30S and 50S ribosomal subunits proteins and rRNA were modified. Specificity of the alkylation of ribosomal proteins and rRNA with the reagent was proved by the inhibitory action of AUGU6. Using the method of two-dimensional electrophoresis in polyacrylamide gel the proteins S4, S12, S13, S14, S15, S18, S19 and S20/L26 which are labelled by the analog of mRNA were identified.     

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.     

Identification by RNA-protein cross-linking of ribosomal proteins located at the interface between the small and the large subunits of mammalian ribosomes

Protein constituents at the subunit interface of rat liver ribosomes were analysed by cross-linking with the bifunctional reagent, diepoxybutane (distance between reactive groups 4 A). Isolated 40S and 60S subunits were labelled with 125I and recombined with unlabelled complementary subunits. The two kinds of selectively labelled 80S ribosomes were treated with diepoxybutane at low concentration. Radioactive ribosomal proteins covalently attached to the rRNA of the unlabelled complementary subparticles were isolated by repeated gradient centrifugation. The RNA-bound, labelled proteins were identified by two-dimensional gel electrophoresis. The experiments showed that proteins S2, S3, S4, S6, S7, S13, and S14 in the small subunit of rat liver ribosomes are located at the ribosomal interface in close proximity to 28S rRNA. Similarly, proteins L3, L6, L7, and L8 were found at the the interface of the large ribosomal subunit in the close vicinity of 18S rRNA.     

Mapping the three-dimensional locations of ribosomal RNA and proteins.

Seven regions of 16S rRNA have been located on the surface of the 30S ribosomal subunit by DNA hybridization electron microscopy in our laboratory. In addition, we have recently mapped the three-dimensional locations of an additional seven small ribosomal proteins by immunoelectron microscopy. The information from the direct mapping of the sites on rRNA has been incorporated into a model for the tertiary structure of 16S rRNA, accounting for approximately 40% of the total 16S rRNA. A novel structure, the platform ring, is proposed for a region of rRNA within the central domain. This structure rings the edges of the platform and includes regions 655-751 and 769-810. Another region, the recognition complex, consists of nucleotides 500-545, and occupies a region on the exterior surface of the subunit, near the EF-Tu binding site. In addition, 19 of the 21 small subunit ribosomal proteins have been mapped by immunoelectron microscopy in our laboratory. In order to evaluate the reliability of our model for the three-dimensional distribution of 16S rRNA, we have predicted which sites of rRNA are adjacent to ribosomal proteins and compared these predictions with r-protein protection studies of others. Good correlation between the model, the locations of rRNA sites, the locations of ribosomal proteins, and regions of rRNA protected by ribosomal proteins, provides independent support for this model.     

Probing the conformational changes in 5.8S, 18S and 28S rRNA upon association of derived subunits into complete 80S ribosomes.

The participation of 18S, 5.8S and 28S ribosomal RNA in subunit association was investigated by chemical modification and primer extension. Derived 40S and 60S ribosomal subunits isolated from mouse Ehrlich ascites cells were reassociated into 80S particles. These ribosomes were treated with dimethyl sulphate and 1-cyclohexyl-3-(morpholinoethyl) carbodiimide metho-p-toluene sulfonate to allow specific modification of single strand bases in the rRNAs. The modification pattern in the 80S ribosome was compared to that of the derived ribosomal subunits. Formation of complete 80S ribosomes altered the extent of modification of a limited number of bases in the rRNAs. The majority of these nucleotides were located to phylogenetically conserved regions in the rRNA but the reactivity of some bases in eukaryote specific sequences was also changed. The nucleotides affected by subunit association were clustered in the central and 3'-minor domains of 18S rRNA as well as in domains I, II, IV and V of 5.8/28S rRNA. Most of the bases became less accessible to modification in the 80S ribosome, suggesting that these bases were involved in subunit interaction. Three regions of the rRNAs, the central domain of 18S rRNA, 5.8S rRNA and domain V in 28S rRNA, contained bases that showed increased accessibility for modification after subunit association. The increased reactivity indicates that these regions undergo structural changes upon subunit association.     

Protein-RNA crosslinking in Escherichia coli 30S ribosomal subunits. Identification of a 16S rRNA fragment crosslinked to protein S12 by the use of the chemical crosslinking reagent 1-ethyl-3-dimethyl-aminopropylcarbodiimide.

1-ethyl-3-dimethyl aminopropylcarbodiimide (EDC) was used to cross-link 30S ribosomal proteins to 16S rRNA within the E. coli 3OS ribosomal subunit. Covalently linked complexes containing 30S proteins and 16S rRNA, isolated by sedimentation of dissociated crosslinked 30S subunits through SDS containing sucrose gradients, were digested with RNase T1, and the resulting oligonucleotide-protein complexes were fractionated on SDS containing polyacrylamide gels. Eluted complexes containing 30S proteins S9 and S12 linked to oligonucleotides were obtained in pure form. Oligonucleotide 5'terminal labelling was successful in the case of S12 containing but not of the S9 containing complex and led to identification of the S12 bound oligonucleotide as CAACUCG which is located at positions 1316-1322 in the 16S rRNA sequence. Protein S12 is crosslinked to the terminal G of this heptanucleotide.     

Probing the structure of mouse Ehrlich ascites cell 5.8S, 18S and 28S ribosomal RNA in situ.

The secondary structure of mouse Ehrlich ascites 18S, 5.8S and 28S ribosomal RNA in situ was investigated by chemical modification using dimethyl sulphate and 1-cyclohexyl-3-(morpholinoethyl) carbodiimide metho-p-toluene sulphonate. These reagents specifically modify unpaired bases in the RNA. The reactive bases were localized by primer extension followed by gel electrophoresis. The three rRNA species were equally accessible for modification i.e. approximately 10% of the nucleotides were reactive. The experimental data support the theoretical secondary structure models proposed for 18S and 5.8/28S rRNA as almost all modified bases were located in putative single-strand regions of the rRNAs or in helical regions that could be expected to undergo dynamic breathing. However, deviations from the suggested models were found in both 18S and 28S rRNA. In 18S rRNA some putative helices in the 5'-domain were extensively modified by the single-strand specific reagents as was one of the suggested helices in domain III of 28S rRNA. Of the four eukaryote specific expansion segments present in mouse Ehrlich ascites cell 28S rRNA, segments I and III were only partly available for modification while segments II and IV showed average to high modification.     

Interaction of human and Escherichia coli tRNA(Phe) with human 80S ribosomes in the presence of oligo- and polyuridylate templates.

Human placenta and Escherichia coli Phe-tRNA(Phe) and N-AcPhe-tRNA(Phe) binding to human placenta 80S ribosomes was studied at 13 mM Mg2+ and 20 degrees C in the presence of poly(U), (pU)6 or without a template. Binding properties of both tRNA species were studied. Poly(U)-programmed 80S ribosomes were able to bind charged tRNA at A and P sites simultaneously under saturating conditions resulting in effective dipeptide formation in the case of Phe-tRNA(Phe). Affinities of both forms of tRNA(Phe) to the P site were similar (about 1 x 10(7) M-1) and exceeded those to the A site. Affinity of the deacylated tRNA(Phe) to the P site was much higher (association constant > 10(10) M-1). Binding at the E site (introduced into the 80S ribosome by its 60S subunit) was specific for deacylated tRNA(Phe). The association constant of this tRNA to the E site when A and P sites were preoccupied with N-AcPhe-tRNA(Phe) was estimated as (1.7 +/- 0.1) x 10(6) M-1. In the presence of (pU)6, charged tRNA(Phe) bound loosely at the A and P sites, and the transpeptidation level exceeded the binding level due to the exchange with free tRNA from solution. Affinities of aminoacyl-tRNA to the A and P sites in the presence of (pU)6 seem to be the same and much lower than those in the case of poly(U). Without a messenger, binding of the charged tRNA(Phe) to 80S ribosomes was undetectable, although an effective transpeptidation was observed suggesting a very labile binding of the tRNA simultaneously at the A and P sites.     

Neighbourhood of the central fold of the tRNA molecule bound to the E. coli ribosome--affinity labeling studies with modified tRNAs carrying photoreactive probes attached to the dihydrouridine loop.

The neighbourhood of the dihydrouridine loop of tRNA molecule bound to E. coli ribosome has been studied by affinity labeling, using modified tRNAs carrying photoreactive azidonitrophenyl probes attached to the 3-(3-amino-3-carboxypropyl)-uridine located at position 20:1 of Lupin methionine elongator tRNA. The maximum distance between the pyrimidine ring and the azido group estimated for the two probes employed in this study is 10-11 A and 18-19 A, respectively. Cross-linking of the uncharged, modified tRNAs has been studied with poly(A, U, G) as a message, under conditions directing uncharged tRNAs preferentially to the ribosomal P-site. Modified tRNAs bind covalently to both ribosomal subunits with high yields upon irradiation of the respective non-covalent complexes. Proteins S7, L33 and L1 have been consistently found cross-linked to tRNAs modified with both probes, and S5 and L5 to tRNA modified with the longer probe. Surprisingly, an S5-tRNA cross-linking product is reproducibly found in a protein fraction prepared from the purified 50S subunit. Cross-linking to rRNAs is significant only for the longer probe and is stimulated 2-4 fold in the presence of poly(A,U,G). The cross-linking sites are located between nucleotides 1302 and 1398 in 16S rRNA and between nucleotides 2281 and 2358 in 23S rRNA.