Positions of S2, S13, S16, S17, S19 and S21 in the 30 S ribosomal subunit of Escherichia coli

Neutron scattering distance data are presented for 33 protein pairs in the 30 S ribosomal subunit from Escherichia coli, along with the methods used for measuring distances between its exchangeable components. When combined with prior data, these new results permit the positioning of S2, S13, S16, S17, S19 and S21 in the 30 S ribosomal subunit, completing the mapping of its proteins by neutron scattering. Comparisons with other data suggest that the neutron map is a reliable guide to the quaternary structure of the 30 S subunit.     

Neutron-scattering studies of the ribosome of Escherichia coli: a provisional map of the locations of proteins S3, S4, S5, S7, S8 and S9 in the 30 S subunit.

Results of neutron-scattering experiments to determine the distances between seven pairs of proteins within the 30 S ribosomal subunit are presented. These results, combined with earlier data (Engelman et al., 1975; Moore et al., 1977) lead to the construction of a three-dimensional map of the positions of the centers of mass of proteins S3, S4, S5, S7, S8 and S9. The properties of this map and its relationship to other information on the structure of the 30 S subunit are discussed.     

Binding of S21 to the 50S subunit and the effect of the 50S subunit on nonradiative energy transfer between the 3' end of 16S RNA and S21

Escherichia coli ribosomal protein S21 was labeled at its single cysteine group with a fluorescent probe. Labeled S21 showed full activity in supporting MS2 RNA-dependent binding of formylmethionyl-tRNAf to 30S ribosomal subunits. Fluorescence anisotropy measurements and direct analysis on glycerol gradients demonstrate conclusively that labeled S21 binds to 50S ribosomal subunits as well as to 30S and 70S particles. The relative binding affinities are in the order 70S greater than 30S greater than 50S. Other results presented appear to indicate that S21 is bound in the same position on either 50S subunits or 30S subunits as in 70S ribosomes, suggesting that the protein is bound simultaneously to both subunits in the latter. Addition of 50S subunits to 30S particles containing probes on S21 and at the 3' end of 16S RNA caused a decrease in the energy transfer between these points. The results correspond to an apparent change in distance from 51 to 61 A.     

Probing the assembly of the 3' major domain of 16 S rRNA. Interactions involving ribosomal proteins S2, S3, S10, S13 and S14

We have used rapid probing methods to follow the changes in reactivity of residues in 16 S rRNA to chemical and enzymatic probes as ribosomal proteins S2, S3, S10, S13 and S14 are assembled into 30 S subunits. Effects observed are confined to the 3' major domain of the RNA and comprise three general classes. (1) Monospecific effects, which are attributable to a single protein. Proteins S13 and S14 each affect the reactivities of different residues which are adjacent to regions previously found protected by S19. S10 effects are located in two separate regions of the domain, the 1120/1150 stem and the 1280 loop; both of these regions are near nucleotides previously found protected by S9. Both S2 and S3 protect different nucleotides between positions 1070 and 1112. In addition, S2 protects residues in the 1160/1170 stem-loop. (2) Co-operative effects, which include residues dependent on the simultaneous presence of both proteins S2 and S3 for their reactivities to appear similar to those observed in native 30 S subunits. (3) Polyspecific effects, where proteins S3 and S2 independently afford the same protection and enhancement pattern in three distal regions of the domain: the 960 stem-loop, the 1050/1200 stem and in the upper part of the domain (nucleotides 1070 to 1190). Proteins S14 and S10 also weakly affect the reactivities of several residues in these regions. We believe that several of the protected residues of the first class are likely sites for protein-RNA contact while the third class is indicative of conformational rearrangement in the RNA during assembly. These results, in combination with the results from our previous study of proteins S7, S9 and S19, are discussed in terms of the assembly, topography and involvement in ribosomal function of the 3' major domain.     

Immunochemical accessibility of ribosomal protein S4 in the 30 S ribosome. The interaction of S4 with S5 and S12

The reactivity of protein S4-specific antibody preparations with 30 S ribosomal subunits and intermediates of in vitro subunit reconstitution has been characterized using a quantitative antibody binding assay. Anti-S4 antibody preparations did not react with native 30 S ribosomal subunits; however, they did react with various subunit assembly intermediates that lacked proteins S5 and S12. The inclusion of proteins S5 and S12 in reconstituted particles resulted in a large decrease in anti-S4 reactivity, and it was concluded that proteins S5 and S12 are primarily responsible for the masking of S4 antigenic determinants in the 30 S subunit. The effect of S5 and S12 on S4 accessibility is consistent with data from a variety of other approaches, suggesting that these proteins form a structural and functional domain in the small ribosomal subunit.     

Positions of proteins S6, S11 and S15 in the 30 S ribosomal subunit of Escherichia coli

A map of the positions of 12 of the 21 proteins of the 30 S ribosomal subunit of Escherichia coli (S1, S3, S4, S5, S6, S7, S8, S9, S10, S11, S12 and S15), based on neutron scattering, is presented and discussed. Estimates for the radii of gyration of these proteins in situ are also obtained. It appears that many ribosomal proteins have compact configurations in the particle.     

Positions of proteins S14, S18 and S20 in the 30 S ribosomal subunit of Escherichia coli

A map of the 30 S ribosomal subunit is presented giving the positions of 15 of its 21 proteins. The components located in the map are S1, S3, S4, S5, S6, S7, S8, S9, S10, S11, S12, S14, S15, S18 and S20.     

Interaction of ribosomal proteins, S6, S8, S15 and S18 with the central domain of 16 S ribosomal RNA

We have constructed complexes of ribosomal proteins S8, S15, S8 + S15 and S8 + S15 + S6 + S18 with 16 S ribosomal RNA, and probed the RNA moiety with a set of structure-specific chemical and enzymatic probes. Our results show the following effects of assembly of proteins on the reactivity of specific nucleotides in 16 S rRNA. (1) In agreement with earlier work, S8 protects nucleotides in and around the 588-606/632-651 stem from attack by chemical probes; this is supported by protection in and around these same regions from nucleases. In addition, we observe protection of positions 573-575, 583, 812, 858-861 and 865. Several S8-dependent enhancements of reactivity are found, indicating that assembly of this protein is accompanied by conformational changes in 16 S rRNA. These results imply that protein S8 influences a much larger region of the central domain than was previously suspected. (2) Protein S15 protects nucleotides in the 655-672/734-751 stem, in agreement with previous findings. We also find S15-dependent protection of nucleotides in the 724-730 region. Assembly of S15 causes several enhancements of reactivity, the most striking of which are found at G664, A665, G674, and A718. (3) The effects of proteins S6 and S18 are dependent on the simultaneous presence of both proteins, and on the presence of protein S15. S6 + S18-dependent protections are located in the 673-730 and 777-803 regions. We observed some variability in our results with these proteins, depending on the ratio of protein to RNA used, and in different trials using enzymatic probes, possibly due to the limited solubility of protein S18. Consistently reproducible was protection of nucleotides in the 664-676 and 715-729 regions. Among the latter are three of the nucleotides (G664, G674 and A718) that are strongly enhanced by assembly of protein S15. This result suggests that an S15-induced conformational change involving these nucleotides may play a role in the co-operative assembly of proteins S6 and S18.     

Positions of proteins S10, S11 and S12 in the 30 S ribosomal subunit of Escherichia coli.

The results of 17 new neutron distance measurements on protein pairs within the 30 S ribosomal subunit are reported. A partial map of the structure is presented giving the locations of S3, S4, S5, S7, S8, S9, S10, S11 and S12. This map is compared to other information on ribosomal organization and function.     

Further evidence that the ribosomal 30S proteins S3, S5, S9, S11, S12, and S18 possess specific 16S RNA binding sites

Summary E. coli ribosomal 16S RNA preparted by an acetic acid-urea extraction technique individually binds, in addition to the seven established proteins, 6 new 30S ribosomal proteins (S3, S5, S9, S12, S18 and S11) (Hochkeppel et al., 1976). In this communication we demonstrate the site specificity of these proteins. Binding curves of the individual proteins with acetic acid-urea 16S RNA show that the binding of all six proteins to the RNA reaches a plateau at 0.3–0.97 copies per 16S RNA molecule. No significant binding of these proteins to classical phenol extracted 16S RNA is observed, with the exception of S13 which binds 0.2 copies of protein per molecule of 16S RNA. Specificity of binding of these proteins is also demonstrated in chase experiments. The site specificity of individual [³H]-labeled 30S proteins bound to 16S RNA is tested by the addition of non-radioactive 30S total protein to the reaction mixture.     

The first position of a codon placed in the A site of the human 80S ribosome contacts nucleotide C1696 of the 18S rRNA as well as proteins S2, S3, S3a, S30, and S15

Messenger RNA analogues (42-mers) containing a GAC codon (aspartic acid) in the middle of their sequence followed by a s(4)UGA stop codon were used to identify the components of the human ribosomal A site in direct contact with the photoactivatable 4-thiouridine (s(4)U) residue. We compared the behavior of the nonphased ribosome-mRNA complex, (-)tRNA(Asp), to the one of the phased complex, (+)tRNA(Asp), in the absence and in the presence of eRF1, the eukaryotic class 1 translation termination factor of human origin. The patterns of cross-links obtained for the three complexes were similar to those previously reported for rabbit ribosomes [Chavatte, L., et al. (2001) Eur. J. Biochem. 268, 2896-2904]. Cross-links involving proteins S2, S3, S3a, and S30 were poorly dependent on the presence of tRNA(Asp) and eRF1. Cross-linking to nucleotide C1696 of 18S rRNA occurred in all complexes, but its yield was at least two times higher in the phased complex with an empty A site than in the nonphased complex or when the A site was occupied by eRF1. In contrast, protein S15 cross-linked only in the phased complex in the absence of eRF1. The data obtained point to notable differences in organization of the decoding site between mammalian and prokaryotic ribosomes and to large internal mobility of the components of the tRNA (eRF1)-free A site.     

Genomic organization of the S core region and the S flanking regions of a class-II S haplotype in Brassica rapa

The nucleotide sequence of an 86.4-kb region that includes the SP11, SRK, and SLG genes of Brassica rapa S-60 (a class-II S haplotype) was determined. In the sequenced region, 13 putative genes were found besides SP11-60, SRK-60, and SLG-60. Five of these sequences were isolated as cDNAs, five were homologues of known genes, cDNAs, or ORFs, and three are hypothetical ORFs. Based on their nucleotide sequences, however, some of them are thought to be non-functional. Two regions of colinearity between the class-II S-60 and Brassica class-I S haplotypes were identified, i.e., S flanking region 1 which shows partial colinearity of non-genic sequences and S flanking region 2 which shows a high level of colinearity. The observed colinearity made it possible to compare the order of SP-11, SRK, and SLG genes in the S locus between the five sequenced S haplotypes. It emerged that the order of SRK and SLG in class-II S-60 is the reverse of that in the four class-I S haplotypes reported so far, and the order of SP11, SRK and SLG is the opposite of that in the class-I haplotype S-910. The possible gene designated as SAN1 (S locus Anther-expressed Non-coding RNA like-1), which is located in the region between SP11-60 and SRK-60, has features reminiscent of genes for non-coding RNAs (ncRNAs), but no homologous sequences were found in the databases. This sequence is transcribed in anthers but not in stigmas or leaves. These features of the genomic structure of S-60 are discussed with special reference to the characteristics of class-II S haplotypes.     

Interferon-gamma engages the p70 S6 kinase to regulate phosphorylation of the 40S S6 ribosomal protein

The signals generated by the IFNgamma receptor to initiate mRNA translation and generation of protein products that mediate IFNgamma responses are largely unknown. In the present study, we provide evidence for the existence of an IFNgamma-dependent signaling cascade activated downstream of the phosphatidylinositol (PI) 3'-kinase, involving the mammalian target of rapamycin (mTOR) and the p70 S6 kinase. Our data demonstrate that p70 S6K is rapidly phosphorylated and activated during engagement of the IFNgamma receptor in sensitive cell lines. Such activation of p70 S6 kinase is blocked by pharmacological inhibitors of the PI 3' kinase and mTOR, and is abrogated in double-knockout mouse embryonic fibroblasts for the alpha and beta isoforms of the p85 regulatory subunit of the PI 3'-kinase. The IFNgamma-activated p70 S6 kinase subsequently phosphorylates the 40S S6 ribosomal protein on serines 235/236, to regulate IFNgamma-dependent mRNA translation. In addition to phosphorylation of 40S ribosomal protein, IFNgamma also induces phosphorylation of the 4E-BP1 repressor of mRNA translation on threonines 37/46, threonine 70, and serine 65, sites whose phosphorylation is required for the inactivation of 4E-BP1 and its dissociation from the eukaryotic initiation factor-4E (eIF4E) complex. Thus, engagement of the PI 3'-kinase and mTOR by the IFNgamma receptor results in the generation of two distinct signals that play roles in the initiation of mRNA translation, suggesting an important role for this pathway in IFNgamma signaling.     

Assembly of the 30S ribosomal subunit: positioning ribosomal protein S13 in the S7 assembly branch

Studies of Escherichia coli 30S ribosomal subunit assembly have revealed a hierarchical and cooperative association of ribosomal proteins with 16S ribosomal RNA; these results have been used to compile an in vitro 30S subunit assembly map. In single protein addition and omission studies, ribosomal protein S13 was shown to be dependent on the prior association of ribosomal protein S20 for binding to the ribonucleoprotein particle. While the overwhelming majority of interactions revealed in the assembly map are consistent with additional data, the dependency of S13 on S20 is not. Structural studies position S13 in the head of the 30S subunit > 100 A away from S20, which resides near the bottom of the body of the 30S subunit. All of the proteins that reside in the head of the 30S subunit, except S13, have been shown to be part of the S7 assembly branch, that is, they all depend on S7 for association with the assembling 30S subunit. Given these observations, the assembly requirements for S13 were investigated using base-specific chemical footprinting and primer extension analysis. These studies reveal that S13 can bind to 16S rRNA in the presence of S7, but not S20. Additionally, interaction between S13 and other members of the S7 assembly branch have been observed. These results link S13 to the 3' major domain family of proteins, and the S7 assembly branch, placing S13 in a new location in the 30S subunit assembly map where its position is in accordance with much biochemical and structural data.     

Structural motifs of the bacterial ribosomal proteins S20, S18 and S16 that contact rRNA present in the eukaryotic ribosomal proteins S25, S26 and S27A,respectively

The majority of constitutive proteins in the bacterial 30S ribosomal subunit have orthologues in Eukarya and Archaea. The eukaryotic counterparts for the remainder (S6, S16, S18 and S20) have not been identified. We assumed that amino acid residues in the ribosomal proteins that contact rRNA are to be constrained in evolution and that the most highly conserved of them are those residues that are involved in forming the secondary protein structure. We aligned the sequences of the bacterial ribosomal proteins from the S20p, S18p and S16p families, which make multiple contacts with rRNA in the Thermus thermophilus 30S ribosomal subunit (in contrast to the S6p family), with the sequences of the unassigned eukaryotic small ribosomal subunit protein families. This made it possible to reveal that the conserved structural motifs of S20p, S18p and S16p that contact rRNA in the bacterial ribosome are present in the ribosomal proteins S25e, S26e and S27Ae, respectively. We suggest that ribosomal protein families S20p, S18p and S16p are homologous to the families S25e, S26e and S27Ae, respectively.     

Interaction of ribosomal proteins S6, S8, S15 and S18 with the central domain of 16 S ribosomal RNA from Escherichia coli

The co-operative interaction of 30 S ribosomal subunit proteins S6, S8, S15 and S18 with 16 S ribosomal RNA from Escherichia coli was studied by (1) determining how the binding of each protein is influenced by the others and (2) characterizing a series of protein-rRNA fragment complexes. Whereas S8 and S15 are known to associate independently with the 16 S rRNA, binding of S18 depended upon S8 and S15, and binding of S6 was found to require S8, S15 and S18. Ribonucleoprotein (RNP) fragments were derived from the S8-, S8/S15- and S6/S8/S15/S18-16 S rRNA complexes by partial RNase hydrolysis and isolated by electrophoresis through Mg2+-containing polyacrylamide gels or by centrifugation through sucrose gradients. Identification of the proteins associated with each RNP by gel electrophoresis in the presence of sodium dodecyl sulfate demonstrated the presence of S8, S8 + S15 and S6 + S8 + S15 + S18 in the corresponding fragment complexes. Analysis of the rRNA components of the RNP particles confirmed that S8 was bound to nucleotides 583 to 605 and 624 to 653, and that S8 and S15 were associated with nucleotides 583 to 605, 624 to 672 and 733 to 757. Proteins S6, S8, S15 and S18 were shown to protect nucleotides 563 to 605, 624 to 680, 702 to 770, 818 to 839 and 844 to 891, which span the entire central domain of the 16 S rRNA molecule (nucleotides 560 to 890). The binding site for each protein contains helical elements as well as single-stranded internal loops ranging in size from a single bulged nucleotide to 20 bases. Three terminal loops and one stem-loop structure within the central domain of the 16 S rRNA were not protected in the four-protein complex. Interestingly, bases within or very close to these unprotected regions have been shown to be accessible to chemical and enzymatic probes in 30 S subunits but not in 70 S ribosomes. Furthermore, nucleotides adjacent to one of the unprotected loops have been cross-linked to a region near the 3' end of 16 S rRNA. Our observations and those of others suggest that the bases in this domain that are not sequestered by interactions with S6, S8, S15 or S18 play a role involved in subunit association or in tertiary interactions between portions of the rRNA chain that are distant from one-another in the primary structure.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mapping subunit contacts in the regulatory complex of the 26 S proteasome. S2 and S5b form a tetramer with ATPase subunits S4 and S7

The 19 S regulatory complex (RC) of the 26 S proteasome is composed of at least 18 different subunits, including six ATPases that form specific pairs S4-S7, S6-S8, and S6'-S10b in vitro. One of the largest regulatory complex subunits, S2, was translated in reticulocyte lysate containing [(35)S]methionine and used to probe membranes containing SDS-polyacrylamide gel electrophoresis separated RC subunits. S2 bound to two ATPases, S4 and S7. Association of S2 with regulatory complex subunits was also assayed by co-translation and sedimentation. S2 formed an immunoprecipitable heterotrimer upon co-translation with S4 and S7. The non-ATPase S5b also formed a ternary complex with S4 and S7 and the three proteins assembled into a tetramer with S2. Neither S2 nor S5b formed complexes with S6'-S10b dimers or with S6-S8 oligomers. The use of chimeric ATPases demonstrated that S2 binds the NH(2)-terminal region of S4 and the COOH-terminal two-thirds of S7. Conversely, S5b binds the COOH-terminal two-thirds of S4 and to S7's NH(2)-terminal region. The demonstrated association of S2 with ATPases in the mammalian 19 S regulatory complex is consistent with and extends the recent finding that the yeast RC is composed of two subcomplexes, the lid and the base (Glickman, M. H., Rubin, D. M., Coux, O., Wefes, I., Pfeifer, G., Cejka, Z., Baumeister, W., Fried, V. A., and Finley, D. (1998) Cell 94, 615-623).     

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.