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.     

A covariant change of the two highly conserved bases in the GTPase-associated center of 28 S rRNA in silkworms and other moths

The GTPase-associated center in 23/28 S rRNA is one of the most conserved functional domains throughout all organisms. We detected a unique sequence of this domain in Bombyx mori species in which the bases at positions 1094 and 1098 (numbering from Escherichia coli 23 S rRNA) are C and G instead of the otherwise universally conserved bases U and A, respectively. These changes were also observed in four other species of moths, but not in organisms other than the moths. Characteristics of the B. mori rRNA domain were investigated by native polyacrylamide gel electrophoresis using RNA fragments containing residues 1030-1128. Although two bands of protein-free RNA appeared on gel, they shifted to a single band when bound to Bombyx ribosomal proteins Bm-L12 and Bm-P complex, equivalent to E. coli L11 and L8, respectively. Bombyx RNA showed lower binding capacity than rat RNA for the ribosomal proteins and anti-28 S autoantibody, specific for a folded structure of the eukaryotic GTPase-associated domain. When the C(1094)/G(1098) bases in Bombyx RNA were replaced by the conserved U/A bases, the protein-free RNA migrated as a single band, and the complex formation with Bm-L12, Bm-P complex, and anti-28 S autoantibody was comparable to that of rat RNA. The results suggest that the GTPase-associated domain of moth-type insects has a labile structural feature that is caused by an unusual covariant change of the U(1094)/A(1098) bases to C/G.     

The secondary structure of the protein L1 binding region of ribosomal 23S RNA. Homologies with putative secondary structures of the L11 mRNA and of a region of mitochondrial 16S rRNA.

An heterologous complex was formed between E. coli protein L1 and P. vulgaris 23S RNA. We determined the primary structure of the RNA region which remained associated with protein L1 after RNase digestion of this complex. We also identified the loci of this RNA region which are highly susceptible to T1, S1 and Naja oxiana nuclease digestions respectively. By comparison of these results with those previously obtained with the homologous regions of E. coli and B. stearothermophilus 23S RNAs, we postulate a general structure for the protein L1 binding region of bacterial 23S RNA. Both mouse and human mit 16S rRNAs and Xenopus laevis and Tetrahymena 28S rRNAs contain a sequence similar to the E. coli 23s RNS region preceding the L1 binding site. The region of mit 16S rRNA which follows this sequence has a potential secondary structure bearing common features with the L1-associated region of bacterial 23S rRNA. The 5'-end region of the L11 mRNA also has several sequence potential secondary structures displaying striking homologies with the protein L1 binding region of 23S rRNA and this probably explains how protein L1 functions as a translational repressor. One of the L11 mRNA putative structures bears the features common to both the L1-associated region of bacterial 23S rRNA and the corresponding region of mit 16S rRNA.     

Defining the structural requirements for a helix in 23 S ribosomal RNA that confers erythromycin resistance

The helix spanning nucleotides 1198 to 1247 (helix 1200-1250) in Escherichia coli 23 S ribosomal RNA (rRNA) is functionally important in protein synthesis, and deletions in this region confer erythromycin resistance. In order to define the structural requirements for resistance, we have dissected this region using in vitro mutagenesis. Erythromycin resistance is established after a minimal deletion of three bases, CAU1231 or AUG1232. The maximum deletion observed to confer resistance is 25 bases. The level of erythromycin resistance conferred by intermediate sized deletions is variable and some deletion mutants show a sensitive phenotype. Deletions that extend into the base-pairing between GCC1208 and GGU1240 result in non-functional 23 S RNAs, which consequently do not confer resistance. A number of phylogenetically conserved nucleotides have been shown to be non-essential for 23 S RNA function. However, removal of either these or non-conserved nucleotides from helix 1200-1250 measurably reduces the efficiency of 23 S RNA in forming functional ribosomes. We have used chemical probing and a modified primer extension method to investigate erythromycin binding to wild-type and resistant ribosomes with a 12-base deletion in 23 S RNA. Erythromycin interacts as strongly with mutant 23 S RNA as with wild-type 23 S RNA. Deletions in the 1200-1250 helix do not therefore confer resistance by reducing erythromycin binding, but by suppressing the effects of the drug at the level of its mechanism of action.     

Mutational analysis of the L1 binding site of 23S rRNA in Escherichia coli.

The L11 ribosomal protein operon of Escherichia coli contains the genes for L11 and L1 and is feedback regulated by the translational repressor L1. Both the L1 binding site on 23S rRNA and the L1 repressor target site on L11 operon mRNA share similar proposed secondary structures and contain some primary sequence identity. Several site-directed mutations in the binding region of 23S rRNA were constructed and their effects on binding were examined. For in vitro analysis, a filter binding method was used. For in vivo analysis, a conditional expression system was used to overproduce a 23S rRNA fragment containing the L1 binding region, which leads to specific derepression of the synthesis of L11 and L1. Changes in the shared region of the 23S rRNA L1 binding site produced effects on L1 binding similar to those found previously in analysis of corresponding changes in the L11 operon mRNA target site. The results support the hypothesis that r-protein L1 interacts with both 23S rRNA and L11 operon mRNA by recognizing similar features on both RNAs.     

Nucleotide sequence of the 5'- and 3'- domains for rabbit 18S ribosomal RNA.

By direct RNA sequence analysis we have determined the primary structures of both the 5' and 3' domains for rabbit 18S ribosomal RNA. Purified 18S rRNA was labeled in vitro at either its 5' or 3' terminus with 32P, base-specifically fragmented enzymatically and chemically, and the resulting fragments electrophoretically fractionated by size in adjacent lanes of 140 cm long polyacrylamide sequencing gels run in 90% formamide. A phylogenetic comparison of both the mammalian 5' proximal 400 residues and the 3' distal 301 nucleotides with the previously determined yeast and Xenopus laevis 18S rRNA sequence shows extensive conservation interspersed with tracts having little homology. Clusters of G + C rich sequences are present within the mammalian 5' domain which are entirely absent in both the Xenopus laevis and yeast 18S rRNAs. Most base differences and insertions within the mammalian 18S rRNA when compared with yeast or Xenopus rRNA result in an increase in the G + C content of these regions. We have found nucleotide sequence analysis of the ribosomal RNA directly permits detection of both cistron heterogeneities and mapping of many of the modified bases.     

Primary structure of rabbit 18S ribosomal RNA determined by direct RNA sequence analysis

The primary structure of rabbit 18S ribosomal RNA was determined by nucleotide sequence analysis of the RNA directly. The rabbit rRNA was specifically cleaved with T1 ribonuclease, as well as with E. coli RNase H using a Pst 1 DNA linker to generate a specific set of overlapping fragments spanning the entire length of the molecule. Both intact and fragmented 18S rRNA were end-labeled with [32P], base-specifically cleaved enzymatically and chemically and nucleotide sequences determined from long polyacrylamide sequencing gels run in formamide. This approach permitted the detection of both cistron heterogeneities and modified bases. Specific nucleotide sequences within E. coli 16S rRNA previously implicated in polyribosome function, tRNA binding, and subunit association are also conserved within the rabbit 18S rRNA. This conservation suggests the likelihood that these regions have similar functions within the eukaryotic 40S subunit.     

Residual tRNA secondary structure in ''denaturing'' 8M urea/TBE polyacrylamide gels: effects on electrophoretic mobility and dependency on prior chemical modification of the tRNA.

Fifteen individual species of tRNA were treated with the chemical modifiers diethylpyrocarbonate, 50% aqueous hydrazine or hydrazine/3 M NaCl. Following purification of the chemically modified material on polyacrylamide gels containing 8 M urea, variant minor bands, in addition to the expected main band, were observed for 12 of the 15 tRNAs. Characterization of the content of chemically altered bases in material recovered from such bands indicated that tRNAs containing modified nucleotides in base-paired stems were excluded from the main band and present, often in enhanced amounts, in the minor variant bands. The persistence of residual secondary structure on 8 M urea gels run at 45 degrees C and the ability of chemically modified bases to alter electrophoretic mobilities warrant caution in designing and interpreting experiments in which chemically modified RNA is isolated on gels prior to further analysis. tRNA(Val) (VAC) was unique in that modified bases in non base-paired regions, according to the cloverleaf model of secondary structure, caused exclusion from the main band. Consequently, we propose a secondary structure for partially denatured tRNA(Val) (VAC), in which these bases are located in double stranded regions of the molecule.     

Ribosome-bound eukaryotic elongation factor 2 protects 5 S rRNA from modification.

The interaction between eukaryotic elongation factor eEF-2 and reconstituted 80 S ribosomes was investigated by analyzing the accessibility of 5 S ribosomal RNA for chemical and enzymatic modification. Ribosomes reconstituted from derived subunits were modified, and the positions of the modified sites were identified by primer extension using a 5 S rRNA-specific probe. All reactive sites were located between nucleotides 38 and 99, and most of them were found in putative single-stranded regions of the 5 S rRNA. Conversion of the ribosomes to the post-translocation type of particles by treatment with the translational inhibitor ricin resulted in the exposure of 3 additional bases for chemical modification, suggesting that the 5 S rRNA was more exposed in this type of ribosome. After binding of eEF-2 in complex with the non-hydrolyzable GTP analogue guanosine 5'-(beta, gamma-methylene)-triphosphate, most of the exposed bases in the 5 S rRNA were protected against both chemical and enzymatic modification.     

The binding site for ribosomal protein complex L8 within 23 s ribosomal RNA of Escherichia coli

The ribosomal protein complex L8 of Escherichia coli consists of two dimers of protein L7/L12 and one monomer of protein L10. This pentameric complex and ribosomal protein L11 bind in mutually cooperative fashion to 23 S rRNA and protect specific fragments of the latter from digestion with ribonuclease T1. Oligonucleotides protected either by the L8 complex alone or by the complex plus protein L11 were isolated from such digests and shown to rebind specifically to these proteins. They were also subjected to nucleotide sequence analysis. The longest oligonucleotide, protected by the L8 complex alone, consisted of residues 1028-1124 of 23 S rRNA and included all the other RNA fragments produced in this study. Previously, protein L11 had been shown to protect residues 1052-1112 of 23 S rRNA. It is concluded that the binding sites for the L8 protein complex and for protein L11 are immediately adjacent within 23 S rRNA of E. coli.     

Binding of tRNA alters the chemical accessibility of nucleotides within the large ribosomal RNAs of E. coli ribosomes.

Functionally active 70S ribosomes were chemically modified with dimethylsulfate (DMS) in the presence and absence of bound tRNA. The ribosomal 16S RNA and 23S RNA were extracted, separated and labeled radioactively at their 3'-ends. DMS modification sites within the last 200 nucleotides from the 3'-ends were investigated on sequencing gels, after borohydride reduction and aniline catalyzed strand scission of the isolated RNA's. tRNA binding caused enhanced reactivity at 9 nucleotide positions while three sites showed decreased reactivity in the 16S RNA. The effects of bound tRNA on the modification of 23S RNA were limited. Only one enhancement was observed in the presence of bound tRNA. mRNA binding alone showed two more sites with enhanced reactivity, however. The results are consistent with the view that the sequence 1400-1500 of the 16S RNA plays an important functional role in the translating ribosome and possibly constitutes part of the tRNA binding site.     

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)     

Characterization of the Escherichia coli 23S Ribosomal RNA region associated with ribosomal protein L1. Evidence for homologies with the 5''-end region of the L11 operon.

The results previously obtained upon studying the L1-23S RNA complex by the fingerprint technique have been reexamined in the light of new data on 23S RNA primary structure. The 23S RNA region that remains associated with the L1 ribosomal protein after RNase digestion of the synthetic complex lies between nucleotides 2067 and 2235 from the 5'-end of the molecule. This region contains a m7G near to the 5'-end and possesses a high degree of mutability in E. coli. Three different sequences were observed in E. coli MRE 600. All three sequences differ in two positions relative to the corresponding sequence in rrnB cistron from E. coli K12. Striking homology is observed between the 23S RNA region associated with protein L1 and the 5'-part of L11 operon. This observation supports the model of feedback regulation of r-proteins synthesis proposed by Yates et al. (PNAS, 77, 1837) and strongly suggests that the region of 23S RNA located between positions 2155 and 2202 is essential for the binding of protein L1.