Localization of an oligodeoxynucleotide complementing 16S ribosomal RNA residues 520-531 on the small subunit of Escherichia coli ribosomes: electron microscopy of ribosome-cDNA-antibody complexes

Large-scale motions within ribosomal 50S subunits as demonstrated using photolabile oligonucleotides

Photolabile oligonucleotides (PHONTs) bind to rRNA sequences to which they are complementary and, on photolysis, incorporate into neighboring ribosomal components. Here we report on photocrosslinking results obtained with PHONTs targeting 23S rRNA nucleotides 1882-1892, in the long lateral arm of the 50S subunit (PHONT 1892), and 1085-1093, in the L11 binding domain (PHONT 1093). Photolysis of the PHONT 1892.50S and PHONT 1093.50S complexes leads to formation of 'long-range' crosslinks from C1892 to U1094/A1095 and G1950, and from G1093 to U1712/1716 and U1926, that are clearly incompatible with published crystal structures of 50S subunits. These results provide strong evidence that within the 50S subunit (a) the L11 binding domain can extend in an arm-like fashion, accessing large areas of the ribosome, and (b) the lateral arm can bend about the noncanonical helix at its center. Such motions may have functional relevance in identifying regions that undergo major conformational change as the ribosome moves through its catalytic cycle.

Three-dimensional placement of the conserved 530 loop of 16 S rRNA and of its neighboring components in the 30 S subunit

Nucleotides 518-533 form a loop in ribosomal 30 S subunits that is almost universally conserved. Both biochemical and genetic evidence clearly implicate the 530 loop in ribosomal function, with respect both to the accuracy control mechanism and to tRNA binding. Here, building on earlier work, we identify proteins and nucleotides (or limited sequences) site-specifically photolabeled by radioactive photolabile oligoDNA probes targeted toward the 530 loop of 30 S subunits. The probes we employ are complementary to 16 S rRNA nucleotides 517-527, and have aryl azides attached to nucleotides complementary to nucleotides 518, 522, and 525-527, positioning the photogenerated nitrene a maximum of 19-26 A from the complemented rRNA base. The crosslinks obtained are used as constraints to revise an earlier model of 30 S structure, using the YAMMP molecular modeling package, and to place the 530 loop region within that structure.

Conformational variability in Escherichia coli 70S ribosome as revealed by 3D cryo-electron microscopy

During protein biosynthesis, ribosomes are believed to go through a cycle of conformational transitions. We have identified some of the most variable regions of the E. coli 70S ribosome and its subunits, by means of cryo-electron microscopy and three-dimensional (3D) reconstruction. Conformational changes in the smaller 30S subunit are mainly associated with the functionally important domains of the subunit, such as the neck and the platform, as seen by comparison of heat-activated, non-activated and 50S-bound states. In the larger 50S subunit the most variable regions are the L7/L12 stalk, central protuberance and the L1-protein, as observed in various tRNA-70S ribosome complexes. Difference maps calculated between 3D maps of ribosomes help pinpoint the location of ribosomal regions that are most strongly affected by conformational transitions. These results throw direct light on the dynamic behavior of the ribosome and help in understanding the role of these flexible domains in the translation process.

Cleavage of 16S rRNA within the ribosome by mRNA modified in the A-site codon with phenanthroline-Cu(II)

Cleavage of 16S rRNA was obtained through mRNA modified at position +5 with the chemical cleavage agent 1,10-o-phenanthroline. In the presence of Cu2+, and after addition of reducing agent to the modified mRNA-70S complex, cleavage of proximal nucleotides within the 16S rRNA occurred. Primer extension analysis of 16S rRNA fragments revealed that nucleotides 528-532, 1196, and 1396-1397 were cleaved. Nucleotides 1053-1055 were also cleaved but did not show the same level of specificity as the former. These results provide evidence that at some point in the translation process these regions are all within 15 A of position +5, the A-site codon, on the mRNA.

Site-directed hydroxyl radical probing of the rRNA neighborhood of ribosomal protein S5

Cysteine residues were introduced into three different positions distributed on the surface of ribosomal protein S5, to serve as targets for derivatization with an Fe(II)-ethyl-enediaminetetraacetic acid linker. Hydroxyl radicals generated locally from the tethered Fe(II) in intermediate ribonucleoprotein particles or in 30S ribosomal subunits reconstituted from derivatized S5 caused cleavage of the RNA, resulting in characteristically different cleavage patterns for the three different tethering positions. These findings provide constraints for the three-dimensional folding of 16S ribosomal RNA (rRNA) and for the orientation of S5 in the 30S subunit, and they further suggest that antibiotic resistance and accuracy mutations in S5 may involve perturbation of 16S rRNA.

Ribosomal components neighboring the conserved 518-533 loop of 16S rRNA in 30S subunits

We report the synthesis of a radioactive, photolabile oligodeoxyribonucleotide probe complementary to 16S rRNA nucleotides 518-526 and its exploitation in identifying 30S ribosomal subunit components neighboring its target site in 16S rRNA. Nucleotides 518-526 lie within an almost universally conserved single-stranded loop that has been linked to the decoding region of Escherichia coli ribosomes. On photolysis in the presence of activated 30S ribosomes, the probe site-specifically incorporates into proteins S3, S4, S7, and S12 (identified by SDS-PAGE, RP-HPLC, and immunological analysis); nucleotides C525, C526, and G527 adjacent to its target binding site; and the 3'-terminus of 16S rRNA. When the probe is photoincorporated into 30S subunits subjected to brief cold inactivation (SI subunits), S7 labeling is increased compared to activated subunit incorporation, while S3, S4, and S12 labeling is decreased, as is labeling to nucleotides C525, C526, and G527; labeling at the 16S rRNA 3'-terminus appears unchanged. Longer cold inactivation of the 30S subunits (LI subunits) leads to decreases in the labeling of all components. These results provide clear evidence that C526 lies within 24 A (the distance between C526 and the photogenerated nitrene) of proteins S3, S4, S7, and S12 and the 3'-terminus of 16S rRNA. The identity of the tryptic digestion patterns of S7 labeled with the probe complementary to 16S rRNA nucleotides 518-526 and with a probe complementary to nucleotides 1397-1405 [Muralikrishna, P., & Cooperman, B. S. (1994) Biochemistry 33, 1392-1398] also provides evidence for proximity between C526 and G1405. Our results support the conclusion of Dontsova et al. [Dontsova, O., et al. (1992) EMBO J. 11, 3105-3116] in placing the 530 loop in close proximity to the decoding center of the 30S subunit but are apparently inconsistent with some protein-protein distances determined by neutron diffraction [Capel, M. S., et al. (1988) J. Mol. Biol. 200, 65-87]. This inconsistency suggests that a multistate model of subunit conformation may be required to account for the totality of results pertaining to the internal structure of the 30S subunit.

Selective perturbation of G530 of 16 S rRNA by translational miscoding agents and a streptomycin-dependence mutation in protein S12

Previous studies have shown that a concise set of universally conserved bases in 16 S rRNA are strongly protected from attack by chemical probes when tRNA is bound specifically to the ribosomal A site. Two of these bases, A1492 and A1493, are located in the cleft of the 30 S subunit, the site of codon-anticodon interaction. A third residue, G530, is located within the highly conserved 530 stem-loop, a region that is involved in interactions with proteins S4 and S12, mutations in which perturb the translational error frequency. The 530 loop is also thought to be located at or near the site of interaction of elongation factor Tu on the 30 S subunit, a location that is distinct from the decoding site. This study monitors the response of these two A-site-related regions of 16 S rRNA to a variety of translational miscoding agents. Several of these agents, including streptomycin, neomycin and ethanol, selectively potentiate tRNA-dependent protection of residue G530 from kethoxal modification; in contrast, little change in reactivity of residues A1492 and A1493 is observed. These results are consistent with the previously demonstrated importance of G530 for A-site function and, moreover, suggest a common mechanism of action for these miscoding agents, even though they appear to have distinctly different modes of interaction with 16 S rRNA. In contrast to the miscoding agents, we find that a streptomycin-dependence (SmD) mutation in protein S12, which causes ribosomes to be hyperaccurate, antagonizes tRNA-dependent protection of G530. The possibility that 5' or 3' flanking regions of mRNA could be involved in tRNA-dependent protection of G530 was tested by using different lengths of oligo(U) to promote binding of tRNA(Phe) to the A site. The relative levels of protection of G530, A1492 and A1493 were unchanged as the size of the mRNA fragment was decreased from 16 to 6 bases in length. We conclude, therefore, that for protection of G530 to be the result of direct contact with message, it must necessarily be located directly at the decoding site; otherwise, its protection is best explained by allosteric interactions, either with mRNA, or with the codon-anticodon complex. These results are discussed in terms of a model wherein the conformation of the 530 loop is correlated with the affinity of the ribosome for elongation factor Tu.

Evidence for functional interaction between elongation factor Tu and 16S ribosomal RNA

Translation of the genetic code requires the accurate selection of elongation factor (EF)-Tu.GTP.tRNA ternary complexes at the ribosomal acceptor site, or A site. Several independent lines of evidence have implicated the universally conserved 530 loop of 16S rRNA in this process; yet its precise role has not been identified. Using an allele-specific chemical probing strategy, we have examined the functional defect caused by a dominant lethal G-->A substitution at position 530. We find that mutant ribosomes are impaired in EF-Tu-dependent binding of aminoacyl-tRNA in vitro; in contrast, nonenzymatic binding of tRNA to the A and P sites is unaffected, indicating that the defect involves an EF-Tu-related function rather than tRNA-ribosome interactions per se. In vivo, the mutant ribosomes are found in polysomes at low levels and contain reduced amounts of A-site-bound tRNA, but normal levels of P-site tRNA, in agreement with the in vitro results; thus the dominant lethal phenotype of mutations at G530 can be explained by impaired interaction of mutant ribosomes with ternary complex. These results provide evidence for a newly defined function of 16S rRNA--namely, modulation of EF-Tu activity during translation.

mRNA periodical infrastructure complementary to the proof-reading site in the ribosome

Virtually all mRNA sequences carry a 3-base periodical pattern, presumably involved in the translation frame monitoring mechanism (Trifonov, E.N., J. Mol. Biol. 194, 643-652, 87). The hidden pattern, 5'-(GHN)n-3' (H representing nonG, N any base), is further refined by extensive computational analysis of mRNA sequences. According to mononucleotide preferences in the three positions of coding triplets, it appears now as 5'-(GHU)n-3'. Dinucleotide frequencies independent of mononucleotides (contrast dinucleotides, 2) generate the motif 5'-(GCU)n-3'. The same motif is found by regarding the expected avoidance of destabilizing base oppositions in hypothetical transient complementary complexes between mRNA and rRNA. This hidden pattern, in its refined consensus form, 5'-(GCU)n-3', is an almost perfect complementary match to a unique site in small subunit rRNA, the universally conserved (3) proofreading loop at position 525 (of E.coli small subunit rRNA): [formula: see text] This strongly suggests that the 525 site is a major structural component of the previously proposed frame-keeping mechanism which is based on the in-frame contacts between mRNA and three segments of rRNA. Consistent with the original proposition, this site is one of three believed to interact with mRNA.

Recognition of correct reading frame by the ribosome

The translation frame-monitoring mechanism has been suggested earlier, based on transient complementary contacts, between mRNA and rRNA. Recent studies related to the frame-monitoring mechanism are reviewed. The mechanism is well supported by both new experimental and sequence analysis data. Experiments are suggested for further elucidation of the structural details of the mRNA-rRNA interaction in the ribosome.

The interaction between streptomycin and ribosomal RNA

The present study shows that a mutation in the 530 loop of 16S rRNA impairs the binding of streptomycin to the bacterial ribosome, thereby restricting the misreading effect of the drug. Previous reports demonstrated that proteins S4, S5 and S12 as well as the 915 region of 16S rRNA are involved in the binding of streptomycin, and indicated that the drug not only interacts with the 30S subunit but also with the 50S subunit. The relationship between the target of streptomycin and its known interference with the proofreading control of translational accuracy is examined in light of these results.

Localization of a segment of 16S RNA on the surface of the small ribosomal subunit by immune electron microscopy of complementary oligodeoxynucleotides

Oligonucleotides that complement Escherichia coli 16S ribosomal RNA residues 685-696 and 694-705 have been synthesized so as to incorporate antibody-recognizable markers: a 3'-terminal residue of N6-delta 2-isopentenyladenosine, a 5'-dinitrophenyl group, or both. Each oligonucleotide is able to bind RNA within the small ribosomal subunit, whether free or in 70S ribosomes. Immune electron microscopy places probes at nucleotides 685, 694 and 705 within a single area, at the tip of the subunit platform, very near the position of the 3'-end of the 16S RNA.

A deletion mutation at the 5' end of Escherichia coli 16S ribosomal RNA

A deletion of five nucleotides was introduced at the 5' end of the Escherichia coli 16S rRNA gene cloned in an appropriate vector under control of a T7 promoter. The 16S rRNA generated by in vitro transcription could be assembled into 30S subunits. The deletion did not affect the efficiency of translation of natural messengers and the correct selection of the reading frame. However, it reduced the binding of the messengers, which suggests that the 5' end of 16S rRNA is located on the pathway followed by the messengers on the 30S subunits. The deletion also restricted the stimulation of misreading by streptomycin in a poly(U)-directed system. This is in accord with the proximity of the 5' end of 16S rRNA to proteins S4, S5 and S12, which are known to be involved in the control of translational accuracy.