Dominant lethal mutations in a conserved loop in 16S rRNA.

The 530 stem-loop region in 16S rRNA is among the most phylogenetically conserved structural elements in all rRNAs, yet its role in protein synthesis remains mysterious. G-530 is protected from kethoxal attack when tRNA, or its 15-nucleotide anticodon stem-loop fragment, is bound to the ribosomal A site. Based on presently available evidence, however, this region is believed to be too remote from the decoding site for this protection to be the result of direct contact. In this study, we use a conditional rRNA expression system to demonstrate that plasmid-encoded 16S rRNA genes carrying A, C, and T point mutations at position G-530 confer a dominant lethal phenotype when expressed in Escherichia coli. Analysis of the distribution of plasmid-encoded 16S rRNA in ribosomal particles, following induction of the A-530 mutation, shows that mutant rRNA is present both in 30S subunits and in 70S ribosomes. Little mutant rRNA is found in polyribosomes, however, indicating that the mutant ribosomes are severely impaired at the stage of polysome formation and/or stability. Detailed chemical probing of mutant ribosomal particles reveals no evidence of structural perturbation within the 16S rRNA. Taken together, these results argue for the direct participation of G-530 in ribosomal function and, furthermore, suggest that the dominant lethal phenotype caused by these mutations is due primarily to the mutant ribosomes blocking a crucial step in protein synthesis after translational initiation.     

Sites of interaction of the CCA end of peptidyl-tRNA with 23S rRNA.

Oligonucleotide fragments derived from the 3' CCA terminus of acylated tRNA, such as CACCA-(AcPhe), UACCA-(AcLeu), and CAACCA-(fMet), bind specifically to ribosomes in the presence of sparsomycin and methanol [Monro, R. E., Celma, M. L. & Vazquez, D. (1969) Nature (London) 222, 356-358]. All three oligonucleotides protect a characteristic set of bases in 23S rRNA from chemical probes: G2252, G2253, A2439, A2451, U2506, and U2585. A2602 shows enhanced reactivity. These account for most of the same bases that are protected when peptidyl-tRNA analogues such as AcPhe-tRNA are bound to the ribosomal P site, and correspond precisely to those bases whose protection is abolished by removal of the 3'-CA end of tRNA. We conclude that most of the observed interactions between tRNA and 23S rRNA in the 50S ribosomal P site involve the conserved CCA terminus of tRNA. Sparsomycin may inhibit protein synthesis by stabilizing interaction between the peptidyl-CCA and the 23S P site, preventing formation of the intermediate A/P hybrid state.     

THE UTILIZATION OF GENES FOR RIBOSOMAL RNA, 5S RNA, AND TRANSFER RNA IN LIVER CELLS OF ADULT RATS

The rates of synthesis of ribosomes, 5S RNA, and tRNA necessary to maintain the steady-state concentrations of these entities in liver cytoplasm of adult rats were determined. On the average, each liver cell in the adult rat synthesizes 650 ribosomes, 650 molecules of 5S RNA, and 11,000 molecules of tRNA each minute. The numbers of genes per liver cell for rRNA, 5S RNA, and tRNA were 330, 1660, and 13,000, respectively, as determined by RNA: DNA hybridization experiments. Thus, on the average, individual genes for rRNA, tRNA, and 5S RNA are transcribed twice a minute, once a minute, and once every 2.5 minutes, respectively, in the adult rat liver.     

Conserved 5S rRNA complement to tRNA is not required for protein synthesis.

The notion that tRNA and 5S rRNA interact through evolutionarily conserved complementary sequences has been tested by nucleolytic modification of the 5S rRNA, using the modified rRNA to reconstitute the large ribosomal subunit, and assaying for poly(uridylic acid)-directed polyphenylalanine synthesis. The 5S rRNA sequence C-G-A-A (residues 43-46) and several residues surrounding it are not essential for protein synthesis.     

Analysis of mutations at residues A2451 and G2447 of 23S rRNA in the peptidyltransferase active site of the 50S ribosomal subunit

On the basis of the recent atomic-resolution x-ray structure of the 50S ribosomal subunit, residues A2451 and G2447 of 23S rRNA were proposed to participate directly in ribosome-catalyzed peptide bond formation. We have examined the peptidyltransferase and protein synthesis activities of ribosomes carrying mutations at these nucleotides. In Escherichia coli, pure mutant ribosome populations carrying either the G2447A or G2447C mutations maintained cell viability. In vitro, the G2447A ribosomes supported protein synthesis at a rate comparable to that of wild-type ribosomes. In single-turnover peptidyltransferase assays, G2447A ribosomes were shown to have essentially unimpaired peptidyltransferase activity at saturating substrate concentrations. All three base changes at the universally conserved A2451 conferred a dominant lethal phenotype when expressed in E. coli. Nonetheless, significant amounts of 2451 mutant ribosomes accumulated in polysomes, and all three 2451 mutations stimulated frameshifting and readthrough of stop codons in vivo. Furthermore, ribosomes carrying the A2451U transversion synthesized full-length beta-lactamase chains in vitro. Pure mutant ribosome populations with changes at A2451 were generated by reconstituting Bacillus stearothermophilus 50S subunits from in vitro transcribed 23S rRNA. In single-turnover peptidyltransferase assays, the rate of peptide bond formation was diminished 3- to 14-fold by these mutations. Peptidyltransferase activity and in vitro beta-lactamase synthesis by ribosomes with mutations at A2451 or G2447 were highly resistant to chloramphenicol. The significant levels of peptidyltransferase activity of ribosomes with mutations at A2451 and G2447 need to be reconciled with the roles proposed for these residues in catalysis.     

Molecular diagnostic of parasites using rRNA gene sequence

Ribosomal RNA (rRNA) is a component of the ribosomes. Eukaryotic ribosomes contain four different rRNA molecules: 18S, 5,8S, 28S and 5S rRNA. rRNA is the most conserved (least variable) gene in all cells. For this reason, genes that encode the rRNA (rDNA) are sequenced to identify an organism's taxonomic group, calculate related groups, and estimate rates of species divergence. Especially the internal transcribed spacers (ITS) are very useful for molecular diagnostic of parasite. They are noncoding regions of DNA sequence that separate genes coding for the 28S, 5.8S, and 18S ribosomal RNAs. These ribosomal RNA (rRNA) genes are highly conserved across taxa while the spacers between them may be species-specific. In this paper authors describe practical using of rRNA gene to parasite diagnostic.     

Peptide inhibitors of peptidyltransferase alter the conformation of domains IV and V of large subunit rRNA: a model for nascent peptide control of translation.

Peptides of 5 and 8 residues encoded by the leaders of attenuation regulated chloramphenicol-resistance genes inhibit the peptidyltransferase of microorganisms from the three kingdoms. Therefore, the ribosomal target for the peptides is likely to be a conserved structure and/or sequence. The inhibitor peptides "footprint" to nucleotides of domain V in large subunit rRNA when peptide-ribosome complexes are probed with dimethyl sulfate. Accordingly, rRNA was examined as a candidate for the site of peptide binding. Inhibitor peptides MVKTD and MSTSKNAD were mixed with rRNA phenol-extracted from Escherichia coli ribosomes. The conformation of the RNA was then probed by limited digestion with nucleases that cleave at single-stranded (T1 endonuclease) and double-stranded (V1 endonuclease) sites. Both peptides selectively altered the susceptibility of domains IV and V of 23S rRNA to digestion by T1 endonuclease. Peptide effects on cleavage by V1 nuclease were observed only in domain V. The T1 nuclease susceptibility of domain V of in vitro-transcribed 23S rRNA was also altered by the peptides, demonstrating that peptide binding to the rRNA is independent of ribosomal protein. We propose the peptides MVKTD and MSTSKNAD perturb peptidyltransferase center catalytic activities by altering the conformation of domains IV and V of 23S rRNA. These findings provide a general mechanism through which nascent peptides may cis-regulate the catalytic activities of translating ribosomes.     

Base changes at position 792 of Escherichia coli 16S rRNA affect assembly of 70S ribosomes.

To investigate the function of base 792 of 16S rRNA in 30S ribosomes of Escherichia coli, the wild-type (adenine) residue was changed to guanine, cytosine, or uracil by oligonucleotide-directed mutagenesis. Each base change conferred a unique phenotype on the cells. Cells containing plasmid pKK3535 with G792 or T792 showed no difference in generation time in LB broth containing ampicillin, whereas cells with C792 exhibited a 20% increase in generation time in this medium. To study the effect on cell growth of a homogeneous population of mutant ribosomes, the mutations were cloned into the 16S rRNA gene on pKK3535 carrying a spectinomycin-resistance marker (thymine at position 1192), and the cells were grown with spectinomycin. Cells containing G792 or C792 showed 16% and 56% increases in generation time, respectively, and a concomitant decrease in 35S assimilation into proteins. Cells with T792 did not grow in spectinomycin-containing medium. Maxicell analyses indicated decreasing ability to form 70S ribosomes from 30S subunits containing guanine, cytosine, or uracil at position 792 in 16S rRNA. It appeared that C792-containing 30S ribosomes had lost the ability to bind initiation factor 3.     

23S rRNA positions essential for tRNA binding in ribosomal functional sites

rRNA plays an important role in function of peptidyl transferase, the catalytic center of the ribosome responsible for the peptide bond formation. Proper placement of the peptidyl transferase substrates, peptidyl-tRNA and aminoacyl-tRNA, is essential for catalysis of the transpeptidation reaction and protein synthesis. In this report, we define a small set of rRNA nucleotides that are most likely directly involved in binding of tRNA in the functional sites of the large ribosomal subunit. By binding biotinylated tRNA substrates to randomly modified large ribosomal subunits from Escherichia coli and capturing resulting complexes on the avidin resin, we identified four nucleotides in the large ribosomal subunit rRNA (positions G2252, A2451, U2506, and U2585) whose modifications prevent binding of a peptidyl-tRNA analog in the P site and one residue (U2555) whose modification interferes with transfer of peptidyl moiety to puromycin. These nucleotides represent a subset of positions protected by tRNA analogs from chemical modification and significantly narrow the number of 23S rRNA nucleotides that may be directly involved in tRNA binding in the ribosomal functional sites.     

Coregulation of processing and translation: mature 5'' termini of Escherichia coli 23S ribosomal RNA form in polysomes.

In Escherichia coli, the final maturation of rRNA occurs in precursor particles, and recent experiments have suggested that ongoing protein synthesis may somehow be required for maturation to occur. The protein synthesis requirement for the formation of the 5' terminus of 23S rRNA has been clarified in vitro by varying the substrate of the reaction. In cell extracts, pre-23S rRNA in free ribosomes was not matured, but that in polysomes was efficiently processed. The reaction occurred in polysomes without the need for an energy source or other additives required for protein synthesis. Furthermore, when polysomes were dissociated into ribosomal subunits, they were no longer substrates for maturation; but the ribosomes became substrates again when they once more were incubated in the conditions for protein synthesis. All of these results are consistent with the notion that protein synthesis serves to form a polysomal complex that is the true substrate for maturation. Ribosomes in polysomes, possibly in the form of 70S initiation complexes, may more easily adopt a conformation that facilitates maturation cleavage. As a result, the rates of ribosome formation and protein synthesis could be coregulated.     

rRNA complementarity within mRNAs: A possible basis for mRNA-ribosome interactions and translational control

Our recent demonstration that many eukaryotic mRNAs contain sequences complementary to rRNA led to the hypothesis that these sequences might mediate specific interactions between mRNAs and ribosomes and thereby affect translation. In the present experiments, the ability of complementary sequences to bind to rRNA was investigated by using photochemical cross-linking. RNA probes with perfect complementarity to 18S or 28S rRNA were shown to cross-link specifically to the corresponding rRNA within intact ribosomal subunits. Similar results were obtained by using probes based on natural mRNA sequences with varying degrees of complementarity to the 18S rRNA. RNase H cleavage localized four such probes to complementary regions of the 18S rRNA. The effects of complementarity on translation were assessed by using the mRNA encoding ribosomal protein S15. This mRNA contains a sequence within its coding region that is complementary to the 18S rRNA at 20 of 22 nucleotides. RNA from an S15-luciferase fusion construct was translated in a cell-free lysate and compared with the translation of four related constructs that were mutated to decrease complementarity to the 18S rRNA. These mutations did not alter the amino acid sequence or the codon bias. A correlation between complementarity and translation was observed; constructs with less complementarity increased the amount of translation up to 54%. These findings raised the possibility that direct base-pairing of particular mRNAs to rRNAs within ribosomes may function as a mechanism of translational control.     

Specific binding of tRNAMet to 23S rRNA of Escherichia coli.

tRNAMetf binds to 23S rRNA of Escherichia coli, forming a complex with a melting temperature of 75 degrees (in 0.6 M NaCl). The regions within the RNAs that bind to each other have been isolated and their nucleotide sequences have been determined. The interacting region in tRNAMetf is 17 nucleotides long, extending from G5 in the acceptor stem to D21 (D = 5.6-dihydrouridine) in the D loop. The sequence in 23S rRNA is complementary to that sequence except for an extra Up in the middle and allowing a Gp.D base pair. We propose that association of these two sequences may play a role in initiation of protein synthesis by tRNAMetf. In addition, part of this sequence in 23S rRNA may also stabilize tRNA binding to the ribosome during elongation of nascent polypeptides.     

Identification of spacer tRNA genes in individual ribosomal RNA transcription units of Escherichia coli.

Transfer RNA genes ("spacer tRNA genes") are present in the spacer region between 16S and 23S rRNA genes in Escherichia coli. We have analyzed spacer tRNA genes carried by seven rRNA operons with different chromosomal locations. Six of these were isolated on plasmids and one on a transducing phage. We found that, in addition to the two previously identified genes for tRNA2Glu and tRNAIIle, there is a spacer tRNA gene which codes for tRNAIBAla. Of the seven rRNA operons studied, three had both tRNAIBAla and tRNAIIle genes, and the remaining four had the tRNA2Glu gene in their spacers. In addition, genes for tRNAIAsp were found near the distal ends of two different rRNA operons.     

Appropriate maturation and folding of 16S rRNA during 30S subunit biogenesis are critical for translational fidelity

Ribosomal protein S5 is critical for small ribosomal subunit (SSU) assembly and is indispensable for SSU function. Previously, we identified a point mutation in S5, (G28D) that alters both SSU formation and translational fidelity in vivo, which is unprecedented for other characterized S5 mutations. Surprisingly, additional copies of an extraribosomal assembly factor, RimJ, rescued all the phenotypes associated with S5(G28D), including fidelity defects, suggesting that the effect of RimJ on rescuing the miscoding of S5(G28D) is indirect. To understand the underlying mechanism, we focused on the biogenesis cascade and observed defects in processing of precursor 16S (p16S) rRNA in the S5(G28D) strain, which were rescued by RimJ. Analyses of p16S rRNA-containing ribosomes from other strains further supported a correspondence between the extent of 5^′ end maturation of 16S rRNA and translational miscoding. Chemical probing of mutant ribosomes with additional leader sequences at the 5^′ end of 16S rRNA compared to WT ribosomes revealed structural differences in the region of helix 1. Thus, the presence of additional nucleotides at the 5^′ end of 16S rRNA could alter fidelity by changing the architecture of 16S rRNA in translating ribosomes and suggests that fidelity is governed by accuracy and completeness of the SSU biogenesis cascade.     

Identification and chromosomal distribution of 5S rRNA genes in Neurospora crassa.

The 5S rRNA genes of Neurospora crassa, unlike those of most organisms, are not tandemly arranged, and they are found imbedded in a variety of unique sequences. The 5S rRNA regions of most of the genes are of one type, alpha; however, several other "isotypes" (beta, gamma, delta, zeta, and eta) are also found. We asked whether Neurospora 5S rRNA genes are dispersed on a chromosomal scale and whether genes of different isotypes are spatially segregated. We identified, by DNA sequencing, 5S rRNA genes in 22 5S DNA clones, and we mapped these genes by conventional crosses by using restriction fragment length polymorphisms in their flanking sequences as genetic markers. The results show that the 5S rRNA genes are distributed on at least six of the seven chromosomes. Their location does not appear to be completely random. Some of them are closely linked. One of the chromosomes carries a disproportionate number of 5S rRNA genes of the most common structural type, alpha; another chromosome carries three of the four mapped beta 5S rRNA genes. None of the 5S rRNA genes studied maps close to the nucleolus organizer, the site of the genes that code for the three larger rRNAs.     

Introducing mutations into the single-copy chromosomal 23S rRNA gene of the archaeon Halobacterium halobium by using an rRNA operon-based transformation system.

A vector-transformation system is described that permits replacement of a portion of the single rRNA operon of the archaeon Halobacterium halobium with a homologous fragment from a vector-borne gene. The vector construct contains three functional sections: (i) an entire H. halobium rRNA operon with two selective mutations in the 23S rRNA gene, the substitutions of A----G at position 1159 conferring resistance to thiostrepton and C----U at position 2471 conferring resistance to anisomycin; (ii) the complete pHSB1 plasmid from Halobacterium sp. SB3, which interferes with vector maintenance in the transformed halobacterial cells; and (iii) a segment of the pBR322 plasmid that permits vector replication in Escherichia coli. Transformation of H. halobium with the vector plasmid generates cells resistant to both anisomycin and thiostrepton that can be selected for, and discriminated from spontaneous mutants, by a two-step selection procedure. After transformation, the plasmid recombines homologously with the chromosome so that the plasmid-borne rDNA segment with resistance markers substitutes for the corresponding region of the chromosomal rRNA operon, and the transforming plasmid is lost. Eventually, this leads to a homogeneous population of the mutant ribosomes in the cell. Other mutations that are engineered in the vector-borne rRNA sequences can be transferred to the chromosomal rRNA operon concomitantly with the selective markers. The system has considerable potential for ribosomal engineering.