RNA sequences in ribonucleoprotein fragments of the complex formed from ribosomal 23-S RNA and ribosomal protein L24 of Escherichia coli

Genetic interactions reveal that specific defects of chloroplast translation are associated with the suppression of var2-mediated leaf variegation

Arabidopsis thaliana L. yellow variegated (var2) mutant is defective in a chloroplast FtsH family metalloprotease, AtFtsH2/VAR2, and displays an intriguing green and white leaf variegation. This unique var2-mediated leaf variegation offers a simple yet powerful tool for dissecting the genetic regulation of chloroplast development. Here, we report the isolation and characterization of a new var2 suppressor gene, SUPPRESSOR OF VARIEGATION8 (SVR8), which encodes a putative chloroplast ribosomal large subunit protein, L24. Mutations in SVR8 suppress var2 leaf variegation at ambient temperature and partially suppress the cold-induced chlorosis phenotype of var2. Loss of SVR8 causes unique chloroplast rRNA processing defects, particularly the 23S-4.5S dicistronic precursor. The recovery of the major abnormal processing site in svr8 23S-4.5S precursor indicate that it does not lie in the same position where SVR8/L24 binds on the ribosome. Surprisingly, we found that the loss of a chloroplast ribosomal small subunit protein, S21, results in aberrant chloroplast rRNA processing but not suppression of var2 variegation. These findings suggest that the disruption of specific aspects of chloroplast translation, rather than a general impairment in chloroplast translation, suppress var2 variegation and the existence of complex genetic interactions in chloroplast development.

Attachment sites of primary binding proteins L1, L2 and L23 on 23 S ribosomal RNA of Escherichia coli

The attachment sites of the primary binding proteins L1, L2 and L23 on 23 S ribosomal RNA of Escherichia coli were examined by a chemical and ribonuclease footprinting method using several probes with different specificities. The results show that the sites are confined to localized RNA regions within the large ribonuclease-protected ribonucleoprotein fragments that were characterized earlier. They are as follows: (1) L1 recognizes a tertiary structural motif in domain V centred on two interacting internal loops; the main protein interaction sites occur at the internal loop/helix junctions. (2) The L2 site constitutes a single irregular stem/loop structure in the centre of domain IV where non-Watson-Crick pairing is likely to occur. (3) L23 recognizes a tertiary structural motif involving a single terminal loop structure and part of an adjacent internal loop at the centre of domain III. Each of the three primary binding proteins, whose presence is essential for ribosomal assembly, has been associated with important ribosomal functions: L1 lies in the E-site for deacylated tRNA binding while L2 and L23 have been implicated in the P and A substrate sites, respectively, of the peptidyl transferase centre. Moreover, each of the protein sites, but particularly those of L2 and L23, lies at the centre of RNA domains where they can maximally influence both the assembly of secondary binding proteins and the function of the RNA region.

The phenotypic suppression of a mutation in the gene rplX for ribosomal protein L24 by mutations affecting the lon gene product for protease LA in Escherichia coli K12

A suppressor mutation of a temperature-sensitive mutant of ribosomal protein L24 (rplX19) was mapped close to the lon gene by genetic analysis and was shown to affect protease LA. The degradation and the synthesis rates of individual ribosomal proteins were determined. Proteins L24, L14, L15 and L27 were found to be degraded faster in the original rplX19 mutant than in the rplX19 mutant containing the suppressor mutation. Other ribosomal proteins were either weakly or not at all degraded in both mutants. Temperature-sensitive growth was also suppressed by the overproduction of mutant protein L24 from a plasmid. Our results suggest that (1) either free ribosomal proteins or proteins bound to abortive assembly precursors are highly susceptible to the lon gene product and (2) the mutationally altered protein L24 can still function at the nonpermissive growth temperature of the mutant, if it is present in sufficient amounts.

Spontaneous missense mutations in the rplX gene for ribosomal protein L24 from Escherichia coli

Temperature-resistant pseudorevertants of the temperature-sensitive Escherichia coli mutant KNS19, harboring a mutation in rplX, the gene for ribosomal protein L24, were isolated, cloned, and sequenced. The codon GAC for the amino acid Asp in the temperature-sensitive mutant corresponding to position 84 in the protein chain mutated either back to the wild type (Gly) or to codons for the amino acids Tyr and Glu. Furthermore, rplX genes from two other mutants with an altered protein L24 were cloned and sequenced. The mutations were localized at position 56 (Gly to Asp) and at position 62 (Glu to Lys) in the rplX gene. The latter two mutants lacked a conditional lethal phenotype. The results suggest that the amino acid Gly at positions 56 and 84 in the protein might be involved in loop formations.

Structure and accessibility of domain I of Escherichia coli 23 S RNA in free RNA, in the L24-RNA complex and in 50 S subunits. Implications for ribosomal assembly

Domain I of 23 S RNA of Escherichia coli was probed in renatured RNA, in the protein L24-RNA complex and in 50 S subunits with ribonucleases specific for single- and double-stranded regions and with chemical reagents specific for guanosines (N-1 and N-2), adenosines (N-1, N-7 and N-6), cytidines (N-3) and uridines (N-3). Reactive sites were detected by a reverse transcriptase procedure. The results support most new features of the latest version of the Santa Cruz/Urbana model of the secondary structure, which is based on evidence from sequence comparison. Most double-helical segments were reactive to cobra venom ribonuclease to some degree; the exceptions were the five "long-range" helices that are probably compactly folded within the structure. The data provide evidence for the occurrence of A(syn) X G(anti) pairings in internal loops and at the ends of some helices; they also support the existence of extensive higher-order structuring, especially within the interhelical regions, and are compatible with two of three tertiary interactions in the free RNA that were predicted from comparative sequence studies. Protein L24 is the only primary binding protein that associates with domain I and it strongly protects two sites against ribonuclease and chemical activity. Site A has the properties of a classic protein binding site and we conclude from four lines of evidence that it is the primary attachment site. Site B is rich in highly conserved, unpaired adenosine residues and lies in a potentially critical region of the structure adjoining a group of long-range helices; we infer that L24 binding here is related to the important role of L24 in initiating ribosomal assembly; the existence of both sites is supported, independently, by genetic experiments. L24-induced enhanced reactivities were detected throughout the domain and are consistent with a general "tuning" of the RNA structure. The RNA domain in the 50 S subunits is almost completely resistant to ribonucleases and only a few sites, mainly interhelical, are accessible to chemical reagents. The appearance of several newly reactive nucleotides in the subunit RNA and the enhancement of some others suggest that some minor conformational changes occur on assembly. Nevertheless, the minimal secondary structure of the renatured RNA appears to be retained. We draw the general conclusion that domain I is a highly structured domain that is important for initiating assembly and for the subsequent organization of the ribosome.

Accessibility of phosphodiester bonds in the yeast ribosomal 5 S RNA protein complex

The tertiary structure of the protein-associated yeast ribosomal 5 S RNA was examined using ethylnitrosourea reactivity as a probe for phosphodiester bonds. A reduced reactivity was consistently observed in at least nine residues within four distinct regions of the RNA sequence. Seven of these were also observed in three regions of the free RNA molecule while two, A27 and G30, were only present in the ribonucleoprotein complex. The results strongly suggest that the tertiary structure of the free eukaryotic 5 S RNA is largely conserved in the 5 S RNA-protein complex although it appears to be further stabilized in interaction with the ribosomal protein.

Primary sequence and partial secondary structure of the 12S kinetoplast (mitochondrial) ribosomal RNA from Leishmania tarentolae: conservation of peptidyl-transferase structural elements

The sequence of the 1173 nt 12S kinetoplast ribosomal RNA from Leishmania tarentolae was determined from the maxicircle DNA sequence, and the 5' and 3' ends localized by primer runoff and S1 nuclease protection experiments. The gene was shown to be free of introns by S1 nuclease analysis. A partial secondary structure model of the 12S RNA molecule is presented which is equivalent in certain respects to the corresponding portions of the Escherichia coli 23S ribosomal RNA model. Domain II of the E. coli model is completely missing in the kinetoplast model with the exception of several phylogenetically conserved stems and one loop. There is a striking conservation of the functionally important peptidyl-transferase region except for the deletion of a few stems and loops. The 12S RNA is the smallest large subunit ribosomal RNA described to date.

Xenopus laevis 28S ribosomal RNA: a secondary structure model and its evolutionary and functional implications

Based upon the three experimentally derived models of E. coli 23S rRNA (1-3) and the partial model for yeast 26S rRNA (4), which was deduced by homology to E. coli, we derived a secondary structure model for Xenopus laevis 28S rRNA. This is the first complete model presented for eukaryotic 28S rRNA. Compensatory base changes support the general validity of our model and offer help to resolve which of the three E. coli models is correct in regions where they are different from one another. Eukaryotic rDNA is longer than prokaryotic rDNA by virtue of introns, expansion segments and transcribed spacers, all of which are discussed relative to our secondary structure model. Comments are made on the evolutionary origins of these three categories and the processing fates of their transcripts. Functionally important sites on our 28S rRNA secondary structure model are suggested by analogy for ribosomal protein binding, the GTPase center, the peptidyl transferase center, and for rRNA interaction with tRNA and 5S RNA. We discuss how RNA-RNA interactions may play a vital role in translocation.

The 5S RNA binding protein from yeast (Saccharomyces cerevisiae) ribosomes. An RNA binding sequence in the carboxyl-terminal region

The carboxyl-terminal half (CN2 fragment) of the yeast 5S RNA binding protein (YL3) retains an ability to form homogeneous ribonucleoprotein complexes with RNA although the N-terminal half (CN1) appears to confer specificity for the 5S RNA molecule [Nazar, R.N., Yaguchi, M., Willick, G.E., Rollin, C.F. and Roy, C. (1979) Eur. J. Biochem. 102, 573-582]. The nucleic acid binding site in this fragment was more clearly delineated by cleaving the CN2 fragment with a variety of enzymatic and chemical reagents and further examining the ability of the products to form RNA-peptide complexes. Hot acetic acid treatment produced a 47-residue subfragment (CN2-A1) which originated from the C terminus and continued to form stable ribonucleopeptide complexes. The amino acid sequence of this subfragment was determined to be: -Pro-Ala-Phe-Lys-Pro-Thr-Glu-Lys50-Phe-Thr-Lys-Glu-Gln-Tyr-Ala-Ala -Glu60-Ser-Ly s -Lys-Tyr-Arg-Gln-Thr-Lys-Leu-Ser70-Lys-Gln-Gln-Arg-Ala-Ala-Arg-Val -Ala-Ala80-Ly s -Ile-Ala-Ala-Leu-Ala-Gly-Gln-Gln-COOH, with 12 of the 16 basic residues in the CN2 fragment being present in this binding site. The amino acid sequence of the CN2-A1 fragment bears a limited homology in both amino acid and charge distribution with histone 2B from mammals and with one of the 5S RNA binding proteins (EL25) from Escherichia coli. The results suggest that many protein binding sites for nucleic acids may share common structural features and further support the notion that the single large eukaryotic 5S RNA protein may have evolved through a fusion of genes for the multiple 5S RNA binding proteins in prokaryotes.

Primary and secondary structures of Escherichia coli MRE 600 23S ribosomal RNA. Comparison with models of secondary structure for maize chloroplast 23S rRNA and for large portions of mouse and human 16S mitochondrial rRNAs

We determined 90% of the primary structure of E.coli MRE 600 23S rRNA by applying the sequencing gel technique to products of T1, S1, A and Naja oxiana nuclease digestion. Eight cistron heterogeneities were detected, as well as 16 differences with the published sequence of a 23S rRNA gene of an E.coli K12 strain. The positions of 13 post-transcriptionally modified nucleotides and of single-stranded, double-stranded and subunit surface regions of E.coli 23S rRNA were identified. Using these experimental results and by comparing the sequences of E.coli 23S rRNA, maize chloro. 23S rRNA and mouse and human mit 16S rRNAs, we built models of secondary structure for the two 23S rRNAs and for large portions of the two mit rRNAs. The structures proposed for maize chloroplast and E.coli 23S rRNAs are very similar, consisting of 7 domains closed by long-range base-pairings. In the mitochondrial 16S rRNAs, 3 of these domains are strongly reduced in size and have a very different primary structure compared to those of the 23S rRNAs. These domains were previously found to constitute a compact area in the E.coli 50S subunits. The conserved domains do not belong to this area and contain almost all the modified nucleotides. The most highly conserved domain, 2042-2625, is probably part of the ribosomal A site. Finally, our study strongly suggests that in cytoplasmic ribosomes the 3'-end of 5.8S rRNA is basepaired with the 5'-end of 26S rRNA. This confirms the idea that 5.8S RNA is the counterpart of the 5'-terminal region of prokaryotic 23S rRNA.

Defective assembly of the small ribosomal subunit in a temperature-sensitive mutant of Escherichia coli. Experiments in vitro

Comparison of the properties in vitro of total 30-S ribosomal subunit proteins and purified protein S4 of Escherichia coli D10 (wild type) and E. coli 219ts2(temperature-sensitive) has given the following results. 1. Reconstitution of functional 30-S subunits in vitro occurs when total 30-S subunit proteins of either strain are used even at temperatures which are not permissive for 30-S subunit assembly in vivo in E. coli 219ts2. The yield of reconstitution is, however, twofold lower with 30-S subunit proteins of E. coli 219ts2 than with wild-type proteins. 2. The yield of complex formation between 16-S rRNA and protein S4 of E. coli 219ts2 is temperature-sensitive and lower at all temperatures tested (33-42 degrees C) than that observed when wild-type S4 is used. 3. The conformational stability of complexes between 16-S rRNA and S4 from 219ts2 is more temperature-sensitive than that of analogous complexes containing wild-type S4. These observations provide an explanation for the temperature sensitivity of 30-S subunit assembly in E. coli 219ts2.

Electron microscopic mapping of secondary structures in bacterial 16S and 23S ribosomal ribonucleic acid and 30S precursor ribosomal ribonucleic acid

Electron microscopy revealed reproducible secondary structure patterns within partially denatured 16S and 23S ribosomal ribonucleic acid (rRNA) from Escherichia coli. When prepared with 50% formamide-100 mM ammonium acetate, 16S rRNA included two small hairpins that appeared in over 50% of all molecules. Three open loops were observed with frequencies of less than 25%. In contrast, 23S rRNA included a terminal open loop and two additional large structures in over 75% of all molecules. These secondary structure patterns were conserved in the 16S and 23S rRNA from Pseudomonas aeruginosa. The secondary structure of the 30S precursor rRNA from the ribonclease III-deficient E. coli mutant AB105 was mapped after partial denaturation in 70% formamide-100 mM ammonium acetate. Two large open loops were superimposed on the 16S and 23S rRNA secondary structure patterns. These loops were the most frequent structures found on the precursor, and their stems coincided with ribonuclease III cleavage sites. A tentative 5'-3 orientation was determined for the secondary structure patterns of 16S and 23S rRNA from their relative locations within 30S precursor rRNA. The relation of secondary structure to ribosomal protein binding and ribonuclease III cleavage is discussed.