A temperature-sensitive mutant in the gene rplX for ribosomal protein L24 and its suppression by spontaneous mutations in a 23S rRNA gene of Escherichia coli.

A temperature-sensitive mutant with an altered ribosomal protein L24 was analysed. Revertant analysis showed that the temperature-sensitive growth was correlated with the altered protein. A DNA segment containing the mutant rplX gene was cloned and sequenced. The GGC codon for glycine at the amino acid position 84 of the protein was found to be altered to a GAC codon for aspartic acid. By transforming the rplX mutant with a plasmid carrying the rrnB operon and by selecting for temperature-resistant transformants we obtained two spontaneous suppressor mutants in the gene for 23S rRNA. DNA sequence analysis of the region corresponding to the 5' end of the 23S rRNA showed a C to T alteration at position 33 in both mutants and an additional A to G alteration at position 466 in one of them. The results suggest intimate interaction of protein L24 and the 5' end of 23S rRNA in vivo and support a secondary structure model of the 23S rRNA which brings these mutational points into a close contact.     

Unbalanced regulation of the ribosomal 5 S RNA-binding protein in Saccharomyces cerevisiae expressing mutant 5 S rRNAs.

A gene encoding the 5 S rRNA-binding protein (YL3) in yeast (Saccharomyces cerevisiae) was further characterized with respect to its chromosomal localization, the controlling sequence regions, and the influence of 5 S rRNA gene expression. Sequence and chromosome blot analyses localized the gene on chromosome XVI immediately downstream of a cytochrome oxidase assembly gene, COXII. S1 nuclease protection studies identified two major initiation sites, 20 and 65 nucleotides upstream of the coding sequence, and a single polyadenylation site, 98 nucleotides downstream of the stop codon. Northern blot analyses and S1 nuclease protection indicated a normal pattern of gene regulation in media supporting alternate rates of growth, but significantly unbalanced regulation was observed in the presence of mutant 5 S rRNA genes which under-produce RNA and result in reduced growth rates. The results suggest a co-ordinating regulatory mechanism which maintains appropriate levels of 5 S rRNA-protein complex; an internal control region-like sequence in the upstream region of the YL3 gene is consistent with this feedback mechanism.     

Essential structural features in the Schizosaccharomyces pombe pre-rRNA 5' external transcribed spacer

The proximal region in the 5' external transcribed spacer (5'ETS) of the genes encoding ribosomal RNAs in Schizosaccharomyces pombe was examined with respect to structural features which underlie rRNA maturation. Computer analyses and partial digestion with nuclease probes indicate a crucifix-like structure composed primarily of three extended hairpins which are more highly ordered than previously proposed in Saccharomyces cerevisiae. A re-evaluation of the same region in S. cerevisiae indicates a conserved core structure, including the U3 snoRNA binding site within this higher-order structure. The sequences encoding the individual hairpins were deleted by PCR-mediated mutagenesis and the mutant rDNAs were expressed in vivo to determine the effect of these features on rRNA maturation. Quantitative hybridization analyses indicate that the first hairpin only has modest effects on 18 S rRNA maturation, but the other two regions are critical and no mature 18 S rRNA was observed. When smaller changes were systematically introduced into the critical regions, strong correlations were observed with known or putative events in rRNA maturation. Changes associated with an intermediate cleavage site in helix II and with the putative U3 snoRNA binding site were again critical to 18 S rRNA production. In each case, the effects were sequence dependent and not simply the result of disrupted structure. Further analyses of the 5.8 S rRNA indicate that the large ribosomal subunit RNA can be properly processed in each case but the efficiency is reduced by as much as 60 %, an observation which provides new evidence of interdependency in the maturation process. The results illustrate that rRNA processing is more critically dependent on the 5'ETS than previously believed.     

Sequence organization of repetitive elements in the flanking regions of the chloroplast ribosomal unit of Chlamydomonas reinhardii.

The flanking regions and the end of the chloroplast ribosomal unit of Chlamydomonas reinhardii have been sequenced. The upstream region of the ribosomal unit contains three open reading frames coding for 111, 117 and 124 amino acids, respectively. The latter polypeptide is partially related to the ribosomal protein L16 of E. coli. Two of the open reading frames overlap each other and are oriented in opposite direction. The region between these open reading frames and the 5' end of the 16S rRNA gene contains numerous short direct and inverted repeats which can be folded into large stem-loop structures. Sequence elements that resemble prokaryotic promoters are found in the same region. Several of the repeated elements are distributed throughout the non-coding regions of the chloroplast inverted repeat. Sequence comparison between the 5S rRNA and its gene does not reveal any significant sequence heterogeneity between the chloroplast 5S rRNA genes.     

Complementarity between the mRNA 5' untranslated region and 18S ribosomal RNA can inhibit translation

In eubacteria, base pairing between the 3' end of 16S rRNA and the ribosome-binding site of mRNA is required for efficient initiation of translation. An interaction between the 18S rRNA and the mRNA was also proposed for translation initiation in eukaryotes. Here, we used an antisense RNA approach in vivo to identify the regions of 18S rRNA that might interact with the mRNA 5' untranslated region (5' UTR). Various fragments covering the entire mouse 18S rRNA gene were cloned 5' of a cat reporter gene in a eukaryotic vector, and translation products were analyzed after transient expression in human cells. For the largest part of 18S rRNA, we show that the insertion of complementary fragments in the mRNA 5' UTR do not impair translation of the downstream open reading frame (ORF). When translation inhibition is observed, reduction of the size of the complementary sequence to less than 200 nt alleviates the inhibitory effect. A single fragment complementary to the 18S rRNA 3' domain retains its inhibitory potential when reduced to 100 nt. Deletion analyses show that two distinct sequences of approximately 25 nt separated by a spacer sequence of 50 nt are required for the inhibitory effect. Sucrose gradient fractionation of polysomes reveals that mRNAs containing the inhibitory sequences accumulate in the fractions with 40S ribosomal subunits, suggesting that translation is blocked due to stalling of initiation complexes. Our results support an mRNA-rRNA base pairing to explain the translation inhibition observed and suggest that this region of 18S rRNA is properly located for interacting with mRNA.     

Sequence of the gene for isoleucine tRNA1 and the surrounding region in a ribosomal RNA operon of Escherichia coli

A DNA fragment of about 2000 base pairs carrying the gene for tRNA(1) (Ile) has been cloned from a total Eco RI endonuclease digest of Escherichia coli DNA. Sequence analyses revealed that about the first 850 base pairs from one end of the fragment contain a nucleotide sequence corresponding to that in the 3'-end of 16S rRNA. The gene for tRNA(Ile) follows the 16S rRNA gene and both genes flank a spacer sequence of 68 base pairs. The spacer region contains a repeating, a hair pin and a symmetrical structure when the sequence is viewed in the single stranded form. A notable hair pin structure is also observed in the region adjacent to the 3'-end of the tRNA(1) (Ile) gene. In addition, about 850 base pairs from the other end of the DNA fragment have been found to contain the nucleotide sequence of the 5'-end of 23S rRNA. The presence of the genes for tRNA(1) (Ile), 16S and 23S rRNA and the hybridization to tRNA(1) (Ala) suggest that this cloned DNA is part of one of the E. coli rRNA operons carrying these two tRNA genes as a spacer.Images     

Nucleotide sequence of a 'truncated rRNA operon' of the Euglena gracilis chloroplast genome.

An extra 16S rRNA gene (s-16S rDNA) from the Euglena gracilis chloroplast genome and several hundred positions of its flanking regions have been sequenced. The structural part has 1486 positions and is to 98% homologous in its sequence with the 16S rRNA gene in functional chloroplast rRNA operons. Sequences of about 200 positions upstream and 15 positions downstream of the structural part of the s-16S rRNA gene region are highly homologous with corresponding parts in the functional operon. Neither tRNA genes (A1a, I1e) nor parts of the 23S and 5S rRNA genes are found within 557 positions after the 3' end of the s-16S rRNA gene, i.e., the 330 bp homology, observed in electron microscopic studies of heteroduplexes (4), between the s-16S rDNA downstream region and the 6.2 kb repeated segment containing the functional rRNA operon, must be due to a DNA stretch in the interoperon spacer. A structural model of the "truncated rRNA operon" is presented. Results from S-1 endonuclease analysis suggest that the s-16S rDNA region is probably not transcribed into stable s-16S rRNA.