Molecular cloning and comparative sequence analyses of rRNA operons in Streptomyces nodosus ATCC 14899.

The genome of Streptomyces nodosus contains six ribosomal RNA (rRNA) operons. Four of the rRNA operons; rrnB, rrnD, rrnE and rrnF were cloned. We have completely sequenced all four operons, including a region 750 base pairs (bp) upstream of the 16S rRNA gene. The three rRNA genes present in each operon were closely linked in the order 16S-23S-5S. A sequence comparison of the four operons showed more than 99% sequence similarity between the corresponding 16S and 23S rRNA genes, and more than 97% similarity between 5S rRNA genes. The sequence differences observed between 23S rRNA genes appeared to be localized in two specific regions. Substantial sequence differences were found in the region upstream of the 16S rRNA gene as well as in the internal transcribed spacers. No tRNA gene was found in the 16S-23S spacer regions.     

Unbalanced rRNA gene dosage and its effects on rRNA and ribosomal-protein synthesis.

The synthesis of rRNA was unbalanced by the introduction of plasmids containing rRNA operons with large internal deletions. Significant unbalanced synthesis was achieved only when the deletions affected both 16S and 23S RNA genes or when the deletions affected the 23S RNA gene alone. Although large imbalances in rRNA synthesis resulted from deletions affecting 16S and 23S RNA genes or only 23S RNA genes, excess 16S RNA and defective rRNA species were rapidly degraded. Large imbalances in the synthesis of regions of rRNA did not result in significantly unbalanced synthesis of ribosomal proteins. It therefore is probable that excess intact 16S RNA is degraded because ribosomal proteins are not available for packaging the RNA into ribosomes. Defective RNA species also may be degraded for this reason or because proper ribosome assembly is prevented by the defects in RNA structure. We propose two possible explanations for the finding that unbalanced overproduction of binding sites for feedback ribosomal protein does not result in significant unbalanced translational feedback depression of ribosomal protein mRNAs.     

Ribosomal RNA and ribosomal proteins in corynebacteria

Ribosomal RNAs (rRNAs) (16S, 23S, 5S) encoded by the rrn operons and ribosomal proteins play a very important role in the formation of ribosomes and in the control of translation. Five copies of the rrn operon were reported by hybridization studies in Brevibacterium (Corynebacterium) lactofermentum but the genome sequence of Corynebacterium glutamicum provided evidence for six rrn copies. All six copies of the C. glutamicum 16S rRNA have a size of 1523 bp and each of the six copies of the 5S contain 120 bp whereas size differences are found between the six copies of the 23S rRNA. The anti-Shine-Dalgarno sequence at the 3'-end of the 16S rRNA was 5'-CCUCCUUUC-3'. Each rrn operon is transcribed as a large precursor rRNA (pre-rRNA) that is processed by RNaseIII and other RNases at specific cleavage boxes that have been identified in the C. glutamicum pre-rRNA. A secondary structure of the C. glutamicum 16S rRNA is proposed. The 16S rRNA sequence has been used as a molecular evolution clock allowing the deduction of a phylogenetic tree of all Corynebacterium species. In C. glutamicum, there are 11 ribosomal protein gene clusters encoding 42 ribosomal proteins. The organization of some of the ribosomal protein gene cluster is identical to that of Escherichia coli whereas in other clusters the organization of the genes is rather different. Some specific ribosomal protein genes are located in a different cluster in C. glutamicum when compared with E. coli, indicating that the control of expression of these genes is different in E. coli and C. glutamicum.     

5S rRNA gene deletions cause an unexpectedly high fitness loss in Escherichia coli.

In Escherichia coli, ribosomal RNAs (16S, 23S and 5S) are co-transcribed in a highly regulated manner from seven genomically dispersed operons. Previous studies on the cellular effects of altered levels of two of these rRNAs (16S and 23S) have been useful in better understanding the regulation of rRNA expression. Furthering these studies, we have investigated the effect of 5S rRNA deficiencies on cell fitness through the sequential deletion of 5S rRNA genes. Our findings indicate that the loss of 5S rDNA from multiple genes decreases cell fitness more rapidly than loss of a similar number of 16S and 23S rRNA genes. These results suggest that the cell's innate ability to up-regulate rRNA operons does not compensate for 5S rRNA deficiencies, as was previously shown for 16S and 23S rRNAs. A plasmid-borne 5S rRNA gene is able to compensate for the deleted 5S rRNA genes.     

Molecular cloning of the ribosomal RNA genes of the photosynthetic bacterium Rhodopseudomonas capsulata

Summary Chromosomal segments of Rhodopseudomonas capsulata carrying the ribosomal operons and cloned with the cosmid vector pHC79 have been identified by cross hybridization with ³²P-ATP labeled rRNAs. At least seven rRNA operons are present in the R. capsulata chromosome. By R-loop analyses of DNA-RNA hybrids, two distinct loop structures of sizes 1.50 kb and 2.52 kb corresponding to the 16S and 23S RNA molecules, respectively, were detected. Intact 23S RNA molecules can be isolated from R. capsulata ribosomes by sucrose density centrifugation. However, fragmentation of the 23S RNA molecule into a 16S-like molecule was observed during gel electrophoresis. Restriction mapping and hybridization of a 9 kb PstI fragment that contained one copy of the rRNA operon showed the following sequence of the RNA genes in R. capsulata 16S, 23S, and 5S. A spacer region of 0.91 kb was found between the 16S and the 23S RNA genes.