A mutant from Escherichia coli which lacks ribosomal proteins S17 and L29 used to localize these two proteins on the ribosomal surface

Inactivation of ribosomal protein genes in Bacillus subtilis reveals importance of each ribosomal protein for cell proliferation and cell differentiation

Among the 57 genes that encode ribosomal proteins in the genome of Bacillus subtilis, a Gram-positive bacterium, 50 genes were targeted by systematic inactivation. Individual deletion mutants of 16 ribosomal proteins (L1, L9, L15, L22, L23, L28, L29, L32, L33.1, L33.2, L34, L35, L36, S6, S20, and S21) were obtained successfully. In conjunction with previous reports, 22 ribosomal proteins have been shown to be nonessential in B. subtilis, at least for cell proliferation. Although several mutants that harbored a deletion of a ribosomal protein gene did not show any significant differences in any of the phenotypes that were tested, various mutants showed a reduced growth rate and reduced levels of 70S ribosomes compared with the wild type. In addition, severe defects in the sporulation frequency of the ΔrplA (L1) mutant and the motility of the ΔrpsU (S21) mutant were observed. These data provide the first evidence in B. subtilis that L1 and S21 are required for the progression of cellular differentiation.

Systematic chromosomal deletion of bacterial ribosomal protein genes

Detailed studies of ribosomal proteins (RPs), essential components of the protein biosynthetic machinery, have been hampered by the lack of readily accessible chromosomal deletions of the corresponding genes. Here, we report the systematic genomic deletion of 41 individual RP genes in Escherichia coli, which are not included in the Keio collection. Chromosomal copies of these genes were replaced by an antibiotic resistance gene in the presence of an inducible, easy-to-exchange plasmid-born allele. Using this knockout collection, we found nine RPs (L15, L21, L24, L27, L29, L30, L34, S9, and S17) nonessential for survival under induction conditions at various temperatures. Taken together with previous results, this analysis revealed that 22 of the 54 E. coli RP genes can be individually deleted from the genome. These strains also allow expression of truncated protein variants to probe the importance of RNA-protein interactions in functional sites of the ribosome. This set of strains should enhance in vivo studies of ribosome assembly/function and may ultimately allow systematic substitution of RPs with RNA.

Ribosomal gene disruption in the extreme thermophile Thermus thermophilus HB8. Generation of a mutant lacking ribosomal protein S17

S17 is a primary rRNA-binding protein which has been implicated in ribosome assembly and translational fidelity. We describe the generation and biochemical characterization of an S17 minus ribosomal mutant, a ribosomal protein-lacking mutant obtained in Thermus thermophilus HB8. The S17 mutant was obtained by insertional inactivation of the target gene with the kanamycin adenyl transferase (kat) gene, making use of a Thermus-Escherichia shuttle vector and the natural ability of Thermus to transform. In the final construct used to transform Thermus cells, the S17 coding region was replaced with the kat gene cloned in-frame with the first three amino acids of S17. Hence, in vivo transcription of the kat gene was under the control of the ribosomal operon promoter. As in Escherichia coli, the Thermus S17 mutant exhibited a temperature-sensitive phenotype. Two-dimensional PAGE, Western blot, and ELISA confirmed the absence of S17 from the mutant ribosomes. Sucrose-gradient profiles of mutant cells showed a clear separation and normal proportions of 50S and 30S subunits and a normal ratio between them. In addition, the S17 mutant showed the presence of a 20S peak representing assembly-defective particles. The successful re-incorporation of protein S17 into the mutant ribosomes was demonstrated when reconstitution with isolated S17 was performed at 60 degrees C.

Subpopulations of chloroplast ribosomes change during photoregulated development of Zea mays leaves: ribosomal proteins L2, L21, and L29

Seedlings grown in darkness, i.e., etiolated seedlings, lack chlorophyll and most other components of the photosynthetic apparatus. On illumination, the plastids become photosynthetically competent through the production of chlorophylls and proteins encoded by certain chloroplast and nuclear genes. There are two types of photosynthetic cells in leaves of the C4 plant maize: bundle sheath cells (BSC) and adjacent mesophyll cells (MC). Some proteins of the maize photosynthetic machinery are solely or preferentially localized in MC and others in BSC. A particular gene may be photoregulated up in one cell type and down in the other. Transcripts of the nuclear gene rpl29, encoding the chloroplast ribosomal protein L29, increase in abundance about 17-fold during light-induced maturation of plastids. There is about 1.5 times more L29 protein in ribosomes of greening leaves than in ribosomes of unilluminated leaves; the L29 contents of MC and BSC are about the same. However, L21 is present about equally in plastid ribosomes of unilluminated and illuminated seedlings. In contrast to both L29 and L21, the fraction of the ribosome population containing L2 is about the same in MC and BSC of etiolated leaves but, on illumination, the proportion of the ribosome population with L2 increases in BSC but not in MC. The existence of different subpopulations of plastid ribosomes-e.g., those with and without L21 and/or L29 during development-evokes interesting, but as yet unanswered, questions about the roles of different types of ribosomes in differentiation.

Nucleotides in 16S rRNA protected by the association of 30S and 50S ribosomal subunits

We have studied the interaction of 16S rRNA in 30S subunits with 50S subunits using a series of chemical probes that monitor the accessibility of the RNA bases and backbone. The probes include 1-cyclohexyl-3-(2-morpholinoethyl) carbodiimide metho-p-toluene sulfonate (CMCT; to probe U at N-3 and G at N-1), diethylpyrocarbonate (DEPC; to probe A at N-7), dimethyl sulfate (DMS; to probe A at N-1, and C at N-3), kethoxal (to probe G at N-1 and N-2), hydroxyl radicals generated by free Fe(II)-EDTA (to probe the backbone ribose groups) and Pb(II). The sites of reaction were identified by primer extension of the probed RNA. Association of the subunits protects the bases of 11 nucleotides and the ribose groups of over 90 nucleotides of 16S rRNA. The nucleotides protected from the base-specific probes are often adjacent to one another and surrounded by sugar-phosphate backbone protections; thus, the results obtained with the different probes confirmed each other. Most of the protected nucleotides occur in five extended-stem-loop structures around positions 250, 700, 790, 900, and 1408-1495. These regions are located in the platform and bottom of the subunit in the general vicinity of inter-subunit bridges that are visible in reconstructed electron micrographs. Our results provide an extensive map of the nucleotides in 16S rRNA that are likely to be involved in subunit-subunit interactions.

Mutants lacking individual ribosomal proteins as a tool to investigate ribosomal properties

We have isolated and characterized mutants which lack one or two of sixteen of the proteins of the Escherichia coli ribosome. The mutation responsible in each case mapped close to, and probably in, the corresponding gene. A conditional lethal phenotype and a variable degree of impairment in growth was observed. The missing protein was readily restored to the organelle if E coli or other eubacterial ribosomal proteins were added to a suspension of the mutant particles. The mutants have been used to investigate the role of individual proteins in ribosome function and assembly. They have also aided in the topographic pinpointing of proteins on the surface of the organelle.

Ribosomal protein L30 is dispensable in the yeast Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, L30 is one of many ribosomal proteins that is encoded by two functional genes. We have cloned and sequenced RPL30B, which shows strong homology to RPL30A. Use of mRNA as a template for a polymerase chain reaction demonstrated that RPL30B contains an intron in its 5' untranslated region. This intron has an unusual 5' splice site, C/GUAUGU. The genomic copies of RPL30A and RPL30B were disrupted by homologous recombination. Growth rates, primer extension, and two-dimensional ribosomal protein analyses of these disruption mutants suggested that RPL30A is responsible for the majority of L30 production. Surprisingly, meiosis of a diploid strain carrying one disrupted RPL30A and one disrupted RPL30B yielded four viable spores. Ribosomes from haploid cells carrying both disrupted genes had no detectable L30, yet such cells grew with a doubling time only 30% longer than that of wild-type cells. Furthermore, depletion of L30 did not alter the ratio of 60S to 40S ribosomal subunits, suggesting that there is no serious effect on the assembly of 60S subunits. Polysome profiles, however, suggest that the absence of L30 leads to the formation of stalled translation initiation complexes.

Ribosomal protein L30 is dispensable in the yeast Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, L30 is one of many ribosomal proteins that is encoded by two functional genes. We have cloned and sequenced RPL30B, which shows strong homology to RPL30A. Use of mRNA as a template for a polymerase chain reaction demonstrated that RPL30B contains an intron in its 5' untranslated region. This intron has an unusual 5' splice site, C/GUAUGU. The genomic copies of RPL30A and RPL30B were disrupted by homologous recombination. Growth rates, primer extension, and two-dimensional ribosomal protein analyses of these disruption mutants suggested that RPL30A is responsible for the majority of L30 production. Surprisingly, meiosis of a diploid strain carrying one disrupted RPL30A and one disrupted RPL30B yielded four viable spores. Ribosomes from haploid cells carrying both disrupted genes had no detectable L30, yet such cells grew with a doubling time only 30% longer than that of wild-type cells. Furthermore, depletion of L30 did not alter the ratio of 60S to 40S ribosomal subunits, suggesting that there is no serious effect on the assembly of 60S subunits. Polysome profiles, however, suggest that the absence of L30 leads to the formation of stalled translation initiation complexes.

Localization of proteins L4, L5, L20 and L25 on the ribosomal surface by immuno-electron microscopy

Ribosomal proteins L4, L5, L20 and L25 have been localized on the surface of the 50S ribosomal subunit of Escherichia coli by immuno-electron microscopy. The two 5S RNA binding proteins L5 and L25 were both located at the central protuberance extending towards its base, at the interface side of the 50S particle. L5 was localized on the side of the central protuberance that faces the L1 protuberance, whereas L25 was localized on the side that faces the L7/L12 stalk. Proteins L4 and L20 were both located at the back of the 50S subunit; L4 was located in the vicinity of proteins L23 and L29, and protein L20 was localized between proteins L17 and L10 and is thus located below the origin of the L7/L12 stalk.

Immunoelectron microscopic localisation of ribosomal proteins from Bacillus stearothermophilus that are homologous to Escherichia coli L1, L6, L23 and L29

The locations of proteins BL1, BL6, BL23 and BL29 from Bacillus stearothermophilus have been determined on the ribosomal surface by immunoelectron microscopy. All four proteins were localized in the same region of the 50S subunit as their homologous counterparts from Escherichia coli, indicating that the ribosomal architecture is the same in both species. This finding is of great importance as it allows structural data obtained on ribosomes from either organism to be incorporated into a unique ribosome model.

Localization of ribosomal protein L27 at the peptidyl transferase centre of the 50 S subunit, as determined by immuno-electron microscopy

Protein L27 has been localized on the ribosomal surface by immuno-electron microscopy by using antibodies specific for Escherichia coli L27, and by reconstituting 50 S subunits from an E. coli mutant, which lacks protein L27, with the homologous protein from Bacillus subtilis and using antibodies specific for the B. subtilis protein. With both approaches, protein L27 has been located at the base of the central protuberance at the interface side of the 50 S particle and thus in proximity to the peptidyl transferase centre. The immuno-electron microscopic data also suggest that the interface region of the 50 S particle is not as flat as most of the proposed three-dimensional models suggest, but instead there is a significant depression.

The topography of ribosomal proteins on the surface of the 30S subunit of Escherichia coli

Eight ribosomal proteins, S6, S10, S11, S15, S16, S18, S19 and S21 have been localized on the surface of the 30S subunit from Escherichia coli by immuno electron microscopy. The specificity of the antibody binding sites was demonstrated by stringent absorption experiments. In addition we have reinvestigated and refined the locations of proteins S5, S13 and S14 on the ribosomal surface which had previously been localized in our laboratory (Tischendorf et al., Mol. Gen. Genet. 134, 209-223, 1974). Thus altogether 16 out of the 21 ribosomal proteins of the small subunit from E. coli have been mapped in our laboratory.