A pair of Bacillus subtilis ribosomal protein genes mapping outside the principal ribosomal protein cluster.

Before now, the only ribosomal protein gene loci to be identified in Bacillus subtilis map within the principal ribosomal protein gene cluster at about 10 degrees on the linkage map. Using mutants with alterations in large subunit ribosomal proteins L20 or L24, I mapped the corresponding genes near leuA at approximately 240 degrees. The data were fully consistent with the fact that the genes for the two proteins were close together but not near any other ribosomal protein genes, as is also the case with the genes for the corresponding proteins of Escherichia coli.     

The yeast ribosomal protein S7 and its genes.

Ribosomal protein S7 of Saccharomyces cerevisiae is encoded by two genes RPS7A and RPS7B. The sequence of each copy was determined; their coding regions differ in only 14 nucleotides, none of which leads to changes in the amino acid sequence. The predicted protein consists of 261 amino acids, making it the largest protein of the 40 S ribosomal subunit. It is highly basic near the NH2 terminus, as are most ribosomal proteins. Protein S7 is homologous to both human and rat ribosomal protein S4. RPS7A and RPS7B contain introns of 257 and 269 nucleotides, respectively, located 11 nucleotides beyond the initiator AUG. The splicing of the introns is efficient. Either RPS7A or RPS7B will support growth. However, deletion of both genes is lethal. RPS7A maps distal to CDC11 on chromosome X, and RPS7B maps distal to CUP1 on chromosome VIII.     

Cloning and analysis of the spc ribosomal protein operon of Bacillus subtilis: comparison with the spc operon of Escherichia coli.

A segment of Bacillus subtilis chromosomal DNA homologous to the Escherichia coli spc ribosomal protein operon was isolated using cloned E. coli rplE (L5) DNA as a hybridization probe. DNA sequence analysis of the B. subtilis cloned DNA indicated a high degree of conservation of spc operon ribosomal protein genes between B. subtilis and E. coli. This fragment contains DNA homologous to the promoter-proximal region of the spc operon, including coding sequences for ribosomal proteins L14, L24, L5, S14, and part of S8; the organization of B. subtilis genes in this region is identical to that found in E. coli. A region homologous to the E. coli L16, L29 and S17 genes, the last genes of the S10 operon, was located upstream from the gene for L14, the first gene in the spc operon. Although the ribosomal protein coding sequences showed 40-60% amino acid identity with E. coli sequences, we failed to find sequences which would form a structure resembling the E. coli target site for the S8 translational repressor, located near the beginning of the L5 coding region in E. coli, in this region or elsewhere in the B. subtilis spc DNA.     

Subcellular distribution of ribosomal proteins S6 and eL12

Summary The process of ribosome assembly in eukaryotes was studied by injecting tritium-labeled ribosomal proteins S6 and eL12 into oocytes of Xenopus laevis. The subcellular distribution of the two proteins was visualized by means of autoradiography in sections of oocytes. Protein S6 but not eL12 was found in the nucleus where it accumulated at the nucleoli. In the presence of actinomycin D the accumulation of S6 at the nucleoli was reduced. In-situ immunofluorescence studies indicated that S6 is located at the nucleoli and eL12 exclusively in the cytoplasm. It appears that S6 is involved in the early ribosomal assembly process at the nucleoli, whereas eL12 is restricted to the cytoplasm where it is incorporated into 60S ribosomal subunits in a late assembly step.     

Bacillus subtilis mutants with alterations in ribosomal protein S4.

Two mutants with different alterations in the electrophoretic mobility of ribosomal protein S4 were isolated as spore-plus revertants of a streptomycin-resistant, spore-minus strain of Bacillus subtilis. The mutations causing the S4 alterations, designated rpsD1 and rpsD2, were located between the argGH and aroG genes, at 263 degrees on the B. subtilis chromosome, distant from the major ribosomal protein gene cluster at 12 degrees. The mutant rpsD alleles were isolated by hybridization using a wild-type rpsD probe, and their DNA sequences were determined. The two mutants contained alterations at the same position within the S4-coding sequence, in a region containing a 12-bp tandem duplication; the rpsD1 allele corresponded to an additional copy of this repeated segment, resulting in the insertion of four amino acids, whereas the rpsD2 allele corresponded to deletion of one copy of this segment, resulting in the loss of four amino acids. The effects of these mutations, alone and in combination with streptomycin resistance mutations, on growth, sporulation, and streptomycin resistance were analyzed.     

Nucleotide sequences of Bacillus stearothermophilus ribosomal protein genes: part of the ribosomal S10 operon

Restriction fragments from Bacillus stearothermophilus chromosomal DNA were cross-hybridized with the Escherichia coli ribosomal protein L2 gene rplB. A 2-kb EcoRI fragment which showed cross-hybridization was cloned into the M13 phage and sequenced by the dideoxy chain-terminating method. Comparison of the deduced amino-acid sequences with the corresponding sequences of E. coli ribosomal proteins showed that this fragment contains the region encoding the C-terminus of L2, the genes encoding S19, L22, S3 as well as the N-terminus of L16. Thus the organization of this gene cluster is the same as that in the S10 operon of E. coli. The deduced sequences of proteins L22 and S3, which have not been determined so far, were found to have 52% or 55% amino-acid identity, respectively, with those of the corresponding proteins in E. coli. The deduced B. stearothermophilus S19 protein sequence was in accordance with the reinvestigated protein sequence (H. Hirano, personal communication).     

The GTP-binding protein YlqF participates in the late step of 50 S ribosomal subunit assembly in Bacillus subtilis

Bacillus subtilis YlqF belongs to the Era/Obg subfamily of small GTP-binding proteins and is essential for bacterial growth. Here we report that YlqF participates in the late step of 50 S ribosomal subunit assembly. YlqF was co-fractionated with the 50 S subunit, depending on the presence of noncleavable GTP analog. Moreover, the GTPase activity of YlqF was stimulated specifically by the 50 S subunit in vitro. Dimethyl sulfate footprinting analysis disclosed that YlqF binds to a unique position in 23 S rRNA. Yeast two-hybrid data revealed interactions between YlqF and the B. subtilis L25 protein (Ctc). The interaction was confirmed by the pull-down assay of the purified proteins. Specifically, YlqF is positioned around the A-site and P-site on the 50 S subunit. Proteome analysis of the abnormal 50 S subunits that accumulated in YlqF-depleted cells showed that L16 and L27 proteins, located near the YlqF-binding domain, are missing. Our results collectively indicate that YlqF will organize the late step of 50 S ribosomal subunit assembly.     

Crystal structure of the ribosomal protein S6 from Thermus thermophilus.

The amino acid sequence and crystal structure of the ribosomal protein S6 from the small ribosomal subunit of Thermus thermophilus have been determined. S6 is a small protein with 101 amino acid residues. The 3D structure, which was determined to 2.0 A resolution, consists of a four-stranded anti-parallel beta-sheet with two alpha-helices packed on one side. Similar folding patterns have been observed for other ribosomal proteins and may suggest an original RNA-interacting motif. Related topologies are also found in several other nucleic acid-interacting proteins and based on the assumption that the structure of the ribosome was established early in the molecular evolution, the possibility that an ancestral RNA-interacting motif in ribosomal proteins is the evolutionary origin for the nucleic acid-interacting domain in large classes of ribonucleic acid binding proteins should be considered.     

The rpsD gene, encoding ribosomal protein S4, is autogenously regulated in Bacillus subtilis.

Although the mechanisms for regulation of ribosomal protein gene expression have been established for gram-negative bacteria such as Escherichia coli, the regulation of these genes in gram-positive bacteria such as Bacillus subtilis has not yet been characterized. In this study, the B. subtilis rpsD gene, encoding ribosomal protein S4, was found to be subject to autogenous control. In E. coli, rpsD is located in the alpha operon, and S4 acts as the translational regulator for alpha operon expression, binding to a target site in the alpha operon mRNA. The target site for repression of B. subtilis rpsD by protein S4 was localized by deletion and oligonucleotide-directed mutagenesis to the leader region of the monocistronic rpsD gene. The B. subtilis rpsD leader exhibits little sequence homology to the E. coli alpha operon leader but may be able to form a pseudoknotlike structure similar to that found in E. coli.     

Interaction of ribosomal proteins, S6, S8, S15 and S18 with the central domain of 16 S ribosomal RNA

We have constructed complexes of ribosomal proteins S8, S15, S8 + S15 and S8 + S15 + S6 + S18 with 16 S ribosomal RNA, and probed the RNA moiety with a set of structure-specific chemical and enzymatic probes. Our results show the following effects of assembly of proteins on the reactivity of specific nucleotides in 16 S rRNA. (1) In agreement with earlier work, S8 protects nucleotides in and around the 588-606/632-651 stem from attack by chemical probes; this is supported by protection in and around these same regions from nucleases. In addition, we observe protection of positions 573-575, 583, 812, 858-861 and 865. Several S8-dependent enhancements of reactivity are found, indicating that assembly of this protein is accompanied by conformational changes in 16 S rRNA. These results imply that protein S8 influences a much larger region of the central domain than was previously suspected. (2) Protein S15 protects nucleotides in the 655-672/734-751 stem, in agreement with previous findings. We also find S15-dependent protection of nucleotides in the 724-730 region. Assembly of S15 causes several enhancements of reactivity, the most striking of which are found at G664, A665, G674, and A718. (3) The effects of proteins S6 and S18 are dependent on the simultaneous presence of both proteins, and on the presence of protein S15. S6 + S18-dependent protections are located in the 673-730 and 777-803 regions. We observed some variability in our results with these proteins, depending on the ratio of protein to RNA used, and in different trials using enzymatic probes, possibly due to the limited solubility of protein S18. Consistently reproducible was protection of nucleotides in the 664-676 and 715-729 regions. Among the latter are three of the nucleotides (G664, G674 and A718) that are strongly enhanced by assembly of protein S15. This result suggests that an S15-induced conformational change involving these nucleotides may play a role in the co-operative assembly of proteins S6 and S18.     

Subcellular distribution of ribosomal proteins in Dictyostelium discoideum

The distribution of ribosomal proteins in monosomes, polysomes, the postribosomal cytosol, and the nucleus was determined during steady-state growth in vegetative amoebae. A partitioning of previously reported cell-specific ribosomal proteins between monosomes and polysomes was observed. L18, one of the two unique proteins in amoeba ribosomes, was distributed equally among monosomes and polysomes. However S5, the other unique protein, was abundant in monosomes but barely visible in polysomes. Of the developmentally regulated proteins, D and S6 were detectable only in polysomes and S14 was more abundant in monosomes. The cytosol revealed no ribosomal proteins. On staining of the nuclear proteins with Coomassie blue, about 18, 7 from 40S subunit and 11 from 60S subunit, were identified as ribosomal proteins. By in vivo labeling of the proteins with [35S]methionine, 24 of the 34 small subunit proteins and 33 of the 42 large subunit proteins were localized in the nucleus. For the majority of the ribosomal proteins, the apparent relative stoichiometry was similar in nuclear preribosomal particles and in cytoplasmic ribosomes. However, in preribosomal particles the relative amount of four proteins (S11, S30, L7, and L10) was two- to four-fold higher and of eight proteins (S14, S15, S20, S34, L12, L27, L34, and L42) was two-to four-fold lower than that of cytoplasmic ribosomes.     

Replication of the extrachromosomal ribosomal RNA genes of Tetrahymena thermophilia.

Cultures of Tetrahymena thermophila were deprived of nutrients and later refed with enriched medium to obtain partial synchrony of DNA replication. Preferential replication of the extrachromosomal, macronuclear ribosomal RNA genes (rDNA) was found to occur at 40-80 min after refeeding. The rDNA accounted for one half of the label incorporated into cellular DNA during this period. Electron microscopy of the purified rDNA showed 1% replicative intermediates. Their structure was that expected for bidirectional replication of the linear rDNA from an origin or origins located in the central nontranscribed region of the palindromic molecule. Similar forms had previously been observed for the rDNA of a related species, Tetrahymena pyriformis. The electron microscopic data was consistent with an origin of replication located approximatley 600 base pairs from the center of the rDNA of T. thermophila, in contrast to a more central location in the rDNA of T. pyriformis. One implication of an off-center origin of replication is that there are two such sequences per palindromic molecule.     

Comparative electron microscopic study on the location of ribosomal proteins S3 and S7 on the surface of the E. coli 30S subunit using monoclonal and conventional antibody

Summary Mice were immunised with 30S subunits from E. coli and their spleen cells were fused with myeloma cells. From this fusion two monoclonal antibodies were obtained, one of which was shown to be specific for ribosomal protein S3, the other for ribosomal protein S7. The two monoclonal antibodies formed stable complexes with intact 30S subunits and were therefore used for the three-dimensional localisation of ribosomal proteins S3 and S7 on the surface of the E. coli small subunit by immuno electron microscopy. The antibody binding sites determined with the two monoclonal antibodies were found to lie in the same area as those obtained with conventional antibodies. Both proteins S3 and S7 are located on the head of the 30S subunit, close to the one-third/two-thirds partition. Protein S3 is located just above the small lobe, whereas protein S7 is located on the side of the large lobe.     

Importance of the 5 S rRNA-binding ribosomal proteins for cell viability and translation in Escherichia coli

A specific complex of 5 S rRNA and several ribosomal proteins is an integral part of ribosomes in all living organisms. Here we studied the importance of Escherichia coli genes rplE, rplR and rplY, encoding 5 S rRNA-binding ribosomal proteins L5, L18 and L25, respectively, for cell growth, viability and translation. Using recombineering to create gene replacements in the E. coli chromosome, it was shown that rplE and rplR are essential for cell viability, whereas cells deleted for rplY are viable, but grow noticeably slower than the parental strain. The slow growth of these L25-defective cells can be stimulated by a plasmid expressing the rplY gene and also by a plasmid bearing the gene for homologous to L25 general stress protein CTC from Bacillus subtilis. The rplY mutant ribosomes are physically normal and contain all ribosomal proteins except L25. The ribosomes from L25-defective and parental cells translate in vitro at the same rate either poly(U) or natural mRNA. The difference observed was that the mutant ribosomes synthesized less natural polypeptide, compared to wild-type ribosomes both in vivo and in vitro. We speculate that the defect is at the ribosome recycling step.