Structural and functional analyses of a yeast mitochondrial ribosomal protein homologous to ribosomal protein S15 of Escherichia coli.

We have purified a small subunit mitochondrial ribosomal protein, MRPS28p, from the yeast, Saccharomyces cerevisiae. Sequence from the amino terminus of MRPS28p was used to design a degenerate oligonucleotide that was complementary to the MRPS28 gene. The MRPS28 gene was isolated and its sequence determined. The MRPS28 sequence encodes a 28 kDa protein that has a region of homology with ribosomal protein S15 of E. coli. This region spans the entire length of the E. coli protein, but as MRPS28p is larger, includes only the portion of the MRPS28p sequence from amino acids 150 to 238. Based on this homology, we predict that MRPS28p, like E. coli S15, interacts directly with small subunit rRNA and functions as an early protein in ribosome assembly. Cells carrying a disrupted chromosomal copy of MRPS28 are unable to respire and spontaneously lose portions of their mitochondrial genomes at a high frequency. These phenotypes are consistent with an essential role for MRPS28p in the assembly and/or function of the mitochondrial ribosome.     

Site-specific AT-cluster insertions in the mitochondrial 15S rRNA gene of the yeast S. cerevisiae.

By comparing the mitochondrial 15S rRNA sequences of four wildtype yeast strains together with their respective secondary structures, with those of the 16S-like ribosomal RNA from other organisms we detected two optional and two invariant AT-clusters. The origin of these clusters is discussed with respect to their roles as possible mobile elements.     

rig encodes ribosomal protein S15. The primary structure of mammalian ribosomal protein S15

rig, a gene originally isolated from a rat insulinoma cDNA library, codes for a basic 145 amino acid protein [( 1986) Diabetes 35, 1178-1180]. Here we show that the immunoreactivity to a monoclonal antibody against the deduced rig protein and the translation product of rig mRNA comigrated with ribosomal protein S15. The amino acid sequence of ribosomal protein S15 purified from rat liver coincided with that deduced from the nucleotide sequence of rig mRNA, but there were indications that the initiator methionine was removed and the succeeding alanyl residue was monoacetylated. From these results, we conclude that the product of rig is ribosomal protein S15.     

Assembly of 60S ribosomal subunits is perturbed in temperature-sensitive yeast mutants defective in ribosomal protein L16.

Temperature-sensitive mutants defective in 60S ribosomal subunit protein L16 of Saccharomyces cerevisiae were isolated through hydroxylamine mutagenesis of the RPL16B gene and plasmid shuffling. Two heat-sensitive and two cold-sensitive isolates were characterized. The growth of the four mutants is inhibited at their restrictive temperatures. However, many of the cells remain viable if returned to their permissive temperatures. All of the mutants are deficient in 60S ribosomal subunits and therefore accumulate translational preinitiation complexes. Three of the mutants exhibit a shortage of mature 25S rRNA, and one accumulates rRNA precursors. The accumulation of rRNA precursors suggests that ribosome assembly may be slowed in this mutant. These phenotypes lead us to propose that mutants containing the rpl16b alleles are defective for 60S subunit assembly rather than function. In the mutant carrying the rpl16b-1 allele, ribosomes initiate translation at the noncanonical codon AUA, at least on the rpl16b-1 mRNA, bringing to light a possible connection between the rate and the fidelity of translation initiation.     

The amino acid sequence of the ribosomal protein S8 of Escherichia coli.

The primary structure of protein S8 from the 30S subunit of Escherichia coli ribosomes has been determined by sequencing the peptides derived from tryptic, chymotryptic, thermolytic and staphylococcal protease digestion of the protein. Protein S8 has 129 amino acid residues which result in a molecular weight of 13996. The N-terminal part of the sequence up to position 68 is in complete agreement with the reported sequence data[1,2]. However, differences exist in the C-terminal half, where an additional hydrophobic tryptic peptide has been found.     

Mutation of a highly conserved base in the yeast mitochondrial 21S rRNA restricts ribosomal frameshifting

A mutation shown to cause resistance to chloramphenicol inSaccharomyces cerevisiae was mapped to the central loop in domain V of the yeast mitochondrial 21S rRNA. The mutant 21S rRNA has a base pair exchange from U₂₆₇₇ (corresponding to U₂₅₀₄ inEscherichia coli) to C₂₆₇₇, which significantly reduces rightward frameshifting at a UU UUU UCC A site in a + 1 U mutant. There is evidence to suggest that this reduction also applies to leftward frameshifting at the same site in a – 1 U mutant. The mutation did not increase the rate of misreading of a number of mitochondrial missense, nonsense or frameshift (of both signs) mutations, and did not adversely affect the synthesis of wild-type mitochondrial gene products. It is suggested here that ribosomes bearing either the C₂₆₇₇ mutation or its wild-type allele may behave identically during normal decoding and only differ at sites where a ribosomal stall, by permitting non-standard decoding, differentially affects the normal interaction of tRNAs with the chloramphenicol resistant domain V. Chloramphenicol-resistant mutations mapping at two other sites in domain V are described. These mutations had no effect on frameshifting.     

Identification of highly conserved hydrophobic amino acid motif in deduced amino acid sequence of Elymus sibiricus L. mitochondrial S13 ribosomal protein

The nucleotide sequence of mitochondrial ribosomal protein rps13 gene from wild perennial grass Elymus sibiricus is presented. It was determined by the method of PCR amplification with specific oligonucleotide primers and the direct sequencing of the amplification product. The sequence of E. sibiricus mitochondrial gene for S13 predicts a hydrophobic ribosomal protein of 116 amino acids that shows strong similarity to those of wheat (99.7% identity) and maize (98%). The deduced amino acid sequence of S13 protein from E. sibiricus and homologous plant's (Zea mays, Daucus carota, Nicotiana tabacum, Marchantia polymorpha) and nonplant's (Escherichia coli) proteins shows the presence of hydrophobic amino acids' motif -L-X10-L-X10-M-X10-L-X10-L-. Slightly modified it can be found in many other ribosomal proteins. This conserved motif is presumed to be particularly important for association of the ribosomal S13 protein with other proteins in the small subunit of the mitochondrial ribosome.     

Dissection of the 16S rRNA binding site for ribosomal protein S4

The ribosomal protein S4 from Escherichia coli is essential for initiation of assembly of 30S ribosomal subunits. We have undertaken the identification of specific features required in the 16S rRNA for S4 recognition by synthesizing mutants bearing deletions within a 460 nucleotide region which contains the minimum S4 binding site. We made a set of large nested deletions in a subdomain of the molecule, as well as individual deletions of nine hairpins, and used a nitrocellulose filter binding assay to calculate association constants. Some small hairpins can be eliminated with only minor effects on S4 recognition, while three hairpins scattered throughout the domain (76-90, 376-389 and 456-476) are essential for specific interaction. The loop sequence of hairpin 456-476 is important for S4 binding, and may be directly recognized by the protein. Some of the essential features are in phylogenetically variable regions; consistent with this, Mycoplasma capricolum rRNA is only weakly recognized by S4, and no specific binding to Xenopus laevis rRNA can be detected.     

Role of N-terminal helix in interaction of ribosomal protein S15 with 16S rRNA

The position and conformation of the N-terminal helix of free ribosomal protein S15 was earlier found to be modified under various conditions. This variability was supposed to provide the recognition by the protein of its specific site on 16S rRNA. To test this hypothesis, we substituted some amino acid residues in this helix and assessed effects of these substitutions on the affinity of the protein for 16S rRNA. The crystal structure of the complex of one of these mutants (Thr3Cys S15) with the 16S rRNA fragment was determined, and a computer model of the complex containing another mutant (Gln8Met S15) was designed. The available and new information was analyzed in detail, and the N-terminal helix was concluded to play no significant role in the specific binding of the S15 protein to its target on 16S rRNA.     

The 23 S rRNA environment of ribosomal protein L9 in the 50 S ribosomal subunit

Ribosomal protein L9 consists of two globular alpha/beta domains separated by a nine-turn alpha-helix. We examined the rRNA environment of L9 by chemical footprinting and directed hydroxyl radical probing. We reconstituted L9, or individual domains of L9, with L9-deficient 50 S subunits, or with deproteinized 23 S rRNA. A footprint was identified in domain V of 23 S rRNA that was mainly attributable to N-domain binding. Fe(II) was tethered to L9 via cysteine residues introduced at positions along the alpha-helix and in the C-domain, and derivatized proteins were reconstituted with L9-deficient subunits. Directed hydroxyl radical probing targeted regions of domains I, III, IV, and V of 23 S rRNA, reinforcing the view that 50 S subunit architecture is typified by interwoven rRNA domains. There was a striking correlation between the cleavage patterns from the Fe(II) probes attached to the alpha-helix and their predicted orientations, constraining both the position and orientation of L9, as well as the arrangement of specific elements of 23 S rRNA, in the 50 S subunit.     

Role of conserved nucleotides in building the 16 S rRNA binding site for ribosomal protein S15

Ribosomal protein S15 recognizes a highly conserved target on 16 S rRNA, which consists of two distinct binding regions. Here, we used extensive site-directed mutagenesis on a Escherichia coli 16 S rRNA fragment containing the S15 binding site, to investigate the role of conserved nucleotides in protein recognition and to evaluate the relative contribution of the two sites. The effect of mutations on S15 recognition was studied by measuring the relative binding affinity, RNA probing and footprinting. The crystallographic structure of the Thermus thermophilus complex allowed molecular modelling of the E. coli complex and facilitated interpretation of biochemical data. Binding is essentially driven by site 1, which includes a three-way junction constrained by a conserved base triple and cross-strand stacking. Recognition is based mainly on shape complementarity, and the role of conserved nucleotides is to maintain a unique backbone geometry. The wild-type base triple is absolutely required for protein interaction, while changes in the conserved surrounding nucleotides are partially tolerated. Site 2, which provides functional groups in a conserved G-U/G-C motif, contributes only modestly to the stability of the interaction. Binding to this motif is dependent on binding at site 1 and is allowed only if the two sites are in the correct relative orientation. Non-conserved bulged nucleotides as well as a conserved purine interior loop, although not directly involved in recognition, are used to provide an appropriate flexibility between the two sites. In addition, correct binding at the two sites triggers conformational adjustments in the purine interior loop and in a distal region, which are known to be involved for subsequent binding of proteins S6 and S18. Thus, the role of site 1 is to anchor S15 to the rRNA, while binding at site 2 is aimed to induce a cascade of events required for subunit assembly.     

The complete amino acid sequence of ribosomal protein S8 fromThermus thermophilus

Protein S8 fromThermus thermophilus consists of 138 amino acids ofM, 15,840. Its primary structure was established using peptide sequences from two different digests. Protein S8 fromT. thermophilus shares a high percentage of identity with protein S8 fromThermus aquaticus. There are some consensus sequences between proteins S8 from eubacteria, archebacteria, chloroplasts, and cyanelles.     

Recognition of 16S rRNA by ribosomal protein S4 from Bacillus stearothermophilus

Protein S4 is essential for bacterial small ribosomal subunit assembly and recognizes the 5' domain (approximately 500 nt) of small subunit rRNA. This study characterizes the thermodynamics of forming the S4-5' domain rRNA complex from a thermophile, Bacillus stearothermophilus, and points out unexpected differences from the homologous Escherichia coli complex. Upon incubation of the protein and RNA at temperatures between 35 and 50 degrees C under ribosome reconstitution conditions [350 mM KCl, 8 mM MgCl2, and 30 mM Tris (pH 7.5)], a complex with an association constant of > or = 10(9) M(-1) was observed, more than an order of magnitude tighter than previously found for the homologous E. coli complex under similar conditions. This high-affinity complex was shown to be stoichiometric, in equilibrium, and formed at rates on the order of magnitude expected for diffusion-controlled reactions ( approximately 10(7) M(-1) x s(-1)), though at low temperatures the complex became kinetically trapped. Heterologous binding experiments with E. coli S4 and 5' domain RNA suggest that it is the B. stearothermophilus S4, not the rRNA, that is activated by higher temperatures; the E. coli S4 is able to bind 5' domain rRNA equally well at 0 and 37 degrees C. Tight complex formation requires a low Mg ion concentration (1-2 mM) and is very sensitive to KCl concentration [- partial differential[log(K)]/partial differential(log[KCl]) = 9.3]. The protein has an unusually strong nonspecific binding affinity of 3-5 x 10(6) M(-1), detected as a binding of one or two additional proteins to the target 5' domain RNA or two to three proteins binding a noncognate 23S rRNA fragment of the approximately same size. This binding is not as sensitive to monovalent ion concentration [- partial differential[log(K)]/partial differential(log[KCl]) = 6.3] as specific binding and does not require Mg ion. These findings are consistent with S4 stabilizing a compact form of the rRNA 5' domain.     

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.     

Specific ribosomal RNA recognition by a fragment of E. coli ribosomal protein S4 missing the C-terminal 36 amino acid residues.

We have previously investigated the role of the N-terminal region of ribosomal protein S4 to participate in 30S ribosome assembly and function (1-3). In this report we extend these studies to the two fragments produced by the chemical cleavage of protein S4 at the tryptophan residue 167. We find that the carboxyl terminal fragment (168-203) does not bind 16S RNA nor does it participate in assembly with the other 20 proteins from the 30S ribosome. In contrast, the larger fragment (1-167), does bind 16S RNA specifically. If the S4-fragment (1-167) is used to replace protein S4 in the complete 30S assembly reaction, all 20 of the other 30S proteins are incorporated. We conclude that the carboxyl terminal section of the protein S4 is not directly involved in binding 16S RNA or in the assembly of any of the other 30S proteins.     

The 16S rRNA binding site of Thermus thermophilus ribosomal protein S15: comparison with Escherichia coli S15, minimum site and structure.

Binding of Escherichia coli and Thermus thermophilus ribosomal proteins S15 to a 16S ribosomal RNA fragment from T. thermophilus (nt 559-753) has been investigated in detail by extensive deletion analysis, filter-binding assays, gel mobility shift, structure probing, footprinting with chemical, enzymatic, and hydroxyl radical probes. Both S15 proteins recognize two distinct sites. The first one maps in the bottom of helix 638-655/717-734 (H22) and in the three-way junction between helix 560-570/737-747 (H20), helix 571-600/606-634 (H21), and H22. The second is located in a conserved purine-rich region in the center of H22. The first site provides a higher contribution to the free energy of binding than the second one, and both are required for efficient binding. A short RNA fragment of 56 nt containing these elements binds S15 with high affinity. The structure of the rRNA is constrained by the three-way junction and requires both magnesium and S15 to be stabilized. A 3D model, derived by computer modeling with the use of experimental data, suggests that the bound form adopts a Y-shaped conformation, with a quasi-coaxial stacking of H22 on H20, and H21 forming an acute angle with H22. In this model, S15 binds to the shallow groove of the RNA on the exterior side of the Y-shaped structure, making contact with the two sites, which are separated by one helix turn.     

The structure of the yeast ribosomal RNA genes. 4. Complete sequence of the 25 S rRNA gene from Saccharomyces cerevisae.

The complete nucleotide sequence of the 25 S rRNA gene from one rDNA repeating unit of Saccharomyces cerevisiae has been determined. The corresponding 25 S rRNA molecule contains 3392 nucleotides and has an estimated relative molecular mass (Mr, Na-salt) or 1.17 x 10(6). Striking sequence homology is observed with known 5'- and 3'-end terminal segments of L-rRNA from other eukaryotes. Possible models of interaction with 5.8 S rRNA are discussed.