The participation of 5S rRNA in the co-translational formation of a eukaryotic 5S ribonucleoprotein complex

The eukaryotic ribosomal 5S RNA–protein complex (5S rRNP) is formed by a co-translational event that requires 5S rRNA binding to the nascent peptide chain of eukaryotic ribosomal protein L5. Binding between 5S rRNA and the nascent chain is specific: neither the 5S rRNA nor the nascent chain of L5 protein can be substituted by other RNAs or other ribosomal proteins. The region responsible for binding 5S rRNA is located at positions 35–50 with amino acid sequence RLVIQDIKNKYNTPKYRM. Eukaryotic 5S rRNA binds a nascent chain having this sequence, but such binding is not substantive enough to form a 5S-associated RNP complex, suggesting that 5S rRNA binding to the nascent chain is amino acid sequence dependent and that formation of the 5S rRNP complex is L5 protein specific. Microinjection of 5S rRNP complex into the cytoplasm of Xenopus oocytes results in both an increase in the initial rate and also in the extent of net nuclear import of L5. This suggests that the 5S rRNP complex enhances nuclear transport of L5. We propose that 5S rRNA plays a chaperone-like role in folding of the nascent chain of L5 and directs L5 into a 5S rRNP complex for nuclear entry.     

In vitro nuclear transport of ribosomal ribonucleoprotein: temperature affects quantity but not quality of exported particles.

The in vitro export of ribosomal ribonucleoprotein (rRNP) from Tetrahymena nuclei was investigated at the optimal growth temperature of 28 degrees C and at the nonlethal temperature of 8 degrees C. At both temperatures, nuclei exported ribosomal precursor particles that revealed the same physical qualities of size, appearance in negative-staining electron microscopy, sedimentation coefficient, buoyant density, and rRNA pattern. Surprisingly, fewer rRNP particles were exported at 8 than at 28 degrees C, as was revealed by a lower saturation plateau in the export kinetics from nuclei prelabeled with [3H]uridine. Upon a temperature increase from 8 to 28 degrees C, additional rRNP particles were exported. We conclude that nuclei export only a defined portion of rRNP particles at a given temperature, although enough potentially transportable rRNP particles are present in nuclei. Obviously, the reactivity of at least one of the reactants involved directly or indirectly in rRNP export changes with temperature.     

Function of eukaryotic initiation factor 5 in the formation of an 80 S ribosomal polypeptide chain initiation complex.

Eukaryotic initiation factor 5 (eIF-5), isolated from rabbit reticulocyte lysates, is a monomeric protein of 58-62 kDa. The function of eIF-5 in the formation of an 80 S polypeptide chain initiation complex from a 40 S initiation complex has been investigated. Incubation of the isolated 40 S initiation complex (40 S.AUG.Met.tRNAf.eIF-2 GTP) with eIF-5 resulted in the rapid and quantitative hydrolysis of GTP bound to the 40 S initiation complex. The rate of this reaction was unaffected by the presence of 60 S ribosomal subunits. Analysis of eIF-5-catalyzed reaction products by gel filtration indicated that both eIF-2.GDP binary complex and Pi formed were released from the ribosomal complex whereas Met-tRNAf remained bound to 40 S ribosomes as a Met-tRNAf.40 S.AUG complex. Reactions carried out with biologically active 32P-labeled eIF-5 indicated that this protein was not associated with the 40 S.AUG.Met-tRNAf complex; similar results were obtained by immunological methods using monospecific anti-eIF-5 antibodies. The isolated 40 S.AUG.Met-RNAf complex, free of eIF-2.GDP binary complex and eIF-5, readily interacted with 60 S ribosomal subunits in the absence of exogenously added eIF-5 to form the 80 S initiation complex capable of transferring Met-tRNAf into peptide linkages. These results indicate that the sole function of eIF-5 in the initiation of protein synthesis is to mediate hydrolysis of GTP bound to the 40 S initiation complex in the absence of 60 S ribosomal subunits. This leads to formation of the intermediate 40 S.AUG.Met-tRNAf and dissociation of the eIF-2.GDP binary complex. Subsequent joining of 60 S ribosomal subunits to the intermediate 40 S.AUG.Met-tRNAf complex does not require participation of eIF-5. Thus, the formation of an 80 S ribosomal polypeptide chain initiation complex from a 40 S ribosomal initiation complex can be summarized by the following sequence of partial reactions. (40 S.AUG.Met-tRNAf.eIF-2.GTP) eIF-5----(40 S.AUG.Met-tRNAf) + (eIF-2.GDP) + Pi (1) (40 S.AUG.Met-tRNAf) + 60 S----(80 S.AUG.Met-tRNAf) (2) 80 S initiation complex.     

In vitro ribosomal ribonucleoprotein transport. Temperature-induced "graded unlocking" of nuclei

We examine the effect of temperature on the export of ribosomal precursor particles from nuclei isolated from Tetrahymena. A new phenomenon is observed. Temperature does affect not only the export rate, but also the maximal portion of particles exported. At 8 degrees C, for example, the export kinetics reveals a significantly lower saturation plateau which does not equilibrate with the higher plateau at 28 degrees C even after 3 h. This nonequilibration is not due to (i) a different physical quality of the exported particles, (ii) a degradation of the nuclear rRNA, (iii) a backward import of exported particles into nuclei, (iv) an irreversible inactivation of potentially transportable nuclear ribosomal ribonucleoprotein (rRNP) particles, or (v) a thermodynamic equilibrium between transportable rRNP particles associated with nuclei and those exported from nuclei. We conclude, therefore, that potentially transportable rRNP particles are somehow "locked" in nuclei at low temperature and temperature raising induces a "graded unlocking."     

Identification of ribosomal protein autoantigens

Approximately 20% of patients with systemic lupus erythematosus and with anti-Sm autoantibodies synthesize autoantibodies, called anti-rRNP, to components of the ribosome. We found that anti-rRNP sera reacted predominantly with three ribosomal phosphoproteins of approximate Mr = 38,000, 16,000 and 15,000, both by immunoprecipitation and by immunoblotting. The human autoantibodies cross-reacted with similar antigens present in rodent, brine shrimp, and yeast cells but reacted weakly if at all with proteins of bacteria. Thus the human autoantibodies recognize epitopes that are widely conserved in evolution. Purified ribosomal proteins together with specific rabbit antisera were used to identify the two smaller rRNP antigens as the acidic phosphoproteins of the large ribosomal subunit, designated P1/P2(L40/L41) (rat), eL7/eL12 (Artemia, brine shrimp), and A1/A2 (yeast). These proteins function in the elongation step of protein synthesis in an analogous fashion to the L7/L12 ribosomal proteins of E. coli. The 38,000-dalton rRNP antigen corresponds to a nonacidic protein also associated with the large ribosomal subunit. The human autoantibodies appear to have a specificity similar to that of a previously described mouse monoclonal antibody obtained from mice injected with heterologous (chick) ribosomes, suggesting that both the human polyclonal autoantibodies and the mouse monoclonal recognize a class of epitope(s) that is common in all three ribosomal proteins. In addition, we found that many of the anti-ribosomal sera contained a further class of autoantibodies reactive with naked RNA. These may be similar to the anti-RNA antibodies previously described in both humans and mice with autoimmune disease.     

Formation and release of eukaryotic initiation factor 2 X GDP complex during eukaryotic ribosomal polypeptide chain initiation complex formation

The formation and release of an eukaryotic initiation factor (eIF)-2 X GDP binary complex during eIF-5-mediated assembly of an 80 S ribosomal polypeptide chain initiation complex have been studied by sucrose gradient centrifugation analysis. Isolated 40 S initiation complex reacts with eIF-5 and 60 S ribosomal subunits to form an 80 S ribosomal initiation complex with concomitant hydrolysis of an equimolar amount of bound GTP to GDP and Pi. Sucrose gradient analysis of reaction products revealed that GDP was released from ribosomes as an eIF-2 X GDP complex. Evidence is presented that eIF-5-mediated hydrolysis releases the GTP bound to the 40 S initiation complex as an intact eIF-2 X GDP complex rather than as free GDP and eIF-2 which subsequently recombine to form the binary complex. Furthermore, formation and release of eIF-2 X GDP from the ribosomal complex do not require concomitant formation of an 80 S initiation complex since both reactions occur efficiently when the 40 S initiation complex reacts with eIF-5 in the absence of 60 S ribosomal subunits. These results, along with the observation that the 40 S initiation complex formed with the nonhydrolyzable analogue of GTP, 5'-guanylylmethylene diphosphonate, can neither join a 60 S ribosomal subunit nor releases ribosome-bound eIF-2, suggest that following eIF-5-mediated hydrolysis of GTP bound to the 40 S initiation complex, both Pi and eIF-2 X GDP complex are released from ribosomes prior to the joining of 60 S ribosomal subunits to the 40 S initiation complex.     

In vitro assembly of yeast 5S rRNA and a fusion protein containing ribosomal protein L5 and maltose binding protein

Binding of yeast ribosomal protein L5 with 5S rRNA has long been considered a promising model for studying molecular mechanisms of protein-RNA interactions. However, in vitro assembly of a ribonucleoprotein (RNP) complex from purified yeast ribosomal protein L5 (also known as L1, L1a, or YL3) and 5S rRNA proved to be difficult, thus limiting the utility of this model. In the present report, we present data on the successful in vitro assembly of a RNP complex using a fusion (MBP-L5) protein consisting of the yeast ribosomal protein L5 fused to the carboxyl terminus of the E. coli maltose-binding protein (MBP). We demonstrated that: 1) the MBP-L5 protein binds yeast 5S rRNA but not 5.8S rRNA in vitro; 2) the MBP protein itself does not bind yeast 5S rRNA; 3) formation of the RNP complex is proportional to the concentration of MBP-L5 protein and 5S rRNA; and 4) the MBP moiety of the fusion protein in the RNP complex can be removed with factor Xa. The electrophoretic mobility of the resultant RNP complex is indistinguishable from that of L5-5S rRNA complex isolated from the ribosome. Using this new experimental approach, we further showed that the RNA binding capability of a mutant L5 protein is decreased by 60% compared to the wild-type protein. Additionally, the mutant RNP complex migrates slower than the wild-type RNP complex suggesting that the mutant RNP complex has a less compact conformation. The finding provides a probable explanation for an earlier observation that the 60S ribosomal subunit containing the mutant protein is unstable.     

Conserved 5S and variable 45S rDNA chromosomal localisation revealed by FISH in <Emphasis Type="Italic">Astyanax scabripinnis</Emphasis> (Pisces,Characidae)

Fluorescence in situhybridisation (FISH) and double FISH experiments were carried out to ascertain the chromosomal distribution pattern of the 45S and 5S ribosomal (r) DNAs in four populations of the characid fish Astyanax scabripinnis – a group considered to be a species complex for its wide karyotypical and morphological diversity. The results regarding the 45S rDNA agreed with this hypothesis, since these sites showed intra- and inter-populational, numerical and positional variations. However, the data obtained with the 5S rDNA probe revealed a highly conserved chromosomal distribution pattern of these sequences among individuals of each population, as well as among the populations analysed. We consider this contrasting situation as a functional divergence between 45S and 5S ribosomal DNAs, which may reflect the localisation of these sequences in distinct nuclear compartments, leading them to undergo differentiated evolutionary processes.     

Release and recycling of eukaryotic initiation factor 2 in the formation of an 80 S ribosomal polypeptide chain initiation complex.

The eukaryotic initiation factor (eIF)-5 mediates hydrolysis of GTP bound to the 40 S initiation complex in the absence of 60 S ribosomal subunits. The eIF-2.GDP formed under these conditions is released from the 40 S ribosomal subunit while initiator Met-tRNA(f) remains bound. The released eIF-2.GDP can participate in an eIF-2B-catalyzed GDP/GTP exchange reaction to reform the Met-tRNA(f).eIF-2.GTP ternary complex. In contrast, when 60 S ribosomal subunits were also present in an eIF-5-catalyzed reaction, the eIF-2.GDP produced remained bound to the 60 S ribosomal subunit of the 80 S initiation complex. When such an 80 S initiation complex, containing bound eIF-2.GDP, was incubated with GTP and eIF-2B, GDP was released. However, eIF-2 still remained bound to the ribosomes and was unable to form a Met-tRNA(f)l.eIF-2.GTP ternary complex. In contrast, when 60 S ribosomal subunits were preincubated with either free eIF-2 or with eIF-2.eIF-2B complex and then added to a reaction containing both the 40 S initiation complex and eIF-5, the eIF-2.GDP produced did not bind to the 60 S ribosomal subunits but was released from the ribosomes. Thus, the 80 S initiation complex formed under these conditions did not contain bound eIF-2.GDP. Under similar experimental conditions, preincubation of 60 S ribosomal subunits with purified eIF-2B (free of eIF-2) failed to cause release of eIF-2.GDP from the ribosomal initiation complex. These results suggest that 60 S ribosome-bound eIF-2.GDP does not act as a direct substrate for eIF-2B-mediated release of eIF-2 from ribosomes. Rather, the affinity of 60 S ribosomal subunits for either eIF-2, or the eIF-2 moiety of the eIF-2.eIF-2B complex, prevents association of 60 S ribosomal subunits with eIF-2.GDP formed in the initiation reaction. This ensures release of eIF-2 from ribosomes following hydrolysis of GTP bound to the 40 S initiation complex.     

A rice (Oryza sativa L.) cDNA encodes a protein sequence homologous to the eukaryotic ribosomal 5S RNA-binding protein

A rice (Oryza sativa L.) cDNA clone coding for the cytoplasmic ribosomal protein L5, which associates with 5 S rRNA for ribosome assembly, was cloned and its nucleotide sequence was determined. The primary structure of rice L5, deduced from the nucleotide sequence, contains 294 amino acids and has intriguing features some of which are also conserved in other eucaryotic homologues. These include: four clusters of basic amino acids, one of which may serve as a nucleolar localization signal; three repeated amino acid sequences; the conservation of glycine residues. This protein was identified as the nuclear-encoded cytoplasmic ribosomal protein L5 of rice by sequence similarity to other eucaryotic ribosomal 5 S RNA-binding proteins of rat, chicken, Xenopus laevis, and Saccharomyces cerevisiae. Rice L5 shares 51 to 62% amino acid sequence identity with the homologues. A group of ribosomal proteins from archaebacteria including Methanococcus vanniellii L18 and Halobacterium cutirubrum L13, which are known to be associated with 5 S rRNA, also related to rice L5 and the other eucaryotic counterparts, suggesting an evolutionary relationship in these ribosomal 5 S RNA-binding proteins.     

Characterization of hibernating ribosomes in mammalian cells

Protein synthesis across kingdoms involves the assembly of 70S (prokaryotes) or 80S (eukaryotes) ribosomes on the mRNAs to be translated. 70S ribosomes are protected from degradation in bacteria during stationary growth or stress conditions by forming dimers that migrate in polysome profiles as 100S complexes. Formation of ribosome dimers in Escherichia coli is mediated by proteins, namely the ribosome modulation factor (RMF), which is induced in the stationary phase of cell growth. It is reported here a similar ribosomal complex of 110S in eukaryotic cells, which forms during nutrient starvation. The dynamic nature of the 110S ribosomal complex (mammalian equivalent of the bacterial 100S) was supported by the rapid conversion into polysomes upon nutrient-refeeding via a mechanism sensitive to inhibitors of translation initiation. Several experiments were used to show that the 110S complex is a dimer of nontranslating ribosomes. Cryo-electron microscopy visualization of the 110S complex revealed that two 80S ribosomes are connected by a flexible, albeit localized, interaction. We conclude that, similarly to bacteria, rat cells contain stress-induced ribosomal dimers. The identification of ribosomal dimers in rat cells will bring new insights in our thinking of the ribosome structure and its function during the cellular response to stress conditions.     

Chromosomal location and reorganization of the 45S and 5S rDNA in theBrachyscome lineariloba complex (Asteraceae)

The chromosomal locations of the 45S (18S-5.8S-26S) and 5S ribosomal DNA in theBrachyscome lineariloba complex and two related species have been determined by the use of multicolor fluorescencein situ hybridization (McFISH). TheBrachyscome lineariloba complex includes five cytodemes with 2n=4, 8, 10, 12 and 16. Each of the 5S and 45S rDNA loci occurs at two sites on chromosomes in cytodemes with 2n=4. While in cytodemes with 2n=8, 10, 12 and 16, the number of 5S rDNA sites increases from four to eight paralleled to the genomic addition of diploid (4 chromosomes) or haploid (2 chromosomes) dosage. Of the 5S rDNA sites, only one pair is major, except for the cytodeme with 2n=10. The remaining 5S rDNA sites are minor and seem to have reduced the unit number of the 5S rDNA during the successive genomic additions. The 45S rDNA site is detected only at two nucleolar organizing regions in all cytodemes regardless of successive genomic addition. The loss or diminution of 45S rDNA sequences seem to have proceeded more rapidly than 5S rDNA sequences in theB. lineariloba complex.     

Isolation, Crystallization, and Investigation of Ribosomal Protein S8 Complexed with Specific Fragments of rRNA of Bacterial or Archaeal Origin

The core ribosomal protein S8 binds to the central domain of 16S rRNA independently of other ribosomal proteins and is required for assembling the 30S subunit. It has been shown with E. coli ribosomes that a short rRNA fragment restricted by nucleotides 588-602 and 636-651 is sufficient for strong and specific protein S8 binding. In this work, we studied the complexes formed by ribosomal protein S8 from Thermus thermophilus and Methanococcus jannaschii with short rRNA fragments isolated from the same organisms. The dissociation constants of the complexes of protein S8 with rRNA fragments were determined. Based on the results of binding experiments, rRNA fragments of different length were designed and synthesized in preparative amounts in vitro using T7 RNA-polymerase. Stable S8–RNA complexes were crystallized. Crystals were obtained both for homologous bacterial and archaeal complexes and for hybrid complexes of archaeal protein with bacterial rRNA. Crystals of the complex of protein S8 from M. jannaschii with the 37-nucleotide rRNA fragment from the same organism suitable for X-ray analysis were obtained.     

AN INTERGENERIC HYBRID IN THE SAXIFRAGACEAE: EVIDENCE FROM RIBOSOMAL RNA GENES

The tandemly repeated multigene families encoding the 5S and 18S-25S ribosomal RNAs were studied at the restriction enzyme level in Tolmiea menziesii, Tellima grandiflora, and in a putative intergeneric hybrid. Using restriction endonucleases that cut once per repeat, the repeat lengths of the 5S and 18S-25S ribosomal genes were estimated. The 5S ribosomal gene repeat length is approximately 480 and 450 base pairs, respectively, in Tolmiea and Tellima. The repeat length of the 18S-25S ribosomal genes varied from 11–13 kb in Tolmiea, and was only about 9 kb in Tellima. The putative hybrid combined the repeat lengths of both Tolmiea and Tellima for both the 5S and the 18S-25S ribosomal genes. These data substantiate the occurrence of natural hybridization between Tolmiea and Tellima. For both the 5S and 18S-25S gene experiments, the hybrid appears to contain fewer repeats corresponding to Tolmiea than to Tellima.     

Molecular interactions of ribosomal components

Summary Five of the 30S ribosomal proteins from E. coli were tested for their ability to bind to 16S ribosomal RNA. Only one of these, S15, can form a complex with the RNA. Quantitative measurements as well as competition experiments show that the RNA binding site for the attachment of S15 is specific for this protein.These experiments complete our analysis of all 21 of the 30S ribosomal proteins. Five of these have now been shown to form a site-specific complex with 16S RNA. These are S4, S7, S8, S15 and S20. The relationship of these data to the assembly and structure of the ribosome are discussed.     

Cold-sensitive growth of a mutant of Escherichia coli with an altered ribosomal protein S8: analysis of revertants.

Summary 26 cold-resistant revertants of a cold-sensitiveEscherichia coli mutant with an altered ribosomal protein S8 were analyzed for their ribosomal protein pattern by two-dimensional polyacrylamide gel electrophoresis. It was found that 16 of them had acquired the apparent wild-type form of protein S8, one exhibits a more strongly altered S8 than the original mutant and two revertants regained the wild-type form of S8 and, in addition, possess alterations in protein L30. The ribosomes of the residual revertants showed no detectable difference from those of the parental S8 mutant.The mutation leading to the more strongly altered S8 was genetically not separable from the primary S8 mutation; this indicates that both mutations are very close to each other or at the same site. The structural gene for ribosomal protein L30 was mapped relative to two other ribosomal protein genes (for proteins S5 and S8) by the aid of one of the L30 mutants: The relative order obtained is:aroE....rpmD(L30)....rpsE(S5)....rpsH(S8)....THe L30 mutation impairs growth and ribosomal assembly at 20°C and is therefore the first example of a mutant with a defined 50S alteration that has (partial) cold-sensitive ribosome assembly. A double mutant was constructed which possesses both the S8 and the L30 mutations. It was found that the L30 mutation had a slight antagonistic effect on the growth inhibition caused by the S8 mutation. Thus the L30 mutants might have possibly arisen from the original S8 mutants first as S8/L30 double mutants which was followed by the loss of the original S8 lesion.     

Binding of erythromycin to the 50S ribosomal subunit is affected by alterations in the 30S ribosomal subunit

Summary Expression of resistance to erythromycin in Escherichia coli, caused by an altered L4 protein in the 50S ribosomal subunit, can be masked when two additional ribosomal mutations affecting the 30S proteins S5 and S12 are introduced into the strain (Saltzman, Brown, and Apirion, 1974). Ribosomes from such strains bind erythromycin to the same extent as ribosomes from erythromycin sensitive parental strains (Apirion and Saltzman, 1974).Among mutants isolated for the reappearance of erythromycin resistance, kasugamycin resistant mutants were found. One such mutant was analysed and found to be due to undermethylation of the rRNA. The ribosomes of this strain do not bind erythromycin, thus there is a complete correlation between phenotype of cells with respect to erythromycin resistance and binding of erythromycin to ribosomes.Furthermore, by separating the ribosomal subunits we showed that 50S ribosomes bind or do not bind erythromycin according to their L4 protein; 50S with normal L4 bind and 50S with altered L4 do not bind erythromycin. However, the 30s ribosomes with altered S5 and S12 can restore binding in resistant 50S ribosomes while the 30S ribosomes in which the rRNA also became undermethylated did not allow erythromycin binding to occur.Thus, evidence for an intimate functional relationship between 30S and 50S ribosomal elements in the function of the ribosome could be demonstrated. These functional interrelationships concerns four ribosomal components, two proteins from the 30S ribosomal subunit, S5, and S12, one protein from the 50S subunit L4, and 16S rRNA.