Developmental expression and 5S rRNA-binding activity of Xenopus laevis ribosomal protein L5.

Ribosomal protein L5 binds specifically to 5S rRNA to form a complex that is a precursor to 60S subunit assembly in vivo. Analyses in yeast cells, mammalian cells, and Xenopus embryos have shown that the accumulation of L5 is not coordinated with the expression of other ribosomal proteins. In this study, the primary structure and developmental expression of Xenopus ribosomal protein L5 were examined to determine the basis for its distinct regulation. These analyses showed that L5 expression could either coincide with 5S rRNA synthesis and ribosome assembly or be controlled independently of these events at different stages of Xenopus development. L5 synthesis during oogenesis was uncoupled from the accumulation of 5S rRNa but coincided with subunit assembly. In early embryos, the inefficient translation of L5 mRNA resulted in the accumulation of a stable L5-5S rRNA complex before ribosome assembly at later stages of development. Additional results demonstrated that L5 protein synthesized in vitro bound specifically to 5S rRNA.     

A second-site mutation at glutamate-257 that restores the function of the mutant yeast ribosomal protein L5 containing lysine-270,271-->arginine

A genetic approach was used to identify interacting regions of yeast ribosomal protein L5 (also known as L1, L1a, or YL3). Previous studies from our laboratory showed that residues K270 and K271 in protein L5 are essential for its function. The mutant L5 protein in which both residues were replaced by arginine residues (K270,271R) exhibited about 80% RNA binding capability compared to the wild-type and the mutant protein was assembled into the 60S ribosomal subunits in vivo. The yeast strain expressing this mutant protein in a homozygous form was lethal (Biochim. Biophys. Acta 1308 (1996) 133-141). In the present study, this non-functional mutant was used to select intragenic suppressors. A spontaneous, intragenic suppressor which contained an E257K substitution (in addition to the primary mutations) was identified. The suppressor protein bound about 60% of yeast 5S rRNA in vitro compared to the wild-type. To gain more insight into the nature of the intragenic suppressor, additional mutant proteins in which E257 was substituted by a variety of amino acids were produced by site-directed mutagenesis. The ability of each mutant protein to bind yeast 5S rRNA in vitro and to suppress the lethal effect of the double K270,271 mutation in vivo were examined. Results suggest communication between two non-contiguous domains on protein L5 and that several factors, such as electrostatic interaction and hydrogen bonding are likely to play a role in this global communication. Mutation studies on E257 alone also reveal that substitutions of this residue in L5 protein could affect cell growth under specified conditions, but a variety of changes could be tolerated without serious deleterious effects. We propose a working model in which E257 is located in a loop and the dynamic as well as the flexibility of this loop is important for L5 function.     

A 5S rRNA/L5 complex is a precursor to ribosome assembly in mammalian cells

A novel 5S RNA-protein (RNP) complex in human and mouse cells has been analyzed using patient autoantibodies. The RNP is small (approximately 7S) and contains most of the nonribosome-associated 5S RNA molecules in HeLa cells. The 5S RNA in the particle is matured at its 3' end, consistent with the results of in vivo pulse-chase experiments which indicate that this RNP represents a later step in 5S biogenesis than a previously described 5S*/La protein complex. The protein moiety of the 5S RNP has been identified as ribosomal protein L5, which is known to be released from ribosomes in a complex with 5S after various treatments of the 60S subunit. Indirect immunofluorescence indicates that the L5/5S complex is concentrated in the nucleolus. L5 may therefore play a role in delivering 5S rRNA to the nucleolus for assembly into ribosomes.     

Saccharomyces cerevisiae ribosomal protein L26 is not essential for ribosome assembly and function

Ribosomal proteins play important roles in ribosome biogenesis and function. Here, we study the evolutionarily conserved L26 in Saccharomyces cerevisiae, which assembles into pre-60S ribosomal particles in the nucle(ol)us. Yeast L26 is one of the many ribosomal proteins encoded by two functional genes. We have disrupted both genes; surprisingly, the growth of the resulting rpl26 null mutant is apparently identical to that of the isogenic wild-type strain. The absence of L26 minimally alters 60S ribosomal subunit biogenesis. Polysome analysis revealed the appearance of half-mers. Analysis of pre-rRNA processing indicated that L26 is mainly required to optimize 27S pre-rRNA maturation, without which the release of pre-60S particles from the nucle(ol)us is partially impaired. Ribosomes lacking L26 exhibit differential reactivity to dimethylsulfate in domain I of 25S/5.8S rRNAs but apparently are able to support translation in vivo with wild-type accuracy. The bacterial homologue of yeast L26, L24, is a primary rRNA binding protein required for 50S ribosomal subunit assembly in vitro and in vivo. Our results underscore potential differences between prokaryotic and eukaryotic ribosome assembly. We discuss the reasons why yeast L26 plays such an apparently nonessential role in the cell.     

Yeast 5S rRNA binding to ribosomal protein L1a alters the fluorescence of tryptophan residues lying outside the binding site.

The yeast ribosomal protein L1a contains two tryptophan residues located at positions 95 and 183. Spectrofluorometric analysis showed that the average tryptophan environment is moderately polar. Quenching studies of the yeast 5S rRNA-L1a protein complex (RNP) with acrylamide and iodide revealed tryptophan heterogeneity. The two tryptophan residues are located in the non-RNA-binding region of the L1a molecule. However, dissociation of the yeast 5S rRNA-L1a protein RNP complex to its components resulted in a decline of tryptophan fluorescence. The observation implied that the environment of the tryptophan-containing L1a regions which were not known to be involved in RNA binding was influenced by association with the 5S rRNA molecule.     

Stepwise dissociation of yeast 60S ribosomal subunits by LiCl and identification of L25 as a primary 26S rRNA binding protein

Treatment of yeast 60S ribosomal subunits with 0.5 M LiCl was found to remove all but six of the ribosomal proteins. The proteins remaining associated with the (26S + 5.8S) rRNA complex were identified as L4, L8, L10, L12, L16 and L25. These core proteins were split off sequentially in the order (L16 + L12), L10, (L4 + L8), L25 by further increasing the LiCl concentration. At 1.0 M LiCl only ribosomal protein L25 remains bound to the rRNA. Upon lowering the LiCl concentration the core proteins reassociate with the rRNA in the reverse order of their removal. The susceptibility of the ribosomal proteins to removal by LiCl corresponds quite well with their order of assembly into the 60S subunit in vivo as determined earlier [Kruiswijk et al. (1978) Biochim. Biophys. Acta 517, 378-389]. Binding studies in vitro using partially purified L25 showed that this protein binds specifically to 26S rRNA. Therefore our experiments for the first time directly identify a eukaryotic ribosomal protein capable of binding to high-molecular-mass rRNA. Binding studies in vitro using a blot technique demonstrated that core proteins L8 and L16 as well as protein L21, though not present in any of the core particles, are also capable of binding to 26S rRNA to approximately the same extent as L25. About nine additional 60S proteins appeared to interact with the 26S rRNA, though to a lesser extent.     

Functional features of the C-terminal region of yeast ribosomal protein L5

The aim of this study was to analyze the functional importance of the C-terminus of the essential yeast ribosomal protein L5 (YrpL5). Previous studies have indicated that the C-terminal region of YrpL5 forms an alpha-helix with a positively charged surface that is involved in protein-5S rRNA interaction. Formation of an YrpL5.5S rRNA complex is a prerequisite for nuclear import of YrpL5. Here we have tested the importance of the alpha-helix and the positively charged surface for YrpL5 function in Saccharomyces cerevisiae using site directed mutagenesis in combination with functional complementation. Alterations in the sequence forming the putative alpha-helix affected the functional capacity of YrpL5. However, the effect did not correlate with a decreased ability of the protein to bind to 5S rRNA as all rpL5 mutants tested were imported to the nucleus whether or not the alpha-helix or the positively charged surface were intact. The alterations introduced in the C-terminal sequence affected the growth rate of cells expressing mutant but functional forms of YrpL5. The reduced growth rate was correlated with a reduced ribosomal content per cell indicating that the alterations introduced in the C-terminus interfered with ribosome assembly.     

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.     

Synergistic defect in 60S ribosomal subunit assembly caused by a mutation of Rrs1p, a ribosomal protein L11-binding protein, and 3'-extension of 5S rRNA in Saccharomyces cerevisiae

Rrs1p, a ribosomal protein L11-binding protein, has an essential role in biogenesis of 60S ribosomal subunits. We obtained conditionally synthetic lethal allele with the rrs1-5 mutation and determined that the mutation is in REX1, which encodes an exonuclease. The highly conserved leucine at 305 was substituted with tryptophan in rex1-1. The rex1-1 allele resulted in 3′-extended 5S rRNA. Polysome analysis revealed that rex1-1 and rrs1-5 caused a synergistic defect in the assembly of 60S ribosomal subunits. In vivo and in vitro binding assays indicate that Rrs1p interacts with the ribosomal protein L5–5S rRNA complex. The rrs1-5 mutation weakens the interaction between Rrs1p with both L5 and L11. These data suggest that the assembly of L5–5S rRNA on 60S ribosomal subunits coordinates with assembly of L11 via Rrs1p.     

A Role for Ribosomal Protein L5 in the Nuclear Import of 5S rRNA inXenopusOocytes

Prior to ribosome assembly, 5S ribosomal RNA (5S rRNA) binds to ribosomal protein L5 to form a stable ribonucleoprotein particle (5S RNP). We have analyzed the role of L5 binding in the nuclear targeting of 5S rRNA inXenopusoocytes, and have compared the nuclear import pathway of 5S RNPs with other karyophilic molecules. Nuclear import ofin vitro-generated 5S RNPs was found to be sensitive to three general inhibitors of nuclear pore complex-mediated translocation: ATP depletion, chilling, and wheat germ agglutinin. The initial rate and extent of net nuclear import was threefold greater with preassembled 5S RNPs than with 5S rRNA microinjected alone, suggesting that L5 binding is a prerequisite for nuclear accumulation. Nuclear import of 5S rRNA/5S RNPs is a facilitated process dependent on limiting factors, since nuclear import exhibited saturation kinetics. Not only was nuclear import of labeled 5S rRNA reduced in the presence of excess unlabeled 5S rRNA, but also in the presence of the synthetic karyophilic protein P(lys)-BSA. In contrast, import was not inhibited by U1 small nuclear RNA (snRNA) or U3 small nucleolar RNA (snoRNA). 5S rRNA/5S RNP nuclear import therefore appears to follow a pathway of molecular interactions similar to many karyophilic proteins, but not the methylguanosine cap-dependent U1 snRNA pathway or the cap-independent U3 snoRNA pathway.     

5S-rRNA-containing ribonucleoproteins from rabbit muscle and liver. Complex and partial primary structures

A 5S-rRNA-containing ribonucleoprotein was purified to homogeneity from a rabbit muscle extract through its affinity to phosphofructokinase-1 and then structurally characterized. This RNP was compared to the 5S-rRNA-containing ribonucleoprotein extracted from rabbit liver ribosomal 60S subunits with EDTA. Analytical gel filtration revealed a molecular mass of 70-80 kDa for both complexes. Gel electrophoresis of the ribosomal complex revealed three protein components, one migrating as a band of 35 kDa and two other small polypeptides of apparently 16.5 kDa and 17.5 kDa. In the sarcoplasmic RNP these small polypeptides were absent. However, besides a major component of 35 kDa, up to five slightly larger and smaller species of 31.5-36.5 kDa were detected. Despite this heterogeneity, only one N-terminal amino acid sequence was obtained for the isolated sarcoplasmic protein, suggesting a C-terminal heterogeneity of one single polypeptide. Within the first 46 amino acid residues no difference between the sequences of the isolated 35-kDa components of sarcoplasmic and ribosomal complexes was found. Homology criteria indicated that this component belongs to the ribosomal protein L5 family. The RNA was identified by complete enzymatic sequencing as 5S rRNA; it was also identical in both complexes and is strongly homologous to 5S rRNA of man. Both L5-5S-RNA complexes could be resolved by hydroxyapatite chromatography into three species still consisting of both protein and RNA. 5'-Terminal dephosphorylation experiments showed that this heterogeneity is exclusively due to the differing number (1-3) of 5'-terminal phosphates. The two additional low-molecular-mass proteins were stably associated to the ribosomal RNP at high salt concentrations in a stoichiometry of about 2:1. They were identified as the acidic phosphoproteins P2/P3 by N-terminal sequencing. High phosphate concentrations facilitated their dissociation from the L5-5S-RNA complex. For the sarcoplasmic L5-5S-RNA complex a hitherto unknown interaction with phosphofructokinase-1, affecting the enzymatic properties, was demonstrated.     

Assessing the function of the Ro ribonucleoprotein complex using Caenorhabditis elegans as a biological tool.

The Ro ribonucleoprotein complex (Ro RNP) was initially described as an autoimmune target in human diseases such as systemic lupus erythematosus and Sj?gren's syndrome. In Xenopus and human cells, its general structure is composed of one major protein of 60 kDa, Ro60, that binds to one of four small RNA molecules, designated Y RNAs. Although no function has been assigned to the Ro RNP, Ro60 has been shown to bind mutant 5S ribosomal RNA (rRNA) molecules in Xenopus oocytes, suggesting a role for Ro60 in 5S rRNA biogenesis. Ro60 has also been shown to participate in the regulation of the translational fate of the L4 ribosomal protein mRNA by interacting with the 5' untranslated region, again suggesting its possible implication in ribosome biogenesis. To identify the function of Ro RNP, we have taken a genetic approach in the nematode Caenorhabditis elegans. As such, we characterized the gene encoding the protein ROP-1, the homologue of the human Ro60 protein. Here, we review the phenotypic analysis of C. elegans rop-l(-) mutants and integrate these results into a model for the function of the Ro RNP particle.     

Yeast ribosomal protein deletion mutants possess altered peptidyltransferase activity and different sensitivity to cycloheximide.

The major function of the ribosome is its ability to catalyze formation of peptide bonds, and it is carried out by the ribosomal peptidyltransferase. Recent evidence suggests that the catalyst of peptide bond formation is the 23S rRNA of the large ribosomal subunit. We have developed an in vitro system for the determination of peptidyltransferase activity in yeast ribosomes. Using this system, a kinetic analysis of a model reaction for peptidyltransferase is described with Ac-Phe-tRNA as the peptidyl donor and puromycin as the acceptor. The Ac-Phe-tRNA-poly(U)-80S ribosome complex (complex C) was isolated and then reacted with excess puromycin to give Ac-Phe-puromycin. This reaction (puromycin reaction) followed first-order kinetics. At saturating concentrations of puromycin, the first-order rate constant (k(3)) is identical to the catalytic rate constant (k(cat)) of peptidyltransferase. This k(cat) from wild-type yeast strains was equal to 2.18 min(-1) at 30 degrees C. We now present for the first time kinetic evidence that yeast ribosomes lacking a particular protein of the 60S subunit may possess significantly altered peptide bond-forming ability. The k(cat) of peptidyltransferase from mutants lacking ribosomal protein L24 was decreased 3-fold to 0.69 min(-1), whereas the k(cat) from mutants lacking L39 was slightly increased to 3.05 min(-1) and that from mutants lacking both proteins was 1.07 min(-1). These results suggest that the presence of ribosomal proteins L24 and, to a lesser extent, L39 is required for exhibition of the normal catalytic activity of the ribosome. Finally, the L24 or L39 mutants did not affect the rate or the extent of the translocation phase of protein synthesis. However, the absence of L24 caused increased resistance to cycloheximide, a translocation inhibitor. Translocation of Ac-Phe-tRNA from the A- to P-site was inhibited by 50% at 1.4 microM cycloheximide for the L24 mutant compared to 0.7 microM for the wild type.     

Deletions in the S1 domain of Rrp5p cause processing at a novel site in ITS1 of yeast pre-rRNA that depends on Rex4p

Rrp5p is the only protein so far known to be required for the processing of yeast pre-rRNA at both the early sites A0, A1 and A2 leading to 18S rRNA and at site A3, the first step specific for the pathway leading to 5.8S/25S rRNA. Previous in vivo mutational analysis of Rrp5p demonstrated that the first 8 of its 12 S1 RNA-binding motifs are involved in the formation of the 'short' form of 5.8S rRNA (5.8S(S)), which is the predominant species under normal conditions. We have constructed two strains in which the genomic RRP5 gene has been replaced by an rrp5 deletion mutant lacking either S1 motifs 3-5 (rrp5-Delta3) or 5-8 (rrp5-Delta4). The first mutant synthesizes almost exclusively 5.8S(L) rRNA, whereas the second one still produces a considerable amount of the 5.8S(S) species. Nevertheless, both mutations were found to block cleavage at site A3 completely. Instead, a novel processing event occurs at a site in a conserved stem-loop structure located between sites A2 and A3, which we have named A4. A synthetic lethality screen using the rrp5-Delta3 and rrp-Delta4 mutations identified the REX4 gene, which encodes a non-essential protein belonging to a class of related yeast proteins that includes several known 3'-->5' exonucleases. Inactivation of the REX4 gene in rrp5-Delta3 or rrp-Delta4 cells abolished cleavage at A4, restored cleavage at A3 and returned the 5.8S(S):5.8S(L) ratio to the wild-type value. The sl phenotype of the rrp5Delta/rex4(-) double mutants appears to be due to a severe disturbance in ribosomal subunit assembly, rather than pre-rRNA processing. The data provide direct evidence for a crucial role of the multiple S1 motifs of Rrp5p in ensuring the correct assembly and action of the processing complex responsible for cleavage at site A3. Furthermore, they clearly implicate Rex4p in both pre-rRNA processing and ribosome assembly, even though this protein is not essential for yeast.     

The antibiotic micrococcin acts on protein L11 at the ribosomal GTPase centre

Micrococcin-resistant mutants of Bacillus megaterium that carry mutations affecting ribosomal protein L11 have been characterised. The mutants fall into two groups. "L11-minus" strains containing an L11 gene with deletions, insertions or nonsense mutations which grow 2.5-fold slower than the wild-type strain, whereas other mutants carrying single-site substitutions within an 11 amino acid residue segment of the N-terminal domain of L11 grow normally. Protein L11 binds to 23 S rRNA within the ribosomal GTPase centre which regulates GTP hydrolysis on ribosomal factors. Micrococcin binding within the rRNA component of this centre was probed on wild-type and mutant ribosomes, in vivo, using dimethyl sulphate where it generated an rRNA footprint indistinguishable from that produced in vitro, even after the cell growth had been arrested by treatment with either kirromycin or fusidic acid. No drug-rRNA binding was detected in vivo for the L11-minus mutants, while reduced binding (approximately 30-fold) was observed for two single-site mutants P23L and P26L. For the latter, the reduced drug affinity alone did not account for the resistance-phenotype because rapid cell growth occurred even at drug concentrations that would saturate the ribosomes. Micrococcin was also bound to complexes containing an rRNA fragment and wild-type or mutant L11, expressed as fusion proteins, and they were probed with proteinases. The drug produced strong protection effects on the wild-type protein and weak effects on the P23L and P26L mutant proteins. We infer that inhibition of cell growth by micrococcin, as for thiostrepton, results from the imposition of a conformational constraint on protein L11 which, in turn, perturbs the function(s) of the ribosomal factor-guanosine nucleotide complexes.     

RNA-protein interactions of stored 5S RNA with TFIIIA and ribosomal protein L5 during Xenopus oogenesis

We studied the pathway of 5S RNA during oogenesis in Xenopus laevis from its storage in the cytoplasm to accumulation in the nucleus, the sequence requirements for the 5S RNA to follow that pathway, and the 5S RNA-protein interactions that occur during the mobilization of stored 5S RNA for assembly into ribosomes. In situ hybridization to sections of oocytes indicates that 5S RNA first becomes associated with the amplified nucleoli during vitellogenesis when the nucleoli are activity synthesizing ribosomal RNA and assembling ribosomes. When labeled 5S RNA is microinjected into the cytoplasm of stage V oocytes, it migrates into the nucleus, whether microinjected naked or complexed with the protein TFIIIA as a 7S RNP storage particle. During vitellogenesis, a nonribosome bound pool of 5S RNA complexed with ribosomal protein L5 (5S RNPs) is formed, which is present throughout the remainder of oogenesis. Immunoprecipitation assays on homogenates of microinjected oocytes showed that labeled 5S RNA can become complexed either with L5 or with TFIIIA. Nucleotides 11 through 108 of the 5S RNA molecule provide the necessary sequence and conformational information required for the formation of immunologically detectable complexes with TFIIIA or L5 and for nuclear accumulation. Furthermore, labeled 5S RNA from microinjected 7S RNPs can subsequently become associated with L5. Such labeled 5S RNA is found in both 5S RNPs and 7S RNPs in the cytoplasm, but only in 5S RNPs in the nucleus of microinjected oocytes. These data suggest that during oogenesis a major pathway for incorporation of 5S RNA into nascent ribosomes involves the migration of 5S RNA from the nucleus to the cytoplasm for storage in an RNP complex with TFIIIA, exchange of that protein association for binding with ribosomal protein L5, and a return to the nucleus for incorporation into ribosomes as they are being assembled in the amplified nucleoli.     

Cytosolic import factor- and Ran-independent nuclear transport of ribosomal protein L5

Ribosomal protein L5 is a shuttling protein that, in Xenopus oocytes, is involved in the nucleocytoplasmic transport of 5S rRNA. As demonstrated earlier, L5 contains three independent nuclear import signals (NLSs), which function in oocytes as well as in somatic cells. Upon physical separation, these NLSs differ in respect to their capacity to bind to nuclear import factors in vitro and to mediate the nuclear import of a heterologous RNP in vivo. As reported in this communication, analysis of the in vitro nuclear import activity of these three NLSs reveals that they also differ in respect to their requirements for cytosolic import factors and Ran. Nuclear import mediated by the N-terminal and the central NLS depends on cytosolic import factor(s) and Ran, whereas import via the C-terminal NLS occurs independently from these factors. Thus, the presence of multiple NLSs in ribosomal protein L5 appears to allow for efficient nuclear transport via utilisation of multiple, mechanistically different import pathways.