Overexpression of the methanococcal ribosomal protein L12 in Escherichia coli and its incorporation into halobacterial 50 S subunits yielding active ribosomes

The gene for the ribosomal L12 protein from the archaebacterium Methanococcus vannielii was cloned into the expression vector pKK223-3. The protein was overexpressed and remained stable in Escherichia coli XL1 cells. Purification yielded a protein with the same amino acid composition and sequence as in Methanococcus but it was acetylated at the N terminus as in the case with the homologous protein of E. coli. The in vivo incorporation of the overexpressed protein into the E. coli ribosomes was not observed. The overexpressed M. vannielii protein MvaL12e was incorporated into halobacterial ribosomes, thereby displacing the corresponding halobacterial L12 protein. Intact 70 S ribosomes were reconstituted from halobacterial 50 S subunits carrying the MvaL12e protein. These ribosomes were as active as native halobacterial ribosomes in a poly(U) assay. On the other hand, our attempts to incorporate L12 proteins from Bacillus stearothermophilus and E. coli into halobacterial ribosomes were not successful. These results support the conclusion which is based on primary sequence and predicted secondary structure comparisons that there exist two distinct L12 protein families, namely the eubacterial L12 protein family and the eukaryotic/archaebacterial L12 protein family.     

Ribosomal proteins at the stalk region modulate functional rRNA structures in the GTPase center

Replacement of the L10.L7/L12 protein complex and L11 in Escherichia coli ribosomes with the respective rat counterparts P0.P1/P2 and eukaryotic L12 causes conversion of ribosomal specificity for elongation factors from prokaryotic elongation factor (EF)-Tu/EF-G to eukaryotic EF (eEF)-1alpha/eEF-2. Here we have investigated the effects of protein replacement on the structure and function of two rRNA domains around positions 1070 and 2660 (sarcin/ricin loop) of 23 S rRNA. Protein replacement at the 1070 region in E. coli 50 S subunits was demonstrated by chemical probing analysis. Binding of rat proteins to the 1070 region caused increased accessibility of the 2660 and 1070 regions to ligands for eukaryotic ribosomes: the ribotoxin pepocin for the 2660 region (E. coli numbering), anti-28 S autoantibody for the 1070 region, and eEF-2 for both regions. Moreover, binding of the E. coli L10.L7/L12 complex and L11 to the 1070 region was shown to be responsible for E. coli ribosomal accessibility to another ribotoxin, gypsophilin. Ribosomal proteins at the 1070 region appear to modulate the structures and functions of the 2660 and 1070 RNA regions in slightly different modes in prokaryotes and eukaryotes.     

Replacement of L7/L12.L10 protein complex in Escherichia coli ribosomes with the eukaryotic counterpart changes the specificity of elongation factor binding.

The L8 protein complex consisting of L7/L12 and L10 in Escherichia coli ribosomes is assembled on the conserved region of 23 S rRNA termed the GTPase-associated domain. We replaced the L8 complex in E. coli 50 S subunits with the rat counterpart P protein complex consisting of P1, P2, and P0. The L8 complex was removed from the ribosome with 50% ethanol, 10 mM MgCl(2), 0.5 M NH(4)Cl, at 30 degrees C, and the rat P complex bound to the core particle. Binding of the P complex to the core was prevented by addition of RNA fragment covering the GTPase-associated domain of E. coli 23 S rRNA to which rat P complex bound strongly, suggesting a direct role of the RNA domain in this incorporation. The resultant hybrid ribosomes showed eukaryotic translocase elongation factor (EF)-2-dependent, but not prokaryotic EF-G-dependent, GTPase activity comparable with rat 80 S ribosomes. The EF-2-dependent activity was dependent upon the P complex binding and was inhibited by the antibiotic thiostrepton, a ligand for a portion of the GTPase-associated domain of prokaryotic ribosomes. This hybrid system clearly shows significance of binding of the P complex to the GTPase-associated RNA domain for interaction of EF-2 with the ribosome. The results also suggest that E. coli 23 S rRNA participates in the eukaryotic translocase-dependent GTPase activity in the hybrid system.     

Methylation of ribosomal proteins in bacteria: evidence of conserved modification of the eubacterial 50S subunit.

Methylation of the 50S ribosomal proteins from Bacillus stearothermophilus, Bacillus subtilis, Alteromonas espejiana, and Halobacterium cutirubrum was measured after the cells were grown in the presence of [1-14C]methionine or [methyl-3H]methionine or both. Two-dimensional polyacrylamide gel electrophoretic analysis revealed, in general, similar relative electrophoretic mobilities of the methylated proteins from each eubacterium studied. Proteins known to be structurally and functionally homologous in several microorganisms were all methylated. Thus, the following group of proteins, which appear to be involved in peptidyltransferase or in polyphenylalanine-synthesizing activity in B. stearothermophilus (P.E. Auron and S. R. Fahnestock, J. Biol. Chem. 256:10105-10110, 1981), were methylated (possible Escherichia coli methylated homologs are indicated in parentheses): BTL5(EL5), BTL6(EL3), BTL8(EL10), BTL11(EL11), BTL13(EL7L12) and BTL20b(EL16). In addition, the pentameric ribosomal complex BTL13 X BTL8, analogous to the complex EL7L12 X EL10 of E. coli, contained methylated proteins. Analysis of the methylated amino acids in the most heavily methylated proteins, BSL11 from B. subtilis and BTL11 from B. stearothermophilus, showed the presence of epsilon-N-trimethyllysine as the major methylated amino acid in both proteins, in agreement with known data for E. coli. In addition, BSL11 appeared to contain trimethylalanine, a characteristic, modified amino acid previously described only in EL11 from E. coli. These results and those previously obtained from other bacteria indicate a high degree of conservation for ribosomal protein methylation and suggest an important, albeit unknown, role for the modification of these components in eubacterial ribosomes.     

gamma-Carboxyglutamic acid in eukaryotic and prokaryotic ribosomes.

γ-carboxyglutamic acid (GLA) has been assayed in ribosomes of wheat germ and E. coli, and in E. coli ribosomal sub-units, by amino acid analysis of total protein. Results, as nMoles GLA/mg protein, were 18.1 (wheat germ), 58.4 (E. coli), 39.6 and 81.5 (E. coli 30S and 50S sub-units, respectively.) Results for wheat germ and previously reported mammalian ribosomes were highly similar. Hence the level of GLA in eukaryotic ribosomes appears to be approximately constant, but low compared to bacterial (E. coli) ribosomes.     

Mobile domains in ribosomes revealed by proton nuclear magnetic resonance

Ribosomes and subunits from eukaryotic and prokaryotic sources were studied by high-resolution proton magnetic-resonance spectroscopy. If all ribosomal components are firmly bound within the particle, then only broad spectra would be expected. However, relatively sharp resonances were found both in ribosomal subunits and in 70 or 80 S ribosomes. The regions of these mobile protein domains have been partially assigned in Escherichia coli ribosomes. Large and small ribosomal subunits were treated to remove selectively proteins L7/12 and S1, respectively. Sharp proton magnetic resonance spectra were not observed for the stripped large subunit showing that proteins L7/12 comprise the flexible protein region and that there is little other flexibility in the stripped subunit. Complete removal of S1 from the small subunit greatly reduced but did not abolish the sharp protein resonance peaks, indicating that protein S1 contains a substantial flexible component but that other flexible components remain in the stripped small subunit. Evidence for generality of these features of ribosome organization is provided by similar studies on ribosomes from eukaryotic sources.     

In vitro reconstitution of the GTPase-associated centre of the archaebacterial ribosome: the functional features observed in a hybrid form with Escherichia coli 50S subunits

We cloned the genes encoding the ribosomal proteins Ph (Pyrococcus horikoshii)-P0, Ph-L12 and Ph-L11, which constitute the GTPase-associated centre of the archaebacterium Pyrococcus horikoshii. These proteins are homologues of the eukaryotic P0, P1/P2 and eL12 proteins, and correspond to Escherichia coli L10, L7/L12 and L11 proteins respectively. The proteins and the truncation mutants of Ph-P0 were overexpressed in E. coli cells and used for in vitro assembly on to the conserved domain around position 1070 of 23S rRNA (E. coli numbering). Ph-L12 tightly associated as a homodimer and bound to the C-terminal half of Ph-P0. The Ph-P0.Ph-L12 complex and Ph-L11 bound to the 1070 rRNA fragments from the three biological kingdoms in the same manner as the equivalent proteins of eukaryotic and eubacterial ribosomes. The Ph-P0.Ph-L12 complex and Ph-L11 could replace L10.L7/L12 and L11 respectively, on the E. coli 50S subunit in vitro. The resultant hybrid ribosome was accessible for eukaryotic, as well as archaebacterial elongation factors, but not for prokaryotic elongation factors. The GTPase and polyphenylalanine-synthetic activity that is dependent on eukaryotic elongation factors was comparable with that of the hybrid ribosomes carrying the eukaryotic ribosomal proteins. The results suggest that the archaebacterial proteins, including the Ph-L12 homodimer, are functionally accessible to eukaryotic translation factors.     

The solution structure of ribosomal protein S17E from Methanobacterium thermoautotrophicum: a structural homolog of the FF domain

The ribosomal protein S17E from the archaeon Methanobacterium thermoautotrophicum is a component of the 30S ribosomal subunit. S17E is a 62-residue protein conserved in archaea and eukaryotes and has no counterparts in bacteria. Mammalian S17E is a phosphoprotein component of eukaryotic ribosomes. Archaeal S17E proteins range from 59 to 79 amino acids, and are about half the length of the eukaryotic homologs which have an additional C-terminal region. Here we report the three-dimensional solution structure of S17E. S17E folds into a small three-helix bundle strikingly similar to the FF domain of human HYPA/FBP11, a novel phosphopeptide-binding fold. S17E bears a conserved positively charged surface acting as a robust scaffold for molecular recognition. The structure of M. thermoautotrophicum S17E provides a template for homology modeling of eukaryotic S17E proteins in the family.     

Translation elongation by a hybrid ribosome in which proteins at the GTPase center of the Escherichia coli ribosome are replaced with rat counterparts.

Ribosomal L10-L7/L12 protein complex and L11 bind to a highly conserved RNA region around position 1070 in domain II of 23 S rRNA and constitute a part of the GTPase-associated center in Escherichia coli ribosomes. We replaced these ribosomal proteins in vitro with the rat counterparts P0-P1/P2 complex and RL12, and tested them for ribosomal activities. The core 50 S subunit lacking the proteins on the 1070 RNA domain was prepared under gentle conditions from a mutant deficient in ribosomal protein L11. The rat proteins bound to the core 50 S subunit through their interactions with the 1070 RNA domain. The resultant hybrid ribosome was insensitive to thiostrepton and showed poly(U)-programmed polyphenylalanine synthesis dependent on the actions of both eukaryotic elongation factors 1alpha (eEF-1alpha) and 2 (eEF-2) but not of the prokaryotic equivalent factors EF-Tu and EF-G. The results from replacement of either the L10-L7/L12 complex or L11 with rat protein showed that the P0-P1/P2 complex, and not RL12, was responsible for the specificity of the eukaryotic ribosomes to eukaryotic elongation factors and for the accompanying GTPase activity. The presence of either E. coli L11 or rat RL12 considerably stimulated the polyphenylalanine synthesis by the hybrid ribosome, suggesting that L11/RL12 proteins play an important role in post-GTPase events of translation elongation.     

Ribosomal acidic proteins of eucaryotic cells

Summary By the method of ethanol-salt extraction with ion-exchange chromatography on CM-cellulose an acidic protein of pea 80S ribosomes was isolated. This protein located in the large subunit, had a molecular weight of 14 000 and an IEP of 4.7. The protein is partially phosphorylated, alanine-rich and has methionine at the N-terminal position. Based on these characteristics and on the comparative study of tryptic hydrolyzates of the plant protein and E. coli L7/L12, the protein so obtained is found to be homologous to the L7/Ll2 of the procaryotic ribosomes.     

Structure function relationships in the ribosomal stalk proteins of archaebacteria.

The ribosomal L12 protein gene of Sulfolobus solfataricus (SsoL12) has been subcloned and overexpressed in Escherichia coli. Five protein L12 mutants were designed: two NH2-terminal and two COOH-terminal truncated mutants and one mutant lacking the highly charged part of the COOH-terminal region. The mutant protein genes were overexpressed in E. coli and the products purified. The amino acid composition was verified and the NH2 terminally truncated mutants were subjected to Edman degradation. The SsoL12 protein was selectively removed from entire S. solfataricus ribosomes by an ethanol wash. The remaining ribosomal core particles showed a substantial decrease in the in vitro translational activity. S. solfataricus L12 protein overexpressed in E. coli (SsoL12e) was incorporated into these ribosomal cores and restored their translational activity. Mutants lacking any part of the COOH-terminal region could be incorporated into these cores, as proven by two-dimensional polyacrylamide gels of the reconstituted particles. Mutant SsoL12 MC2 (residue 1-70) was sufficient for dimerization and incorporation into ribosomes. In contrast to the COOH terminally truncated mutants, L12 proteins lacking the 12 highly conserved NH2-terminal residues or the entire NH2-terminal region (44 amino acids) are unable to bind to ribosomes, suggesting that the SsoL12 protein binds with its NH2-terminal portion to the ribosome. None of the mutants could significantly increase the translational activity of the core particles suggesting that every deleted part of the protein was needed directly or indirectly for translational activity. Our results suggest that the COOH terminally truncated mutants were bound to ribosomes but not functional for translation. Cores preincubated with these COOH terminally truncated mutants regained activity when a second incubation with the entire overexpressed SsoL12e protein followed. This finding suggests that archaebacterial L12 proteins are freely exchanged on the ribosome.     

Deletion of C-terminal residues of Escherichia coli ribosomal protein L10 causes the loss of binding of one L7/L12 dimer: ribosomes with one L7/L12 dimer are active

Escherichia coli ribosomal protein L10 binds the two L7/L12 dimers and thereby anchors them to the large ribosomal subunit. C-Terminal deletion variants (Delta10, Delta20, and Delta33 amino acids) of ribosomal protein L10 were constructed in order to define the binding sites for the two L7/L12 dimers and then to make and test ribosomal particles that contain only one of the two dimers. None of the deletions interfered with binding of L10 variants to ribosomal core particles. Deletion of 20 or 33 amino acids led to the inability of the proteins to bind both dimers of protein L7/L12. The L10 variant with deletion of 10 amino acids bound one L7/L12 dimer in solution and when reconstituted into ribosomes promoted the binding of only one L7/L12 dimer to the ribosome. The ribosomes that contained a single L7/L12 dimer were homogeneous by gel electrophoresis where they had a mobility between wild-type 50S subunits and cores completely lacking L7/L12. The single-dimer ribosomal particles supported elongation factor G dependent GTP hydrolysis and protein synthesis in vitro with the same activity as that of two-dimer particles. The results suggest that amino acids 145-154 in protein L10 determine the binding site ("internal-site") for one L7/L12 dimer (the one reported here), and residues 155-164 ("C-terminal-site") are involved in the interaction with the second L7/L12 dimer. Homogeneous ribosomal particles containing a single L7/L12 dimer in each of the distinct sites present an ideal system for studying the location, conformation, dynamics, and function of each of the dimers individually.     

Molecular cloning and analysis of cDNA sequences for two ribosomal proteins from Artemia. The coordinate expression of genes for ribosomal proteins and elongation factor 1 during embryogenesis of Artemia

The large subunit of eukaryotic ribosomes contains acidic phosphoproteins which are related to L7/L12 from Escherichia coli. In the brine shrimp Artemia these proteins are designated eL12 and eL12'. We have isolated cDNA clones for these proteins from a cDNA bank that was constructed by the use of size-fractionated poly(A)-rich RNA (8-10S fraction) from Artemia and a synthetic oligonucleotide as primer. Clones containing DNA sequences coding for eL12 and eL12 were characterized by hybrid-selected translation and DNA sequencing. The proteins eL12 and eL12' share an identical peptide of 22 amino acids at their carboxy termini whereas the remaining part of the protein shows little sequence homology. The nucleotide sequences show a different codon use for the amino acids in the common carboxy terminus, thereby excluding a common exon coding for this part of both proteins. Despite the differences in amino acid sequence in the major part of eL12 and eL12' the proteins have a considerable degree of homology on the basis of the distribution of hydrophobic and hydrophilic amino acids over the polypeptide chains, in agreement with a related folding and function of both proteins. Relative levels of mRNA coding for eL12, eL12' and elongation factor 1 alpha were determined during the development of Artemia from a dormant cyst to a nauplius. The data show a coordinate expression of the genes for EF-1 alpha and both ribosomal proteins, excluding a differential expression of the genes for these related ribosomal proteins during embryogenesis. Analysis of the gene copy number for eL12 and eL12' indicates the presence of a few genes for each protein.     

Specificities of RNA N-glycosidase activity of Mirabilis antiviral protein variants.

Mirabilis antiviral protein (MAP), a ribosome-inactivating protein, inactivates both eukaryotic and prokaryotic ribosomes by means of site-specific RNA N-glycosidase activity. In order to identify the site of this activity, some amino acid residues of MAP, conserved in homologous ribosome-inactivating proteins, were altered to other amino acids by replacing DNA fragments of the total synthetic gene of MAP. When the in vitro proteins synthesis of rabbit reticulocyte was treated with MAP variants secreted into culture media of Escherichia coli transformants, the inhibitory effect of R26L and R48L (R26L designates MAP variant with Arg-26 changed to Leu) was found to be similar to that of native MAP. Both purified Y72F and Y118F had the same effect as native MAP, and E168D had a slightly weaker effect. In contrast, on the protein synthesis of E. coli, Y118F had one-tenth the effect of native MAP, and Y72F and E168D approximately one-hundredth the effect. These three variant proteins also exhibited reduced RNA N-glycosidase activity on substrate E. coli ribosomes. These results suggest that Tyr-72 and Glu-168 are involved in RNA N-glycosidase activity. When the R171K gene was expressed in E. coli, an N-glycosidic bond of the 23 S rRNA of the host ribosome was found to be cleaved, although no product of the gene could be detected. This suggests that MAP variants can maintain their N-glycosidase activity when the conserved Glu-168 and Arg-171 are changed to similarly charged residues.     

Signature amino acids enable the archaeal L7Ae box C/D RNP core protein to recognize and bind the K-loop RNA motif

The archaeal L7Ae and eukaryotic 15.5kD protein homologs are members of the L7Ae/15.5kD protein family that characteristically recognize K-turn motifs found in both archaeal and eukaryotic RNAs. In Archaea, the L7Ae protein uniquely binds the K-loop motif found in box C/D and H/ACA sRNAs, whereas the eukaryotic 15.5kD homolog is unable to recognize this variant K-turn RNA. Comparative sequence and structural analyses, coupled with amino acid replacement experiments, have demonstrated that five amino acids enable the archaeal L7Ae core protein to recognize and bind the K-loop motif. These signature residues are highly conserved in the archaeal L7Ae and eukaryotic 15.5kD homologs, but differ between the two domains of life. Interestingly, loss of K-loop binding by archaeal L7Ae does not disrupt C′/D′ RNP formation or RNA-guided nucleotide modification. L7Ae is still incorporated into the C′/D′ RNP despite its inability to bind the K-loop, thus indicating the importance of protein–protein interactions for RNP assembly and function. Finally, these five signature amino acids are distinct for each of the L7Ae/L30 family members, suggesting an evolutionary continuum of these RNA-binding proteins for recognition of the various K-turn motifs contained in their cognate RNAs.     

Preparation and characterization of fluorescent 50S ribosomes. Specific labeling of ribosomal proteins L7/L12 and L10 of Escherichia coli

So that the topographic and dynamic properties of the L7/L12--L10 complex in the 50S ribosome of Escherichia coli could be studied, methods and reagents were developed in order to introduce fluorescent groups at specific positions of these proteins. In the case of L7/L12, this was done by attaching an aldehyde group to Lys-51 of the protein by using 4-(4-formylphenoxy)butyrimidate or by converting the amino terminus of L12 into an aldehyde group by periodate oxidation. Subsequent reaction of the aldehyde groups with newly developed hydrazine derivatives of fluorescein and coumarin resulted in specifically labeled L7/L12 derivatives. L10 was modified at the single cysteine residue with N-[7-(dimethylamino)-4-methylcoumarinyl]maleimide. The fluorescent proteins L10 and L7/L12 could be reconstituted into 50S ribosomes. The resulting specifically labeled 50S ribosomes show 25--100% activity in elongation factor G dependent GTPase as well as in polyphenylalanine synthesis. The fluorescent properties of the labeled 50S ribosomes show that these fluorescent derivatives are suitable for energy transfer studies.     

Investigation of ribosomes of E. coli and T. maritima by atomic force microscopy

Subunits 70S, 50S, and 30S of ribosomes of E. coli and T. maritima have been studied by atomic force microscopy. A considerable heterogeneity of structures was visualized when 70S and 30S subunits were sorbed on mica. The linear size and the height of molecules were estimated. It was found that the heights of ribosomes of E. coli and T. maritima substantially differ. The average height of 70S ribosomes of E. coli was 9.4 + 0.01 nm and that of T. maritima was 10.35 +/- 0.02 nm. The differences in the dimensions were probably determined by special organization of the mobile ribosomal element the L7/L12-stalk.