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.     

Localization of Lys-51 of L7/L12 on 50S ribosomes from Escherichia coli

Ribosomal protein L7/L12 from Escherichia coli was modified specifically at Lys-51 with 4-(6-formyl-3-azido-phenoxy)butyrimidate. Reconstitution of ribosomal cores, lacking L7/L12, with imidate-modified L7/L12 resulted in back formation of 50S particles which were fully active in elongation-factor-dependent processes. By use of the formylazidophenoxy moiety as hapten, the position of Lys-51 of L7/L12 on the 50S ribosome was determined by immune electron microscopy. The results show that an L7/L12 dimer is present in the L7/L12 stalk in such a way that Lys-51 is located at the far cytoplasmic end of the stalk. The experimental data are discussed in relation to a proposed model for the L7/L12 dimer.     

The ribosomal domain of the bacterial release factors. The carboxyl-terminal domain of the dimer of Escherichia coli ribosomal protein L7/L12 located in the body of the ribosome is important for release factor interaction.

1. Polyclonal antibodies (pAb 1-73 and pAb 26-120) have been raised against both an N-terminal fragment of Escherichia coli ribosomal protein L7/L12 (amino acids 1-73), and a fragment lacking part of the N-terminal domain (amino acids 26-120). 2. Only pAb 26-120 inhibited release-factor-dependent in vitro termination functions on the ribosome. This antibody binds over the length of the stalk of the large subunit of the ribosome as determined by immune electron microscopy, thereby not distinguishing between the C-terminal domains of the two L7/L12 dimers, those in the stalk or those in the body of the subunit. 3. A monoclonal antibody against an epitope of the C-terminal two thirds of the protein (mAb 74-120), which binds both to the distal tip of the stalk as well as to a region at its base, reflecting the positions of the two dimers is strongly inhibitory of release factor function. 4. A monoclonal antibody against an epitope of the N-terminal fragment of L7/L12 (mAb 1-73), previously shown to remove the dimer of L7/L12 in the 50S subunit stalk but still bind to the body of the particle, partially inhibited release-factor-mediated events. 5. The mAb 74-120 inhibited in vitro termination with a similar profile when the stalk dimer of L7/L12 was removed with mAb 1-73, indicating that the body L7/L12 dimer, and in particular its C-terminal domains, are important for release factor/ribosome interaction. 6. The two release factors have subtle differences in their binding domains with respect to L7/L12.     

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.     

Conformation and dynamics of ribosomal stalk protein L12 in solution and on the ribosome

During translation, the ribosome and several of its constituent proteins undergo structural transitions between different functional states. Protein L12, present in four copies in prokaryotic ribosomes, forms a flexible "stalk" with key functions in factor-dependent GTP hydrolysis during translocation. Here we have used heteronuclear NMR spectroscopy to characterize L12 conformation and dynamics in solution and on the ribosome. Isolated L12 forms a symmetric dimer mediated by the N-terminal domains (NTDs), to which each C-terminal domain (CTD) is connected via an unstructured hinge segment. The overall structure can be described as three ellipsoids joined by flexible linkers. No persistent contacts are seen between the two CTDs, or between the NTD and CTD in the L12 dimer in solution. In the (1)H-(15)N HSQC spectrum of the Escherichia coli 70S ribosome, a single set of cross-peaks are observed for residues 40-120 of L12, the intensities of which correspond to only two of four protein copies. The structure of the CTDs observed on the ribosome is indistinguishable from that of isolated L12. These results indicate that two CTDs with identical average structures are mobile and extend away from the ribosome, while the other two copies most likely interact tightly with the ribosome even in the absence of translational factors.     

From structure and dynamics of protein L7/L12 to molecular switching in ribosome

Based on the (1)H-(15)N NMR spectroscopy data, the three-dimensional structure and internal dynamic properties of ribosomal protein L7 from Escherichia coli were derived. The structure of L7 dimer in solution can be described as a set of three distinct domains, tumbling rather independently and linked via flexible hinge regions. The dimeric N-terminal domain (residues 1-32) consists of two antiparallel alpha-alpha-hairpins forming a symmetrical four-helical bundle, whereas the two identical C-terminal domains (residues 52-120) adopt a compact alpha/beta-fold. There is an indirect evidence of the existence of transitory helical structures at least in the first part (residues 33-43) of the hinge region. Combining structural data for the ribosomal protein L7/L12 from NMR spectroscopy and x-ray crystallography, it was suggested that its hinge region acts as a molecular switch, initiating "ratchet-like" motions of the L7/L12 stalk with respect to the ribosomal surface in response to elongation factor binding and GTP hydrolysis. This hypothesis allows an explanation of events observed during the translation cycle and provides useful insights into the role of protein L7/L12 in the functioning of the ribosome.     

A point mutation in ribosomal protein L7/L12 reduces its ability to form a compact dimer structure and to assemble into the GTPase center

An Escherichia coli mutant, LL103, harboring a mutation (Ser15 to Phe) in ribosomal protein L7/L12 was isolated among revertants of a streptomycin-dependent strain. In the crystal structure of the L7/L12 dimer, residue 15 within the N-terminal domain contacts the C-terminal domain of the partner monomer. We tested effects of the mutation on molecular assembly by biochemical approaches. Gel electrophoretic analysis showed that the Phe15-L7/L12 variant had reduced ability in binding to L10, an effect enhanced in the presence of 0.05% of nonionic detergent. Mobility of Phe15-L7/L12 on gel containing the detergent was very low compared to the wild-type proteins, presumably because of an extended structural state of the mutant L7/L12. Ribosomes isolated from LL103 cells contained a reduced amount of L7/L12 and showed low levels (15-30% of wild-type ribosomes) of activities dependent on elongation factors and in translation of natural mRNA. The ribosomal activity was completely recovered by addition of an excess amount of Phe15-L7/L12 to the ribosomes, suggesting that the mutant L7/L12 exerts normal functions when bound on the ribosome. The interaction of Ser15 with the C-terminal domain of the partner molecule seems to contribute to formation of the compact dimer structure and its efficient assembly into the ribosomal GTPase center. We propose a model relating compact and elongated forms of L7/L12 dimers. Phe15-L7/L12 provides a new tool for studying the functional structure of the homodimer.     

Structure of the C-terminal domain of the ribosomal protein L7/L12 from Escherichia coli at 1.7 A

The structure of a C-terminal fragment of the ribosomal protein L7/L12 from Escherichia coli has been refined using crystallographic data to 1.7 A resolution. The R-value is 17.4%. Six residues at the N terminus are too disordered in the structure to be localized. These residues are probably part of a hinge in the complete L7/L12 molecule. The possibility that a 2-fold crystallographic axis is a molecular 2-fold axis is discussed. A patch of invariant residues on the surface of the dimer is probably involved in functional interactions with elongation factors.     

Functional compatibility of elongation factors between mammalian mitochondrial and bacterial ribosomes: characterization of GTPase activity and translation elongation by hybrid ribosomes bearing heterologous L7/12 proteins

The mammalian mitochondrial (mt) ribosome (mitoribosome) is a bacterial-type ribosome but has a highly protein-rich composition. Almost half of the rRNA contained in the bacterial ribosome is replaced with proteins in the mitoribosome. Escherichia coli elongation factor G (EF-G Ec) has no translocase activity on the mitoribosome but EF-G mt is functional on the E.coli ribosome. To investigate the functional equivalency of the mt and E.coli ribosomes, we prepared hybrid mt and E.coli ribosomes. The hybrid mitoribosome containing E.coli L7/12 (L7/12 Ec) instead of L7/12 mt clearly activated the GTPase of EF-G Ec and efficiently promoted its translocase activity in an in vitro translation system. Thus, the mitoribosome is functionally equivalent to the E.coli ribosome despite their distinct compositions. The mt EF-Tu-dependent translation activity of the E.coli ribosome was also clearly enhanced by replacing the C-terminal domain (CTD) of L7/12 Ec with the mt counterpart (the hybrid E.coli ribosome). This strongly indicates that the CTD of L7/12 is responsible for EF-Tu function. These results demonstrate that functional compatibility between elongation factors and the L7/12 protein in the ribosome governs its translational specificity.     

Flexibility, conformational diversity and two dimerization modes in complexes of ribosomal protein L12

Protein L12, the only multicopy component of the ribosome, is presumed to be involved in the binding of translation factors, stimulating factor-dependent GTP hydrolysis. Crystal structures of L12 from Thermotogamaritima have been solved in two space groups by the multiple anomalous dispersion method and refined at 2.4 and 2.0 A resolution. In both crystal forms, an asymmetric unit comprises two full-length L12 molecules and two N-terminal L12 fragments that are associated in a specific, hetero-tetrameric complex with one non-crystallographic 2-fold axis. The two full-length proteins form a tight, symmetric, parallel dimer, mainly through their N-terminal domains. Each monomer of this central dimer additionally associates in a different way with an N-terminal L12 fragment. Both dimerization modes are unlike models proposed previously and suggest that similar complexes may occur in vivo and in situ. The structures also display different L12 monomer conformations, in accord with the suggested dynamic role of the protein in the ribosomal translocation process. The structures have been submitted to the Protein Databank (http://www.rcsb.org/pdb) under accession numbers 1DD3 and 1DD4.     

Structure of a Two-Domain N-Terminal Fragment of Ribosomal Protein L10 from Methanococcus jannaschii Reveals a Specific Piece of the Archaeal Ribosomal Stalk

Ribosomal stalk is involved in the formation of the so-called “GTPase-associated site” and plays a key role in the interaction of ribosome with translation factors and in the control of translation accuracy. The stalk is formed by two or three copies of the L7/L12 dimer bound to the C-terminal tail of protein L10. The N-terminal domain of L10 binds to a segment of domain II of 23S rRNA near the binding site for ribosomal protein L11. The structure of bacterial L10 in complex with three L7/L12 N-terminal dimers has been determined in the isolated state, and the structure of the first third of archaeal L10 bound to domain II of 23S rRNA has been solved within the Haloarcula marismortui 50S ribosomal subunit. A close structural similarity between the RNA-binding domain of archaeal L10 and the RNA-binding domain of bacterial L10 has been demonstrated. In this work, a long RNA-binding N-terminal fragment of L10 from Methanococcus jannaschii has been isolated and crystallized. The crystal structure of this fragment (which encompasses two-thirds of the protein) has been solved at 1.6 Å resolution. The model presented shows the structure of the RNA-binding domain and the structure of the adjacent domain that exist in archaeal L10 and eukaryotic P0 proteins only. Furthermore, our model incorporated into the structure of the H. marismortui 50S ribosomal subunit allows clarification of the structure of the archaeal ribosomal stalk base.     

Oligomeric state and mode of self-association of Thermotoga maritima ribosomal stalk protein L12 in solution

The "stalk" of the prokaryotic 50S ribosomal subunit is comprised of four copies of the protein L7/L12. In Escherichia coli, L7/L12 is a dimeric protein at micromolar concentrations, which is able to undergo rapid subunit exchange. A recent structural study indicated a tetrameric arrangement of the L12 proteins isolated from Thermotoga maritima, in which the proteins engaged in two different dimerization modes. In one mode, the two monomers of L12 form a tight symmetric and parallel dimer held together by a four-helix bundle, which encompasses the hinge region between the N- and C-terminal domains. In the other mode, the two monomers bind through their N-terminal region in an antiparallel configuration, in which one monomer comprises an alpha-helical hinge and the other monomer adopts an elongated shape with an unfolded hinge region. Presently, it is unclear which dimer contact prevails in solution and on the ribosome. Using cysteine mutants of T. maritima labeled with fluorescent probes, we investigated the mode of interactions between L12 subunits. Data from Forster resonance energy transfer experiments support a dimerization of L12 in solution, in which two monomers bind through their N-terminal region in an antiparallel configuration. We also demonstrate that the rate of subunit exchange in T. maritima L12 is significantly slower at 25 degrees C than that in the E. coli system. The exchange rate increases with increasing temperature and approaches the one observed for the E. coli system at 50 degrees C. Possible factors responsible for this difference are discussed.     

The N-terminal sequence protein of L7/L 12 is responsible for its dimerization.

Ultracentrifuge studies of intact protein L7/L12, of its fragments 27--120, 1--74 and 74--120 and of protein L7/L12 with oxidized methionine residues, indicate that the N-terminal sequence of the protein L7/L12 is responsible for its dimerization. The symmetry model of the dimer is discussed.     

Selective separation procedure for determination of ribosomal proteins L7 and L12.

An electrophoretic procedure for the selective separation and determination of the closely similar ribosomal proteins L7 and L12 (which are specifically involved in the GTPase reactions of the ribosome) from the total protein mixture extracted from unwashed ribosomes is described. In this procedure, which takes advantage of their unusually low isoelectric points. L7 and L12 (and a few other acidic proteins) migrate into gel asanions, while the bulk of ribosomal proteins which are basic remain behind. The positions of L7 and L12 were determined with authentic, pure proteins. It was further determined by means of 2-dimensional gel electrophoresis that no other protein components present in unwashed ribosomes comigrate with the bands of L7 and L12.     

Characterization of the region on protein L7/L12 involved in binding to ribosomal particles

Tryptic digestion of reductively methylated protein L7/L12 yields a large tryptic fragment, which comprises amino acids 1-59. At the most, two molecules of this fragment can bind to a 50-S ribosomal particle, deprived of protein L7/L12. Besides, binding of each single 1-59 fragment competes with binding of one dimeric L7/L12 molecule. Molecular weight studies on the fragment reveal a monomeric structure. Digestion of the 1-59 fragment with carboxypeptidase Y leads to the formation of a 1-55 fragment. The binding characteristics of the latter fragment are similar to those of the 1-59 fragment. The results suggest that a monomeric stretch of L7/L12, comprising the first 55 amino acids, is sufficient for attaching L7/L12 to the ribosome.     

Localization of two epitopes of protein L7/L12 to both the body and stalk of the large ribosomal subunit. Immune electron microscopy using monoclonal antibodies

Four molecules of ribosomal protein L7/L12 are found as two dimers on the Escherichia coli 50 S ribosomal subunit. Immune electron microscopy using monoclonal antibodies directed against two epitopes of protein L7/L12 has allowed placement of elements of each dimer. One monoclonal antibody, directed against a determinant in the COOH-terminal domain, allows localization of two identical determinants at or near the end of the subunit stalk. The same antibody was used to place two additional determinants at the periphery of stalkless subunits, in an area from which a stalk might be expected to project. A second antibody, directed against an epitope in the amino-terminal portion of L7/L12, caused loss of stalks from the 50 S subunits. The micrographs showed symmetrical oligometric complexes of the dissociated dimeric protein with bivalent antibody. Antibodies were also seen to bind to the body of stalkless subunits, in a region near the COOH-terminal sites. The results are explained by a model in which one dimer of protein L7/L12 exists in a folded conformation on the subunit body and the second dimer occurs in an extended conformation in the subunit stalk.     

A molecular dynamics study of the C-terminal fragment of the L7/L12 ribosomal protein

The crystallographic dimer of the C-terminal fragment (CTF) of the L7/L12 ribosomal protein has been subjected to molecular dynamics (MD) simulations. A 90 picosecond (ps) trajectory for the protein dimer, 19 water molecules and two counter ions has been calculated at constant temperature. Effects of intermolecular interactions on the structure and dynamics have been studied. The exact crystallographic symmetry is lost and the atomic fluctuations differ from one monomer to the other. The average MD structure is more stable than the X-ray one, as judged by accessible surface area and energy calculations. Crystal (non-dimeric) interactions have been simulated in another 40 ps trajectory by using harmonic restraints to represent intermolecular hydrogen bonds. The conformational changes with respect ot the X-ray structure are then virtually suppressed.The unrestrained dimer trajectory has been scanned for cooperative motions involving secondary structure elements. The intrinsic collective motions of the monomer are transmitted via intermolecular contacts to the dimer structure.The existence of a stable dimeric form of CTF, resembling the crystallographic one, has been documented. At the cost of fairly small energy expenditure the dimer has considerable conformational flexibility. This flexibility may endow the dimer with some functional potential as an energy transducer.     

Stimulation of the GTPase activity of translation elongation factor G by ribosomal protein L7/12

Elongation factors (EFs) Tu and G are GTPases that have important functions in protein synthesis. The low intrinsic GTPase activity of both factors is strongly stimulated on the ribosome by unknown mechanisms. Here we report that isolated ribosomal protein L7/12 strongly stimulates GTP hydrolysis by EF-G, but not by EF-Tu, indicating a major contribution of L7/12 to GTPase activation of EF-G on the ribosome. The effect is due to the acceleration of the catalytic step because the rate of GDP-GTP exchange on EF-G, as measured by rapid kinetics, is much faster than the steady-state GTPase rate. The unique, highly conserved arginine residue in the C-terminal domain of L7/12 is not essential for the activation, excluding an "arginine finger"-type mechanism. L7/12 appears to function by stabilizing the GTPase transition state of EF-G.     

Specific interactions of the L10(L12)4 ribosomal protein complex with mRNA, rRNA, and L11

Large ribosomal subunit proteins L10 and L12 form a pentameric protein complex, L10(L12) 4, that is intimately involved in the ribosome elongation cycle. Its contacts with rRNA or other ribosomal proteins have been only partially resolved by crystallography. In Escherichia coli, L10 and L12 are encoded from a single operon for which L10(L12) 4 is a translational repressor that recognizes a secondary structure in the mRNA leader. In this study, L10(L12) 4 was expressed from the moderate thermophile Bacillus stearothermophilus to quantitatively compare strategies for binding of the complex to mRNA and ribosome targets. The minimal mRNA recognition structure is widely distributed among bacteria and has the potential to form a kink-turn structure similar to one identified in the rRNA as part of the L10(L12) 4 binding site. Mutations in equivalent positions between the two sequences have similar effects on L10(L12) 4-RNA binding affinity and identify the kink-turn motif and a loop AA sequence as important recognition elements. In contrast to the larger rRNA structure, the mRNA apparently positions the kink-turn motif and loop for protein recognition without the benefit of Mg (2+)-dependent tertiary structure. The mRNA and rRNA fragments bind L10(L12) 4 with similar affinity ( approximately 10 (8) M (-1)), but fluorescence binding studies show that a nearby protein in the ribosome, L11, enhances L10(L12) 4 binding approximately 100-fold. Thus, mRNA and ribosome targets use similar RNA features, held in different structural contexts, to recognize L10(L12) 4, and the ribosome ensures the saturation of its L10(L12) 4 binding site by means of an additional protein-protein interaction.