Mobile domains in ribosomes revealed by proton nuclear magnetic resonance

Protein folding on the ribosome studied using NMR spectroscopy

NMR spectroscopy is a powerful tool for the investigation of protein folding and misfolding, providing a characterization of molecular structure, dynamics and exchange processes, across a very wide range of timescales and with near atomic resolution. In recent years NMR methods have also been developed to study protein folding as it might occur within the cell, in a de novo manner, by observing the folding of nascent polypeptides in the process of emerging from the ribosome during synthesis. Despite the 2.3 MDa molecular weight of the bacterial 70S ribosome, many nascent polypeptides, and some ribosomal proteins, have sufficient local flexibility that sharp resonances may be observed in solution-state NMR spectra. In providing information on dynamic regions of the structure, NMR spectroscopy is therefore highly complementary to alternative methods such as X-ray crystallography and cryo-electron microscopy, which have successfully characterized the rigid core of the ribosome particle. However, the low working concentrations and limited sample stability associated with ribosome-nascent chain complexes means that such studies still present significant technical challenges to the NMR spectroscopist. This review will discuss the progress that has been made in this area, surveying all NMR studies that have been published to date, and with a particular focus on strategies for improving experimental sensitivity.

Engineering and characterization of the ribosomal L10.L12 stalk complex. A structural element responsible for high turnover of the elongation factor G-dependent GTPase

The ribosomal stalk protein L12 is essential for events dependent on the GTP-binding translation factors. It has been recently shown that ribosomes from Thermus thermophilus contain a heptameric complex L10.(L12)2.(L12)2.(L12)2, rather than the conventional pentameric complex L10.(L12)2.(L12)2. Here we describe the reconstitution of the heptameric complex from purified L10 and L12 and the characterization of its role in elongation factor G-dependent GTPase activity using a hybrid system with Escherichia coli ribosomes. The T. thermophilus heptameric complex resulted in a 2.5-fold higher activity than the E. coli pentameric complex. The structural element of the T. thermophilus complex responsible for the higher activity was investigated using a chimeric L10 protein (Ec-Tt-L10), in which the C-terminal L12-binding site in E. coli L10 was replaced with the same region from T. thermophilus, and two chimeric L12 proteins: Ec-Tt-L12, in which the E. coli N-terminal domain was fused with the T. thermophilus C-terminal domain, and Tt.Ec-L12, in which the T. thermophilus N-terminal domain was fused with the E. coli C-terminal domain. High GTPase turnover was observed with the pentameric chimeric complex formed from E. coli L10 and Ec-Tt-L12 but not with the heptameric complex formed from Ec-Tt-L10 and Tt.Ec-L12. This suggested that the C-terminal region of T. thermophilus L12, rather than the heptameric nature of the complex, was responsible for the high GTPase turnover. Further analyses with other chimeric L12 proteins identified helix alpha6 as the region most likely to contain the responsible element.

Biochemical evidence for the heptameric complex L10(L12)6 in the Thermus thermophilus ribosome: in vitro analysis of its molecular assembly and functional properties

The stalk protein L12 is the only multiple component in 50S ribosomal subunit. In Escherichia coli, two L12 dimers bind to the C-terminal domain of L10 to form a pentameric complex, L10[(L12)(2)](2), while the recent X-ray crystallographic study and tandem MS analyses revealed the presence of a heptameric complex, L10[(L12)(2)](3), in some thermophilic bacteria. We here characterized the complex of Thermus thermophilus (Tt-) L10 and Tt-L12 stalk proteins by biochemical approaches using C-terminally truncated variants of Tt-L10. The C-terminal 44-residues removal (Delta44) resulted in complete loss of interactions with Tt-L12. Quantitative analysis of Tt-L12 assembled onto E. coli 50S core particles, together with Tt-L10 variants, indicated that the wild-type, Delta13 and Delta23 variants bound three, two and one Tt-L12 dimers, respectively. The hybrid ribosomes that contained the T. thermophilus proteins were highly accessible to E. coli elongation factors. The progressive removal of Tt-L12 dimers caused a stepwise reduction of ribosomal activities, which suggested that each individual stalk dimer contributed to ribosomal function. Interestingly, the hybrid ribosomes showed higher EF-G-dependent GTPase activity than E. coli ribosomes, even when two or one Tt-L12 dimer. This result seems to be due to a structural characteristic of Tt-L12 dimer.

Functional interaction between bases C1049 in domain II and G2751 in domain VI of 23S rRNA in Escherichia coli ribosomes

The factor-binding center within the Escherichia coli ribosome is comprised of two discrete domains of 23S rRNA: the GTPase-associated region (GAR) in domain II and the sarcin-ricin loop in domain VI. These two regions appear to collaborate in the factor-dependent events that occur during protein synthesis. Current X-ray crystallography of the ribosome shows an interaction between C1049 in the GAR and G2751 in domain VI. We have confirmed this interaction by site-directed mutagenesis and chemical probing. Disruption of this base pair affected not only the chemical modification of some bases in domains II and VI and in helix H89 of domain V, but also ribosome function dependent on both EF-G and EF-Tu. Mutant ribosomes carrying the C1049 to G substitution, which show enhancement of chemical modification at G2751, were used to probe the interactions between the regions around 1049 and 2751. Binding of EF-G-GDP-fusidic acid, but not EF-G-GMP-PNP, to the ribosome protected G2751 from modification. The G2751 protection was also observed after tRNA binding to the ribosomal P and E sites. The results suggest that the interactions between the bases around 1049 and 2751 alter during different stages of the translation process.

Three Binding Sites for Stalk Protein Dimers Are Generally Present in Ribosomes from Archaeal Organism

Ribosomes have a characteristic protuberance termed the stalk, which is indispensable for ribosomal function. The ribosomal stalk has long been believed to be a pentameric protein complex composed of two sets of protein dimers, L12-L12, bound to a single anchor protein, although ribosomes carrying three L12 dimers were recently discovered in a few thermophilic bacteria. Here we have characterized the stalk complex from Pyrococcus horikoshii, a thermophilic species of Archaea. This complex is known to be composed of proteins homologous to eukaryotic counterparts rather than bacterial ones. In truncation experiments of the C-terminal regions of the anchor protein Ph-P0, we surprisingly observed three Ph-L12 dimers bound to the C-terminal half of Ph-P0, and the binding site for the third dimer was unique to the archaeal homologs. The stoichiometry of the heptameric complex Ph-P0(Ph-L12)(2)(Ph-L12)(2)(Ph-L12)(2) was confirmed by mass spectrometry of the intact complex. In functional tests, ribosomes carrying a single Ph-L12 dimer had significant activity, but the addition of the second and third dimers increased the activity. A bioinformatics analysis revealed the evidence that ribosomes from all archaeal and also from many bacterial organisms may contain a heptameric complex at the stalk, whereas eukaryotic ribosomes seem to contain exclusively a pentameric stalk complex, thus modifying our view of the stalk structure significantly.

Structural Characterization of the Ribosomal P1A−P2B Protein Dimer by Small-Angle X-ray Scattering and NMR Spectroscopy

The five ribosomal P-proteins, denoted P0-(P1-P2)2, constitute the stalk structure of the large subunit of eukaryotic ribosomes. In the yeast Saccharomyces cerevisiae, the group of P1 and P2 proteins is differentiated into subgroups that form two separate P1A-P2B and P1B-P2A heterodimers on the stalk. So far, structural studies on the P-proteins have not yielded any satisfactory information using either X-ray crystallography or NMR spectroscopy, and the structures of the ribosomal stalk and its individual constituents remain obscure. Here we outline a first, coarse-grained view of the P1A-P2B solution structure obtained by a combination of small-angle X-ray scattering and heteronuclear NMR spectroscopy. The complex has an elongated shape with a length of 10 nm and a cross section of approximately 2.5 nm. 15N NMR relaxation measurements establish that roughly 30% of the residues are present in highly flexible segments, which belong primarily to the linker region and the C-terminal part of the polypeptide chain. Secondary structure predictions and NMR chemical shift analysis, together with previous results from CD spectroscopy, indicate that the structured regions involve alpha-helices. NMR relaxation data further suggest that several helices are arranged in a nearly parallel or antiparallel topology. These results provide the first structural comparison between eukaryotic P1 and P2 proteins and the prokaryotic L12 counterpart, revealing considerable differences in their overall shapes, despite similar functional roles and similar oligomeric arrangements. These results present for the first time a view of the structure of the eukaryotic stalk constituents, which is the only domain of the eukaryotic ribosome that has escaped successful structural characterization.

The Ribosomal Stalk Binds to Translation Factors IF2, EF-Tu, EF-G and RF3 via a Conserved Region of the L12 C-terminal Domain

Efficient protein synthesis in bacteria requires initiation factor 2 (IF2), elongation factors Tu (EF-Tu) and G (EF-G), and release factor 3 (RF3), each of which catalyzes a major step of translation in a GTP-dependent fashion. Previous reports have suggested that recruitment of factors to the ribosome and subsequent GTP hydrolysis involve the dimeric protein L12, which forms a flexible "stalk" on the ribosome. Using heteronuclear NMR spectroscopy we demonstrate that L12 binds directly to the factors IF2, EF-Tu, EF-G, and RF3 from Escherichia coli, and map the region of L12 involved in these interactions. Factor-dependent chemical shift changes show that all four factors bind to the same region of the C-terminal domain of L12. This region includes three strictly conserved residues, K70, L80, and E82, and a set of highly conserved residues, including V66, A67, V68 and G79. Upon factor binding, all NMR signals from the C-terminal domain become broadened beyond detection, while those from the N-terminal domain are virtually unaffected, implying that the C-terminal domain binds to the factor, while the N-terminal domain dimer retains its rotational freedom mediated by the flexible hinge between the two domains. Factor-dependent variations in linewidths further reveal that L12 binds to each factor with a dissociation constant in the millimolar range in solution. These results indicate that the L12-factor complexes will be highly populated on the ribosome, because of the high local concentration of ribosome-bound factor with respect to L12.

Heteronuclear NMR investigations of dynamic regions of intact Escherichia coli ribosomes

15N-(1)H NMR spectroscopy has been used to probe the dynamic properties of uniformly (15)N labeled Escherichia coli ribosomes. Despite the high molecular weight of the complex ( approximately 2.3 MDa), [(1)H-(15)N] heteronuclear single-quantum correlation spectra contain approximately 100 well resolved resonances, the majority of which arise from two of the four C-terminal domains of the stalk proteins, L7/L12. Heteronuclear pulse-field gradient NMR experiments show that the resonances arise from species with a translational diffusion constant consistent with that of the intact ribosome. Longitudinal relaxation time (T(1)) and T(1 rho) (15)N-spin relaxation measurements show that the observable domains tumble anisotropically, with an apparent rotational correlation time significantly longer than that expected for a free L7/L12 domain but much shorter than expected for a protein rigidly incorporated within the ribosomal particle. The relaxation data allow the ribosomally bound C-terminal domains to be oriented relative to the rotational diffusion tensor. Binding of elongation factor G to the ribosome results in the disappearance of the resonances of the L7/L12 domains, indicating a dramatic reduction in their mobility. This result is in agreement with cryoelectron microscopy studies showing that the ribosomal stalk assumes a single rigid orientation upon elongation factor G binding. As well as providing information about the dynamical properties of L7/L12, these results demonstrate the utility of heteronuclear NMR in the study of mobile regions of large biological complexes and form the basis for further NMR studies of functional ribosomal complexes in the context of protein synthesis.

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.

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.

Structural characterization of yeast acidic ribosomal P proteins forming the P1A-P2B heterocomplex

Acidic ribosomal P proteins form a distinct lateral protuberance on the 60S ribosomal subunit. In yeast, this structure is composed of two heterocomplexes (P1A-P2B and P1B-P2A) attached to the ribosome with the aid of the P0 protein. In solution, the isolated P proteins P1A and P2B have a flexible structure with some characteristics of a molten globule [Zurdo, J., et al. (2000) Biochemistry 39, 8935-8943]. In this report, the structure of P1A-P2B heterocomplex from Saccharomyces cerevisiae is investigated by means of size-exclusion chromatography, chemical cross-linking, circular dichroism, light scattering, and fluorescence spectroscopy. The circular dichroism experiment shows that the complex could be ranked in the tertiary class of all-alpha proteins, with an average alpha-helical content of approximately 65%. Heat and urea denaturation experiments reveal that the P1A-P2B complex, unlike the isolated proteins, has a full cooperative transition which can be fitted into a two-state folding-unfolding model. The behavior of the complex in the presence of 2,2,2-trifluoroethanol also resembles a two-state folding-unfolding transition, further supporting the idea that the heterocomplex contains well-packed side chains. In conclusion, the P1A-P2B heterocomplex, unlike the isolated proteins, has a well-defined hydrophobic core. Consequently, the complex can put up its structure without additional ribosomal components, so the heterodimeric complex reflects the intrinsic properties of the two analyzed proteins, indicating thus that this is the only possible configuration of the P1A and P2B proteins on the ribosomal stalk structure.

Ribosome as a molecular machine

General principles of structure and function of the ribosome are surveyed, and the translating ribosome is regarded as a molecular conveying machine. Two coupled conveying processes, the passing of compact tRNA globules and the drawing of linear mRNA chain through intraribosomal channel, are considered driven by discrete acts of translocation during translation. Instead of mechanical transmission mechanisms and power-stroke 'motors', thermal motion and chemically induced changes in affinities of ribosomal binding sites for their ligands (tRNAs, mRNA, elongation factors) are proposed to underlie all the directional movements within the ribosomal complex. The GTP-dependent catalysis of conformational transitions by elongation factors during translation is also discussed.

A decade of progress in understanding the structural basis of protein synthesis

The key reaction of protein synthesis, peptidyl transfer, is catalysed in all living organisms by the ribosome - an advanced and highly efficient molecular machine. During the last decade extensive X-ray crystallographic and NMR studies of the three-dimensional structure of ribosomal proteins, ribosomal RNA components and their complexes with ribosomal proteins, and of several translation factors in different functional states have taken us to a new level of understanding of the mechanism of function of the protein synthesis machinery. Among the new remarkable features revealed by structural studies, is the mimicry of the tRNA molecule by elongation factor G, ribosomal recycling factor and the eukaryotic release factor 1. Several other translation factors, for which three-dimensional structures are not yet known, are also expected to show some form of tRNA mimicry. The efforts of several crystallographic and biochemical groups have resulted in the determination by X-ray crystallography of the structures of the 30S and 50S subunits at moderate resolution, and of the structure of the 70S subunit both by X-ray crystallography and cryo-electron microscopy (EM). In addition, low resolution cryo-EM models of the ribosome with different translation factors and tRNA have been obtained. The new ribosomal models allowed for the first time a clear identification of the functional centres of the ribosome and of the binding sites for tRNA and ribosomal proteins with known three-dimensional structure. The new structural data have opened a way for the design of new experiments aimed at deeper understanding at an atomic level of the dynamics of the system.

Structural differences between Saccharomyces cerevisiae ribosomal stalk proteins P1 and P2 support their functional diversity

The eukaryotic acidic P1 and P2 proteins modulate the activity of the ribosomal stalk but playing distinct roles. The aim of this work was to analyze the structural features that are behind their different function. A structural characterization of Saccharomyces cerevisaie P1 alpha and P2 beta proteins was performed by circular dichroism, nuclear magnetic resonance, fluorescence spectroscopy, thermal denaturation, and protease sensitivity. The results confirm the low structure present in both proteins but reveal clear differences between them. P1 alpha shows a virtually unordered secondary structure with a residual helical content that disappears below 30 degrees C and a clear tendency to acquire secondary structure at low pH and in the presence of trifluoroethanol. In agreement with this higher disorder P1 alpha has a fully solvent-accessible tryptophan residue and, in contrast to P2 beta, is highly sensitive to protease degradation. An interaction between both proteins was observed, which induces an increase in the global secondary structure content of both proteins. Moreover, mixing of both proteins causes a shift of the P1 alpha tryptophan 40 signal, pointing to an involvement of this region in the interaction. This evidence directly proves an interaction between P1 alpha and P2 beta before ribosome binding and suggests a functional complementation between them. On a whole, the results provide structural support for the different functional roles played by the proteins of the two groups showing, at the same time, that relatively small structural differences between the two stalk acidic protein types can result in significant functional changes.

X-ray crystal structures of 70S ribosome functional complexes

Structures of 70S ribosome complexes containing messenger RNA and transfer RNA (tRNA), or tRNA analogs, have been solved by x-ray crystallography at up to 7.8 angstrom resolution. Many details of the interactions between tRNA and the ribosome, and of the packing arrangements of ribosomal RNA (rRNA) helices in and between the ribosomal subunits, can be seen. Numerous contacts are made between the 30S subunit and the P-tRNA anticodon stem-loop; in contrast, the anticodon region of A-tRNA is much more exposed. A complex network of molecular interactions suggestive of a functional relay is centered around the long penultimate stem of 16S rRNA at the subunit interface, including interactions involving the "switch" helix and decoding site of 16S rRNA, and RNA bridges from the 50S subunit.

Evolutionary analyses of the 12-kDa acidic ribosomal P-proteins reveal a distinct protein of higher plant ribosomes

The P-protein complex of eukaryotic ribosomes forms a lateral stalk structure in the active site of the large ribosomal subunit and is thought to assist in the elongation phase of translation by stimulating GTPase activity of elongation factor-2 and removal of deacylated tRNA. The complex in animals, fungi, and protozoans is composed of the acidic phosphoproteins P0 (35 kDa), P1 (11-12 kDa), and P2 (11-12 kDa). Previously we demonstrated by protein purification and microsequencing that ribosomes of maize (Zea mays L.) contain P0, one type of P1, two types of P2, and a distinct P1/P2 type protein designated P3. Here we implemented distance matrices, maximum parsimony, and neighbor-joining analyses to assess the evolutionary relationships between the 12 kDa P-proteins of maize and representative eukaryotic species. The analyses identify P3, found to date only in mono- and dicotyledonous plants, as an evolutionarily distinct P-protein. Plants possess three distinct groups of 12 kDa P-proteins (P1, P2, and P3), whereas animals, fungi, and protozoans possess only two distinct groups (P1 and P2). These findings demonstrate that the P-protein complex has evolved into a highly divergent complex with respect to protein composition despite its critical position within the active site of the ribosome.

Visualization of a large conformation change of ribosomes in Escherichia coli cells starved for tryptophan or treated with kirromycin

Computer-aided electron tomography has been used to visualize ribosomes in Escherichia coli cells treated with kirromycin. This antibiotic stops bacterial growth by blocking the release of EF-Tu. GDP from the ribosome after GTP cleavage. Ribosomes in the kirromycin-treated cells are very compact, with the two subunits in close contact with each other. This closed structure is different from the open structure with spatially separated subunits that characterizes ribosomes in tryptophan-starved cells, giving deficiency for tryptophanyl.tRNA. A comparison of ribosomes in exponentially growing bacteria suggests that most ribosomes in an undefined working mode are in the closed conformation.

Cross-linking of selected residues in the N- and C-terminal domains of Escherichia coli protein L7/L12 to other ribosomal proteins and the effect of elongation factor Tu

Five different variants of protein L7/L12, each with a single cysteine substitution at a selected site, were produced, modified with 125I-N-[4-(p-azidosalicylamido)-butyl]-3-(2'-pyridyldithio)propion amide, a radiolabeled, sulfhydryl-specific, heterobifunctional, cleavable photocross-linking reagent that transfers radiolabel to the target molecule upon reduction of the disulfide bond. The proteins were reconstituted with core particles depleted of wild type L7/L12 to yield 70 S ribosomes. Cross-linked molecules were identified and quantified by the radiolabel. No cross-linking of RNA was detected. Two sites in the dimeric N-terminal domain, Cys-12 and Cys-33, cross-linked strongly to L10 and in lower yield to L11 but to no other proteins. The three sites in the globular C-terminal domain all cross-linked strongly to L11 and, in lower yield, to L10. Weaker cross-linking to 50 S proteins L2 and L5 occurred from all three C-terminal domain locations. The 30 S ribosomal proteins S2, S3, S7, S14, S18 were also cross-linked from all three of these sites. Binding of the ternary complex [14C]Phe-tRNA-elongation factor Tu.guanyl-5'-yl imidodiphosphate) but not [14C]Phe-tRNA.elongation factor Tu.GDP.kirromycin increased labeling of L2, L5, and all of the 30 S proteins. These results imply the flexibility of L7/L12 and the transient proximity of three surfaces of the C-terminal domain with the base of the stalk, the peptidyl transferase domain, and the head of the 30 S subunit.

The exchangeable yeast ribosomal acidic protein YP2beta shows characteristics of a partly folded state under physiological conditions

The eukaryotic acidic ribosomal P proteins, contrary to the standard r-proteins which are rapidly degraded in the cytoplasm, are found forming a large cytoplasmic pool that exchanges with the ribosome-bound proteins during translation. The native structure of the P proteins in solution is therefore an essential determinant of the protein-protein interactions that take place in the exchange process. In this work, the structure of the ribosomal acidic protein YP2beta from Saccharomyces cerevisiae has been investigated by fluorescence spectroscopy, circular dichroism (CD), nuclear magnetic resonance (NMR), and sedimentation equilibrium techniques. We have established the fact that YP2beta bears a 22% alpha-helical secondary structure and a noncompact tertiary structure under physiological conditions (pH 7.0 and 25 degrees C); the hydrophobic core of the protein appears to be solvent-exposed, and very low cooperativity is observed for heat- or urea-induced denaturation. Moreover, the 1H-NMR spectra show a small signal dispersion, and virtually all the amide protons exchange with the solvent on a very short time scale, which is characteristic of an open structure. At low pH, YP2beta maintains its secondary structure content, but there is no evidence for tertiary structure. 2,2,2-Trifluoroethanol (TFE) induces a higher amount of alpha-helical structure but also disrupts any trace of the remaining tertiary fold. These results indicate that YP2beta may have a flexible structure in the cytoplasmic pool, with some of the characteristics of a "molten globule", and also point out the physiological relevance of such flexible protein states in processes other than protein folding.

Localization of two domains of a mutant form of Escherichia coli protein L7/L12 that binds the large ribosomal subunit as a single dimer

Escherichia coli ribosomal protein L7/L12 occurs on the large subunit as two dimers: one dimer is extended and comprises the stalk, while the second dimer is folded and occupies a site on the subunit body. A variant protein, in which all 18 amino acids of the flexible hinge region that links separate N-terminal and C-terminal domains of L7/L12 has been deleted, binds the subunit as a single dimer and does not generate stalks that are visible in electron micrographs. Monoclonal antibodies directed against each domain of the protein have been used to localize the variant in electron micrographs of 50S subunits. Both C-terminal domains are seen at a shoulder of the subunit, near its edge as viewed in the most common quasisymmetric projection. N-terminal domains are placed on the subunit body, about 50 A from the C-terminal domains. The antibody to the N-terminal domain also causes dissociation of the variant dimer from the particle and the formation of oligomeric antibody-protein dimer complexes. Similar complexes were seen previously (Olson HM et al (1986) J Biol Chem 261, 6924-6936) when this antibody induced dissociation of one dimer of the native protein. We conclude that the shortened variant most probably occupies the lower-affinity site on the subunit that is normally filled by the stalk dimer.

The L7/L12 ribosomal domain of the ribosome: structural and functional studies

The L7/L12 protein forms a functionally important domain in the ribosome. This domain is involved in interaction with translation factors during protein biosynthesis. The tertiary and quaternary structure of the L7/L12 protein was established as a result of intensive studies in solution and in the ribosome. The conformational changes of L7/L12, the elongation factors Tu and G and other ribosomal proteins were traced by different experimental techniques. These changes occur upon interaction of the ribosome with the elongation factors and depend on GTP hydrolysis in accordance with the functional states of the ribosome.

Rotational and conformational dynamics of Escherichia coli ribosomal protein L7/L12

Fluorescence methods were utilized to study dynamic aspects of the 24 kDa dimeric Escherichia coli ribosomal protein L7/L12. Oligonucleotide site-directed mutagenesis was used to introduce cysteine residues at specific locations along the peptide chain, in both the C-terminal and N-terminal domains, and various sulfhydryl reactive fluorescence probes (iodoacetamido) fluorescein, IAEDANS, pyrenemethyl iodoacetate) were attached to these residues. In addition to the full-length proteins, a hinge-deleted variant and variants corresponding to the C-terminal fragment and the N-terminal fragment were also studied. Both steady-state and time-resolved fluorescence measurements were carried out, and the results demonstrated that L7/L12 is not a rigid molecule. Specifically, the two C-terminal domains move freely with respect to one another and with respect to the dimeric N-terminal domain. Removal of the hinge region, however, significantly reduces the mobility of the C-terminal domains. The data also show that the rotational relaxation time monitored by the fluorescent probe-depends upon the probe's excited state lifetime. This observation is interpreted to indicate that a hierarchy of motions exists in the L7/L12 molecule including facile motions of the C-terminal domains and dimeric N-terminal domain, in addition to the overall tumbling of the protein. Probes attached to the N-terminal domain exhibit global rotational relaxation times consistent with the molecular mass of the dimeric N-terminal fragment. Upon reconstitution of labeled L7/L12 with ribosomal cores, however, the motion associated with the dimeric N-terminal domain is greatly diminished while the facile motion of the C-terminal domains is almost unchanged.

Tetramethylrhodamine dimer formation as a spectroscopic probe of the conformation of Escherichia coli ribosomal protein L7/L12 dimers

The fluorescent probe tetramethylrhodamine iodoacetamide was attached to cysteine residues substituted at various specific locations in full-length and deletion variants of the homodimeric Escherichia coli ribosomal protein L7/L12. Ground-state tetramethylrhodamine dimers form between the two subunits of L7/L12 depending upon the location of the probe. The formation of tetramethylrhodamine dimers caused the appearance of a new absorption band at 518 nm that was used to estimate the extent of interaction of the probes in the different protein variants. Intersubunit tetramethylrhodamine dimers form when tetramethylrhodamine acetamide is attached to two different sites in the N-terminal domain of the L7/L12 dimer (residues 12 or 33), but not when attached to sites in the C-terminal domain (residues 63, 89, or 99). The tetramethylrhodamine dimers do form at sites in the C-terminal domain in L7/L12 variants that contain deletions of 11 or 18 residues within the putative flexible hinge that separates the N- and C-terminal domains. The tetramethylrhodamine dimers disappear rapidly (within 5 s) upon addition of excess unlabeled wild-type L7/L12. It appears that singly labeled L7/L12 dimers are formed by exchange with wild-type dimers. Binding of L7/L12:tetramethylrhodamine cysteine 33 or cysteine 12 dimers either to L7/L12-depleted ribosomal core particles, or to ribosomal protein L10 alone, results in disappearance of the 518-nm absorption band. This result implies a conformational change in the N-terminal domain of L7/L12 upon its binding to the ribosome, or to L10.

Location and domain structure of Escherichia coli ribosomal protein L7/L12: site specific cysteine crosslinking and attachment of fluorescent probes

Five different variants of L7/L12 containing single cysteine substitutions, two in the N-terminal (NTD) and three in the C-terminal domain (CTD), were produced, modified with [125I]N-[4-(p-azidosalicylamido)butyl]-3-(2'-pyridyldithio) propionamide ([125I]APDP), a sulfhydryl-specific, heterobifunctional, cleavable photo-cross-linking reagent, and reconstituted into ribosomes. These were irradiated, the total proteins were extracted and reductively cleaved, and the cross-linked proteins were identified. The effect of zero-length disulfide cross-linking on binding and activity was also determined. The same sites in L7/L12 were used to attach a rhodamine dye. The formation of ground-state rhodamine dimers caused the appearance of a new absorption band at 518 nm that was used to estimate the extent of interaction of the probes in the free protein and in complexes with L10. The three sites in the CTD, but not the N-terminal sites, cross-linked to L2 and L5 and to 30S proteins S2, S3, S7, S14, and S18 in a manner influenced by elongation factors. Binding to the ribosome and, therefore, function were blocked by zero-length cross-linking within the NTD, but not the CTD. Binding also disrupted rhodamine dimers in the NTD. No rhodamine dimers formed in the CTD.

The highly conserved protein P0 carboxyl end is essential for ribosome activity only in the absence of proteins P1 and P2

Protein P0 together with proteins P1 and P2 form the stalk in eukaryotic ribosomes. P0 has a carboxyl-terminal domain about 100 amino acids long that has high sequence similar to the ribosomal proteins P1 and P2. By sequential deletion of this region, a series of Saccharomyces cerevisiae truncated P0 genes have been constructed that encode proteins lacking 21, 87, and 132 amino acids from the carboxyl terminus, respectively. These constructions have been used to transform yeast P0 conditional null mutants to test their capacity to restore cell growth. Removal of only the last 21 amino acids causes a small effect on cell growth in wild-type strains; however, this deletion is lethal in strains having P protein-deficient ribosomes. A P0 lacking 87 amino acids allows cell growth at a low rate, and ribosomes bind P proteins with much less affinity. Lastly, removal of 132 amino acids totally inactivates P0; this deleted protein is unable to bind to the particles, causing a deficiency in active 60 S subunits and making the cell nonviable. These results indicate that at least one out of the five protein P-like carboxyl termini present in the ribosome has to be firmly bound to the particle for protein synthesis and cell viability, and this structure can be provided by protein P0. The part of P0 from around positions 230-290 is important for the interaction of proteins P1/P2 with the ribosome, but it is not essential for protein synthesis. Finally, the region including from residues 185 to 230 is required for the interaction of P0 with the rRNA.

Zero-length cross-linking of the C-terminal domain of Escherichia coli ribosomal protein L7/L12 to L10 in the ribosome and in the (L7/L12)4-L10 pentameric complex

L7/L12Cys89 is a variant of L7/L12 that has a single cysteine residue located in the C-terminal domain in which Cys89 is the only cysteine residue in the protein. A cross-link between this site and the single cysteine in L10, residue 70, was formed with 1,4-di[3'-(2'-pyridyldithio)-propionamido]butane, a sulfhydryl-specific homobifunctional reagent of maximum length 16 A. It is now shown that a zero-length disulfide cross-link between L7/L12Cys89 and L10Cys70 is formed by mild oxidation with Cu2+(phenanthroline)3 of either intact ribosomes or the stable, pentameric complex (L7/L12)4-L10. The formation of the zero-length cross-link defines more closely the contact between the two proteins. Protein L10 is located at the base of the L7/L12 stalk where it provides binding sites for the N-terminal domains of both dimers of L7/L12. The L7/L12Cys89-L10Cys70 cross-link lends further support to our previous model that places at least one of the two dimers of L7/L12 on the surface of the body of the 50S subunit in a bent conformation with the C-terminal domain in close proximity to its N-terminal domain, at the base of the L7/L12 stalk. The L7/L12Cys89-L10Cys70 cross-link in the pentameric L8 complex implies that the protein can exist in this bent conformation there as well as in the ribosome.

The length of the interdomain region of the L7/L12 protein is important for its function

Several mutated L7/L12 proteins with changed interdomain regions were obtained. The results showed that the flexible region comprising the 39-52 amino acid residues is functionally important. Its length, but not its amino acid composition, is crucial for the function.

Functional aspects of ribosomal proteins

A short personal recollection of HG Wittmann is given with emphasis on his basic contribution to the structure of the ribosome, in particular the ribosomal proteins. With these considerations in mind, two interrelated problems are reviewed here. The first relates to the internal symmetry both in tRNA and in the tetrameric L12-protein complex. The second problem to be addressed relates to the dynamics of transfer RNA in the ribosome and the role of L12 proteins in this process. The importance of electrostatic repulsion in the maintenance of the mutual spatial orientation of tRNAs and L12 in the ribosome is emphasized in relation to a pendulum model for how L12 may steer translocation.

Sequence alignment and evolutionary comparison of the L10 equivalent and L12 equivalent ribosomal proteins from archaebacteria, eubacteria, and eucaryotes

The genes corresponding to the L10 and L12 equivalent ribosomal proteins (L10e and L12e) of Escherichia coli have been cloned and sequenced from two widely divergent species of archaebacteria, Halobacterium cutirubrum and Sulfolobus solfataricus. The deduced amino acid sequences of the L10e and L12e proteins have been compared to each other and to available eubacterial and eucaryotic sequences. We have identified the human P0 protein as the eucaryotic L10e. The L10e proteins from the three kingdoms were found to be colinear. The eubacterial L10e protein is much shorter than the archaebacterial-eucaryotic proteins because of two large deletions, one internal and one at the carboxy terminus. The archaebacterial and eucaryotic L12e proteins were also colinear; the eubacterial protein is homologous to the archaebacterial and eucaryotic L12e proteins, but has suffered rearrangement through what appear to be gene fusion events. Intraspecies comparisons between L10e and L12e sequences indicate the archaebacterial and eucaryotic L10e proteins contain a partial copy of the L12e protein fused to their carboxy terminus. In the eubacteria most of this fusion has been removed by the carboxy terminal deletion. Within the L12e-derived region, a 26-amino acid-long internal modular sequence reiterated thrice in the archaebacterial L10e, twice in the eucaryotic L10e, and once in the eubacterial L10e was discovered. This modular sequence also appears to be present as a single copy in all L12e proteins and may play a role in L12e dimerization, L10e-L12e complex formation, and the function of L10e-L12e complex in translation.(ABSTRACT TRUNCATED AT 250 WORDS)

Immunoblotting analysis of protein-protein crosslinks within the 50S ribosomal subunit of Escherichia coli. A study using dimethylsuberimidate as crosslinking reagent

50S ribosomal subunits of Escherichia coli have been crosslinked with the bifunctional imidoester dimethyl-suberimidate and the protein-protein crosslinks have been analyzed by immunoblotting, using antisera specific for the individual ribosomal proteins of the large ribosomal subunit. Crosslinked protein pairs which occurred in yields higher than 5% have been unambiguously identified. Thus 13 crosslinks have been identified, namely L1-L33, L5-L7/12, L6-L19, L7/12-L10, L7/12-L11, L9-L28, L10-L11, L13-L20, L16-L27, L17-L32, L18-L22, L19-L25 and L27-L33. These data, together with the results which we will be presenting elsewhere, contribute considerably to our knowledge of the protein topography of the 50S ribosomal proteins as determined by immunoelectron microscopy. We can now propose the approximate locations of ten proteins that have not previously been localized.

Nuclear magnetic resonance techniques for studying structure and function of ribosomes

The following conclusions can be drawn from the use of NMR techniques for studies of ribosomes: 1. The majority of ribosomal proteins are rigidly fixed within the particles, and the most mobile components in the isolated ribosome are L7/L12 proteins from the large subunit. 2. Interaction of EF-G with ribosomes results in some changes in ribosomal domains, and, particularly, immobilization of L7/L12 proteins takes place. The changes may pertain to the translocation reaction, since complexes with ribosomes, EF-G, and GTP are functional. The results of these studies using 1H NMR show that structural studies with this technique are limited as only a few proteins express their resonances in the 1H NMR spectra (S1, L7/L12). At the same time such studies are not exhaustive, since only the simplest samples were studied (ribosomes, the ribosomal complex with EF-G). Complexes with other ligands (tRNA, EF-Tu) have not yet been studied. It is also possible to enhance the resolution of 1H NMR techniques with the help of deuterated factors, ribosomes, and proteins, and to adapt the use of NMR to other nuclei (e.g., the use of fluorinated labels or incorporation of fluoroamino acids into the proteins). Many other approaches using NMR in biology have still to be explored. Therefore it is hoped that the use of NMR techniques will prove to be very useful in studies of the different functional steps of protein biosynthesis.

Characteristic views of prokaryotic 50S ribosomal subunits

Multivariate statistical analysis and classification techniques are powerful tools in sorting noisy electron micrographs of single particles according to their principal features, enabling one to form average images with an enhanced signal-to-noise ratio and a better reproducible resolution. We apply this methodology here to determining the characteristic views of the large (50S) ribosomal subunits from the eubacterium Escherichia coli and the archaebacteria Methanococcus vannielii, Sulfolobus solfataricus, and Halobacterium marismortui. Average images were obtained of the subunit in the common crown and kidney projections, but views of the particle in orientations intermediate between these two extremes were also elucidated for all species. These averages show reproducible detail of up to 2.0 nm resolution, thus enabling the visualization and interspecies comparison of many structural features as a first step toward comparing the actual three-dimensional structures. Our results disprove evolutionary lineages recently postulated on the basis of electron microscopical images of ribosomal subunits.

The structure and dynamics of ribosomal protein L12

The protein L12 in bacterial ribosomes is essential for the proper function of a number of factors involved in protein synthesis. The protein is mostly described in terms of a rigid structure despite the repeated observation of high flexibility. This paper gives a review of the structure and flexibility of L12 in relation to its function.

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.