Protein Topography of Ribosomal Functional Domains: Effects of Monoclonal Antibodies to Different Epitopes in Escherichia coli Protein L7/L12 on Ribosome Function and Structure

MrpL36p, a highly diverged L31 ribosomal protein homolog with additional functional domains in Saccharomyces cerevisiae mitochondria

Translation in mitochondria utilizes a large complement of ribosomal proteins. Many mitochondrial ribosomal components are clearly homologous to eubacterial ribosomal proteins, but others appear unique to the mitochondrial system. A handful of mitochondrial ribosomal proteins appear to be eubacterial in origin but to have evolved additional functional domains. MrpL36p is an essential mitochondrial ribosomal large-subunit component in Saccharomyces cerevisiae. Increased dosage of MRPL36 also has been shown to suppress certain types of translation defects encoded within the mitochondrial COX2 mRNA. A central domain of MrpL36p that is similar to eubacterial ribosomal large-subunit protein L31 is sufficient for general mitochondrial translation but not suppression, and proteins bearing this domain sediment with the ribosomal large subunit in sucrose gradients. In contrast, proteins lacking the L31 domain, but retaining a novel N-terminal sequence and a C-terminal sequence with weak similarity to the Escherichia coli signal recognition particle component Ffh, are sufficient for dosage suppression and do not sediment with the large subunit of the ribosome. Interestingly, the activity of MrpL36p as a dosage suppressor exhibits gene and allele specificity. We propose that MrpL36p represents a highly diverged L31 homolog with derived domains functioning in mRNA selection in yeast mitochondria.

Crystal structure of ribosomal protein L27 from Thermus thermophilus HB8

Ribosomal protein L27 is located near the peptidyltransferase center at the interface of ribosomal subunits, and is important for ribosomal assembly and function. We report the crystal structure of ribosomal protein L27 from Thermus thermophilus HB8, which was determined by the multiwavelength anomalous dispersion method and refined to an R-factor of 19.7% (R(free) = 23.6%) at 2.8 A resolution. The overall fold is an all beta-sheet hybrid. It consists of two sets of four-stranded beta-sheets formed around a well-defined hydrophobic core, with a highly positive charge on the protein surface. The structure of ribosomal protein L27 from T. thermophilus HB8 in the RNA-free form is investigated, and its functional roles in the ribosomal subunit are discussed.

Characterization of Escherichia coli 50S ribosomal protein L31

The published C-terminal sequence of Escherichia coli 50S ribosomal protein L31, ellipsisRFNK (Brosius, J. (1978) Biochemistry 17, 501-508), differs from that predicted by the gene sequence, ellipsisRFNKRFNIPGSK (GenBank accession no. X78541). This discrepancy might be due to post-translational processing of the protein. To examine this possibility, we have isolated L31 from E. coli strain MRE600 and sequenced the C-terminal tryptic peptide. We find the sequence to be FBIPGSK. Size comparisons of L31 from several E. coli strains demonstrate that all are identical in size to the protein isolated from MRE600 and larger than the previously described protein, indicating that ellipsisRFNKRFNIPGSK represents the true C-terminus of L31. In addition, we show that the failure to identify L31 in many ribosome preparations is probably due to the protein's loose association with the ribosome and its ability to form various intramolecular disulfide bonds, leading to L31 forms with distinct mobilities in gels.

Placement of protein and RNA structures into a 5 A-resolution map of the 50S ribosomal subunit

We have calculated at 5.0 A resolution an electron-density map of the large 50S ribosomal subunit from the bacterium Haloarcula marismortui by using phases derived from four heavy-atom derivatives, intercrystal density averaging and density-modification procedures. More than 300 base pairs of A-form RNA duplex have been fitted into this map, as have regions of non-A-form duplex, single-stranded segments and tetraloops. The long rods of RNA crisscrossing the subunit arise from the stacking of short, separate double helices, not all of which are A-form, and in many places proteins crosslink two or more of these rods. The polypeptide exit channel was marked by tungsten cluster compounds bound in one heavy-atom-derivatized crystal. We have determined the structure of the translation-factor-binding centre by fitting the crystal structures of the ribosomal proteins L6, L11 and L14, the sarcin-ricin loop RNA, and the RNA sequence that binds L11 into the electron density. We can position either elongation factor G or elongation factor Tu complexed with an aminoacylated transfer RNA and GTP onto the factor-binding centre in a manner that is consistent with results from biochemical and electron microscopy studies.

Conformational variability in Escherichia coli 70S ribosome as revealed by 3D cryo-electron microscopy

During protein biosynthesis, ribosomes are believed to go through a cycle of conformational transitions. We have identified some of the most variable regions of the E. coli 70S ribosome and its subunits, by means of cryo-electron microscopy and three-dimensional (3D) reconstruction. Conformational changes in the smaller 30S subunit are mainly associated with the functionally important domains of the subunit, such as the neck and the platform, as seen by comparison of heat-activated, non-activated and 50S-bound states. In the larger 50S subunit the most variable regions are the L7/L12 stalk, central protuberance and the L1-protein, as observed in various tRNA-70S ribosome complexes. Difference maps calculated between 3D maps of ribosomes help pinpoint the location of ribosomal regions that are most strongly affected by conformational transitions. These results throw direct light on the dynamic behavior of the ribosome and help in understanding the role of these flexible domains in the translation process.

Visualization of elongation factor G on the Escherichia coli 70S ribosome: the mechanism of translocation

During protein synthesis, elongation factor G (EF-G) binds to the ribosome and promotes the step of translocation, a process in which tRNA moves from the A to the P site of the ribosome and the mRNA is advanced by one codon. By using three-dimensional cryo-electron microscopy, we have visualized EF-G in a ribosome-EF-G-GDP-fusidic acid complex. Fitting the crystal structure of EF-G-GDP into the cryo density map reveals a large conformational change mainly associated with domain IV, the domain that mimics the shape of the anticodon arm of the tRNA in the structurally homologous ternary complex of Phe-tRNAPhe, EF-Tu, and a GTP analog. The tip portion of this domain is found in a position that overlaps the anticodon arm of the A-site tRNA, whose position in the ribosome is known from a study of the pretranslocational complex, implying that EF-G displaces the A-site tRNA to the P site by physical interaction with the anticodon arm.

Carboxyl-terminal amino acid residues in elongation factor G essential for ribosome association and translocation

The translocation of ribosomes on mRNA is carried out by cellular machinery that has been extremely well conserved across the entire spectrum of living species. This process requires elongation factor G (EF-G, or EF-2 in archaebacteria and eukaryotes), which is a member of the GTPase superfamily. Using genetic techniques, we have identified a series of mutated alleles of fusA (the Escherichia coli gene that encodes EF-G) that were unable to support protein synthesis in vivo. These alleles encode proteins with point mutations at codons 495 (a variant with a Q-to-P change at codon 495 [Q495P]), 502 (G502D), and 563 (G563D) and a nonsense mutation at codon 608. Biochemical analyses demonstrated that EF-G Q495P, G502D, and delta 608-703 were not disrupted in guanine nucleotide binding but were deficient in ribosome-dependent GTP hydrolysis and guanine nucleotide-dependent ribosome association. We propose that all of these mutations are present in a domain that is essential for ribosome association and that GTP hydrolysis was deficient as a secondary consequence of impaired binding to 70S ribosomes.

Structural dynamics of translating ribosomes: 16S ribosomal RNA bases that may move twice during translocation

Recent footprinting, sedimentation and neutron-scattering results obtained in vivo or on pre-translocation and post-translocation ribosomal complexes are integrated with cross-linking and immunoelectron microscopy information. It is proposed that the 30S subunit pulses during translocation and that its pre- and post-translocation structures are not necessarily identical. Accordingly, translocation is characterized by three consecutive conformational states of the 30S and 50S subunits. State 1 (the pre-translocation state) lasts until the elongation factor EF-G.GTP complex binds to the ribosome or adopts the GTPase conformation. State 2 (the translocation state, or the peak or plateau of the pulse) follows and lasts until EF-G adopts a subsequent conformation or is released from the ribosome. State 3 (the post-translocation state) ensues and lasts until A (aminoacyl) site binding of aminoacyl-tRNA. In state 2, 16S RNA hairpins 26 and 33-33A, located in the platform and the head of the 30S subunit, respectively, become kinked or twisted, and residue A1503, near the decoding site, becomes exposed. A platform twist is associated with P (peptide) to E (exit) site tRNA movements and a head twist with pivoting of the peptidyl-tRNA elbow from the A to the P site, around a (retractable?) S19 domain. These twists result in an unlocking of the platform and the head from the 50S subunit. Exposure of A1503 is tentatively associated with movements of mRNA or tRNA anticodon stem-loops. These twisted or otherwise-exposed residues readopt their previous setting upon completion of translocation, i.e. states 1 and 3 of 16S RNA differ more from state 2 than from each other.(ABSTRACT TRUNCATED AT 250 WORDS)

In vivo selection of conditional-lethal mutations in the gene encoding elongation factor G of Escherichia coli

The ribosome translocation step that occurs during protein synthesis is a highly conserved, essential activity of all cells. The precise movement of one codon that occurs following peptide bond formation is regulated by elongation factor G (EF-G) in eubacteria or elongation factor 2 (EF-2) in eukaryotes. To begin to understand molecular interactions that regulate this process, a genetic selection was developed with the aim of obtaining conditional-lethal alleles of the gene (fusA) that encodes EF-G in Escherichia coli. The genetic selection depends on the observation that resistant strains arose spontaneously in the presence of sublethal concentrations of the antibiotic kanamycin. Replica plating was performed to obtain mutant isolates from this collection that were restrictive for growth at 42 degrees C. Two tightly temperature-sensitive strains were characterized in detail and shown to harbor single-site missense mutations within fusA. The fusA100 mutant encoded a glycine-to-aspartic acid change at codon 502. The fusA101 allele encoded a glutamine-to-proline alteration at position 495. Induction kinetics of beta-galactosidase activity suggested that both mutations resulted in slower elongation rates in vivo. These missense mutations were very near a small group of conserved amino acid residues (positions 483 to 493) that occur in EF-G and EF-2 but not EF-Tu. It is concluded that these sequences encode a specific domain that is essential for efficient translocase function.

Localization of surface peptide from ribosomal protein L7 on 80 S ribosome by biotinylation

A surface topography of ribosomal peptides on ribosome particles was conducted by using N',Hydroxysuccinimido-biotin (NHS-biotin) modification. All rat ribosomal proteins, except proteins L3 and L8, are biotinylated when the ribosome particle is the substrate. A surface peptide from protein L7 was determined from biotinylated ribosomes by high performance liquid chromatography and cyanogen bromide peptide mapping. It was found that only the tandem repeats of the NH2-terminal segment of protein L7 are accessible to biotinylation. It is concluded that the NH2-terminal-end of protein L7 should be exposed on the surface of ribosomal particles.

Characterization of the yeast acidic ribosomal phosphoproteins using monoclonal antibodies. Proteins L44/L45 and L44' have different functional roles

In order to characterize the acidic ribosomal proteins immunologically and functionally, a battery of monoclonal antibodies specific for L44, L44' and L45, the three acidic proteins detected in Saccharomyces cerevisiae, were obtained. Eight monoclonal antibodies were obtained specific for L45, three for L44' and one for L44. In addition, two mAbs recognizing only the phosphorylated forms of the three proteins were obtained. The specific immunogenic determinants are located in the middle region of the protein structure and are differently exposed in the ribosomal surface. The common determinants are present in the carboxyl end of the three proteins. An estimation of the acidic proteins by ELISA indicated that, in contrast to L44 and L45, L44' is practically absent from the cell supernatant; this suggests that protein L44' does not intervene in the exchange that has been shown to take place between the acidic proteins in the ribosome and in the cytoplasmic pool. It has also been found that, while IgGs specific for L44 and L45 do not inhibit the ribosome activity, the anti-L44' effectively blocks the polymerizing activity of the particles. These results show for the first time that the different eukaryotic acidic ribosomal proteins play a different functional role.

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)

Subunit association defects in Escherichia coli ribosome mutants lacking proteins S20 and L11

The subunit association capacity of 30S and 50S ribosomal subunits from Escherichia coli mutants lacking protein S20 or L11 as well as of 50S subunits depleted of L7/L12 was tested by sucrose gradient centrifugation and by a nitrocellulose filtration method based on the protection from hydrolysis with peptidyl-tRNA hydrolase of ribosome-bound AcPhe-tRNA. It was found that the subunits lacking either S20 or L11 display an altered association capacity, while the 50S subunits lacking L7/L12 have normal association behavior. The association of S20-lacking 30S subunits is quantitatively reduced, especially at low Mg2+ concentrations (5-12 mM), and produces loosely interacting particles which dissociate during sucrose gradient centrifugation. The association of L11-lacking 50S subunits is quantitatively near-normal at all Mg2+ concentrations and produces loosely associating particles only at low Mg2+ concentrations (5-8 mM); the mechanism of their association with 30S subunits, however, or the structure of the resulting 30S-50S couples is altered in such a way as to cause the ejection of an AcPhe-tRNA molecule pre-bound to the 30S subunits in response to poly(U).

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.

Three-dimensional location of ribosomal protein BL2 from Bacillus stearothermophilus, a key component of the peptidyl transferase center

Protein BL2 from Bacillus stearothermophilus has been localized by immunoelectron microscopy on the interface side of the 50 S subunit, beneath the angle formed between the central protuberance and the L1 protuberance. The immuno-electron microscopic data suggest that the interface region of the 50 S particle is not as flat as most of the proposed three-dimensional models suggest, but instead there is a significant concavity. Since several studies demonstrated that BL2 is implicated in peptidyl transferase activity or at least located close to the peptidyl transferase center, the location of protein BL2 also provides information as to the location of this important functional domain.

The ribosome returns

Fashions come and go in biochemistry. The discovery that some RNAs are enzymes is reviving interest in the long-neglected ribosome.

Semi-preparative HPLC purification of ribosomal proteins from Bacillus stearothermophilus and sequence determination of the highly conserved protein S19

Several proteins from the Bacillus stearothermophilus 30S ribosomal subunit which could not be isolated by conventional open-column chromatography were purified by high-performance liquid chromatography using a semi-preparative reverse-phase C4 column. Protein S19 was purified by this technique and the complete amino acid sequence determined. Protein S19 was fragmented and the peptides isolated in picomole quantities were sequenced by an improved manual 4-N,N-dimethylaminoazobenzene-4'-isothiocyanate (DABITC) technique; the presence of five consecutive C-terminal lysines in the S19 sequence was confirmed by gas-phase sequencing and fast-atom-bombardment (FAB) mass spectrometry. Protein S19 is composed of 91 amino acid residues which correspond to a molecular mass of 10,428 Da. 71% of the B. stearothermophilus S19 sequence was found to be identical with the corresponding ribosomal protein from Escherichia coli [Yaguchi and Wittmann (1978), FEBS Lett. 88, 227] and both sequences can be aligned without gaps. Among the known 26 amino acid sequences of the B. stearothermophilus and E. coli ribosome such a high degree of conservation has only been observed for a few proteins, all of which are known to be involved in the protein biosynthesis process. Although a clear function has not yet been assigned to protein S19, its high sequence conservation in these two eubacteria clearly indicates an important role of this protein for the function of the ribosome.