The primary structure of protein S5 from the small subunit of the Escherichia coli ribosome

Ribosomal protein S18 acetyltransferase RimI is responsible for the acetylation of elongation factor Tu

N-terminal acetylation is widespread in the eukaryotic proteome but in bacteria is restricted to a small number of proteins mainly involved in translation. It was long known that elongation factor Tu (EF-Tu) is N-terminally acetylated, whereas the enzyme responsible for this process was unclear. Here, we report that RimI acetyltransferase, known to modify ribosomal protein S18, is likewise responsible for N-acetylation of the EF-Tu. With the help of inducible tufA expression plasmid, we demonstrated that the acetylation does not alter the stability of EF-Tu. Binding of aminoacyl tRNA to the recombinant EF-Tu in vitro was found to be unaffected by the acetylation. At the same time, with the help of fast kinetics methods, we demonstrate that an acetylated variant of EF-Tu more efficiently accelerates A-site occupation by aminoacyl-tRNA, thus increasing the efficiency of in vitro translation. Finally, we show that a strain devoid of RimI has a reduced growth rate, expanded to an evolutionary timescale, and might potentially promote conservation of the acetylation mechanism of S18 and EF-Tu. This study increased our understanding of the modification of bacterial translation apparatus.

RbfA Is Involved in Two Important Stages of 30S Subunit Assembly: Formation of the Central Pseudoknot and Docking of Helix 44 to the Decoding Center

Ribosome biogenesis is a highly coordinated and complex process that requires numerous assembly factors that ensure prompt and flawless maturation of ribosomal subunits. Despite the increasing amount of data collected, the exact role of most assembly factors and mechanistic details of their operation remain unclear, mainly due to the shortage of high-resolution structural information. Here, using cryo-electron microscopy, we characterized 30S ribosomal particles isolated from an Escherichia coli strain with a deleted gene for the RbfA factor. The cryo-EM maps for pre-30S subunits were divided into six classes corresponding to consecutive assembly intermediates: from the particles with a completely unresolved head domain and unfolded central pseudoknot to almost mature 30S subunits with well-resolved body, platform, and head domains and partially distorted helix 44. The structures of two predominant 30S intermediates belonging to most populated classes obtained at 2.7 Å resolutions indicate that RbfA acts at two distinctive 30S assembly stages: early formation of the central pseudoknot including folding of the head, and positioning of helix 44 in the decoding center at a later stage. Additionally, it was shown that the formation of the central pseudoknot may promote stabilization of the head domain, likely through the RbfA-dependent maturation of the neck helix 28. An update to the model of factor-dependent 30S maturation is proposed, suggesting that RfbA is involved in most of the subunit assembly process.

Modulation of the bacterial CobB sirtuin deacylase activity by N-terminal acetylation

In eukaryotic cells, the N-terminal amino moiety of many proteins is modified by N-acetyltransferases (NATs). This protein modification can alter the folding of the target protein; can affect binding interactions of the target protein with substrates, allosteric effectors, or other proteins; or can trigger protein degradation. In prokaryotes, only ribosomal proteins are known to be N-terminally acetylated, and the acetyltransferases responsible for this modification belong to the Rim family of proteins. Here, we report that, in Salmonella enterica, the sirtuin deacylase CobB long isoform (CobB_L) is N-terminally acetylated by the YiaC protein of this bacterium. Results of in vitro acetylation assays showed that CobB_L was acetylated by YiaC; liquid chromatography-tandem mass spectrometry (LC-MS/MS) was used to confirm these results. Results of in vitro and in vivo experiments showed that CobB_L deacetylase activity was negatively affected when YiaC acetylated its N terminus. We report 1) modulation of a bacterial sirtuin deacylase activity by acetylation, 2) that the Gcn5-related YiaC protein is the acetyltransferase that modifies CobB_L, and 3) that YiaC is an NAT. Based on our data, we propose the name of NatA (N-acyltransferase A) in lieu of YiaC to reflect the function of the enzyme.

Analysis of Proteins, Protein Complexes, and Organellar Proteomes Using Sheathless Capillary Zone Electrophoresis - Native Mass Spectrometry

Native mass spectrometry (MS) is a rapidly advancing field in the analysis of proteins, protein complexes, and macromolecular species of various types. The majority of native MS experiments reported to-date has been conducted using direct infusion of purified analytes into a mass spectrometer. In this study, capillary zone electrophoresis (CZE) was coupled online to Orbitrap mass spectrometers using a commercial sheathless interface to enable high-performance separation, identification, and structural characterization of limited amounts of purified proteins and protein complexes, the latter with preserved non-covalent associations under native conditions. The performance of both bare-fused silica and polyacrylamide-coated capillaries was assessed using mixtures of protein standards known to form non-covalent protein-protein and protein-ligand complexes. High-efficiency separation of native complexes is demonstrated using both capillary types, while the polyacrylamide neutral-coated capillary showed better reproducibility and higher efficiency for more complex samples. The platform was then evaluated for the determination of monoclonal antibody aggregation and for analysis of proteomes of limited complexity using a ribosomal isolate from E. coli. Native CZE-MS, using accurate single stage and tandem-MS measurements, enabled identification of proteoforms and non-covalent complexes at femtomole levels. This study demonstrates that native CZE-MS can serve as an orthogonal and complementary technique to conventional native MS methodologies with the advantages of low sample consumption, minimal sample processing and losses, and high throughput and sensitivity. This study presents a novel platform for analysis of ribosomes and other macromolecular complexes and organelles, with the potential for discovery of novel structural features defining cellular phenotypes (e.g., specialized ribosomes). Graphical Abstract ᅟ.

The Loop 2 Region of Ribosomal Protein uS5 Influences Spectinomycin Sensitivity, Translational Fidelity, and Ribosome Biogenesis

Ribosomal protein uS5 is an essential component of the small ribosomal subunit that is involved in subunit assembly, maintenance of translational fidelity, and the ribosome's response to the antibiotic spectinomycin. While many of the characterized uS5 mutations that affect decoding map to its interface with uS4, more recent work has shown that residues distant from the uS4-uS5 interface can also affect the decoding process. We targeted one such interface-remote area, the loop 2 region (residues 20 to 31), for mutagenesis in Escherichia. coli and generated 21 unique mutants. A majority of the loop 2 alterations confer resistance to spectinomycin and affect the fidelity of translation. However, only a minority show altered rRNA processing or ribosome biogenesis defects.

Proteome-wide analysis of the amino terminal status of Escherichia coli proteins at the steady-state and upon deformylation inhibition

A proteome wide analysis was performed in Escherichia coli to identify the impact on protein N-termini of actinonin, an antibiotic specifically inhibiting peptide deformylase (PDF). A strategy and tool suite (SILProNaQ) was employed to provide large-scale quantitation of N-terminal modifications. In control conditions, more than 1000 unique N-termini were identified with 56% showing initiator methionine removal. Additional modifications corresponded to partial or complete Nα-acetylation (10%) and N-formyl retention (5%). Among the proteins undergoing these N-terminal modifications, 140 unique N-termini from translocated membrane proteins were highlighted. The very early time-course impact of actinonin was followed after addition of bacteriostatic concentrations of the drug. Under these conditions, 26% of all proteins did not undergo deformylation any longer after 10 min, a value reaching more than 60% of all characterized proteins after 40 min of treatment. The N-formylation ratio measured on individual proteins increased with the same trend. Upon early PDF inhibition, two major categories of proteins retained their N-formyl group: a large number of inner membrane proteins and many proteins involved in protein synthesis including factors assisting the nascent chains in early cotranslational events. All MS data have been deposited in the ProteomeXchange with identifiers PXD001979, PXD002012 and PXD001983 (http://proteomecentral.proteomexchange.org/dataset/PXD001979, http://proteomecentral.proteomexchange.org/dataset/PXD002012 and http://proteomecentral.proteomexchange.org/dataset/PXD001983).

Modulation of decoding fidelity by ribosomal proteins S4 and S5

Ribosomal proteins S4 and S5 participate in the decoding and assembly processes on the ribosome and the interaction with specific antibiotic inhibitors of translation. Many of the characterized mutations affecting these proteins decrease the accuracy of translation, leading to a ribosomal-ambiguity phenotype. Structural analyses of ribosomal complexes indicate that the tRNA selection pathway involves a transition between the closed and open conformations of the 30S ribosomal subunit and requires disruption of the interface between the S4 and S5 proteins. In agreement with this observation, several of the mutations that promote miscoding alter residues located at the S4-S5 interface. Here, the Escherichia coli rpsD and rpsE genes encoding the S4 and S5 proteins were targeted for mutagenesis and screened for accuracy-altering mutations. While a majority of the 38 mutant proteins recovered decrease the accuracy of translation, error-restrictive mutations were also recovered; only a minority of the mutant proteins affected rRNA processing, ribosome assembly, or interactions with antibiotics. Several of the mutations affect residues at the S4-S5 interface. These include five nonsense mutations that generate C-terminal truncations of S4. These truncations are predicted to destabilize the S4-S5 interface and, consistent with the domain closure model, all have ribosomal-ambiguity phenotypes. A substantial number of the mutations alter distant locations and conceivably affect tRNA selection through indirect effects on the S4-S5 interface or by altering interactions with adjacent ribosomal proteins and 16S rRNA.

Dynamics of ribosomal protein S1 on a bacterial ribosome with cross-linking and mass spectrometry

Ribosomal protein S1 has been shown to be a significant effector of prokaryotic translation. The protein is in fact capable of efficiently initiating translation, regardless of the presence of a Shine-Dalgarno sequence in mRNA. Structural insights into this process have remained elusive, as S1 is recalcitrant to traditional techniques of structural analysis, such as x-ray crystallography. Through the application of protein cross-linking and high resolution mass spectrometry, we have detailed the ribosomal binding site of S1 and have observed evidence of its dynamics. Our results support a previous hypothesis that S1 acts as the mRNA catching arm of the prokaryotic ribosome. We also demonstrate that in solution the major domains of the 30S subunit are remarkably flexible, capable of moving 30-50Å with respect to one another.

Crystal structure of RimI from Salmonella typhimurium LT2, the GNAT responsible for N(alpha)-acetylation of ribosomal protein S18

The three ribosomal proteins L7, S5, and S18 are included in the rare subset of prokaryotic proteins that are known to be N(alpha)-acetylated. The GCN5-related N-acetyltransferase (GNAT) protein RimI, responsible for the N(alpha)-acetylation of the ribosomal protein S18, was cloned from Salmonella typhimurium LT2 (RimI(ST)), overexpressed, and purified to homogeneity. Steady-state kinetic parameters for RimI(ST) were determined for AcCoA and a peptide substrate consisting of the first six amino acids of the target protein S18. The crystal structure of RimI(ST) was determined in complex with CoA, AcCoA, and a CoA-S-acetyl-ARYFRR bisubstrate inhibitor. The structures are consistent with a direct nucleophilic addition-elimination mechanism with Glu103 and Tyr115 acting as the catalytic base and acid, respectively. The RimI(ST)-bisubstrate complex suggests that several residues change conformation upon interacting with the N terminus of S18, including Glu103, the proposed active site base, facilitating proton exchange and catalysis.

A novel single amino acid change in small subunit ribosomal protein S5 has profound effects on translational fidelity

S5 is a small subunit ribosomal protein (r-protein) linked to the functional center of the 30S ribosomal subunit. In this study we have identified a unique amino acid mutation in Escherichia coli S5 that produces spectinomycin-resistance and cold sensitivity. This mutation significantly alters cell growth, folding of 16S ribosomal RNA, and translational fidelity. While translation initiation is not affected, both +1 and -1 frameshifting and nonsense suppression are greatly enhanced in the mutant strain. Interestingly, this S5 ribosome ambiguity-like mutation is spatially remote from previously identified S5 ribosome ambiguity (ram) mutations. This suggests that the mechanism responsible for ram phenotypes in the novel mutant strain is possibly distinct from those proposed for other known S5 (and S4) ram mutants. This study highlights the importance of S5 in ribosome function and cell physiology, and suggests that translational fidelity can be regulated in multiple ways.

The GTP binding protein Obg homolog ObgE is involved in ribosome maturation

Obg proteins belong to a subfamily of GTP binding proteins, which are highly conserved from bacteria to human. Mutations of obgE genes cause pleiotropic defects in various species but the function remained unclear. Here we examine the function of ObgE, the Obg homolog in Escherichia coli. The growth rate correlates with the amount of ObgE in cells. Co-fractionation experiments further suggest that ObgE binds to 30S and 50S ribosomal subunits, but not to 70S ribosome. Pull-down assays suggest that ObgE associates with several specific ribosomal proteins of 30S and 50S subunits, as well as RNA helicase CsdA. Purified ObgE cosediments with 16S and 23S ribosomal RNAs in vitro in the presence of GTP. Finally, mutation of ObgE affects pre-16Sr-RNA processing, ribosomal protein levels, and ribosomal protein modification, thereby significantly reducing 70S ribosome levels. This evidence implicates that ObgE functions in ribosomal biogenesis, presumably through the binding to rRNAs and/or rRNA-ribosomal protein complexes, perhaps as an rRNA/ribosomal protein folding chaperone or scaffold protein.

Crystal structure of the 30 S ribosomal subunit from Thermus thermophilus: structure of the proteins and their interactions with 16 S RNA

We present a detailed analysis of the protein structures in the 30 S ribosomal subunit from Thermus thermophilus, and their interactions with 16 S RNA based on a crystal structure at 3.05 A resolution. With 20 different polypeptide chains, the 30 S subunit adds significantly to our data base of RNA structure and protein-RNA interactions. In addition to globular domains, many of the proteins have long, extended regions, either in the termini or in internal loops, which make extensive contact to the RNA component and are involved in stabilizing RNA tertiary structure. Many ribosomal proteins share similar alpha+beta sandwich folds, but we show that the topology of this domain varies considerably, as do the ways in which the proteins interact with RNA. Analysis of the protein-RNA interactions in the context of ribosomal assembly shows that the primary binders are globular proteins that bind at RNA multihelix junctions, whereas proteins with long extensions assemble later. We attempt to correlate the structure with a large body of biochemical and genetic data on the 30 S subunit.

Functional insights from the structure of the 30S ribosomal subunit and its interactions with antibiotics

The 30S ribosomal subunit has two primary functions in protein synthesis. It discriminates against aminoacyl transfer RNAs that do not match the codon of messenger RNA, thereby ensuring accuracy in translation of the genetic message in a process called decoding. Also, it works with the 50S subunit to move the tRNAs and associated mRNA by precisely one codon, in a process called translocation. Here we describe the functional implications of the high-resolution 30S crystal structure presented in the accompanying paper, and infer details of the interactions between the 30S subunit and its tRNA and mRNA ligands. We also describe the crystal structure of the 30S subunit complexed with the antibiotics paromomycin, streptomycin and spectinomycin, which interfere with decoding and translocation. This work reveals the structural basis for the action of these antibiotics, and leads to a model for the role of the universally conserved 16S RNA residues A1492 and A1493 in the decoding process.

Structure of functionally activated small ribosomal subunit at 3.3 angstroms resolution

The small ribosomal subunit performs the decoding of genetic information during translation. The structure of that from Thermus thermophilus shows that the decoding center, which positions mRNA and three tRNAs, is constructed entirely of RNA. The entrance to the mRNA channel will encircle the message when a latch-like contact closes and contributes to processivity and fidelity. Extended RNA helical elements that run longitudinally through the body transmit structural changes, correlating events at the particle's far end with the cycle of mRNA translocation at the decoding region. 96% of the nucleotides were traced and the main fold of all proteins was determined. The latter are either peripheral or appear to serve as linkers. Some may assist the directionality of translocation.

Structure of a bacterial 30S ribosomal subunit at 5.5 A resolution

The 30S ribosomal subunit binds messenger RNA and the anticodon stem-loop of transfer RNA during protein synthesis. A crystallographic analysis of the structure of the subunit from the bacterium Thermus thermophilus is presented. At a resolution of 5.5 A, the phosphate backbone of the ribosomal RNA is visible, as are the alpha-helices of the ribosomal proteins, enabling double-helical regions of RNA to be identified throughout the subunit, all seven of the small-subunit proteins of known crystal structure to be positioned in the electron density map, and the fold of the entire central domain of the small-subunit ribosomal RNA to be determined.

Solution scattering structural analysis of the 70 S Escherichia coli ribosome by contrast variation. I. Invariants and validation of electron microscopy models

Solutions of selectively deuterated 70 S Escherichia coli ribosomes and of free 30 S and 50 S subunits were studied by neutron scattering using contrast variation. The integrity of the partially deuterated particles was controlled by parallel X-ray measurements. Integral parameters of the entire ribosome, of its subunits and of the protein and rRNA moieties were evaluated. The data allow an experimental validation of the two most recent electron microscopy reconstructions of the 70 S ribosome presented by the groups of J. Frank (Albany) and of M. van Heel & R. Brimacombe (Berlin). For each reconstruction, integral parameters and theoretical scattering curves from the 70 S and its subunits were calculated and compared with the experimental data. Although neither of the two models yields a comprehensive agreement with the experimental data, Frank's model provides a better fit. For the 50 S subunit of van Heel & Brimacombe's model the fit with the experimental data improves significantly when the internal channels and tunnels are filled up. The poorer fit of the latter model is thus caused by its "sponge"-like structure which may partly be due to an enhancement of high frequency contributions in some of the steps of the three-dimensional image reconstruction. It seems therefore unlikely that the ribosome has a "sponge"-like structure with a pronounced network of channels.

The structure of ribosomal protein S5 reveals sites of interaction with 16S rRNA

Understanding the process whereby the ribosome translates the genetic code into protein molecules will ultimately require high-resolution structural information, and we report here the first crystal structure of a protein from the small ribosomal subunit. This protein, S5, has a molecular mass of 17,500 and is highly conserved in all lifeforms. The molecule contains two distinct alpha/beta domains that have structural similarities to several other proteins that are components of ribonucleoprotein complexes. Mutations in S5 result in several phenotypes which suggest that S5 may have a role in translational fidelity and translocation. These include ribosome ambiguity or ram, reversion from streptomycin dependence and resistance to spectinomycin. Also, a cold-sensitive, spectinomycin-resistant mutant of S5 has been identified which is defective in initiation. Here we show that these mutations map to two distinct regions of the molecule which seem to be sites of interaction with ribosomal RNA. A structure/function analysis of the molecule reveals discrepancies with current models of the 30S subunit.

Organization and nucleotide sequence of ten ribosomal protein genes from the region equivalent to the spectinomycin operon in the archaebacterium Halobacterium marismortui

The nucleotide sequence has been determined of a 4700 bp region from a ribosomal protein gene cluster of Halobacterium marismortui (Haloarcula marismortui), which is equivalent to part of the spectinomycin operon of Escherichia coli. The genes were localized on the recombinant lambda EMBL3 clone PP*7, which also contains several other ribosomal protein genes from the DNA region in H. marismortui equivalent to the linked S10/spc operon. The genes analysed encode ten ribosomal proteins, namely HmaL5, HmaS14, HmaS8, HmaL6, HL5, HL24, HmaL18, HmaS5, HmaL30 and HmaL15. The gene organization of the archaebacterial cluster is similar to that in eubacteria but has two additional genes, namely those encoding HL5 and HL24, which were identified as extra proteins that are apparently not present in E. coli. These correspond to the gene products of orfd and orfe in Methanococcus vannielii and also have eukaryotic counterparts.

A developmentally regulated gene encodes the dictyostelium homolog of yeast ribosomal protein S4 and mammalian LLRep3 proteins

We report the sequence and expression of a single-copy gene from Dictyostelium discoideum which encodes the homolog of yeast ribosomal protein S4, a protein located on the small ribosomal subunit and known to play an important role in maintaining translational fidelity. Over a highly conserved central region, the Dictyostelium protein has 78% sequence similarity to the yeast protein and 83% sequence similarity to mammalian S4 protein homologs, the LLRep3 proteins. The Dictyostelium gene encodes a polypeptide 28,717 Da in size and hence this ribosomal protein has been named rp29. The N-terminal sequence of the Dictyostelium rp29 protein is extended by 61 amino acids and 14 amino acids compared to the mammalian and yeast proteins, respectively, and the C-terminus is correspondingly 15 amino acids or 2 amino acids shorter. Although the coding region of the rp29 gene is present on a single exon, a 157bp intron interrupts the 5' untranslated region and unusually contains four direct repeats of the sequence TCAATCT. The gene is expressed maximally during vegetative growth but a second peak of expression also occurs late in development which is restricted to prestalk cells; rp29 is the first Dictyostelium ribosomal protein gene reported which shows prestalk-specific developmental expression. During each round of expression, only a single 0.9kb transcript is produced which is similar in size to the yeast S4 ribosomal protein transcript (0.8kb) but markedly smaller than the mammalian LLRep3 mRNA (1.7kb) due to a much shorter 5' untranslated region.

Sequence and functional similarity between a yeast ribosomal protein and the Escherichia coli S5 ram protein

The accurate and efficient translation of proteins is of fundamental importance to both bacteria and higher organisms. Most of our knowledge about the control of translational fidelity comes from studies of Escherichia coli. In particular, ram (ribosomal ambiguity) mutations in structural genes of E. coli ribosomal proteins S4 and S5 have been shown to increase translational error frequencies. We describe the first sequence of a ribosomal protein gene that affects translational ambiguity in a eucaryote. We show that the yeast omnipotent suppressor SUP44 encodes the yeast ribosomal protein S4. The gene exists as a single copy without an intron. The SUP44 protein is 26% identical (54% similar) to the well-characterized E. coli S5 ram protein. SUP44 is also 59% identical (78% similar) to mouse protein LLrep3, whose function was previously unknown (D.L. Heller, K.M. Gianda, and L. Leinwand, Mol. Cell. Biol. 8:2797-2803, 1988). The SUP44 suppressor mutation occurs near a region of the protein that corresponds to the known positions of alterations in E. coli S5 ram mutations. This is the first ribosomal protein whose function and sequence have been shown to be conserved between procaryotes and eucaryotes.

Sequence and functional similarity between a yeast ribosomal protein and the Escherichia coli S5 ram protein

The accurate and efficient translation of proteins is of fundamental importance to both bacteria and higher organisms. Most of our knowledge about the control of translational fidelity comes from studies of Escherichia coli. In particular, ram (ribosomal ambiguity) mutations in structural genes of E. coli ribosomal proteins S4 and S5 have been shown to increase translational error frequencies. We describe the first sequence of a ribosomal protein gene that affects translational ambiguity in a eucaryote. We show that the yeast omnipotent suppressor SUP44 encodes the yeast ribosomal protein S4. The gene exists as a single copy without an intron. The SUP44 protein is 26% identical (54% similar) to the well-characterized E. coli S5 ram protein. SUP44 is also 59% identical (78% similar) to mouse protein LLrep3, whose function was previously unknown (D.L. Heller, K.M. Gianda, and L. Leinwand, Mol. Cell. Biol. 8:2797-2803, 1988). The SUP44 suppressor mutation occurs near a region of the protein that corresponds to the known positions of alterations in E. coli S5 ram mutations. This is the first ribosomal protein whose function and sequence have been shown to be conserved between procaryotes and eucaryotes.

Organization and structure of the Methanococcus transcriptional unit homologous to the Escherichia coli "spectinomycin operon". Implications for the evolutionary relationship of 70 S and 80 S ribosomes

By means of an immunological approach and a subsequent chromosome-walking strategy a chromosomal region encoding ribosomal proteins in the archaebacterium Methanococcus vannielii was cloned. The determination of the nucleotide sequence of the 7.8 x 10(3) base DNA fragment revealed the existence of 14 putative ribosomal protein genes and two unidentified open reading frames. They are organized in a transcriptional unit that is very similar to the Escherichia coli "spectinomycin operon" in respect of both gene composition and gene order. The Methanococcus transcriptional unit contains, in addition to those genes whose products have a homologue in the E. coli operon, three genes whose products share sequence similarity with eukaryotic 80 S but not with eubacterial ribosomal proteins. The Methanococcus ribosomal proteins almost exclusively exhibit a higher sequence similarity to eukaryotic 80 S ribosomal proteins than to those of eubacteria and many of them have a size intermediate between those of their eukaryotic and eubacterial homologues. These results are discussed in terms of a hypothesis that implies that the recent eubacterial ribosome developed by a "minimization" process from a more complex organelle and that the archaebacterial ribosome has maintained features of this ancestor.

Characterization of the gene rimK responsible for the addition of glutamic acid residues to the C-terminus of ribosomal protein S6 in Escherichia coli K12

Ribosomal protein S6 of wild-type strains of Escherichia coli contains up to six glutamic acid residues at its C-terminus. The first two residues are encoded by the structural gene for this protein (rpsF) and the rest are added post-translationally. Mutants deficient in this modification were isolated and characterized genetically and biochemically. The S6 protein in these mutants appeared to contain only two glutamic acid residues at the C-terminus as expected. The mutated gene was termed rimK and was mapped at 18.7 min between cmlA and aroA. The rimK gene was cloned into a cosmid vector and its nucleotide sequence determined. Analysis of the transcriptional and translational products of this gene indicates that it encodes a protein with an Mr of 31.5 kDa and that it forms an operon with a gene encoding a 24 kDa protein. An rpsF mutant containing a Glu to Lys replacement in the second residue from the C-terminus of protein S6 was isolated. The S6 protein of this mutant was apparently inaccessible to the RimK modification system. This indicates that the RimK modification system requires the wild-type amino acid sequence at least in the C-terminal region of ribosomal protein S6.

The histone-like H protein of Escherichia coli is ribosomal protein S3

We report the purification of four proteins from Escherichia coli that stimulate or inhibit inter- and/or intramolecular recombination promoted by the yeast plasmid-encoded FLP protein. The proteins are identified as the ribosomal proteins S3 (27 kDa), L2 (26 kDa), S4 (24 kDa), and S5 (16 kDa), on the basis of N-terminal sequence analysis. The S3 protein is found to be identical to H protein, an E. coli histone-like protein that is related to histone H2A immunologically and by virtue of amino acid content. The H protein/S3 identity is based on co-migration on polyacrylamide gels, heat stability, amino acid analysis, and effects on FLP-promoted recombination. These results are relevant to current studies on the structure of the E. coli nucleoid. Since the H protein has previously been found associated with the E. coli nucleoid, the results indicate that either (a) some ribosomal proteins serve a dual function in E. coli, or, more likely, (b) ribosomal proteins can and are being mis-identified as nucleoid constituents.

Escherichia coli-derived human interferon-gamma with Cys-Tyr-Cys at the N-terminus is partially N alpha-acylated

Purified preparations of recombinant human interferon-gamma (rIFN-gamma) with Cys-Tyr-Cys at the N-terminus ([ Cys-Tyr-Cys]IFN-gamma) derived from Escherichia coli gave two closely migrating bands on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and two peaks on reversed-phase high-performance liquid chromatography (rpHPLC). In contrast, rIFN-gamma without Cys-Tyr-Cys and rIFN-gamma in which both Cys-1 and Cys-3 were substituted with serine behaved as a single species on both SDS-PAGE and rpHPLC. These results suggest that the N-terminal portion of rIFN-gamma is heterogeneous. To elucidate the structure of the N-terminal portion, the N-terminal peptide preparation was obtained by binding rIFN-gamma to thiopropyl-Sepharose 6B gel with disulfide linkage followed by trypsin digestion and elution with 2-mercaptoethanol. The preparation gave four peaks (NT-1, NT-2, NT-3, and NT-4, in order of elution) on rpHPLC; all four were found to be Cys-1-Lys-9 by amino acid analysis after acid hydrolysis. Various analyses indicate that NT-1 is the intact nonapeptide, that NT-3 and NT-4 are N alpha-formyl and N alpha-acetyl forms of NT-1, respectively, and that NT-2 may be S-blocked at Cys-1. It is concluded that E. coli-derived [Cys-Tyr-Cys]IFN-gamma is partially N alpha-acylated. The data also suggest that N alpha-acylation does not affect the biological activity of [Cys-Tyr-Cys]IFN-gamma.

Amino acid sequence homology applied to the prediction of protein secondary structures, and joint prediction with existing methods

The assumption that homologous segments in different proteins may share a similar conformation is applied to the prediction of secondary structures in proteins. Sequences homologous to a target protein are searched, without allowing any gap, and compared against a number of reference proteins of known three-dimensional structure, and then a conformational state (alpha, beta or coil) for each residue of the protein is predicted by looking at the secondary structure of corresponding homologous segments. This prediction is done in a statistical rather than 'deterministic' way, by assigning the most probable conformation state among homologous data to each residue site of a target protein. A test application for 22 sample proteins yields 60% correctness on the average, a better value in comparison with two other existing methods. Joint prediction combining three methods into one is shown to increase the reliability up to 70%, when only the regions identically predicted with the three methods are taken into account. Application of the present method to 10 proteins of unknown structure is demonstrated.

Homologies and anomalies in primary structural patterns of nucleotide binding proteins

In searches for homology among nucleotide binding proteins, recent reports have described primary structure alignments for stretches of 30 or so amino acid residues among a variety of proteins including the ras and src oncogene products. The significance of these sequence matches has been tested by searching in available data banks for certain conserved residue patterns resulting from the alignments. The tests suggest that alignments over these limited stretches are not necessarily justifiable and any implications for residues involved in nucleotide binding must be viewed with caution.

On the statistical significance of homologous structures among the Escherichia coli ribosomal proteins

Completion of the sequence determination of all 52 Escherichia coli ribosomal proteins enabled a final comparison of their sequences. Similarities in amino acid compositions were compared to the relatedness of the sequences, which was analyzed statistically with the aid of the computer programs RELATE and ALIGN. Among the examined 52 X 52 possible protein pairs at least 40 pairs were found that can be regarded as distantly related (showing segment comparison score values slightly above 3.0 S.D. units). These protein pairs were further examined with the programs ALIGN and SEEK to locate homologous sequence stretches. In no case were two complete homologous sequences found (with the exception of the known identical pairs L7/L12 and S20/L26). However, short homologous sequence regions were observed. Beside those protein pairs that show significant although distant relatedness, other pairs were slightly below the threshold value of 3.0 S.D. units. Those pairs observed to be distantly related consisted either of two proteins from the same subunit or of one protein from each of the different subunits. A further analysis of these pairs revealed a correlation between their relatedness and their time of incorporation into the ribosome during assembly.

The complete amino acid sequences of ribosomal proteins L17, L27, and S9 from Bacillus stearothermophilus

The complete primary structures of proteins L17, L27 and S9 extracted from the Bacillus stearothermophilus ribosomes with 1 M NaCl and purified to homogeneity by column chromatography have been determined. The amino acid sequences of these proteins are compared to those of the homologous ribosomal proteins from Escherichia coli. The number of identical amino acid residues between the homologous proteins lies between 33-55%.

The structural periodicity of E. coli ribosomal proteins

It is established that the sequences of all different proteins from E. coli ribosome as well as two protein biosynthesis initiation factors, two ribosome-associated DNA-binding proteins, and the elongation factor EF-Tu from the same source possess a periodicity expressed more weakly and different from that found earlier for a number of proteins representatives of 18 superfamilies. The statistical significance of the periodicity observed was checked by comparing the area below the periodicity curve of every protein examined with that of computer generated sequences having the same amino acid composition and length. The results concerning the proteins from small and large ribosomal subunit are compared. The conclusions support and supplement the concept about the presence of a trend in protein molecular evolution from universal (Gly, Ala) to specialized (Phe, Tyr, Trp, Cys) amino acids.

Spectinomycin resistance due to a mutation in an rRNA operon of Escherichia coli

A spectinomycin resistance mutation was isolated in an Escherichia coli rRNA operon (rrnH) located on a multicopy plasmid. Cell-free protein-synthesizing extracts made from cells containing the plasmid were partially resistant to spectinomycin. Although spectinomycin is an aminoglycoside antibiotic, the mutation did not confer resistance to any other aminoglycoside antibiotic tested.

The spc ribosomal protein operon of Escherichia coli: sequence and cotranscription of the ribosomal protein genes and a protein export gene

The genes encoding the 52 ribosomal proteins (r-proteins) of Escherichia coli are organized into approximately 19 operons scattered throughout the chromosome. One of these, the spc operon, contains the genes for ten ribosomal proteins: L14, L24, L5, S14, S8, L6, L18, S5, L30 and L15 (rp1N, rp1X, rp1E, rpsN, rpsH, rp1F, rp1R, rpsE, rpmD, and rp1O). We now report the entire 5.9 kb nucleotide sequence of the spc operon. DNA sequence analysis has confirmed the genetic organization and refined the amino acid sequence of the ten r-proteins in this operon. It has also revealed the presence of two open reading frames past the last known gene (L15) of the spc operon. One of these corresponds to a gene (pr1A or secY) which recently has been shown by others to be involved in protein export. In addition, S1 mapping experiments indicate that a significant proportion of transcription initiated from the spc operon continues not only into the two putative genes, but also without termination into the downstream alpha r-protein operon.

Optical characteristics of all individual proteins from the small subunit of Escherichia coli ribosomes

The procedure of isolation and renaturation of all ribosomal proteins from the 30-S subunit of Escherichia coli ribosomes is described. Absorption spectra of these proteins in the near-ultraviolet region have been measured and molar absorption coefficients have been determined on the basis of nitrogen content. Molar absorption coefficients have been calculated for 20 proteins with a known amino acid sequence and the calculated values have been compared with the experimentally determined ones. The absorption spectra obtained allow an easy, precise and highly reproducible spectrophotometric determination of the concentration of individual ribosomal proteins. Circular dichroic spectra of 21 individual proteins from the 30-S subunit of E. coli ribosomes were measured in the range 184-310 nm. The secondary structure of the proteins studied was calculated from the spectra in the range 190-240 nm. Almost all proteins (except proteins S12, S17, S18 and S19) are characterized by a high content of secondary structure. Circular dichroic spectra in the near-ultraviolet region (240-310 nm) indicate that the side groups of aromatic amino acids are fixed in the tertiary structure of the proteins studied. Some internal characteristics (independent of the measurement conditions) of the circular dichroic spectrum in the far-ultraviolet region were proposed as a measure of the resemblance to the native state of ribosomal proteins; these characteristics may be useful for comparison of protein preparations obtained by different methods in different laboratories.

The histidines of the bacterial ribosome: a tritium exchange study

The accessibility of histidines in the E. coli 30S subunits was assessed by exchange of C-2 histidine protons with tritiated water at 37 degrees C. The absence of exchange at acidic pH allowed the separation and identification of individual proteins without loss of histidine labelling. Only the two ribosomal proteins S5 and S6 exhibited significant exchange. No gross change of accessibility was detected in the 70S ribosome couples.

Ribosomal protein modification in Escherichia coli. III. Studies of mutants lacking an acetylase activity specific for protein L12

Among mutants of E. coli selected for temperature-sensitive growth, four were found to possess alterations in ribosomal proteins L7/L12. Of these, three apparently lack protein L7, the acetylated form of protein L12. Genetic analyses have revealed that the mutation responsible for this alteration maps at a locus around 34 min of the current E. coli genetic map, which is clearly different from the location for the structural gene for protein L7/L12 which is situated at 89 min. Hence, the gene affected in these mutants was termed rimL. Tryptic and thermolysin fingerprints of the protein L12 purified from the rimL mutants showed a profile indistinguishable from that of wild-type protein. It was found that the assayed in vitro, in the high-speed supernatant prepared from mutant cells. These results indicated that the three mutants contain mutations in the gene rimL codes for an acetylating enzyme specific for ribosomal protein L12.

Ribosomal protein modification in Escherichia coli. II. Studies of a mutant lacking the N-terminal acetylation of protein S18

A mutant of Escherichia coli K12 has been isolated which shows an alteration in the ribosomal protein S18. Genetic analyses have revealed that the mutation causing this alteration maps at 99.3 min of the E. coli genetic map, between dnaC and deo. This indicated that the mutation has occurred in a gene different from the structural gene for this protein which has been located at 94 min. From the N-terminal amino acid sequence analysis it is concluded that the mutation has resulted in loss of the N-terminal acetyl group of this protein. The gene which is affected in this mutant is termed rimI that most likely specifies an enzyme acetylating the N-terminal alanine of protein S18. The mutation does not affect the acetylation of two other ribosomal proteins, S5 and L12, both of which are known to be acetylated in wild-type E. coli K12.