Purification of ribosomal proteins from Escherichia coli under nondenaturing conditions

Ribosome rescue by Escherichia coli ArfA (YhdL) in the absence of trans-translation system

Although SsrA(tmRNA)-mediated trans-translation is thought to maintain the translation capacity of bacterial cells by rescuing ribosomes stalled on messenger RNA lacking an in-frame stop codon, single disruption of ssrA does not crucially hamper growth of Escherichia coli. Here, we identified YhdL (renamed ArfA for alternative ribosome-rescue factor) as a factor essential for the viability of E. coli in the absence of SsrA. The ssrA-arfA synthetic lethality was alleviated by SsrA(DD) , an SsrA variant that adds a proteolysis-refractory tag through trans-translation, indicating that ArfA-deficient cells require continued translation, rather than subsequent proteolysis of the truncated polypeptide. In accordance with this notion, depletion of SsrA in the ΔarfA background led to reduced translation of a model protein without affecting transcription, and puromycin, a codon-independent mimic of aminoacyl-tRNA, rescued the bacterial growth under such conditions. That ArfA takes over the role of SsrA was suggested by the observation that its overexpression enabled detection of the polypeptide encoded by a model non-stop mRNA, which was otherwise SsrA-tagged and degraded. In vitro, purified ArfA acted on a ribosome-nascent chain complex to resolve the peptidyl-tRNA. These results indicate that ArfA rescues the ribosome stalled at the 3' end of a non-stop mRNA without involving trans-translation.

A top-down/bottom-up study of the ribosomal proteins of Caulobacter crescentus

Ribosomes from the Gram-negative alpha-proteobacterium Caulobacter crescentus were isolated using standard methods. Proteins were separated using a two-dimensional liquid chromatographic system that allowed the analysis of whole proteins by direct coupling to an ESI-QTOF mass spectrometer and of proteolytic digests by a number of mass spectrometric methods. The masses of 53 of 54 ribosomal proteins were directly measured. Protein identifications and proposed post-translational modifications were supported by proteolysis with trypsin, endoprotease Glu-C, and exoproteases carboxypeptidases Y and P. Tryptic peptide mass maps show an average sequence coverage of 62%, and carboxypeptidase C-terminal sequence tagging provided unambiguous identification of the small, highly basic proteins of the large subunit. C. crescentus presents some post-translational modifications that are similar to those of Escherichia coli (e.g., N-terminal acetylation of S9 and S18) along with some unique variations, such as a near absence of L7 and extensive modification of L11. The comprehensive description of this organism's ribosomal proteome provides a foundation for the study of ribosome structure, dependence of post-translational modifications on growth conditions, and the evolution of subcellular organelles.

Transcription of eukaryotic protein-coding genes

The past decade has seen an explosive increase in information about regulation of eukaryotic gene transcription, especially for protein-coding genes. The most striking advances in our knowledge of transcriptional regulation involve the chromatin template, the large complexes recruited by transcriptional activators that regulate chromatin structure and the transcription apparatus, the holoenzyme forms of RNA polymerase II involved in initiation and elongation, and the mechanisms that link mRNA processing with its synthesis. We describe here the major advances in these areas, with particular emphasis on the modular complexes associated with RNA polymerase II that are targeted by activators and other regulators of mRNA biosynthesis.

Assembly of proteins and 5 S rRNA to transcripts of the major structural domains of 23 S rRNA

The six major structural domains of 23 S rRNA from Escherichia coli, and all combinations thereof, were synthesized as separate T7 transcripts and reconstituted with total 50 S subunit proteins. Analysis by one and two-dimensional gel electrophoresis demonstrated the presence of at least one primary binding protein associated with each RNA domain and additional proteins assembled to domains I, II, V and VI. For all the combinations of two to five domains, enhanced assembly yields and/or new proteins were observed primarily to those transcripts containing either domains I+II or domains V+VI. This indicates that there are two major protein assembly centres located at the ends of the 23 S rRNA, which is consistent with an earlier view that in vitro protein assembly nucleates around proteins L24 and L3. Although similar protein assembly patterns were observed over a range of temperature and magnesium concentrations, protein L2 assembled strongly with domains II and IV at 4-8 mM Mg2+ (the first step of the two-step reconstitution procedure) and with domain IV alone at higher Mg2+ concentrations (the second step). It is proposed that this change in protein-RNA binding provides a basis for the two-step reconstitution in vitro. A chemical footprinting approach was employed on the reconstituted protein-domain complexes to localize a putative L4 binding region within domain I to a region that is partially co-structural with the site on the L4-mRNA where L4 binds and inhibits its own translation. A similar approach was used to map the putative binding regions on domain V of protein L9 and the 5 S RNA-L5-L18 complex.

The human U5-220kD protein (hPrp8) forms a stable RNA-free complex with several U5-specific proteins, including an RNA unwindase, a homologue of ribosomal elongation factor EF-2, and a novel WD-40 protein

The human small nuclear ribonucleoprotein (snRNP) U5 is biochemically the most complex of the snRNP particles, containing not only the Sm core proteins but also 10 particle-specific proteins. Several of these proteins have sequence motifs which suggest that they participate in conformational changes of RNA and protein. Together, the specific proteins comprise 85% of the mass of the U5 snRNP particle. Therefore, protein-protein interactions should be highly important for both the architecture and the function of this particle. We investigated protein-protein interactions using both native and recombinant U5-specific proteins. Native U5 proteins were obtained by dissociation of U5 snRNP particles with the chaotropic salt sodium thiocyanate. A stable, RNA-free complex containing the 116-kDa EF-2 homologue (116kD), the 200kD RNA unwindase, the 220kD protein, which is the orthologue of the yeast Prp8p protein, and the U5-40kD protein was detected by sedimentation analysis of the dissociated proteins. By cDNA cloning, we show that the 40kD protein is a novel WD-40 repeat protein and is thus likely to mediate regulated protein-protein interactions. Additional biochemical analyses demonstrated that the 220kD protein binds simultaneously to the 40- and the 116kD proteins and probably also to the 200kD protein. Since the 220kD protein is also known to contact both the pre-mRNA and the U5 snRNA, it is in a position to relay the functional state of the spliceosome to the other proteins in the complex and thus modulate their activity.

Regulatory targets in the RNA polymerase II holoenzyme

The RNA polymerase II holoenzyme is the form of polymerase recruited to promoters for protein-coding genes. Several targets of mammalian activators, previously called coactivators, turn out to be subunits of the holoenzyme which activators use to recruit and regulate the holoenzyme. Several of these newly identified holoenzyme components have been implicated in human disease.

Ribosomal protein structures: insights into the architecture, machinery and evolution of the ribosome

Models of the bacterial ribosome based on recent structural analyses are beginning to provide new insights into the protein synthetic machinery. Central to evolving models are the high-resolution structures of individual ribosomal proteins, which represent detailed probes of their local RNA and protein environments. Ribosomal proteins are extremely ancient molecules; the structures therefore also provide a unique window into early protein evolution. Many of the proteins contain domains that are present in more recently evolved families of RNA- and DNA-binding proteins. Such structural homology can be used to predict mechanisms by which proteins interact with RNA in the ribosome.

Measurement of thermodynamic nonideality arising from volume-exclusion interactions between proteins and polymers

The effective thermodynamic radii of 23 ribosomal proteins from the 50 S subunit have been determined by gel chromatography on Sephadex G-50, thereby supporting the contention that most of the proteins of the 50 S ribosomal unit exhibit reasonably globular structures. To investigate further the usefulness of modelling proteins as spheres, the second virial coefficient describing excluded volume interactions of some ribosomal proteins with two inert polymers, polyethylene glycol (PEG) and dextran, has been determined by gel chromatography and/or sedimentation equilibrium techniques. Protein-polymer excluded volumes obtained with PEG 20000 and Dextran T70 as the space-filling solute are shown to conform reasonably well with a quantitative expression describing interaction between an impenetrable sphere and an ideal Brownian path (K.M. Jansons and C.G. Phillips, J. Colloid Interface Sci., 137 (1990) 75).

Ribosomal proteins of Thermomyces lanuginosus--characterisation by two-dimensional gel electrophoresis and differential disassembly

One- and two-dimensional gel electrophoresis were employed to characterise the proteins derived from the ribosomes of the thermophilic fungus Thermomyces lanuginosus. Approximately 32 (29 basic and 3 acidic) and 45 (43 basic and 2 acidic) protein spots were resolved from Th. lanuginosus small and large ribosomal subunits, respectively. The molecular weight of the small subunit proteins ranged from 9,800-36,000 Da with a number average molecular weight of 20,300 Da. The molecular weight range for the large subunit proteins was 12,000-48,500 Da with a number average molecular weight of 25,900 Da. Most proteins appeared to be present in unimolar amounts. These data are comparable with but not identical to those from other eukaryotic ribosomes. The sensitivities of the ribosomal proteins to increasing concentrations of NH4Cl were also evaluated by two-dimensional gel electrophoresis. Most ribosomal proteins were gradually released over a wide range of salt concentrations but some were preferentially enriched in one or two salt conditions.

Purification and characterization of the 30S ribosomal proteins from the bacterium Thermus thermophilus

The total protein mixture of the 30S subunit (TP-30) of the bacterium Thermus thermophilus has been purified using reverse-phase HPLC and the proteins obtained were identified both by means of two-dimensional polyacrylamide gel electrophoresis as well as by amino-terminal amino acid microsequence analysis. The proteins are numbered according to their primary structural similarity with known prokaryotic ribosomal proteins. Eight of them, namely proteins S6, S7, S9, S10, S14, S15, S16 and S17 run at different positions in the two-dimensional gel electrophoresis system to those suggested [Sedelnikova, S. C., Agalarov, M. B., Garber, M. & Yusupov, M. M. (1987) FEBS Lett. 220, 227-230]. All characterized proteins are homologous to known ribosomal proteins from other species, except for a small basic protein which shows homology only to a ribosomal protein from spinach chloroplasts [Choli, T., Franceschi, F., Yonath, A. & Wittmann-Leibold, B. (1993) Biol. Chem. Hoppe-Seyler 374, 377-383; Subramanian, A.-R. (1984) Trends Biochem. Sci. 9, 491-494].

Proteins of the Thermus thermophilus ribosome. Purification of proteins from the large ribosomal subunit

Special procedures have been developed to isolate and purify 26 of the 30 individual proteins of the large ribosomal subunit from Thermus thermophilus. Sixteen of them have been purified under non-denaturing conditions to be used for crystallization and further structural studies. These proteins have been characterized by their amino acid content, molecular mass, UV-spectrum and extinction coefficient. An additional 10 proteins have been purified by reverse phase chromatography. Thirteen proteins have been identified by homological E coli proteins.

Purification of E. coli 30S ribosomal proteins by high-performance liquid chromatography under non-denaturing conditions

High-performance ion-exchange chromatography was applied to the separation of proteins from the 30S ribosomal subunit under non-denaturing conditions. It was shown that a single chromatographic step only allows the purification of nine proteins. To increase the number of separated proteins, a prefractionation step was added that depends on the physical characteristics of the proteins to be purified. Sixteen out of 21 proteins could be purified by using prefractionation (gel permeation and lithium chloride salt washing). This method is well suited to preparing fresh samples on demand for optical studies owing to the simplicity of the buffers used and the amounts of proteins recovered in the eluted peaks (0.05-0.1 mg/ml).

Affinity labeling of the virginiamycin S binding site on bacterial ribosome

Virginiamycin S (VS, a type B synergimycin) inhibits peptide bond synthesis in vitro and in vivo. The attachment of virginiamycin S to the large ribosomal subunit (50S) is competitively inhibited by erythromycin (Ery, a macrolide) and enhanced by virginiamycin M (VM, a type A synergimycin). We have previously shown, by fluorescence energy transfer measurements, that virginiamycin S binds at the base of the central protuberance of 50S, the putative location of peptidyltransferase domain [Di Giambattista et al. (1986) Biochemistry 25, 3540-3547]. In the present work, the ribosomal protein components at the virginiamycin S binding site were affinity labeled by the N-hydroxysuccinimide ester derivative (HSE) of this antibiotic. Evidence has been provided for (a) the association constant of HSE-ribosome complex formation being similar to that of native virginiamycin S, (b) HSE binding to ribosomes being antagonized by erythromycin and enhanced by virginiamycin M, and (c) a specific linkage of HSE with a single region of 50S, with virtually no fixation to 30S. After dissociation of covalent ribosome-HSE complexes, the resulting ribosomal proteins have been fractionated by electrophoresis and blotted to nitrocellulose, and the HSE-binding proteins have been detected by an immunoenzymometric procedure. More than 80% of label was present within a double spot corresponding to proteins L18 and L22, whose Rfs were modified by the affinity-labeling reagent. It is concluded that these proteins are components of the peptidyltransferase domain of bacterial ribosomes, for which a topographical model, including the available literature data, is proposed.

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.

Domain VI of Escherichia coli 23 S ribosomal RNA. Structure, assembly and function

Domain VI at the 3' end of the 23 S ribosomal RNA from Escherichia coli was prepared using the in vitro T7 RNA polymerase system. Its structure was examined by probing with ribonucleases and chemical reagents, including a psoralen derivative, of various nucleotide specificities, using a reverse transcriptase procedure for analysis. The data provided support for the most recent secondary structure derived from phylogenetic sequence comparisons and for additional structuring that was inferred from earlier experimental data. Moreover, the structure was essentially the same in the free domain, in renatured 23 S RNA and in 50 S subunits. Protein L3 bound to the isolated domain and its binding site was located at a long-range double helix containing a large internal loop. This structure is unusual for a protein-RNA binding site and it may characterize a new (third) class of site. Protein L3 has been implicated, together with L24, in initiating assembly of the 50 S subunit and it shares the exceptional property with L24 that it binds adjacent to the junction of two RNA domains from where it can maximally influence RNA folding. Protein L6 also assembled to domain VI and, in a control experiment, protein L2 bound to isolated domain IV. Domain VI was largely inaccessible in the 50 S subunit and the few accessible RNA sites occurred mainly within conserved sequence regions that constitute potential functional sites. alpha-Sarcin inactivates ribosomes by cutting at one of these sites in 50 S subunits; it also recognized the same site in the free 23 S RNA and in the free domain. Both the EF-Tu ternary complex, and the EF-G ternary complex stabilized by fusidic acid or by a non-hydrolyzable GTP derivative, inhibited alpha-sarcin attack while non-enzymatically bound tRNA did not, thus providing evidence, more direct than before, for the involvement of the RNA region in a common elongation factor binding site.

Immunoelectron microscopic localisation of ribosomal proteins from Bacillus stearothermophilus that are homologous to Escherichia coli L1, L6, L23 and L29

The locations of proteins BL1, BL6, BL23 and BL29 from Bacillus stearothermophilus have been determined on the ribosomal surface by immunoelectron microscopy. All four proteins were localized in the same region of the 50S subunit as their homologous counterparts from Escherichia coli, indicating that the ribosomal architecture is the same in both species. This finding is of great importance as it allows structural data obtained on ribosomes from either organism to be incorporated into a unique ribosome model.

Electrostatic potential of macromolecules measured by pKa shift of a fluorophore. 1. The 3' terminus of 16S RNA

We have investigated the use of the pH-sensitive fluorescein label as a probe for electrostatic potential in macromolecules. The practicality of this technique is demonstrated by its application to the 16S RNA molecule. The dependence of the electrostatic potential upon ionic conditions and upon the presence of ribosomal proteins and the state of the RNA was studied. The combination of electrostatic and anisotropy data emphasizes the rôle of the 30S ribosomal proteins, rather than of the renaturation of the 16S RNA or the presence of the 50S subunit, in shaping the environment of the 3' terminus of the 16S RNA in the active ribosome.

RNA binding proteins of the large subunit of bovine mitochondrial ribosomes

RNA binding properties of proteins from the large subunit of bovine mitochondrial ribosomes were studied using four different approaches: binding of radiolabeled RNA to western blotted proteins; disassembly of the intact 39 S ribosomal subunits with urea; binding of ribosomal proteins to RNA in the presence of urea; and binding of proteins extracted with lithium chloride to RNA. Results from these four approaches allowed us to identify a set of six proteins (L7, L13, L14, L21, L26, and L44) which appear to be strong RNA binding proteins. Seven additional proteins (L8, L11, L28, L35, L40, L49, and L50) were identified as secondary RNA binding proteins. RNA binding properties of the proteins in both of these sets were compared with the topographic disposition and susceptibility towards lithium chloride extraction of the individual proteins. Proteins from the first set are good candidates for early assembly proteins since they have a high affinity for RNA, are generally found in 4M lithium chloride core particles, and are among the most buried proteins in the 39 S subunit.

The tertiary structure of salt-extracted ribosomal proteins from Escherichia coli as studied by proton magnetic resonance spectroscopy and limited proteolysis experiments

Ribosomal proteins from Escherichia coli have been isolated by a mild purification procedure. Their tertiary structure has been explored by two techniques, proton magnetic resonance and limited proteolysis. A number of proteins when subjected to limited proteolysis produce resistant fragments in good yields. In most cases this does not depend on the specificity of the enzyme used. The proteins S15, S16, S17 and L30 are not degraded at all, whereas a few proteins are very susceptible to proteolysis. 1H-NMR experiments show that the majority of the ribosomal proteins have a uniquely folded tertiary structure. This is particularly pronounced in the four proteins mentioned above which resist proteolysis. In general, a good agreement is observed between the degree of proteolytic resistance and the amount of folding indicated by NMR spectroscopy. Similar studies on a few ribosomal proteins purified under denaturing conditions show that, in contrast, these protein preparations are not structurally homogeneous and that they contain a mixture of denatured and renatured molecules. The results are interpreted in terms of a compactly folded tertiary structure for the four proteinase-resistant proteins while the majority of the other proteins appear to have two domains, one compactly folded and resistant to proteinase and the other flexible and susceptible to proteolysis. A few proteins seem to have a completely flexible structure and can therefore be easily degraded.

The secondary structure of salt-extracted ribosomal proteins from Escherichia coli as studied by circular dichroic spectroscopy

Ribosomal proteins from Escherichia coli MRE600 have been obtained by a new, mild purification procedure. This involves extraction of the subunits with salt followed by chromatographic fractionation in the presence of salt. The use of urea or other denaturing agents and conditions is avoided. A survey of the secondary structure of the 30 S and 50 S proteins, as observed by circular dichroic spectroscopy, is presented. The spectra have been analysed by a new procedure which uses a library of 16 circular dichroic spectra of proteins with a known three-dimensional structure. This method provides a more reliable analysis, especially of the contribution from beta-sheet. The results show that most of the 30 S proteins have a high alpha-helix content, whereas the 50 S proteins are more diverse. The latter group shows a larger contribution from beta-sheet. The data presented here are compared with those already published for a number of proteins which were, with one exception, prepared in the presence of urea. In most cases we find higher alpha-helix and beta-sheet values for the salt-extracted proteins than for the corresponding urea-treated proteins. In those cases, however, where special care was taken to renature the urea-treated proteins agreement is found to within the expected experimental error. The results show that salt-extracted ribosomal proteins have a well-defined secondary structure with a relatively small contribution from unordered structure.

Crystal structure of a prokaryotic ribosomal protein

The structure of ribosomal protein L30 from Bacillus stearothermophilus has been solved to a resolution of 2.5 A. The molecule is somewhat elongated and contains two helices and a three-stranded, anti-parallel beta-pleated sheet. The protein fold, in which helices pack on the same side of the sheet, generates a simple helix-sheet, two-layered motif. It is possible to distinguish three hydrophobic patches on the molecular surface, and one end has six isolated arginine and lysine residues. It is proposed that these reflect sites of protein-protein and protein-RNA interaction, respectively. The protein fold is very similar to that of the only other known ribosomal protein structure, L7/L12 from Escherichia coli, and, based on this similarity, an attempt is made to align the amino acid sequences of the two proteins.

Affinity chromatography with an immobilized RNA enzyme

M1 RNA, the catalytic subunit of Escherichia coli RNase P, has been covalently linked at its 3' terminus to agarose beads. Unlike M1 RNA, which is active in solution in the absence of the protein component (C5) of RNase P, the RNA linked to the beads is active only in the presence of C5 protein. Affinity chromatography of crude extracts of E. coli on a column prepared from the beads to which the RNA has been crosslinked results in the purification of C5 protein in a single step. The protein has been purified in this manner from cells that contain a plasmid, pINIIIR20, which includes the gene that codes for C5 protein. A 6-fold amplification of the expression of C5 protein is found in these cells after induction as compared to cells that do not harbor the plasmid.

Localization of L11 on the Escherichia coli ribosome by singlet-singlet energy transfer

Isolated Escherichia coli ribosomal protein L11 was labeled with maleimidyl derivatives of coumarin or fluorescein at the thiol group of its single cysteine, then reconstituted singly or in pairs with other fluorescently labeled ribosomal components. The characteristics of fluorescence from the labeled protein were studied and its distance to other components was determined by non-radiative energy transfer. The distance between probes on L11 and cysteine residues on other proteins or the 3' end of the ribosomal RNAs were found to be: S1, 7.4-8.3 nm; S21, 7.6 nm; 23S RNA, 6.9 nm; 5S RNA, 7.6 nm; 16S RNA, greater than 8.5 nm. Considered together with previously published results these distances indicate that the location of L11 in the 50S subunit is below the lateral protuberance characterized by L7/L12.

Rapid separation of Escherichia coli 30S ribosomal proteins by fast protein liquid chromatography (FPLC)

The proteins of the 30S ribosomal subunit from Escherichia coli have been separated by reverse-phase high-performance liquid chromatography on a short alkyl chain (C1/C8)-coated phase. The reverse-phase column was connected to a fast protein liquid chromatography (FPLC) system. The 21 proteins of the 30S ribosomal subunit were resolved into 16 peaks. Eleven proteins were isolated in purified form in a single chromatographic run as shown by polyacrylamide gel electrophoresis and amino acid analysis. Interestingly, the retention times of some proteins differed from the retention times observed on other reversed-phase support materials. The results show the speed and resolution of reverse-phase FPLC for both analytical and semi-preparative separations of 30S ribosomal proteins.

Effects of different amino-group reagents on ribosomal integrity: structural role of lysine residues

Treatment of 60S subunits from yeast ribosomes with dicarboxylic acid anhydrides (maleic, dimethylmaleic and tetrahydrophtalic), which introduces negatively-charged residues, is accompanied by substantial dissociation of protein components (35-55%). In contrast, acetic anhydride or cyanate, which introduce uncharged groups, cause practically no protein release, even after extensive modification. Therefore, in addition to blocking lysine-RNA interactions, a large change in the electric charge of the proteins appears to be necessary to obtain dissociation. These results seem to indicate that lysine residues are not essential to ribosome integrity, while arginine-RNA interactions should play an important role in the maintenance of ribosomal structure.

Studies of the GTPase domain of archaebacterial ribosomes

Ribosomes from the methanogens Methanococcus vannielii and Methanobacterium formicicum catalyse uncoupled hydrolysis of GTP in the presence of factor EF-2 from rat liver (but not factor EF-G from Escherichia coli). In this assay, and in poly(U)-dependent protein synthesis, they were sensitive to thiostrepton. In contrast, ribosomes from Sulfolobus solfataricus did not respond to factor EF-2 (or factor EF-G) but possessed endogenous GTPase activity, which was also sensitive to thiostrepton. Ribosomes from the methanogens did not support (p)ppGpp production, but did appear to possess the equivalent of protein L11, which in E. coli is normally required for guanosine polyphosphate synthesis. Protein L11 from E. coli bound well to 23S rRNA from all three archaebacteria (as did thiostrepton) and oligonucleotides protected by the protein were sequenced and compared with rRNA sequences from other sources.

Regulation of polyamine biosynthesis by antizyme and some recent developments relating the induction of polyamine biosynthesis to cell growth. Review

This review considers the role of antizyme, of amino acids and of protein synthesis in the regulation of polyamine biosynthesis. The ornithine decarboxylase of eukaryotic cells and of Escherichia coli can be non-competitively inhibited by proteins, termed antizymes, which are induced by di- and poly- amines. Some antizymes have been purified to homogeneity and have been shown to be structurally unique to the cell of origin. Yet, the E. coli antizyme and the rat liver antizyme cross react and inhibit each other's biosynthetic decarboxylases. These results indicate that aspects of the control of polyamine biosynthesis have been highly conserved throughout evolution. Evidence for the physiological role of the antizyme in mammalian cells rests upon its identification in normal uninduced cells, upon the inverse relationship that exists between antizyme and ornithine decarboxylase as well as upon the existence of the complex of ornithine decarboxylase and antizyme in vivo. Furthermore, the antizyme has been shown to be highly specific; its Keq for ornithine decarboxylase is 1.4 X 10(11) M-1. In addition, mammalian cells contain an anti-antizyme, a protein that specifically binds to the antizyme of an ornithine decarboxylase-antizyme complex and liberates free ornithine decarboxylase from the complex. In E. coli, in which polyamine biosynthesis is mediated both by ornithine decarboxylase and by arginine decarboxylase, three proteins (one acidic and two basic) have been purified, each of which inhibits both these enzymes. They do not inhibit the biodegradative ornithine and arginine decarboxylases nor lysine decarboxylase. The two basic inhibitors have been shown to correspond to the ribosomal proteins S20/L26 and L34, respectively. The relationship of the acidic antizyme to other known E. coli proteins remains to be determined. In mammalian cells, ornithine decarboxylase can be induced by a broad spectrum of compounds. These range from hormones and growth factors to natural amino acids such as asparagine and to non-metabolizable amino acid analogues such as alpha-amino-isobutyric acid. The amino acids that induce ornithine decarboxylase as well as those that promote polyamine uptake utilize the sodium dependent A and N transport systems. Consequently, they act in concert and increase intracellular polyamine levels by both mechanisms. The induction of ornithine decarboxylase by growth factors, such as NGF, EGF, and PDGF as well as by insulin requires the presence of these same amino acids and does not occur in their absence. However, the inducing amino acid need not be incorporated into protein nor covalently modified.(ABSTRACT TRUNCATED AT 400 WORDS)

Partial reconstitution of 60S ribosomal subunits from yeast

Ribosomal 60S subunits active in polyphenylalanine synthesis can be reconstituted from core particles lacking 20-40% of the total protein. These core particles were obtained by treatment of yeast 60S subunits with dimethylmaleic anhydride, a reagent for protein amino groups. Upon reconstitution a complementary amount of split proteins is incorporated into the ribosomal particles, which have the sedimentation coefficient of the original subunits. Ribosomal protein fractions obtained by extraction with 1.25 M NH4Cl, 4 M LiCl, 7 M LiCl, or 67% acetic acid, are much less efficient in the reconstitution of active subunits from these core particles than the corresponding released fraction prepared with dimethylmaleic anhydride. Attempts to reconstitute active subunits from protein-deficient particles obtained with 1.25 M NH4Cl plus different preparations of ribosomal proteins, including the fraction released with dimethylmaleic anhydride, were unsuccessful. Therefore, under our conditions, of the disassembly procedures assayed only dimethylmaleic anhydride allows partial reconstitution of active 60S subunits.

Stepwise dissociation of yeast 60S ribosomal subunits by LiCl and identification of L25 as a primary 26S rRNA binding protein

Treatment of yeast 60S ribosomal subunits with 0.5 M LiCl was found to remove all but six of the ribosomal proteins. The proteins remaining associated with the (26S + 5.8S) rRNA complex were identified as L4, L8, L10, L12, L16 and L25. These core proteins were split off sequentially in the order (L16 + L12), L10, (L4 + L8), L25 by further increasing the LiCl concentration. At 1.0 M LiCl only ribosomal protein L25 remains bound to the rRNA. Upon lowering the LiCl concentration the core proteins reassociate with the rRNA in the reverse order of their removal. The susceptibility of the ribosomal proteins to removal by LiCl corresponds quite well with their order of assembly into the 60S subunit in vivo as determined earlier [Kruiswijk et al. (1978) Biochim. Biophys. Acta 517, 378-389]. Binding studies in vitro using partially purified L25 showed that this protein binds specifically to 26S rRNA. Therefore our experiments for the first time directly identify a eukaryotic ribosomal protein capable of binding to high-molecular-mass rRNA. Binding studies in vitro using a blot technique demonstrated that core proteins L8 and L16 as well as protein L21, though not present in any of the core particles, are also capable of binding to 26S rRNA to approximately the same extent as L25. About nine additional 60S proteins appeared to interact with the 26S rRNA, though to a lesser extent.

Electron microscopy of secondary structure in partially denatured Escherichia coli 16S rRNA and 30S subunits

Loops observed in partially denatured 16S rRNA lie within three domains, each about 500 nucleotides long. The loops observed in the 5' and central domains agree well with features of the model proposed by Woese et al. [Woese, C. R., Gutell, R., Gupta, R., & Noller, H. F. (1983) Microbiol. Rev. 47, 621-669]. The structure in the 3' domain is more complex and variable but is still consistent with the model. Published psoralen cross-linking studies have reported one of the observed loops but have also identified loops other than those observed here or predicted by any secondary structure model. These loops are stabilized by increasing concentrations of Mg2+ ions and by bound ribosomal proteins. For example, protein S4 in LiCl core particles stabilizes a loop of 370 nucleotides which forms part of its putative binding site on rRNA. The loop structures are characteristic enough to permit an overall comparison of the most stable of the predicted and observed loops in 16S and 23S rRNAs. Both rRNAs show a stable 5'-terminal loop and a set of subterminal nested loops near the 3' end.

Purification of Escherichia coli 50 S ribosomal proteins by high performance liquid chromatography

The 50 S subunit proteins from the Escherichia coli ribosome were purified by size-exclusion, ion-exchange or reversed phase high performance liquid chromatography (HPLC) avoiding any precipitation or desalting procedures during isolation. Best resolution of this complex protein mixture was achieved by reversed phase chromatography on supports with short alkyl chains and C18 hydrocarbon-bonded phases; 23 out of the 32 proteins from the 50 S subunit were purified as shown by two-dimensional gel electrophoresis, amino acid analysis and direct micro-sequencing. Protein recoveries varied between 25 and 84% as determined by amino acid analysis. Ribosomal proteins of other organisms can be separated under similar conditions.