Protein binding sites on Escherichia coli 16S ribosomal RNA; RNA regions that are protected by proteins S7, S9 and S19, and by proteins S8, S15 and S17.

Selected groups of isolated 14C-labelled proteins from E. coli 30S ribosomal subunits were reconstituted with 32P-labelled 16S RNA, and the reconstituted complexes were partially digested with ribonuclease A. RNA fragments protected by the proteins were separated by gel electrophoresis and subjected to sequence analysis. Complexes containing proteins S7 and S19 protected an RNA region comprising helices 29 to 32, part of helix 41, and helices 42 and 43 of the 16S RNA secondary structure. Addition of protein S9 had no effect. When compared with previous data for proteins S7, S9, S14 and S19, these results suggest that S14 interacts with helix 33, and that S9 and S14 together interact with the loop-end of helix 41. Complexes containing proteins S8, S15 and S17 protected helices 7 to 10 as well as the "S8-S15 binding site" (helices 20, 22 and parts of helices 21 and 23). When protein S15 was omitted, S8 and S18 showed protection of part of helix 44 in addition to the latter regions. The results are discussed in terms of our model for the detailed arrangement of proteins and RNA in the 30S subunit.     

Flavors of protein disorder

Intrinsically disordered proteins are characterized by long regions lacking 3-D structure in their native states, yet they have been so far associated with 28 distinguishable functions. Previous studies showed that protein predictors trained on disorder from one type of protein often achieve poor accuracy on disorder of proteins of a different type, thus indicating significant differences in sequence properties among disordered proteins. Important biological problems are identifying different types, or flavors, of disorder and examining their relationships with protein function. Innovative use of computational methods is needed in addressing these problems due to relative scarcity of experimental data and background knowledge related to protein disorder. We developed an algorithm that partitions protein disorder into flavors based on competition among increasing numbers of predictors, with prediction accuracy determining both the number of distinct predictors and the partitioning of the individual proteins. Using 145 variously characterized proteins with long (>30 amino acids) disordered regions, 3 flavors, called V, C, and S, were identified by this approach, with the V subset containing 52 segments and 7743 residues, C containing 39 segments and 3402 residues, and S containing 54 segments and 5752 residues. The V, C, and S flavors were distinguishable by amino acid compositions, sequence locations, and biological function. For the sequences in SwissProt and 28 genomes, their protein functions exhibit correlations with the commonness and usage of different disorder flavors, suggesting different flavor-function sets across these protein groups. Overall, the results herein support the flavor-function approach as a useful complement to structural genomics as a means for automatically assigning possible functions to sequences.     

Affinity labeling the ribosome with eukaryotic-specific antibiotics: (bromoacetyl)trichodermin

Trichodermin, a eukaryotic-specific antibiotic, inhibits protein synthesis in Drosophila cells. We have synthesized a 14C-labeled bromoacetyl derivative of trichodermin that binds to Drosophila 80S ribosomes and once bound reacts covalently with ribosomal proteins. It does not react with rRNA. Three large-subunit proteins (L1, L3, and L24) and three small-subunit proteins (S3/S5, 2/3S, and S8) are labeled by [14C] (bromoacetyl)trichodermin. Reaction with each of these proteins can be competed by an excess of unmodified trichodermin, indicating that the labeling has occurred from the native binding site of the parent drug. One of the (bromoacetyl)trichodermin-labeled proteins (S8) is also labeled by photoactivated puromycin in the A site. A second protein (S3/S5) is found to be labeled by a P-site affinity reagent. The results suggest that the trichodermin binding site spans both the small and large subunits and portions of both the A and P sites. These data combined with previous studies on the A and P sites of Drosophila ribosomes have allowed us to construct a model of the protein locations in this important active site.     

Learning cellular sorting pathways using protein interactions and sequence motifs

Proper subcellular localization is critical for proteins to perform their roles in cellular functions. Proteins are transported by different cellular sorting pathways, some of which take a protein through several intermediate locations until reaching its final destination. The pathway a protein is transported through is determined by carrier proteins that bind to specific sequence motifs. In this article, we present a new method that integrates protein interaction and sequence motif data to model how proteins are sorted through these sorting pathways. We use a hidden Markov model (HMM) to represent protein sorting pathways. The model is able to determine intermediate sorting states and to assign carrier proteins and motifs to the sorting pathways. In simulation studies, we show that the method can accurately recover an underlying sorting model. Using data for yeast, we show that our model leads to accurate prediction of subcellular localization. We also show that the pathways learned by our model recover many known sorting pathways and correctly assign proteins to the path they utilize. The learned model identified new pathways and their putative carriers and motifs and these may represent novel protein sorting mechanisms. Supplementary results and software implementation are available from http://murphylab.web.cmu.edu/software/2010_RECOMB_pathways/.     

Mapping the three-dimensional locations of ribosomal RNA and proteins.

Seven regions of 16S rRNA have been located on the surface of the 30S ribosomal subunit by DNA hybridization electron microscopy in our laboratory. In addition, we have recently mapped the three-dimensional locations of an additional seven small ribosomal proteins by immunoelectron microscopy. The information from the direct mapping of the sites on rRNA has been incorporated into a model for the tertiary structure of 16S rRNA, accounting for approximately 40% of the total 16S rRNA. A novel structure, the platform ring, is proposed for a region of rRNA within the central domain. This structure rings the edges of the platform and includes regions 655-751 and 769-810. Another region, the recognition complex, consists of nucleotides 500-545, and occupies a region on the exterior surface of the subunit, near the EF-Tu binding site. In addition, 19 of the 21 small subunit ribosomal proteins have been mapped by immunoelectron microscopy in our laboratory. In order to evaluate the reliability of our model for the three-dimensional distribution of 16S rRNA, we have predicted which sites of rRNA are adjacent to ribosomal proteins and compared these predictions with r-protein protection studies of others. Good correlation between the model, the locations of rRNA sites, the locations of ribosomal proteins, and regions of rRNA protected by ribosomal proteins, provides independent support for this model.     

What curves alpha-solenoids? Evidence for an alpha-helical toroid structure of Rpn1 and Rpn2 proteins of the 26 S proteasome

The alpha-helical solenoid proteins adopt a variety of elongated curved structures. They have been examined to identify the interactions that determine their curvature. A sequence pattern characteristic for strongly curved alpha-helical solenoids has been constructed and was found to match protein sequences containing the proteasome/cyclosome repeats. Based on this, a structural model of the repeat-containing domains of the Rpn1/S2 and Rpn2/S1 proteins, which represent the largest subunits of the 26 S proteasome, has been proposed. The model has a novel architecture resembling an alpha-helical toroid. Molecular modeling shows that these toroids have a central pore that would allow passage of an unfolded protein substrate through it. This implies that the Rpn1 and Rpn2 toroids are aligned along the common axial pores of the ATPase hexamer and form an "antechamber" of the 26 S proteasome. The proposed quaternary structure agrees with the available experimental data. It is suggested that the function of this antechamber is assistance to the ATPases in the unfolding of protein substrates prior to proteolysis. An evolutionary link between the PC repeat-containing proteins and tetratricopeptide repeat proteins is proposed.     

Reverse-phase high-performance liquid chromatography of Escherichia coli ribosomal small subunit proteins

Reverse-phase high-performance liquid chromatography has been explored as an approach for the separation of the proteins of the 30 S subunit of Escherichia coli ribosomes. The majority of these proteins are of similar molecular weight and isoelectric point, making separation by size exclusion or ion exchange difficult. With the use of an octadecasilyl silica column and a trifluoroacetic acid-acetonitrile solvent system, the 21 proteins of the 30 S subunit have been separated into 15 peaks. The yield of total protein recovered from the column was ≥85%. The proteins present in each peak have been identified by polyacrylamide gel electrophoretic analysis of the peaks as well as by comparison with the relative retention volumes of known purified 30 S proteins on the column. The results clearly show that this method is a powerful and rapid technique for the identification and purification of 30 S proteins. Analysis of [³H]puromycin-labeled 30 S subunit protein provides an illustrative example of its utility for affinity labeling studies.     

Individual ribosomal protein pool size and turnover rate in Escherichia coli

The pool size of free individual ribosomal proteins present in the cell sap of Escherichia coli has been determined by pulse-labelling a culture before a chase with cold marker.Ribosomes plus ribosomal precursor particles were prepared together and the proteins from this fraction purified. The specific radioactivity of each 30 S and 50 S protein was measured at the time of pulse and at the various times of chase: unequal labelling was already observed at the time of pulse; the kinetics of chase of most 30 S proteins reached a plateau very rapidly; the kinetics of 50 S proteins were more variable. Precise calculation of individual pool size was carried out using the mathematical model described in the Appendix. Almost all ribosomal 30 S proteins have a pool size close to zero. Only four 30 S proteins (S10, S16, S17 and S18) have a sizeable pool (2 to 6% of the corresponding ribosomal protein). Most 50 S proteins have a small pool size (1 to 2%). The free ribosomal proteins of the pool are transferred to mature ribosomes; the half-life of these proteins in the pool has been calculated (0 to 1·4 min). Finally, as judged from the kinetic data, no degradation of ribosome-bound protein was apparent. The significance of the results is discussed with respect to the function of ribosome and the process of ribosome biogenesis.     

A detailed model of the three-dimensional structure of Escherichia coli 16 S ribosomal RNA in situ in the 30 S subunit

A large body of intra-RNA and RNA-protein crosslinking data, obtained in this laboratory, was used to fold the phylogenetically and experimentally established secondary structure of Escherichia coli 16 S RNA into a three-dimensional model. All the crosslinks were induced in intact 30 S subunits (or in some cases in growing E. coli cells), and the sites of crosslinking were precisely localized on the RNA by oligonucleotide analysis. The RNA-protein crosslinking data (including 28 sites, and involving 13 of the 21 30S ribosomal were used to relate the RNA structure to the distribution of the proteins as determined by neutron scattering. The three-dimensional model of the 16 S RNA has overall dimensions of 220 A x 140 A x 90 A, in good agreement with electron microscopic estimates for the 30 S subunit. The shape of the model is also recognizably the same as that seen in electron micrographs, and the positions in the model of bases localized on the 30 S subunit by immunoelectron microscopy (the 5' and 3' termini, the m7G and m6(2)A residues, and C-1400) correspond closely to their experimentally observed positions. The distances between the RNA-protein crosslink sites in the model correlate well with the distances between protein centres of mass obtained by neutron scattering, only two out of 66 distances falling outside the expected tolerance limits. These two distances both involve protein S13, a protein noted for its anomalous behaviour. A comparison with other experimental information not specifically used in deriving the model shows that it fits well with published data on RNA-protein binding sites, mutation sites on the RNA causing resistance to antibiotics, tertiary interactions in the RNA, and a potential secondary structural "switch". Of the sites on 16 S RNA that have been found to be accessible to chemical modification in the 30 S subunit, 87% are at obviously exposed positions in the model. In contrast, 70% of the sites corresponding to positions that have ribose 2'-O-methylations in the eukaryotic 18 S RNA from Xenopus laevis are at non-exposed (i.e. internal) positions in the model. All nine of the modified bases in the E. coli 16 S RNA itself show a remarkable distribution, in that they form a "necklace" in one plane around the "throat" of the subunit. Insertions in eukaryotic 18 S RNA, and corresponding deletions in chloroplast or mammalian mitochondrial ribosomal RNA relative to E. coli 16 S RNA represent distinct sub-domains in the structure.(ABSTRACT TRUNCATED AT 400 WORDS)     

Identification of the amino acid residues of proteins S5 and S8 adjacent to each other in the 30 S ribosomal subunit of Escherichia coli.

When Escherichia coli 30 S ribosomal subunits are reacted with protein-protein bifunctional reagents, a number of protein pairs as well as aggregates containing three or more ribosomal proteins are formed. In the present study we have purified one of the protein pairs obtained by reaction of 30 S ribosomal subunits with either radioactive or nonradioactive dimethylsuberimidate. Following molecular weight determination and ammonolysis, the pair was shown to consist of ribosomal proteins S5 and S8. The "native" structure of the complex was surmised from its capacity to be reconstituted into a biologically active 30 S ribosomal subunit. From peptide maps and primary structure determination of various peptides it was demonstrated that the cross-linking bond between ribosomal proteins S5 and S8 involves primarily the residues Lys-93 of protein S8 and the COOH-terminal lysine (Lys-166) of ribosomal protein S5. This result is substantiated by the finding that a mutant carrying an altered S5 lacking the COOH-terminal lysine yields a greatly reduced amount of S5-S8 cross-link. In addition to the points of cross-linking it was found that Lys-30, Lys-68, and Lys-86 of S8 and Lys-5 of S5 react with dimethylsuberimidate, indicating that these residues are available for reaction and suggesting their topographical localization on the ribosomal surface.     

Whey proteins as a model system for chromatographic separation of proteins

Although chromatographic separation of whey proteins has been considered too expensive, whey may serve as an excellent model mixture to investigate and validate the use of simulation tools in the development and optimization of chromatographic separations and the outcome could easily be utilized since the model system has an intrinsic value. Besides, milk from transgenic animals could be an attractive source of pharmaceuticals which must be separated from the other proteins in the milk. Several whey proteins are of interest especially, alpha-lactalbumin, beta-lactoglobulins, immunoglobulins, lactoperoxidase, and lactoferrin. The scope of the project is to develop a consistent set of chromatographic data for whey proteins including isotherms, transport properties and scale-up studies and to develop the appropriate models for the anion exchangers Q-Sepharose XL, Source 30Q, Ceramic Q-HyperD F, and Merck Fractogel EMD TMAE 650 (S). In this work we have determined and correlated gradient and isocratic retention volumes in the linear range of the isotherm for alpha-lactalbumin, beta-lactoglobulin A and B, and bovine serum albumin at a pH from 6 to 9 at various NaCl concentrations.     

IF-3 crosslinking to Escherichia coli ribosomal 30 S subunits by three different light-dependent procedures: Identification of 30 S proteins crosslinked to IF-3—Utilization of a new two-stage crosslinking reagent, p-nitrobenzylmaleimide

We here report the results of using three light-dependent procedures for crosslinking IF-3 to 30 S proteins within an IF-3·30 S complex. In the first procedure, employing FMN as a photosensitizer, protein S12 is found to be the only major crosslinked protein. In the second procedure, IF-3 is first reacted with the new two-stage crosslinking reagent, p-nitrobenzylmaleimide (PNBM), and the PNBM—IF-3·30 S complex is irradiated. The major crosslinked proteins are S3 > S2, S12, S18. Small amounts of crosslinked S11 and S21 are also found. In the third procedure, the IF-3·30 S complex is reacted with PNBM and then irradiated. The major crosslinked proteins are S12 > S3 > S11 and small amounts of crosslinked S1, S13, and S21 are also found. These results are compared with results obtained by others using different crosslinking procedures and are used to discuss the Lake and Kahan model (J. A. Lake and L. Kahan, 1975, J. Mol. Biol., 99, 631–644, and J. A. Lake, 1978, in Advanced Techniques in Biological Electron Microscopy II, Koehler, J. K., ed., pp. 173–211, Springer-Verlag, Berlin) for IF-3 binding to 30 S subunits.     

Ribosomal protein-nucleic acid interactions. I. Isolation of a polypeptide fragment from 30S protein S8 which binds to 16S rRNA.

Within the bacterial ribosome a large number of specific protein and rRNA interactions appear to be required for assembly of the particle and its subsequent function in protein synthesis. In this communication it is shown that it is possible to isolate cyanogen bromide digestion products from ribosomal 30S protein S8 which will interact stoichiometrically with 16S rRNA. In addition to this a small binding polypeptide was generated from S8-16S rRNA complexes which were treated with proteinase K. The digestion of the complex yields a "protected" fragment of protein S8 which binds to 16S-rRNA. The isolated fragment will reassociate with 16S rRNA. It is not displaced by other 30S ribosomal proteins and blocks the binding of intact S8 to 16S rRNA. The size the possible structure of the S8 protein binding site are discussed and compared with the binding of cyanogen bromide digestion products which bind to 16S rRNA.     

Further evidence that the ribosomal 30S proteins S3, S5, S9, S11, S12, and S18 possess specific 16S RNA binding sites

Summary E. coli ribosomal 16S RNA preparted by an acetic acid-urea extraction technique individually binds, in addition to the seven established proteins, 6 new 30S ribosomal proteins (S3, S5, S9, S12, S18 and S11) (Hochkeppel et al., 1976). In this communication we demonstrate the site specificity of these proteins. Binding curves of the individual proteins with acetic acid-urea 16S RNA show that the binding of all six proteins to the RNA reaches a plateau at 0.3–0.97 copies per 16S RNA molecule. No significant binding of these proteins to classical phenol extracted 16S RNA is observed, with the exception of S13 which binds 0.2 copies of protein per molecule of 16S RNA. Specificity of binding of these proteins is also demonstrated in chase experiments. The site specificity of individual [³H]-labeled 30S proteins bound to 16S RNA is tested by the addition of non-radioactive 30S total protein to the reaction mixture.     

Translational repression of the Escherichia coli alpha operon mRNA: importance of an mRNA conformational switch and a ternary entrapment complex

Ribosomal protein S4 represses synthesis of the four ribosomal proteins (including itself) in the Escherichia coli alpha operon by binding to a nested pseudoknot structure that spans the ribosome binding site. A model for the repression mechanism previously proposed two unusual features: (i) the mRNA switches between conformations that are "active" or "inactive" in translation, with S4 as an allosteric effector of the inactive form, and (ii) S4 holds the 30 S subunit in an unproductive complex on the mRNA ("entrapment"), in contrast to direct competition between repressor and ribosome binding ("displacement"). These two key points have been experimentally tested. First, it is found that the mRNA pseudoknot exists in an equilibrium between two conformers with different electrophoretic mobilities. S4 selectively binds to one form of the RNA, as predicted for an allosteric effector; binding of ribosomal 30 S subunits is nearly equal in the two forms. Second, we have used S4 labeled at a unique cysteine with either of two fluorophores to characterize its interactions with mRNA and 30 S subunits. Equilibrium experiments detect the formation of a specific ternary complex of S4, mRNA pseudoknot, and 30 S subunits. The existence of this ternary complex is unambiguous evidence for translational repression of the alpha operon by an entrapment mechanism.     

The ABC transporters of Saccharomyces cerevisiae

The ABC transporters (ATP Binding Cassette) compose one of the bigest protein family with the great medical, industrial and economical impact. They are found in all organism from bacteria to man. ABC proteins are responsible for resistance of microorganism to antibiotics and fungicides and multidrug resistance of cancer cells. Mutations in ABC transporters genes cause seriuos deseases like cystic fibrosis, adrenoleucodystrophy or ataxia. Transport catalized by ABC proteins is charged with energy from the ATP hydrolysis. The ABC superfamily contains transporters, canals, receptors. Analysis of the Saccharomyces cerevisiae genome allowed to distinguish 30 potential ABC proteins which are classified into 6 subfamilies. The structural and functional similarity of the yeast and human ABC proteins allowes to use the S. cerevisiae as a model organism for ABC transporters characterisation. In this work the present state of knowleadge on yeast S. cerevisiae ABC proteins was summarised.     

Identification of neighbor relationships among proteins in the 30 S ribosome: intermolecular cross-linkage of three proteins induced by tetranitromethane

Earlier studies have indicated that the reaction of tetranitromethane with the 30 S riboaome from Escherichia coli results in the disappearance of two protein bands from the polyacrylamide gel electrophoresis pattern (Craven et al., 1969b). As tetranitromethane is known to induce intermolecular cross-linkage in other protein systems, we studied further this reaction with the view that it might yield knowledge of protein-protein neighbor relationships within the ribosome.The use of two-dimensional polyacrylamide gel electrophoresis showed that the reaction with tetranitromethane caused the disappearance of four proteins from the pattern of 30 S ribosomal proteins. It was shown that this alteration in electrophoretic behavior was not due to simple protein modification (e.g. production of 3-nitrotyrosine), as reaction with extracted protein in 8 M-urea resulted in no observable change in the electrophoretic pattern.It was also shown that three of these proteins could be uniquely labeled with [¹⁴C]iodoacetate without changing their reactivity with tetranitromethane. Thus, ribosomes were labeled with [¹⁴C]iodoacetate, reacted with tetranitromethane and the radioactive reaction products were isolated by column chromatography and preparative gel electrophoresis. The radioactive peptide patterns of the three proteins digested by trypsin were compared with the three major reaction products. One of these products was shown to contain the radioactive tryptic peptides of all three proteins. We believe that this reaction product is an intermolecular cross-linked aggregate of these three proteins, identified as S11, S18 and S21. We suggest that these three proteins are clustered closely together in the 30 S ribosome. The fourth protein, S12, may also be involved in this aggregate.