Identification of Escherichia coli ribosomal proteins by an alternative two-dimensional electrophoresis system.

We have developed a two-dimensional gel electrophoretic system for the identification of Escherichia coli ribosomal proteins that involves the use of acid-urea in the first dimension and sodium dodecyl sulfate in the second dimension. This system has high sensitivity, resolution, and speed, and it is more convenient than others previously described. We have identified individual E. coli ribosomal proteins by this system.

Interaction of proteins S16, S17 and S20 with 16 S ribosomal RNA.

We have used rapid chemical probing methods to examine the effect of assembly of ribosomal proteins S16, S17 and S20 on the reactivity of individual residues of 16 S rRNA. Protein S17 strongly protects a compact region of the RNA between positions 245 and 281, a site previously assigned to binding of S20. Protein S20 also protects many of these same positions, albeit more weakly than S17. Strong S20-dependent protections are seen elsewhere in the 5' domain, most notably at positions 108, and in the 160-200 and 330 loop regions. Enenpectedly, S20 also causes protection of several bases in the 1430-1450 region, in the 3' minor domain. In the presence of the primary binding proteins S4, S8 and S20, we observe a variety of effects that result from assembly of the secondary binding protein S16. Most strongly protected are nucleotides around positions 50, 120, 300 to 330 and 360 in the 5' domain, and positions 606 to 630 in the central domain. In addition, numerous nucleotides in the 5' and central domains exhibit enhanced reactivity in response to S16. Interestingly, the strength of the S20-dependent effects in the 1430-1450 region is attenuated in the presence of S4 + S8 + S20, and restored in the presence of S4 + S8 + S20 + S16. Finally, the previously observed rearrangement of the 300 region stem-loop that occurs during assembly is shown to be an S16-dependent event. We discuss these findings with respect to assignment of RNA binding sites for these proteins, and in regard to the co-operativity of ribosome assembly.

Interaction of ribosomal proteins, S6, S8, S15 and S18 with the central domain of 16 S ribosomal RNA.

We have constructed complexes of ribosomal proteins S8, S15, S8 + S15 and S8 + S15 + S6 + S18 with 16 S ribosomal RNA, and probed the RNA moiety with a set of structure-specific chemical and enzymatic probes. Our results show the following effects of assembly of proteins on the reactivity of specific nucleotides in 16 S rRNA. (1) In agreement with earlier work, S8 protects nucleotides in and around the 588-606/632-651 stem from attack by chemical probes; this is supported by protection in and around these same regions from nucleases. In addition, we observe protection of positions 573-575, 583, 812, 858-861 and 865. Several S8-dependent enhancements of reactivity are found, indicating that assembly of this protein is accompanied by conformational changes in 16 S rRNA. These results imply that protein S8 influences a much larger region of the central domain than was previously suspected. (2) Protein S15 protects nucleotides in the 655-672/734-751 stem, in agreement with previous findings. We also find S15-dependent protection of nucleotides in the 724-730 region. Assembly of S15 causes several enhancements of reactivity, the most striking of which are found at G664, A665, G674, and A718. (3) The effects of proteins S6 and S18 are dependent on the simultaneous presence of both proteins, and on the presence of protein S15. S6 + S18-dependent protections are located in the 673-730 and 777-803 regions. We observed some variability in our results with these proteins, depending on the ratio of protein to RNA used, and in different trials using enzymatic probes, possibly due to the limited solubility of protein S18. Consistently reproducible was protection of nucleotides in the 664-676 and 715-729 regions. Among the latter are three of the nucleotides (G664, G674 and A718) that are strongly enhanced by assembly of protein S15. This result suggests that an S15-induced conformational change involving these nucleotides may play a role in the co-operative assembly of proteins S6 and S18.

Probing the assembly of the 3' major domain of 16 S ribosomal RNA. Quaternary interactions involving ribosomal proteins S7, S9 and S19.

We have studied the effect of assembly of ribosomal proteins S7, S9 and S19 on the accessibility and conformation of nucleotides in 16 S ribosomal RNA. Complexes formed between 16 S rRNA and S7, S7 + S9, S7 + S19 or S7 + S9 + S19 were subjected to a combination of chemical and enzymatic probes, whose sites of attack in 16 S rRNA were identified by primer extension. The results of this study show that: (1) Protein S7 affects the reactivity of an extensive region in the lower half of the 3' major domain. Inclusion of proteins S9 or S19 with S7 has generally little additional effect on S7-specific protection of the RNA. Clusters of nucleotides that are protected by protein S7 are localized in the 935-945 region, the 950/1230 stem, the 1250/1285 internal loop, and the 1350/1370 stem. (2) Addition of protein S9 in the presence of S7 causes several additional effects principally in two structurally distal regions. We observe strong S9-dependent protection of positions 1278 to 1283, and of several positions in the 1125/1145 internal loop. These findings suggest that interaction of protein S9 with 16 S rRNA results in a structure in which the 1125/1145 and 1280 regions are proximal to each other. (3) Most of the strong S19-dependent effects are clustered in the 950-1050 and 1210-1230 regions, which are joined by base-pairing in the 16 S rRNA secondary structure. The highly conserved 960-975 stemp-loop, which has been implicated in tRNA binding, appears to be destabilized in the presence of S19. (4) Protein S7 causes enhanced reactivity at several sites that become protected upon addition of S9 or S19. This suggests that S7-induced conformational changes in 16 S rRNA play a role in the co-operativity of assembly of the 3' major domain.

A cyanogen bromide fragment of S4 that specifically rebinds 16S RNA.

Escherichia coli ribosomal protein S4 was subjected to cyanogen bromide cleavage and was found to generate a complete cleavage product capable of rebinding 16S rRNA. This fragment, consisting of residues 1-103, was found to bind with an apparent association constant of 11 microM-1. This fragment was used in place of S4 in an in vitro reconstitution experiment. Although the particles formed had a protein composition not significantly different from reconstituted 30S ribosomal subunits, their sedimentation behavior was more like that of particles reconstituted without S4. These results indicate to us that, although residues 104-203 of S4 are involved in the assembly of the 30S ribosome, they are not necessary for the binding of S4 to 16S RNA. Taken with previous results, the domain of S4 involved in specific binding of 16S RNA can be confined to residues 47-103.

A rapid and preparative method for the separation of yeast ribosomal proteins by using high-performance liquid chromatography.

Ribosomal proteins from the yeast Saccharomyces cerevisiae were separated, on a preparative scale, by ion-exchange h.p.l.c. Proteins from the small and large ribosomal subunits were resolved, respectively, into 33 and 23 peaks, and most of the proteins present in these peaks were identified by using one- and two-dimensional gel electrophoresis. Several of the peaks appeared to contain a single protein uncontaminated by other species. Ribosomal proteins were also separated by using reverse-phase h.p.l.c. Analysis of the peaks resolved indicated that the order of elution for the proteins of both ribosomal subunits is, in certain cases, different for each of the two h.p.l.c. techniques used. Thus a combination of the two chromatographic methods employed here has the potential to facilitate the rapid and preparative separation of each of the proteins present in yeast ribosomes.

Preparative ion-exchange high-performance liquid chromatography of bacterial ribosomal proteins.

We have developed analytical and preparative ion-exchange HPLC methods for the separation of bacterial ribosomal proteins. Proteins separated by the TSK SP-5-PW column were identified with reverse-phase HPLC and gel electrophoresis. The 21 proteins of the small ribosomal subunit were resolved into 18 peaks, and the 32 large ribosomal subunit proteins produced 25 distinct peaks. All peaks containing more than one protein were resolved using reverse-phase HPLC. Peak volumes were typically a few milliliters. Separation times were 90 min for analytical and 5 h for preparative columns. Preparative-scale sample loads ranged from 100 to 400 mg. Overall recovery efficiency for 30S and 50S subunit proteins was approximately 100%. 30S ribosomal subunit proteins purified by this method were shown to be fully capable of participating in vitro reassembly to form intact, active ribosomal subunits.

Chemical and functional characterization of an altered form of ribosomal protein S4 derived from a strain of E. coli defective in auto-regulation of the alpha operon.

We have isolated a mutant form of Escherichia coli ribosomal protein S4. This mutant is temperature sensitive and apparently fails to autogenously regulate the gene products of the alpha operon, which consists of the genes for proteins S13, S11, S4, L17, and the alpha subunit of RNA polymerase (1). We have shown that this mutation results in the production of an S4 protein with a molecular weight approximately 4,000 daltons less than the wild-type protein. Our chemical analyses demonstrate that the mutant protein is missing its C-terminal section consisting of residues 170-203. However, our studies to determine the capacity of this mutant protein to bind 16S RNA show that this protein is unimpaired in RNA binding function. This observation suggests that the functional domain of protein S4 responsible for translational regulation of the S4 gene products requires more of the protein than the 16S RNA binding domain.

Application of high-performance liquid chromatography to the purification and characterization of ribosomal protein L3 from trichodermin-resistant yeast mutants.

A new h.p.l.c. cation-exchange method has been used to separate proteins from 60S ribosomal subunits prepared from strains of Saccharomyces cerevisiae sensitive or resistant to trichodermin. Ribosomal protein L3 was identified in column eluates by one-dimensional and two-dimensional gel electrophoresis and purified further by reverse-phase h.p.l.c. The protein was cleaved with CNBr and the products were analysed, again by reverse-phase h.p.l.c. A marked difference was observed in the peptide profiles between preparations from trichodermin-sensitive and trichodermin-resistant yeast strains. These results provide the first direct demonstration that, in yeast, mutationally induced resistance to trichodermin can alter the covalent structure of ribosomal protein L3. They convincingly demonstrate the potential of the experimental technique for the rapid and preparative separation of a selected yeast ribosomal protein and its subsequent characterization.

Studies on the kinetic sequence of in vitro ribosome assembly using cibacron blue F3GA as a general assembly inhibitor.

We have found that all E. coli ribosomal proteins strongly bind to an agarose affinity column derivatized with the dye Cibacron Blue F3GA. We have also shown that the capacity to bind the dye is lost when the proteins are organized within the structure of the ribosome or are members of pre-formed protein-RNA complexes. We conclude that the binding of ribosomal proteins to this dye involves specific protein-RNA recognition sites. These observations led us to discover that Cibacron Blue can be used to inhibit in vitro ribosome assembly at any stage of the assembly process. This has allowed us to determine a kinetic order of ribosome assembly.

The use of hydroxylamine cleavage to produce a fragment of ribosomal protein S4 which retains the capacity to specifically bind 16S ribosomal RNA.

In previous reports we have described the isolation of fragments of 30S ribosomal protein S4 using a number of different enzymatic and chemical cleavage techniques. These experiments were designed to determine the region of the protein responsible for 16S RNA recognition. We report here the isolation of two fragments produced by the hydroxylamine cleavage of the asparaginyl-glycyl peptide bond between positions 124 and 125. The purified fragments were chemically identified and tested for RNA binding capacity. The fragment consisting of residues 1-124 retains RNA binding activity and the fragment 125-203 is totally without RNA binding function. These results and previous results strongly suggest that the domain of protein S4 responsible for 16S RNA specific association is within the region consisting of residues 46-124.

Specific ribosomal RNA recognition by a fragment of E. coli ribosomal protein S4 missing the C-terminal 36 amino acid residues.

We have previously investigated the role of the N-terminal region of ribosomal protein S4 to participate in 30S ribosome assembly and function (1-3). In this report we extend these studies to the two fragments produced by the chemical cleavage of protein S4 at the tryptophan residue 167. We find that the carboxyl terminal fragment (168-203) does not bind 16S RNA nor does it participate in assembly with the other 20 proteins from the 30S ribosome. In contrast, the larger fragment (1-167), does bind 16S RNA specifically. If the S4-fragment (1-167) is used to replace protein S4 in the complete 30S assembly reaction, all 20 of the other 30S proteins are incorporated. We conclude that the carboxyl terminal section of the protein S4 is not directly involved in binding 16S RNA or in the assembly of any of the other 30S proteins.

Evidence that E. coli ribosomal protein S13 has two separable functional domains involved in 16S RNA recognition and protein S19 binding.

We have found that E. coli ribosomal protein S13 recognizes multiple sites on 16S RNA. However, when protein S19 is included with a mixture of proteins S4, S7, S8, S16/S17 and S20, the S13 binds to the complex with measurably greater strength and with a stoichiometry of 1.5 copies per particle. This suggests that the protein may have two functional domains. We have tested this idea by cleaving the protein into two polypeptides. It was found that one of the fragments, composed of amino acid residues 84-117, retained the capacity to bind 16S RNA at multiple sites. Protein S19 had no affect on the strength or stoichiometry of the binding of this fragment. These data suggest that S13 has a C-terminal domain primarily responsible for RNA recognition and possibly that the N-terminal region is important for association with protein S19.

Apparent association constants for E. coli ribosomal proteins S4, S7, S8, S15, S17 and S20 binding to 16S RNA.

We have previously reported the development of a technique utilizing nitrocellulose filters, which rapidly separates ribosomal protein-ribosomal RNA complexes from unbound protein. We have used this technique to obtain binding data for the association of proteins S4, S7, S8, S15, S17, and S20 with 16S RNA. With the exception of protein S17, the association behavior for each of these proteins exhibits a single binding site with a unique binding constant. The apparent association constants have been calculated and have been found to have a range from 1.6 x 10(6) M-1 for protein S7 to 7.1 x 10(7) M-1 for protein S17. The Scatchard plot for the protein S17 binding data is biphasic, suggesting that within the RNA population two different binding sites exist, each with a different apparent association constant.

Partial purification and characterization of the proteins from the 40-S ribosomes of Artemia salina and wheat germ.

The proteins were extracted from purified 40-S ribosomes derived from wheat germ and Artemia salina and separated by carboxymethylcellulose ion-exchange chromatography. Approximately four proteins from Artemia and four proteins from wheat germ were separated in a state of high purity. All proteins were identified by co-electrophoresis using a two-dimensional polyacrylamide gel system. A total of 30 unique proteins were found for Artemia and 32 proteins for wheat. The molecular weights of all proteins were estimated by sodium dodecylsulfate gel electrophoresis. Assuming each protein to be present in one copy per 40-S ribosome, the total protein molecular weight was estimated to be 560,000 associated with Artemia 40-S particles and 550,000 associated with wheat germ 40-S ribosomes.

Analysis of protein--protein relationships in 30S ribosome assembly intermediates using protection from proteolytic digestion.

Treatment of the intact bacterial ribosome with proteolytic enzymes results in little or no digestion of many of the component proteins [Craven, G. R., & Gupta, V. (1970) Proc. Natl. Acad. Sci. U.S.A. 67, 1329]. In contrast, when the proteins are released from the constraints of ribosome structure they become completely susceptible to proteolytic attack. We have attempted to exploit these observations in an effort to determine the precise steps in ribosome assembly which result in a conversion of the structures of the various proteins from a proteolysis sensitive to a resistant form. Thus, a total of 11 30S ribosome assembly intermediate complexes of proteins and 16S RNA were prepared and digested with trypsin or chymotrypsin. The kinetics of digestion of each protein in the complex were followed by polyacrylamide gel electrophoresis. By a comparison of the digestion pattern of two complexes differing only by the presence of a single protein, it was possible to deduce several specific protective effects of one protein on its neighbor in the complex. On the basis of these studies, we propose nine protein-protein protective effects. The possible relevance of these interrelationships to other well-established proximity relationships is discussed.