Protein synthesis in Bacillus subtilis. I. Hydrodynamics and in vitro functional properties of ribosomes from B. subtilis W168.

On the basis of their sedimentation properties, the ribosomal particles in crude extracts of Bacillus subtilis W168 are characterized as pressure-sensitive couples, pressure-resistant couples, or non-associating subunits. Pressure-sensitive couples dissociate into subunits, yielding a peak at 60 S in the gradient profile, on sedimentation at high speed in the presence of 10 to 15 mm-Mg²⁺. Under the same conditions, pressure-resistant couples sediment at 70 S. Under certain conditions, pressure-resistant couples apparently aggregate, possibly in 70 S · 70 S dimers. Procedures are described for the isolation of pressure-sensitive couples from B. subtilis. The isolated couples are shown by chemical fixation experiments to require approximately twice the Mg²⁺ concentration required by Escherichia coli couples to remain associated at atmospheric pressure.All three types of B. subtilis ribosome incorporate amino acids into acid-insoluble material in the presence of B. subtilis cellular RNA, B. subtilis ribosomal salt wash fraction, and E. coli post-ribosomal supernatant. Overall incorporation, dependence on added RNA, and dependence on salt wash fraction are greatest with pressure-sensitive couples. The products of protein synthesis in vitro stimulated by total B. subtilis RNA appear to be a low molecular weight subset of the proteins synthesized most abundantly in vivo. Incubation of pressure-sensitive couples with cellular RNA from B. subtilis, fMet-tRNA_f^Met, ribosomal salt wash fraction and GTP results in their conversion to pressure-resistant couples, with concomitant and stoichiometric binding of fMet-tRNA to the 70 S species. It is concluded that in B. subtilis as in E. coli, pressure-sensitive couples are “vacant”, while pressure-resistant couples are “complexed” with messenger RNA. fMet-tRNA-bearing complexed couples are interpreted as initiation complexes in which ribosomes have bound mRNA, presumably at initiation sites. Their formation in vitro is strictly dependent on RNA, salt wash fraction and fMet-tRNA when vacant ribosomal couples are used.     

Reconstitution of active 50 S ribosomal subunits from Bacillus licheniformis and Bacillus subtilis.

Active 50 S ribosomal subunits from Bacillus licheniformis and Bacillus subtilis can be reconstituted in vitro from dissociated RNA and proteins. The reconstituted 50 S sub-units are indistinguishable from native 50 S subunits in sedimentation on sucrose gradients and in protein composition. The procedure used is similar to that developed for reconstitution of Bacillus stearothermophilus 50 S subunits, though the optimal conditions are somewhat different. Hybrid ribosomes can be reconstituted with 23 S RNA and proteins from different sources (B. stearothermophilus and B. licheniformis or B. subtilis). The thermal stability of these ribosomes depends on the source of the proteins, and not on the source of 23 S RNA.     

Protein-protein proximity in the association of ribosomal subunits of Escherichia coli: crosslinking of 30 S protein S16 to 50 S proteins by glutaraldehyde or formaldehyde

The interaction of ribosomal subunits from Escherichia coli has been studied using crosslinking reagents. Radioactive ³⁵S-labeled 50 S subunits and non-radioactive 30 S subunits were allowed to reassociate to form 70 S ribosomes. The 70 S particles, containing radioactivity only in the 50 S protein moiety, were incubated with glutaraldehyde or formaldehyde. As a result of this treatment a substantial fraction of the 70 S particles did not dissociate at 1 mm-Mg²⁺. This fraction was isolated and the ribosomal proteins were extracted. The protein mixture was analyzed by the Ouchterlony double diffusion technique by using eighteen antisera prepared against single 30 S ribosomal proteins (all except those against S3, S15 and S17). As a result of the crosslinking procedure it was found that only anti-S16 co-precipitated ³⁵S-labeled 50 S protein. It is concluded that the 30 S protein S16 is at or near the site of interaction between subunits and can become crosslinked to one or more 50 S ribosomal proteins.     

Purification and characterization of 30S ribosomal proteins from Bacillus subtilis: correlation to Escherichia coli 30S proteins

Summary Twenty proteins were isolated from the 30S ribosomal subunits of Bacillus subtilis and their amino acid compositions and amino-terminal amino acid sequences were determined. These results were compared with the data of Escherichia coli 30S ribosomal proteins and the structural correspondence of individual ribosomal proteins has been established between B. subtilis and E. coli.Post-translational modifications of amino-terminal amino acids of the ribosomal proteins which have been found in E. coli are almost absent in B. subtilis with the exception of acetylated forms of S9.     

Maize mitochondria: purification and characterization of ribosomes and ribosomal ribonucleic Acid

Mitochondria were prepared from etiolated maize shoots (Zea mays L. var. McNair 508) by homogenization followed by differential centrifugation and equilibrium banding in discontinuous sucrose or Renografin-sucrose gradients. Mitochondria prepared by sucrose banding showed better physiological integrity than those prepared by renografin-sucrose banding, although both procedures yielded mitochondria that showed respiratory control and coupling of oxidation to phosphorylation of ADP. Mitochondria prepared by Renografin-sucrose banding were free of dectectable cytoplasmic ribosomal RNA, while sucrose banding resulted in a low level of contamination. Ribosomes isolated from mitochondria sedimented at about 78S, with subunits sedimenting at 60 and 44S. Using Escherichia coli ribosomal RNA as internal standards, the molecular weights of mitochondrial ribosomal RNAs were found to be 0.74 to 0.75 and 1.26 × 10⁶ daltons by polyacrylamide gel electrophoresis, before or after denaturation in formaldehyde. Cytoplasmic ribosomal RNA molecular weights were 0.70 and 1.26 × 16⁶ before denaturation, and 0.68 and 1.5 × 10⁶ after denaturation, suggesting an unusual reaction of the heavy ribosomal RNA to formaldehyde.     

Effect of polyamines on in vitro reconstitution of ribosomal subunits

The effect of polyamines on in vitro reconstitution of Escherichia coli 30S and 50S ribosomal subunits has been studied. Spermidine stimulated the reconstitution of 30S particles from 16S rRNA lacking the methyl groups on two neighboring adenines and total proteins of 30S subunits at least 1.6-fold. The reconstitution of 30S particles from normal 16S rRNA and total proteins of 30S subunits exhibited only slight spermidine stimulation. However, the optimal Mg2+ concentration of the reconstitution was decreased from 20 mM to 16 mM in the presence of 3 mM spermidine. In the absence of spermidine the assembly of 30S particles from normal 16S rRNA was more rapid than the assembly from 16S rRNA lacking the methyl groups on two neighboring adenines. The reconstitution of 50S particles from 23S and 5S rRNA and total proteins of 50S subunits was not influenced greatly by spermidine. Gel electrophoresis results, from reconstitution experiments of 30S particles from 16S rRNA lacking the methyl groups on two neighboring adenines and total proteins of 30S subunits, showed that the assembly of S1 and S9 proteins to 23S core particles was stimulated by spermidine during reconstitution. The relationship of polyamine effects on in vitro ribosome assembly from its constituents to in vivo ribosome assembly is discussed. The reconstitution of Bacillus subtilis 30S particles from 16S rRNA and total proteins of 30S subunits was also stimulated approximately 1.3-fold by 3 mM spermidine.     

Functional Inactivation and Appearance of Breaks in RNA Chains Caused by Gamma Irradiation of Escherichia coli Ribosomes

70S ribosomes and 30S ribosomal subunits from Escherichia coli MRE 600 were exposed to gamma irradiation at -80szC. Exponential decline of activity with dose was observed when the ability of ribosomes to support the synthesis of polyphenylalanine was assayed. Irradiated ribosomes showed also an increased thermal lability. D₃₇ values of 2.2 MR and 4.8 MR, corresponding to radiation-sensitive molecular weights of 3.1 × 10⁵ and 1.4 × 10⁵, were determined for inactivation of 70S ribosomes and 30S subunits, respectively. Zone sedimentation analysis of RNA isolated from irradiated bacteria or 30S ribosomal subunits showed that at average, one chain scission occurs per four hits into ribosomal RNA. From these results it was concluded that the integrity of only a part of ribosomal proteins (the sum of their molecular weights not exceeding 1.4 × 10⁵) could be essential for the function of the 30S subunit in the polymerization of phenylalanine. This amount is smaller if the breaks in the RNA chain inactivate the ribosome.     

RNase J1 endonuclease activity as a probe of RNA secondary structure

Reliable determination of RNA secondary structure depends on both computer algorithms and experimental probing of nucleotides in single- or double-stranded conformation. Here we describe the exploitation of the endonucleolytic activity of the Bacillus subtilis enzyme RNase J1 as a probe of RNA structure. RNase J1 cleaves in single-stranded regions and, in vitro at least, the enzyme has relatively relaxed nucleotide specificity. We confirmed the feasibility of the approach on an RNA of known structure, B. subtilis tRNA^Thr. We then used RNase J1 to solve the secondary structure of the 5′ end of the hbs mRNA. Finally, we showed that RNase J1 can also be used in footprinting experiments by probing the interaction between the 30S ribosomal subunit and the Shine–Dalgarno element of the hbs mRNA.     

Properties of ribosomes and RNA synthesized by Escherichia coli grown in the presence of ethionine. V. Methylation dependence on the assembly of E. coli 50 S ribosomal subunits.

An ethionine-containing submethylated particle related to the 50 S ribosomal subunit has been isolated from Escherichia coli grown in the presence of ethionine. This particle (E-50S) lacks L16, contains reduced amounts of L6, L27, L28 and L30 and possesses a more labile and flexible structure than the normal 50 S subunit. The E-50S particle has defective association properties and is incapable of peptide bond formation. It can be converted to an active 50 S ribosomal subunit when ethionine-treated bacteria are incubated under conditions which permit methylation of submethylated cellular components (presence of methionine) in the absence of de novo protein and RNA synthesis (presence of rifampicin).Total reconstitution of 50 S ribosomal subunits in vitro using normal 23 S and 5 S ribosomal RNA and proteins prepared from E-50S particles yields active subunits only if L16 is also added. The hypothesis that E-50S particles accumulate in ethionine-treated bacteria because the absence of methylation of one or more of their components blocks a late stage (L16 integration) in the normal 50 S assembly process is discussed.     

Stimulation by polyamines of enzymatic methylation of two adjacent adenines near the 3′ end of 16S ribosomal RNA of Escherichia coli

Effect of polyamines on the methylation of adenine in 16S rRNA was examined using the purified methylating enzyme. When 23S core particles were used as substrate, the activity was stimulated by Mg²⁺, Ca²⁺ and monovalent cations. Even in the presence of optimal concentrations of Mg²⁺ and NH₄⁺, the addition of 1 mM spermidine stimulated the methylation approximately 1.7-fold. When 30S ribosomal subunits were used as substrate, the rate of methylation was 20% of that of the methylation of 23S core particles. The activity was not influenced significantly by Mg²⁺, Ca²⁺ or monovalent cations. The addition of spermidine inhibited the methylation.     

Surface topography of the Bacillus stearothermophilus ribosome.

Summary The surface topography of the intact 70S ribosome and free 30S and 50S subunits from Bacillus stearothermophilus strain 2184 was investigated by lactoperoxidase-catalyzed iodination. Two-dimensional polyacrylamide gel electrophoresis was employed to separate ribosomal proteins for analysis of their reactivity. Free 50S subunits incorporated about 18% more ¹²⁵I than did 50S subunits derived from 70S ribosomes, whereas free 30S subunits and 30S subunits derived from 70S ribosomes incorporated similar amounts of ¹²⁵I. Iodinated 70S ribosomes and subunits retained 62–78% of the protein synthesis activity of untreated particles and sedimentation profiles showed no gross conformational changes due to iodination. The proteins most reactive to enzymatic iodination were S4, S7, S10 and Sa of the small subunit and L2, L4, L5/9, L6 and L36 of the large subunit. Proteins S2, S3, S7, S13, Sa, L5/9, L10, L11 and L24/25 were labeled substantially more in the free subunits than in the 70S ribosome. Other proteins, including S5, S9, S12, S15/16, S18 and L36 were more extensively iodinated in the 70S ribosome than in the free subunits. The locations of tyrosine residues in some homologus ribosomal proteins from B. stearothermophilus and E. coli are compared.     

The protein composition of Mycoplasma capricolum

Summary The whole cell proteins and the ribosomal proteins of Mycoplasma capricolum ATCC 27343 have been analyzed by two-dimensional polyacrylamide gel electrophoresis. The M. capricolum cell is relatively rich in basic proteins. The number of total protein spots detected was approximately 355, which is less than one-third of that of Escherichia coli or Bacillus subtilis. In contrast, the number (30 and 20 protein species have been found to be present in the 50S and 30S ribosomal subunits, respectively) and the size of the ribosomal proteins in the M. capricolum do not seem to be significantly different from those of typical eubacteria.     

Topography of 16 S RNA in 30 S subunits and 70 S ribosomes accessibility to cobra venom ribonuclease

A ribonuclease extracted from the venom of the cobra Naja oxiana, which shows an unusual specificity for double-stranded RNA regions, was used to obtain new insight on the topography of Escherichia coli ribosomal 16 S RNA in the 30 S subunit and in the 70 S couple. ³²P-labeled 30 S subunits or reconstituted 70 S tight couples containing ³²P-labeled 16 S RNA have been digested under progressively stronger conditions. The cleavage sites have been precisely localized and the chronology of the hydrolysis process studied.The enzyme cleaves the 16 S RNA within 30 S subunits at 21 different sites, which are not uniformly distributed along the molecule. These results provide valuable information on the 16 S RNA topography and evidence for secondary structure features.The binding of the 50 S subunit markedly reduces the rate of the 16 S RNA hydrolysis and provides protection for several cleavage sites. Four of them are clustered in the 3′-terminal 200 nucleotides of the molecule, one in the middle (at position 772) and one in the 5′ domain (at position 336). Our results provide further evidence that the 3′-terminal and central regions of the RNA chain are close to each other in the ribosome structure and lie at the interface of the two subunits. They also suggest that the 5′ domain is probably not involved exclusively in structure and assembly.     

A method of preparing Escherichia coli 16 S RNA possessing previously unobserved 30 S ribosomal protein binding sites

A method of preparing 16 S RNA has been developed which yields RNA capable of binding specifically at least 12, and possibly 13, 30 S ribosomal proteins. This RNA, prepared by precipitation from 30 S subunits using a mixture of acetic acid and urea, is able to form stable complexes with proteins S3, S5, S9, S12, S13, S18 and possibly S11. In addition, this RNA has not been impaired in its capacity to interact with proteins S4, S7, S8, S15, S17 and S20, which are proteins that most other workers have shown to bind RNA prepared by the traditional phenol extraction procedure (Held et al., 1974; Garrett et al., 1971; Schaup et al., 1970,1971).We have applied several criteria of specificity to the binding of proteins to 16 S RNA prepared by the acetic acid-urea method. First, the new set of proteins interacts only with acetic acid-urea 16 S RNA and not with 16 S RNA prepared by the phenol method or with 23 S RNA prepared by the acetic acid-urea procedure. Second, 50 S ribosomal proteins do not interact with acetic acidurea 16 S RNA but do bind to 23 S RNA. Third, in the case of protein S9, we have shown that the bound protein co-sediments with acetic acid-urea 16 S RNA in a sucrose gradient. Additionally, a saturation binding experiment showed that approximately one mole of protein S9 binds acetic acid-urea 16 S RNA at saturation. Thus, we conclude that the method employed for the preparation of 16 S RNA greatly influences the ability of the RNA to form specific protein complexes. The significance of these results is discussed with regard to the in vitro assembly sequence.     

Mutant Ribosomal Protein with Defective RNA Binding Site

THE 30S ribosomal subunits of Escherichia coli contain twenty-one different proteins^1–4, which together with 16S RNA can reassemble in vitro to form functional 30S particles⁵. Five proteins can individually bind to specific sites on the 16S RNA^6–8 and these are S4, S7, S8, S15 and S20 (in the nomenclature recently adopted by several laboratories to report results with the E. coli system⁹). We report here the first identification of a mutation that affects a ribosomal protein-nucleic acid interaction.     

The identification of spermine binding sites in 16S rRNA allows interpretation of the spermine effect on ribosomal 30S subunit functions

A photoreactive analogue of spermine, N¹-azidobenzamidino (ABA)-spermine, was covalently attached after irradiation to Escherichia coli 30S ribosomal subunits or naked 16S rRNA. By means of RNase H digestion and primer extension, the cross-linking sites of ABA-spermine in naked 16S rRNA were characterised and compared with those identified in 30S subunits. The 5′ domain, the internal and terminal loops of helix H24, as well as the upper part of helix H44 in naked 16S rRNA, were found to be preferable binding sites for polyamines. Association of 16S rRNA with ribosomal proteins facilitated its interaction with photoprobe, except for 530 stem–loop nt, whose modification by ABA-spermine was abolished. Association of 30S with 50S subunits, poly(U) and AcPhe-tRNA (complex C) further altered the susceptibility of ABA-spermine cross-linking to 16S rRNA. Complex C, modified in its 30S subunit by ABA-spermine, reacted with puromycin similarly to non-photolabelled complex. On the contrary, poly(U)-programmed 70S ribosomes reconstituted from photolabelled 30S subunits and untreated 50S subunits bound AcPhe-tRNA more efficiently than untreated ribosomes, but were less able to recognise and reject near cognate aminoacyl-tRNA. The above can be interpreted in terms of conformational changes in 16S rRNA, induced by the incorporation of ABA-spermine.     

Structural dynamics of bacterial ribosomes: II. Preparation and characterization of ribosomes and subunits active in the translation of natural messenger RNA

Ribosomes from Escherichia coli were tested for activity in initiation with R17 RNA as messenger. All vacant 70 S ribosomes but not all subunits were found to be active. The ability of 30 S and 50 S subunits to form a 70 S couple at Mg²⁺ concentrations above 4 mm is a stringent test for activity.Fresh extracts, prepared at 10 mm-Mg²⁺ from cells harvested after slow cooling contain up to 80% of the ribosomes in the form of vacant 70 S couples and 20% of free subunits. The proportion of subunits increases with standing as a result of the preferential inactivation of the 50 S particles. “Native” subunits are heterogeneous and consist mostly of active 30 S and inactive 50 S particles.In contrast to 50 S subunits, 30 S subunits prepared by exposure of 70 S ribosomes to low Mg²⁺ concentrations, are largely inactive and unable to reassociate with their active 50 S counterparts. However, both initiation and association activity can be restored by heating.The results imply that the structures necessary for subunit association are most critical for the biological activity of ribosomes, presumably because they are topologically closely related to the binding sites for messenger RNA, transfer RNA, and the protein factors for initiation, translocation and termination.     

Increase of degree of spermidine stimulation of polypeptide synthesis in the presence of phosphate

The addition of phosphate caused an increase in the degree of spermidine stimulation of polypeptide synthesis in an Escherichia coli and a wheat germ cell-free system. Optimal stimulation of polypeptide synthesis was observed at 20 mm phosphate for both systems, but concentrations of phosphate up to 40 mm had no additional effect. The increase of degree of spermidine stimulation in the presence of phosphate in an E. coli cell-free system occurred at the level of aminoacyl-tRNA binding to ribosomes and not at the level of peptide bond formation, translocation, or aminoacyl-tRNA formation. From the results of studies on RNase A sensitivity of ribosomal subunits and the effect of antibiotics known to act on the 30 S ribosomal subunits, it is suggested that the nature of the 30 S ribosomal subunits is changed by phosphate so that the degree of spermidine stimulation of polypeptide synthesis is increased.     

Mechanism of ribosomal subunit association: discrimination of specific sites in 16 S RNA essential for association activity.

Modification of 30 S ribosomal subunits with kethoxal causes loss of their ability to associate with 50 S subunits under tight couple conditions. To identify those 16 S RNA sequences important for the association. ³²P-labeled 30 S subunits were partially inactivated by reaction with kethoxal. The remaining association-competent 30 S subunits were selected from the modified population by their ability to form 70 S ribosomes. Comparison of kethoxal diagonal maps of the association-competent subunits with those of the total population of modified subunits reveals nine sites in 16 S RNA whose modification leads to loss of association activity. Eight of these sites were previously found to be protected from kethoxal attack and one was shown to have enhanced reactivity in 70 S ribosomes (Chapman &; Noller, 1977). As before, these sites are not distributed thoughout the molecule, but are found to be clustered in two regions, at the middle and at the 3′ terminus of the 16 S RNA chain.We interpret these findings in terms of a simple preliminary model for the functional organization of 16 S RNA, supported by the observations of other investigators, in which we divide the molecule into four domains. (1) Residues 1 to 600 are involved mainly in structural organization and assembly. (2) Residues 600 to 850 include sites which make contact with the 50 S subunit and are essential for subunit association. (3) Sites from the domain comprising residues 850 to 1350 line a pocket at the interface between the two ribosomal subunits. and contribute to the binding site(s) for transfer RNA. (4) Residues 1350 to 1541 also contain sequences which bind the 50 S subunit, but some sites in this domain alternatively participate in the initiation of protein synthesis.