Proteins S7, S10, S16 and S19 of the human 40S ribosomal subunit are most resistant to dissociation by salt

The protein components of human 40S ribosomal subunits were dissociated by centrifugation in gradients of sucrose and LiCl in the presence of 0.5 M KCl. The proteins that split off were analyzed by SDS-PAGE and 2D-PAGE. The order of dissociation of the proteins, depending on the salt concentration (from 0.8 M to 1.55 M), was established. The majority of the proteins started to split off simultaneously at a monovalent cation concentration of 0.8 M. Ten proteins were found to be more resistant; of these proteins S7, S10, S16, and S19 were retained most strongly and thereby may be considered to be core proteins.     

Purification of Drosophila ribosomal proteins. Isolation of proteins S8, S13, S14, S16, S19, S20/L24, S22/L26, S24, S25/S27, S26, S29, L4, L10/L11, L12, L13, L16, L18, L19, L27, 1, 7/8, 9, and 11

The proteins of Drosophila melanogaster embryonic ribosomes were separated into seven groups (A80 through G80) by stepwise elution from carboxymethylcellulose with lithium chloride at pH 6.5 by procedures previously described [Chooi, W. Y., Sabatini, L. M., MacKlin, M. D., & Fraser, W. (1980) Biochemistry 19, 1425-1433]. Three relatively acidic proteins, S14, S25/S27, and 7/8, have now been isolated from group A80 by ion-exchange chromatog raphy on carboxymethylcellulose eluted with a linear gradient of lithium chloride at pH 4.2. Fractions containing the relatively basic proteins (groups B80 through G80) were furher combined into a total of 24 "pools". The criterion for combination was the migration patterns in one-dimensional polyacrylamide gels containing sodium dodecyl sulfate (NaDodS04) of every fifth fraction from the carboxymethylcellulose column. Each pool contained between 1 and 12 major proteins. Proteins S8, S13, S16, S19, S20/L24, S22/L26, S24, S26, S29, L4, L10/L11, L12, L13, L16, L18, L19, L27, 1, 9, and 11 have now been isolated from selected pools by gel filtration through Sephadix G-100. The amount of each protein recovered from a starting amount of 1.8 g of total 80S proteins varied form 0.2 to 10.8 mg. Five proteins had no detectable contamination, and in each of the others the impurities were no greater than 9%. The amino acid composition of the individual purified proteins was determined. The molecular weights of the proteins were estimated by polyacrylamide gel electrophoresis in NaDodSO4.     

Dissociation of ferritins

Apoferritins prepared from horse spleen and heart and rat heart and liver were dissociated by treatment with acetic acid (pH 1.3-3.0). Sedimentation velocity studies showed that apoferritins of spleen and liver (16-17 S) and heart (18-19 S) dissociated into material sedimenting near 3.2 S. Sedimentation equilibrium measurements determined that most of the material had a molecular weight of 38,000-43,000, corresponding to subunit dimers. Failure to dissociate into subunit monomers was confirmed by gel chromatography on Sephadex G-75 and G-150. With the exception of boiling in sodium dodecyl sulfate, further treatments with 0.1-0.4 M KCl, NaCl, 4-9 M urea, 0.01-0.5 M KSCN, 0.1-0.5% Triton X-100, 5-52% dimethylsulfoxide, 10% ethylene glycol, or 0.1% trifluoroacetic acid all failed to cause dissociation into individual subunits, as did exposure to 6 M guanidine-HCl or formic acid, or prior succinylation and/or nitration of the protein. Reassociation occurred between pH 4 and 7 but was not aided by the addition of Fe(II) or reducing agents. It is concluded that ferritins readily dissociate to subunit dimer units and that further dissociation does not occur without full denaturation of the protein.     

Reversible modification of Escherichia coli ribosomes with 2,3-dimethylmaleic anhydride. A new method to obtain protein-deficient ribosomal particles.

Treatment of Escherichia coli ribosomes with the protein reagent 2,3-dimethylmaleic anhydride is accompanied by inactivation of polypeptide polymerization and by dissociation of ribosomal proteins. Regeneration of the modified amino groups at pH 6.0 is followed by reactivation and reconstitution of the ribosomes. Prior to regeneration of the amino groups, ribosomal particles and split proteins can be separated by centrifugation, which allows the preparation of new protein-deficient particles. The ribosomal particles obtained by three successive treatments with 2,3-dimethyl-maleic anhydride at a molar ratio of reagent to ribosome equal to 16,000 lack proteins S1, S2, S3, S5, S10, S13, S14, L7, L8, L10, L11, L12, and L20 and have lost part of proteins S4, L1, L6, L16, and L25. This new procedure to obtain protein-deficient ribosomal particles is mild and might be useful to dissociate other protein-containing structures in addition to ribosomes.     

Protein binding sites on Escherichia coli 16S RNA; RNA regions that are protected by proteins S7, S14 and S19 in the presence or absence of protein S9.

14C-labelled proteins from E. coli 30S ribosomal subunits were isolated by HPLC, and selected groups of these proteins were reconstituted with 32P-labelled 16S RNA. The isolated reconstituted particles were partially digested with ribonuclease A, and the RNA fragments protected by the proteins were separated by gel electrophoresis and subjected to sequence analysis. Protein S7 alone gave no protected fragments, but S7 together with S14 and S19 protected an RNA region comprising the sequences 936-965, 972-1030, 1208-1262 and 1285-1379 of the 16S RNA. Addition of increasing amounts of protein S9 to the S7/S14/S19 particle resulted in a parallel increase in the protection of the hairpin loop between bases 1262 and 1285. The results are discussed in terms of the three-dimensional folding of 16S RNA in the 30S subunit.     

RNA-protein interactions in the ribosome. II. Binding of ribosomal proteins to isolated fragments of the 16 S RNA

Specific fragments of the 16 S ribosomal RNA of Escherichia coli have been isolated and tested for their ability to interact with proteins of the 30 S ribosomal subunit. The 12 S RNA, a 900-nucleotide fragment derived from the 5′-terminal portion of the 16 S RNA, was shown to form specific complexes with proteins S4, S8, S15, and S20. The stoichiometry of binding at saturation was determined in each case. Interaction between the 12 S RNA and protein fraction $\text{S}\text{16}\text{S}\text{17}$ was detected in the presence of S4, S8, S15 and S20; only these proteins were able to bind to this fragment, even when all 21 proteins of the 30 S subunit were added to the reaction mixture. Protein S4 also interacted specifically with the 9 S RNA, a fragment of 500 nucleotides that corresponds to the 5′-terminal third of the 16 S RNA, and protein S15 bound independently to the 4 S RNA, a fragment containing 140 nucleotides situated toward the middle of the RNA molecule. None of the proteins interacted with the 600-nucleotide 8 S fragment that arose from the 3′-end of the 16 S RNA.When the 16 S RNA was incubated with an unfractionated mixture of 30 S subunit proteins at 0 °C, 10 to 12 of the proteins interacted with the ribosomal RNA to form the reconstitution intermediate (RI) particle. Limited hydrolysis of this particle with T₁ ribonuclease yielded 14 S and 8 S subparticles whose RNA components were indistinguishable from the 12 S and 8 S RNAs isolated from digests of free 16 S RNA. The 14 S subparticle contained proteins S6 and S18 in addition to the RNA-binding proteins S4, S8, S15, S20 and $\text{S}\text{16}\text{S}\text{17}$. The 8 S subparticle contained proteins S7, S9, S13 and S19. These findings serve to localize the sites at which proteins incapable of independent interaction with 16 S RNA are fixed during the early stages of 30 S subunit assembly.     

Effect of potassium phenosan on structure of plasma membranes of mice liver cells in vitro

The effect of synthetic anti-oxidant potassium phenosan (PP, potassium salt of β-(4-hydroxy-3,5-ditretbutil-phenyl)-propionic acid) on the structural state of the surface (8 Å) and deep (20–22 Å) lipid regions of plasma membranes of mice liver cells was studied by spin probes method in vitro in a wide range of concentrations (10^?5–10^?21 M). Two stable free radicals, 5- and 16-doxyl-stearic acids (C₅ and C₁₆), were used as spin probes. The nonlinear polymodal dose-effect dependences were obtained for parameters that characterize the microviscosity of the lipid bilayer (τ_c) in the site of localization of the probe C₁₆, and the order parameter (S), which characterizes the stiffness of the surface layers of lipids in the site of localization of the probe C₅. Statistically a reliable increase was observed for parameter τ_c after addition of PP at concentrations 10^?5–10^?7 M and 10^?18–10^?19 M, and for parameter S after addition of PP at concentrations 10^?6–10^?7 M and 10^?13–10^?15 M. Peaks on both dose-effect curves were separated by the intervals of concentrations where PP had no effect on the studied physico-chemical characteristics of biomembranes. For PP concentrations which caused maximal changes in τ_c and S, we investigated thermal dependence of these parameters and determined the thermally induced structural transitions. Comparing with control, ultra-low doses of PP (10^?13–10^?15 M) and (10^?18–10^?19 M) caused an appearance of additional thermally induced structural transition in the surface and deep regions of plasma membrane lipids. The possible role of the interaction of PP molecules with specific binding sites on plasma membranes and formation of nanoparticles of PP in very dilute aqueous solutions are discussed.     

Co-operative response of oligomeric protein receptors coupled to non-co-operative ligand binding.

The biogenesis of 30 S and 50 S ribosomal subunits in exponentially growing Escherichia coli has been studied by following the rate of appearance of pulse-labelled ribosomal proteins on mature subunits. Cells were pulse-labelled for two minutes and for three and a half minutes with radioactive leucine. Ribosomal proteins were extracted and purified by chromatography on carboxymethyl cellulose and analysed by bidimensional gel electrophoresis. All 30 S proteins and most of the 50 S proteins were thus prepared and their radioactivity counted: unequal labelling was obtained. 30 S and 50 S proteins were ordered according to increasing specific radioactivity at both time pulses. The incorporation was greater at three and a half minutes than at two minutes. No major difference in the order at the two labelling times was observed.Only two classes of proteins can be defined in the 30 S and the 50 S subunits, namely early and late proteins. In each class a gradual increase in the radioactivity is apparent from the poorly labelled to the highly labelled proteins. This suggests a definite order of addition.Early 30 S proteins: S17, S16, S15, S19, S18, S8, S4, S20, S10, S6, S9, S12, S7.Late 30 S proteins: S5, S3, S2, S14, S11, S13, S1, S21.Early 50 S proteins: L22, L20, L21, L4, L13, L16, L3, L23, L18, L24, L28, L17, L19, L29, L32, L5, L15, L2, L30, L27.Late 50 S proteins: L25, L11, L7, L12, L1, L9, L8, L10, L33, L14, L6.This order is discussed taking into account the pool size of the proteins measured in the same conditions of cell culture.     

Binding of 16S rRNA to chloroplast 30S ribosomal proteins blotted on nitrocellulose

Protein-RNA associations were studied by a method using proteins blotted on a nitrocellulose sheet. This method was assayed with Escherichia Coli 30S ribosomal components. In stringent conditions (300 mM NaCl or 20° C) only 9 E. coli ribosomal proteins strongly bound to the 16S rRNA: S4, S5, S7, S9, S12, S13, S14, S19, S20. 8 of these proteins have been previously found to bind independently to the 16S rRNA. The same method was applied to determine protein-RNA interactions in spinach chloroplast 30S ribosomal subunits. A set of only 7 proteins was bound to chloroplast rRNA in stringent conditions: chloroplast S6, S10, S11, S14, S15, S17 and S22. They also bound to E. coli 16S rRNA. This set includes 4 chloroplast-synthesized proteins: S6, S11, S15 and S22. The core particles obtained after treatment by LiCl of chloroplast 30S ribosomal subunit contained 3 proteins (S6, S10 and S14) which are included in the set of 7 binding proteins. This set of proteins probably play a part in the early steps of the assembly of the chloroplast 30S ribosomal subunit.     

RNA--protein interactions in the ribosome. III. Conformation and stability of ribosomal protein binding sites in the 16 S RNA

Following dialysis against distilled water, the 16 S ribosomal RNA of Escherichia coli is unable to interact with 30 S subunit protein S4 at 0 °C. The dialysed RNA recovered this capacity, however, when heated at 40 °C in the presence of 0.02m-MgCl₂ prior to addition of the protein. Furthermore, its sensitivity to ribo-nuclease markedly declined and its sedimentation rate increased as a consequence of this treatment. Although no concomitant changes in secondary structure were detected by absorbance and fluorescence techniques, the rearrangement of a small number of base-pairs was not excluded. Kinetic measurements revealed that binding site reactivation satisfies the first-order rate law and that the process is highly temperature-dependent, exhibiting an Arrhenius activation energy of 40,800 cal/mol. Together, these data suggest that dialysed RNA undergoes a unimolecular conformational transition upon pre-incubation in Mg²⁺-containing buffers and that this transition leads to renaturation of the binding site for protein S4.Similar results were obtained for several other proteins of the 30 S subunit. In particular, S7, S16/S17 and S20 all failed to interact efficiently with dialysed 16 S RNA at 0 °C. These proteins bound normally to the RNA, however, after it had been incubated at 40 °C in the presence of Mg²⁺ ions. By contrast, prior dialysis of the 16 S RNA did not affect its ability to associate with S8 and S15 at 0 °C. These two proteins interacted equally well with dialysed and pre-incubated 16 S RNA, indicating that their binding sites are not susceptible to the reversible alterations in conformation which influence the attachment of the other RNA-binding proteins to the nucleic acid molecule. The effects of dialysis and pre-incubation on the interaction of 16 S RNA with an unfractionated mixture of 30 S subunit proteins were also investigated. The dialysed RNA bound only S6, S8, S15 and S18 at 0 °C whereas, after heating at. high Mg²⁺ concentrations, the RNA associated with S4, S7, S9, S13, S16/S17, S19 and S20 as well. These results leave little doubt that the protein-binding capacities of the 16 S RNA are intimately related to its three-dimensional configuration, although individual binding sites appear to differ significantly in their stability to small changes in structure.     

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.     

Assembly of the 30S subunit from Escherichia coli ribosomes occurs via two assembly domains which are initiated by S4 and S7

A protein which initiates assembly of ribosomes is defined as a protein which binds to the respective rRNA without cooperativity (i.e., without the help of other proteins) during the onset of assembly and is essential for the formation of active ribosomal subunits. The number of proteins binding without cooperativity was determined by monitoring the reconstitution output of active particles at various inputs of 16S rRNA, in the presence of constant amounts of 30S-derived proteins (TP30): This showed that only two of the proteins of the 30S subunit are assembly-initiator proteins. These two proteins are still present on a LiCl core particle comprising 16S rRNA and 12 proteins (including minor proteins). The 12 proteins were isolated, and a series of reconstitution experiments at various levels of rRNA excess demonstrated that S4 and S7 are the initiator proteins. Pulse-chase experiments performed during the early assembly with 14C- and 3H-labeled TP30 and the determination of the 14C/3H ratio of the individual proteins within the assembled particles revealed a bilobal structure of the 30S assembly: A group of six proteins headed by S4 (namely, S4, S20, S16, S15, S6, and S18) resisted the chasing most efficiently (S4 assembly domain). None of the proteins depending on S7 during assembly were found in this group but rather in a second group with intermediate chasing stability [S7 assembly domain; consisting of S7, S9, (S8), S19, and S3]. A number of proteins could be fully chased during the early assembly and therefore represent "late assembly proteins" (S10, S5, S13, S2, S21, S1). These findings fit well with the 30S assembly map.(ABSTRACT TRUNCATED AT 250 WORDS)     

Efficient reconstitution of functional Escherichia coli 30S ribosomal subunits from a complete set of recombinant small subunit ribosomal proteins.

Previous studies have shown that the 30S ribosomal subunit of Escherichia coli can be reconstituted in vitro from individually purified ribosomal proteins and 16S ribosomal RNA, which were isolated from natural 30S subunits. We have developed a 30S subunit reconstitution system that uses only recombinant ribosomal protein components. The genes encoding E. coli ribosomal proteins S2-S21 were cloned, and all twenty of the individual proteins were overexpressed and purified. Reconstitution, following standard procedures, using the complete set of recombinant proteins and purified 16S ribosomal RNA is highly inefficient. Efficient reconstitution of 30S subunits using these components requires sequential addition of proteins, following either the 30S subunit assembly map (Mizushima & Nomura, 1970, Nature 226:1214-1218; Held et al., 1974, J Biol Chem 249:3103-3111) or following the order of protein assembly predicted from in vitro assembly kinetics (Powers et al., 1993, J MoI Biol 232:362-374). In the first procedure, the proteins were divided into three groups, Group I (S4, S7, S8, S15, S17, and S20), Group II (S5, S6, S9, Sll, S12, S13, S16, S18, and S19), and Group III (S2, S3, S10, S14, and S21), which were sequentially added to 16S rRNA with a 20 min incubation at 42 degrees C following the addition of each group. In the second procedure, the proteins were divided into Group I (S4, S6, S11, S15, S16, S17, S18, and S20), Group II (S7, S8, S9, S13, and S19), Group II' (S5 and S12) and Group III (S2, S3, S10, S14, and S21). Similarly efficient reconstitution is observed whether the proteins are grouped according to the assembly map or according to the results of in vitro 30S subunit assembly kinetics. Although reconstitution of 30S subunits using the recombinant proteins is slightly less efficient than reconstitution using a mixture of total proteins isolated from 30S subunits, it is much more efficient than reconstitution using proteins that were individually isolated from ribosomes. Particles reconstituted from the recombinant proteins sediment at 30S in sucrose gradients, bind tRNA in a template-dependent manner, and associate with 50S subunits to form 70S ribosomes that are active in poly(U)-directed polyphenylalanine synthesis. Both the protein composition and the dimethyl sulfate modification pattern of 16S ribosomal RNA are similar for 30S subunits reconstituted with either recombinant proteins or proteins isolated as a mixture from ribosomal subunits as well as for natural 30S subunits.     

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.     

Induction of reactive oxygen species by diphenyl diselenide is preceded by changes in cell morphology and permeability in Saccharomyces cerevisiae

Organoselenium compounds, such as diphenyl diselenide (PhSe)₂ and phenylselenium zinc chloride (PhSeZnCl), show protective activities related to their thiol peroxidase activity. However, depending on experimental conditions, organoselenium compounds can cause toxicity by oxidising thiol groups of proteins and induce the production of reactive oxygen species (ROS). Here, we analysed the toxicity of (PhSe)₂ and PhSeZnCl in yeast Saccharomyces cerevisiae. Cell growth of S. cerevisiae after 1, 2, 3, 4, 6, and 16?h of treatment with 2, 4, 6, and 10?μM of (PhSe)₂ was evaluated. For comparative purpose, PhSeZnCl was analysed only at 16?h of incubation at equivalent concentrations of selenium (i.e. 4, 8, 12, and 20?μM). ROS production (DCFH-DA), size, granularity, and cell membrane permeability (propidium iodide) were determined by flow cytometry. (PhSe)₂ inhibited cell growth at 2?h (10?μM) of incubation, followed by increase in cell size. The increase of cell membrane permeability and granularity (10?μM) was observed after 3?h of incubation, however, ROS production occurs only at 16?h of incubation (10?μM) with (PhSe)₂, indicating that ROS overproduction is a more likely consequence of (PhSe)₂ toxicity and not its determinant. All tested parameters showed that only concentration of 20?μM induced toxicity in samples incubated with PhSeZnCl. In summary, the results suggest that (PhSe)₂ toxicity in S. cerevisiae is time and concentration dependent, presenting more toxicity when compared with PhSeZnCl.     

Binding of aminoacyl-tRNA to rat liver ribosomal proteins

Rat liver ribosome treatment with ethanol and 1 M NH₄Cl releases some 31–33 ribosomal proteins. This split protein fraction binds Phe-tRNA, Ac-Phe-tRNA, Met-tRNA_M and f-Met-tRNA_F in the absence of K⁺ and Mg⁺⁺ ions. When the split protein fraction is passed through Sephadex G-100 only six proteins are retained in the column: S10, S14, S15, S19, L35, and L36. The aminoacyl-tRNA binding activity of this protein fraction retained in the Sephadex G-100 column is similar to that of the total split protein fraction, suggesting that the above six proteins, or only some of them, are involved in the binding reaction.     

Three Novel Gibberellins Produced by Gibberella fujikuroi

Three novel gibberellins, GA₅₄ (ent-1α, 3α, 10-trihydroxy-20-norgibberell-16-ene-7, 19-dioic acid 19, 10-lactone), GA₅₅ (ent-1α, 3α, 10, 13-tetrahydroxy-20-norgibberell-16-ene-7, 19-dioic acid 19, 10-lactone) and GA₅₆ (ent-2β, 3α, 10, 13-tetrahydroxy-20-norgibberell-16-ene-7, 19-dioic acid 19, 10-lactone) were shown to occur in the culture broth of Gibberella fujikuroi. Their structures were determined mainly by mass spectrometrical comparison of the derivatives with those of authentic compounds prepared from known gibberellins.     

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.     

Further studies on the identity of proteins at the subunit interface of the 70 S E. coli ribosome

The ability of 1 m NH₄Cl to detach iodinated 50 S ribosomal proteins from 50 S subunits and 70 S ribosomes was compared. High salt treatment was effective in preferentially releasing L16, L20, L24, L26, L27, L29, and L30 from the 50 S subunit. Similar but smaller effects were seen for L2, L6, L15, L19, L28, and L31. When these results are combined with several previous studies on accessibility, twelve 50 S proteins appear to be less exposed in the 70 S particle than in the free subunit, by more than one entirely different measure of accessibility. These twelve must be considered strong candidates for possible subunit interface proteins.Lactoperoxidase catalyzed iodination was used to probe the surface topography of active and reversibly inactivated 30 S subunits. The magnesium depleted inactive 30 S particle reproducibly incorporates more ¹²⁵I than the active subunit indicating that a conformational change, characterized by an opening or expansion of the 30 S particles, accompanies 30 S inactivation. Seven 30 S proteins, S5, S21, S4, S7, S10, S13, and S16 become more accessible to lactoperoxidase as a result of inactivation. These proteins are different from those known to become more accessible to lactoperoxidase as a result of the conformational reorganization accompanying subunit association, S3, S6, S9, and S18. Thus, although both inactive 30 S and 50 S-bound 30 S are more open or reactive compared with free active 30 S, the regions which are affected appear to be different.     

The ribonucleic acids of Crithidia fasciculata

Crithidia fasciculata ribosomes were found to be 80S and to dissociate into 58 and 41S subunits; on 5 to 50% sucrose gradients, rRNA was separated into 25, 18, and 5S components. The molecular sizes of the heavier rRNA species, estimated by polyacrylamide gel electrophoresis were 1.24 and 0.84 M (X 10(6) daltons). The 25S RNA has a tendency to interact with the 18S RNA to give a complex that is difficult to separate by sucrose gradient centrifugation. The 25S RNA is also unstable and dissociates into 0.73 and 0.57 M components. The 18S RNA has molecular size (0.84 M) higher than the 0.7 M reported for most eukaryotes, but similar to that of Euglena and Amoeba. Ribosomal RNA hybridized 0.29% of the nuclear DNA. Mitochondrial RNA, extracted by a rapid procedure was resolved into 16 and 5S components in sucrose gradients.