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

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

Comparison of the physical properties of ribosomal proteins from Escherichia coli 50S subparticles isolated by different methods

Physical properties of ribosomal proteins obtained with or without denaturing agents were compared. CD measurements and PMR studies have shown that proteins L2, L19, L24 and L30 isolated under denaturing conditions have the same properties as those prepared avoiding denaturing agents. CD and PMR data of L1, L6, L11, L23, L25 and L29 obtained by us under denaturing conditions practically coincide with the data for these proteins obtained in "mild" conditions and published in the literature. These findings indicate that the differences of physical properties reported in the literature can be due to different procedures of protein renaturation rather than to the methods of their isolation.     

Fractionation of brain macromolecules. Chromatography on hydroxyapatite of soluble proteins and nucleic acids from whole rat brain and the effect of autolysis

1. A procedure for the chromatographic fractionation of soluble brain proteins on calcium hydroxyapatite is described. Chromatograms obtained are reproducible; approximately 11 protein and at least three nucleic acid components can be identified. The effects of column dimensions and flow rate on the chromatograms obtained are described. 2. One of the nucleic acid components appears to correspond to soluble RNA and another to ribosomal RNA. Treatment of homogenates by procedures that cause the removal of ribosomes from soluble extracts also cause the disappearance of the component corresponding to ribosomal RNA. Centrifugation of rat-brain homogenates prepared in 0·25m-sucrose at 105400g for 90min. causes the sedimentation of ribosomes as well as the disappearance of the component corresponding to ribosomal RNA. Extraction of brain tissue, or particulate fractions prepared from brain, with dilute buffers causes the solubilization of part of the ribosomal RNA that then can subsequently be identified in the chromatogram. 3. Autolysis under aerobic conditions has been shown to cause an increase in the nucleic acid component in the chromatogram that corresponds to the ribosomal RNA. Aerobic autolysis causes part of the ribosomal RNA to be solubilized, as evidenced by its failure to be sedimented by centrifugation at 105400g for 90min. and by its appearance in the fraction corresponding to ribosomal RNA in the chromatogram. These changes were not observed when autolysis was carried out under anaerobic conditions. Aerobic autolysis also caused changes in those proteins that are strongly adsorbed on the gel. 4. In general, the proteins of the cell sap appeared to be fairly stable to autolysis. Marked differences in the chromatograms are observed when soluble proteins from the particle fraction were autolysed and chromatographed.     

Organization of proteins in mammalian mitochondrial ribosomes. Accessibility to lactoperoxidase-catalyzed radioiodination

To assess the relative exposure of individual ribosomal proteins (r-proteins) in the large and small subunits of the bovine mitochondrial ribosome, we used a double label iodination technique. Regions of r-proteins exposed in purified ribosomal subunits were labeled with 131I using the lactoperoxidase-catalyzed iodination system, and additional reactive groups available upon denaturing the r-proteins in urea were labeled with 125I using the chloramine-T mediated reaction. The ratio of 131I to 125I incorporated into individual proteins under these conditions is representative of the degree of exposure for each of the proteins in the subunits. In this manner, the r-proteins have been grouped into 3 classes depending on their degree of exposure: high exposure, intermediate exposure, and essentially buried. While both subunits have a few proteins in the "highly exposed" group, and a large number of proteins in the "intermediate exposure" group, only the large ribosomal subunit has an appreciable number of proteins which appear essentially buried. The more buried proteins may serve mainly structural roles, perhaps acting as "assembly proteins," since many from this group bind to ribosomal RNA. The more superficially disposed proteins may comprise binding sites for macromolecules that interact with ribosomes during protein synthesis, as well as stabilizing the association of the large and small subribosomal particles.     

Physical properties of ribosomal proteins isolated under different conditions from the Escherichia coli 50 S subunit

Physical properties of ribosomal proteins obtained with or without denaturating agents were compared. CD measurements and NMR studies have shown that proteins L2, L19, L24 and L30 isolated under denaturing conditions have the same properties as those prepared avoiding denaturating agents. CD and NMR spectra of proteins L1, L6, L11, L23, L25 and L29 obtained by us under denaturating conditions practically coincide with the data for the same proteins reported under 'mild' conditions. These findings suggest that the differences of reported physical properties can be due to different procedures of protein renaturation rather than to the methods of their isolation.     

A new two-dimensional gel electrophoresis system for the analysis of complex protein mixtures: Application to the ribosome of E. coli

A new method for two-dimensional polyacrylamide gel electrophoresis of proteins is described. The method, illustrated here by its application for the analysis of ribosomal proteins of E. coli, has a high resolving power. The proteins S15 and S16 can be resolved either following alkylation or under reducing conditions. This was not possible with urea gel systems previously employed. The method should be advantageous in the identification of the components of dimers formed with the reagent methyl 4-mercaptobutyrimidate. An additional advantage of the new method is that both dimensions are run at an acidic pH. For ribosomal proteins it is therefore unnecessary to either polymerize the protein sample in the middle of the first dimension disc gel or to electrophorese two samples with opposite polarity.     

Biogenesis of ribosomes: free ribosomal protein pools in Escherichia coli

Proteins from ribosomal subunits (30 s and 50 s) have been fractionated into split (SP-30 and SP-50) and core (core-30 and eore-50) proteins. Antisera prepared in rabbit against them are shown to be highly group-specific as judged by the Ouchterlony (1967) double diffusion test and by precipitin reaction in solution. Various parameters which influence the immuno-precipitation of these proteins by specific antisera have been investigated. It is demonstrated that under controlled conditions this provides a sensitive and reliable method for characterization and quantitative estimation of free ribosomal proteins. The technique has been successfully applied in the investigations of various properties of free ribosomal protein pools existing in Escherichia coli. It is concluded that free ribosomal proteins in E. coli may constitute 8 to 14% of total soluble proteins under different growth conditions. Relative pool sizes of four classes of proteins expressed as a percentage of the total soluble proteins in bacteria grown in L broth (doubling period, 30 min) are estimated to be core-30, 2.1; core-50, 3.4; SP-30, 3.6; SP-50, 5.0. From the studies on bacteria grown in different media (doubling period, 30, 42 and 60 min), we further conclude that the amount of free proteins increases with the growth rate so as to constitute a constant fraction (7 to 9%) of total ribosomal proteins. Relative pool-sizes corresponding to four classes of ribosomal proteins, however, remain unaltered by different growth rate.     

Analysis of Escherichia coli ribosomal proteins by an improved two dimensional gel electrophoresis. II. Characterization of four new proteins

Four new proteins, A, B, C, and D, found in Escherichia coli ribosomes by an improved two dimensional gel electrophoresis were characterized by oxidation, reduction, and carboxymethylation of cysteine residues, and CsCl fractionation. The cysteine contents of proteins A, B, C, and D were determined to be 1 +/- 0, 3 +/- 1, 5 +/- 1, and 0 +/- 0 by carboxymethylation with iodoacetic acid. The components of protein complexes, which formed numerously under non-reducing conditions, were analyzed. Including protein A, B, and C, every ribosomal protein (r-protein) having cysteine residue(s) except unconfirmed S1 was proved to form such complexes with various combinations. The cysteine residue in protein A, in particular, was highly reactive to make intermolecular S-S bridges so that spot A almost disappeared on the second dimension gel under the non-reducing conditions. Proteins B and C shifted their spots by reduction towards upper left side as do all known r-proteins having plural cysteine residues except S1. This suggests that proteins B and C change their conformation by intramolecular S-S bridges. The CsCl density gradient centrifugation of high salt washed 70S ribosomes showed that protein A belonged to the insoluble split proteins, proteins B and C to the core particles, and protein D and a small population of B to the soluble split proteins. The electrophoretic behaviors, CsCl fractionation and stoichiometry of the four new proteins suggested strongly that they were intrinsic ribosomal constituents different from known ribosomal proteins or factors.     

Purification and conformation of ribosomal protein L25 from E. coli ribosome

Ribosomal protein L25 from the large subunit of E. coli ribosomes has been purified using a new procedure involving a 2M LiCl extraction followed by phosphocellulose chromatography in 6 M urea elution buffer. The conformation of purified L25 was studied employing circular dichroism and ultraviolet absorption spectroscopy in reconstitution buffer. The analysis of the far u.v. circular dichroism spectrum of L25 indicates L25 contains approximately 16% alpha-helix and approximately 19% beta-structure. The conformation of L25 was also studied using the predictive methods of Chou & Fasman and Maxfield & Scheraga. Both of these methods predict approximately three times the percent alpha-helix present in L25 as compared with that determined from the analysis of the circular dichroism spectrum. A structure for L25 is predicted which contains two positively charged binding domains and is consistent with published binding data on the interaction of 5S RNA and L25. The large difference in the % alpha-helix as determined from the analysis of the circular dichroism spectrum and the predictive techniques is suggested to result from the denaturing effects of 6 M urea used in the preparation of ribosomal proteins.     

An optimized strategy for ICAT quantification of membrane proteins

The work presented here focuses on the development of a method adapting isotope labeling of proteins with ICAT to the study of highly hydrophobic proteins. Conditions for the labeling of proteins were first established using two standard soluble proteins and iodoacetamidyl-3,6-dioxaoctanediamine biotin (PEO-iodoacetyl biotin). Results demonstrated the efficiency of the labeling in the presence of high concentrations of both SDS and urea. These conditions were then used to label a highly hydrophobic mitochondrial membrane protein, the adenine nucleotide translocator ANT-1, with PEO-iodoacetyl biotin and then with the cleavable ICAT reagent. The results presented here show that labeling of proteins with cleavable ICAT is possible and may even be improved in strong denaturing buffers containing both SDS at a concentration higher than 0.5% (w/v) and urea. These results open the possibility of applying the ICAT strategy to complex samples containing very hydrophobic proteins solubilized in urea-SDS buffers. The adaptability of the developed method is demonstrated here with preliminary results obtained during the study of membrane-enriched fractions prepared from murine embryonic stem cells.     

Eukaryotic initiation factor 5 from calf liver is a single polypeptide chain protein of Mr = 62,000

Eukaryotic initiation factor 5 (eIF-5), which specifically catalyzes the joining of a 60 S ribosomal subunit to a 40 S initiation complex to form a functional 80 S initiation complex, has been purified from ribosomal salt wash proteins of calf liver. The purified factor exhibits only one polypeptide band of Mr = 62,000 following electrophoresis in 10% polyacrylamide gels in the presence of sodium dodecyl sulfate. The native protein has a sedimentation coefficient of 4.2 S and a Stokes radius of 33 A which is consistent with eIF-5 being a monomeric protein of Mr = 58,000-62,000. Less pure preparations of eIF-5 elute in gel filtration columns with an apparent Mr of 160,000-180,000 presumably due to association of eIF-5 with other high molecular weight proteins since eIF-5 activity present in such preparations can also be shown by gel electrophoretic separation under denaturing conditions to be associated with a 62,000-dalton protein. Furthermore, eIF-5 purified from calf liver extracts with or without a number of protease inhibitors is indistinguishable with regard to molecular weight and final specific activity of purified preparations. The purified factor catalyzes the hydrolysis of GTP present in 40 S initiation complexes in the absence of 60 S ribosomal subunits. The presence of 60 S ribosomal subunits neither stimulates nor inhibits the hydrolysis of GTP. However, the factor cannot mediate 40 S or 40 + 60 S ribosome-dependent hydrolysis of GTP in the absence of Met-tRNAf or other components required for 40 S initiation complex formation. It can be calculated that 1 pmol of eIF-5 protein can catalyze the formation of at least 10 pmol of 80 S initiation complex under the conditions of in vitro initiation reactions.     

The effect of a cytidine-to-uridine transition on the stability of Escherichia coli A19 5-S RNA

We have been able to isolate several species of 5-S ribosomal RNA from Escherichia coli A19. These molecules were separated on the basis of their differing stabilities during electrophoresis on 12% polyacrylamide gels in 7 M urea. This differing stability is shown, in one case, to be due to a different primary sequence. We have determined the sequence of the least stable of these molecules and have found only one difference to the published sequence of E. coli A19 5-S RNA, namely a uridine in place of a cytidine at position 92. The consequent G x U base pair, formed in a normally highly stable G x C-rich region, is responsible for a drastic reduction in the stability of the molecule. This instability leads to a less constrained, more compact molecule which thus migrates faster in electrophoresis under denaturing conditions. This species of 5-S RNA is shown to make up 30% of the total 5-S RNA in the 50-S ribosomal subunits in this organism. Further structural studies were carried out using S1 nuclease digestion, sodium bisulphite modification and thermal melting analysis. All these methods indicate a 5-S RNA drastically destabilized in parts of its secondary and tertiary structure. Finally, the ability of the variant 5-S RNA to recognize and form a complex with its 50-S subunit binding proteins was examined and found to be impaired.     

The nature of the proteins present in the 'relaxed particles' from methionine-starved Escherichia coli A19 (Hfr rel met rns).

The 'relaxed particles' formed during methionine starvation of Escherichia coli A19 (Hfr rel met rns) have been isolated by large-scale rate-zonal density gradient ultracentrifugation. The proteins and rRNA species associated with these particles have been examined. The rRNA species present are precursor and mature forms of 16S and 23S rRNA. The bulk of the rRNA which accumulates during starvation is found within the particles. The proteins prepared directly from the particles give strong multiple immunoprecipitates with antisera specific to 30S and 50S ribosomal proteins. The soluble proteins, prepared and examined in the same manner, do not give this immunological reaction. Two-dimensional electrophoresis patterns of the proteins from the particles show that the proteins co-migrate with proteins from 30S and 50S ribosomes and are entirely dissimilar to the proteins prepared by the same methods from the soluble fraction of the cells. On the basis of these and other observations, it is concluded that the 'relaxed particles' are not artefacts but are arrested ribosome precursors containing both rRNA and certain ribosomal proteins. The free pool of ribosomal proteins is low in exponential-phase cells and is not significantly increased by a 2 h period of starvation for glucose. The implications of these observations concerning the proteins associated with 'relaxed' and 'chloramphenicol particles' are discussed in raltion to ribosome biogenesis and the stabilization of rRNA.     

Structural Changes in Halophilic and Non-halophilic Proteases in Response to Chaotropic Reagents

Halophilic enzymes have been established for their stability and catalytic abilities under harsh operational conditions. These have been documented to withstand denaturation at high temperature, pH, organic solvents, and chaotropic agents. However, this stability is modulated by salt. The present study targets an important aspect in understanding protein–urea/GdmCl interactions using proteases from halophilic Bacillus sp. EMB9 and non-halophilic subtilisin (Carlsberg) from Bacillus licheniformis as model systems. While, halophilic protease containing 1 % (w/v) NaCl (0.17 M) retained full activity towards urea (8 M), non-halophilic protease lost about 90 % activity under similar conditions. The secondary and tertiary structure were lost in non-halophilic but preserved for halophilic protein. This effect could be due to the possible charge screening and shielding of the protein surface by Ca²⁺ and Na⁺ ions rendering it stable against denaturation. The dialyzed halophilic protease almost behaved like the non-halophilic counterpart. Incorporation of NaCl (up to 5 %, w/v or 0.85 M) in dialyzed EMB9 protease containing urea/GdmCl, not only helped regain of proteolytic activity but also evaded denaturing action. Deciphering the basis of this salt modulated stability amidst a denaturing milieu will provide guidelines and templates for engineering stable proteins/enzymes for biotechnological applications.     

Isolation of messenger RNA coding for the "fast" protein of embryonic chick feathers.

The messenger RNA coding for the "Fast" protein of embryonic chick feathers has been purified from the overwhelming relative amounts of keratin mRNA which are present in the developing feathers. The "Fast" protein mRNA represents about 4-8% of the total mRNA population of the feather. Despite differences between the size of the "Fast" proteins and the keratins the two mRNA species are very similar in molecular weight as judged by electrophoresis under denaturing conditions. However, by electrophoresis in 8 M urea gels at 55 degrees C, the "Fast" protein mRNA could be separated from keratin mRNA, presumably reflecting differences in messenger RNA secondary structure.     

An enzyme-linked immunosorbent assay for zein and other proteins using unconventional solvents for antigen adsorption

An enzyme-linked immunosorbent assay (ELISA) performed in polystyrene microtiter plates that can detect and quantitate the maize prolamin zein is described. The assay yields positive reactions with as little as 1 ng of antigen and uses solvents not ordinarily employed in ELISA methods. A systematic investigation of zein adsorption to polystyrene in various solvents supports the hypothesis that antigen binding occurs through nonpolar interactions. The method was also used to determine structural relationships among three zein polypeptides differing in size and charge. Additional experiments indicate that a number of soluble proteins are absorbed to polystyrene in the denaturing agent urea and retain immunological reactivity. The retention of antigen reactivity after solubilization in 6-8 M urea suggests that ELISA methods may be applicable to other proteins which are insoluble, or rendered insoluble, in aqueous buffers.     

Ribosomal proteins of Tetrahymena thermophila. Correlation of one- and two-dimensional electrophoretic migration patterns and characterization of additional small and large subunit proteins

Further analysis of the protein complement of the cytoplasmic ribosome of the protozoon Tetrahymena thermophila has led to the identification and characterization of seven additional proteins, three in the small and four in the large subunit of this ribosome. Several of these proteins are poorly soluble or insoluble in the absence of high concentrations of urea and are not seen in the electrophoretic distribution patterns of ribosomal proteins in two-dimensional polyacrylamide gels unless 6 M urea is added to electrode buffers in contact with protein samples (first dimension) and first-dimension gels (second dimension). The migration patterns of the 40S and 60S subunits of the T. thermophila ribosome in one-dimensional polyacrylamide SDS gels and in two-dimensional gels prepared by means of the basic-acidic system of Kaltschmidt and Wittmann**, and the basic-SDS system of Zinker and Warner*** have been correlated.     

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

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

Solution of ribosomal proteins under mild conditions.

Ribosomal proteins from two eucaryotic species, prepared by either the guanidine . HCl or LiCl . urea method and subsequently dissolved in 8 M urea were found to be largely retained in solution after removal of the urea by dialysis against a solution of low ionic strength (0.05 M Tris . HCl, pH 7.6, 0.025 M KCl, 0.005 M magnesium acetate) and centrifugation at 100,000 times g. The protein composition of this preparation was virtually identical to that of the original urea-containing solution as determined by two-dimensional polyacrylamide gel electrophoresis. Thus, there exists a very simple method for obtaining the bulk of the ribosomal proteins in solution under conditions where ribosomes themselves are stable.     

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.