Localization of proteins L4, L5, L20 and L25 on the ribosomal surface by immuno-electron microscopy

Summary Ribosomal proteins L4, L5, L20 and L25 have been localized on the surface of the 50S ribosomal subunit of Escherichia coli by immuno-electron microscopy. The two 5S RNA binding proteins L5 and L25 were both located at the central protuberance extending towards its base, at the interface side of the 50S particle. L5 was localized on the side of the central protuberance that faces the L1 protuberance, whereas L25 was localized on the side that faces the L7/L12 stalk. Proteins L4 and L20 were both located at the back of the 50S subunit; L4 was located in the vicinity of proteins L23 and L29, and protein L20 was localized between proteins L17 and L10 and is thus located below the origin of the L7/L12 stalk.     

Two-dimensional maps in very acidic immobilized pH gradients

Up to the present time it has been impossible to perform two-dimensional (2-D) separations in very acidic immobilized pH gradients (IPG), due to the lack of suitable buffering acrylamido derivatives to be incorporated into the polyacrylamide matrix. The advent of the pK 3.1 buffer (2-acrylamido glycolic acid; Righetti et al., J. Biochem. Biophys. Methods 16, 1988, 185–192) allowed the formulation of such acidic gradients. We report here separations in IPG pH 2.8–5.0 intervals of polypeptide chains from total lysates of rat intestinal and liver cells and 30S and 50S ribosomal proteins from Halobacterium marismortui. Conditions are given for highly reproducible first and second dimensions gels and for a proper silver staining of 2-D maps with practically no background deposition.     

Protein-protein cross-linking of the 50 S ribosomal subunit of Escherichia coli using 2-iminothiolane. Identification of cross-links by immunoblotting techniques

We have investigated the protein-protein cross-links formed within the 50 S subunit of the Escherichia coli ribosome using 2-iminothiolane as the cross-linking reagent. The members of the cross-links have been identified by immunoblotting from one-dimensional and two-dimensional diagonal sodium dodecyl sulfate-polyacrylamide gels using antisera specific for the individual ribosomal proteins. This method also allowed a quantitation of the yield of cross-linking for each cross-link. A total of 14 cross-links have been identified: L1-L33, L2-L9, L2-L9-L28, L3-L19, L9-L28, L13-L21, L14-L19, L16-L27, L17-L30, L17-L32, L19-L25, L20-L21, L22-L32, and L23-L34. Our results are compared with those of Traut and coworkers (Traut, R. R., Tewari, D. S., Sommer, A., Gavino, G. R., Olson, H. M., and Glitz, D. G. (1986) in Structure, Function and Genetics of Ribosomes (Hardesty, B. and Kramer, G., eds) pp. 286-308, Springer-Verlag, New York). Our cross-linking data allow us to propose the approximate locations of eight proteins of the 50 S ribosomal subunit that so far have not been localized by immunoelectron microscopy and they thus contribute considerably to our knowledge of ribosome structure.     

Mutants of Escherichia coli lacking ribosomal protein L11

Three mutants with ribosomes apparently lacking Protein L11, AM68, AM76, and AM77, were investigated using a variety of immunological techniques to determine whether L11 was indeed lacking. Ouchterlony double diffusion, modified immunoelectrophoresis, and dimer formation on sucrose gradients all gave results indicating Protein L11 was missing from the ribosome in these mutants. Electron micrographs of ribosomes of the mutants were indistinguishable from those of wild type. Ribosomes of AM68, AM76, and AM77, did not bind the antibiotic thiostrepton, but binding was recovered upon reconstitution with wild type Protein L11.     

Localization of ribosomal protein S2 on the surface of the 30S subunit from Escherichia coli, using monoclonal antibodies.

Protein S2 has been localized on the surface of the 30S subunit of Escherichia coli by immuno-electron microscopy. The antibody was obtained from a fusion of myeloma cells with spleen cells of mice, which had been immunized with intact 30S ribosomal subunits of E. coli. The binding site of the antibody was on the head of the small subunit, just above the small lobe, in the region where protein S3 has also been localized. S2 is the first ribosomal protein to have been mapped exclusively with monoclonal antibody.     

Characterisation of a mutant from Escherichia coli lacking protein L15 and localisation of protein L15 by immuno-electron microscopy

Two mutants lacking protein L15 from the ribosome as determined by two dimensional gels were investigated using a number of different immunological methods. One strain was found to possess several protein L15 moieties which differed in net charge and in size. The other showed no evidence of L15 cross-reacting material (CRM) on the ribosome or in the supernatant. Ribosomes of this strain were used as a control in the process of the localisation of protein L15 on the surface of the large subunit of Escherichia coli ribosomes. Antigenic determinants mapped in the angle between the central protuberance and the L1 protuberance. Protein L15 has been assigned a central role in the large subunit in vitro assembly map, in peptidyltransferase activity and in the binding of erythromycin, so the significance of a mutant lacking this protein is discussed.     

A model for the spatial arrangement of the proteins in the large subunit of the Escherichia coli ribosome.

A three-dimensional model for the arrangement of 29 of the 33 proteins from the Escherichia coli large ribosomal subunit has been generated by interactive computer graphics. The topographical information that served as input in the model building process was obtained by combining the immunoelectron microscopically determined network of epitope-epitope distances on the surface of the large ribosomal subunit with in situ protein-protein cross-linking data. These two independent sets of data were shown to be compatible by geometric analysis, thus allowing the construction of an inherently consistent model. The model shows (i) that the lower third of the large subunit is protein-poor, (ii) that proteins known to be functionally involved in peptide bond formation and translocation are clustered in two separate regions, (iii) that proteins functionally interdependent during the self-assembly of the large subunit are close neighbours in the mature subunit and (iv) that proteins forming the early assembly nucleus are grouped together in a distinct region at the 'back' of the subunit.     

The topography of ribosomal proteins on the surface of the 30S subunit of Escherichia coli

Eight ribosomal proteins, S6, S10, S11, S15, S16, S18, S19 and S21 have been localized on the surface of the 30S subunit from Escherichia coli by immuno electron microscopy. The specificity of the antibody binding sites was demonstrated by stringent absorption experiments. In addition we have reinvestigated and refined the locations of proteins S5, S13 and S14 on the ribosomal surface which had previously been localized in our laboratory (Tischendorf et al., Mol. Gen. Genet. 134, 209-223, 1974). Thus altogether 16 out of the 21 ribosomal proteins of the small subunit from E. coli have been mapped in our laboratory.     

The binding site of ribosomal protein L10 in eubacteria and archaebacteria is conserved: reconstitution of chimeric 50S subunits.

It has been shown by electron microscopy that the selective removal of the stalk from 50S ribosomal subunits of two representative archaebacteria, namely Methanococcus vaniellii and Sulfolobus solfataricus, is accompanied by loss of the archaebacterial L10 and L12 proteins. The stalk was reformed if archaebacterial core particles were reconstituted with their corresponding split proteins. Next, structurally intact chimeric 50S subunits have been reconstituted in vitro by addition of Escherichia coli ribosomal proteins L10 and L7/L12 to 50S core particles from M vaniellii or S solfataricus, respectively. In the reverse experiment, using core particles from E coli and split proteins from M vaniellii, stalk-bearing 50S particles were also obtained. Analysis of the reconstituted 50S subunits by immunoblotting revealed that E coli L10 was incorporated into archaebacterial core particles in both presence or absence of E coli L7/L12. In contrast, incorporation of E coli L7/L12 into archaebacterial cores was only possible in the presence of E coli L10. Our results suggest that in archaebacteria - as in E coli - the stalk is formed by archaebacterial L12 proteins that bind to the ribosome via L10. The structural equivalence of eubacterial and archaebacterial L10 and L12 proteins has thus for the first time been established. The chimeric reconstitution experiments provide evidence that the domain of protein L10 that interacts with the ribosomal particle is highly conserved between eubacteria and archaebacteria.     

Mutants of Escherichia coli lacking ribosomal protein L1

Two independently isolated mutants of Escherichia coli, RD19 and MV17-10, that appeared to lack protein L1 on their ribosomes, as determined by two-dimensional gels, were subjected to a battery of immunological tests to find if L1 was indeed lacking. The tests involved Ouchterlony double diffusion, modified immunoelectrophoresis, dimer formation on sucrose gradients, and affinity chromatography. By all these criteria, protein L1 was missing from the ribosome in these mutants. Nor was any L1 cross-reacting material detectable in the supernatant. There was, however, a specific two- to fivefold increase in concentrations of protein L11 in the supernatants of the mutants, which was evidence that protein L1 acts as a feedback inhibitor of expression of the operon coding for the genes for proteins L11 and L1.Electron micrographs of ribosomes obtained from these mutants were indistinguishable from those of wild-type strains. 50 S ribosomal subunits from mutants RD19 and MV17-10 were reconstituted with purified L1 from wild-type and investigated by immunoelectron microscopy. The three-dimensional location of ribosomal protein L1 on the surface of the large subunit was determined. L1 is located on the wider lateral protuberance of the 50 S subunit. The position of protein L1 in 50 S subunits reconstituted from mutants RD19 and MV17-10 was indistinguishable from the position in subunits from wild-type.