E. coli ribosomal protein L4 is a feedback regulatory protein

We studied the synthesis of ribosomal proteins encoded by the S10 operon, an eleven gene operon from the str-spc region of the E. coli chromosome, using a λfus3 DNA-directed, in vitro protein synthesizing system. Addition of ribosomal protein L4 (1 μM) to in vitro protein synthesis reactions caused selective inhibition of synthesis of the promoter-proximal proteins of the S10 operon, S10, L3, L4, L23 and possibly L2. Proteins of the S10 operon other than L4 did not cause selective inhibition of protein synthesis. Autoregulatory ribosomal proteins previously identified from other operons, L1, S4 and S8, did not inhibit protein synthesis from the S10 operon; nor did L4 cause significant inhibition of protein synthesis from operons other than the S10 operon. As with L1, S4 and S8, L4 inhibits gene expression at the level of translation.     

Analysis of a sequence region of 5S RNA from E. coli cross-linked in situ to the ribosomal protein L25.

70S ribosomes from E. coli were chemically cross-linked under conditions of in vitro protein biosynthesis. The ribosomal RNAs were extracted from reacted ribosomes and separated on sucrose gradients. The 5S RNA was shown to contain the ribosomal protein L25 covalently bound. After total RNase T1 hydrolysis of the covalent RNA-protein complex several high molecular weight RNA fragments were obtained and identified by sequencing. One fragment, sequence region U103 to U120, was shown to be directly linked to the protein first by protein specific staining of the particular fragment and second by phosphor cellulose chromatography of the covalent RNA-protein complex. The other two fragments, U89 to G106 and A34 to G51, could not be shown to be directly linked to L25 but were only formed under cross-linking conditions. While the fragment U89 to G106 may be protected from RNase T1 digestion because of a strong interaction with the covalent RNA-protein complex, the formation of the fragment A34 to G51 is very likely the result of a double monovalent modification of two neighbouring guanosines in the 5S RNA. The RNA sequences U103 to U120 established to be in direct contact to the protein L25 within the ribosome falls into the sequence region previously proposed as L25 binding site from studies with isolated 5S RNA-protein complexes.     

Studies on 30S ribosomal protein S1 from E. coli. I. Purification and physicochemical properties.

1. The distribution of ribosomal protein S1 in subcellular fractions of E. coli was determined by radioimmunoassay. It was found that about 70%, 20% and 10% of protein S1 were present in the high salt (1.0 M NH4Cl)-washed ribosomes, the ribosomal wash and the S100 fraction, respectively. 2. Protein S1 was purified from unwashed ribosomes by an improved procedure which included: (i) extraction of protein S1 from unwashed ribosomes with 1.2 M LiCl and 1.0 M NH4Cl, (ii) ammonium sulfate fractionation, (iii) two successive column chromatographies on DEAE-Sephadex, and (iv) hydroxylapatite column chromatography. Purified protein S1 was homogeneous in polyacrylamide gel electrophoresis under native and denatured conditions. 3. The molecular weights determined by sedimentation equilibrium and by SDS-polyacrylamide gel electrophoresis were 83,000 and 70,000 respectively. The sedimentation coefficient was estimated as 3.0S by glycerol gradient centrifugation. The stokes radius determined by Sephadex G-200 gel filtration was 45 A. From these data, the frictional ratio of protein S1 was calculated to be 1.65, assuming the molecular weight and partial specific volume to be 70,000 and 0.736, respectively. Protein S1 had an elongated shape with an axial ratio of approximately 8.5. 4. Protein S1 contained 2 residues of half-cystine and about 10 residues of tryptophan. From CD measurements, the contents of alpha-helix and beta-structure were estimated to be 32 and 27%, respectively. 5. As reported by Kolb et al. (1977) (Proc. Natl. Acad. Sci. U.S. 74, 2379-2383), and Draper et al. (1977) (Proc. Natl. Acad. Sci. U.S. 74, 4786-4790), the intrinsic fluorescence of protein S1 was markedly quenched on interaction with poly(U). The maximal quenching was observed when 30 mol of poly(U) (as UMP residues) was added to one mol of the protein.     

Physical studies on the conformation of ribosomal protein S4 from Escherichia coli.

Proton magnetic resonance, circular dichroism and infrared spectroscopy were used to investigate the secondary and tertiary structure of the 16-S RNA binding protein S4 from Escherichia coli ribosomes. The proton magnetic resonance spectra of protein S4 in ribosomal reconstitution and low-salt buffers were identical and showed little dipolar broadening of the peaks, suggesting that the protein had an open extended structure. A ring-current-shifted apolar methyl resonance in the high-field region of the spectrum, together with a perturbation of the tyrosine ring proton resonance in the low-field region, indicated the existence of a specific tertiary fold in the polypeptide chain. This structure disappeared on lowering the pH below 5 or on heating above 30 degrees C, both processes being reversible. Circular dichroism measurements on protein S4 showed an alpha-helix content of 32% in reconstitution buffer compared with 26% in low-salt buffer. Heating the protein solution in reconstitution buffer above 35 degrees C reversibly disrupted this extra helix. Infrared studies on both solid films and solutions of protein S4 indicated the presence of little or no beta-structure. These results correlate well with the known RNA binding properties of protein S4.     

Studies on the RNA and protein binding sites of the E. coli ribosomal protein L10.

We have used modification of specific amino acid residues in the E. coli ribosomal protein L10 as a tool to study its interactions with another ribosomal protein, L7/L12, as well as with ribosomal core particles and with 23S RNA. The ribosome and RNA binding capability of L10 was found to be inhibited by modification of one more of its arginine residues. This treatment does not affect the ability of L10 to bind four molecules of L7/L12 in a L7/L12-L10 complex. Our results support the view that L10's role in promoting the L7/L12-ribosome association is due primarily to its ability to bind to both 23S RNA and L7/L12 simultaneously.     

Genetic engineering and overexpression of ribosomal L12 protein genes from three different archaebacteria in E coli.

Genes coding for ribosomal protein L12 from Methanococcus vannielii (Mva), Halobacterium halobium (Hha) and Sulfolobus solfataricus (Sso) have been subcloned in the polylinker region of pUC19. An efficient Shine-Dalgarno sequence has been attached to the 5' end of the genes, and two ochre stop codons have been created at their 3' ends, where necessary. In addition, mutants of the MvaL12 and HhaL12 genes were constructed, which coded for a cysteine residue at the C-terminus of the protein. The constructs were transferred together with the pUC19 polylinker as gene cartridges into different expression vectors. These constructed plasmids were transformed in the appropriate E coli hosts and tested for expression. Two systems were found to work efficiently for overexpression, namely the pKK223-3 vector featuring a tac promoter, and the pT7-5 vector featuring a T7-promoter. The over-expressed proteins were purified to homogeneity; their purity was investigated by one and two-dimensional gel systems, amino acid analysis and N-terminal protein sequencing for 10 steps or more. The amount of protein purified from E coli test cultures bearing the expression plasmids was always more than 2.5 mg/l of medium used.     

Purification and properties of a ribosomal protein methylase from Eschericha coli Q13.

Ribosomal protein methylase has been purified from Escherichia coli strain Q13 using methyl-deficient 50S subunits as substrates. The purified enzyme (or enzyme complex) which is devoid of rRNA methylating activity is quite stable and has a pH optimum around 8.0. The Km for S-adenosyl-L-methionine is 3.2 muM. The molecular weight of the enzyme is 3.1 X 10(4); minor methylating activity was also detected for protein peaks with molecular weights of 1.7 X 10(4) and 5.6 X 10(4). Protein L11 is the major protein methylated by the purified enzyme. Product analysis revealed the presence of N epislon-trimethyllysine, a methylated neutral amino acid(s) previously observed in protein L11 and N epislon-monomethyllysine. Free ribosomal proteins were much better substrates for the methylation, indicating that methylation of 50S ribosomal proteins can occur before the complete assembly of the 50S ribosomal subunit.     

Regulation of the in vitro synthesis of E. coli ribosomal protein L12.

The $\text{in}\text{vitro}$ DNA dependent synthesis of ribosomal protein L12 and the β subunit of RNA polymerase has been investigated using DNA from a plasmid which contains the genetic information for ribosomal protein L12 and the β subunit of RNA polymerase. This DNA, however, lacks the promoter region and the genetic information for the first 26 amino acids of ribosomal protein L10. It was found that L12 and the β subunit of RNA polymerase are efficiently synthesized $\text{in}\text{vitro}$ from this DNA. These results suggest that L12 and the β subunit of RNA polymerase can be synthesized from a promoter situated within the L10 gene.     

Protein L4 of the E. coli ribosome regulates an eleven gene r protein operon

We have previously reported autogenous regulation of the S10 operon encoding eleven ribosomal proteins. By measuring the synthesis of individual r proteins after specific oversynthesis of nine different ribosomal proteins from the S10 operon, we now find that one, L4, affects the expression of the operon. Moreover, the induction of L4 synthesis results in a strong reduction of the synthesis of mRNA from at least four genes of the S10 operon.     

Yeast ribosomal protein L25 binds to an evolutionary conserved site on yeast 26S and E. coli 23S rRNA.

The binding site of the yeast 60S ribosomal subunit protein L25 on 26S rRNA was determined by RNase protection experiments. The fragments protected by L25 originate from a distinct substructure within domain IV of the rRNA, encompassing nucleotides 1465-1632 and 1811-1861. The protected fragments are able to rebind to L25 showing that they constitute the complete protein binding site. This binding site is remarkably conserved in all 23/26/28S rRNAs sequenced to date including Escherichia coli 23S rRNA. In fact heterologous complexes between L25 and E. coli 23S rRNA could be formed and RNase protection studies on these complexes demonstrated that L25 indeed recognizes the conserved structure. Strikingly the L25 binding site on 23S rRNA is virtually identical to the previously identified binding site of E. coli ribosomal protein EL23. Therefore EL23 is likely to be the prokaryotic counterpart of L25 in spite of the limited homology displayed by the amino acid sequences of the two proteins.     

Probing ribosome function and the location of Escherichia coli ribosomal protein L5 with a monoclonal antibody

A monoclonal antibody specific for Escherichia coli ribosomal protein L5 was isolated from a cell line obtained from Dr. David Schlessinger. Its unique specificity for L5 was confirmed by one- and two-dimensional electrophoresis and immunoblotting. The antibody recognized L5 both in 50 S subunits and 70 S ribosomes. Both antibody and Fab fragments had similar effects on the ribosome functions tested. Antibody bound to 50 S subunits inhibited their reassociation with 30 S subunits at 10 mM Mg2+ but not 15 mM, the concentration present for in vitro protein synthesis. The 70 S couples were not dissociated by the antibody. The antibody caused inhibition of polyphenylalanine synthesis at molar ratios to 50 S or 70 S particles of 4:1. The major inhibitory effect was on the peptidyltransferase reaction. There was no effect on either elongation factor binding or the associated GTPase activities. The site of antibody binding to 50 S was determined by electron microscopy. Antibody was seen to bind beside the central protuberance or head of the particle, on the side away from the L7/L12 stalk, and on or near the region at which the 50 S subunit interacts with the 30 S subunit. This site of antibody binding is fully consistent with its biochemical effects.     

Structural properties of ribosomal protein L11 from Escherichia coli

Protein L11 has been isolated from the large subunit of the E. coli ribosome under non-denaturing conditions and studied by proton magnetic resonance spectroscopy, limited proteolysis, and fluorescence and UV spectroscopy. The protein consists of two domains, a tightly-folded N-terminal part and a C-terminal half with an extended and loosely folded conformation. It is likely that the N-terminal domain is located on the surface of the subunit whereas the C-terminal part is buried within the ribosomal structure. The two tyrosines in the N-terminal region behave as solvent-exposed residues, in good agreement with iodination studies on L11 in situ. It appears probable that the central region of L11, in which the protease cleavages occur, plays an important part in structural and functional aspects.     

Structure of ribosomal protein L6 from Escherichia coli. A fluorescence study

Protein L6 from the 50-S ribosomal subunit has been investigated using fluorimetric techniques. The intrinsic fluorophore Trp-61 and fluorescent labels (acetylaminoethyl-dansyl and acetylaminofluorescein) attached to the residue Cys-124 were used. It proved possible to incorporate fluorescence-labelled L6 into the 50-S ribosome. Trp-61 is exposed to solvent, as shown by its emission wavelength and by quenching experiments; the latter also show that it lies in a pocket with a high positive charge due to the basic residues in the N-terminal fragment. Cys-124 lies in a less strongly positive region. Upon incorporation into the 50-S subunit, the label on Cys-124 becomes less accessible for quenching but its positive potential rises, showing the absence of direct contact with 23-S RNA. Analysis of anisotropy data indicates a considerable degree of asphericity of free L6. Energy transfer between Trp-61 and the dansyl label on Cys-124, measured by donor quenching and acceptor enhancement, reveals a separation of 3.5 +/- 0.4 nm (35 +/- 4 A) between fluorophores.     

Primary structure of Escherichia coli ribosomal protein L31.

Protein L31 from the 50S ribosomal subunit of Escherichia coli was manually sequenced by the dansyl-Edman method. Owing to the availability of only small quantities of purified L31, sequencing methods were scaled down such that the entire primary structure could be determined with 700 microgram of protein. The techniques employed are described in detail. The protein consists of a single chain of 62 amino acids, with a calculated molecular weight of 6967. Four half-cystine residues were identified at positions 16, 18, 37, and 40. Evidence is presented that suggests that these residues form two disulfide bridges in the protein, as isolated.