The primary structure of ribosomal protein L3 from Escherichia coli 70 S ribosomes

Methylation of yeast ribosomal protein Rpl3 promotes translational elongation fidelity

Rpl3, a highly conserved ribosomal protein, is methylated at histidine 243 by the Hpm1 methyltransferase in Saccharomyces cerevisiae. Histidine 243 lies close to the peptidyl transferase center in a functionally important region of Rpl3 designated as the basic thumb that coordinates the decoding, peptidyl transfer, and translocation steps of translation elongation. Hpm1 was recently implicated in ribosome biogenesis and translation. However, the biological role of methylation of its Rpl3 substrate has not been identified. Here we interrogate the role of Rpl3 methylation at H243 by investigating the functional impact of mutating this histidine residue to alanine (rpl3-H243A). Akin to Hpm1-deficient cells, rpl3-H243A cells accumulate 35S and 23S pre-rRNA precursors to a similar extent, confirming an important role for histidine methylation in pre-rRNA processing. In contrast, Hpm1-deficient cells but not rpl3-H243A mutants show perturbed levels of ribosomal subunits. We show that Hpm1 has multiple substrates in different subcellular fractions, suggesting that methylation of proteins other than Rpl3 may be important for controlling ribosomal subunit levels. Finally, translational fidelity assays demonstrate that like Hpm1-deficient cells, rpl3-H243A mutants have defects in translation elongation resulting in decreased translational accuracy. These data suggest that Rpl3 methylation at H243 is playing a significant role in translation elongation, likely via the basic thumb, but has little impact on ribosomal subunit levels. Hpm1 is therefore a multifunctional methyltransferase with independent roles in ribosome biogenesis and translation.

15 Modification of phycobiliproteins at asparagine residues

Side-chain amide methylation of asparagine was described in a special complement of photosynthesis accessory pigment-protein complexes called phycobiliproteins nearly 20 years ago. Since that report, several investigations have assigned this posttranslational modification a functional role in tuning the spectroscopic properties of the phycobiliprotein chromophores. Asparagine methylation has not been reported in other systems and is restricted to the broader phycobiliprotein family. The methyltransferase responsible for this modification has been partially characterized but the structural gene has not been identified.

A top-down/bottom-up study of the ribosomal proteins of Caulobacter crescentus

Ribosomes from the Gram-negative alpha-proteobacterium Caulobacter crescentus were isolated using standard methods. Proteins were separated using a two-dimensional liquid chromatographic system that allowed the analysis of whole proteins by direct coupling to an ESI-QTOF mass spectrometer and of proteolytic digests by a number of mass spectrometric methods. The masses of 53 of 54 ribosomal proteins were directly measured. Protein identifications and proposed post-translational modifications were supported by proteolysis with trypsin, endoprotease Glu-C, and exoproteases carboxypeptidases Y and P. Tryptic peptide mass maps show an average sequence coverage of 62%, and carboxypeptidase C-terminal sequence tagging provided unambiguous identification of the small, highly basic proteins of the large subunit. C. crescentus presents some post-translational modifications that are similar to those of Escherichia coli (e.g., N-terminal acetylation of S9 and S18) along with some unique variations, such as a near absence of L7 and extensive modification of L11. The comprehensive description of this organism's ribosomal proteome provides a foundation for the study of ribosome structure, dependence of post-translational modifications on growth conditions, and the evolution of subcellular organelles.

Extending ribosomal protein identifications to unsequenced bacterial strains using matrix-assisted laser desorption/ionization mass spectrometry

A protocol has been developed that allows protein identifications using available DNA-based or protein sequences from a reference strain of a bacterial species to be extended to bacterial strains for which no prior DNA-based or protein sequence information exists. The protocol is predicated on careful isolation of a specific sub-cellular group of proteins. In this study, ribosomal proteins were chosen due to their high relative abundance and similarity in copy number per cell. After isolation of ribosomal proteins, MALDI-MS is used to acquire accurate protein molecular weights. An iterative comparison of reference protein molecular weights and identities is made to the resulting data, allowing for the straightforward identification of ribosomal proteins from any non-reference strains. This approach can reveal differences between proteins at the amino acid or post-translational level. The protocol was developed, validated and applied to ribosomal proteins from three strains of the extreme thermophile Thermus thermophilus. This approach revealed that nearly 60% of the ribosomal proteins from all three strains are identical. The extension of protein identification to additional bacterial strains can be useful in phylogenetic studies as well as in biomarker identification.

Characterization and analysis of posttranslational modifications of the human large cytoplasmic ribosomal subunit proteins by mass spectrometry and Edman sequencing

The 60S ribosomal proteins were isolated from ribosomes of human placenta and separated by reversed phase HPLC. The fractions obtained were subjected to trypsin and Glu-C digestion and analyzed by mass fingerprinting (MALDI-TOF), MS/MS (ESI), and Edman sequencing. Forty-six large subunit proteins were found, 22 of which showed masses in accordance with the SwissProt database (June 2002) masses (proteins L6, L7, L9, L13, L15, L17, L18, L21, L22, L24, L26, L27, L30, L32, L34, L35, L36, L37, L37A, L38, L39, L41). Eleven (proteins L7, L10A, L11, L12, L13A, L23, L23A, L27A, L28, L29, and P0) resulted in mass changes that are consistent with N-terminal loss of methionine, acetylation, internal methylation, or hydroxylation. A loss of methionine without acetylation was found for protein L8 and L17. For nine proteins (L3, L4, L5, L7A, L10, L14, L19, L31, and L40), the molecular masses could not be determined. Proteins P1 and protein L3-like were not identified by the methods applied.

The hemK gene in Escherichia coli encodes the N(5)-glutamine methyltransferase that modifies peptide release factors

Class 1 peptide release factors (RFs) in Escherichia coli are N(5)-methylated on the glutamine residue of the universally conserved GGQ motif. One other protein alone has been shown to contain N(5)-methylglutamine: E.coli ribosomal protein L3. We identify the L3 methyltransferase as YfcB and show that it methylates ribosomes from a yfcB strain in vitro, but not RF1 or RF2. HemK, a close orthologue of YfcB, is shown to methylate RF1 and RF2 in vitro. hemK is immediately downstream of and co-expressed with prfA. Its deletion in E.coli K12 leads to very poor growth on rich media and abolishes methylation of RF1. The activity of unmethylated RF2 from K12 strains is extremely low due to the cumulative effects of threonine at position 246, in place of alanine or serine present in all other bacterial RFs, and the lack of N(5)-methylation of Gln252. Fast-growing spontaneous revertants in hemK K12 strains contain the mutations Thr246Ala or Thr246Ser in RF2. HemK and YfcB are the first identified methyltransferases modifying glutamine, and are widely distributed in nature.

Molecular cloning and characterization of a TAR-binding nuclear factor from T cells

The TAt protein of the human immunodeficiency virus type 1 (HIV-1) activates the expression of viral mRNA through a cis-acting element in the LTR termed TAR. TAR RNA forms a stable stem-loop structure. Mutagenesis studies indicate that the stem structure, the primary sequence of the loop, and three unpaired bases in the stem (bulge) are important for Tat activation. Using the in vitro-transcribed TAR RNA as a probe, we have cloned a gene (TARBP-b) that encodes a TAR-binding protein from a cDNA expression library derived from Hut-78 cells. Expression of the 1.4-kb TARBP-b mRNA was observed in all mammalian cell lines tested. TARBP-b binds specifically to the bulge region of TAR RNA and trans-activates the HIV-1 long terminal repeat in the presence of ptat and prev expression plasmids. These results suggest that TARBP-b contributes to tat-mediated trans-activation.

Primary structures of ribosomal proteins L3 and L4 from Bacillus stearothermophilus

Ribosomal proteins L3 and L4 were purified to homogeneity from total protein isolated from the 50S subunit of Bacillus stearothermophilus by reversed-phase high-performance liquid chromatography (RP-HPLC). Amino acid sequences of both proteins were determined by automated N-terminal sequence analysis and sequencing of internal peptides. Using oligonucleotides deduced from the N-terminal region of protein L3 as hybridization probes, a DNA fragment coding for proteins L3, L4 and the N-terminal part of protein L23 has been identified, cloned and sequenced. The organization of the genes is identical to that found in the S10 operon of Escherichia coli. Comparison of the sequences of proteins L3 and L4 with those of other organisms revealed that all proteins of the L3 family are highly conserved. On the other hand, the archaebacterial L4 proteins show no significant sequence similarity to the E. coli L4 protein whereas the L4 protein of B. stearothermophilus is significantly similar to all of the L4 proteins and thus justifies the membership of all the L4 proteins in one protein family. The results are discussed with respect to the phylogenetic relationship between eubacteria, archaebacteria and eukaryotes and possible functional domains of proteins L3 and L4.

YmL9, a nucleus-encoded mitochondrial ribosomal protein of yeast, is homologous to L3 ribosomal proteins from all natural kingdoms and photosynthetic organelles

The nuclear gene for mitochondrial ribosomal protein YmL9 (MRP-L9) of yeast has been cloned and sequenced. The deduced amino acid sequence characterizes YmL9 as a basic (net charge + 30) protein of 27.5 kDa with a putative signal peptide for mitochondrial import of 19 amino acid residues. The intact MRP-L9 gene is essential for mitochondrial function and is located on chromosome XV or VII. YmL9 shows significant sequence similarities to Escherichia coli ribosomal protein L3 and related proteins from various organisms of all three natural kingdoms as well as photosynthetic organelles (cyanelles). The observed structural conservation is located mostly in the C-terminal half and is independent of the intracellular location of the corresponding genes [Graack, H.-R., Grohmann, L. & Kitakawa, M. (1990) Biol. Chem. Hoppe Seyler 371, 787-788]. YmL9 shows the highest degree of sequence similarity to its eubacterial and cyanelle homologues and is less related to the archaebacterial or eukaryotic cytoplasmic ribosomal proteins. Due to their high sequence similarity to the YmL9 protein two mammalian cytoplasmic ribosomal proteins [MRL3 human and rat; Ou, J.-H., Yen, T. S. B., Wang, Y.-F., Kam, W. K. & Rutter, W. J. (1987) Nucleic Acids Res. 15, 8919-8934] are postulated to be true nucleus-encoded mitochondrial ribosomal proteins.

Cloning and characterization of a human ribosomal protein gene with enhanced expression in fetal and neoplastic cells

Hepatocellular carcinoma is strongly associated with hepatitis B virus carrier patients who usually have HBV sequences integrated in the chromosomal DNA of liver cells. To assess the possible effects of HBV regulatory sequences (e.g., the enhancer) on expression of neighboring host genes we have screened for cellular genes that are both overexpressed and adjacent to integrated HBV sequences in hepatocellular carcinoma cells. The cloned cDNA for one such gene encodes a protein similar to the E. coli L-3 ribosomal protein which is thought to play a role in mRNA binding to the ribosome. The protein encoded by the cDNA localizes to the nucleolus and is also found in ribosomes; possibly it is the mammalian homologue of L-3 (MRL3). The expression of MRL3 is higher in colon carcinoma and lymphoma cell lines than in normal liver, placenta and diploid fibroblasts, and is also higher in fetal than in adult liver. Therefore, MRL3 overexpression seems to be a property of rapidly dividing cells and is not directly linked to oncogenesis.

Structure of the Escherichia coli S10 ribosomal protein operon

The complete structure of the Escherichia coli S10 ribosomal protein operon is presented. Based on the DNA sequence, the deduced order of the 11 genes in the operon is rpsJ, rplC, rplD, rplW, rplB, rpsS, rplV, rpsC, rplP, rpmC, rpsQ. The estimated transcribed length of the operon is 5181 base pairs. Putative sequences involved in ribosome binding are discussed. The DNA sequence data corrects several errors in previously determined protein sequence data.

The structural periodicity of E. coli ribosomal proteins

It is established that the sequences of all different proteins from E. coli ribosome as well as two protein biosynthesis initiation factors, two ribosome-associated DNA-binding proteins, and the elongation factor EF-Tu from the same source possess a periodicity expressed more weakly and different from that found earlier for a number of proteins representatives of 18 superfamilies. The statistical significance of the periodicity observed was checked by comparing the area below the periodicity curve of every protein examined with that of computer generated sequences having the same amino acid composition and length. The results concerning the proteins from small and large ribosomal subunit are compared. The conclusions support and supplement the concept about the presence of a trend in protein molecular evolution from universal (Gly, Ala) to specialized (Phe, Tyr, Trp, Cys) amino acids.

Cold-sensitive ribosome assembly in an Escherichia coli mutant lacking a single methyl group in ribosomal protein L3

Ribosomal protein methylation has been well documented but its function remains unclear. We have examined this phenomenon using an Escherichia coli mutant (prmB2), which fails to methylate glutamine residue number 150 of ribosomal protein L3. This mutant exhibits a cold-sensitive phenotype: its growth rate at 22 degrees C is abnormally low in complete medium. In addition, strains with this mutation accumulate abnormal and unstable ribosomal particles; 50-S and 30-S subunits are formed, but at a lower rate. Once assembled, ribosomes with unmethylated L3 are fully active by several criteria. (a) Protein synthesis in vitro with purified 70-S prmB2 ribosomes is as active as wild-type using either a natural (R17) or an artificial [poly(U)] messenger. (b) The induction of beta-galactosidase in vivo exhibits normal kinetics and the enzyme has a normal rate of thermal denaturation. (c) These ribosomes are standard when exposed in vitro to a low magnesium concentration or increasing molarities of LiCl. Efficient methylation of L3 in vitro requires either unfolded ribosomes or a mixture of ribosomal protein and RNA. We suggest that the L3-specific methyltransferase may qualify as one of the postulated 'assembly factors' of the E. coli ribosome.

Regulation of the S10 ribosomal protein operon in E. coli: nucleotide sequence at the start of the operon

We have determined the DNA sequence of a 1250 base pair segment of the Escherichia coli chromosome that carries the promoter for the S10 ribosomal protein operon, the S10 gene and part of the L3 gene. A DNA fragment carrying the putative S10 promoter was cloned into the plasmid mini-Col E1, which contains a transcription termination signal close to the single Hind II site. Cells harboring the hybrid plasmid produced a relatively stable hybrid mRNA with the expected sequence, demonstrating that the promoter functions in vivo. Comparison of the mRNA sequence around the start of the S10 coding region, the presumed target site for L4 repressor protein, with the known binding site for L4 on 23S rRNA revealed the presence of sequence homologies. This supports the model of the translational feedback regulation of the S10 operon by L4.

Photochemical cross-linking of elongation factor G to 70-S ribosomes from Escherichia coli by 4-(6-formyl-3-azidophenoxy)butyrimidate

Ribosomal proteins situated at or near the binding site of elongation factor G (EF-G) on the Escherichia coli ribosome have been identified by use of the heterobifunctional cross-linker 4-(6-formyl-3-azidophenoxy)butyrimidate. Four different preparations of EF-G, in which the number of cross-linker molecules coupled to EF-G ranged from four to seven, all cross-linked to 50-S subunit proteins L1, L3 and L11 as well as to 30-S subunit proteins S3 and S4. Cross-linking of EF-G to ribosomal proteins was tested electrophoretically. In the case of L7/L12 and L11 immunological methods were also used. Cross-linking of EF-G to L1, L3, L11, S3 and S4 is specific as judged from the fact that addition of unmodified EF-G and of thiostrepton results in less cross-linking. The cross-linking data suggests that the binding site for EF-G includes several proteins which are located at the interface between the 30-S and 50-S subunits.

Methylated amino acids in ribosomal proteins from Escherichia coli treated with ethionine and from a mutant lacking methylation of protein L11

In the present study, the nature, proportions and distribution of methylated amino acids in ribosomal proteins from Escherichia coli grown in the presence of ethionine and from mutant prm 1 were studied. The undermethylated ribosomes had been labeled by addition in vitro or in vivo of radioactive methyl groups from S-adenosylmethionine or from methionine. The following compounds were identified : N alpha-mono-, di- and trimethylalanines, N epsilon-mono-, di- and trimethyllysines, methylamine and N alpha-trimethylalanyllysine. Except for the latter compound and N-alpha-dimethylalanine, all other derivatives had been previously identified in the literature. It is shown that the dipeptide had been in the past mistaken for N epsilon-monomethyllysine, and arises through incomplete hydrolysis in 24 hrs of the N-terminal peptide bond of protein L11. The results of the present study are discussed in the light of previous work on ribosomal protein methylation by the authors and other workers in the field.