Methylation of newly synthesized ribosomal protein L11 in a DNA-directed in vitro system

Methylation of proteins involved in translation

Methylation is one of the most common protein modifications. Many different prokaryotic and eukaryotic proteins are methylated, including proteins involved in translation, including ribosomal proteins (RPs) and translation factors (TFs). Positions of the methylated residues in six Escherichia coli RPs and two Saccharomyces cerevisiae RPs have been determined. At least two RPs, L3 and L12, are methylated in both organisms. Both prokaryotic and eukaryotic elongation TFs (EF1A) are methylated at lysine residues, while both release factors are methylated at glutamine residues. The enzymes catalysing methylation reactions, protein methyltransferases (MTases), generally use S-adenosylmethionine as the methyl donor to add one to three methyl groups that, in case of arginine, can be asymetrically positioned. The biological significance of RP and TF methylation is poorly understood, and deletions of the MTase genes usually do not cause major phenotypes. Apparently methylation modulates intra- or intermolecular interactions of the target proteins or affects their affinity for RNA, and, thus, influences various cell processes, including transcriptional regulation, RNA processing, ribosome assembly, translation accuracy, protein nuclear trafficking and metabolism, and cellular signalling. Differential methylation of specific RPs and TFs in a number of organisms at different physiological states indicates that this modification may play a regulatory role.

Molecular cloning, sequencing, and expression of a chemoreceptor gene from Leptospirillum ferrooxidans

We have cloned and sequenced a 2,262-bp chromosomal DNA fragment from the chemolithoautotrophic acidophilic bacterium Leptospirillum ferrooxidans. This DNA contained an open reading frame for a 577-amino-acid protein showing several characteristics of the bacterial chemoreceptors and, therefore, we named this gene lcrI for Leptospirillum chemotaxis receptor I. This is the first sequence reported for a gene from L. ferrooxidans encoding a protein. The lcrI gene showed both sigma 28-like and sigma 70-like putative promoters. The LcrI deduced protein contained two hydrophobic regions most likely corresponding to the two transmembrane regions present in all of the methyl-accepting chemotaxis proteins (MCPs) which make them fold with both periplasmic and cytoplasmic domains. We have proposed a cytoplasmic domain for LcrI, which also contains the highly conserved domain (HCD region), present in all of the chemotactic receptors, and two probable methylation sites. The in vitro expression of a DNA plasmid containing the 2,262-bp fragment showed the synthesis of a 58-kDa protein which was immunoprecipitated by antibodies against the Tar protein (an MCP from Escherichia coli), confirming some degree of antigenic conservation. In addition, this 58-kDa protein was expressed in E. coli, being associated with its cytoplasmic membrane fraction. It was not possible to determine a chemotactic receptor function for LcrI expressed in E. coli. This was most likely due to the fact that the periplasmic pH of E. coli, which differs by 3 to 4 pH units from that of acidophilic chemolithotrophs, does not allow the right conformation for the LcrI periplasmic domain.

Modulation of the heat shock response by one-carbon metabolism in Escherichia coli

A genetic screen designed to isolate mutants of Escherichia coli W3110 altered in the ability to induce the heat shock response identified a strain unable to induce the heat shock proteins in a rich, defined medium lacking methionine after exposure to 2,4-dinitrophenol. This strain also grew slowly at 28 degrees C and linearly at 42 degrees C in this medium. The abnormal induction of the heat shock proteins and abnormal growth at both high and low temperatures were reversed when methionine was included in the growth medium. The mutation responsible for these phenotypes mapped to the glyA gene, a biosynthetic gene encoding the enzyme that converts serine and tetrahydrofolate to glycine and 5,10-methylenetetrahydrofolate. This reaction is the major source of glycine and one-carbon units in the cell. Because fixed one-carbon units, in the form of methionine, allowed mutant cells to induce the heat shock response after exposure to 2,4-dinitrophenol, a one-carbon restriction may be responsible for the phenotypes described above.

Prokaryotic gene expression in vitro: transcription-translation coupled systems

Transcription-translation coupled systems have been developed to study prokaryotic gene expression. Several types of expression system have been described. The original system consists of a crude unfractionated Escherichia coli extract, which supports protein synthesis directed by a template DNA. Control of gene expression at the transcriptional stage has been studied using this unfractionated system. In this respect, two examples of particular interest, lactose and tryptophan operons, are described. Other systems are either partially reconstituted or highly defined, containing up to 30 purified factors necessary for transcription (RNA polymerase) and translation (aminoacyl-tRNA synthetases, initiation, elongation and release factors). Additional differences between the various systems relate to the analysis of the gene products. Whereas most methods involve analysis of the totally synthesized protein, a particular system implies the formation of only the N-terminal di- or tripeptide of the gene product. Reconstituted systems have proved useful in studies on transcriptional, e.g., discovery and role of L factor, as well as translational regulation of gene expression, e.g., autogenous control of ribosomal protein synthesis.

Methylation of ribosomal proteins in bacteria: evidence of conserved modification of the eubacterial 50S subunit

Methylation of the 50S ribosomal proteins from Bacillus stearothermophilus, Bacillus subtilis, Alteromonas espejiana, and Halobacterium cutirubrum was measured after the cells were grown in the presence of [1-14C]methionine or [methyl-3H]methionine or both. Two-dimensional polyacrylamide gel electrophoretic analysis revealed, in general, similar relative electrophoretic mobilities of the methylated proteins from each eubacterium studied. Proteins known to be structurally and functionally homologous in several microorganisms were all methylated. Thus, the following group of proteins, which appear to be involved in peptidyltransferase or in polyphenylalanine-synthesizing activity in B. stearothermophilus (P.E. Auron and S. R. Fahnestock, J. Biol. Chem. 256:10105-10110, 1981), were methylated (possible Escherichia coli methylated homologs are indicated in parentheses): BTL5(EL5), BTL6(EL3), BTL8(EL10), BTL11(EL11), BTL13(EL7L12) and BTL20b(EL16). In addition, the pentameric ribosomal complex BTL13 X BTL8, analogous to the complex EL7L12 X EL10 of E. coli, contained methylated proteins. Analysis of the methylated amino acids in the most heavily methylated proteins, BSL11 from B. subtilis and BTL11 from B. stearothermophilus, showed the presence of epsilon-N-trimethyllysine as the major methylated amino acid in both proteins, in agreement with known data for E. coli. In addition, BSL11 appeared to contain trimethylalanine, a characteristic, modified amino acid previously described only in EL11 from E. coli. These results and those previously obtained from other bacteria indicate a high degree of conservation for ribosomal protein methylation and suggest an important, albeit unknown, role for the modification of these components in eubacterial ribosomes.

Methylation of ribosomal proteins during ribosome assembly in Escherichia coli

In Escherichia coli, a number of ribosomal proteins are methylated. The time of methylation of L7 and L11 during ribosome assembly was studied. It was observed that the methylation of L7 could occur in the free protein stage. Both the 32S and 40S ribonucleoprotein intermediates also contained methylated L7 although the extent of methylation in these particles was not as high as in the free L7, the 45S or the 50S particles. Free L11 could also be partially methylated but the bulk of methylation of this protein was found in the 45S and the 50S particles. It was previously reported that the methylation of L7 is inversely proportional to the growth temperature (Chang 1978), we now show that once L7 is methylated at 25 degree, the methyl group is stable when the culture is shifted to 37 degree C. However, a partial turnover of the methyl group of L7 is observed when the methylated ribosome is chased at 25 degree C. On the other hand, the methyl groups of L11 appear to be stable at either 25 degree C or 37 degree C. We also observe that the extent of methylation of both L7 and L11 stays nearly constant during the cell growth cycle from early log to stationary phase.