Yeast Ribosomal/Cytochrome c SET Domain Methyltransferase Subfamily

SET domain-containing methyltransferases post-translationally modify a variety of cellular proteins, such as histones, cytochrome c, ribulose-bisphosphate carboxylase/oxygenase, and ribosomal proteins. In the fission yeast Schizosaccharomyces pombe, at least 13 SET domain-containing proteins have been identified in the genome, four of which are involved in transcriptional regulation through their modification of histone tails. However, the roles played by the other SET domain proteins in cellular processes and their physiological substrates remain unresolved. We show here that S. pombe Set11, a SET domaincontaining protein encoded by SPCC1223.04c, specifically modifies Rpl12 (ribosomal protein L12). Recombinant Set11 prepared from Escherichia coli had catalytic activity and methylated a 17-kDa polypeptide in cellular extracts of set11 mutant cells. The methylated protein was isolated by two-dimensional gel electrophoresis or by reverse-phase chromatography and was identified as Rpl12 by mass spectrometry. In vitro methylation experiments using wild-type and mutant Rpl12 proteins verified that Set11 modified recombinant Rpl12 and suggested that its potential target site was lysine 3. The methylation site modified by Set11 was also confirmed by mass spectrometric analysis, which also revealed other unique methylation sites of Rpl12. Finally, we found that Set11 predominantly localized to the nucleolus and that the overproduction of Set11 caused a severe growth defect. These results suggest that Rpl12 methylation occurs during the ribosomal assembly processes and that control of the Set11 expression level is important for its cellular function.

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

A Conserved SET Domain Methyltransferase, Set11, Modifies Ribosomal Protein Rpl12 in Fission Yeast

Sadaie

Shinmyozu²,

Nakayama

2008

“…Interestingly, the majority of the yeast point mutations displaying phenotypes 3 H-methylated large ribosomal subunits were isolated from [ 3 H]AdoMetlabeled intact BY4742 wild-type cells and reverse-phase HPLC was used to isolate a fraction containing a mixture of Rpl3 and Rpl23ab as described in "Experimental Procedures." The latter protein is a known coeluting species known to contain two dimethyllysine residues (17). This mixture was acid hydrolyzed and 1 mol each of ⑀-dimethyllysine and 3-methyl-L-histidine (-methyl-L-histidine, Vega Biochemicals 12608) standards were added.…”

Section: ϫ13mentioning

confidence: 99%

“…We have used mass spectrometry to screen for loss of methylation in the intact ribosomal proteins of yeast strains lacking a single known or putative methyltransferase. Using this approach, SET-domain methyltransferases responsible for modifying Rpl12ab, Rpl23ab, Rpl42ab, and eEF1a at specific lysine residues have been identified (13)(14)(15)(16)(17). In addition to screening the SET-domain methyltransferase gene knock-out strains, we also screened the seven ␤-strand methyltransferase gene family for loss of methylation in gene deletions.…”

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confidence: 99%

A Novel 3-Methylhistidine Modification of Yeast Ribosomal Protein Rpl3 Is Dependent upon the YIL110W Methyltransferase

Webb

Zurita-Lopez

Al-Hadid

et al. 2010

Self Cite

114

We have shown that Rpl3, a protein of the large ribosomal subunit from baker's yeast (Saccharomyces cerevisiae), is stoichiometrically monomethylated at position 243, producing a 3-methylhistidine residue. This conclusion is supported by topdown and bottom-up mass spectrometry of Rpl3, as well as by biochemical analysis of Rpl3 radiolabeled in vivo with S-adenosyl-L-[methyl-3 H]methionine. The results show that a ؉14-Da modification occurs within the GTKKLPRKTHRGLRKVAC sequence of Rpl3. Using high-resolution cation-exchange chromatography and thin layer chromatography, we demonstrate that neither lysine nor arginine residues are methylated and that a 3-methylhistidine residue is present. Analysis of 37 deletion strains of known and putative methyltransferases revealed that only the deletion of the YIL110W gene, encoding a seven ␤-strand methyltransferase, results in the loss of the ؉14-Da modification of Rpl3. We suggest that YIL110W encodes a protein histidine methyltransferase responsible for the modification of Rpl3 and potentially other yeast proteins, and now designate it Hpm1 (Histidine protein methyltransferase 1). Deletion of the YIL110W/HPM1 gene results in numerous phenotypes including some that may result from abnormal interactions between Rpl3 and the 25 S ribosomal RNA. This is the first report of a methylated histidine residue in yeast cells, and the first example of a gene required for protein histidine methylation in nature.The addition of methyl groups to proteins from the methyl donor S-adenosylmethionine is one of the most common posttranslational modifications, resulting in an expansion of the physico-chemical characteristics of amino acids and the potential to modulate protein function (1). Major sites of protein methylation are at lysine and arginine residues (2, 3), and less major sites include glutamate, glutamine, and histidine residues, as well as N-terminal amino and C-terminal carboxyl groups (4 -6). The extensive role of histone methylation in transcriptional control highlights the biological significance of this modification (7-10). Protein methylation is also important in the translational machinery. Indeed, many proteins involved in translation, including ribosomal proteins and various elongation and release factors, are subject to methylation in both prokaryotes and eukaryotes (11).Saccharomyces cerevisiae is an ideal organism to investigate the methylation of ribosomal proteins; its genome is well annotated and single open reading frame gene deletion mutants are available. High-resolution intact mass spectrometry suggested that six proteins of the large ribosomal subunit may be methylated: Rpl1ab, Rpl3, Rpl12ab, Rpl23ab, Rpl42ab, and Rpl43ab (12).2 This study, however, did not identify the sites of methylation in these proteins nor did it identify the corresponding methyltransferases. In our laboratory, we have been interested in characterizing these modifications and identifying the methyltransferases involved in an effort to understand their physiological significance in trans...

“…Rpl3 is modified to form a 3-methylhistidine residue at position 243 (13), whereas Rpl12ab is modified at three positions: a dimethylproline residue is present at the N terminus (14), an ⑀-trimethyllysine residue is found at position 3 (9,19), and an unusual ␦-monomethylarginine residue is found at position 66 (2). Rpl23ab is modified by ⑀-dimethyllysine formation at positions 105 and 109 (7), and Rpl42ab is modified by ⑀-monomethyllysine formation at positions 39 and 55 (9). The proposed methylation at Rpl43ab has not been observed to date in our studies.…”

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confidence: 99%

The Ribosomal L1 Protuberance in Yeast Is Methylated on a Lysine Residue Catalyzed by a Seven-β-strand Methyltransferase

Webb¹,

Al-Hadid²,

Zurita-Lopez

et al. 2011

Modification of proteins of the translational apparatus is common in many organisms. In the yeast Saccharomyces cerevisiae, we provide evidence for the methylation of Rpl1ab, a well conserved protein forming the ribosomal L1 protuberance of the large subunit that functions in the release of tRNA from the exit site. We show that the intact mass of Rpl1ab is 14 Da larger than its calculated mass with the previously described loss of the initiator methionine residue and N-terminal acetylation. We determined that the increase in mass of yeast Rpl1ab is consistent with the addition of a methyl group to lysine 46 using topdown mass spectrometry. Lysine modification was confirmed by detecting 3 H-N-⑀-monomethyllysine in hydrolysates of Rpl1ab purified from yeast cells radiolabeled in vivo with S-adenosyl-L-[methyl-3 H]methionine. Mass spectrometric analysis of intact Rpl1ab purified from 37 deletion strains of known and putative yeast methyltransferases revealed that only the deletion of the YLR137W gene, encoding a seven-␤-strand methyltransferase, results in the loss of the ؉14-Da modification. We expressed the YLR137W gene as a His-tagged protein in Escherichia coli and showed that it catalyzes N-⑀-monomethyllysine formation within Rpl1ab on ribosomes from the ⌬YLR137W mutant strain lacking the methyltransferase activity but not from wild-type ribosomes. We also showed that the His-tagged protein could catalyze monomethyllysine formation on a 16-residue peptide corresponding to residues 38 -53 of Rpl1ab. We propose that the YLR137W gene be given the standard name RKM5 (ribosomal lysine (K) methyltransferase 5). Orthologs of RKM5 are found only in fungal species, suggesting a role unique to their survival.Proteins of the eukaryotic translational apparatus are often targets for post-translational covalent modifications (1). One of the major types of these reactions is the transfer of methyl groups from S-adenosylmethionine to a variety of residues including arginine (2-5), lysine (6 -11), glutamine (12), histidine (13), and N-terminal (14, 15) residues. Ribosomal proteins (1-5, 7-11, 13, 14, 16), elongation factor 1A (1, 6, 17), and translational release factors (12) are common substrates of protein methyltransferases. These modifications are known to enhance resistance to ribosome-targeting antibiotics, facilitate ribosomal protein transport into and out of the nucleus, allow efficient ribosomal assembly, and increase translational accuracy (1, 5).We have been interested in understanding the role of protein methylation in ribosomal function and assembly in Saccharomyces cerevisiae using a proteomics-guided approach. Previous efforts have identified modifications within proteins of the large ribosomal subunit. Interestingly, mass spectrometric analysis suggested that six proteins, Rpl1ab, Rpl3, Rpl12ab, Rpl23ab, Rpl42ab, and Rpl43ab, 3 were subject to methylation (18). Further analysis has localized the methylation sites on four of these proteins. Rpl3 is modified to form a 3-methylhistidine residue at position 243 (1...