Identification of epsilon-N-mono-, epsilon-N-di-, and epsilon-N-trimethyllysine by high-performance liquid chromatography.

Dansyl derivatives of epsilon-N-mono-, epsilon-N-di-, and epsilon-N-trimethyllysine were resolved from other amino acids in proteins by the use of high-performance liquid chromatography. The system was tested with amino acid standard combinations as well as with acid-hydrolyzed proteins known to contain methylated residues. In all cases the methylated lysines were well resolved.     

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.     

Fast-Transported Glycoproteins and Nonglycosylated Proteins Contain Sulfate

35SO4-labeled fast-transported proteins of bullfrog dorsal root ganglion neurons were separated by two-dimensional gel electrophoresis, and their mobilities were compared to similar species labeled with [3H]mannose or [3H]fucose. Fluorography revealed regions of poorly resolved, high molecular weight material, likely to represent sulfated proteoglycans, as well as many well resolved spots that corresponded in mobility to individual [35S]methionine-labeled fast-transported proteins. The majority of these well resolved spots appeared as "families," previously identified as glycoproteins based on their labeling with sugars. Thus, sulfate can be a contributor to the carbohydrate side-chain charge that underlies microheterogeneity. The most heavily 35SO4-labeled species, however, corresponded to fast-transported proteins that were not labeled by either sugar. The relative acid labilities of 35SO4 associated with individual species cut from the gel confirmed the assignments of these spots as glycoproteins or nonglycoproteins. A group of spots intermediate in their acid lability was also detected, suggesting that some proteins may contain sulfate linked to carbohydrate as well as to amino acid residues.     

Tissue-specific biosynthesis of epsilon-N-monomethyllysine and epsilon-N-trimethyllysine in skeletal and cardiac muscle myosin: a model for the cell-free study of post-translational amino acid modifications in proteins.

As a continuation of the study on post-ribosomal amino acid modifications in myosin, the regulation of tissue-specific biosynthesis of ϵ-N-monomethyllysine and ϵ-N-trimethyllysine was investigated. While ϵ-N-trimethyllysine is a component of both skeletal and cardiac muscle myosins, in certain species the monomethylated amino acids occur only in myosin from skeletal muscle. The methylation of skeletal and cardiac muscle myosin with cardiac or skeletal muscle enzymes was expected to elucidate whether the tissue-specific occurrence of the ϵ-N-monomethyllysine is related to the structure of skeletal and cardiac myosin or to the existence of the methylating enzyme in the skeletal and cardiac muscle cells. The experimental approach is based on cell-free methylation of lysines at 24 °C, at which temperature the myosin chains remain polysome-bound. The methylated myosin was digested with trypsin and the radioactive methyl group-containing peptides were fractionated with ion-exchange chromatography. The peptide peaks with radioactivity were subjected to amino acid analyses and the radioactive methylated lysine derivatives were identified. ϵ-N-trimethyllysine was found in hydrolysates of all the methylated myosins, and ϵN-monomethyllysine was also present in both skeletal and cardiac muscle myosin if they were incubated with skeletal muscle supernatant. Thus the experimental results agree with our earlier suggestion (Huszar &; Elzinga, 1972) that the lack of a certain methylated amino acid in cardiac muscle myosin is due to the absence of the methylating enzyme rather than to differences in the structure of cardiac versus skeletal myosin. The experimental design developed for this work should be useful to study post-translational modifications in proteins, as well as to investigate muscle and other diseases in which the post-translational processing of proteins contributes to the dys function.     

Enzymatic methylation of carboxyl groups of chromaffin granule membrane proteins.

Carboxyl groups of membrane and soluble proteins from bovine adrenal medulla chromaffin granules were enzymatically methylated. The methylated peptides were resolved using gel electrophoresis under acidic conditions in the presence of N-cetylpyridinium chloride. There was a selective methylation of two groups of membrane peptides which did not correspond to any of the chromaffin granule soluble proteins. Dopamine beta-hydroxylase, an acidic protein accounting for up to 25% of the membrane proteins, was a poor substrate for protein carboxylmethylase. The methyl esters of membrane proteins were more labile than those of the chromaffin granule soluble proteins. At all pH values tested, membrane protein-methyl esters were hydrolyzed three times more rapidly than the soluble protein-methyl esters.     

Systematic Proteomic Analysis of Protein Methylation in Prokaryotes and Eukaryotes Revealed Distinct Substrate Specificity

The studies of protein methylation mainly focus on lysine and arginine residues due to their diverse roles in essential cellular processes from gene expression to signal transduction. Nevertheless, atypical protein methylation occurring on amino acid residues, such as glutamine and glutamic acid, is largely neglected until recently. In addition, the systematic analysis for the distribution of methylation on different amino acids in various species is still lacking, which hinders our understanding of its functional roles. In this study, we deeply explored the methylated sites in three species Escherichia coli, Saccharomyces cerevisiae, and HeLa cells by employing MS‐based proteomic approach coupled with heavy methyl SILAC method. We identify a total of 234 methylated sites on 187 proteins with high localization confidence, including 94 unreported methylated sites on nine different amino acid residues. KEGG and gene ontology analysis show the pathways enriched with methylated proteins are mainly involved in central metabolism for E. coli and S. cerevisiae, but related to spliceosome for HeLa cells. The analysis of methylation preference on different amino acids is conducted in three species. Protein N‐terminal methylation is dominant in E. coli while methylated lysines and arginines are widely identified in S. cerevisiae and HeLa cells, respectively. To study whether some atypical protein methylation has biological relevance in the pathological process in mammalian cells, we focus on histone methylation in diet‐induced obese (DIO) mouse. Two glutamate methylation sites showed statistical significance in DIO mice compared with chow‐fed mice, suggesting their potential roles in diabetes and obesity. Together, these findings expanded the methylome database from microbes to mammals, which will benefit our further appreciation for the protein methylation as well as its possible functions on disease.     

A simple quantitative method for the determination of 3-fluorotyrosine substitution in proteins

A rapid quantitative method is described for determining 3-fluorotyrosine incorporation into proteins. Derivatives of tyrosine and 3-fluorotyrosine with o-phthalaldehyde are well separated from one another by a reverse-phase high-performance liquid chromatography system used for routine analyses of o-phthalaldehyde-amino acid derivatives. Since both amino acids are well resolved from all other derivatized amino acids, the method is useful for amino acid analyses of proteins. Determination of the fluorotyrosine content of proteins by this method involves a single separation step, is reproducible, and requires no corrections for stability or yield. Further, the o-phthalaldehyde derivatives of 5-fluorotryptophan, 2-fluorophenylalanine, 3-fluorophenylalanine, and 4-fluorophenylalanine can also be resolved. The method may be generally applicable to fluorinated aromatic amino acid-labeled proteins that are studied structurally and dynamically by nuclear magnetic resonance.     

Protein N-arginine methylation in subcellular fractions of lymphoblastoid cells

Arginine methylation in RNA-binding proteins containing arginine- and glycine-rich RGG motifs is catalyzed by specific protein arginine N-methyltransferase in cells. We previously showed that lymphoblastoid cells grown in the presence of an indirect methyltransferase inhibitor, adenosine dialdehyde (AdOx), accumulated high level of hypomethylated protein substrates for the endogenous protein methyltransferases or recombinant yeast arginine methyltransferase [Li, C. et al. (1998) Arch. Biochem. Biophys. 351, 53-59]. In this study we fractionated the lymphoblastoid cells to locate the methyltransferases and the substrates in cells. Different sets of hypomethylated methyl-accepting polypeptides with wide range of molecular masses were present in cytosolic, ribosomal, and nucleus fractions. The methylated amino acid residues of the methyl-accepting proteins in these fractions were determined. In all three fractions, dimethylarginine was the most abundant methylated amino acid. The protein-arginine methyltransferase activities in the three fractions were analyzed using recombinant fibrillarin (a nucleolar RGG protein) as the methyl-accepting substrate. Fibrillarin methylation was strongest in the presence of the cytosolic fraction, followed by the ribosomal and then the nucleus fractions. The results demonstrated that protein-arginine methyltransferases as well as their methyl-accepting substrates were widely distributed in different subcellular fractions of lymphoblastoid cells.     

N-terminal methylation of proteins: structure, function and specificity

A common site for the posttranslational modification of proteins is at the N-terminal alpha-amino group. Here we consider the enzymatic addition of one or more methyl groups that has been found to occur in several proteins. Although the methylated proteins have different overall functions, they all appear to be involved in large macromolecular structures such as ribosomes, myofibrils, nucleosomes, pilins, or flagella. Structural features at the N-termini of these methylated proteins suggest that sequences in this region may serve as recognition sites for only a few different types of methylating enzymes. Thus, we propose that three enzymes could account for the N-methylated species so far identified in bacteria, the hypothetical MAK, QP, and pilin methyltransferases, and a single additional enzyme, the hypothetical PK methyltransferase, could account for all of the alpha-amino methylations observed in eukaryotic cells. Finally, we discuss criteria that could be used in conjunction with primary sequence data to predict proteins that might be subject to methylation at their amino termini.     

Evaluation of colorimetric assays for analyzing reductively methylated proteins: Biases and mechanistic insights

Colorimetric protein assays, such as the Coomassie blue G-250 dye-binding (Bradford) and bicinchoninic acid (BCA) assays, are commonly used to quantify protein concentration. The accuracy of these assays depends on the amino acid composition. Because of the extensive use of reductive methylation in the study of proteins and the importance of biological methylation, it is necessary to evaluate the impact of lysyl methylation on the Bradford and BCA assays. Unmodified and reductively methylated proteins were analyzed using the absorbance at 280 nm to standardize the concentrations. Using model compounds, we demonstrate that the dimethylation of lysyl ε-amines does not affect the proteins' molar extinction coefficients at 280 nm. For the Bradford assay, the responses (absorbance per unit concentration) of the unmodified and reductively methylated proteins were similar, with a slight decrease in the response upon methylation. For the BCA assay, the responses of the reductively methylated proteins were consistently higher, overestimating the concentrations of the methylated proteins. The enhanced color formation in the BCA assay may be due to the lower acid dissociation constants of the lysyl ε-dimethylamines compared with the unmodified ε-amine, favoring Cu(II) binding in biuret-like complexes. The implications for the analysis of biologically methylated samples are discussed.     

Genetics of ribosomal protein methylation in Escherichia coli. II. A mutant lacking a new type of methylated amino acid, N5-methylglutamine, in protein L3.

The ribosomes of an Escherichia coli mutant, designated prm-2, can be methylated in vitro by an enzymatic fraction from wild-type. This enzyme is inactive on the ribosomes from another mutant, prm-1, is reported previously to be methyl group-deficient in protein L11. In vitro methylation of prm-2 ribosomes resulted in the incorporation of about one methyl group per molecule of protein L3. After acid hydrolysis, all the methyl groups were found in a very basic compound which was identified as methylamine. This compound could have been generated by acid hydrolysis of N-methylated amide-groups from glutamine or asparagine. Therefore, chemically-synthesized N4-methyl-asparagine and N5-methylglutamine were chromatographed together with an enzymatic hydrolysate of methylated prm-2 proteins. In all the chromatogrphic systems studied the methylated amino acid was found in the same position as N5'-methylglutamine. These results indicate that mutant prm-2 lacks one residue of N5-methylglutamine present in ribosomal protein L3 of wild type E. coli.     

The resolution of membrane proteins based upon size,charge, and hydrophobicity

Currently available systems for resolving membrane proteins are based only on size and charge differences. Recently, it has been shown that Triton-urea-acetic acid gels which separate proteins on the basis of charge, size and hydrophobicity are capable of resolving proteins differing only by the substitution of a single neutral amino acid. We have applied this new method to the resolution of bacterial envelope proteins. Conditions for optimal resolution of different bacterial envelope proteins were determined by electrophoresis through transverse urea and Triton X-100 gradient gels. We have also correlated the components resolved in this system with those resolved by classical sodium dodecyl sulfate-gel electrophoresis by using two-dimensional slab gels combining the two systems. Furthermore, envelope protein fractions from different species and strains of bacteria were compared to identify specific proteins. This system appears to be a promising method for investigating envelope proteins which are due to missense mutations.     

Cationic proteins of polymorphonuclear leukocyte lysosomes. II. Composition, properties, and mechanism of antibacterial action

Zeya, H. I. (University of North Carolina, Chapel Hill), and J. K. Spitznagel. Cationic proteins of polymorphonuclear leukocyte lysosomes. II. Composition, properties, and mechanism of antibacterial action. J. Bacteriol. 91:755-762. 1966.-A basic proteins fraction from guinea pig polymorphonuclear (PMN) granules was obtained by acid extraction and precipitation with 20% (v/v) ethyl alcohol. The fraction accounted for most of the antibacterial activity of the PMN granules and corresponded to the antibacterial cationic components of intact granules (bands I, II, and III) resolved by zone electrophoresis. Absence from the fraction of components identical to the enzymatic components of intact lysosomes showed that the fraction was essentially free from lysosomal enzymes. The amino acid analysis of proteins in the fraction gave a preponderance of basic amino acids (25%), especially of arginine (16%). The comparative amino acid analysis showed that the lysosomal cationic proteins (LCP) fraction was markedly different from nuclear histones. The LCP fraction manifested antibacterial activity against certain gram-positive and gram-positive microorganisms, including Candida albicans, and exhibited stoichiometric relationship in its activity. Microorganisms treated with LCP fraction were agglutinated. Anionic substances such as nucleic acids, heparin, and endotoxin effectively blocked the antibacterial activity of the fraction. The LCP fraction caused suppression of oxygen uptake by bacterial cells and damaged the permeability barriers of cells as manifested by rapid release of P(32) as well as ultraviolet-absorbing material at 260 mmu, in the supernatant fluid.     

Bioinformatics and functional analysis define four distinct groups of AlkB DNA-dioxygenases in bacteria

The iron(II)- and 2-oxoglutarate (2OG)-dependent dioxygenase AlkB from Escherichia coli (EcAlkB) repairs alkylation damage in DNA by direct reversal. EcAlkB substrates include methylated bases, such as 1-methyladenine (m¹A) and 3-methylcytosine (m³C), as well as certain bulkier lesions, for example the exocyclic adduct 1,N⁶-ethenoadenine (εA). EcAlkB is the only bacterial AlkB protein characterized to date, and we here present an extensive bioinformatics and functional analysis of bacterial AlkB proteins. Based on sequence phylogeny, we show that these proteins can be subdivided into four groups: denoted 1A, 1B, 2A and 2B; each characterized by the presence of specific conserved amino acid residues in the putative nucleotide-recognizing domain. A scattered distribution of AlkB proteins from the four different groups across the bacterial kingdom indicates a substantial degree of horizontal transfer of AlkB genes. DNA repair activity was associated with all tested recombinant AlkB proteins. Notably, both a group 2B protein from Xanthomonas campestris and a group 2A protein from Rhizobium etli repaired etheno adducts, but had negligible activity on methylated bases. Our data indicate that the majority, if not all, of the bacterial AlkB proteins are DNA repair enzymes, and that some of these proteins do not primarily target methylated bases.     

EFFECT OF ACETYLATION AND METHYLATION ON THE SWEETNESS INTENSITY OF THAUMATIN I

The lysine residues in thaumatin I were chemically modifiedby acetylation with acetic anhydride and by reductive methylation,under various conditions. The acetylated and methylated thaumatinswere isolated by ion-exchange chromatography. The number ofremaining free amino groups was determined by trinitrophenylation. At least four acetylated thaumatins with either one, two, threeor four acetylated amino groups were obtained as well as onemethylated thaumatin with six dimethyl lysine residues and onemonomethyl lysine residue. The sweetness intensity of the acetylated thaumatins decreasedwith the increasing number of acetylated amino groups; the sweettaste had disappeared completely when four amino groups wereacetylated. The methylated thaumatin with seven modified lysineresidues had a sweetness intensity practically equal to thatof the original thaumatin. The total net change, i.e. the isoelectric point of thaumatin,might play a role in the physiological behaviour of thaumatincausing a sweet taste sensation.     

Relationship among methylation,isoprenylation, and GTP binding in 21-to 23-kDa proteins of neuroblastoma

1. Dimethylsulfoxide-induced differentiated neuroblastoma express high levels of membrane 21 to 23-kDa carboxyl methylated proteins. Relationships among methylation, isoprenylation, and GTP binding in these proteins were investigated. Protein carboxyl methylation, protein isoprenylation, and [alpha-32P]GTP binding were determined in the electrophoretically separated proteins of cells labeled with the methylation precursor [methyl-3H]methionine or with an isoprenoid precursor [3H]mevalonate. 2. A broad band of GTP-binding proteins, which overlaps with the methylated 21 to 23-kDa proteins, was detected in [alpha-32P]GTP blot overlay assays. This band of proteins was separated in two-dimensional gels into nine methylated proteins, of which four bound GTP. 3. The carboxyl-methylated 21 to 23-kDa proteins incorporated [3H]mevalonate metabolites with characteristics of protein isoprenylation. The label was not removed by organic solvents or destroyed by hydroxylamine. Incorporation of radioactivity from [3H]mevalonate was enhanced when endogenous levels of mevalonate were reduced by lovastatin, an inhibitor of mevalonate synthesis. Lovastatin blocked methylation of the 21 to 23-kDa proteins as well (greater than 70%). 4. Methylthioadenosine, a methylation inhibitor, inhibited methylation of these proteins (greater than 80%) but did not affect their labeling by [3H]mevalonate. The results suggest that methylation of the 21 to 23-kDa proteins depends on, and is subsequent to, isoprenylation. The sequence of events may be similar to that known in ras proteins, i.e., carboxyl methylation of a C-terminal cysteine that is isoprenylated. 5. Lovastatin reduced the level of small GTP-binding proteins in the membranes and increased GTP binding in the cytosol. Methylthioadensoine blocked methylation without affecting GTP binding. 6. Thus, isoprenylation appears to precede methylation and to be important for membrane association, while methylation is not required for GTP binding or membrane association. The role of methylation remains to be determined but might be related to specific interactions of the small GTP-binding proteins with other proteins.     

Identification of a gamma-glutamyl methyl ester in bacterial membrane protein involved in chemotaxis.

Evidence is presented that a methyltransferase enzyme, previously shown to be necessary for chemotaxis and identified as the cheR gene product, catalyzes the formation of a gamma-glutamyl methyl ester in one or more membrane proteins of Salmonella typhimurium. The rates of release of methyl label from the methylated protein in acid, base, and hydroxylamine are consistent with a methyl ester and not with a methylated imidazole, guanidino, or amino group. A gamma-glutamyl methyl ester was isolated from a proteolytic digest of the modified protein.     

The adhesive protein of Choromytilus chorus (Molina, 1782) and Aulacomya ater (Molina, 1782): a proline-rich and a glycine-rich polyphenolic protein

The adhesive polyphenolic proteins from Aulacomya ater and Choromytilus chorus with apparent molecular masses of 135000 and 105000, respectively, were digested with trypsin and the peptides produced resolved by reversed phase liquid chromatography. About 5 and 12 major peptides were obtained from the protein of A. ater and C. chorus, respectively. The major peptides were purified by reverse-phase chromatography and the amino acid sequence indicates that both polyphenolic proteins consisted of repeated sequence motifs in their primary structure. The major peptides of A. ater contain seven amino acids corresponding to the consensus sequence AGYGGXK, whereas the tyrosine was always found as 3, 4-dihydroxyphenylalanine (Dopa), the X residue in position 6 was either valine, leucine or isoleucine, and the carboxy terminal was either lysine or hydroxylysine. On the other hand, the major peptides of C. chorus ranged in size from 6 to 21 amino acids and the majority correspond to the consensus sequence AKPSKYPTGYKPPVK. Both proteins differ markedly in the sequence of their tryptic peptides, but they share the common characteristics of other adhesive proteins in having a tandem sequence repeat in their primary structure.     

Characterization of methylated neutral amino acids from Escherichia coli ribosomes.

The methylated neutral amino acids from both 30S and 50S ribosomal subunits of an Escherichia coli K strain were characterized. The 50S ribosomal subunit contains three methylated neutral amino acids: N-monomethylalanine, N-monomethylmethionine, and an as yet unidentified methylated amino acid found in protein L11. Both N-monomethylalanine and N-monomethylmethionine were found in protein L33. The amount of N-monomethylmethionine in this protein, however, is variable but not more than 0.25 molecules per protein. Thus protein L33 from this E. coli K strain has heterogeneity in its N-terminal amino acid and can start with either N-monomethylalanine or N-monomethylmethionine. The N-monomethylmethionine residue was not derived from the reduction of N-formylmethionine in the protein. The 30S ribosomal subunit contains only one methylated neutral amino acid: N-monomethylalanine.     

Methylation of Ribosomal Proteins in Escherichia coli

Escherichia coli was grown in a medium containing [1-(14)C]methionine and [methyl-(3)H]methionine, and the (3)H/(14)C ratio was determined for each of the ribosomal proteins derived from the 70S ribosome. Evidence indicates that six proteins from the 50S subunit were methylated: L7, L9, L11, L12, L18, and L33. Methylation of several other 50S proteins (such as L1, L3, L5, etc.) may also occur. The methylated amino acids in protein L11 have been characterized further and found to be predominately epsilon-trimethyllysine. A small amount of a compound tentatively identified as N(G), N'(G)-dimethylarginine was also detected.