Site specificity of histone H4 methylation by wheat germ protein-arginine N-methyltransferase

CNBr treatment of calf thymus [methyl-14C]histone H4, methylated in vitro with S-adenosyl-L-[methyl-14C]methionine by a highly histone-specific wheat germ protein methylase I (S-adenosyl-L-methionine:protein-L-arginine N-methyltransferase, EC 2.1.1.23), produced two peptide fragments corresponding to residues 1-83 and 84-102, with the former being radioactive. Two-dimensional peptide mapping of the chymotryptic and tryptic digest of [methyl-14C]histone H4 and analysis of the chymotryptic digest on HPLC have shown that only a single peptide is radiolabeled. In order to define the exact site of methylation (arginine residue), the radioactive peptide from the chymotryptic digest of [methyl-14C]histone H4 was further purified on HPLC by linear and then isocratic elution. The purified chymotryptic peptide was then digested with trypsin and purified on HPLC, and its amino acid composition was determined on HPLC. These results indicate that the peptide corresponding to residues 24-35 of histone H4 is radiolabeled. Since this peptide contains a single arginine residue at position 35, we have concluded that the enzyme is specific not only to the protein substrate but also to the methylation site.     

The DNA methyltransferases associate with HP1 and the SUV39H1 histone methyltransferase

The DNA methyltransferases, Dnmts, are the enzymes responsible for methylating DNA in mammals, which leads to gene silencing. Repression by DNA methylation is mediated partly by recruitment of the methyl-CpG-binding protein MeCP2. Recently, MeCP2 was shown to associate and facilitate histone methylation at Lys9 of H3, which is a key epigenetic modification involved in gene silencing. Here, we show that endogenous Dnmt3a associates primarily with histone H3-K9 methyltransferase activity as well as, to a lesser extent, with H3-K4 enzymatic activity. The association with enzymatic activity is mediated by the conserved PHD-like motif of Dnmt3a. The H3-K9 histone methyltransferase that binds Dnmt3a is likely the H3-K9 specific SUV39H1 enzyme since we find that it interacts both in vitro and in vivo with Dnmt3a, using its PHD-like motif. We find that SUV39H1 also binds to Dnmt1 and, consistent with these interactions, SUV39H1 can purify DNA methyltransferase activity from nuclear extracts. In addition, we show that HP1β, a SUV39H1-interacting partner, binds directly to Dnmt1 and Dnmt3a and that native HP1β associates with DNA methyltransferase activity. Our data show a direct connection between the enzymes responsible for DNA methylation and histone methylation. These results further substantiate the notion of a self-reinforcing repressive chromatin state through the interplay between these two global epigenetic modifications.     

CpG-binding protein (CXXC finger protein 1) is a component of the mammalian Set1 histone H3-Lys4 methyltransferase complex, the analogue of the yeast Set1/COMPASS complex

CpG-binding protein (CXXC finger protein 1 (CFP1)) binds to DNA containing unmethylated CpG motifs and is required for mammalian embryogenesis, normal cytosine methylation, and cellular differentiation. Studies were performed to identify proteins that interact with CFP1 to gain insight into the molecular function of this protein. Immunoprecipitation and mass spectrometry reveal that human CFP1 associates with a approximately 450-kDa complex that contains the mammalian homologues of six of the seven components of the Set1/COMPASS complex, the sole histone H3-Lys4 methyltransferase in yeast. In vitro assays demonstrate that the human Set1/CFP1 complex is a histone methyltransferase that produces mono-, di-, and trimethylated histone H3 at Lys4. Confocal microscopy reveals that CFP1 and Set1 co-localize to nuclear speckles associated with euchromatin. A Set1 complex of reduced mass persists in murine embryonic stem cells lacking CFP1. These cells carry elevated levels of methylated histone H3-Lys4 and reduced levels of methylated histone H3-Lys9. Together with the previous finding of reduced levels of cytosine methylation, these data indicate that cells lacking CFP1 contain reduced levels of heterochromatin. Furthermore, ES cells lacking CFP1 exhibit a 4-fold excess of histone H3-Lys4 methylation following induction of differentiation, indicating that CFP1 restricts the activity of the Set1 histone methyltransferase complex. These results reveal a mammalian counterpart to the yeast Set1/COMPASS complex. The presence of CFP1 in this complex implicates this protein as a critical epigenetic regulator of histone modification in addition to cytosine methylation and reveals one mechanism by which this protein intersects with the epigenetic machinery.     

Dual histone H3 methylation marks at lysines 9 and 27 required for interaction with CHROMOMETHYLASE3

Both DNA methylation and post-translational histone modifications contribute to gene silencing, but the mechanistic relationship between these epigenetic marks is unclear. Mutations in two Arabidopsis genes, the KRYPTONITE (KYP) histone H3 lysine 9 (H3K9) methyltransferase and the CHROMOMETHYLASE3 (CMT3) DNA methyltransferase, cause a reduction of CNG DNA methylation, suggesting that H3K9 methylation controls CNG DNA methylation. Here we show that the chromodomain of CMT3 can directly interact with the N-terminal tail of histone H3, but only when it is simultaneously methylated at both the H3K9 and H3K27 positions. Furthermore, using chromatin immunoprecipitation analysis and immunohistolocalization experiments, we found that H3K27 methylation colocalizes with H3K9 methylation at CMT3-controlled loci. The H3K27 methylation present at heterochromatin was not affected by mutations in KYP or in several Arabidopsis PcG related genes including the Enhancer of Zeste homologs, suggesting that a novel pathway controls heterochromatic H3K27 methylation. Our results suggest a model in which H3K9 methylation by KYP, and H3K27 methylation by an unknown enzyme provide a combinatorial histone code for the recruitment of CMT3 to silent loci.     

Isoprenylation and carboxylmethylation in small GTP-binding proteins of pheochromocytoma (PC-12) cells

1. A group of 21 to 24-kDa proteins of pheochromocytoma (PC-12) cells was found in blot overlay assays to bind specifically [alpha-32P]GTP. Binding was inhibited by GTP analogues but not by ATP. Such small GTP-binding proteins were found in the cytosolic and in the particulate fraction of the cells, but they were unevenly distributed: about 75% of the small GTP-binding proteins were localized within the particulate fraction of the cells. Separation of these proteins by two-dimensional gel electrophoresis revealed the existence of seven distinct [alpha-32P]GTP-binding proteins. 2. Targeting of the small GTP-binding proteins to the particulate fraction of PC-12 cells requires modification by isoprenoids, since depleting the cells of the isoprenoid precursor mevalonic acid (MVA) by the use of lovastatin resulted in a 50% decrease in membrane-bound small GTP-binding proteins, with a proportionate increase in the cytosolic form. This blocking effect of lovastatin was reversed by exogenously added MVA. 3. In addition, metabolic labeling of PC-12 cells with [3H]MVA revealed incorporation of [3H]MVA metabolites into the cluster of 21 to 24-kDa proteins in a form typical of isoprenoids; the label was not removed from the proteins by hydroxylamine, and labeling was enhanced in cells incubated with lovastatin. The latter effect reflects a decrease in the isotopic dilution of the exogenously added [3H]MVA, as the addition of exogenous MVA reversed the effect of lovastatin on [3H]MVA-metabolite incorporation into the 21 to 24-kDa proteins. 4. Additional experiments demonstrated that isoprenylation is required not only for membrane association of small GTP-binding proteins, but also for their further modification by a methylation enzyme. This was evident in experiments in which the cells were metabolically labeled with [methyl-3H]methionine, a methylation precursor. The group of 21 to 24-kDa proteins was labeled with a methyl-3H group in a form typical of C-terminal-cysteinyl carboxylmethyl esters. Their methylation was blocked by the methylation inhibitors methylthioadenosine (MTA), 3-deazadenosine and homocysteine thiolactone as well as by lovastatin. MVA reversed the lovastatin block of methylation. 5. Two-dimensional gel analysis of the [3H]methylated proteins detected seven methylated small GTP-binding proteins that correspond to the isoprenylated proteins. Levels of the small GTP-binding proteins as well as isoprenylation and methylation were reduced by cycloheximide. 6. Distribution of the methylated proteins between particulate and cytosolic fractions was found to be similar to that of the small GTP-binding proteins (i.e., a 4:1 ratio).(ABSTRACT TRUNCATED AT 400 WORDS)     

Yeast Hsl7 (histone synthetic lethal 7) catalyses the in vitro formation of omega-N(G)-monomethylarginine in calf thymus histone H2A

The HSL7 (histone synthetic lethal 7) gene in the yeast Saccharomyces cerevisiae encodes a protein with close sequence similarity to the mammalian PRMT5 protein, a member of the class of protein arginine methyltransferases that catalyses the formation of omega-N(G)-monomethylarginine and symmetric omega-N(G),N'(G)-dimethylarginine residues in a number of methyl-accepting species. A full-length HSL7 construct was expressed as a FLAG-tagged protein in Saccharomyces cerevisiae. We found that FLAG-tagged Hsl7 effectively catalyses the transfer of methyl groups from S-adenosyl-[methyl-3H]-L-methionine to calf thymus histone H2A. When the acid-hydrolysed radiolabelled protein products were separated by high-resolution cation-exchange chromatography, we were able to detect one tritiated species that co-migrated with an omega-N(G)-monomethylarginine standard. No radioactivity was observed that co-migrated with either the asymmetric or symmetric dimethylated derivatives. In control experiments, no methylation of histone H2A was found with two mutant constructs of Hsl7. Surprisingly, FLAG-Hsl7 does not appear to effectively catalyse the in vitro methylation of a GST (glutathione S-transferase)-GAR [glycine- and arginine-rich human fibrillarin-(1-148) peptide] fusion protein or bovine brain myelin basic protein, both good methyl-accepting substrates for the human homologue PRMT5. Additionally, FLAG-Hsl7 demonstrates no activity on purified calf thymus histones H1, H2B, H3 or H4. GST-Rmt1, the GST-fusion protein of the major yeast protein arginine methyltransferase, was also found to methylate calf thymus histone H2A. Although we detected Rmt1-dependent arginine methylation in vivo in purified yeast histones H2A, H2B, H3 and H4, we found no evidence for Hsl7-dependent methylation of endogenous yeast histones. The physiological substrates of the Hsl7 enzyme remain to be identified.     

Specificity of rat hepatic phosphatidylethanolamine N-methyltransferase for molecular species of diacyl phosphatidylethanolamine

The specificity of phosphatidylethanolamine (PE) N-methyltransferase for molecular species of PE has been investigated. Phosphatidylcholine (PC), synthesized by incubation of [methyl-3H]S-adenosyl-L-methionine with microsomes or pure enzyme (Ridgway, N. D., and Vance, D. E. (1987) J. Biol. Chem. 262, 17231-17239) plus microsomal PE, had a distribution of methyl label in molecular species similar to the mole percent distribution of molecular species in the precursor PE. A similar lack of specificity was observed with PE that was synthesized from egg PC by transphosphatidylation with phospholipase D. Phosphatidyl-N-monomethylethanolamine (PMME) and phosphatidyl-N,N-dimethylethanolamine (PDME), both with the acyl composition of egg PC, were methylated by the pure enzyme and showed a distribution of labeled molecular species in PDME and PC, respectively, similar to the mole percent distribution of egg PC. Results with synthetic PEs and pure methyltransferase showed higher rates of methylation with more unsaturated species. Long chain saturated PEs (e.g. dipalmitoyl-PE) were not methylated by the enzyme. Maximal methylation rates were obtained with two or more double bonds in the substrate PE. Rates of methylation of the saturated and monoenoic PEs could be enhanced when 40 mol % polyunsaturated-rich microsomal PC was included in the mixed micelles. PC isolated from primary cultures of rat hepatocytes pulsed with [methyl-3H]methionine was analyzed by high performance liquid chromatography. Initially, the labeling pattern of PC molecular species varied slightly from that of total hepatocyte PE and hepatocyte microsomal PE. 1-Palmitoyl-2-docosahexaenoyl-PC had the highest specific activity at the end of the pulse and was preferentially labeled relative to the mole percent distribution of hepatocyte PE molecular species. During the 24-h chase period both the percent distribution of label and specific activity of this species of PC declined. In the same time period, there was a corresponding increase in specific activity and percent distribution of label in 1-palmitoyl and 1-stearoyl species with linoleate and arachidonate in the sn-2 position.     

S-adenosylmethionine-dependent protein methylation in mammalian cytosol via tyrphostin modification by catechol-O-methyltransferase

It has previously been shown that incubation of mammalian cell cytosolic extracts with the protein kinase inhibitor tyrphostin A25 results in enhanced transfer of methyl groups from S-adenosyl-[methyl-3H]methionine to proteins. These findings were interpreted as demonstrating tyrphostin stimulation of a novel type of protein carboxyl methyltransferase. We find here, however, that tyrphostin A25 addition to mouse heart cytosol incubated with S-adenosyl-[methyl-3H]methionine or S-adenosyl-[methyl-14C]methionine stimulates the labeling of small molecules in addition to proteins. Base treatment of both protein and small molecule fractions releases volatile radioactivity, suggesting labile ester-like linkages of the labeled methyl group. Production of both the base-volatile product and labeled protein occurs with tyrphostins A25, A47, and A51, but not with thirteen other tyrphostin family members. These active tyrphostins all contain a catechol moiety and are good substrates for recombinant and endogenous catechol-O-methyltransferase. Inhibition of catechol-O-methyltransferase activity with tyrphostin AG1288 prevents both base-volatile product formation and protein labeling from methyl-labeled S-adenosylmethionine in heart, kidney, and liver, but not in testes or brain extracts. These results suggest that the incorporation of methyl groups into protein follows a complex pathway initiated by the methylation of select tyrphostins by endogenous catechol-O-methyltransferase. We suggest that the methylated tyrphostins are further modified in the cell extract and covalently attached to cellular proteins. The presence of endogenous catechols in cells suggests that similar reactions can also occur in vivo.     

Methylation at arginine 17 of histone H3 is linked to gene activation

The nuclear hormone receptor co-activator CARM1 has the potential to methylate histone H3 at arginine residues in vitro. The methyltransferase activity of CARM1 is necessary for its co-activator functions in transient transfection assays. However, the role of this methyltransferase in vivo is unclear, given that methylation of arginines is not easily detectable on histones. We have raised an antibody that specifically recognizes methylated arginine 17 (R17) of histone H3, the major site of methylation by CARM1. Using this antibody we show that methylated R17 exists in vivo. Chromatin immunoprecipitation analysis shows that R17 methylation on histone H3 is dramatically upregulated when the estrogen receptor-regulated pS2 gene is activated. Coincident with the appearance of methylated R17, CARM1 is found associated with the histones on the pS2 gene. Together these results demonstrate that CARM1 is recruited to an active promoter and that CARM1-mediated R17 methylation on histone H3 takes place in vivo during this active state.     

Determination of methylation specificity of DsaV methyltransferase by a simple biochemical method.

We have developed a simple new method that can identify the base methylated by a sequence-specific DNA methyltransferase and have used it to identify the cytosine that is methylated by DsaV methyltransferase (M. DsaV) within its recognition sequence 5'-CCNGG. The method utilizes the fact that exonuclease III of E. coli does not degrade DNA ends with 3' overhangs and cannot hydrolyze a phosphorothioate linkage. DNA duplexes containing phosphorothioate linkages at specific positions were methylated with M. DsaV in the presence of [methyl-3H] S-adenosylmethionine and were subjected to exonuclease III digestion. The pattern of [methyl-3H] dCMP release from the duplexes was consistent with the methylation of the internal cytosine in CCNGG, but not of the outer cytosine. To establish the accuracy of this method, we confirmed the known specificity of EcoRII methyltransferase by the method. We also confirmed the specificity of M. DsaV using an established biochemical method that involves the use of a type IIS restriction enzyme. Methylation of CCWGG (W = A or T) sequences at the internal cytosines is native to E. coli and is not restricted by the modified cytosine restriction (Mcr) systems. Surprisingly, the gene for M. DsaV was significantly restricted by the McrBC system. We interpret this to mean that M. DsaV may occasionally methylate at sequences other than CCNGG or may occasionally methylate the outer cytosine in its recognition sequence.     

Specificity of the histone lysine methyltransferases from rat brain chromatin

The histone lysine methyltransferases catalyze the transfer of methyl groups from S-adenosylmethionine to specific epsilon-N-lysine residues in the N-terminal regions of histones H3 and H4. These enzymes are located exclusively within the nucleus and are firmly bound to chromatin. The chromosomal bound enzymes do not methylate free or nonspecifically associated histones, while histones H3 and H4 within newly synthesized chromatin are methylated. These enzymes can be solubilized by limited digestion (10-16%) of chromosomal DNA from rapidly proliferating rat brain chromatin with micrococcal nuclease. Histone H3 lysine methyltransferase remained associated with a short DNA fragment throughout purification. Dissociation of the enzyme from the DNA fragment with DNAase digestion resulted in complete loss of enzyme activity; however, when this enzyme remained associated with DNA it was quite stable. Activity of the dissociated enzyme could not be restored upon the addition of sheared calf thymus or Escherichia coli DNA. Histone H3 lysine methyltransferase was found to methylate lysine residues in chromosomal bound or soluble histone H3, while H3 associated with mature nucleosomes was not methylated. The histone H4 lysine methyltransferase which was detectable in the crude nuclease digest was extremely labile, losing all activity upon further purification. We isolated a methyltransferase by DEAE-cellulose chromatography, which would transfer methyl groups to arginine residues in soluble histone H4. However, this enzyme would not methylate nucleosomal or chromosomal bound histone H4, nor were methylated arginine nucleosomal or chromosomal bound histone H4, nor were methylated arginine residues detectable upon incubating intact nuclei or chromatin with S-adenosylmethionine.     

Isolation of glutamic acid methyl ester from an Escherichia coli membrane protein involved in chemotaxis.

We have isolated glutamic acid 5-methyl ester from an Escherichia coli protein that is involved in chemotaxis. The bacteria were first incubated with [methyl-3H]methionine under conditions which are known to result in methylation of the protein. The protein, isolated by gel electrophoresis, was then digested by successive treatment with three proteolytic enzymes. One of the products was [methyl-3H]glutamic acid 5-methyl ester, identified by comparison with an authentic sample in the following studies: (a) chromatography on an automatic amino acid analyzer, (b) chromatography on paper in two solvent systems, (c) chromatography on paper of the N-acetyl derivatives, and (d) stability of the ester bond to various pH conditions. No aspartic acid 4-methyl ester was found in the enzymatic digest. Treatment of the methylated protein with alkali released the radioactivity as [3H]methanol, which was identified by gas chromatography and by preparation of the 3,5-dinitrobenzoate.     

Post-translational changes of chromosomal proteins in rat cerebellum during postnatal development

Acetylation, phosphorylation and methylation of nuclear proteins in rat cerebellum at 10 and 30 days of age were investigated in vitro. Isolated nuclei were incubated in the presence of [1-14C]acetyl CoA, S-adenosyl [methyl-3H]methionine and [gamma-32P]ATP and then separated into histones and non histone proteins (NHP), which were further fractionated by polyacrylamide gel electrophoresis. The results obtained indicate that acetylation, phosphorylation and methylation of both basic and acidic proteins decrease from 10 to 30 days of age. Electrophoretic analysis of histones shows that the decrease mainly concerns H1, H3, and H2b fractions. The H3 fraction is always more labeled than the other fractions and shows the major changes during postnatal development. Phosphorylation of H2a and H4 fractions increases from 10 to 30 days of age, whereas acetylation and methylation of these fractions do not show significant changes from 10 to 30 days. The densitometric and radioactive patterns of NHP show considerable changes between 10 and 30 days, especially in the high molecular weight region. The incorporation of 14C-acetyl and 3H-methyl groups and of 32P phosphate appears to be generalized throughout the molecular weight range and decreases from 10 to 30 days of age. The methylation of an as yet unidentified protein with a molecular weight of approximately 110,000 daltons occurred at both ages.     

Cytoplasmic location of undermethylated messenger RNA in Novikoff cells.

Novikoff cells in culture were labeled with L-[methyl-3H]methionine and [U-14C]uridine in the presence of (a) TubHcy2, (b) AdoHcy, (c) homocysteine, (d) tubercidin, or (e) without any additions. Only in cultures labeled in the presence of TubHcy were undermethylated cap structures observed to represent a significant portion of [3H]methyl radioactivity. Novikoff cells in culture were then simultaneously labeled with L-[methyl-3H]methionine and [32P]orthophosphate in the presence or absence of TubHcy. Total cytoplasmic, polysomal and monosomal poly(A)-containing RNAs were analyzed. Both monosomal and polysomal mRNA fractions from TubHcy-treated cells contain partially methylated cap structures, suggesting that 2'-O-methylation of the nucleoside adjacent to the pyrophosphate linkage in caps is not required for transport, ribosomal binding or translation. Comparison of nuclear and cytoplasmic cap structures from normal and inhibited cultures indicate that an altered mRNA population is generated in the presence of TubHcy.     

In vitro methylation of yeast tRNAAsp by rat brain cortical tRNA-(adenine-1) methyltransferase.

Rat brain cortices from young animals contain large amounts of tRNA (adenine-1)methyltransferase(s). The enzyme(s) can methylate E. coli tRNA and to a lower degree yeast tRNA. Among yeast tRNA species which can be methylated we have selected tRNAAsp as a substrate for the brain enzyme. The digestions of in vitro methylated [Me-3H]-tRNAAsp with pancreatic and/or T1 ribonucleases followed by chromatographies on DEAE-cellulose, 7 M urea, suggested that the methylation of tRNAAsp occurred at a single position within the D-loop. Further digestion of the radioactive oligonucleotide recovered after DEAE-cellulose chromatography by phosphomonoesterase and snake venom phosphodiesterase enzymes followed by bidimensional thin layer chromatography enabled us to determine the location of the adenine residue which becomes methylated by the brain enzyme. This one resulted to be the adenine 14 in the D-loop of yeast tRNAAsp.     

A novel post-translational modification of yeast elongation factor 1A. Methylesterification at the C terminus

Protein methylation reactions can play important roles in cell physiology. After labeling intact Saccharomyces cerevisiae cells with S-adenosyl-l-[methyl-(3)H]methionine, we identified a major methylated 49-kDa polypeptide containing [(3)H]methyl groups in two distinct types of linkages. Peptide sequence analysis of the purified methylated protein revealed that it is eukaryotic elongation factor 1A (eEF1A, formerly EF-1alpha), the protein that forms a complex with GTP and aminoacyl-tRNAs for binding to the ribosomal A site during protein translation. Previous studies have shown that eEF1A is methylated on several internal lysine residues to give mono-, di-, and tri-N-epsilon-methyl-lysine derivatives. We confirm this finding but also detect methylation that is released as volatile methyl groups after base hydrolysis, characteristic of ester linkages. In cycloheximide-treated cells, methyl esterified eEF1A was detected largely in the ribosome and polysome fractions; little or no methylated protein was found in the soluble fraction. Because the base-labile, volatile [methyl-(3)H]radioactivity of eEF1A could be released by trypsin treatment but not by carboxypeptidase Y or chymotrypsin treatment, we suggest that the methyl ester is present on the alpha-carboxyl group of its C-terminal lysine residue. From the results of pulse-chase experiments using radiolabeled intact yeast cells, we find that the N-methylated lysine residues of eEF1A are stable over 4 h, whereas the eEF1A carboxyl methyl ester has a half-life of less than 10 min. The rapid turnover of the methyl ester suggests that the methylation/demethylation of eEF1A at the C-terminal carboxyl group may represent a novel mode of regulation of the activity of this protein in yeast.