Human placenta S-adenosylmethionine: protein carboxyl O-methyltransferase (protein methylase II). Purification and characterization

1. Protein methylase II was purified from human placenta approx. 8700-fold with a yield of 14%. 2. Unlike protein methylase II from other sources, the activity of human placenta enzyme was completely inhibited by 2 mM Cu2+. Other divalent ions were without effect. 3. Human chorionic gonadotropin (HCG), immunoglobulin A and calf thymus histones served as good in vitro substrates for the enzyme, particularly HCG. 4. The Km for S-adenosyl-L-methionine and Ki for S-adenosyl-L-homocysteine were 2.08 x 10(-6) and 5.8 x 10(-7) M, respectively. 5. The protein methylase II activity in human placenta changed with gestational age, the activity at 1st and 2nd trimester being approximately twice that of term placenta.     

Enzymatic methyl esterification of Escherichia coli ribosomal proteins.

Enzymatic methyl ester formation in Escherichia coli ribosomal proteins was observed. Alkali lability of the methylated proteins and derivatization of the methyl groups as methyl esters of 3,5-dinitrobenzoate indicate the presence of protein methyl esters. The esterification reaction occurs predominantly on the 30S ribosomal subunit, with protein S3 as the major esterified protein. When the purified 30S subunit was used as the methyl acceptor, protein S9 was also found to be esterified. The enzyme responsible for the esterification of free carboxyl groups in proteins, protein methylase II (S-adenosyl-L-methionine:protein carboxyl methyltransferase, EC 2.1.1.24), was identified in E. coli Q13. This enzyme is extremely unstable when compared with that from mammalian origin. By molecular sieve chromatography, E. coli protein methylase II showed multiple peaks, with a major broad peak around 120,000 daltons and several minor peaks in the lower-molecular-weight region. Rechromatography of the major enzyme peak showed activities in several fractions that are much lower in molecular weight. The substrate specificity of the E. coli enzyme is similar to that of the mammalian enzyme. The Km value for S-adenosyl-L-methionine is 1.96 X 10(-6) M, and S-adenosyl-L-homocysteine was found to be a competitive inhibitor, with a Ki value of 1.75 X 10(-6) M.     

Myelin basic protein inhibits histone-specific protein methylase I

Bovine brain myelin basic protein, free of associated proteolytic activity, was found to be a specific inhibitor of histone-specific protein methylase I (S-adenosyl-L-methionine:protein-L-arginine N-methyltransferase, EC 2.1.1.23) purified from bovine brain. 50% of the methyl group incorporation into the histone substrate catalyzed by the methylase I was inhibited by myelin basic protein at a concentration of 0.326 mM. However, neither of the peptide fragments (residues 1-116 and residues 117-170) generated by the chemical cleavage of myelin basic protein at the tryptophan residue retained the inhibitory activity for histone-specific protein methylase I. Proteins such as gamma-globulin, bovine serum albumin, bovine pancreatic ribonuclease and polyarginine did not exhibit significant inhibitory activity toward the enzyme. The Ki value for myelin basic protein was estimated to be 3.42 X 10(-5) M for histone-specific protein methylase I and the nature of the inhibition was uncompetitive toward histone substrate.     

Purification and characterization of protein methylase II from Helicobacter pylori

Protein methylase II (AdoMet:protein-carboxyl O-methyltransferase, EC 2.1.1.24) was identified and purified 115-fold from Helicobacter pylori through Q-Sepharose ion exchange column, AdoHcy-Sepharose 4B column, and Superdex 200 HR column chromatography using FPLC. The purified preparation showed two protein bands of about 78 kDa and 29 kDa molecular mass on SDS-PAGE. On non-denaturing gel electrophoresis, the enzyme migrated as a single band with a molecular mass of 410 kDa. In addition, MALDI-TOF-MS analysis and Superdex 200 HR column chromatography of the purified enzyme showed a major mass signal with molecular mass values of 425 kDa and 430 kDa, respectively. Therefore, the above results led us to suggest that protein methylase II purified from H. pylori is composed of four heterodimers with 425 kDa (4x(78+29)=428 kDa). This magnitude of molecular mass is unusual for protein methylases II so far reported. The enzyme has an optimal pH of 6.0, a K(m) value of 5.0x10(-6) M for S-adenosyl-L-methionine and a V(max) of 205 pmol methyl-(14)C transferred min(-1) mg(-1) protein.     

Human placental protein methylase--I. Purification and characterization.

1. Protein methylase I (S-adenosylmethionine[:]protein-arginine N-methyltransferase; EC 2.1.1.23) which methylates protein-bound arginine residues has been purified from human term placenta 400-fold with an approximate yield of 6%. 2. When histone was used as in vitro substrate, the methylation products were found to be NG-mono-, NG, NG-di- and NG, N'G-dimethylarginine. The enzyme was found to be sensitive toward Cu2+ with Ki value of 8 x 10(-5) M. The Km value for S-adenosyl-L-methionine was 5 x 10(-6) M. 3. When this partially purified protein methylase I was incubated with isolated human placental nuclei and S-adenosyl-L-[methyl-3H]methionine, the major endogenous [methyl-3H]-labeled proteins were protein species of 23, 38, 45 and 68 kDa, the 23 kDa species being the most predominant. 4. The endogenous enzyme activity during the pregnancy increased significantly, reaching more than 4 times the initial activity at the end of term.     

Methyl acceptors for protein methylase II from human-erythrocyte membrane.

Membrane proteins from human erythrocytes were methylated with purified protein methylase II (S-adenosylmethionine:protein-carboxyl O-methyltransferase, EC.2.1.1.24). The methylated proteins were analyzed by dodecyl sulfate/polyacrylamide gel electrophoresis. Monomeric and dimeric glycophorin A (NaIO4/Schiff-2 and NaIO4/Schiff-1 positive bands) and 'band 4.5' were identified as two major classes of methyl-acceptor polypeptides for protein methylase II. In rabbit erythrocyte membrane where glycophorin A is absent, 'band 4.5' was the only major methyl-acceptor protein component. Extracted and purified glycophorin A from human erythrocytes was also found to be an excellent substrate for protein methylase II with a Km of 35.7 microM. The role of erythrocyte membrane protein methylation is discussed with regard to membrane function.     

Protease-specificity of Kunitz inhibitor domain of Alzheimer's disease amyloid protein precursor

The putative inhibitor domain of Alzheimer's disease amyloid protein precursor was purified from E. coli containing a synthetic gene encoding the Kunitz domain. The purified protein (A4 inhibitor) inhibited the activity of trypsin, forming a 1:1 molar complex with the enzyme. It also strongly inhibited plasmin (Ki = 7.5 x 10(-11) M) from human serum and tryptase (Ki = 2.2 x 10(-10) M) from rat mast cells (tryptase M). In addition, it inhibited rat pancreatic trypsin, alpha-chymotrypsin and kallikrein and human serum kallikrein, but did not inhibit rat chymase, pancreatic elastase, alpha-thrombin, urokinase, papain or cathepsin B.     

Transmethylation inhibitors decrease chemotactic sensitivity and delay cell aggregation in Dictyostelium discoideum

In Dictyostelium discoideum, extracellular cyclic AMP (cAMP) induces chemotaxis and cell aggregation. Suspensions of cAMP-sensitive cells respond to a cAMP pulse with a rapid, transient increase of protein carboxyl methylation. The transmethylation inhibitors cycloleucine, L-homocysteine thiolactone, and coformycin decrease chemotactic sensitivity and delay cell aggregation when administered in concentrations which do not influence cAMP binding to cell surface receptors or the activity of total phosphodiesterase. The ability of the drugs to inhibit chemotaxis could be correlated with their capacity to convert the initial transient positive response of carboxyl methylation to cAMP into a negative one. This suggests that both protein O-methyltransferase and protein methylesterase are activated after stimulation of aggregative cells with cAMP, the net effect being a transient, positive response of methylation. In the presence of a sufficiently large dose of inhibitor, methyltransferase is inhibited, whereas methylesterase activity is much less affected, so that a transient negative response of methylation to cAMP is observed. The slow, positive response of carboxyl methylation to cAMP which occurs ca. 2.5 to 5 min after stimulus administration is not affected by inhibitors of transmethylation. These results suggest that methylation reactions are involved in the chemotactic response of D. discoideum cells to cAMP.     

The irreversible binding of azacytosine-containing DNA fragments to bacterial DNA(cytosine-5)methyltransferases

DNA containing 5-azacytosine is an irreversible inhibitor of DNA(cytosine-5)methyltransferase. This paper describes the binding of DNA methyltransferase to 32P-labeled fragments of DNA containing 5-azacytosine. The complexes were identified by gel electrophoresis. The EcoRII methyltransferase specified by the R15 plasmid was purified from Escherichia coli B(R15). This enzyme methylates the second C in the sequence CCAGG and has a molecular mass of 60,000 Da. Specific binding of enzyme to DNA fragments could be detected if either excess unlabeled DNA or 0.8% sodium dodecyl sulfate was added to the reaction mixture prior to electrophoresis. Binding was dependent upon the presence of both the CCAGG sequence and azacytosine in the DNA fragment. S-Adenosylmethionine stimulated the formation of the complex. The complex was stable to 6 M urea but could be digested with pronase. These DNA fragments could be used to detect the presence of several different methyltransferases in crude extracts of E. coli. No DNA protein complexes could be detected in E. coli B extracts, a strain that contains no DNA(cytosine-5)methyltransferases. The chromosomally determined methylase with the same specificity as the purified EcoRII methylase could be detected in crude extracts of E. coli K12 strains. The MspI methylase cloned in E. coli HB101 could also be detected in crude extracts. These enzymes are the only proteins that bind azacytosine-containing DNA in crude extracts of E. coli.     

Selenite: a good inhibitor of rat-liver DNA methylase

DNA methylase from rat liver was partially purified through a DEAE sephacel column and characterized in an in vitro assay with respect to time, protein, DNA and S-adenosylmethionine curves. The Km for S-adenosylmethionine was 2.5 microM. Sodium selenium inhibited the methylation of DNA in a dose dependent fashion when added to the assay. It was also demonstrated that selenite non-competitively inhibits rat-liver DNA methylase with a Ki of 6.7 microM. Dithiothreitol had no effect on selenite inhibition and increasing amounts of DNA did not alter the inhibition. However, increasing amounts of protein overcame the inhibition, suggesting that selenite is reacting with the DNA methylase protein. DNA methylase isolated from selenite treated animals had only 43% of the activity as enzyme from control rats. It appears that selenite is a good inhibitor of DNA methylase.     

Purification and characterization of serine proteinase inhibitors form gourd (Lagenaria leucantha Rusby var. Gourda Makino) seeds.

Gourd seed inhibitors were purified in the following manner: gourd seeds were ground and extracted with 10 mM ammonium carbonate, pH 7.8. The extract was precipitated with 65-90% acetone and the acetone precipitates were gel filtered in a Cellulofine GCL-90-m column. Fractions of 3000 Da showing trypsin inhibitory activity were combined and purified further by ion exchange and reversed phase chromatographies. Three inhibitors, LLTI-I, II, and III were thus purified to homogeneity and the amino acid sequences of these inhibitors were: [sequence: see text] The exact sequences are unique but very similar to proteinase inhibitors belonging to the squash family. Based on the sequence, it is assumed that the peptide bond (Arg-Ile) found in the three inhibitors is the reactive site for trypsin. The Ki values estimated for complexes of LLTI-I, II, and III with bovine trypsin were 3.6 x 10(-10) M, 6.5 x 10(-11) M, and 3.0 x 10(-11) M, respectively.     

Trypsin and chymotrypsin inhibitors from viper venom

Inhibitors of trypsin and alpha-chymotrypsin with Mr of about 7000 Da and isoelectric points of greater than 10 and 9.9, respectively, were isolated from the venom of the common viper Vipera berus berus, using gel filtration and ion exchange chromatography. The inhibitor I prefers alpha-chymotrypsin (Ki = 4.6 X 10(-10) M) for the formation of an enzymeinhibitor complex at a molar ratio of 1:1. The inhibitor II prefers trypsin (Ki = 6.7 X 10(-11) M), forms an EI-complex at a molar ratio of 1:2, but also inhibits alpha-chymotrypsin (Ki = 1.4 X 10(-9) M) and hog pancreatic kallikrein (Ki = 1.6 X 10(-8) M). The inhibitor II contains no valine or methionine.     

Characterization of a new inhibitor for angiotensin converting enzyme from the venom of Vipera aspis aspis

1. Angiotensin converting enzyme inhibitor has been isolated from the venom of Vipera aspis aspis by gel filtration and reverse phase HPLC. 2. The purified inhibitor is a decapeptide, whose amino-terminal is blocked, with mol. wt 1044 determined by fast atom bombardment mass spectrometry. 3. The peptide inhibited the conversion of angiotensin I to angiotensin II, and Ki values were determined to be 7.54 x 10(-4) and 1.36 x 10(-4) M, respectively, using Hip-His-Leu and Hip-Gly-Gly as substrates 4. The peptide also inhibited the degradation of bradykinin, induced hypotension in spontaneously hypertensive rats and caused an increase in capillary permeability in rabbits, however, it possessed no lethality.     

Differential inhibition of rat mast cell proteinase I and II by members of the alpha-1-proteinase inhibitor family of serine proteinase inhibitors

Rat mast cell proteinase II (RMCP II) from mucosal mast cells was titrated into rat serum, and the resulting serine proteinase inhibitor (serpin)-enzyme complex was purified by affinity chromatography on anti-RMCP II-Sepharose 4B and by Mono-Q anion-exchange. The purified complex was used to raise polyclonal antibodies which, after cross-absorption against RMCP II-Sepharose 4B, were specific for serpin and were used to affinity purify two rat serpin molecules (RSI and RSII) that inhibit RMCP II in rat serum. The kinetic constants characterizing the interaction between RMCP II and RSI and RSII are ka, 2.2 x 10(5) and 1.65 x 10(5) M-1 s-1, respectively; Ki, 3.6 x 10(-10) and 1.0 x 10(-9) M; and kd, 7.9 x 10(-5) and 1.65 x 10(-4) s-1. Amino-terminal sequence analysis indicated that RSI and RSII are distinct, differing at the amino-terminal residues, and are products of the rat Spi-1 locus. Rat mast cell proteinase I (RMCP I) from connective tissue mast cells cleaved both RSI and RSII and was not inhibited.     

Calliandra selloi Macbride trypsin inhibitor: isolation, characterization, stability, spectroscopic analyses

A trypsin inhibitor was purified from Calliandra selloi Macbride seeds (CSTI). SDS-PAGE under non-reducing conditions showed a single band of approximately 20,000 Da, while under reducing conditions two bands of 16,000 and 6000 Da were observed, indicating that CSTI consists of two polypeptide chains. Molecular masses of 20,078 and 20,279 were obtained by mass spectrometry, although only one pI of 4.0 was observed and one peak was obtained by reversed phase chromatography. Amino-terminal sequence analysis showed homology to Kunitz-type inhibitors. CSTI was able to inhibit trypsin (Ki 2.21 x 10(-7)M), alpha-chymotrypsin (Ki 4.95 x 10(-7)M) and kallikrein (Ki 4.20 x 10(-7)M) but had no effect on elastase. Trypsin inhibitory activity was stable over a wide range of pH and temperature. CSTI was particularly susceptible to DTT treatment, followed by addition of iodoacetamide. Far-UV circular dichroism measurements revealed that CSTI is a beta-II protein. Thermal unfolding showed a two-state transition with a midpoint at 68 degrees C. Far-UV CD spectra of CSTI at pH extremes showed little changes, while more pronounced differences in near-UV CD spectra were detected. Remarkably, treatment with 1mM DTT caused very slight changes in the far-UV CD spectrum, and only after carbamidomethylation was there was a marked loss observed in secondary structure.     

Two distinct O-methyltransferases in aflatoxin biosynthesis

The substances belonging to the sterigmatocystin group bear a close structural relationship to aflatoxins. When demethylsterigmatocystin (DMST) was fed to Aspergillus parasiticus NIAH-26, which endogenously produces neither aflatoxins nor precursors in YES medium, aflatoxins B1 and G1 were produced. When dihydrodemethylsterigmatocystin (DHDMST) was fed to this mutant, aflatoxins B2 and G2 were produced. Results of the cell-free experiment with S-adenosyl-[methyl-3H]methionine showed that first the C-6-OH groups of DMST and DHDMST are methylated to produce sterigmatocystin and dihydrosterigmatocystin (O-methyltransferase I) and then the C-7-OH groups are methylated to produce O-methylsterigmatocystin (OMST) and dihydro-O-methylsterigmatocystin (DHOMST) (O-methyltransferase II). However, no methyltransferase activity was observed when either OMST, DHOMST, 5,6-dimethoxysterigmatocystin, 5-methoxysterigmatocystin, or sterigmatin was incubated with the cell extract. Treatment of the cell extract with N-ethylmaleimide inhibited O-methyltransferase I activity but not that of O-methyltransferase II. Furthermore, these O-methyltransferases were different in their protein molecules and were involved in both the reactions from DMST to OMST and DHDMST to DHOMST. The reactions described in this paper were not observed when the same mold had been cultured in YEP medium.     

Two distinct O-methyltransferases in aflatoxin biosynthesis.

The substances belonging to the sterigmatocystin group bear a close structural relationship to aflatoxins. When demethylsterigmatocystin (DMST) was fed to Aspergillus parasiticus NIAH-26, which endogenously produces neither aflatoxins nor precursors in YES medium, aflatoxins B1 and G1 were produced. When dihydrodemethylsterigmatocystin (DHDMST) was fed to this mutant, aflatoxins B2 and G2 were produced. Results of the cell-free experiment with S-adenosyl-[methyl-3H]methionine showed that first the C-6-OH groups of DMST and DHDMST are methylated to produce sterigmatocystin and dihydrosterigmatocystin (O-methyltransferase I) and then the C-7-OH groups are methylated to produce O-methylsterigmatocystin (OMST) and dihydro-O-methylsterigmatocystin (DHOMST) (O-methyltransferase II). However, no methyltransferase activity was observed when either OMST, DHOMST, 5,6-dimethoxysterigmatocystin, 5-methoxysterigmatocystin, or sterigmatin was incubated with the cell extract. Treatment of the cell extract with N-ethylmaleimide inhibited O-methyltransferase I activity but not that of O-methyltransferase II. Furthermore, these O-methyltransferases were different in their protein molecules and were involved in both the reactions from DMST to OMST and DHDMST to DHOMST. The reactions described in this paper were not observed when the same mold had been cultured in YEP medium.     

Protein methylation in animal cells. I. Purification and properties of S-adenosyl-L-methionine:protein (arginine) N-methyltransferase from Krebs II ascites cells.

1. A protein methylase which specifically transfers methyl groups from S-adenosyl-L-methionine to arginine residues of histones has been substantially purified from Krebs II ascites cells. The purified enzyme was obtained free of contamination by other protein methyl transferases specific for carboxyl and lysine residues. This latter activity copurified with the present enzyme until advanced stages of purification. 2. The purified enzyme does not require any divalent cation for maximum activity. It is inhibited by ionic strength, N-ethylmaleimide and S-adenosyl-L-homocysteine. It has an apparent molecular weight on gel filtration of approx. 5 . 10(5). A Km value for S-adenosyl-L-methionine of 2.5 . 10(-6) M was determined, while the dissociation constant Ki for S-adenosyl-L-homocysteine, which acts as a competitor, was 1.4 . 10(-6) M.     

Cloning and expression of the Momordica charantia trypsin inhibitor II gene in silkworm by using a baculovirus vector

MCTI-II (Momordica charantia trypsin inhibitor II) isolated from bitter gourd (Momordica charantia LINN.) seeds is one of the serine protease inhibitors of the squash family. We cloned cDNA that encodes MCTI-II and constructed an expression system for MCTI-II by using a baculovirus vector. The recombinant baculovirus was inoculated to early fifth-instar larvae of the silkworm (strain: Shunrei x Shougetsu). Four days after infection, the hemolymph of silkworm larvae was collected and the recombinant protein was purified. Two kinds of expressed MCTI-II protein were obtained. An amino acid sequence analysis of the two proteins indicates that both were similar to the authentic inhibitor, except for the addition of a tripeptide derived from the vector at the N-terminus. One of the two inhibitors (MCTI-II A) resulted in a single PTH-amino acid in each Edman degradation cycle, while the other (MCTI-II B) resulted in two PTH-amino acids, suggesting the occurrence of cleavage of the reactive site. The inhibitory activities of MCTI-II expressed toward trypsin are examined in terms of the Ki value, these being 6.4 x 10(-10)M for MCTI-II A and 5.2 x 10(-10) M for MCTI-II B.     

Guanidoacetate methyltransferase. Purification and molecular properties.

Guanidoacetate methyltransferase has been purified about 140-fold from pig liver. Polyacrylamide gel electrophoresis of the purified enzyme showed four protein bands, each of which is associated with guanidoacetate methyltransferase activity. During gel electrophoresis at pH 3 in 8 M urea, guanidoacetate methyltransferase migrated as a single component. The molecular weight of the purified guanidoacetate methyltransferase was estimated to be 31,000 by sodium dodecyl sulfate-gel electrophoresis, which also showed only one protein component with guanidoacetate methyltransferase activity. This molecular weight is in agreement with that estimated by Sephadex G-75 chromatography. Guanidoacetate methyltransferase is inhibited by adenosylhomocysteine, 3-deazaadenosylhomocysteine, and sinefungin with Ki values of 16 microM, 39 microM, and 18 microM, respectively.