Effect of Ecodam DNA-methylase on single-stranded sequences and synthetic oligonucleotides

Interaction of the Ecodam methylase with different substrates were investigated among them the double- and single-stranded DNAs and synthetic oligonucleotides containing some defects in the GATC sequence. These defects were:nick, the absence of one internucleotide phosphate of nucleotide; partially single-stranded form on the recognition site etc. It was demonstrated that the presence of both G . A-dinucleotides in the recognition site is necessary for productive enzyme-substrate interaction. The absence of T and/or C residues is less dramatic for methylase activity. The Ecodam methylase is capable to modify the single-stranded oligonucleotides by forming the double-stranded structure in the symmetric recognition sequences GATC.     

Substrate recognition and selectivity in the type IC DNA modification methylase M.EcoR124I.

The type I DNA modification methylase M.EcoR124I binds sequence specifically to DNA and protects a 25bp fragment containing its cognate recognition sequence from digestion by exonuclease III. Using modified synthetic oligonucleotide duplexes we have investigated the catalytic properties of the methylase, and have established that a specific adenine on each strand of DNA is the site of methylation. We show that the rate of methylation of each adenine is increased at least 100 fold by prior methylation at the other site. However, this is accompanied by a significant decrease in the affinity of the methylase for these substrates according to competitive gel retardation assays. In contrast, methylation of an adenine in the recognition site which is not a target for the enzyme results in only a small decrease in both DNA binding affinity and rate of methylation by the enzyme.     

Purification and biochemical characterisation of the EcoR124 type I modification methylase.

Large scale purification of the type I modification methylase EcoR124 has been achieved from an over-expressing strain by a two step procedure using ion-exchange and heparin chromatography. Pure methylase is obtained at a yield of 30 mg per gm of cell paste. Measurements of the molecular weight and subunit stoichiometry show that the enzyme is a trimeric complex of 162 kDa consisting of two subunits of HsdM (58 kDa) and one subunit of HsdS (46 kDa). The purified enzyme can methylate a DNA fragment bearing its cognate recognition sequence. Binding of the methylase to synthetic DNA fragments containing either the EcoR124 recognition sequence GAAN6RTCG, or the recognition sequence GAAN7RTCG of the related enzyme EcoR124/3, was followed by fluorescence competition assays and by gel retardation analysis. The results show that the methylase binds to its correct sequence with an affinity of the order 10(8) M-1 forming a 1:1 complex with the DNA. The affinity for the incorrect sequence, differing by an additional base pair in the non-specific spacer, is almost two orders of magnitude lower.     

DNA methylation: sequences flanking C-G pairs modulate the specificity of the human DNA methylase.

Synthetic single-stranded oligodeoxynucleotides of known sequence have been used as in vitro substrates for a partially purified HeLa cell DNA methylase. Although most oligonucleotides tested cannot be used by the HeLa DNA methylase in vitro, we have found a unique 27mer, containing 2 C-G pairs, that is an excellent substrate for the enzyme. Analysis of the methylation of the 27mer, its derivatives and other oligomer substrates reveal that the HeLa DNA methylase does not significantly methylate an oligomer which contains just one C-G pair. In addition, only one of the two C-G pairs in the 27mer is methylated and this methylation is abolished if the other C-G pair is converted to a C-A pair. Furthermore, the HeLa enzyme apparently cannot methylate C-G pairs located in compounds containing a high A + T content. The most efficient methylation occurs with multiple separated C-G pairs in a compound with a high G + C content (greater than 65%). The results suggest that clustering of C-G pairs in regions of the DNA high in G + C content may be the preferred site for DNA methylation in vivo.     

Temperature-dependent structural changes in complexes of tRNA(adenine-1)-methyltransferase from Thermus thermophilus HB8 and tRNA studied by optical and electron microscope methods

The complexation of tRNA (adenine-1-)-methyltransferase from Thermus thermophilus HB8 (E.C.2.1.1.36) with Escherichia coli tRNA(Phe) and yeast tRNA1(Val) was investigated in a temperature range from 20 to 90 degrees C. The quantity of methylase subunits bounded with tRNA and the association constant (Ka) were determined by means of fluorescence quenching of the enzyme tryptophane residues by tRNA molecules. The number of enzyme subunits bounded with one tRNA molecule at temperatures 20-70 degrees C is equal to 8 +/- 2. The Ka values increase from (2 divided by 3).10(7) at 20 degrees C up to 8.5.10(7) M-1 at 70 degrees C. The temperature increase from 70 to 90 degrees C causes a decrease in the enzyme specific activity and in Ka values. In the temperature range from 75 to 90 degrees C a cooperative transition of methylase macromolecules into associates was observed. This association is accompanied by an increase of UV-light scattering and of fluorescence polarization coefficient of methylase tryptophane residues. In the absence of tRNA the size of enzyme associates (d) is evaluated to be more than 320 nm (d greater than or equal to lambda-320 nm), in the presence of tRNA-less than 320 nm (d much less than lambda-320 nm). An electron microscopic investigation of methylase and its complexes with tRNA at 20 degrees C revealed disk-like particles with a diameter and height of 8-11 nm and 4-5 nm, respectively. These disk-like methylase preparations dialized against distilled water form flexible polymeric rods with a diameter of 10-12 nm and the length of about several hundreds nm. During complexation of methylase with tRNA, in the same conditions as the dializes was carried out, large associates were not revealed.     

Effect of the structure of oligonucleotide substrates on interaction with methylase Eco dam

The interaction of Eco dam methylase with various synthetic oligonucleotide substrates was investigated. The "imperfect" duplexes contained a normal GATC recognition sequence in one chain of the enzyme recognition site and had some defects in the complementary chain, i.e., the absence of one or several nucleotide residues or the presence of S-methyl thiophosphate groups at the 3'-termini. The 3'-S-methyl thiophosphate residue has the same effect on the methylation of oligonucleotide complexes as does the absence of internucleotide phosphate in the analogous complexes. The presence of both GA dinucleotides in the recognition site is necessary for a productive enzyme-substrate interaction. The experimental data suggest that Eco dam methylase does form a symmetrical enzyme-substrate complex which is similar to that formed by type II restriction enzymes.     

Substrate preferences of human placental DNA methyltransferase investigated with synthetic polydeoxynucleotides

A DNA methyltransferase partly purified from human placenta has been tested on a variety of synthetic polydeoxynucleotides. The results showed that: the enzyme is most active as a 'maintenance' or 'hemi-' methylase but also has some de novo methylating activity; the presence or absence of A or T in the substrate strand has little influence on maintenance or de novo activity, while polymers containing C but not G in the same strand are poor de novo substrates and bind poorly to the enzyme; single-stranded polymers are about as good substrates as double-stranded ones, and the effects of nucleotide composition (particularly G and mC content) on enzyme activity with single strands are similar to those with double-stranded polymers; strands in which all the cytosines are methylated bind the enzyme well. A mechanism is suggested involving two different sites on the enzyme that recognize CG and mCG, and which rationalizes the activity of eukaryotic DNA methyltransferases towards single-stranded DNA.     

5-Fluorocytosine in DNA is a mechanism-based inhibitor of HhaI methylase

5-Fluorodeoxycytidine (FdCyd) was incorporated into a synthetic DNA polymer containing the GCGC recognition sequence of HhaI methylase to give a polymer with about 80% FdCyd. In the absence of AdoMet, poly(FdC-dG) bound competitively with respect to poly(dG-dC) (Ki = 3 nM). In the presence of AdoMet, the analogue caused a time-dependent, first-order (k = 0.05 min-1) inactivation of the enzyme. There is an ordered mechanism of binding in which enzyme first binds to poly(FdC-dG), then binds to AdoMet, and subsequently forms stable, inactive complexes. The complexes did not dissociate over the course of 3 days and were stable to heat (95 degrees C) in the presence of 1% SDS. Gel filtration of a complex formed with HhaI methylase, poly(FdC-dG), and [methyl-3H] AdoMet gave a peak of radioactivity eluting near the void volume. Digestion of the DNA in the complex resulted in a reduction of the molecular weight to the size of the methylase, and the radioactivity in this peak was shown to be associated with protein. These data indicate that the complexes contain covalently bound HhaI methylase, poly(FdC-dG), and methyl groups and that 5-fluorodeoxycytidine is a mechanism-based inactivator of the methylase. By analogy with other pyrimidine-modifying enzymes and recent studies on the mechanism of HhaI methylase (Wu & Santi, 1987), these results suggest that an enzyme nucleophile attacks FdCyd residues at C-6, activating the 5-position for one-carbon transfer.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

An essential role for sodium in the bicarbonate transporting system of the cyanobacterium Anabaena variabilis

The Eco dam methylase is active on denatured DNA and single-stranded synthetic oligonucleotides containing GATC sites. The results suggest that on interaction with single-stranded oligonucleotides the Eco dam methylase is able to form a duplex structure within the GATC site, and that this duplex site is a substrate for enzyme.     

Chemical synthesis and properties of oligonucleotide substrates for restriction endonuclease BamHI and methyltransferase Eco dam

Oligodeoxyribonucleotides which form a number of duplexes, containing the recognition sequences for endonuclease BamHI and DNA methylase Eco dam, were synthesised by the phosphotriester approach. Furthermore, synthesis of 3'-phosphorylated oligodeoxyribonucleotides from corresponding S-methyl phosphorothioate triester oligomers is described. The synthetic duplexes are characterized by some defects in the recognition sequences for endonuclease BamHI and methylase Eco dam, viz. nick, absence of an internucleotide phosphate, modifications (including partial single-strandedness) of the recognition site. Interaction of the enzymes with these synthetic substrates was investigated.     

Partial purification and characterisation of S-adenosylmethionine:protein-histidine N-methyltransferase from rabbit skeletal muscle

A new class of protein methylase (S-adenosylmethionine:protein-histidine N-methyltransferase) which methylates histidine residues of protein substrates using S-adenosylmethionine as the methyl donor has been partially purified from rabbit skeletal muscle, 22-fold with a yield of 56%. The enzyme activity was monitored using denatured myofibrils from young rabbit skeletal muscle as the methyl acceptor protein substrate. The enzyme was localised in the myofibrillar fraction and myofibrils isolated in pure form represented the enzyme-substrate complex. The enzyme was solubilised in 0.275 M KCl. The methylase showed no requirement for any metal ion and has a pH optimum of 8.0. It was shown to require a reducing agent like mercaptoethanol for its activity. It was also shown that cardiac and skeletal muscle forms of actins obtained from different species serve as the efficient methyl acceptor protein substrates. Since the enzyme was found to methylate specifically the histidine residues of actin we propose to designate this new methylase as protein methylase IV, to distinguish it from the already known protein methylases I, II and III.     

DNA methylation. Inhibition of de novo and maintenance methylation in vitro by RNA and synthetic polynucleotides

A partially purified HeLa cell DNA methylase will methylate a totally unmethylated DNA (de novo methylation) at about 3-4% the rate it will methylate a hemimethylated DNA template (maintenance methylation). Our evidence suggests that many, if not most, dCpdG sequences in a natural or synthetic DNA can be methylated by the enzyme. There is a powerful inhibitor of DNA methylase activity in crude extracts which has been identified as RNA. The inhibition of DNA methylase by RNA may indicate that this enzyme is regulated in vivo by the presence of RNA at specific chromosomal sites. The pattern of binding of RNA to DNA in the nucleosome structure and the DNA replication complex may determine specific sites of DNA methylation. An even more potent inhibition of DNA methylase activity is observed with poly(G), but not poly(C), poly(A), or poly(U). The only other synthetic polynucleotides studied which inhibit DNA methylation as well as poly(G) are the homopolymers poly(dC).poly(dG) and poly (dA).poly(dT). These results point out the unique importance of the guanine residue itself in the binding of the DNA methylase to dCpdG, the site of cytosine methylation. The surprising inhibition of the methylation reaction by poly(dA).poly(dT), which is itself not methylated by the enzyme, suggests the possible involvement of adjacent A and T residues in influencing the choice of sites of methylation by the enzyme.     

DNA-methylase from regenerating rat liver: purification and characterisation.

DNA methylase has been purified 660-fold from nuclei from regenerating rat liver. The enzyme is able to methylate single stranded (ss) and double stranded (ds) DNA, the only reaction product being 5-methylcytosine. Previously unmethylated double stranded DNA from prokaryotes (M.luteus) as well as from eukaryotes (Ascaris suis) can serve as substrates. The synthetic copolymers (dG-dC)n . (dC-dG)n and (dG,dC)n are also methylated. While SV40 DNA is almost not methylated, PM2 DNA is a good substrate even in the supercoiled form. The enzyme methylates 1 in 17 bases in heterologous M.luteus DNA, but only 1 in 590 in homologous rat liver DNA. The high methylation level of M.luteus DNA, an analysis of the methylated pyrimidine isostichs and a preliminary dinucleotide analysis suggest that all the CpGs in a DNA can be methylated.     

Isolation and Characterization of Biochemical Properties of DNA Methyltransferase <Emphasis Type="Italic">Fau</Emphasis>IA Modifying the Second Cytosine in the Nonpalindromic Sequence 5′-CCCGC-3′

A gene encoding DNA methyltransferase (methylase) FauIA of the restriction-modification system FauI from Flavobacterium aquatile (recognizing sequence 5'-CCCGC-3') was cloned in pJW vector. The latter was used for transformation of E. coli RRI cells followed by subsequent thermoinduction and biomass elaboration. Highly purified DNA methyltransferase FauIA preparation was obtained using chromatography on different sorbents. The molecular mass of the isolated enzyme of about 39 kD corresponds to its theoretical value. The enzyme was characterized by temperature and pH optima of 33 degrees C and pH 7.5, respectively. Methylation of a synthetic oligonucleotide by FauIA methylase followed by its cleavage with various restrictases and analysis of the resultant restriction fragments revealed that FauIA methylase modified the second cytosine residue in the sequence 5'-CCCGC-3'. Kinetic analysis revealed Km and catalytic constant values of 0.16 microM and 0.05 min(-1), respectively.     

STUDIES ON THE NATURAL SUBSTRATE FOR PROTEIN METHYLASE II IN MAMMALIAN BRAIN AND BLOOD

—The activity of protein methylase II (S-adenosylmethionine:protein-carboxyl methyltransferase, EC 2.1.1.24), which methylates (esterifies) free carboxyl groups in the substrate protein, was measured in several mammalian organs in an effort to elucidate the nature of the natural substrate for the enzyme. The highest endogenous substrate activity was found in posterior and anterior pituitary glands, possibly in association with neurosecretory granules. In other parts of the brain endogenous substrates are lacking, although the cytosol fractions contain high activity of the enzyme which methylates exogenously added substrates. Rat whole blood also contains endogenous substrate protein. The protein precipitated by 50% (NH₄)₂SO₄ contained active substrate protein whereas blood protein methylase II is localized exclusively in the erythrocytes. Cohn fractions I, II and III are more active as substrate for protein methylase II than fraction V.     

Protein methylases in Trypanosoma brucei brucei: activities and response to DL-alpha-difluoromethylornithine

Protein methylases I, II and III were detected in extracts of Trypanosoma brucei brucei, and characterized according to the specific amino substituent methylated. Only protein methylase II activity was elevated by difluoromethylornithine treatment of T. b. brucei, and hence this enzyme was characterized further. Protein methylase II transferred methyl groups from S-adenosyl-L-methionine (S-AdoMet) to the carboxyl residues of several protein substrates, exhibiting highest activity with histone VIII-S (arginine-rich subgroup f3). The crude enzyme had an apparent Km for histone VIII-S of 28 mg ml-1 (11.4 mM-aspartyl and 18.4 mM-glutamyl residues methylated), and an apparent Km for S-AdoMet of 8.4 microM. T. b. brucei protein methylase II was sensitive to inhibition by S-adenosyl-L-homocysteine and its analogue sinefungin with apparent Ki values of 12.9 and 1.6 microM, respectively. Using a partially purified preparation, analysis of kinetic data in the presence and absence of sinefungin indicated that this analogue acts as a competitive inhibitor of the S-AdoMet binding site, and as a non-competitive inhibitor of the (protein) histone VIII-S binding site. The possible role of the enzyme in morphological control and its potential as a chemotherapeutic target are discussed.     

Glutamine-181 is crucial in the enzymatic activity and substrate specificity of human endoplasmic-reticulum aminopeptidase-1

ERAP-1 (endoplasmic-reticulum aminopeptidase-1) is a multifunctional enzyme with roles in the regulation of blood pressure, angiogenesis and the presentation of antigens to MHC class I molecules. Whereas the enzyme shows restricted specificity toward synthetic substrates, its substrate specificity toward natural peptides is rather broad. Because of the pathophysiological significance of ERAP-1, it is important to elucidate the molecular basis of its enzymatic action. In the present study we used site-directed mutagenesis to identify residues affecting the substrate specificity of human ERAP-1 and identified Gln(181) as important for enzymatic activity and substrate specificity. Replacement of Gln(181) by aspartic acid resulted in a significant change in substrate specificity, with Q181D ERAP-1 showing a preference for basic amino acids. In addition, Q181D ERAP-1 cleaved natural peptides possessing a basic amino acid at the N-terminal end more efficiently than did the wild-type enzyme, whereas its cleavage of peptides with a non-basic amino acid was significantly reduced. Another mutant enzyme, Q181E, also revealed some preference for peptides with a basic N-terminal amino acid, although it had little hydrolytic activity toward the synthetic peptides tested. Other mutant enzymes, including Q181N and Q181A ERAP-1s, revealed little enzymatic activity toward synthetic or peptide substrates. These results indicate that Gln(181) is critical for the enzymatic activity and substrate specificity of ERAP-1.