Effects of modification of 4-thiouridine in E. coli tRNA(fMet) on its methyl acceptor activity by thermostable Gm-methylases

tRNA(guanosine-2'-)-methyltransferases (Gm-methylases) isolated from extreme thermophiles, Thermus thermophilus strains HB 27 and HB 8, methylate the 2'-OH of the G18 ribose of the GG sequence in the D loop of tRNA, by recognizing the D "loop-stem" structure as a minimal requirement. To examine the role of the consensus uridine residue at position 8 (U8) adjacent to the D "loop-stem" region in the recognition of Gm-methylase, 4-thiouridine at this position (s4U8) in Escherichia coli tRNAfMet was modified reversibly with S-benzylthioisothiourea (sBTIU) or irreversibly by UV light. The initial velocities of the methylation reaction for the sBTIU-modified and the UV-induced cross-linked tRNAs were decreased to 40 and 30%, respectively, of that of the intact tRNA, but the sBTIU-modified tRNA regained almost full activity on reduction with beta-mercaptoethanol. Although both of the modified tRNAfMetS showed larger Km (although to different extents) and slightly smaller Vmax than the intact tRNAfMet, they retained full activities of methylation with tRNA(adenine-1-)-methyltransferase (m1A-methylase) and of aminoacylation with aminoacyl-tRNA synthetase (ARS) fraction as well, both of which were prepared from T. thermophilus strain HB 27. The 5'-half fragments derived from the sBTIU-modified and cross-linked tRNAfMetS showed methylation efficiency (Vmax/Km) not appreciably different from that of the unmodified 5'-half fragment. These results suggest that the conformation of S4U8 residue of tRNA is deeply involved in the recognition of tRNA by Gm-methylase.     

Mature methyl-deficient tRNA isolated from a mammary adenocarcinoma

A transplantable rat tumor, mammary adenocarcinoma 13762, accumulates tRNA which can be methylated in vitro by mammalian tRNA (adenine-1) methyltransferase. This unusual ability of the tumor RNA to serve as substrate for a homologous tRNA methylating enzyme is correlated with unusually low levels of the A₅₈-specific adenine-1 methyltransferase. The nature of the methyl-accepting RNA has been examined by separating tumor tRNA on two-dimensional polyacrylamide gels. Comparisons of ethidium bromide-stained gels of tumor vs. liver tRNA show no significant quantitative differences and no accumulation of novel tRNAs or precursor tRNAs in adenocarcinoma RNA. Two-dimensional separations of tumor RNA after in vitro [¹⁴C]methylation using purified adenine-1 methyltransferase indicate that about 25% of the tRNA species are strongly methyl-accepting RNAs. Identification of six of the tRNAs separated on two-dimensional gels has been carried out by hybridization of cloned tRNA genes to Northern blots. Three of these, tRNA^Lys3, tRNA^Gln and tRNA^Met_i, are among the adenocarcinoma methyl-accepting RNAs. The other three RNAs, all of which are leucine-specific tRNAs, show no methyl-accepting properties. Our results suggest that low levels of a tRNA methyltransferase in the adenocarcinoma cause selected species of tRNA to escape the normal A₅₈ methylation, resulting in the appearance of several mature tRNAs which are deficient in 1-methyladenine. The methyl-accepting tRNAs from the tumor appear as ethidium bromide-stained spots of similar intensity to those seen for RNA from rat liver; therefore, methyladenine deficiency does not seem to impair processing of these tRNAs.     

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.     

Isolation and characterization of a tRNA(guanine-7-)-methyltransferase from Salmonella typhimurium

The tRNA modifying enzyme, S-adenosylmethionine:tRNA(guanine-7-)-methyltransferase, has been extensively purified from Salmonella typhimurium. A rapid and efficient purification method using phosphocellulose chromatography followed by ammonium sulfate precipitation and Sephadex G-100 gel filtration is described. The enzyme appears to be a single polypeptide chain with a molecular weight of approximately 25 000--30 000 daltons. The Km for S-adenosylmethionine and for undermethylated tRNA is 53 microM and 3.4 microM, respectively. The methylation reaction is dependent on added monovalent or divalent cations; 5 mM spermidine, 3 mM MgCl2 and 1 mM spermine are the most effective. The enzyme, though not homogeneous, is free from contaminating ribonucleases and other tRNA methyltransferases.     

Purification and characterization of transfer RNA (guanine-1)methyltransferase from Escherichia coli

The tRNA modifying enzyme, tRNA (guanine-1)methyltransferase has been purified to near homogeneity from an overproducing Escherichia coli strain harboring a multicopy plasmid carrying the structural gene of the enzyme. The preparation gives a single major band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The enzyme is probably a single polypeptide chain of molecular weight 32,000. The amino acid composition is presented and the NH2-terminal amino acid sequence was established to be H2N-Met-Trp-Ile-Gly-Ile-Ile-Ser-Leu-Phe-Pro. The enzyme has a pI of 5.2. The tRNA (guanine-1)-methyltransferase has a pH optimum of 8.0-8.5, an apparent Km of 5 microM for S-adenosylmethionine. S-adenosylhomocysteine is a competitive inhibitor for the enzyme with an apparent Ki of 6 microM. Spermidine or putrescine are not required for activity, but they stimulate the rate of methylation 1.2-fold with optima at 2 and 6 mM, respectively. Ammonium ion is not required and is inhibitory at concentrations above 0.15 M. Magnesium ion inhibited the activity at a concentration as low as 2 mM. Sodium and potassium ions were inhibitory at concentrations above 0.1 M. The molecular activity of tRNA (guanine-1)-methyltransferase was calculated to 10.0 min-1. It was estimated that the enzyme is present at 80 molecules/genome in cells growing with a specific growth rate of 1.0.     

Selenium metabolism in Drosophila. Characterization of the selenocysteine tRNA population.

The selenocysteine (Sec) tRNA population in Drosophila melanogaster is aminoacylated with serine, forms selenocysteyl-tRNA, and decodes UGA. The Km of Sec tRNA and serine tRNA for seryl-tRNA synthetase is 6.67 and 9.45 nM, respectively. Two major bands of Sec tRNA were resolved by gel electrophoresis. Both tRNAs were sequenced, and their primary structures were indistinguishable and colinear with that of the corresponding single copy gene. They are 90 nucleotides in length and contain three modified nucleosides, 5-methylcarboxymethyluridine, N6-isopentenyladenosine, and pseudouridine, at positions 34, 37, and 55, respectively. Neither form contains 1-methyladenosine at position 58 or 5-methylcarboxymethyl-2'-O-methyluridine, which are characteristically found in Sec tRNA of higher animals. We conclude that the primary structures of the two bands of Sec tRNA resolved by electrophoresis are indistinguishable by the techniques employed and that Sec tRNAs in Drosophila may exist in different conformational forms. The Sec tRNA gene maps to a single locus on chromosome 2 at position 47E or F. To our knowledge, Drosophila is the lowest eukaryote in which the Sec tRNA population has been characterized to date.     

Purification and characterization of two tRNA-(guanine)-methyltransferases from rat liver

tRNA(guanine-1-)-methyltransferase (EC 2.1.1.31) and tRNA(N2-guanine)-methyltransferase I (EC 2.1.1.32) were isolated from rat liver. The (guanine-1-)-methyltransferase preparation is 6800-fold purified and is free from contaminating methyltransferases or ribonuclease. The molecular weight of (guanine-1-)-methyltransferase is 83 000. Of seven purified Escherichia coli tRNAs examined, only tRNAMetf was utilized as substrate by (guanine-1-)-methyltransferase. The methylation of tRNAMetf is maximally stimulated by 40 mM putrescine with a pH optimum of 8.0. Using E. coli K-12 tRNA, the Km for S-adenosylmethionine is 3 micrometer and Ki for S-adenosylhomocysteine is 0.11 micrometer for (guanine-1-)-methyltransferase. (N2-Guanine-)-methyltransferase is 6200-fold purified and is also free of interfering enzymes. It has a molecular weight of 69 000. E. coli tRNAPhe, tRNAVal and tRNAArg are substrates for this enzyme which introduces a methyl at the 2-amino group of the guanine at position 10 from the 5'-terminus of these tRNAs. The methylation of tRNAPhe is maximally stimulated by 100 micrometer spermidine with a pH optimum of 8.0. (N2-Guanine-)-methyltransferase has a Km for S-adenosylmethionine of 2 micrometer and a Ki for S-adenosylhomocysteine of 23 micrometer with E. coli K-12 tRNA as methyl acceptor.     

Substrate structural requirements of Schizosaccharomyces pombe RNase P

RNase P from Schizosaccharomyces pombe has been purified over 2000-fold. The apparent Km for two S. pombe tRNA precursors derived from the supS1 and sup3-e tRNA(Ser) genes is 20 nM; the apparent Vmax is 2.5 nM/min (supS1) and 1.1 nM/min (sup3-e). Processing studies with precursors of other mutants show that the structures of the acceptor stem and anticodon/intron loop of tRNA are crucial for S. pombe RNase P action.     

tRNA methylases from HeLa cells: purification and properties of an adenine-1-methylase and a guanine-N2-methylase

Two enzymes (methylases) that catalyze the transfer of methyl groups from S-adenosyl-l-methionine to tRNA (prepared from Escherichia coli) have been partially purified from extracts of HeLa cells. One catalyzes the methylation of adenine residues of the tRNA to give 1-methyladenine units and the other is responsible for the conversion of guanine residues to N²-methylguanine and N²,N²-dimethylguanine (and may be a mixture of two enzymes). Activities of these relatively unstable enzymes could be maintained by storage at ?20 °C in the presence of 50% glycerol. Substrate specificity studies have revealed that bacterial tRNA (E. coli, Bacillus subtilis) can be used as substrate, whereas tRNA of animal origin (HeLa cells, rat liver) cannot be used. Of the specific tRNA's tested, E. coli tRNA^fMet was used as substrate by both enzymes. E. coli tRNA^Tyr was used by the adenine-1-methylase but not by the guanine-N²-methylase. The adenine-1-methylase catalyzed the transfer of approximately one methyl group per mole of either tRNA^fMet or tRNA^Tyr offered as substrate; in the presence of the guanine-N²-methylase 1 mole of E. coli tRNA^fMet accepted 1 mole of methyl. Studies with the use of both enzymes established that enzymic methylation of the guanine site of E. coli tRNA^fMet did not interfere with subsequent methylation of an adenine residue and neither did prior methylation of adenine interfere with the subsequent methylation of a guanine residue. In the presence of both enzymes, approximately 2 moles of methyl groups were accepted by 1 mole of the E. coli tRNA^fMet.     

Methylation of an adenosine in the D-loop of specific transfer RNAs from yeast by a procaryotic tRNA (adenine-1) methyltransferase.

tRNA (adenine-1) methyltransferase occurs in Bacillus subtilis. Eucaryotic tRNAThr and tRNATyr from yeast in which 1-methyladenosine (m1A) is already present in the TpsiC loop, can be methylated in vitro with S-adenosylmethionine and B. subtilis extracts. Each of the specific tRNAs accepts 1 mol of methyl groups per mol tRNA. The enzyme transforms into m1A the 3'-terminal adenylic acid residue of the dihydrouridine loop, a new position for a modified adenosine residue in tRNA. Both tRNAs have the sequence Py-A-A-G-G-C-m2(2)G in the D-loop and D-stem region. Other tRNAs with the same sequence in this region also serve as substrates for the tRNA (adenine-1) methyltransferase.     

Purification of transfer RNA (m5U54)-methyltransferase from Escherichia coli. Association with RNA

tRNA (m5U54)-methyltransferase (EC 2.1.1.35) catalyzes the transfer of methyl groups from S-adenosyl-L-methionine to transfer ribonucleic acid (tRNA) and thereby forming 5-methyluridine (m5U, ribosylthymine) in position 54 of tRNA. This enzyme, which is involved in the biosynthesis of all tRNA chains in Escherichia coli, was purified 5800-fold. A hybrid plasmid carrying trmA, the structural gene for tRNA (m5U54)-methyltransferase was used to amplify genetically the production of this enzyme 40-fold. The purest fraction contained three polypeptides of 42 kDa, 41 kDa and 32 kDa and a heterogeneous 48-57-kDa RNA-protein complex. All the polypeptides seem to be related to the 42/41-kDa polypeptides previously identified as the tRNA (m5U54)-methyltransferase. RNA comprises about 50% (by mass) of the complex. The RNA seems not to be essential for the methylation activity, but may increase the activity of the enzyme. The amino acid composition is presented and the N-terminal sequence of the 42-kDa polypeptide was found to be: Met-Thr-Pro-Glu-His-Leu-Pro-Thr-Glu-Gln-Tyr-Glu-Ala-Gln-Leu-Ala-Glu-Lys- . The tRNA (m5U54)-methyltransferase has a pI of 4.7 and a pH optimum of 8.0. The enzyme does not require added cations but is stimulated by Mg2+. The apparent Km for tRNA and S-adenosyl-L-methionine are 80 nM and 17 microM, respectively.     

Interaction of s4U8 region of tRNA Phe with tRNA-(adenine-1-)-methyltransferase from Thermus thermophilus

Photoaffinity labelling of tRNA (adenine-1-)-methyltransferase with an E. coli tRNA(Phe) derivative bearing 4-azidophenylmercuro group attached to s4U residue as well as direct photocross-linking of the native tRNA(Phe) with the enzyme via s4U residue has been studied. Both techniques labelling gave similar results, leading to covalent attachment of tRNA(Phe) to the enzyme within a specific complex. The data obtained indicate unambigously that s4U residue contacts with tRNA (adenine-1-)-methyltransferase within the corresponding specific complex.     

Yeast seryl tRNA synthetase: interactions between the ATP binding site and the sites for tRNASer and L-serine.

T1 ribonuclease digestion of yeast tRNASer in the presence of seryl tRNA synthetase was used for monitoring the relationship between the substrate binding sites on the synthetase. It was found that (a) ATP displaces the tRNA from the synthetase with an effector affinity constant corresponding to the Km for ATP of 10 micron; (b) AMP and a number of nucleoside triphosphates, while influencing the rate of aminoacylation, do not displace the tRNA from the enzyme; (c) ADP and PPi inhibit the aminoacylation and the binding of tRNASer; (d) adenylyl diphosphonate is bound to the synthetase and lowers the protection of the tRNA against the nuclease attack in a similar way as does ATP; (e) interactions between the sites of L-serine and tRNASer could only be shown when both sites for serine were saturated and, in addition, the ATP analog or ADP was present. It is concluded that in seryl tRNA synthetase binding sites for ATP interact with the ones for tRNA as well as with the ones for serine. These findings contribute to the understanding of the mechanism of aminoacylation.     

Purification and initial characterization of peptidyl-tRNA hydrolase from rabbit reticulocytes.

We have identified an activity in rabbit reticulocyte lysate as peptidyl-tRNA hydrolase, based upon its ability to hydrolyze native reticulocyte peptidyl-tRNA, isolated from polyribosomes, and N-acylaminoacyl-tRNA, and its inability to hydrolyze aminoacyl-tRNA, precisely the same substrate specificity previously reported for peptidyl-tRNA hydrolase from bacteria or yeast. The physiological role of the reticulocyte enzyme may be to hydrolyze and recycle peptidyl-tRNA that has dissociated prematurely from elongating ribosomes, as suggested for the bacterial and yeast enzymes, since reticulocyte peptidyl-tRNA hydrolase is completely incapable of hydrolyzing peptidyl-tRNA that is still bound to polyribosomes. We have purified reticulocyte peptidyl-tRNA hydrolase over 5,000-fold from the postribosomal supernatant with a yield of 14%. The purified product shows a 72-kDa band upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis that has co-purified with enzyme activity and comprises about 90% of the total stained protein, strongly suggesting that the 72-kDa protein is the enzyme. Sucrose density gradient analysis indicates an apparent molecular mass for the native enzyme of 65 kDa, implying that it is a single polypeptide chain. The enzyme is almost completely inactive in the absence of a divalent cation: Mg2+ (1-2 mM) promotes activity best, Mn2+ is partly effective, and Ca2+ and spermidine are ineffective. The hydrolase shows a Km of 0.60 microM and Vmax of 7.1 nmol/min/mg with reticulocyte peptidyl-tRNA, a Km of 60 nM and Vmax of 14 nmol/min/mg with Escherichia coli fMet-tRNA(fMet), and a Km of 100 nM and Vmax of 2.2 nmol/min/mg with yeast N-acetyl-Phe-tRNA(Phe). The enzyme has a pH optimum of 7.0-7.25, it is inactivated by heat (60 degrees C for 5 min), and its activity is almost completely inhibited by pretreatment with N-ethylmaleimide or incubation with 20 mM phosphate. The fact that the enzyme hydrolyzes E. coli but not yeast or reticulocyte fMet-tRNA(fMet) may be explained, at least in part, by structural similarities between prokaryotic tRNA(fMet) and eukaryotic elongator tRNA that are not shared by eukaryotic tRNA(fMet).     

The mercuric and organomercurial detoxifying enzymes from a plasmid-bearing strain of Escherichia coli.

Two separate enzymes, which determine resistance to inorganic mercury and organomercurials, have been purified from the plasmid-bearing Escherichia coli strain J53-1(R831). The mercuric reductase that reduces Hg2+ to volatile Hg0 was purified about 240-fold from the 160,000 X g supernatant of French press disrupted cells. This enzyme contains bound FAD, requires NADPH as an electron donor, and requires the presence of a sulfhydryl compound for activity. The reductase has a Km of 13 micron HgCl2, a pH optimum of 7.5 in 50 mM sodium phosphate buffer, an isoelectric point of 5.3, a Stokes radius of 50 A, and a molecular weight of about 180,000. The subunit molecular weight, determined by gel electrophoresis in the presence of sodium dodecyl sulfate, is about 63,000 +/- 2,000. These results suggest that the native enzyme is composed of three identical subunits. The organomercurial hydrolase, which breaks the mercury-carbon bond in compounds such as methylmercuric chloride, phenylmercuric acetate, and ethylmercuric chloride, was purified about 38-fold over the starting material. This enzyme has a Km of 0.56 micron for ethylmercuric chloride, a Km of 7.7 micron for methylmercuric chloride, and two Km values of 0.24 micron and over 200 micron for phenylmercuric acetate. The hydrolase has an isoelectric point of 5.5, requires the presence of EDTA and a sulfhydryl compound for activity, has a Stokes radius of 24 A, and has a molecular weight of about 43,000 +/- 4,000.     

Origin and formation of 1,7-dimethylguanosine in tRNA chemical and enzymatic methylation

tRNA chemical methylation: 1. 1,7-Dimethylguanosine was found in in vivo methylated tRNA from liver and kidney of rat after exposure to a low dose of dimethylnitrosamine (4 mg/kg body weight). 2. At 4 h after dimethylnitrosamine administration, the 1,7-dimethylguanosine:7-methylguanine ratio (product ratio) for liver and kidney tRNA was 0.017 and 0.091, respectively. At 24 h after dimethylnitrosamine administration, the product ratio was lower in both hepatic and renal tRNA. 3. When dimethylnitrosamine was given in four separate daily injections, the product ratio in hepatic tRNA 4 h after the last dose was the same as for the same total dose given by a single injection, but in renal tRNA it was lower. No dialkyl compound was found in liver and kidney tRNA 24 h after the last multiple injection. tRNA enzymatic methylation: 1. Base analyses of Escherichia coli B tRNA methylated in vitro, by using S-adenosylmethionine as physiological methyl donor and enzyme preparations from liver and kidney of normal rat, indicated that 1,7-dimethylguanosine was also a product of enzymatic methylation. 2. The amount of 1,7-dimethylguanosine formed by kidney enzyme preparation was 3-times that produced by the liver extract. 3. A second type of enzymatic methylation assay where chemically methylated tRNA was used as substrate indicated that the 7-methylguanosine residues in the nucleic acid are not the substrate of the methylase activity forming the 1,7-dimethylguanosine moieties. Analogous data were obtained for the origin of 1,7-dimethylguanosine residues in tRNA chemical methylation by dimethyl sulphate.     

Regulation of cyclic nucleotide phosphodiesterase activity in human lung fibroblasts.

Cyclic nucleotide phosphodiesterase activity (3', 5'-cyclic-nucleotide 5'-nucleotidohydrolase, 3.1.2.17) was studied in homogenates of WI-38 human lung fibroblasts using 0.1--200 microgram cyclic nucleotides. Activities were observed with low Km for cyclic AMP(2--5 micron) and low Km for cyclic GMP (1--2 micron) as well as with high Km values for cyclic AMP (100--125 micron) and cyclic GMP (75--100 micron). An increased low Km cyclic AMP phosphodiesterase activity was found upon exposure of intact fibroblasts to 3-isobutyl-1-methylxanthine, an inhibitor of phosphodiesterase activity in broken cell preparations, as well as to other agents which elevate cyclic AMP levels in these cells. The enhanced activity following exposure to 3-isobutyl-1-methylxanthine was selective for the low Km cyclic AMP phosphodiesterase since there was no change in activity of low Km cyclic GMP phosphodiesterase activity or in high Km phosphodiesterase activity with either nucleotide as substrate. The enhanced activity due to 3-isobutyl-1-methylxanthine appeared to involve de novo synthesis of a protein with short half-life (30 min), based on experiments involving cycloheximide and actinomycin D. This activity was also enhanced with increased cell density and by decreasing serum concentration. Studies of some biochemical properties and subcellular distribution of the enzyme indicated that the induced enzyme was similar to the non-induced (basal) low Km cyclic AMP phosphodiesterase.     

Transfer RNA methyltransferase activity in paramecium aurelia.

The tRNA methyltransferases from Paramecium aurelia were investigated. The effects of varying the Mg2+ and NH4+ concentrations, pH, and temperature on the methylation of Escherichia coli B tRNA using extracts from P. aurelia were determined. Optimum tRNA methyltransferase activity was observed at pH 7.8 and 37 degrees C. The Mg2+ optimum occurred at 0.66 mM in the absence of NH4+ while the NH4+ optimum occurred at 100 mM in the absence of Mg2+. Analysis of the bases methylated in (E. coli B) tRNA by extracts of P. aurelia showed the presence of 1-methyladenine, 1-methylguanine, N2-methylguanine, N2,N2-dimethylguanine and methylated pyrimidine nucleotides. In comparison, an analysis of the in vivo methylation of tRNA from P. aurelia showed the presence of 1-methyladenine, 6-methyladenine, 6,6-dimethyladenine, 1-methylguanine, N2-methylguanine, N2,N2-dimethylguanine, 7-methylguanine, and methylated pyrimidine nucleotides. The pattern of methylation of tRNA in P. aurelia is similar to that observed in other eukaryotes.