Modified nucleotides in Bacillus subtilis tRNA(Trp) hyperexpressed in Escherichia coli.

In the present study, modified nucleotides in the B. subtilis tRNA(Trp) cloned and hyperexpressed in E. coli have been identified by TLC and HPLC analyses. The modification patterns of the two isoacceptors of cloned B. subtilis tRNA(Trp) have been compared with those of native tRNA(Trp) from B. subtilis and from E. coli. The modifications of the A73 mutant of B. subtilis tRNA(Trp), which is inactive toward its cognate TrpRS, were also investigated. The results indicate the formation of the modified nucleotides S4U8, Gm18, D20, Cm32, i6A/ms2i6A37, T54 and psi 55 on cloned B. subtilis tRNA(Trp). This modification pattern resembles the pattern of E. coli tRNA(Trp), except that m7G is missing from the cloned tRNA(Trp), probably on account of its short extra loop. In contrast, the pattern departs substantially from that of native B. subtilis tRNA(Trp). Therefore, the cloned B. subtilis tRNA(Trp) has taken on largely the modification pattern of E. coli tRNA(Trp) despite the 26% sequence difference between the two species of tRNA, gaining in particular the Cm32 and Gm18 modifications from the E. coli host. A notable difference between the isoacceptors of the cloned tRNA(Trp) was seen in the extent of modification of A37, which occurred as either the hypomodified i6A or the hypermodified ms2i6A form. Surprisingly, base substitution of guanosine by adenosine at position 73 of the cloned tRNA(Trp) has led to the abolition of the 2'-O-methylation modification of the remote G18 residue.     

Silver stain for proteins on a cellulose acetate membrane

A rapid and sensitive silver staining method to detect proteins on a cellulose acetate membrane has been established. This method is achieved by modification of the silver-based color staining for detection of proteins in polyacrylamide gels [D. W. Sammons, L. D. Adams, and E. E. Nishizawa, Electrophoresis 2, 135-141 (1981)] and applied to our new type of two-dimensional electrophoresis for analysis of proteins on a cellulose acetate sheet [T. Toda, T. Fujita, and M. Ohashi, Anal. Biochem. 119, 167-176 (1982)]. Maximal sensitivity of silver stain for proteins on a cellulose acetate membrane can be obtained by an optimal balance between deposition of silver on the protein and on the background. Certain kinds of proteins are colored red, orange, or grayish-blue. The silver stain is 20-80 times more sensitive than Coomassie blue and some spots are visualized reproducibly by silver only. Densitometric evaluation of standard proteins stained with silver and Coomassie blue is also demonstrated. The method takes only 50 min to perform and is sensitive, simple, and reproducible.     

Residues Lys-149 and Glu-153 switch the aminoacylation of tRNA(Trp) in Bacillus subtilis

Tryptophanyl-tRNA synthetase (TrpRS) consists of two identical subunits that induce the cross-subunit binding mode of tRNA(Trp). It has been shown that eubacterial and eukaryotic TrpRSs cannot efficiently cross-aminoacylate the corresponding tRNA(Trp). Although the identity elements in tRNA(Trp) that confer the species-specific recognition have been identified, the corresponding elements in TrpRS have not yet been reported. In this study two residues, Lys-149 and Glu-153, were identified as being crucial for the accurate recognition of tRNA(Trp). These residues reside adjacent to the binding pocket for Trp-AMP and show phylogenic diversities in the charge on their side chains between eubacteria and eukaryotes. Single mutagenesis at Lys-149 or Glu-153 reduced the activity of TrpRS in the activation of Trp. The reduction was less than that caused by the double mutant WBHA (K149D/E153R). It is unusual that E153G had no detectable activity in the activation of Trp unless tRNA(Trp) was added to the reaction. In addition, we successfully switched the species specificity of Bacillus subtilis TrpRS recognition of tRNA(Trp). The affinity of WBHA, K149E and E153K to human tRNA(Trp) was 31-, 13.5-, and 12.9-fold greater than that of wild type B. subtilis TrpRS, respectively. Indeed WBHA and E153K were found to prefer genuine human tRNA(Trp) to their cognate eubacteria tRNA(Trp).     

Occurrence of 1-methyladenosine and absence of ribothymidine in transfer ribonucleic acid of Mycobacterium smegmatis.

The minor base composition of Mycobacterium smegmatis tRNA has been studied. Thin-layer chromatographic patterns of a ribonuclease T2 digest of mycobacterial tRNA indicated the presence of appreciable amounts of 1-methyladenosine (which is commonly present only in eucaryotic tRNA), dihydrouridine, and 7-methylguanosine. Ribothymidine was absent. The S-adenosylmethionine-dependent tRNA methylases of M. smegmatis catalyzed the formation of 1-methyladenosine when Escherichia coli tRNA was used as acceptor. Similarly, E. coli extracts methylated the tRNA of M. smegmatis, forming ribothymidine.     

Topography of the E site on the Escherichia coli ribosome.

Three photoreactive tRNA probes have been utilized in order to identify ribosomal components that are in contact with the aminoacyl acceptor end and the anticodon loop of tRNA bound to the E site of Escherichia coli ribosomes. Two of the probes were derivatives of E. coli tRNA(Phe) in which adenosines at positions 73 and 76 were replaced by 2-azidoadenosine. The third probe was derived from yeast tRNA(Phe) by substituting wyosine at position 37 with 2-azidoadenosine. Despite the modifications, all of the photoreactive tRNA species were able to bind to the E site of E. coli ribosomes programmed with poly(A) and, upon irradiation, formed covalent adducts with the ribosomal subunits. The tRNA(Phe) probes modified at or near the 3' terminus exclusively labeled protein L33 in the 50S subunit. The tRNA(Phe) derivative containing 2-azidoadenosine within the anticodon loop became cross-linked to protein S11 as well as to a segment of the 16S rRNA encompassing the 3'-terminal 30 nucleotides. We have located the two extremities of the E site-bound tRNA on the ribosomal subunits according to the positions of L33, S11 and the 3' end of 16S rRNA defined by immune electron microscopy. Our results demonstrate conclusively that the E site is topographically distinct from either the P site or the A site, and that it is located alongside the P site as expected for the tRNA exit site.     

Assembly of the mitochondrial membrane system. Sequences of yeast mitochondrial tRNA genes

Two cytoplasmic "petite" (rho-) clones of Saccharomyces cerevisiae have been selected for the retention of the aspartic acid tRNA gene. The two clones, designated DS200/A102 and DS200/A5, have tandemly repeated segments of mitochondrial DNA (mtDNA) with unit lengths of 1,000 and 6,400 base pairs, respectively. The DS200/A102 genome has a single tRNA gene with a 3'-CUG-5' anticodon capable of recognizing the 5'-GAC-3' and 5'-GAU-3' codons for aspartic acid. The mtDNA segment of DS200/A102 has been determined to represent the wild type sequence from 5.3 to 6.8 map units. The genome of DS200/A5 is more complex encompassing the region of wild type mtDNA from 3.5 to 12.7 units. A continuous sequence has been obtained from 3.5 to 8.6 units. In addition to the aspartic acid tRNA, this region codes for the tRNAUGCAla,tRNAUCUArg, tRNAACGArg, tRNAGCUSer,tRNAUCCGly and tRNAUUULys. The DNA sequence of the DS200/A5 genome has allowed us to deduce the secondary structures of the seven tRNAs and to assign precise map positions for their genes. All the tRNAs except tRNA GUCAsp exhibit most of the invariant features of prokaryotic and eukaryotic tRNAs. The aspartic acid tRNA has unusual D and T psi C loops. The structure of this tRNA is similar to the mitochondrial initiator tRNA of Neurospora crassa (Heckman, J.E., Hecker, L.I., Shwartzbach, S.D., Barnett, W.E., Baumstark, B., and RajBhandary, U.L. Cell 13, 83-95).     

Temperature jump relaxation studies on the interactions between transfer RNAs with complementary anticodons. The effect of modified bases adjacent to the anticodon triplet

We have used the temperature-jump relaxation technique to determine the kinetic and thermodynamic parameters for the association between the following tRNAs pairs having complementary anticodons: tRNA(Ser) with tRNA(Gly), tRNA(Cys) with tRNA(Ala) and tRNA(Trp) with tRNA(Pro). The anticodon sequence of E. coli tRNA(Ser), GGA, is complementary to the U*CC anticodon of E. coli tRNA(Gly(2] (where U* is a still unknown modified uridine base) and A37 is not modified in none of these two tRNAs. E. coli tRNA(Ala) has a VGC anticodon (V is 5-oxyacetic acid uridine) while tRNA(Cys) has the complementary GCA anticodon with a modified adenine on the 3' side, namely 2-methylthio N6-isopentenyl adenine (mS2i6A37) in E. Coli tRNA(Cys) and N6-isopentenyl adenine (i6A37) in yeast tRNA(Cys). The brewer yeast tRNA(Trp) (anticodon CmCA) differs from the wild type E. coli tRNA(Trp) (anticodon CCA) in several positions of the nucleotide sequence. Nevertheless, in the anticodon loop, only two interesting differences are present: A37 is not modified while C34 at the first anticodon position is modified into a ribose 2'-O methyl derivative (Cm). The corresponding complementary tRNA is E.coli tRNA(Pro) with the VGG anticodon. Our results indicate a dominant effect of the nature and sequence of the anticodon bases and their nearest neighbor in the anticodon loop (particularly at position 37 on the 3' side); no detectable influence of modifications in the other tRNA stems has been detected. We found a strong stabilizing effect of the methylthio group on i6A37 as compared to isopentenyl modification of the same residue. We have not been able so far to assess the effect of isopentenyl modification alone in comparison to unmodified A37. The results obtained with the complex yeast tRNA(Trp)-E.coli tRNA(Pro) also suggest that a modification of C34 to Cm34 does not significantly increase the stability of tRNA(Trp) association with its complementary anticodon in tRNA(Pro). The observations are discussed in the light of inter- and intra-strand stacking interactions among the anticodon triplets and with the purine base adjacent to them, and of possible biological implications.     

Studies on the glutathione S-transferase proteome of adult Drosophila melanogaster: responsiveness to chemical challenge

GSTs from adult Drosophila melanogaster have been partially purified using three different affinity chromatography media and separated by 2-DE. Nine GSTs have been identified by MALDI-TOF MS. In the absence of special treatments, eight GSTs could be positively identified. These were DmGSTs D1 (the dominant Delta isoform which was present in five protein zones of differing pI) and D3 (and possibly also D5); the Epsilon-class GSTs E3, 6, 7 and 9 and a previously uncharacterised, probable member of the class, CG16936. The Sigma-class DmGSTS1 was prominent. DmGSTD2 was detected only after pretreatment of the flies with Phenobarbital (PhB). Treatment with Paraquat (PQ) led to an increase in the total GST activity, as measured with the substrates 1-chloro-2,4-dinitrobenzene (CDNB) and 3,4-dichloro-nitrobenzene (DCNB) and an increase in the relative amounts of the D1, D3, E6 and E7 isoforms. PhB treatment led to increases in the relative amounts of the D1, D2, E3, E6, E7 and E9 isoforms detected with a possible depression in the relative amount of GSTS1. CG16936 was unaffected by either pretreatment.     

Quantitative study of interaction of deacylated tRNA with Escherichia coli ribosomes. Role of 50 S subunits in formation of the E site

The 30 S subunit contains 2 sites for tRNA binding (Phe-tRNA, AcPhe-tRNA, tRNAPheOH) with the functional properties of D and A sites of the 70 S ribosome after attachment of 50 S subunit. The third (E) site specific for deacylated tRNA is introduced into 70 S ribosome by its 50 S subunit. The E-site binding of tRNAPheOH is not sensitive to either tetracycline and edeine, and practically codon-independent. The affinity constant of tRNAPheOH for the E site is 2-3 orders of magnitude lower than that for the D site.     

Aptamer redesigned tRNA is nonfunctional and degraded in cells

An RNA aptamer derived from tRNA(Gln) isolated in vitro and a rationally redesigned tRNA(Gln) were used to address the relationship between structure and function of tRNA(Gln) aminoacylation in Escherichia coli. Two mutant tRNA(Gln) sequences were studied: an aptamer that binds 26-fold tighter to glutaminyl-tRNA synthetase than wild-type tRNA(Gln) in vitro, redesigned in the variable loop, and a mutant with near-normal aminoacylation kinetics for glutamine, redesigned to contain a long variable arm. Both mutants were tested in a tRNA(Gln) knockout strain of E. coli, but neither supported knockout cell growth. It was later found that both mutant tRNAs were present in very low amounts in the cell. These results reveal the difference between in vitro and in vivo studies, demonstrating the complexities of in vivo systems that have not been replicated in vitro.     

Effect of buffer conditions on the position of tRNA on the 70 S ribosome as visualized by cryoelectron microscopy

The effect of buffer conditions on the binding position of tRNA on the Escherichia coli 70 S ribosome have been studied by means of three-dimensional (3D) cryoelectron microscopy. Either deacylated tRNAfMet or fMet-tRNAfMet were bound to the 70 S ribosomes, which were programmed with a 46-nucleotide mRNA having AUG codon in the middle, under two different buffer conditions (conventional buffer: containing Tris and higher Mg2+ concentration [10-15 mM]; and polyamine buffer: containing Hepes, lower Mg2+ concentration [6 mM], and polyamines). Difference maps, obtained by subtracting 3D maps of naked control ribosome in the corresponding buffer from the 3D maps of tRNA.ribosome complexes, reveal the distinct locations of tRNA on the ribosome. The position of deacylated tRNAfMet depends on the buffer condition used, whereas that of fMet-tRNAfMet remains the same in both buffer conditions. The acylated tRNA binds in the classical P site, whereas deacylated tRNA binds mostly in an intermediate P/E position under the conventional buffer condition and mostly in the position corresponding to the classical P site, i. e. in the P/P state, under the polyamine buffer conditions.     

Fluorine-19 nuclear magnetic resonance studies of the structure of 5-fluorouracil-substituted Escherichia coli transfer RNA

19F nuclear magnetic resonance has been used to study fully active Escherichia coli tRNA1Val in which 5-fluorouracil has replaced more than 90% of all uracil and uracil-derived modified bases. The 19F spectrum of the native tRNA contains resolved resonances for all 14 incorporated 5-fluorouracils. These are spread over a 6 ppm range, from 1.8 to 7.7 ppm downfield of the standard free 5-fluorouracil. The 19F resonances serve as sensitive monitors of tRNA conformation. Removal of magnesium or addition of NaCl produces major, reversible changes in the 19F spectrum. Most affected is the lowest field resonance (peak A) in the spectrum of the native tRNA. This shifts 2-3 ppm upfield as the Mg2+ concentration is lowered or the NaCl concentration is raised. Thermal denaturation of the tRNA results in a collapse of the spectrum to a single broad peak centered at 4.7 ppm. Study of the pH dependence of the 19F spectrum shows that five incorporated fluorouracils with 19F signals in the central, 4-5.5 ppm, region of the spectrum, peaks C, D, E, F, and H, are accessible to titration in the pH 4.5-9 range. All have pKa's close to that of free 5-fluorouridine (ca. 7.5). Evidence for a conformation change in the tRNA at mildly acidic pHs, ca. 5.5, is also presented. Four of the titratable 5-fluorouracil residues, those corresponding to peaks D, E/F, and H in the 19F spectrum of fluorine-labeled tRNAVal1, are essentially completely exposed to solvent as determined by the solvent isotope shift (SIS) on transfer of the tRNA from H2O to 2H2O. These are also the 5-fluorouracils that readily form adducts with bisulfite, a reagent that reacts preferentially with pyrimidines in single-stranded regions. On the basis of these results, resonances D, E, F, and H in the middle of the 19F spectrum are attributed to 5-fluorouracils in non-base-paired (loop) regions of the tRNA. Evidence from the ionic strength dependence of the 19F spectrum and arguments based on other recent studies with fluorinated tRNAs support earlier suggestions [Horowitz, J., Ofengand, J., Daniel, W. E., & Cohn, M. (1977) J. Biol. Chem. 252, 4418-4420] that the resonances at lowest field correspond to tertiary hydrogen-bonded 5-fluorouracils. Consideration of ring-current effects and the preferential perturbation of upfield 19F resonances by the cyclophotoaddition of 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen, which is known to react most readily with pyrimidines in double-stranded regions, permits initial assignment of upfield resonances to 5-fluorouracils in helical stems.(ABSTRACT TRUNCATED AT 400 WORDS)     

Selective inhibition of uracil tRNA methylases of E. coli by ethionine.

L-ethionine has been found to inhibit uracil tRNA methylating enzymes in vitro under conditions where methylation of other tRNA bases is unaffected. No selective inhibitor for uracil tRNA methylases has been identified previously. 15 mM L-ethionine or 30 mM D,L-ethionine caused about 40% inhibition of tRNA methylation catalyzed by enzyme extracts from E. coli B or E. coli M3S (mixtures of methylases for uracil, guanine, cytosine, and adenine) but did not inhibit the activity of preparations from an E. coli mutant that lacks uracil tRNA methylase. Analysis of the 14CH3 bases in methyl-deficient E. coli tRNA after its in vitro methylation with E. coli B3 enzymes in the presence or absence of ethionine showed that ethionine inhibited 14CH3 transfer to uracil in tRNA, but did not diminish significantly the 14CH3 transfer to other tRNA bases. Under similar conditions 0.6 mM S-adenosylethionine and 0.2 mM ethylthioadenosine inhibited the overall tRNA base methylating activity of E. coli B preparations about 50% but neither of these ethionine metabolites preferentially inhibited uracil methylation. Ethionine was not competitive with S-adenosyl methionine. Uracil methylation was not inhibited by alanine, valine, or ethionine sulfoxide. It is suggested that the thymine deficiency that we found earlier in tRNA from ethionine-treated E. coli B cells, resulted from base specific inhibition by the amino acid, ethionine, of uracil tRNA methylation in vivo.     

Expression of bovine mitochondrial tRNASer GCU derivatives in Escherichia coli.

By replacing a stretch of five A-U base pairs in the acceptor stem with G-C pairs, mitochondrial tRNA-SerGCU lacking a D arm could be expressed in Escherichia coli cells in considerable amounts. The expressed tRNA with no modified nucleoside was serylated in vitro with the mitochondrial enzyme. The tRNASerGCU derivatives carrying identity elements for alanine tRNA and the related anticodons were expressed. However, this expression event did not affect cell growth, probably because the expression started from the late log phase, which suggests that these mitochondrial tRNA derivatives are not involved in E.coli gene expression systems. Although there are some restrictions in the secondary structure of tRNAs that can be expressed by this method, it could prove useful for preparing large amounts of heterologous tRNAs in vivo.     

Allosteric interactions between the ribosomal transfer RNA-binding sites A and E

We have previously proposed a three-site model for the elongation cycle. The model is characterized by the presence of two tRNAs on the ribosome before and after translocation. We have already shown a first consequence of the model, namely that the translocation reaction is not coupled with a release of deacylated tRNA. Here we demonstrate the following conclusions. Occupation of the A site triggers the tRNA release from the E site, i.e. the A site occupation induces a drastic decrease in the affinity of the E site for deacylated tRNA. In the concentration range of deacylated tRNA in which a ribosome binds a second tRNA in addition to that one already present at the P site the deacylated tRNA does not compete for one and the same binding site with an A site ligand (AcPhe-tRNA) at 37 degrees C. It follows that the second deacylated tRNA binds to a site, the E site, which is physically distinct from the A site. When the ribosome binds a deacylated tRNA at the E site (in addition to a tRNA at the P site), the A site cannot be occupied by AcPhe-tRNA at 0 degree C and only poorly by the ternary complex elongation factor Tu . Phe-tRNA . guanyl-5'-yl imidodiphosphate. At 37 degrees C a significant A site binding is observed, with a corresponding tRNA release from the E site. In contrast, if the E site is free and only the P site occupied, the A site can bind significant amounts of charged tRNA already at 0 degree C. It follows that an occupied E site induces a low-affinity state of the A site. Thus, the ribosome always contains two high-affinity binding sites, which are A and P sites before and P and E sites after translocation. A and E sites are allosterically linked in a bidirectional manner.     

Purification of potential 3'' processing nucleases using synthetic tRNA precursors.

The synthetic tRNA precursors, tRNA-C-114C]U and tRNA-C-C-A-[14C]C-C, as well as poly (a) and diesterase-treated tRNA, have been used to identify and purify potential 3'processing nucleases. Four activities have been separated by this analysis; and three of them have been characterized. Two of the enzymes, which are well-separated on hydroxylapatite columns, act on poly(A), require K+ and Mg2+ for activity, and have molecular weights of about 90,000. These activities have properties previously ascribed to RNase II. The third enzyme does not act on poly(A), requires Mg2+ for activity, and has a molecular weight of about 60,000. It is identical to RNase D, previously characterized as an exonuclease acting on tRNAs with altered structure. Each of the enzymes can remove nucleotides from the tRNA precursor containing extra nucleotides beyond the 3'terminus, whereas they are relatively inactive with intact tRNA or tRNA-C-U. The greatest specificity was displayed by RNase D. The possibility that RNase D is a 3'processing nuclease is discussed.     

Maturation of a hypermodified nucleoside in transfer RNA.

E. coli C6 rel- met- cys- was cultured in a fully supplemented medium and in media lacking cysteine or methionine. tRNA isolated from the three cultures containted, respectively, a normal complement of modified nucleosides; a deficiency in thiolated nucleosides and a deficiency in methylated nucleosides. Both sulfur-deficient tRNA and methyl-deficient tRNA contained large amounts of N-6- (delta-2-isopentenyl) adenosine and small amounts of the 2-methylthio derivative. Methyl-deficient tRNA contained, in addition a large amount of a cytokinin active, differently modified nucleoside that is believed to be a sulfur derivative of N6-(delta-2-isopentenyl) adenosine. The structure of this compound is unknown. When methly-deficient tRNA and the precusor the tRNA-Tyr su3-+ A25 were enzymatically methylated in vitro, methyl groups were incorporated into derivatives of isopentenyladenosine. These results indicate that the biosynthesis of the 2-methylthio derivative of isopentenyladenosine may occur in a sequential manner, i.e., thiolation of isopentenyladenosine followed by methylation.     

The synthesis and functional evaluation of RNA and DNA polymers having the sequence of Escherichia coli tRNA(fMet)

Stepwise, solid-phase chemical synthesis has provided long RNA and DNA polymers related to the sequence of Escherichia coli tRNA(fMet). The 34-ribonucleotide oligomer corresponding to the sequence of the 5'-half tRNA molecule has been synthesized and then characterized by gel purification, terminal nucleotide determinations and sequence analysis. This 34-nucleotide oligomer serves as an acceptor in the RNA-ligase-catalyzed reaction with a phosphorylated 43-ribonucleotide oligomer corresponding to the sequence of the 3'-half molecule of tRNA(fMet). The DNA molecule having the sequence of tRNA(fMet) is a 76-deoxyribonucleotide oligomer with a 3'-terminal riboadenosine residue and all U residues replaced by T. These polymers have been compared with an oligodeoxyribonucleotide lacking all 2'-hydroxyl groups except for the 3'-terminal 2'-OH, an oligoribonucleotide lacking modified nucleosides and E. coli tRNA(fMet). The all-RNA 77-nucleotide oligomer can be aminoacylated by E. coli methionyl-tRNA synthetase preparation from E. coli with methionine and threonylated in the A37 position using a yeast extract. In agreement with work by Khan and Roe using tDNA(Phe) and tDNA(Lys), the rA77-DNA(fMet) can be aminoacylated, and preliminary evidence suggests that it can be threonylated to a small extent. Kinetic data support the notion that aminoacylation of tRNA(fMet) does not depend on the presence of 2'-hydroxyl groups with the exception of that in the 3'-terminal nucleotide.