Ribosomal proteins S7 and L1 are located close to the decoding site of E. coli ribosome--affinity labeling studies with modified tRNAs carrying photoreactive probes attached adjacent to the 3''-end of the anticodon.

Two photoreactive azidonitrophenyl probes have been attached to Yeast methionine elongator tRNA by chemical modification of the N6-(threoninocarbonyl)adenosine located next to the 3'-end of the anticodon. The maximum distance between the purine ring and the azido group estimated for the two probes is 16-17 and 23-24A, respectively. Binding and cross-linking of the uncharged, modified tRNAs to E. coli ribosomes have been studied with and without poly(A,U,G) as a message, under conditions directing uncharged tRNAs preferentially to the P-site. The modified tRNAs retain their binding activity and upon irradiation bind covalently to the ribosome with very high yields. Protein S7 is the major cross-linking target for both modified tRNAs, in the presence or absence of poly(A,U,G). Protein L1 and to a lesser extent proteins L33 and L27 have been found to be cross-linked with the short probe. Cross-linking to 168 rRNA reaches significant levels only in the absence of the message.     

A synthetic alanyl-initiator tRNA with initiator tRNA properties as determined by fluorescence measurements: comparison to a synthetic alanyl-elongator tRNA.

Two synthetic tRNAs have been generated that can be enzymatically aminoacylated with alanine and have AAA anticodons to recognize a poly(U) template. One of the tRNAs (tRNA(eAla/AAA)) is nearly identical to Escherichia coli elongator tRNA(Ala). The other has a sequence similar to Escherichia coli initiator tRNA(Met) (tRNA(iAla/AAA)). Although both tRNAs can be used in poly(U)-directed nonenzymatic initiation at 15 mM Mg2+, only the elongator tRNA can serve for peptide elongation and polyalanine synthesis. Only the initiator tRNA can be bound to 30S ribosomal subunits or 70S ribosomes in the presence of initiation factor 2 (IF-2) and low Mg2+ suggesting that it can function in enzymatic peptide initiation. A derivative of coumarin was covalently attached to the alpha amino group of alanine of these two Ala-tRNA species. The fluorescence spectra, quantum yield and anisotropy for the two Ala-tRNA derivatives are different when they are bound to 70S ribosomes (nonenzymatically in the presence of 15 mM Mg2+) indicating that the local environment of the probe is different. Also, the effect of erythromycin on their fluorescence is quite different, suggesting that the probes and presumably the alanine moiety to which they are covalently linked are in different positions on the ribosomes.     

In vitro selection of RNA aptamers that bind to colicin E3 and structurally resemble the decoding site of 16S ribosomal RNA

Colicin E3 is a ribonuclease that specifically cleaves at the site after A1493 of 16S rRNA in Escherichia coli ribosomes, thus inactivating translation. To analyze the interaction between colicin E3 and 16S rRNA, we used in vitro selection to isolate RNA ligands (aptamers) that bind to the C-terminal ribonuclease domain of colicin E3, from a degenerate RNA pool. Although the aptamers were not digested by colicin E3, they specifically bound to the protein (K(d) = 2-14 nM) and prevented the 16S rRNA cleavage by the C-terminal ribonuclease domain. Among these aptamers, aptamer F2-1 has a sequence similar to that of the region around the cleavage site from residue 1484 to 1506, including the decoding site, of E. coli 16S rRNA. The secondary structure of aptamer F2-1 was determined by the base pair covariation among the variants obtained by a second in vitro selection, using a doped RNA pool based on the aptamer F2-1 sequence. The sequence and structural similarities between the aptamers and 16S rRNA provide insights into the recognition of colicin E3 by this specific 16S rRNA region.     

Neighbourhood of the central fold of the tRNA molecule bound to the E. coli ribosome--affinity labeling studies with modified tRNAs carrying photoreactive probes attached to the dihydrouridine loop.

The neighbourhood of the dihydrouridine loop of tRNA molecule bound to E. coli ribosome has been studied by affinity labeling, using modified tRNAs carrying photoreactive azidonitrophenyl probes attached to the 3-(3-amino-3-carboxypropyl)-uridine located at position 20:1 of Lupin methionine elongator tRNA. The maximum distance between the pyrimidine ring and the azido group estimated for the two probes employed in this study is 10-11 A and 18-19 A, respectively. Cross-linking of the uncharged, modified tRNAs has been studied with poly(A, U, G) as a message, under conditions directing uncharged tRNAs preferentially to the ribosomal P-site. Modified tRNAs bind covalently to both ribosomal subunits with high yields upon irradiation of the respective non-covalent complexes. Proteins S7, L33 and L1 have been consistently found cross-linked to tRNAs modified with both probes, and S5 and L5 to tRNA modified with the longer probe. Surprisingly, an S5-tRNA cross-linking product is reproducibly found in a protein fraction prepared from the purified 50S subunit. Cross-linking to rRNAs is significant only for the longer probe and is stimulated 2-4 fold in the presence of poly(A,U,G). The cross-linking sites are located between nucleotides 1302 and 1398 in 16S rRNA and between nucleotides 2281 and 2358 in 23S rRNA.     

Involvement of the size and sequence of the anticodon loop in tRNA recognition by mammalian and E. coli methionyl-tRNA synthetases.

The rates of the cross-aminoacylation reactions of tRNAs(Met) catalyzed by methionyl-tRNA synthetases from various organisms suggest the occurrence of two types of tRNA(Met)/methionyl-tRNA synthetase systems. In this study, the tRNA determinants recognized by mammalian or E. coli methionyl-tRNA synthetases, which are representative members of the two types, have been examined. Like its prokaryotic counterpart, the mammalian enzyme utilizes the anticodon of tRNA as main recognition element. However, the mammalian cytoplasmic elongator tRNA(Met) species is not recognized by the bacterial synthetase, and both the initiator and elongator E. coli tRNA(Met) behave as poor substrates of the mammalian cytoplasmic synthetase. Synthetic genes encoding variants of tRNAs(Met), including the elongator one from mammals, were expressed in E. coli. tRNAs(Met) recognized by a synthetase of a given type can be converted into a substrate of an enzyme of the other type by introducing one-base substitutions in the anticodon loop or stem. In particular, a reduction of the size of the anticodon loop of cytoplasmic mammalian elongator tRNA(Met) from 9 to 7 bases, through the creation of an additional Watson-Crick pair at the bottom of the anticodon stem, makes it a substrate of the prokaryotic enzyme and decreases its ability to be methionylated by the mammalian enzyme. Moreover, enlarging the size of the anticodon loop of E. coli tRNA(Metm) from 7 to 9 bases, by disrupting the base pair at the bottom of the anticodon stem, renders the resulting tRNA a good substrate of the mammalian enzyme, while strongly altering its reaction with the prokaryotic synthetase. Finally, E. coli tRNA(Metf) can be rendered a better substrate of the mammalian enzyme by changing its U33 into a C. This modification makes the sequence of the anticodon loop of tRNA(Metf) identical to that of cytoplasmic initiator tRNA(Met).     

The nucleotide sequence of spinach chloroplast methionine elongator tRNA.

The nucleotide sequence of spinach chloroplast methionine elongator tRNA (sp. chl. tRNAm Met) has been determined. This tRNA is considerably more homologous to E. coli tRNAm Met (67% homology) than to the three known eukaryotic tRNAm Met (50-55% homology). Sp. chl. tRNAm Met, like the eight other chloroplast tRNAs sequenced, contains a methylated GG sequence in the dihydrouridine loop and lacks unusual structural features which have been found in several mitochondrial tRNAs.     

Colicin E3 is an endonuclease.

It was confirmed by polyacrylamide gel electrophoresis that isolated 16S rRNA was cleaved by the active component (protein A) or the active fragment (T2A) of colicin E3. However, the degradation was random, in contrast with the specific cleavage observed in the interaction of colicin E3 with ribosomes. Furthermore, the active component and the active fragment had low activities, and far greater amounts of these materials were required for degradation of the isolated rRNA than for ribosome inactivation. The degradation of rRNA cannot be due to contaminating ribonuclease(s), but is due to colicin E3 itself, because of the following facts. (1) Protein B of colicin E3, which specifically inhibits the ribosome-inactivating activity of colicin E3, inhibited the degradation of rRNA. (2) Protein B of colicin E2, which inhibits the action of colicin E2 but not of colicin E3, failed to inhibit the degradation of rRNA. (3) The activity appeared in the peak of protein A or fragment T2A, respectively, when they were rechromatographed on Sephadex G-75.     

Specific fragmentation of tRNA and rRNA at a 7-methylguanine residue in the presence of methylated carrier RNA

The reaction of site-specific cleavage of tRNA at a 7-methylguanine residue, including subsequent treatment with sodium borohydride and aniline [Wintermeyer, W. and Zachau, H.G. (1975) FEBS Lett. 58, 306-309], was shown to work only within a certain range of tRNA concentrations (higher than 30 microM). The Escherichia coli 16S rRNA, which contained a unique m7G (position 527), could not be split by this method when taken at any concentration. It was found that the presence of statistically methylated carrier RNA in the reaction mixture at the borohydride stage significantly stimulates site-specific fragmentation of 16S rRNA and 32P-labeled tRNAs. Direct sequencing proved that 16S rRNA and tRNA are cleaved by this procedure successfully at the m7G residue. The E. coli 16S rRNA was preparatively cleaved by the described procedure into two fragments. The 5'-terminal fragment (1-526) and the 3'-terminal fragment (528-1542) were isolated in the pure form and their secondary structure investigated by the circular dichroism method. The results of this study showed that the secondary and tertiary structures of the 5'-terminal one-third of the 16S rRNA are at least as ordered as those of intact 16S rRNA or its 3'-terminal two-thirds.     

The ribosomal environment of tRNA: crosslinks to rRNA from positions 8 and 20:1 in the central fold of tRNA located at the A, P, or E site.

The naturally occurring nucleotide 3-(3-amino-3-carboxy-propyl) uridine ("acp3U") at position 20:1 of lupin tRNAMet was coupled to a photoreactive diazirine derivative. Similarly, the 4-thiouridine at position 8 of Escherichia coli tRNAPhe was modified with an aromatic azide. Each of the derivatized tRNAs was bound to E. coli ribosomes in the presence of suitable mRNA analogues, under conditions specific for the A, P, or E sites. After photoactivation of the diazirine or azide groups, the sites of crosslinking from the tRNAs to 16S or 23S rRNA were analyzed by our standard procedures, involving a combination of ribonuclease H digestion and primer extension analysis. The crosslinked ribosomal proteins were also identified. The results for the rRNA showed a well-defined series of crosslinks to both the 16S and 23S molecules, the most pronounced being (1) an entirely A-site-specific crosslink from tRNA position 20:1 to the loop-end region (nt 877-913) of helix 38 of the 23S RNA (a region that has not so far been associated at all with tRNA binding), and (2) a largely P-site-specific crosslink from tRNA position 8 to nt 2111-2112 of the 23S RNA (nt 2112 being a position that has previously been identified in footprinting studies as belonging to the ribosomal E site). The data are compared with results from a parallel study of crosslinks from position 47 (also in the central fold of the tRNA), as well as with previously published crosslinks from the anticodon loop (positions 32, 34, and 37) and the CCA-end region (position 76, and the aminoacyl residue).     

Analysis of magnesium, europium and lead binding sites in methionine initiator and elongator tRNAs by specific metal-ion-induced cleavages

The specificity of cleavages in yeast and lupin initiator and elongator methionine tRNAs induced by magnesium, europium and lead has been analysed and compared with known patterns of yeast tRNA(Phe) hydrolysis. The strong D-loop cleavages occur in methionine elongator tRNAs at similar positions and with comparable efficiency to those found in tRNA(Phe), while the sites of weak anticodon loop cuts, identical in methionine elongator tRNAs, differ from those found in tRNA(Phe). Methionine initiator tRNAs differ from their elongator counterparts: (a) they are cleaved in the D-loop with much lower efficiency; (b) they are cleaved in the variable loop which is completely resistant to hydrolysis in elongator tRNAs; (c) cleavages in the anticodon loop are stronger in initiator tRNAs and they are located mostly at the 5' side of the loop whereas in elongator tRNAs they occur mostly at the opposite, 3' side of the loop. The distinct pattern of the anticodon loop cleavages is considered to be related to different conformations of the anticodon loop in the two types of methionine tRNAs.     

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.     

Predicting the binding affinities of misacylated tRNAs for Thermus thermophilus EF-Tu.GTP

The free energies for the binding of 20 different unmodified Escherichia coli elongator aminoacyl-tRNAs to Thermus thermophilus elongation factor Tu (EF-Tu) were determined. When combined with the binding free energies for the same tRNA bodies misacylated with either valine or phenylalanine determined previously [Asahara, H., and Uhlenbeck, O. C. (2002) Proc. Natl. Acad. Sci. U.S.A. 99, 3499-3504], these data permit the calculation of the contribution of each esterified amino acid to the total free energy of binding of the complex. The two data sets can also be used to calculate the free energy of binding of EF-Tu to any misacylated E. coli tRNA, and the values agree well with previously published experimental values. In addition, a survey of active misacylated suppressor tRNAs suggests that a minimal threshold of binding free energy for EF-Tu is required for suppression to occur.     

The spoU gene of Escherichia coli, the fourth gene of the spoT operon, is essential for tRNA (Gm18) 2'-O-methyltransferase activity.

We have evidence that the open reading frame previously denoted spoU is necessary for tRNA (Gm18) 2'-O-methyltransferase activity. The spoU gene is located in the gmk-rpoZ-spoT-spoU-recG operon at 82 minutes on the Escherichia coli chromosome. The deduced amino acid sequence of spoU shows strong similarities to previously characterized 2'-O-methyltransferases. Comparison of the nucleoside modification pattern of hydrolyzed tRNA, 16S rRNA and 23S rRNA from wild-type and spoU null mutants showed that the modified nucleoside 2'-O-methylguanosine (Gm), present in a subset of E. coli tRNAs at residue 18, is completely absent in the spoU mutant, suggesting that spoU encodes tRNA (Gm18) 2'-O-methyltransferase. Nucleoside modification of 16S and 23S rRNA was unaffected in the spoU mutant. Insertions in the downstream recG gene did not affect RNA modification. Absence of Gm18 in tRNA does not influence growth rate under the tested conditions and does not interfere with activity of the SupF amber suppressor, a suppressor tRNA that normally has the Gm18 modification. We suggest that the spoU gene be renamed trmH (tRNA methylation).     

Sequence of the gene for isoleucine tRNA1 and the surrounding region in a ribosomal RNA operon of Escherichia coli

A DNA fragment of about 2000 base pairs carrying the gene for tRNA(1) (Ile) has been cloned from a total Eco RI endonuclease digest of Escherichia coli DNA. Sequence analyses revealed that about the first 850 base pairs from one end of the fragment contain a nucleotide sequence corresponding to that in the 3'-end of 16S rRNA. The gene for tRNA(Ile) follows the 16S rRNA gene and both genes flank a spacer sequence of 68 base pairs. The spacer region contains a repeating, a hair pin and a symmetrical structure when the sequence is viewed in the single stranded form. A notable hair pin structure is also observed in the region adjacent to the 3'-end of the tRNA(1) (Ile) gene. In addition, about 850 base pairs from the other end of the DNA fragment have been found to contain the nucleotide sequence of the 5'-end of 23S rRNA. The presence of the genes for tRNA(1) (Ile), 16S and 23S rRNA and the hybridization to tRNA(1) (Ala) suggest that this cloned DNA is part of one of the E. coli rRNA operons carrying these two tRNA genes as a spacer.Images     

An anticodon change switches the identity of E. coli tRNA(mMet) from methionine to threonine.

Recent evidence indicates that the anticodon may often play a crucial role in selection of tRNAs by aminoacyl-tRNA synthetases. In order to quantitate the contribution of the anticodon to discrimination between cognate and noncognate tRNAs by E. coli threonyl-tRNA synthetase, derivatives of the E. coli elongator methionine tRNA (tRNA(mMet)) containing wild type and threonine anticodons have been synthesized in vitro and assayed for threonine acceptor activity. Substitution of the threonine anticodon GGU for the methionine anticodon CAU increased the threonine acceptor activity of tRNA(mMet) by four orders of magnitude while reducing methionine acceptor activity by an even greater amount. These results indicate that the anticodon is the major element which determines the identity of both threonine and methionine tRNAs.     

Recognition of individual procaryotic and eucaryotic transfer-ribonucleic acids by B subtilis adenine-1-methyltransferase specific for the dihydrouridine loop.

Bulk tRNA from yeast and Rat liver can be methylated in vitro with -adenosylmethionine and B, subtilis extracts. The sole product formed is 1-methyladenosine (m1A). This tRNA (adenine-1) methyltransferase converts quantitatively the 3'-terminal adenosine-residue in the dihydrouridine-loop of tRNAThr and tRNATyr from yeast into m1A. Out of 16 eucaryotic tRNAs with known sequences 6 accepted methyl groups, all at a molar ratio of 1. These tRNAs have in common an unpaired adenosine-residue at the specific site in the sequence Py-A-A+-G-G-C-m2G. Out of 12 tRNAs from E. coli 6 served as specific substrates. These E. coli tRNAs also have an unpaired adenosine-residue at the 3'-end of the D-loop. Besides restrictions in primary structure intact secondary and tertiary structure is important for recognition of the specific tRNAs by the enzyme.