Specific cleavage of target RNAs from HIV-1 with 5' half tRNA by mammalian tRNA 3' processing endoribonuclease.

Mammalian tRNA 3' processing endoribonuclease (3' tRNase) can be converted to an RNA cutter that recognizes four bases, with about a 65-nt 3'-truncated tRNA(Arg) or tRNA(Ala). The 3'-truncated tRNA recognizes the target RNA via four base pairings between the 5'terminal sequence and a sequence 1-nt upstream of the cleavage site, resulting in a pre-tRNA-like complex (Nashimoto M, 1995, Nucleic Acids Res 23:3642-3647). Here I developed a general method for more specific RNA cleavage using 3' tRNase. In the presence of a 36-nt 5' half tRNA(Arg) truncated after the anticodon, 3' tRNase cleaved the remaining 56-nt 3' half tRNA(Arg) with a 19-nt 3' trailer after the discriminator. This enzyme also cleaved its derivatives with a 5' extra sequence or nucleotide changes or deletions in the T stem-loop and extra loop regions, although the cleavage efficiency decreases as the degree of structural change increases. This suggests that any target RNA can be cleaved site-specifically by 3'tRNase in the presence of a 5' half tRNA modified to form a pre-tRNA-like complex with the target. Using this method, two partial HIV-1 RNA targets were cleaved site-specifically in vitro. These results also indicate that the sequence and structure of the T stem-loop domain are important, but not essential, for the recognition of pre-tRNAs by 3' tRNase.     

The side-by-side model of two tRNA molecules allowing the alpha-helical conformation of the nascent polypeptide during the ribosomal transpeptidation.

Lim and Spirin [25] proposed a preferable conformation of the nascent peptide during the ribosomal transpeptidation. Spirin and Lim [26] excluded the possibilities of the side-by-side model proposed by Johnson et al [13] and the three-tRNA binding model (A, P and E sites) of Rheinberger and Nierhaus [3]. However, a slight conformational change at the 3' end regions of both A and P site tRNA molecules can enable the three different tRNA binding models to converge. With a modification of the angles of the ribose rings of both anticodon and mRNA this model can also be related to the model of Sundaralingam et al [19]. In this model of E coli rRNA the 3' end sequence ACCA76 or GCCA76 of P site tRNA is base-paired to UGGU810 of 23S rRNA, while the ACC75 or GCC75 of A site tRNA are base-paired to GGU1621 23S rRNA. The conformation of the A76 of A site tRNA is necessarily different from that of P site tRNA, at least during the course of the transpeptidation. The A76 of A site tRNA overlaps the binding region of puromycin. The C1400 of 16S rRNA in this model is located at a distance of 4 A from the 5' end of the anticodon of P site tRNA [14] and 17 A from the 5' end of the anticodon of A site tRNA [15]. It is also shown that a considerable but reasonable modification in the conformation of the anticodon loops could lead to accommodation of three deacylated tRNA(Phe) molecules at a time on 70S ribosome in the presence of poly(U) as observed experimentally [6]. A sterochemical explanation for the negatively-linked allosteric interactions between the A and E sites is also shown in the present model.     

Tertiary structure of Escherichia coli tRNA(3Thr) in solution and interaction of this tRNA with the cognate threonyl-tRNA synthetase

The solution structure of Escherichia coli tRNA(3Thr) (anticodon GGU) and the residues of this tRNA in contact with the alpha 2 dimeric threonyl-tRNA synthetase were studied by chemical and enzymatic footprinting experiments. Alkylation of phosphodiester bonds by ethylnitrosourea and of N-7 positions in guanosines and N-3 positions in cytidines by dimethyl sulphate as well as carbethoxylation of N-7 positions in adenosines by diethyl pyrocarbonate were conducted on different conformers of tRNA(3Thr). The enzymatic structural probes were nuclease S1 and the cobra venom ribonuclease. Results will be compared to those of three other tRNAs, tRNA(Asp), tRNA(Phe) and tRNA(Trp), already mapped with these probes. The reactivity of phosphates towards ethylnitrosourea of the unfolded tRNA was compared to that of the native molecule. The alkylation pattern of tRNA(3Thr) shows some similarities to that of yeast tRNA(Phe) and mammalian tRNA(Trp), especially in the D-arm (positions 19 and 24) and with tRNA(Trp), at position 50, the junction between the variable region and the T-stem. In the T-loop, tRNA(3Thr), similarly to the three other tRNAs, shows protections against alkylation at phosphates 59 and 60. However, tRNA(3Thr) is unique as far as very strong protections are also found for phosphates 55 to 58 in the T-loop. Compared with yeast tRNA(Asp), the main differences in reactivity concern phosphates 19, 24 and 50. Mapping of bases with dimethyl sulphate and diethyl pyrocarbonate reveal conformational similarities with yeast tRNA(Phe). A striking conformational feature of tRNA(3Thr) is found in the 3'-side of its anticodon stem, where G40, surrounded by two G residues, is alkylated under native conditions, in contrast to other G residues in stem regions of tRNAs which are unreactive when sandwiched between two purines. This data is indicative of a perturbed helical conformation in the anticodon stem at the level of the 30-40 base pairs. Footprinting experiments, with chemical and enzymatic probes, on the tRNA complexed with its cognate threonyl-tRNA synthetase indicate significant protections in the anticodon stem and loop region, in the extra-loop, and in the amino acid accepting region. The involvement of the anticodon of tRNA(3Thr) in the recognition process with threonyl-tRNA synthetase was demonstrated by nuclease S1 mapping and by the protection of G34 and G35 against alkylation by dimethyl sulphate. These data are discussed in the light of the tRNA/synthetase recognition problem and of the structural and functional properties of the tRNA-like structure present in the operator region of the thrS mRNA.     

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).     

Cleavage of the HIV replication primer tRNALys,3 in human cells expressing bacterial anticodon nuclease.

Anticodon nuclease is a bacterial restriction enzyme directed against tRNA(Lys). We report that anticodon nuclease also cleaves mammalian tRNA(Lys) molecules, with preference and site specificity shown towards the natural substrate. Expression of the anticodon nuclease core polypeptide PrrC in HeLa cells from a recombinant vaccinia virus elicited cleavage of intracellular tRNA(Lys),3. The data justify an inquiry into the possible application of anticodon nuclease as an inhibitor of tRNA(Lys),3-primed HIV replication. They also indicate that the anticodon region of tRNA(Lys) is a substrate recognition site and suggest that PrrC harbors the enzymatic activity.     

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.     

Molecular analysis of the 16S-23S rDNA internal spacer region (ISR) and truncated tRNAAla gene segments in Campylobacter lari

Following PCR amplification and sequencing, nucleotide sequence alignment analyses demonstrated the presence of two kinds of 16S-23S rDNA internal spacer regions (ISRs), namely, long length ISRs of 837-844 base pair (bp) [n = six for urease-negative (UN) Campylobacter lari isolates, UN C. lari JCM2530(T), RM2100, 176, 293, 299 and 448] and short length ISRs of 679-725 bp [n = six for UN C. lari: n = 14 for urease-positive thermophilic Campylobacter (UPTC) isolates]. The analyses also indicated that the short length ISRs mainly lacked the 156 bp sequence from the nucleotide positions 122-277 bp in long length ISRs for UN C. lari JCM2530(T). The 156 bp sequences shared 94.9-96.8 % sequence similarity among six isolates. Surprisingly, atypical tRNA(Ala) gene segment (5' end 35 bp), which was extremely truncated, occurred within the 156 bp sequences in the long length ISRs, as an unexpected tRNA(Ala) pseudogene. An order of the intercistronic tRNA genes within the short nucleotide spacer of 5'-16S rDNA-tRNA(Ala)-tRNA(Ile)-23S rDNA-3' occurred in all the C. lari isolates examined.     

Fragmentation of 23S rRNA in strains of Proteus and Providencia results from intervening sequences in the rrn (rRNA) genes

Intervening sequences (IVSs) were originally identified in the rrl genes for 23S rRNA (rrl genes, for large ribosomal subunit, part of rrn operon encoding rRNA) of Salmonella enterica serovars Typhimurium LT2 and Arizonae. These sequences are transcribed but later removed during RNase III processing of the rRNA, resulting in fragmentation of the 23S species; IVSs are uncommon, but have been reported in at least 10 bacterial genera. Through PCR amplification of IVS-containing regions of the rrl genes we showed that most Proteus and Providencia strains contain IVSs similar to those of serovar Typhimurium in distribution and location in rrl genes. By extraction and Northern blotting of rRNA, we also found that these IVSs result in rRNA fragmentation. We report the first finding of two very different sizes of IVS (113 bp and 183 to 187 bp) in different rrl genes in the same strain, in helix 25 of Proteus and Providencia spp.; IVSs from helix 45 are 113 to 123 bp in size. Analysis of IVS sequence and postulated secondary structure reveals striking similarities of Proteus and Providencia IVSs to those of serovar Typhimurium, with the stems of the smaller IVSs from helix 25 being similar to those of Salmonella helix 25 IVSs and with both the stem and the central loop domain of helix 45 IVSs being similar. Thus, IVSs of related sequences are widely distributed throughout the Enterobacteriaceae, in Salmonella, Yersinia, Proteus, and Providencia spp., but we did not find them in Escherichia coli, Citrobacter, Enterobacter, Klebsiella, or Morganella spp.; the sporadic distribution of IVSs of related sequence indicates that lateral genetic transfer has occurred.     

Probing the anticodon loop structure in yeast tRNA(Phe-Y) with single strand-specific nuclease S1

Yeast tRNA(Phe) and tRNA(Phe-Y) are cleaved by single strand-specific endonuclease S1 at the same positions within the anticodon loop (phosphates 34, 36 and 37) and at the 3'-terminus (phosphates 75 and 76). The efficiency of the anticodon loop hydrolysis is much higher in tRNA(Phe-Y) while the cutting at the 3'-terminus is not influenced considerably by the Y-base1 removal from yeast tRNA(Phe). The effect of the Y-base excision on the structure of the anticodon loop is discussed on the basis of the S1 digestion studies as well as other relevant results.     

The effect of modification of nucleotide-37 on the interaction of aminoacyl-tRNA with the A-site of the 70S ribosome

To estimate the effect of modified nucleotide-37, the interaction of two yeast aminoacyl-tRNAs (Phe-tRNAK+YPhe and Phe-tRNAK-YPhe) with the A site of complex [70S.poly(U).deacylated tRNA(Phe) in the P site] was assayed at 0-20 degrees C. As comparisons with native Phe-tRNAK+YPhe showed, removal of the Y base decreased the association constant of Phe-tRNAK-YPhe and the complex by an order of magnitude at any temperature, and increased the enthalpy of their interaction by 23 kJ/mol. When the Y base was present in the anticodon loop of deacylated tRNA(Phe) bound to the P site of the 70S ribosome, twice higher affinity for the A site was observed for Phe-tRNAK-YPhe but not for Phe-tRNAK+YPhe. Thus, the modified nucleotide 3' of the Phe-tRNA(Phe) anticodon stabilized the codon-anticodon interaction both in the A and in the P sites of the 70S ribosome.     

Identification and characterization of an intervening sequence within the 23S ribosomal RNA genes of Edwardsiella ictaluri

Comparison of the 23S rRNA gene sequences of Edwardsiella tarda and Edw. ictaluri confirmed a close phylogenetic relationship between these two fish pathogen species and a distant relation with the 'core' members of the Enterobacteriaceae family. Analysis of the rrl gene for 23S rRNA in Edw. ictaluri revealed the presence of an intervening sequence (IVS) in helix-45. This new 98bp IVS shared 97% nucleotide identity with Salmonella typhimurium helix-45 IVS. Edw. ictaluri helix-45 IVS was present in all Edw. ictaluri strains analyzed and in at least six rrl operons within each cell. Fragmentation of 23S rRNA due to IVS excision by RNase III was observed by methylene blue staining of ribosomal RNA extracted from Edw. ictaluri isolates. This is the first report of an IVS in the 23S rRNA gene of the genus Edwardsiella.     

Determination of the nucleotide sequence of the 23S ribosomal RNA and flanking spacers of an Enterococcus faecium strain, reveals insertion-deletion events in the ribosomal spacer 1 of enterococci

The usefulness of 16S-23S (ITS1) and 23S-5S (ITS2) ribosomal spacer nucleotide sequence determination, as a complementary approach to the biochemical tests traditionally used for enterococcal species identification, is shown by its application to the identification of a strain, E27, isolated from a natural bacteria mixture used for cheese production. Using combined approaches we showed, unambiguously, that strain E27 belongs to the Enterococcus faecium species. However, its ITS1 region has an interesting peculiarity. In our previous study of ITS1s from various enterococcal species (NAIMI et al., 1997, Microbiology 143, 823-834), the ITS1s of the two E. faecium strains studied, were found to contain an additional 115-nt long stem-loop structure as compared to the ITS1s of other enterococci, only one out of the 3 ITS1s of E. hirae ATCC 9790, was found to contain a similar 107-nt long stem-loop structure. The ITS1 of strain E27 is 100% identical to that of E. faecium ATCC 19434T, except that the 115-nt additional fragment is absent. This strongly suggests the existence of lateral DNA transfer or DNA recombination events at a hot spot position of the ITS1s from E. faecium and E. hirae. Small and large ITS1 nucleotide sequence determination for strain E27 generalized the notion of two kinds of ITSs in enterococci: one with a tRNA(Ala) gene, one without tRNA gene. To complete strain E27 characterization, its 23S rRNA sequence was established. This is the first complete 23S rRNA nucleotide sequence determined for an enterococcal species.     

Interactions between 23S rRNA and tRNA in the ribosomal E site

Interactions between tRNA or its analogs and 23S rRNA in the large ribosomal subunit were analyzed by RNA footprinting and by modification-interference selection. In the E site, tRNA protected bases G2112, A2392, and C2394 of 23S rRNA. Truncated tRNA, lacking the anticodon stem-loop, protected A2392 and C2394, but not G2112, and tRNA derivatives with a shortened 3' end protected only G2112, but not A2392 or C2394. Modification interference revealed C2394 as the only accessible nucleotide in 23S rRNA whose modification interferes with binding of tRNA in the large ribosomal subunit E site. The results suggest a direct contact between A76 of tRNA A76 and C2394 of 23S rRNA. Protections at G2112 may reflect interaction of this 23S rRNA region with the tRNA central fold.     

Nucleotide sequence of three isoaccepting lysine tRNAs from rabbit liver and SV40-transformed mouse fibroblasts.

The lysine isoacceptor tRNAs differ in two aspects from the majority of the other mammalian tRNA species: they do not contain ribosylthymine (T) in loop IV, and a 'new' lysine tRNA, which is practically absent in non-dividing tissue, appears at elevated levels in proliferating cells. We have therefore purified the three major isoaccepting lysine tRNAs from rabbit liver and the 'new' lysine tRNA isolated from SV40-transformed mouse fibroblasts, and determined their nucleotide sequences. Our basic findings are as follows. a) The three major lysine tRNAs (species 1, 2 and 3) from rabbit liver contain 2'-O-methylribosylthymine (Tm) in place of T. tRNA1Lys and tRNA2Lys differ only by a single base pair in the middle of the anticodon stem; the anticodon sequence C-U-U is followed by N-threonyl-adenosine (t6A). TRNA3Lys has the anticodon S-U-U and contains two highly modified thionucleosides, S (shown to be 2-thio-5-carboxymethyl-uridine methyl ester) and a further modified derivative of t6 A (2-methyl-thio-N6-threonyl-adenosine) on the 3' side of the anticodon. tRNA3Lys differs in 14 and 16 positions, respectively, from the other two isoacceptors. b) Protein synthesis in vitro, using synthetic polynucleotides of defined sequence, showed that tRNA2Lys with anticodon C-U-U recognized A-A-G only, whereas tRNA3Lys, which contains thio-nucleotides in and next to the anticodon, decodes both lysine codons A-A-G and A-A-A, but with a preference for A-A-A. In a globin-mRNA-translating cell-free system from ascites cells, both lysine tRNAs donated lysine into globin. The rate and extent of lysine incorporation, however, was higher with tRNA2Lys than with tRNA3Lys, in agreement with the fact that alpha-globin and beta-globin mRNAs contain more A-A-G than A-A-A- codons for lysine. c) A comparison of the nucleotide sequences of lysine tRNA species 1, 2 and 3 from rabbit liver, with that of the 'new' tRNA4Lys from transformed and rapidly dividing cells showed that this tRNA is not the product of a new gene or group of genes, but is an undermodified tRNA derived exclusively from tRNA2Lys. Of the two dihydrouridines present in tRNA2Lys, one is found as U in tRNA4Lys; the purine next to the anticodon is as yet unidentified but is known not be t6 A. In addition we have found U, T and psi besides Tm as the first nucleoside in loop IV.