Primary structure of three tRNAs from brewer's yeast: tRNAPro2, tRNAHis1 and tRNAHis2

The 2'-O-methyltransferase responsible for modification of yeast tRNA at position 4

The methylation of the ribose 2'-OH of RNA occurs widely in nature and in all stable RNAs and occurs at five positions in yeast tRNA. 2'-O-methylation of tRNA at position 4 is interesting because it occurs in the acceptor stem (which is normally undermodified), it is the only 2'-O-methylation that occurs in the middle of a duplex region in tRNA, the modification is conserved in eukaryotes, and the features of the tRNA necessary for substrate recognition are poorly defined. We show here that Saccharomyces cerevisiae ORF YOL125w (TRM13) is necessary and sufficient for 2'-O-methylation at position 4 of yeast tRNA. Biochemical analysis of the S. cerevisiae proteome shows that Trm13 copurifies with 2'-O-methylation activity, using tRNAGlyGCC as a substrate, and extracts made from a trm13-Delta strain have undetectable levels of this activity. Trm13 is necessary for activity in vivo because tRNAs isolated from a trm13-Delta strain lack the corresponding 2'-O-methylated residue for each of the three known tRNAs with this modification. Trm13 is sufficient for 2'-O-methylation at position 4 in vitro since yeast Trm13 protein purified after expression in Escherichia coli has the same activity as that produced in yeast. Trm13 protein binds substrates tRNAHis and tRNAGlyGCC with KD values of 85+/-8 and 100+/-14 nM, respectively, and has a KM for tRNAHis of 10 nM, but binds nonsubstrate tRNAs very poorly (KD>1 microM). Trm13 is conserved in eukaryotes, but there is no sequence similarity between Trm13 and other known methyltransferases.

An Efficient Mammalian Transfer RNA Target for Bleomycin

The antitumor antibiotic bleomycin has long been believed to exert its therapeutic effects at the level of DNA cleavage. Recently, evidence has been presented to suggest that RNA cleavage may also be important and that one or more transfer RNAs may be involved. To define those tRNAs that may represent important loci for the action of bleomycin, we have fractionated chicken liver tRNAs and identified those isoacceptors most susceptible to oxidative cleavage by Fe(II).BLM. Two chicken liver tRNAs, tRNA3Lys and tRNAPhe, were found to be cleaved with exceptional facility by Fe(II).BLM, and both were cleaved predominantly at U66. The cleavage of tRNA3Lys was shown to be minimally affected by physiological concentrations of Mg2+. Chicken liver tRNA3Lys is identical in sequence with human tRNA3Lys. These findings support a possible role for a critical tRNA such as tRNA3Lys in the mechanism by which bleomycin mediates its antitumor activity.

A new yeast poly(A) polymerase complex involved in RNA quality control

Eukaryotic cells contain several unconventional poly(A) polymerases in addition to the canonical enzymes responsible for the synthesis of poly(A) tails of nuclear messenger RNA precursors. The yeast protein Trf4p has been implicated in a quality control pathway that leads to the polyadenylation and subsequent exosome-mediated degradation of hypomethylated initiator tRNA^Met (tRNA_i^Met). Here we show that Trf4p is the catalytic subunit of a new poly(A) polymerase complex that contains Air1p or Air2p as potential RNA-binding subunits, as well as the putative RNA helicase Mtr4p. Comparison of native tRNA_i^Met with its in vitro transcribed unmodified counterpart revealed that the unmodified RNA was preferentially polyadenylated by affinity-purified Trf4 complex from yeast, as well as by complexes reconstituted from recombinant components. These results and additional experiments with other tRNA substrates suggested that the Trf4 complex can discriminate between native tRNAs and molecules that are incorrectly folded. Moreover, the polyadenylation activity of the Trf4 complex stimulated the degradation of unmodified tRNA_i^Met by nuclear exosome fractions in vitro. Degradation was most efficient when coupled to the polyadenylation activity of the Trf4 complex, indicating that the poly(A) tails serve as signals for the recruitment of the exosome. This polyadenylation-mediated RNA surveillance resembles the role of polyadenylation in bacterial RNA turnover.

A new molecular surveillance mechanism is uncovered in eukaryotes, in which incorrectly folded tRNAs are polyadenylated and then targeted for degradation

Structure-function relationships of the initiation complex of HIV-1 reverse transcription: the case of mutant viruses using tRNA(His) as primer

Reverse transcription of HIV-1 RNA is initiated from the 3' end of a tRNA3Lys molecule annealed to the primer binding site (PBS). An additional interaction between the anticodon loop of tRNA3Lys and a viral A-rich loop is required for efficient initiation of reverse transcription of the HIV-1 MAL isolate. In the HIV-1 HXB2 isolate, simultaneous mutations of the PBS and the A-rich loop (mutant His-AC), but not of the PBS alone (mutant His) allows the virus to stably utilize tRNA(His) as primer. However, mutant His-AC selects additional mutations during cell culture, generating successively His-AC-GAC and His-AC-AT-GAC. Here, we wanted to establish direct relationships between the evolution of these mutants in cell culture, their efficiency in initiating reverse transcription and the structure of the primer/template complexes in vitro. The initiation of reverse transcription of His and His-AC RNAs was dramatically reduced. However, His-AC-GAC RNA, which incorporated three adaptative point mutations, was reverse transcribed more efficiently than the wild type RNA. Incorporation of two additional mutations decreased the efficiency of the initiation of reverse transcription, which remained at the wild type level. Structural probing showed that even though both His-AC and His-AC-GAC RNAs can potentially interact with the anticodon loop of tRNA(His), only the latter template formed a stable interaction. Thus, our results showed that the selection of adaptative mutations by HIV-1 mutants utilizing tRNA(His) as primer was initially dictated by the efficiency of the initiation of reverse transcription, which relied on the existence of a stable interaction between the mutated A-rich loop and the anticodon loop of tRNA(His).

Efficient separation of Thermus aquaticus EF-Tu functional complexes

A new method for fast separation of the main functional complexes of the elongation factor Tu from Thermus aquaticus has been developed. Binary complexes EF-Tu * GDP and EF-Tu * GDPNP as well as the ternary complex EF-Tu * GDPNP * Leu approximately tRNA were separated from each other by means of HPLC on a hydrophobic sorbent TSK-Gel Phenyl 5PW in a reverse gradient of ammonium sulfate. This technique is suitable for monitoring EF-Tu activity, characterisation of the ratio between different EF-Tu forms in cell extracts, and isolation of individual EF-Tu complexes for structural and functional investigations. In order to illustrate the potentials of the method, we used HPLC on a TSK-Gel Phenyl 5PW matrix to determine the ratio between affinities of GDP and GDPNP for EF-Tu. We found that K(a)(GDP) is about 27 times higher than K(a)(GDPNP) at 37 degrees C, the value being close to the one reported for Thermus thermophilus EF-Tu.

Histidyl-tRNA synthetase

Histidyl-tRNA synthetase (HisRS) is responsible for the synthesis of histidyl-transfer RNA, which is essential for the incorporation of histidine into proteins. This amino acid has uniquely moderate basic properties and is an important group in many catalytic functions of enzymes. A compilation of currently known primary structures of HisRS shows that the subunits of these homo-dimeric enzymes consist of 420-550 amino acid residues. This represents a relatively short chain length among aminoacyl-tRNA synthetases (aaRS), whose peptide chain sizes range from about 300 to 1100 amino acid residues. The crystal structures of HisRS from two organisms and their complexes with histidine, histidyl-adenylate and histidinol with ATP have been solved. HisRS from Escherichia coli and Thermus thermophilus are very similar dimeric enzymes consisting of three domains: the N-terminal catalytic domain containing the six-stranded antiparallel beta-sheet and the three motifs characteristic of class II aaRS, a HisRS-specific helical domain inserted between motifs 2 and 3 that may contact the acceptor stem of the tRNA, and a C-terminal alpha/beta domain that may be involved in the recognition of the anticodon stem and loop of tRNA(His). The aminoacylation reaction follows the standard two-step mechanism. HisRS also belongs to the group of aaRS that can rapidly synthesize diadenosine tetraphosphate, a compound that is suspected to be involved in several regulatory mechanisms of cell metabolism. Many analogs of histidine have been tested for their properties as substrates or inhibitors of HisRS, leading to the elucidation of structure-activity relationships concerning configuration, importance of the carboxy and amino group, and the nature of the side chain. HisRS has been found to act as a particularly important antigen in autoimmune diseases such as rheumatic arthritis or myositis. Successful attempts have been made to identify epitopes responsible for the complexation with such auto-antibodies.

Role of post-transcriptional modifications of primer tRNALys,3 in the fidelity and efficacy of plus strand DNA transfer during HIV-1 reverse transcription

During HIV reverse transcription, (+) strand DNA synthesis is primed by an RNase H-resistant sequence, the polypurine tract, and continues as far as a 18-nt double-stranded RNA region corresponding to the 3' end of tRNALys,3 hybridized to the viral primer binding site (PBS). Before (+) strand DNA transfer, reverse transcriptase (RT) needs to unwind the double-stranded tRNA-PBS RNA in order to reverse-transcribe the 3' end of primer tRNALys,3. Since the detailed mechanism of (+) strand DNA transfer remains incompletely understood, we developed an in vitro system to closely examine this mechanism, composed of HIV 5' RNA, natural modified tRNALys,3, synthetic unmodified tRNALys,3 or oligonucleotides (RNA or DNA) complementary to the PBS, as well as the viral proteins RT and nucleocapsid protein (NCp7). Prior to (+) strand DNA transfer, RT stalls at the double-stranded tRNA-PBS RNA complex and is able to reverse-transcribe modified nucleosides of natural tRNALys,3. Modified nucleoside m1A-58 of natural tRNALys,3 is only partially effective as a stop signal, as RT can transcribe as far as the hyper-modified adenosine (ms2t6A-37) in the anticodon loop. m1A-58 is almost always transcribed into A, whereas other modified nucleosides are transcribed correctly, except for m7G-46, which is sometimes transcribed into T. In contrast, synthetic tRNALys,3, an RNA PBS primer, and a DNA PBS primer are completely reverse-transcribed. In the presence of an acceptor template, (+) strand DNA transfer is efficient only with templates containing natural tRNALys,3 or the RNA PBS primer. Sequence analysis of transfer products revealed frequent errors at the transfer site with synthetic tRNALys,3, not observed with natural tRNALys,3. Thus, modified nucleoside m1A-58, present in all retroviral tRNA primers, appears to be important for both efficacy and fidelity of (+) strand DNA transfer. We show that other factors such as the nature of the (-) PBS of the acceptor template and the RNase H activity of RT also influence the efficacy of (+) strand DNA transfer.

New sequence-specific human ribonuclease: purification and properties

A new sequence-specific RNase was isolated from human colon carcinoma T84 cells. The enzyme was purified to electrophoretical homogeneity by pH precipitation, HiTrapSP and Superdex 200 FPLC. The molecular weight of the new enzyme, which we have named RNase T84, is 19 kDa. RNase T84 is an endonuclease which generates 5'-phosphate-terminated products. The new RNase selectively cleaved the phosphodiester bonds at AU or GU steps at the 3' side of A or G and the 5' side of U. 5'AU3' or 5'GU3' is the minimal sequence required for T84 RNase activity, but the rate of cleavage depends on the sequence and/or structure context. Synthetic ribohomopolymers such as poly(A), poly(G), poly(U) and poly(C) were very poorly hydrolysed by T84 enzyme. In contrast, poly(I) and heteroribopolymers poly(A,U) and poly(A,G,U) were good substrates for the new RNase. The activity towards poly(I) was stronger in two colon carcinoma cell lines than in three other epithelial cell lines. Our results show that RNase T84 is a new sequence-specific enzyme whose gene is abundantly expressed in human colon carcinoma cell lines.

Identification of the tRNAs which up-regulate agrostin, barley RIP and PAP-S, three ribosome-inactivating proteins of plant origin

Ribosome-inactivating proteins (RIP) are RNA-N-glycosidases widely diffused in plants which depurinate ribosomal RNA at a specific universally conserved position, A4324 in rat ribosomes. A small group of RIPs (cofactor-dependent RIPs) require ATP and tRNA to reach maximal activity on isolated ribosomes. The tRNA which stimulates gelonin was identified as tRNA(Trp). The present paper reports the identification of three other tRNAs which stimulate agrostin (tRNA(Ala)), barley RIP (tRNA(Ala), tRNA(Val)) and PAP-S (tRNA(Gly)), while for tritin-S no particular stimulating tRNA emerged. The sequences of tRNA(Val) and tRNA(Gly) correspond to the already known ones (rabbit and man, respectively). The tRNA(Ala) (anticodon IGC) identifies a new isoacceptor. Only the stimulating activity of the tRNA(Ala) for agrostin approaches the specificity previously observed for the couple gelonin-tRNA(Trp).

Modified nucleotides of tRNAPro restrict interactions in the binary primer/template complex of M-MuLV

In all retroviruses, reverse transcription is primed by a cellular tRNA, which is base-paired through its 3'-terminal 18 nucleotides to a complementary sequence on the viral RNA genome termed the primer binding site (PBS). Evidence for specific primer-template interactions in addition to this standard interaction has recently been demonstrated for several retroviruses. Here, we used chemical and enzymatic probing to investigate the interactions between Moloney murine leukemia virus (M-MuLV) RNA and its natural primer tRNAPro. The existence of extended interactions was further tested by comparing the viral RNA/tRNAPro complex with simplified complexes in which viral RNA or tRNA were reduced to the 18 nt of the PBS or to the complementary tRNA sequence. These data, combined with computer modeling provide important clues on the secondary structure and three-dimensional folding of the M-MuLV RNA/tRNAPro complex. In contrast with other retroviruses, we found that the interaction between tRNAPro and the M-MuLV RNA template is restricted to the standard PBS interaction. In this binary complex, the viral RNA is highly constrained and the rest of tRNAPro is rearranged, with the exception of the anticodon arm, leading to a very compact structure. Unexpectedly, when a synthetic tRNAPro lacking the post-transcriptional modifications is substituted for the natural tRNAPro primer, the interactions between the primer and the viral RNA are extended. Hence, our data suggest that the post-transcriptional modifications of natural tRNAPro prevent additional contacts between tRNAPro and the U5 region of M-MuLV RNA.

RNA-protein interactions within the 3 ' untranslated region of vimentin mRNA

Several functions have been attributed to protein binding within the 3'untranslated region (3'UTR) of mRNA, including mRNA localization, stability, and translational repression. Vimentin is an intermediate filament protein whose 3'untranslated sequence is highly conserved between species. In order to identify sequences that might play a role in vimentin mRNA function, we synthesized32P-labeled RNA from different regions of vimentin's 3'UTR and assayed for protein binding with HeLa extracts using band shift assays. Sequences required for binding are contained within a region 61-114 nucleotides downstream of the stop codon, a region which is highly conserved from Xenopus to man. As judged by competition assays, binding is specific. Solution probing studies of 32P-labeled RNA with various nucleases and lead support a complex stem and loop structure for this region. Finally, UV cross-linking of the RNA-protein complex identifies an RNA binding protein of 46 kDa. Fractionation of a HeLa extract on a sizing column suggests that in addition to the 46 kDa protein, larger complexes containing additional protein(s) can be identified. Vimentin mRNA has been shown to be localized to the perinuclear region of the cytoplasm, possibly at sites of intermediate filament assembly. To date, all sequences required for localization of various mRNAs have been confined to the 3'UTR. Therefore, we hypothesize that this region and associated protein(s) might be important for vimentin mRNA function such as in localization.

Two step synthesis of (-) strong-stop DNA by avian and murine reverse transcriptases in vitro

Retroviral reverses transcriptases (RTs) are RNA- and DNA-dependent DNA polymerases that use a tRNA bound at the so-called primer binding site (PBS) located near the 5'end of the genomic RNA as primer. Thus, RTs must be able to accommodate both RNA and DNA in the primer strand. To test whether the natural primer confers some advantages to the priming process, we compared initiation of reverse transcription of avian and murine retroviral RNAs, using either their natural tRNA primer, tRNATrp and tRNAPro, respectively, or synthetic 18mer oligodeoxyribonucleotides (ODNs) and oligoribonucleotides (ORNs) complementary to their PBS. In both retroviral systems, the initial extension of ODNs was fast and processive. The initial extension of ORNs, tRNATrp and tRNAPro was much slower and distributive, giving rise to the transient accumulation of short pausing products. Synthesis of (-) strong-stop DNA was delayed when using ORNs and tRNAs, compared to ODNs. Even though ORNs and tRNAs were initially extended at the same rate, the short pausing products were more rapidly extended when using the tRNA primers. As a consequence, synthesis of (-) strong-stop DNA was much more efficient with tRNA primers, compared to ORNs. Taken together, these results suggest that the tRNA-primed synthesis of (-) strong-stop DNA is a two-step process, as already observed for HIV-1. The initiation mode corresponds to the initial non-processive nucleotide addition and extension of the short pausing products. It is more efficient with the natural primers than with ORNs. Initiation is followed by a more processive and unspecific elongation mode. Elongation is observed when the primer strand is DNA, i.e. when using the ODNs as primers or when the ORN and tRNA primers have been extended by a sufficient number (depending on the retroviral system) of deoxyribonucleotides.

2'-O-methyl-5-formylcytidine (f5Cm), a new modified nucleotide at the 'wobble' of two cytoplasmic tRNAs Leu (NAA) from bovine liver

The nucleotide analysis of a cytoplasmic tRNA(Leu) isolated from bovine liver revealed the presence of an unknown modified nucleotide N. The corresponding N nucleoside was isolated by different enzymatic and chromatographic protocols from a partially purified preparation of this tRNA(Leu). Its chemical characterization was determined from its chromatographic properties, UV-absorption spectroscopy and mass spectrometric measurements, as well as from those of the borohydride reduced N nucleoside and its etheno-trimethylsilyl derivative. The structure of N was established as 2'-O-methyl-5-formylcytidine (f5CM), and its reduced derivative as 2'-O-methyl-5-hydroxy-methylcytidine (om5Cm). By sequencing the bovine liver tRNA(Leu), the structure of the anticodon was determined as f5CmAA. In addition, the nucleotide sequence showed two primary structures differing only by the nucleotide 47c which is either uridine or adenosine. The two slightly differing bovine liver tRNAs-Leu(f5CmAA) are the only tRNAs so far sequenced which contain f5Cm. The role of such a modified cytidine at the first position of the anticodon is discussed in terms of decoding properties for the UUG and UUA leucine codons. Recently, precise evidence was obtained for the presence of f5Cm at the same position in tRNAs(Leu)(NAA) isolated from rabbit and lamb liver. Therefore, the 2'-O-methyl-5-formyl modification of cytidine at position 34 could be a general feature of cytoplasmic tRNAs(Leu)(NAA) in mammals.

Native bovine selenocysteine tRNA(Sec) secondary structure as probed by two plant single-strand-specific nucleases

Two single-strand-specific nucleases, discovered in plants, have been used to investigate the secondary and tertiary structures of the native bovine liver selenocysteine tRNA(Sec). To check the possible influence of nucleotide modifications on these structures, we compared the results obtained with the fully modified tRNA to the unmodified transcript prepared by in vitro T7 transcription of the Xenopus laevis tRNA(Sec) gene. We found that the structures in solution of the native tRNA(Sec) and the transcript are very similar despite some differences in accessibility to the enzymatic probes. Indeed, the modified anticodon-loop of native bovine tRNA(Sec), containing 5-methylcarboxymethyluridine (mcm5U34) and N6-isopentenyladenosine (i6A37), is less accessible to Rn nuclease than that of the transcript: the intensity of bands representing cuts at A36 and A38 is much lower as compared to those of the transcript, whereas no cuts were found at the level of i6A37 in the anticodon loop of the native molecule. Surprisingly, the variable arm of the native molecule has been found to be more susceptible to single-strand-specific nuclease action, suggesting a looser structure of the variable arm in native bovine tRNA(Sec) than in the transcript.

Binding of the HIV-1 nucleocapsid protein to the primer tRNA(3Lys), in vitro, is essentially not specific

The nucleocapsid protein NCp7 of human immunodeficiency virus, type 1, is a key component in the viral life cycle. Since, the first common step of all reported NCp7 activities corresponds to a nucleic acid-binding step, the NCp7 binding parameters to the natural primer tRNA(3Lys) were investigated. Using NCp7 intrinsic fluorescence, we found that (i) in 0.1 M NaCl, NCp7 bound noncooperatively to tRNA(3Lys) with a Kobs = 3.2 x 10(6) M-1 association constant and a n = 6 binding site size, (ii) four ionic interactions were formed in the NCp7.tRNA(3Lys) complex, and (iii) nonelectrostatic factors provided about 60% of the binding energy. These binding parameters were not significantly altered when the natural tRNA(3Lys) was replaced by either an in vitro synthetic tRNA(3Lys) transcript, the heterologous yeast tRNA(Phe) or the structurally unrelated 5 S RNA from Escherichia coli. Moreover, the environment of the intrinsic fluorescent reporters (Trp37 and Trp61) was similar in the various complexes. Finally, experiments performed at low protein concentration provide no evidence of high affinity binding sites. Taken together, our data strongly suggested an essentially nonspecific binding of NCp7 to tRNA(3Lys) and thus did not seem to support a direct role of NCp7, per se, in the selection of tRNA(3Lys) from the pool of cellular tRNAs.

Histidylation by yeast HisRS of tRNA or tRNA-like structure relies on residues -1 and 73 but is dependent on the RNA context

Residue G-1 and discriminator base C73 are the major histidine identity elements in prokaryotes. Here we evaluate the importance of these two nucleotides in yeast histidine aminoacylation identity. Deletion of G-1 in yeast tRNA(His) transcript leads to a drastic loss of histidylation specificity (about 500-fold). Mutation of discriminator base A73, common to all yeast tRNA(His) species, into G73 has a more moderate but still significant effect with a 22-fold decrease in histidylation specificity. Changes at position 36 in the anticodon loop has negligible effect on histidylation. The role of residues -1 and 73 for specific aminoacylation by yeast HisRS was further investigated by studying the histidylation capacities of seven minihelices derived from the Turnip Yellow Mosaic Virus tRNA-like structure. Changes in the nature of nucleotides -1 and 73 modulate this activity but do not suppress it. The optimal mini-substrate for HisRS presents a G.A mismatch at the position equivalent to residues G-1.A73 in yeast tRNA(His), confirms the importance of this structural feature in yeast histidine identity. The fact that the minisubstrates contain a pseudoknot in which position -1 is mimicked by an internal nucleotide from the pseudoknot highlights further the necessity of a stacking interaction of this position over the amino acid accepting branch of the tRNA during the aminoacylation process. Individual transplantation of G-1 or A73 into yeast tRNA(Asp) transcript improves the histidylation efficiency of the engineered tRNA(Asp). However, a tRNA(Asp) transcript presenting simultaneously both residues G-1 and A73 becomes a less good substrate for HisRS, suggesting the importance of the structural context and/or the presence of antideterminants for an optimal expression of these two identity elements.

Yeast serine isoacceptor tRNAs: variations of their content as a function of growth conditions and primary structure of the minor tRNA(Ser)GCU

The primary structure of Saccharomyces cerevisiae tRNA(Ser)GCU is presented (EMBL database accession No. X74268 S. cerevisiae tRNA-Ser). In addition, quantitation of the relative amounts of serine isoaccepting tRNAs in yeast grown on different media showed that the minor tRNA(Ser)GCU decreased while the major tRNA(Ser)AGA increased as the growth rate and the cellular protein content increased. The minor species, tRNA(Ser)CGA and tRNA(Ser)UGA, were not separated by our gel system, however, taken together they appeared to vary in the same way as tRNA(Ser)GCU. These data suggest a growth rate dependence of yeast tRNAs similar to that previously described for E. coli tRNAs.

Rye nuclease I as a tool for structural studies of tRNAs with large variable arms

A single-strand-specific nuclease from rye germ (Rn nuclease I) was used for secondary and tertiary structure investigations of tRNAs with large variable arms (class II tRNAs). We have studied the structure in solution of two recently sequenced tRNA(Leu): yeast tRNA(Leu)(ncm5UmAA) and bovine tRNA(Leu)(XmAA) as well as yeast tRNA(Leu)(UAG), tRNA(Leu)(m5CAA) and tRNA(Ser)(IGA). The latter is the only tRNA with a long variable arm for which the secondary and tertiary structure has already been studied by use of chemical probes and computer modelling. The data obtained in this work showed that the general model of class II tRNAs proposed by others for tRNA(Ser) can be extended to tRNAs(Leu) as well. However interesting differences in the structure of tRNAs(Leu) versus tRNA(Ser)(IGA) were also noticed. The main difference was observed in the accessibility of the variable loops to nucleolytic attack of Rn nuclease I: variable loops of all studied tRNA(Leu) species were cut by Rn nuclease I, while that of yeast tRNA(Ser)(IGA) was not. This could be due to differences in stability of the variable arms and the lengths of their loops which are 3 and 4 nucleotides in tRNA(Ser)(IGA) and tRNAs(Leu) respectively.

Structural specificity of Rn nuclease I as probed on yeast tRNA(Phe) and tRNA(Asp)

A single-strand-specific nuclease from rye germ (Rn nuclease I) was characterized as a tool for secondary and tertiary structure investigation of RNAs. To test the procedure, yeast tRNA(Phe) and tRNA(Asp) for which the tertiary structures are known, as well as the 3'-half of tRNA(Asp) were used as substrates. In tRNA(Phe) the nuclease introduced main primary cuts at positions U33 and A35 of the anticodon loop and G18 and G19 of the D loop. No primary cuts were observed within the double stranded stems. In tRNA(Asp) the main cuts occurred at positions U33, G34, U35, C36 of the anticodon loop and G18 and C20:1 positions in the D loop. No cuts were observed in the T loop in intact tRNA(Asp) but strong primary cleavages occurred at positions psi 55, C56, A57 within that loop in the absence of the tertiary interactions between T and D loops (use of 3'-half tRNA(Asp)). These results show that Rn nuclease I is specific for exposed single-stranded regions.

Use of a dot blot hybridization method for identification of pure tRNA species on different membranes

The characterization of a tRNA in purification procedures usually involves aminoacylation assays but recently, the hybridization by dot blot with specific oligonucleotides as probes has been used for the tRNA identification. We present here an optimization of a dot blot hybridization method for the tRNA detection by comparing the efficiency of eight different nylon membranes. Neutral 0.22 microns porosity membranes (Nytran, Biodine A) give the best detection efficiency when small quantities of material (less than 40 ng of tRNA) are dotted on filter; by contrast, neutral 0.45 microns porosity membranes (such as Hybond N) are the most efficient when larger quantities of tRNA are dotted on the filter. The described technique allows to detect less than 20 pg of a pure tRNA species. Its use in the identification of Saccharomyces cerevisiae initiator tRNA(Met) in counter-current distribution fractions is shown.

O-ribosyl-phosphate purine as a constant modified nucleotide located at position 64 in cytoplasmic initiator tRNAs(Met) of yeasts

The unknown modified nucleotide G*, isolated from both Schizosaccharomyces pombe and Torulopsis utilis initiator tRNAs(Met), has been identified as an O-ribosyl-(1"----2')-guanosine-5"-phosphate, called Gr(p), by means of HPLC, UV-absorption, mass spectrometry and periodate oxidation procedures. By comparison with the previously published structure of Ar(p) isolated from Saccharomyces cerevisiae initiator tRNA(Met), the (1"----2')-glycosidic bond in Gr(p) has been postulated to have a beta-spatial conformation. The modified nucleotide Gr(p) is located at position 64 in the tRNA(Met) molecules, i.e. at the same position as Ar(p). Since we have also characterized Gr(p) in Candida albicans initiator tRNA(Met), the phosphoribosylation of purine 64 can be considered as a constant nucleotide modification in the cytoplasmic initiator tRNAs(Met) of all yeast species so far sequenced. Precise evidence for the presence of Gr(p) in initiator tRNAs(Met) of several plants is also reported.

Identification and structural characterization of O-beta-ribosyl-(1"----2')-adenosine-5"-phosphate in yeast methionine initiator tRNA

We report in this paper on the complete structure determination of the modified nucleotide A*, now called Ar(p), that was previously identified in yeast methionine initiator tRNA as an isomeric form of O-ribosyl-adenosine bearing an additional phosphoryl-monoester group on its ribose2 moiety. By using the chemical procedure of periodate oxidation and subsequent beta-elimination with cyclohexylamine on mono- and dinucleotides containing Ar(p), we characterized the location of the phosphate group on the C-5" of the ribose2 moiety, and the linkage between the two riboses as a (1"----2')-glycosidic bond. Since the structural difference between phosphatase treated Ar(p) and authentic O-alpha-ribosyl-(1"----2')-adenosine from poly(ADP-Ribose) was previously assigned to an isomeric difference in the ribose2-ribose1 linkage, the (1"----2')-glycosidic bond of Ar(p) was deduced to have a beta-spatial configuration. Thus, final chemical structure for Ar(p) at the position 64 in yeast initiator tRNA(Met) has been established as O-beta-ribosyl-(1"----2')-adenosine-5"-phosphate. This nucleotide is linked by a 3',5'-phosphodiester bond to G at the position 65.

Eukaryotic tRNAs(Pro): primary structure of the anticodon loop; presence of 5-carbamoylmethyluridine or inosine as the first nucleoside of the anticodon

The modified nucleoside U*, located in the first position of the anticodon of yeast, chicken liver and bovine liver tRNA(Pro) (anticodon U*GG), has been determined by means of TLC, HPLC, ultraviolet spectrum and gas chromatography-mass spectrometry. The structure was established as 5-carbamoylmethyluridine (ncm5U). In addition, we report on the primary structures of the above-mentioned tRNAs as well as those which have the IGG anticodon. In yeast, the two tRNA(Pro) (anticodons U*GG and IGG) differ by eight nucleotides, whereas in chicken and in bovine liver, both anticodons are carried by the same 'body tRNA' with one posttranscriptional exception at position 32, where pseudouridine is associated with ncm5U (position 34) in tRNA(Pro) (U*GG) and 2'-O-methylpseudouridine is associated with inosine (position 34) in tRNA(Pro) (IGG).

Heterogeneities in vertebrate tRNAs(Trp) avian retroviruses package only as a primer the tRNA(Trp) lacking modified m2G in position 7

Bovine, rabbit and chicken tRNA(Trp) species and tRNA(Trp) packaged in avian myeloblastosis virus were separated and purified using two-dimensional gel electrophoresis and their primary structures were determined. Two major tRNA(Trp) species (1 and 2) were identified in beef and rabbit, two minor ones (3 and 4) in beef and only one minor in rabbit. Their structures differ by 4 nucleotide substitutions located in the D, S and T loops (positions 16, 47, 57 and 59). Species 3 and 4 differ from one another by only one nucleotide at position 2. Differences between tRNA(Trp) species were also observed in the extent of methylation of some nucleotides. Chicken tRNA(Trp) presents only one species similar to the mammalian type 1 tRNA(Trp). In the case of the three studies animals this tRNA could be separated into two subspecies, which differ by a post-transcriptional modification of nucleotide 7 in the acceptor stem: G or m2G. However only the nonmethylated species is used as the primer of DNA-RNA directed retrotranscription since it is only that form which was found in avian retroviruses. The methylation of G to m2G at position 7 could thus prevent the recognition of tRNA(Trp) by retroviral protein(s) responsible for the selective packaging of the primer tRNA(Trp).

Chorismic acid, a key metabolite in modification of tRNA

Chorismic acid is the common precursor for the biosynthesis of the three aromatic amino acids as well as for four vitamins. Mutants of Escherichia coli defective in any of the genes involved in the synthesis of chorismic acid are also unable to synthesize uridine 5-oxyacetic acid (cmo5U) and its methyl ester (mcmo5U). Both modified nucleosides are normally present in the wobble position of some tRNA species. Mutants defective in any of the specific pathways leading to phenylalanine, tyrosine, tryptophan, folate, enterochelin, ubiquinone, and menaquinone have normal levels of cmo5U and mcmo5U in their tRNA. The presence of shikimic acid in the growth medium restores the ability of an aroD mutant to synthesize cmo5U, while O-succinylbenzoate, which is an early intermediate in the synthesis of menaquinone, does not. Thus, chorismic acid is a key metabolite in the synthesis of these two modified nucleosides in tRNA. The absence of chorismic acid blocks the formation of cmo5U and mcmo5U at the first step, which might be the formation of 5-hydroxyuridine. This results in an unmodified U in the wobble position of tRNA(1Val) and in most of the tRNAs normally containing cmo5U and mcmo5U. Since cmo5U and mcmo5U are synthesized under anaerobic conditions, the formation of these nucleosides does not require molecular oxygen. One of the carbon atoms of the side chain, --O--CH2--COOH, originates from the methyl group of methionine. The other carbon atom does not originate directly from the C-1 pool, from the carboxyl group methionine, or from bicarbonate. This metabolic link between intermediary metabolism and translation also exists for another member of the family Enterobacteriaceae, Salmonella typhimurium, as well as for the distantly related gram-positive organism Bacillus subtilis.

Clostridium difficile toxin B: characterization and sequence of three peptides

The cytotoxin, also named toxin B, was isolated from a toxigenic strain of Clostridium difficile, purified to homogeneity and partially characterized. The purification procedure included ultrafiltration followed by anion-exchange chromatography. We noticed that a non-specific nucleic material eluted with the protein during the purification. The presence of these nucleic acids appeared to be important for the toxic activity of the protein. Some characteristics of the cytotoxin were examined, especially the amino acid composition and the sequence of three tryptic fragments.

Presence of phosphorylated O-ribosyl-adenosine in T-psi-stem of yeast methionine initiator tRNA

We report in this paper on isolation and characterization of two unknown nucleosides G* and [A*] located in the T-psi-stem of yeast methionine initiator tRNA, using the combined means of HPLC protocols, real time UV-absorption spectrum, and post-run mass spectrometry by electron impact or fast atom bombardment. The G* nucleoside in position 65 was identified as unmodified guanosine. The structure of the unknown [A*] in position 64 was characterized as an isomeric form of O-ribosyl-adenosine by comparison of its chromatographic, UV-spectral and mass spectrometric properties with those of authentic O-alpha-ribofuranosyl-(1"----2')-adenosine isolated from biosynthetic poly(adenosine diphosphate ribose). Our studies also brought evidence for the presence of a phosphorylmonoester group located on this new modified nucleoside [A*], when isolated by ion exchange chromatography from enzymic hydrolysis of yeast initiator tRNAMet without phosphatase treatment.

Completion of the rabies virus genome sequence determination: highly conserved domains among the L (polymerase) proteins of unsegmented negative-strand RNA viruses

We have now completed the rabies genome structure by the cloning and the sequencing of the entire L gene and the 5' untranscribed region. The L gene encodes a single open reading frame 2142 amino acids in length (244,206 Da) that corresponds to the viral RNA-dependent RNA polymerase. In contrast with other isofunctional proteins, the rabies polymerase exhibits a high degree of homology with the vesicular stomatitis virus polymerase, and a lesser degree, although significant, with those of Sendai virus and Newcastle disease virus, which suggests a differential evolution of the different cistrons. We have observed several strongly conserved stretches which may designate the independent functional domains of this multifunctional protein. In addition to the conservation of related transcription signals (N. Tordo et al. (1986) Proc. Natl. Acad. Sci. USA 83, 3914-3918.), this highlights the striking selective pressure on elements involved in transcription and replication mechanisms, and provides further evidence for a common ancestry of Rhabdoviridae and Paramyxoviridae families. The terminal complementarity observed in the rabies genome suggests the conservation of important genomic signals.

Distribution of isoaccepting tRNAs and codons for proline and glycine in collagenous and noncollagenous chicken tissues

The relation between codon usage and tRNA content for proline and glycine, the major constituents of collagen, was studied in two tissues: the magnum of laying hen oviduct and the leg tendons of chick embryo where collagen is produced. Although the relative contents of tRNA(GCCGly) and tRNA(IGGPro) in tendons, as compared to magnum indicate a specialization of the tRNA population for collagen synthesis, the distribution of the preponderant codons in collagen mRNA is correlated but at a lesser extent to that of their cognate tRNAs.

Evidence for the existence of an expressed minor variant tRNAPhe in yeast

Two expressed brewer's yeast tRNAsPhe, a major and a minor one, have been purified and sequenced. The major tRNAPhe corresponds to the already known tRNAPhe, whereas the minor one differs from the former in the substitution of T6-A67 by C6-G67 base pair in the "acceptor stem". The minor tRNAPhe contaminates all preparations of yeast tRNAPhe except those prepared by polyacrylamide gel electrophoresis.

Splicing of a yeast proline tRNA containing a novel suppressor mutation in the anticodon stem

The intron-containing proline tRNAUGG genes in Saccharomyces cerevisiae can mutate to suppress +1 frameshift mutations in proline codons via a G to U base substitution mutation at position 39. The mutation alters the 3' splice junction and disrupts the bottom base-pair of the anticodon stem which presumably allows the tRNA to read a four-base codon. In order to understand the mechanism of suppression and to study the splicing of suppressor pre-tRNA, we determined the sequences of the mature wild-type and mutant suppressor gene products in vivo and analyzed splicing of the corresponding pre-tRNAs in vitro. We show that a novel tRNA isolated from suppressor strains is the product of frameshift suppressor genes. Sequence analysis indicated that suppressor pre-tRNA is spliced at the same sites as wild-type pre-tRNA. The tRNA therefore contains a four-base anticodon stem and nine-base anticodon loop. Analysis of suppressor pre-tRNA in vitro revealed that endonuclease cleavage at the 3' splice junction occurred with reduced efficiency compared to wild-type. In addition, reduced accumulation of mature suppressor tRNA was observed in a combined cleavage and ligation reaction. These results suggest that cleavage at the 3' splice junction is inefficient but not abolished. The novel tRNA from suppressor strains was shown to be the functional agent of suppression by deleting the intron from a suppressor gene. The tRNA produced in vivo from this gene is identical to that of the product of an intron+ gene, indicating that the intron is not required for proper base modification. The product of the intron- gene is a more efficient suppressor than the product of an intron+ gene. One interpretation of this result is that inefficient splicing in vivo may be limiting the steady-state level of mature suppressor tRNA.

Accumulation and specific cleavage of 5S RNA in the isthmus of laying hen oviduct. Evidence for three chicken 5S RNA

RNA extracts from the isthmus of laying hen oviduct contain truncated 5S RNA molecules that were found to be shorter at their 5' terminus as compared to native 5S RNA I and II. Moreover one of the truncated species differs from 5S RNA I by the absence of the 3' end nucleotide. The truncated forms increase of about 70% the total 5S RNA (intact + truncated) in the isthmus, as compared to the other studied tissues. Furthermore 5S RNA I is heterogeneous: 25% have A instead of U at the 3' end, and some evidence was obtained for the existence of two 5S RNA I conformers.

The different intron 2 species excised in vivo from the E2A premRNA of adenovirus-2: an approach to analyse alternative splicing

In the early period of cellular infection by adenovirus 2, the E2A region gives rise to 2 major mRNA species of 2.0 and 2.3 kilobases, formed by alternative excisions of intron 2 (Gattoni et al., 1986, J. Mol. Biol. 187, 379-307). We have analysed the excision pathways of this intron. Two major intron species of 626 and 337 nucleotides, generated by the use of 2 consensus 3' splicing sites and a minor intron species of 520 nucleotides, generated by the use of another weaker 3' splicing site, are identified, the 3 species sharing a common 5' splicing site. They are detected predominantly in the lariat form. For the 2 major species we analyzed, the branched nucleotides are localized at consensus branching sequences, 26 or 25 nucleotides upstream from the 3' terminal AG. Our results confirm that the first reactions of cleavage at the 5' end of introns and branching occur in vivo as described in in vitro systems. The second predominant form of intron 2 is the linear segment, whereas the nicked lariat form which is very minor, might not be a genuine product of in vivo splicing. All intron 2 molecules show practically intact 5' and 3' terminal sequences, indicating that they are well protected against nuclease attack throughout their life. Therefore, these results indicate that the primary reaction following the excision of the lariat intron is debranching. In addition, the existence of a potential 5' splicing site contiguous to the major internal 3' splicing site raised the possibility of an elimination of the major 626 nucleotide intron in 2 cycles of excision. However, we demonstrate that intron 2 is systematically excised by a one cycle process, which is likely to represent the general rule for the production of correctly spliced mRNA.

Primary structure of leader RNA and nucleoprotein genes of the rabies genome: segmented homology with VSV

We have determined the nucleotide sequence of the 3'region of the rabies genome (PV strain). This work is a first step in a project aimed at establishing the complete primary structure. From the 3'nucleotide sequence of the RNA genome, an octadecanucleotide complementary to the 3'extremity was constructed and used to prime cDNA synthesis. Two overlapping recombinant cDNA clones hybridizing with the nucleoprotein mRNA (NmRNA) were isolated and sequenced. The 1500 first nucleotides of the rabies genome cover two transcriptional units: the leader RNA and the NmRNA which was shown to be initiated around residue 59 by S1 nuclease protection experiments. Comparison between rabies PV and CVS strains up to residue 180 suggests a rapid evolution in the leader region. Studies of the sequence relationships between the 3'regions of two Rhabdoviruses, rabies virus and Vesicular Stomatitis Virus (VSV), demonstrate that there is a segmented homology. Stretches of highly conserved amino acids possibly involved in the interaction with the RNA genome were observed in the N protein, despite a wide divergence in the remaining sequence. In addition, the high homology between the transcription start and stop signals reflects the conservation of a similar transcriptional mechanism in these two non segmented negative strand RNA viruses.

The primary structure of threonine tRNA (anticodon I-G-U) from bovine liver

The primary structure of threonine tRNA (anticodon I-G-U) from bovine liver has been determined using 32P postlabeling methods. Its nucleotide sequence is pG-G-C-C-C-U-G-U-m1G-m2G-C-U-A-G-C-D-G-G-D-C-A-A-A-G-C-m2(2)G-C-C- U-G-U-m3 C-U-I-G-U-t6A-A-A-C-A-G-G-A-G-A-D-m5C-C-U-G-G-G-U-psi-C-G-m1 A-A-U-C-C-C-A-G-C-G-G-G-G-C-m5C-U-C-C-A. The anticodon I-G-U, according to the wobble hypothesis, is expected to recognize A-C-U, A-C-C and A-C-A, 3 out of the 4 codons for threonine. However, if the original wobble hypothesis, as it has been shown recently for several yeasts and a fungus, is only restricted to U and C in the ox, it would recognize only 2 codons: A-C-C and A-C-U.

The nucleotide sequence of asparagine tRNA from brewer's yeast

The nucleotide sequence of asparagine tRNA from brewer's yeast has been determined using postlabeling methods. The primary structure is as follows: pG-A-C-U-C-C-A-U-G-m2G-C-C-A-A-G-D-D-G-G-D-D-A-A-G-G-C-m2 2G- U-G-C-G-A-C-U-G-U-U -t6A-A-psi-C-G-C-A-A-G-A-D-m5C-G-U-G-A-G-T-psi-C-A-m1A-C-C-C-U-C-A-C-U-G -G-G-G- U -C-G-C-C-A. Its anticodon G-U-U can recognize the two codons for asparagine.

Conservation of plant cytoplasmic tRNA structure. Nucleotide sequence of rape tRNAPhe

The primary structure of rape seeds tRNAPhe has been determined. It is identical to that of wheat germ, pea and barley tRNAsPhe, and of the minor tRNAPhe species of yellow lupin seeds.