The primary structure of tRNA trp from brewer's yeast. I. Complete digestion with pancreatic ribonuclease and T 1 ribonuclease

Control of gag-pol gene expression in the Candida albicans retrotransposon Tca2

Background

In the C. albicans retrotransposon Tca2, the gag and pol ORFs are separated by a UGA stop codon, 3' of which is a potential RNA pseudoknot. It is unclear how the Tca2 gag UGA codon is bypassed to allow pol expression. However, in other retroelements, translational readthrough of the gag stop codon can be directed by its flanking sequence, including a 3' pseudoknot.

Results

The hypothesis was tested that in Tca2, gag stop codon flanking sequences direct translational readthrough and synthesis of a gag-pol fusion protein. Sequence from the Tca2 gag-UGA-pol junction (300 nt) was inserted between fused lacZ and luciferase (luc) genes in a Saccharomyces cerevisiae dual reporter construct. Although downstream of UGA, luc was expressed, but its expression was unaffected by inserting additional stop codons at the 3' end of lacZ. Luc expression was instead being driven by a previously unknown minor promoter activity within the gag-pol junction region. Evidence together indicated that junction sequence alone cannot direct UGA readthrough. Using reporter genes in C. albicans, the activities of this gag-pol junction promoter and the Tca2 long terminal repeat (LTR) promoter were compared. Of the two promoters, only the LTR promoter was induced by heat-shock, which also triggers retrotransposition. Tca2 pol protein, epitope-tagged in C. albicans to allow detection, was also heat-shock induced, indicating that pol proteins were expressed from a gag-UGA-pol RNA.

Conclusion

This is the first demonstration that the LTR promoter directs Tca2 pol protein expression, and that pol proteins are translated from a gag-pol RNA, which thus requires a mechanism for stop codon bypass. However, in contrast to most other retroelement and viral readthrough signals, immediate gag UGA-flanking sequences were insufficient to direct stop readthrough in S. cerevisiae, indicating non-canonical mechanisms direct gag UGA bypass in Tca2.

A previously unidentified activity of yeast and mouse RNA:pseudouridine synthases 1 (Pus1p) on tRNAs

Mouse pseudouridine synthase 1 (mPus1p) was the first vertebrate RNA:pseudouridine synthase that was cloned and characterized biochemically. The mPus1p was previously found to catalyze Psi formation at positions 27, 28, 34, and 36 in in vitro produced yeast and human tRNAs. On the other hand, the homologous Saccharomyces cerevisiae scPus1p protein was shown to modify seven uridine residues in tRNAs (26, 27, 28, 34, 36, 65, and 67) and U44 in U2 snRNA. In this work, we expressed mPus1p in yeast cells lacking scPus1p and studied modification of U2 snRNA and several yeast tRNAs. Our data showed that, in these in vivo conditions, the mouse enzyme efficiently modifies yeast U2 snRNA at position 44 and tRNAs at positions 27, 28, 34, and 36. However, a tRNA:Psi26-synthase activity of mPus1p was not observed. Furthermore, we found that both scPus1p and mPus1p, in vivo and in vitro, have a previously unidentified activity at position 1 in cytoplasmic tRNAArg(ACG). This modification can take place in mature tRNA, as well as in pre-tRNAs with 5' and/or 3' extensions. Thus, we identified the protein carrying one of the last missing yeast tRNA:Psi synthase activities. In addition, our results reveal an additional activity of mPus1p at position 30 in tRNA that scPus1p does not possess.

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).

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.

Characterization of the cDNA synthesized by avian retrovirus reverse transcriptase using 35 S avian myeloblastosis virus RNA and an exogenous bovine primer tRNA

Bovine tRNA(Trp) can be partially hybridized to the avian myeloblastosis virus (AMV) 35 S RNA at 37 degrees C, in the presence of AMV RNA-dependent DNA polymerase (reverse transcriptase). This template-primer complex is active in the synthesis of viral cDNA. The size of the cDNA products synthesized in the in vitro reconstituted AMV system was determined by urea-polyacrylamide gel electrophoresis using a tRNA labelled at the 3'-end by yeast tRNA nucleotidyl transferase. The synthesized cDNA has a size of about 100 nucleotides and was shown by Southern blotting to be complementary to a specific sequence of the 5'-end of the retroviral genome. These results indicate that reverse transcriptase is able to anneal the exogenous primer tRNA at the 'primer-binding site' near the 5'-end of the long terminal repeat (LTR) of AMV RNA.

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.

Mutual conformational changes of tryptophanyl-tRNA synthetase and tRNATrp in the course of their specific interaction

tRNATrp (beef, yeast) is capable of accelerating limited tryptic hydrolysis of the N-terminal part in the polypeptide chains of dimeric beef pancreas tryptophanyl-tRNA synthetase; it can also eliminate the protective effect of tryptophanyl adenylate on the enzyme proteolysis. The effect of tRNA on the proteolysis is manifested even when the 3'-CCA terminus is removed. It has been concluded that the conformation of the synthetase changes when it forms a complex with tRNATrp. Yeast tRNATrp lacking the 3'-half of the acceptor stem can still interact with the synthetase and, to certain extent, induces changes in the conformation of the latter. The susceptibility of single-stranded and double-stranded regions of tRNATrp to cleavage with endonucleases has been studied, and the results are indicative of the fact that, regardless of considerable differences in the nucleotide sequence of yeast and beef tRNATrp, their three-dimensional structures are similar. This fact is consistent with the finding that parameters for the interaction of these tRNAsTrp with beef tryptophanyl-tRNA synthetase are rather close. The three-dimensional structure of tRNATrp is altered when the enzyme forms a complex with it, as seen from (a) a change in the circular dichroic spectrum and (b) an elevated susceptibility of the anticodon and, apparently, acceptor stems to cleavage with nuclease. The conversion of exposed cytidine residues in tRNATrp into uridine residues results in a loss of the acceptor activity; the capability to accelerate limited tryptic hydrolysis of tryptophanyl-tRNA synthetase is also lost although the enzyme-substrate complex, as seen from circular dichroic spectra, can still be formed. The conversion of cytosine in the anticodon stem into uracil modifies the conformation of the anticodon stem. The anticodon arm (including the anticodon) and the acceptor stem play an essential role in the interaction between tRNATrp and tryptophanyl-tRNA synthetase.

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

The primary structures of three brewer's yeast tRNAs: tRNAPro2 and tRNAHis1 and 2 have been determined (Formula:see text) The U* in the anticodon U*-G-G of tRNAPro2 is probably a derivative of U; tRNAPro2 has 80 per cent homology with mammalian tRNAsPro. tRNAHis1 and tRNAHis2 differ by only 5 nucleotides; they have identical anticodons and may therefore recognize both codons for histidine; they have an additional nucleotide at the 5' end. As in all other sequenced tRNAsHis this nucleotide is not paired with the fourth nucleotide from acceptor adenosine. All three sequenced tRNAs have a low degree of homology with their counterparts from yeast mitochondria.

A rapid method for mapping exposed cytosines in polyribonucleotides. Application to tRNATrp (yeast, beef liver)

A rapid method for mapping exposed cytosine residues in 5'-[32P]-labeled RNA molecules is suggested. The exposed cytosines (C's) are converted into uracyls (U's) by bisulphite treatment at pH 5.8 in the presence of Mg2+, followed by complete modification of the residual (non-exposed) C's by a methoxyamine and bisulphite mixture at pH 5.0. The control RNA is modified only by methoxyamine and bisulphite without the preliminary C leads to U conversion. The location of the exposed C's is determined by comparing the products of partial T1, T2, A and U2 ribonuclease digestions of the C leads to U converted and control RNAs after slab gel polyacrylamide electrophoresis and autoradiography. The method has been applied for mapping exposed cytosine bases in tRNATrp (yeast) which have been found in the anti-codon loop and at the 3'-end of the molecule. In tRNATrp (beef liver), in addition to the same exposed bases, C in the diHU-loop is exposed. The data obtained are in full agreement with what is known about exposed C's for other tRNAs.

Primary structure of the nucleic acid from the 1,4-alpha-glucan branching enzyme

The primary structure of the nucleic acid from the branching enzyme 1,4-alpha-D-glucan: 1,4-alpha-D-glucan 6-alpha-(1,4-alpha-glucano)-transferase (2.5-S RNA) isolated from rabbit muscles has been elucidated. The polyribonucleotide consists of 31 nucleotides; the unique features of the polyribonucleotide are the unusually high content of modified nucleotides (32%) and guanine residues (40%). Apparently 2.5-S RNA belongs to a class of nucleic acids unknown up to now. It is the first time that the structure of a nucleic acid component from a ribonucleoenzyme has been defined. This work is a preprequisite for gaining insight into the intimate activating effect of the poly-ribonucleotide on the enzyme action.

Primary structure of bovine liver tRNATrp

Purified tRNATrp from bovine liver, accepting 1700 pmol tryptophan per A260nm unit, was completely digested with pancreatic ribonuclease and T1 ribonuclease. The sequences of the resulting oligonucleotides were determined and the primary structure of the tRNA was deduced. These analyses showed numerous incomplete post-transcriptional modifications, and several positions heterogenously occupied by two different nucleotides, which lead us to think that in bovine liver there exist a mixture of several tRNATrp.

The primary structure of rabbit, calf and bovine liver tRNAPhe

Highly purified tRNAPhe from rabbit liver, calf liver and bovine liver were completely digested with pancreatic ribonuclease and ribonuclease T1. The oligonucleotides were separated and identified. The tRNAPhe from rabbit liver and calf liver were partially cleaved with ribonuclease T1 or by action of lead acetate. We describe the analyses of the large fragments and the derivation of the primary structure of these mammalian tRNAsPhe.

[Primary structure of tRNA Thr 1a and b from brewer's yeast]

One of the two major species of brewer's yeast tRNA threonine (tRNA Thr 1) has been purified by countercurrent distribution followed by two chromatographic steps (respectively on a Sepharose 4B and a BD-cellulose column). Complete digestion with pancreatic and T1 RNases and a partial hydrolysis with T1 RNase followed by the isolation and determination of the nucleotide sequences of the resulting fragments permitted the derivation of its primary structure. tRNA Thr 1 is in fact a mixture of two subspecies differing only by a A49-U65 base pair in 50 per cent of the molecules which is replaced by a G49-C65 pair in the other 50 per cent. These two subspecies consist of 76 nucleotide residues including 14 minor nucleotides. They show a characteristic m3C at the 3'terminal end of the anticodon loop, an anticodon I-G-U followed by t6A and C48, uncompletely modified (50 per cent) to m5C within the 5 nucleotides long extra-arm. The minor nucleotides m2G m2 2G are located at positions in which they generally occur in the tRNA structures as does m1A within the T-psi-C loop.

Specific cleavages of pure tRNAs by plumbous ions

After renaturation some pure tRNAs were submitted to the action of lead acetate 1 . 10(-3) M at pH 7.3 and at 37 degrees C in the presence of either 1 M or 0.5 M NaCl. These tRNAs were specifically cleaved by Pb2+. The exact cleavage points were determined by analysing the oligonucleotides obtained from three yeast tRNAs. In 1 M NaCl, tRNA(Phe) is cleaved after the hUp17 and partially cleaved after Cp73. In 0.5 M NaCl, there are cleaveages after hUp16, hUp17 as well as a partial one after pGP1. In 1 M NaCl tRNA(Asp) is not cleaved, whereas in 0.5 M NaCl 50% of the molecules are cleaved in the anticodon region after Up35, 14% after hUp19 and 6% after hUp16. In 1 M NaCl tRNA(Val) is cleaved in the hU loop: 40% after hUp16 and 60% after CP17. The action of lead on five other pure tRNAs was studied on the analytical scale only, by polyacrylamide gel electrophoresis. They could be classified into two familites, one cleaved mainly in the hU loop, the other in the anticodon loop. The minimal concentrations of Pb2+ required for cleavage were determined for several tRNAs, the most sensitive of which, yeast tRNA(Val), being still cleaved with a concentration of 5 . 10(-6) M in 0.15 M NaCl. Although the cleavage often occurs after hUp, poly (hU) is less sensitive than poly(U). This and other results indicate that cleavages depend more on the conformation than the sequence of the polynucleotide chain, bends in the tertiary structure being lead-sensitive sites. Finally, the amino acid acceptance activities of cleaved tRNA(Phe) and tRNA(Asp) were determined.

The primary structure of tRNAIIArg from brewers' yeast. 1. Complete digestions with pancreatic and T1 ribonucleases

tRNAIIArg purified from bulk brewers' yeast tRNA by countercurrent distribution followed by two column-chromatographic steps was completely digested with pancreatic and T1 ribonucleases. Isolations of the products have been carried out either by column chromatography or by high-voltage electrophoresis. Analyses of the isolated nucleotides and olignoucleotides were in good agreement and indicate that this tRNA is composed of 76 nucltotide residues including 13 minor nucleotides. Overlaps resulting from the end-products of the two complementary digests led to a sequence of 25 residues. The primary structure of tRNAIIArg has been determined after partial digestion with T1 ribonuclease as described in the following paper.