A doubtful relationship between tyrosine tRNA and suppression of the vermilion mutant in Drosophila.

The conditions under which Drosophila melanogaster are grown markedly influence the amount of the hypermodified nucleoside Q found in certain tRNAs. This effect on Q biosynthesis was found in both the wild-type and the suppressor of sable [su(s)2] mutant. Suppressed vermilion flies [su(s)2v; bw] with 78% of the tyrosine tRNA in the Q-lacking (gamma) form had brown eyes indistinguishible from su(s)2v; bw flies with only 6% of the tyrosine tRNA in the gamma form. The proposal that this tRNA is a specific inhibitor or tryptophan pyrrolase in vermilion flies, and that its absence in su(s)2 flies is the mechanism of suppression is not consistent with these results. In addition, the su(s)2 locus does not seem to be primarily responsible for controlling Q biosynthesis as previously suggested.     

Evidence for a direct role of tRNA in an amino acid transport system.

The transport of phenylalanine by the general aromatic transport system in spheroplasts of Escherichia coli 9723 has been found to be stimulated by exogenous tRNA. Neither periodate-treated tRNA nor phenylalanine-charged tRNA stimulated, and the latter inhibited, phenylalanine uptake. Among preparations of specific tRNAs, tRNAPhe and tRNATyr were effective in stimulating the uptake of phenylalanine and tyrosine, respectively, and tRNAGlu and tRNAVal gave no detectable stimulation of phenylalanine or tyrosine transport. The preparation of tRNATyr was 10 times as active as unfractionated tRNA and gave as much as 167% stimulation of tyrosine transport. Correspondingly, the preparation of tRNAPhe was at least 3.5 times as active as the unfractionated tRNA and 2.5 times as active as the preparation of tRNATyr in stimulation of phenylalanine transport. Preliminary results in fractionation of the active component of tRNA for stimulating phenylalanine uptake show that the major activity resides in minor isoacceptor(s) tRNAPhe rather than the major component tRNAPhe, and the slight activity of preparations of tRNATyr is probably due to a contamination of the active tRNAPhe. Other preliminary results indicate that this type of stimulation occurs with uptake of other amino acids and their tRNA.     

Mechanism of suppression in Drosophila: a change in tyrosine transfer RNA

The mechanism of suppression of the vermilion locus in Drosophila melanogaster is examined. The suppressor locus, su(s)², is shown to control directly the amount of a specific tyrosine transfer RNA which occurs in the adult fly. Wild-type flies have three chromatographic forms of tyrosine tRNA but flies that are homozygous for the suppressor gene su(s)² contain little or none of the second chromatographic form. The isoacceptor patterns of tRNA for leucine, phenylalanine and serine are identical in the suppressor mutant and wild-type fly. Genetic data show that the phenotypic expression of su(s)² and the altered chromatographic pattern of tyrosine tRNA are recessive and that both map at the same position on the left tip of the X chromosome. Furthermore, another suppressor of vermilion was induced by ethyl methane sulfate, su(s)^e1, that is at the same locus as su(s)² and that produces the same change in tyrosine tRNA as su(s)².     

Isopentenyladenosine deficient tRNA from an antisuppressor mutant of Saccharomyces cerevisiae.

We have isolated a mutant of Saccharomyces cerevisiae that contains 1.5% of the normal tRNA complement of isopentenyladenosine (i6A). The mutant was characterized by the reduction in efficiency of a tyrosine inserting UAA nonsense suppressor. The chromatographic profiles of tRNATyr and tRNASer on benzoylated DEAE-cellulose are consistent with the loss of i6A by these species. Transfer RNA from the mutant exhibits 6.5% of the cytokinin biological activity expected for yeast tRNA. Transfer RNAs from the mutant that normally contain i6A accept the same levels of amino acids in vitro as the fully modified species. With the exception of i6A, the level of modified bases in unfractionated tRNA from the mutant appears to be normal. The loss of i6A apparently affects tRNA's role in protein synthesis at a step subsequent to aminoacylation.     

Presence of queuine in Drosophila melanogaster: correlation of free pool with queuosine content of tRNA and effect of mutations in pteridine metabolism.

Queuine, a modified form of 7-deazaguanine present in certain transfer RNAs, is shown to occur in Drosophila melanogaster adults in a free form and its concentration varies as a function of age, nutrition and genotype. In several, but not all mutant strains, the concentrations of queuine and the Q(+) (queuine-containing) form of tRNATyr are correlated. The bioassay employs L-M cells which respond to the presence of queuine by an increase in their Q(+)tRNAAsp that is accompanied by a decrease in the Q(-)tRNAAsp isoacceptors. The increase in Q(+)tRNATyr in Drosophila that occurs on a yeast diet is accompanied by an increase in queuine. Similarly the increase of Q(+)tRNAs with age also is accompanied by an increase in free queuine. In two mutants, brown and sepia, these correlations were either diminished or failed to occur. Indeed, the extract of both mutants inhibited the response of the L-M cells to authentic queuine. When the pteridines that occur at abnormally high levels in sepia were used at 1 x 10(-6)M, the inhibition of the L-M cell assay occurred in the order biopterin greater than pterin greater than sepiapterin. These pteridines were also inhibitory for the purified guanine:tRNA transglycosylase from rabbit but the relative effectiveness then was pterin greater than biopterin greater than sepiapterin. Pterin was competitive with guanine in the enzyme reaction with Ki = 0.9 x 10(-7)M. Also when an extract of sepia was chromatographed on Sephadex G-50, the pteridine-containing fractions only were inhibitory toward the L-M cell assay or the enzyme assay. These results indicate that free queuine occurs in Drosophila but also that certain pteridines may interfere with the incorporation of queuine into RNA.     

Mechanism of suppression in Drosophila: II. Enzymatic discrimination of wild-type and suppressor tyrosine transfer RNA

Previous studies had shown that two principle forms of tyrosine transfer RNA of Drosophila melanogaster were present in wild-type adult flies but that the second form was virtually absent in a suppressor mutant, su(s)². Current results are at variance with the previous ones, in that the suppressor mutant has significant amounts of the second form of tRNA^Tyr. A second chromatography system for separating these forms of tRNA^Tyr is described, RPC-5, and is compared to the system used previously, RPC-2. Both systems indicate that wild-type flies contain the two forms of tRNA^Tyr in a ratio of $\text{40}\text{60}$, the suppressor mutant in a ratio of $\text{60}\text{40}$. The difference between current and previous results can be attributed to the procedures used in the preparation of the enzyme that is used as a source of tyrosyl-tRNA ligase. The enzyme activity can be separated into two fractions on DEAE-cellulose chromatography. With suppressor tRNA as substrate, one enzyme fraction charges both forms of tRNA^Tyr but the second enzyme fraction charges the first form preferentially or nearly exclusively in some cases, as was seen in the previous experiments. With wild-type tRNA as substrate both enzyme fractions charge both forms of tRNA^Tyr. Storage results in the loss of the enzyme's ability to discriminate against the second form of tRNA^Tyr from the suppressor mutant, while the enzymatic activity is retained. We postulate that the su(s)⁺ locus produces an enzyme that modifies the second isoacceptor of tRNA^Tyr and that, when such modification fails to occur (as in the su(s)² mutant), the tRNA is unable to accept tyrosine from one form of tyrosyl-tRNA ligase. How the discrimination against the second isoacceptor by the ligase may be important metabolically is not apparent.     

Role of residue Glu152 in the discrimination between transfer RNAs by tyrosyl-tRNA synthetase from Bacillus stearothermophilus.

Residue Glu152 of tyrosyl-tRNA synthetase (TyrTS) from Bacillus stearothermophilus is close to phosphate groups 73 and 74 of tRNATyr in the structural model of their complex. TyrTS(E152A), a mutant synthetase carrying the change of Glu152 to Ala, was toxic when overproduced in Escherichia coli. The toxicity strongly increased with the growth temperature. It was measured by the ratios of the efficiencies with which the producing cells plated in induced or repressed conditions and at 30 degrees C or 37 degrees C. TyrTS(E152Q), TyrTS(E152D) and the wild-type synthetase were not toxic in conditions where TyrTS(E152A) was toxic. The toxicity of TyrTS(E152A) was abolished by additional mutations of the synthetase that prevent the binding of tRNATyr but not by a mutation that prevents the formation of Tyr-AMP. Because TyrTS(E152A) was active for the aminoacylation of tRNATyr, its toxicity could only be due to faulty interactions with non-cognate tRNAs, either their non-productive binding or their mischarging with tyrosine. TyrTS(E152A) and TyrTS(E152Q) mischarged tRNAPhe and tRNAVal in vitro with tyrosine unlike TyrTS(E152D) or the wild-type enzyme. Thus, several features of the side-chain in position 152 of TyrTS, including its negative charge, are important for the rejection of non-cognate tRNAs. TyrTS(E152A), TyrTS(E152D) and TyrTS(E152Q) had similar steady-state kinetics parameters for the charging of tRNATyr with tyrosine in vitro, with kcat/KM ratios improved 2.5 times relative to the wild-type synthetase. We conclude that the side-chain of residue Glu152 weakens the binding of TyrTS to tRNATyr and prevents its interaction with non-cognate tRNAs.     

The nucleotide sequences of a cytoplasmic and a chloroplast tRNATyr from Scenedesmus obliquus.

The nucleotide sequences of two species of tyrosine accepting tRNA from the eukaryotic green alga Scenedesmus obliquus have been determined. The sequence of the cytoplasmic tRNATyr is: (sequence in text) This is the first chloroplast tRNATyr species to be sequenced.     

Transfer RNATyr of melanoma tissues and cells: relevance to melanin synthesis?

The tRNA present in swine melanoma tumor tissue and normal gray skin tissue were compared by aminoacylation of the unfractionated tRNA preparations. Of the seventeen amino acids studied, seven showed differences in rate of acceptance to tRNAs from normal and tumor tissues; the tRNAs of two amino acids, tyrosine and glycine, showed dramatic three fold increases in melanoma tumor. As melanin biosynthesis proceeds from tyrosine oxidation the investigations focused on the increase in tyrosine tRNA. Kinetic analysis of tyrosine aminoacylation to normal and melanoma tRNAs revealed no differences. Analysis of the isoaccepting species of tRNATyr from normal skin and melanoma tumor tissues identified three isoacceptors; tRNATyr, represented the predominant species in normal gray skin, while tRNA2Tyr predominated in melanoma tumor tissue. The tyrosine acceptances by tRNAs from three human melanoma cell lines were analyzed and found to be variable, but isoaccepting species analysis of the tRNATyr of these three cell lines still showed a correlation between the preponderance of tRNA2Tyr and extent of tyrosine acceptance. Additionally the enzymatic activity for the oxidation of tyrosine was found to be related to tyrosine acceptance and tRNA2Tyr predominance..     

Mischarging mutants of Su+2 glutamine tRNA in E. coli. II. Amino acid specificities of the mutant tRNAs

Among the mischarging mutants isolated from strains with Su+2 glutamine tRNA, two double-mutants, A37A29 and A37C38, have been suggested to insert tryptophan at the UAG amber mutation site as determined by the suppression patterns of a set of tester mutants of bacteria and phages (Yamao et al., 1988). In this paper, we screened temperature sensitive mutants of E. coli in which the mischarging suppression was abolished even at the permissive temperature. Four such mutants were obtained and they were identified as the mutants of a structural gene for tryptophanyl-tRNA synthetase (trpS). Authentic trpS mutations, such as trpS5 or trpS18, also restricted the mischarging suppression. These results strongly support the previous prediction that the mutant tRNAs of Su+2, A37A29 and A37C38, are capable of interacting with tryptophanyl-tRNA synthetase and being misaminoacylated with tryptophan in vivo. However, in an assay to determine the specificity of the mutant glutamin tRNAs, we detected predominantly glutamine, but not any other amino acid, being inserted at an amber codon in vivo to any significant degree. We conclude that the mutant tRNAs still accept mostly glutamine, but can accept tryptophan in an extent for mischarging suppression. Since the amber suppressors of Su+7 tryptophan tRNA and the mischarging mutants of Su+3 tyrosine tRNA are charged with glutamine, structural similarity among the tRNAs for glutamine, tryptophan and tyrosine is discussed.     

Enzymatic replacement of nucleotide sequences in the D-loop of T. utilis tRNATyr and its effect on aminoacylation

An efficient method for replacement of nucleotide sequences in the D-loop of T. utilis tRNATyr has been developed. An abnormal tRNATyr lacking in tetranucleotide D16-D-Gm-G19 in its D-loop has been reconstructed by this method and shown to accept tyrosine to about 55% of the aminoacylation level observed for intact tRNATyr. This suggests that the deleted sequence itself is not essential for recognition by TyrRS but a conformational instability of the tRNA possibly caused by the disruption of tertiary interactions between the D-loop and T psi C-loop might have influenced the forward reaction rate leading to the decreased level of aminoacylation.     

Isolation of mammalian tRNAAsp and tRNATyr by lectin-Sepharose affinity column chromatography.

tRNAAsp from rabbit liver, rat liver and rat ascites hepatoma was readily isolated by concanavalin A-Sepharose (Con A-Sepharose) affinity column chromatography. tRNATyr from these sources was extensively purified by Ricinus communis lectin-Sepharose column chromatography. These results, together with the chromatographic behaviour of four tRNAs (tRNATyr, tRNAHis, tRNAAsn and tRNAAsp) on acetylated DBAE-cellulose column chromatography suggested that tRNAAsp contains a Q nucleoside species having a mannose moiety while tRNATyr contains Q nucleoside with galactose. The sugars attached in 4-position of cyclopentene diol in the Q molecule are therefore not present at random in the four tRNAs, but present only in each specific tRNA. This is the first case which shows that plant agglutinin interacts with nucleic Acid as well as polysaccharide and glycoproteins.     

Fluoresceinylthiocarbamyl-tRNATyr: a useful derivative of tRNATyr (E.coli) for physicochemical studies.

Fluoresceinylthiocarbamyl-tRNATyr (FTC-tRNATyr) is prepared from tRNATyr and fluoresceinisothiogyanate (FITC) under mildly alkaline conditions. Labelling occurs specificly at the base Q of tRNATyr. The modified tRNA is fully active in the aminoacylation assay; when aminoacylated it is recognized by the elongation factor Tu (EF-Tu). Codon-anticodon interaction, however, is severely affected by the modification.     

Queuine-containing isoacceptor of tyrosine tRNA in Drosophila melanogaster. Alteration of levels by divalent cations

Dietary cadmium causes the queuine-containing, Q(+), isoacceptors to increase relative to the guanine-containing, Q(-), ones of tRNATyr, tRNAHis and tRNAAsp of Drosophila melanogaster. Of the other divalent cations examined, Sr2+, Ni2+, Cu2+, Zn2+ and Hg2+, only Hg2+ failed to cause an increase in Q(+)tRNATyr. For these results, all pre-adult stages of the organism were spent on media containing the divalent ions. Adult flies that had developed on a normal diet also responded to divalent ions; Hg2+ as well as Cd2+, Sr2+ and Zn2+ caused an increase in Q(+)tRNATyr in 4 days. Using adult flies, the rate of the response was measured; when placed on a Cd2+-containing diet, they formed significantly more Q(+)tRNATyr within 24 h as compared to adults on a normal diet. Whether the queuine is derived from the diet or from de novo synthesis is yet to be determined. Since the metal ions represent a range of values in the 'hard-soft' classification, different sites of reaction are expected, yet for Drosophila a common result is an alteration in the ratio of Q(+) and Q(-) isoacceptors of these tRNAs. The transition to Q(+)tRNA may be an early indication of the metabolic imbalances resulting from the presence of the divalent cation.     

Deletion mutagenesis using an 'M13 splint': the N-terminal structural domain of tyrosyl-tRNA synthetase (B. stearothermophilus) catalyses the formation of tyrosyl adenylate.

The X-ray crystallographic structure of tyrosyl-tRNA synthetase (TyrTS) comprises only the N-terminal 320 amino acids of the molecule as the C-terminal 99 amino acids are poorly ordered in the crystal. A new technique, employing a single-stranded M13 splint, has been used to direct a deletion in the cloned gene of TyrTS so as to remove the disordered C-terminal region. We find that the truncated enzyme catalyses the formation of tyrosyl adenylate with unchanged Kcat and Km values and the crystallographic model must therefore include all the binding and catalytic residues involved in tyrosine activation. However, the truncated enzyme no longer binds tRNATyr or transfers tyrosine to tRNATyr. This indicates that the structural division of TyrTS is equally a functional one: the N-terminal structural domain catalyses tyrosine activation while the disordered C-terminal domain carries major determinants in tRNA binding.