tRNA(Tyr) genes of Drosophila melanogaster: expression of single-copy genes studied by S1 mapping

Differential expression of individual suppressor tRNA(Trp) gene gene family members in vitro and in vivo in the nematode Caenorhabditis elegans

Eight different amber suppressor tRNA (suptRNA) mutations in the nematode Caenorhabditis elegans have been isolated; all are derived from members of the tRNA(Trp) gene family (K. Kondo, B. Makovec, R. H. Waterston, and J. Hodgkin, J. Mol. Biol. 215:7-19, 1990). Genetic assays of suppressor activity suggested that individual tRNA genes were differentially expressed, probably in a tissue- or developmental stage-specific manner. We have now examined the expression of representative members of this gene family both in vitro, using transcription in embryonic cell extracts, and in vivo, by assaying suppression of an amber-mutated lacZ reporter gene in animals carrying different suptRNA mutations. Individual wild-type tRNA(Trp) genes and their amber-suppressing counterparts appear to be transcribed and processed identically in vitro, suggesting that the behavior of suptRNAs should reflect wild-type tRNA expression. The levels of transcription of different suptRNA genes closely parallel the extent of genetic suppression in vivo. The results suggest that differential expression of tRNA genes is most likely at the transcriptional rather than the posttranscriptional level and that 5' flanking sequences play a role in vitro, and probably in vivo as well. Using suppression of a lacZ(Am) reporter gene as a more direct assay of suptRNA activity in individual cell types, we have again observed differential expression which correlates with genetic and in vitro transcription results. This provides a model system to more extensively study the basis for differential expression of this tRNA gene family.

The tRNATyr-isoacceptors and their genes in the ciliate Tetrahymena thermophila: cytoplasmic tRNATyr has a QPsiA anticodon and is coded by multiple intron-containing genes

In the ciliated protozoa Tetrahymena thermophila introns have been detected in rRNA and mRNAs until now. We have isolated and sequenced seven tRNATyr genes from the T.thermophila nuclear genome. All of these genes contain introns of identical length and sequence. The 11 bp long intervening sequences are located 1 nt 3' to the anticodon as found in other eukaryotic nuclear tRNA genes. Tetrahymena tRNATyr genes are efficiently transcribed in HeLa cell nuclear extract. Moreover, processing and splicing occurred in HeLa as well as in wheat germ extracts, supporting the notion that Tetrahymena tRNATyr introns can be classified as authentic tRNA introns. We have also isolated cytoplasmic tRNATyr from Tetrahymena cells. This tRNATyr isoacceptor has a QPsiA anticodon and is not a UAG suppressor as shown in in vitro translation studies. Since UAG and UAA codons are used as glutamine codons in Tetrahymena macronuclear DNA, the presence of a strong natural UAG suppressor such as tRNATyr with GPsiA anticodon should cause misreading of the glutamine as tyrosine codons and the absence of the latter had thus been predicted. Furthermore we have studied the organization of tRNATyr genes in the genome of T.thermophila and have found two types of tRNATyr gene arrangement. A minimum of 12 tRNATyr genes are present as single copies in genomic DNA HindIII restriction fragments ranging in size from 0.6 to 7 kb. Additionally one cluster of tRNATyr genes consisting of six members has been detected in a 2.3 kb HindIII fragment.

Identification of new eukaryotic tRNA genes in genomic DNA databases by a multistep weight matrix analysis of transcriptional control regions

A linear method for the search of eukaryotic nuclear tRNA genes in DNA databases is described. Based on a modified version of the general weight matrix procedure, our algorithm relies on the recognition of two intragenic control regions known as A and B boxes, a transcription termination signal, and on the evaluation of the spacing between these elements. The scanning of the eukaryotic nuclear DNA database using this search algorithm correctly identified 933 of the 940 known tRNA genes (0.74% of false negatives). Thirty new potential tRNA genes were identified, and the transcriptional activity of two of them was directly verified by in vitro transcription. The total false positive rate of the algorithm was 0.014%. Structurally unusual tRNA genes, like those coding for selenocysteine tRNAs, could also be recognized using a set of rules concerning their specific properties, and one human gene coding for such tRNA was identified. Some of the newly identified tRNA genes were found in rather uncommon genomic positions: 2 in centromeric regions and 3 within introns. Furthermore, the presence of extragenically located B boxes in tRNA genes from various organisms could be detected through a specific subroutine of the standard search program.

A family of genes encoding neurotransmitter transporters

The genomic and cDNA clones of the mouse gamma-aminobutyric acid transporter were sequenced and analyzed. The genomic clone contains 12 introns including 1 intron prior to the initiator methionine. The second intron comes immediately after the stretch of amino acids that is most conserved among the neurotransmitter transporters sequenced so far. By using a probe constructed according to this conserved region, several partial genomic clones were isolated. Sequence analysis of those clones reveals not only homology to the family of neurotransmitter transporters within the reading frame but also an identical location of an exon-intron junction after the conserved region. A search of the GenBank data base (April 1991) revealed that two invertebrate genes exhibit homology to the conserved sequence of the above family. One, a Drosophila melanogaster gene, encoded the N-terminal part of a protein homologous to neurotransmitter transporters and the second was in Caenorhabditis elegans. The Drosophila gene contains an intron that starts at a position identical to the corresponding positions of all the mammalian genes of the family.

Conservatism of sites of tRNA loci among the linkage groups of several Drosophila species

The sites of seven tRNA genes (Arg-2, Lys-2, Ser-2b, Ser-7, Thr-3, Thr-4, Val-3b) were studied by in situ hybridization. 125I-labeled tRNA probes from Drosophila melanogaster were hybridized to spreads of polytene chromosomes prepared from four Drosophila species representing different evolutionary lineages (D. melanogaster, Drosophila hydei, Drosophila pseudoobscura, and Drosophila virilis). Most tRNA loci occurred on homologous chromosomal elements of all four species. In some cases the number of hybridization sites within an element varied and sites on nonhomologous elements were found. It was observed that both tRNA(2Arg) and tRNA(2Lys) hybridized to the same site on homologous elements in several species. These data suggest a limited amount of exchange among different linkage groups during the evolution of Drosophila species.

Pseudouridine modification in the tRNA(Tyr) anticodon is dependent on the presence, but independent of the size and sequence, of the intron in eucaryotic tRNA(Tyr) genes

In Saccharomyces cerevisiae, pseudouridine formation in the middle position of the tRNA(Tyr) anticodon (psi 35) is dependent on the presence of the intron in the tRNA(Tyr) gene (Johnson and Abelson, Nature 302:681-687, 1983). Drosophila melanogaster tRNA(Tyr) genes contain introns of three size classes: 20 or 21 base pairs (bp) (six genes), 48 bp (one gene), and 113 bp (one gene). As in yeast, removal of the intron led to loss of psi 35 in the anticodon when transcription was assayed in Xenopus laevis oocytes. All Drosophila intron sizes supported psi 35 formation. The same results were obtained with the homologous X. laevis tRNA(Tyr) genes containing introns of 12 or 13 bp or with a deleted intron. The introns of yeast (Nishikura and DeRobertis, J. Mol. Biol. 145:405-420, 1981), D. melanogaster, and X. laevis tRNA(Tyr) wild-type genes, while they all supported psi 35 synthesis, did not share any consensus sequences. As discussed, these results, taken together, suggest that for appropriate function the psi 35 enzyme in the X. laevis oocyte needs the presence of an unqualified intron in the tRNA gene and a tRNA(Tyr)-like structure in the unprocessed tRNA precursor.

Pseudouridine modification in the tRNA(Tyr) anticodon is dependent on the presence, but independent of the size and sequence, of the intron in eucaryotic tRNA(Tyr) genes

In Saccharomyces cerevisiae, pseudouridine formation in the middle position of the tRNA(Tyr) anticodon (psi 35) is dependent on the presence of the intron in the tRNA(Tyr) gene (Johnson and Abelson, Nature 302:681-687, 1983). Drosophila melanogaster tRNA(Tyr) genes contain introns of three size classes: 20 or 21 base pairs (bp) (six genes), 48 bp (one gene), and 113 bp (one gene). As in yeast, removal of the intron led to loss of psi 35 in the anticodon when transcription was assayed in Xenopus laevis oocytes. All Drosophila intron sizes supported psi 35 formation. The same results were obtained with the homologous X. laevis tRNA(Tyr) genes containing introns of 12 or 13 bp or with a deleted intron. The introns of yeast (Nishikura and DeRobertis, J. Mol. Biol. 145:405-420, 1981), D. melanogaster, and X. laevis tRNA(Tyr) wild-type genes, while they all supported psi 35 synthesis, did not share any consensus sequences. As discussed, these results, taken together, suggest that for appropriate function the psi 35 enzyme in the X. laevis oocyte needs the presence of an unqualified intron in the tRNA gene and a tRNA(Tyr)-like structure in the unprocessed tRNA precursor.