The initiator tRNA genes of Drosophila melanogaster: evidence for a tRNA pseudogene

Engineering tRNAs for the Ribosomal Translation of Non-proteinogenic Monomers

Ribosome-dependent protein biosynthesis is an essential cellular process mediated by transfer RNAs (tRNAs). Generally, ribosomally synthesized proteins are limited to the 22 proteinogenic amino acids (pAAs: 20 l-α-amino acids present in the standard genetic code, selenocysteine, and pyrrolysine). However, engineering tRNAs for the ribosomal incorporation of non-proteinogenic monomers (npMs) as building blocks has led to the creation of unique polypeptides with broad applications in cellular biology, material science, spectroscopy, and pharmaceuticals. Ribosomal polymerization of these engineered polypeptides presents a variety of challenges for biochemists, as translation efficiency and fidelity is often insufficient when employing npMs. In this Review, we will focus on the methodologies for engineering tRNAs to overcome these issues and explore recent advances both in vitro and in vivo. These efforts include increasing orthogonality, recruiting essential translation factors, and creation of expanded genetic codes. After our review on the biochemical optimizations of tRNAs, we provide examples of their use in genetic code manipulation, with a focus on the in vitro discovery of bioactive macrocyclic peptides containing npMs. Finally, an analysis of the current state of tRNA engineering is presented, along with existing challenges and future perspectives for the field.

Introducing multiple-gene mutations in Pleurotus ostreatus using a polycistronic tRNA and CRISPR guide RNA strategy

The white-rot fungus Pleurotus ostreatus is an agaricomycete that is frequently used in molecular genetics studies as many useful tools are applicable to the fungus. In particular, efficient gene targeting using homologous recombination and CRISPR/Cas9 enables the introduction of a mutation in the gene of interest for functional analysis. Multiple genes encoding various lignocellulose-degrading enzymes are predicted to be present in the genome; therefore, analyses of multiple-gene mutants are required to elucidate the mechanisms underlying lignocellulose degradation by P. ostreatus. Conventional tools for generating multiple-gene mutations in P. ostreatus are laborious and time-consuming. Therefore, more efficient and practical methods are needed. In this study, we introduced CRISPR/Cas9-assisted multiple-gene mutations using a polycistronic tRNA and CRISPR guide RNA approach. The frequency (triple-gene mutation in fcy1, vp2, and   62347) was only 3.3% when a tetracistronic tRNA-sgRNA containing four different sgRNAs targeting fcy1, vp2, vp3, or   62347 was expressed. It increased to 20% (triple-gene mutation in vp1, vp2, and vp3) after a tricistronic tRNA-sgRNA was expressed with replaced/modulated promoter and tRNA sequences. This study demonstrated, for the first time, the applicability of a strategy to induce multiple-gene mutations in P. ostreatus in a transformation experiment.

Efficient genome editing using tRNA promoter-driven CRISPR/Cas9 gRNA in Aspergillus niger

As a powerful tool for fast and precise genome editing, the CRISPR/Cas9 system has been applied in filamentous fungi to improve the efficiency of genome alteration. However, the method of delivering guide RNA (gRNA) remains a bottleneck in performing CRISPR mutagenesis in Aspergillus species. Here we report a gRNA transcription driven by endogenous tRNA promoters which include a tRNA gene plus 100 base pairs of upstream sequence. Co-transformation of a cas9-expressing plasmid with a linear DNA coding for gRNA demonstrated that 36 of the 37 tRNA promoters tested were able to generate the intended mutation in A. niger. When gRNA and cas9 were expressed in a single extra-chromosomal plasmid, the efficiency of gene mutation was as high as 97%. Co-transformation with DNA template for homologous recombination, the CRISPR/Cas9 system resulted ~42% efficiency of gene replacement in a strain with a functioning non-homologous end joining machinery (kusA+), and an efficiency of >90% gene replacement in a kusA- background. Our results demonstrate that tRNA promoter-mediated gRNA expressions are reliable and efficient in genome editing in A. niger.

The Levels of a Universally Conserved tRNA Modification Regulate Cell Growth

N(6)-Threonylcarbamoyl-adenosine (t(6)A) is a universal modification occurring at position 37 in nearly all tRNAs that decode A-starting codons, including the eukaryotic initiator tRNA (tRNAi (Met)). Yeast lacking central components of the t(6)A synthesis machinery, such as Tcs3p (Kae1p) or Tcs5p (Bud32p), show slow-growth phenotypes. In the present work, we show that loss of the Drosophila tcs3 homolog also leads to a severe reduction in size and demonstrate, for the first time in a non-microbe, that Tcs3 is required for t(6)A synthesis. In Drosophila and in mammals, tRNAi (Met) is a limiting factor for cell and animal growth. We report that the t(6)A-modified form of tRNAi (Met) is the actual limiting factor. We show that changing the proportion of t(6)A-modified tRNAi (Met), by expression of an un-modifiable tRNAi (Met) or changing the levels of Tcs3, regulate target of rapamycin (TOR) kinase activity and influences cell and animal growth in vivo. These findings reveal an unprecedented relationship between the translation machinery and TOR, where translation efficiency, limited by the availability of t(6)A-modified tRNA, determines growth potential in eukaryotic cells.

Pseudogenes: are they "junk" or functional DNA?

Pseudogenes have been defined as nonfunctional sequences of genomic DNA originally derived from functional genes. It is therefore assumed that all pseudogene mutations are selectively neutral and have equal probability to become fixed in the population. Rather, pseudogenes that have been suitably investigated often exhibit functional roles, such as gene expression, gene regulation, generation of genetic (antibody, antigenic, and other) diversity. Pseudogenes are involved in gene conversion or recombination with functional genes. Pseudogenes exhibit evolutionary conservation of gene sequence, reduced nucleotide variability, excess synonymous over nonsynonymous nucleotide polymorphism, and other features that are expected in genes or DNA sequences that have functional roles. We first review the Drosophila literature and then extend the discussion to the various functional features identified in the pseudogenes of other organisms. A pseudogene that has arisen by duplication or retroposition may, at first, not be subject to natural selection if the source gene remains functional. Mutant alleles that incorporate new functions may, nevertheless, be favored by natural selection and will have enhanced probability of becoming fixed in the population. We agree with the proposal that pseudogenes be considered as potogenes, i.e., DNA sequences with a potentiality for becoming new genes.

The transposable elements of the Drosophila melanogaster euchromatin: a genomics perspective

BACKGROUND

Transposable elements are found in the genomes of nearly all eukaryotes. The recent completion of the Release 3 euchromatic genomic sequence of Drosophila melanogaster by the Berkeley Drosophila Genome Project has provided precise sequence for the repetitive elements in the Drosophila euchromatin. We have used this genomic sequence to describe the euchromatic transposable elements in the sequenced strain of this species.

RESULTS

We identified 85 known and eight novel families of transposable element varying in copy number from one to 146. A total of 1,572 full and partial transposable elements were identified, comprising 3.86% of the sequence. More than two-thirds of the transposable elements are partial. The density of transposable elements increases an average of 4.7 times in the centromere-proximal regions of each of the major chromosome arms. We found that transposable elements are preferentially found outside genes; only 436 of 1,572 transposable elements are contained within the 61.4 Mb of sequence that is annotated as being transcribed. A large proportion of transposable elements is found nested within other elements of the same or different classes. Lastly, an analysis of structural variation from different families reveals distinct patterns of deletion for elements belonging to different classes.

CONCLUSIONS

This analysis represents an initial characterization of the transposable elements in the Release 3 euchromatic genomic sequence of D. melanogaster for which comparison to the transposable elements of other organisms can begin to be made. These data have been made available on the Berkeley Drosophila Genome Project website for future analyses.

Transfer RNA genes from Dictyostelium discoideum are frequently associated with repetitive elements and contain consensus boxes in their 5' and 3'-flanking regions

A total of 68 different tRNA genes from the cellular slime mold Dictyostelium discoideum have been isolated and characterized. Although these tRNA genes show features common to typical nuclear tRNA genes from other organisms, several unique characteristics are apparent: (1) the 5'-proximal flanking region is very similar for most of the tRNA genes; (2) more than 80% of the tRNA genes contain an "ex-B motif" within their 3'-flanking region, which strongly resembles characteristics of the consensus sequence of a T-stem/T-loop region (B-box) of a tRNA gene; (3) probably more than 50% of the tRNA genes in certain D. discoideum strains are associated with a retrotransposon, termed DRE (Dictyostelium repetitive element), or with a transposon, termed Tdd-3 (Transposon Dictyostelium discoideum). DRE always occurs 50 (+/- 3) nucleotides upstream and Tdd-3 always occurs 100 (+/- 20) nucleotides downstream from the tRNA gene. D. discoideum tRNA genes are organized in multicopy gene families consisting of 5 to 20 individual genes. Members of a particular gene family are identical within the mature tRNA coding region while flanking sequences are idiosyncratic.

Cleavage of tRNA within the mature tRNA sequence by the catalytic RNA of RNase P: implication for the formation of the primer tRNA fragment for reverse transcription in copia retrovirus-like particles

The retrovirus-like particles of Drosophila are intermediates of retrotransposition of the transposable element copia. In these particles, a 39-nucleotide-long fragment from the 5' region of Drosophila initiator methionine tRNA (tRNA(iMet) is used as the primer for copia minus-strand reverse transcription. To function as primer for this reverse transcription, the Drosophila tRNA(iMet) must be cleaved in vivo at the site between nucleotides 39 and 40. When a synthetic Drosophila tRNA(iMet) precursor was incubated with M1RNA, the catalytic RNA of Escherichia coli RNase P, other cleavages within the mature tRNA sequence were detected in addition to the efficient removal of the 5' leader sequence of this tRNA precursor. One of these cleavage sites is between nucleotides 39 and 40 of Drosophila tRNA(iMet). Based on this result, we propose a model for formation of the primer tRNA fragment for reverse transcription in copia retrovirus-like particles.

DNA sequence evolution of the amylase multigene family in Drosophila pseudoobscura

The alpha-Amylase locus in Drosophila pseudoobscura is a multigene family of one, two or three copies on the third chromosome. The nucleotide sequences of the three Amylase genes from a single chromosome of D. pseudoobscura are presented. The three Amylase genes differ at about 0.5% of their nucleotides. Each gene has a putative intron of 71 (Amy1) or 81 (Amy2 and Amy3) bp. In contrast, Drosophila melanogaster Amylase genes do not have an intron. The functional Amy1 gene of D. pseudoobscura differs from the Amy-p1 gene of D. melanogaster at an estimated 13.3% of the 1482 nucleotides in the coding region. The estimated rate of synonymous substitutions is 0.398 +/- 0.043, and the estimated rate of nonsynonymous substitutions is 0.068 +/- 0.008. From the sequence data we infer that Amy2 and Amy3 are more closely related to each other than either is to Amy1. From the pattern of nucleotide substitutions we reason that there is selection against synonymous substitutions within the Amy1 sequence; that there is selection against nonsynonymous substitutions within the Amy2 sequence, or that Amy2 has recently undergone a gene conversion with Amy1; and that Amy3 is nonfunctional and subject to random genetic drift.

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.

Genes, variant genes and pseudogenes of the human tRNA(Val) gene family. Expression and pre-tRNA maturation in vitro

Nine different members of the human tRNA(Val) gene family have been cloned and characterized. Only four of the genes code for one of the known tRNA(Val) isoacceptors. The remaining five genes carry mutations, which in two cases even affect the normal three-dimensional tRNA structure. Each of the genes is transcribed by polymerase III in a HeLa cell nuclear extract, but their transcription efficiencies differ by up to an order of magnitude. Conserved sequences immediately flanking the structural genes that could serve as extragenic control elements were not detected. However, short sequences in the 5' flanking region of two genes show striking similarity with sequences upstream from two Drosophila melanogaster tRNA(Val) genes. Each of the human tRNA(Val) genes has multiple, i.e. two to four, transcription initiation sites. In most cases, transcription termination is caused by oligo(T) sequences downstream from the structural genes. However, the signal sequences ATCTT and CTTCTT also serve as effective polymerase III transcription terminators. The precursors derived from the four tRNA(Val) genes coding for known isoacceptors and those derived from two mutant genes are processed first at their 3' and subsequently at their 5' ends to yield mature tRNAs. The precursor derived from a third mutant gene is incompletely maturated at its 3' end, presumably as a consequence of base-pairing between 5' and 3' flanking sequences. Finally, precursors encoded by the genes that carry mutations affecting the tRNA tertiary structure are completely resistant to 5' and 3' processing.

Initiator tRNAMet genes from the nematode Caenorhabditis elegans

Five different members of the initiator tRNAMet gene family have been isolated and characterized from the nematode Caenorhabditis elegans. All five show identical tRNA coding sequences, followed by a block of T residues associated with termination by RNA polymerase III. Nucleotide sequences flanking the tDNAs are completely divergent, except for two distinct members with identical flanking sequences, which may have arisen from a recent gene duplication event. Each tDNA is also flanked by middle-repetitive DNA, but the lack of cross-hybridization to each other suggests that these repetitive sequences have no common functional significance. The tRNAMeti genes do not appear to be closely linked to each other, although in vitro transcription reveals a putative tDNA adjacent to one member. Finally, there are large differences in the extent to which the five genes are transcribed by a homologous C. elegans cell-free extract, suggesting that flanking sequences have a significant effect on transcription by RNA polymerase III.

Primary structure and functional organization of Drosophila 1731 retrotransposon

We have determined the nucleotide sequence of the Drosophila retrotransposon 1731. 1731 is 4648 bp long and is flanked by 336 bp terminal repeats (LTRs) previously described as being reminiscent of provirus LTRs. The 1731 genome consists of two long open reading frames (ORFs 1 and 2) which slightly overlap each other. The ORF 1 and 2 present similarities with retroviral gag and pol genes respectively as shown by computer analysis. The pol gene exhibits several enzymatic activities in the following order: protease, endonuclease and reverse transcriptase. It is possible that 1731 also encompasses a ribonuclease H activity located between the endonuclease and reverse transcriptase domains. Moreover, comparison of the 1731 pol gene with the pol region of copia shows similarities extending over the protease, endonuclease and reverse transcriptase domains. We show that codon usage in the two retrotransposons is different. Finally, no ORF able to encode an env gene is detected in 1731.

Extensive microheterogeneity of serine tRNA genes from Drosophila melanogaster

The nucleotide sequences of nine genes corresponding to tRNA(Ser)4 or tRNA(Ser)7 of Drosophila melanogaster were determined. Eight of the genes compose the major tRNA(Ser)4,7 cluster at 12DE on the X chromosome, while the other is from 23E on the left arm of chromosome 2. Among the eight X-linked genes, five different, interrelated, classes of sequence were found. Four of the eight genes correspond to tRNA(Ser)4 and tRNA(Ser)7 (which are 96% homologous), two appear to result from single crossovers between tRNA(Ser)4 and tRNA(Ser)7 genes, one is an apparent double crossover product, and the last differs from a tRNA(Ser)4 gene by a single C to T transition at position 50. The single autosomal gene corresponds to tRNA(Ser)7. Comparison of a pair of genes corresponding to tRNA(Ser)4 from D. melanogaster and Drosophila simulans showed that, while gene flanking sequences may diverge considerably by accumulation of point changes, gene sequences are maintained intact. Our data indicate that recombination occurs between non-allelic tRNA(Ser) genes, and suggest that at least some recombinational events may be intergenic conversions.

Human U1 RNA pseudogenes may be generated by both DNA- and RNA-mediated mechanisms

Analysis of cloned human genomic loci homologous to the small nuclear RNA U1 established that such sequences are abundant and dispersed in the human genome and that only a fraction represent bona fide genes. The majority of genomic loci bear defective gene copies, or pseudogenes, which contain scattered base mismatches and in some cases lack the sequence corresponding to the 3' end of U1 RNA. Although all of the U1 genes examined to date are flanked by essentially identical sequences and therefore appear to comprise a single multigene family, we present evidence for the existence of at least three structurally distinct classes of U1 pseudogenes. Class I pseudogenes had considerable flanking sequence homology with the U1 gene family and were probably derived from it by a DNA-mediated event such as gene duplication. In contrast, the U1 sequence in class II and III U1 pseudogenes was flanked by single-copy genomic sequences completely unrelated to those flanking the U1 gene family; in addition, short direct repeats flanked the class III but not the class II pseudogenes. We therefore propose that both class II and III U1 pseudogenes were generated by an RNA-mediated mechanism involving the insertion of U1 sequence information into a new chromosomal locus. We also noted that two other types of repetitive DNA sequences in eucaryotes, the Alu family in vertebrates and the ribosomal DNA insertions in Drosophila, bore a striking structural resemblance to the classes of U1 pseudogenes described here and may have been created by an RNA-mediated insertion event.

Transcription factor binding is limited by the 5'-flanking regions of a Drosophila tRNAHis gene and a tRNAHis pseudogene

We determined the sequence of a Drosophila tRNA gene cluster containing a tRNAHis gene and a tRNAHis pseudogene in close proximity on the same DNA strand. The pseudogene contains eight consecutive base pairs different from the region of the bona fide gene which codes for the 3' portion of the anticodon stem of tRNAHis. The tRNAHis gene is transcribed efficiently in Drosophila Kc cell extract, whereas the pseudogene is not. The pseudogene is also a much poorer competitor than the real gene in a stable transcription complex formation assay, even though the sequence alteration in the pseudogene does not affect the sequence or spacing of the putative internal transcription control regions. Recombinant clones were constructed in which the 5'-flanking regions are exchanged. The transcription efficiencies and competitive abilities of the recombinant clones resemble those of the genes from which the 5' flank was derived; for example, the tRNAHis pseudogene with the 5'-flanking sequence of the tRNAHis gene is now efficiently transcribed. Deletion analysis of the pseudogene 5' flank failed to uncover an inhibitory element. Deletion analysis of the real gene showed very high dependence on the presence of the wild-type 5'-flanking sequence for factor binding to the internal control regions and stable complex formation. The 5'-flanking sequence of a Drosophila tRNAArg gene active in the Drosophila Kc cell extract does not restore transcriptional activity or stable complex formation. The tRNAHis gene and pseudogene behave atypically in HeLa cell extract. Both genes compete for HeLa transcription factors, but neither of them is efficiently transcribed. Removal of the 5'-flanking sequences of each gene and replacement with various sequences, including the tRNAArg gene 5' flank, does not allow increased transcription in HeLa cell extract.

Characterisation of a Dictyostelium discoideum DNA fragment coding for a putative tRNAValGUU gene. Evidence for a single transcription unit consisting of two overlapping class III genes

A genomic DNA fragment from Dictyostelium discoideum was characterized. This DNA, although 74% d(A + T)-rich, codes for a putative tRNAValGUU. The tRNAVal gene overlaps at its 5' half with another RNA polymerase III transcription unit. This RNA polymerase III transcription unit can be folded into a tRNA-like shape and is comprised of significant amounts of invariant and semi-invariant nucleotides present in all eukaryotic tRNAs. This unit contains the two promoter blocks defined for RNA polymerase III, which are homologous to recently defined promoter elements to the extent of 76-88% (A block) and 86-93% (B block) respectively [Sharp et al. (1981) Proc. Natl Acad. Sci. USA 78, 6657-6661]. Both of the overlapping class III genes are transcribed in germinal vesicle extracts prepared from Xenopus laevis oocytes as a single transcription unit, resulting in an unusually large product compared to primary transcripts of other tRNA genes. The unit is not transcribed in HeLa extracts but it competes very strongly for transcription factor(s) under the conditions of stable transcription complex formation. Although the whole unit is transcribed, it is believed that only one functional product is formed. Therefore we define the tRNA-like structure, coded for on this class III transcription unit, as a putative tRNA 'pseudogene' meaning that, although it is transcribed by RNA polymerase III, it is not likely to mature to a functional tRNA.

Drosophila melanogaster tRNAVal3b genes and their allogenes

Drosophila tRNAVal3b genes have been analyzed with respect to their nucleotide sequence and in vitro transcription efficiency. Plasmid pDt78R contains a single tRNA gene derived from the major tRNAVal3b gene cluster at chromosome band 84D. Its sequence corresponds to that of the tRNAVal3b. Two other plasmids, pDt41R and pDt48, each contain a tRNAVal3b-like gene from the minor tRNAVal3b gene cluster at chromosome bands 90BC. They contain the expected CAC anticodon, but their sequence differs from the tRNA at four positions. In homologous cell-free extracts, the tRNAVal3b variant genes in pDt41R and pDt48 are transcribed an order of magnitude more efficiently than the tRNAVal3b gene in pDt78R. However, the variant genes do not appear to contribute significantly to the in vivo tRNA pool [Larsen et al.: Mol. Gen. Genet. 185 (1982) 390-396]. We propose the term allogenes to describe families of related DNA sequences that may code for variant forms of a standard tRNA isoaccepting species.

Structure and transcription of eukaryotic tRNA genes

The availability of cloned tRNA genes and a variety of eukaryotic in vitro transcription systems allowed rapid progress during the past few years in the characterization of signals in the DNA-controlling gene transcription and in the processing of the precurser RNAs formed. This will be the subject matter discussed in this review.

Transcription factor binding is limited by the 5'-flanking regions of a Drosophila tRNAHis gene and a tRNAHis pseudogene

We determined the sequence of a Drosophila tRNA gene cluster containing a tRNAHis gene and a tRNAHis pseudogene in close proximity on the same DNA strand. The pseudogene contains eight consecutive base pairs different from the region of the bona fide gene which codes for the 3' portion of the anticodon stem of tRNAHis. The tRNAHis gene is transcribed efficiently in Drosophila Kc cell extract, whereas the pseudogene is not. The pseudogene is also a much poorer competitor than the real gene in a stable transcription complex formation assay, even though the sequence alteration in the pseudogene does not affect the sequence or spacing of the putative internal transcription control regions. Recombinant clones were constructed in which the 5'-flanking regions are exchanged. The transcription efficiencies and competitive abilities of the recombinant clones resemble those of the genes from which the 5' flank was derived; for example, the tRNAHis pseudogene with the 5'-flanking sequence of the tRNAHis gene is now efficiently transcribed. Deletion analysis of the pseudogene 5' flank failed to uncover an inhibitory element. Deletion analysis of the real gene showed very high dependence on the presence of the wild-type 5'-flanking sequence for factor binding to the internal control regions and stable complex formation. The 5'-flanking sequence of a Drosophila tRNAArg gene active in the Drosophila Kc cell extract does not restore transcriptional activity or stable complex formation. The tRNAHis gene and pseudogene behave atypically in HeLa cell extract. Both genes compete for HeLa transcription factors, but neither of them is efficiently transcribed. Removal of the 5'-flanking sequences of each gene and replacement with various sequences, including the tRNAArg gene 5' flank, does not allow increased transcription in HeLa cell extract.

Structure and evolution of mammalian tRNA genes: sequence of a mouse tRNAiMet gene, the 5'-flanking region of which is homologous to a human gene

From a recombinant lambda phage, we have determined a 317-bp sequence containing a mouse tRNAiMet gene. The coding region is precisely homologous to mammalian tRNAiMet if post-transcriptional modifications (including addition of the 3'-terminal CCA) are not considered. The gene does not contain introns and has a typical RNA polymerase III termination site in the 3'-flanking region. It is transcribed by RNA polymerase III in the HeLa cell S-100 system in vitro. Notably, the 5'-flanking region of the mouse tRNAiMet gene shares a "patchwork" pattern of homology with one of the human tRNAiMet genes of Santos and Zasloff [Cell 23 (1981) 699-710]. The 5'-flanking regions of the two genes contain strings of nucleotides, 6 to 32 bp in length, the homology of which is 76-100%. These are separated by short strings of unrelated nucleotides. This is one of the first examples of tRNA genes containing homologous 5'-flanking regions isolated from distantly related mammals. We also report a novel method for constructing deletion mutants of sequences cloned in M13 vectors.

A DNA sequence of Drosophila melanogaster with a differential telomeric distribution

A DNA sequence (8-19T) of 2.3 kilobase pairs (kb) of Drosophila melanogaster was localized by in situ hybridization to the extreme ends of polytene chromosomes and to the chromocenter. The relative abundance of this sequence at the ends of polytene chromosomes X:2L:2R:3L:3R is 1:3.4:1.9:0:2.7. This differential distribution is probably due to different copy numbers at the individual telomeric regions. Restriction enzyme analysis of genomic DNA shows that 8-19T sequences are interspersed with other sequences. The clone 8-19T, which contains most of this interspersed repetitive sequence, is itself not internally repetitive but has a complex sequence composition. Some of these sequences are transcribed into poly(A)+RNA. We suggest that the ends of Drosophila chromosomes are of a complex arrangement with some sequences common to all ends.

Molecular cloning, sequence analysis and in vitro expression of a rat tRNA gene cluster

A rat genomic DNA fragment containing a tRNA gene cluster was isolated from a lambda phage library. Hybridization and nucleotide sequence analysis revealed the presence of a 83 bp tRNALeuCUG gene and a 72 bp tRNAAspGUG gene. Both genes possessed intact coding regions and putative transcription termination signals at their respective 3' ends. In vitro transcription analysis of the two subcloned genes in a HeLa cell S-100 system demonstrated the specific synthesis of a number of RNAs by RNA polymerase III. Studies carried out in the presence of alpha-amanitin showed that the larger RNAs are precursors for the final processed transcripts of the tRNALeu and tRNAAsp genes, respectively. Further nucleotide sequence analysis of the cluster revealed the presence of tRNAGly and a tRNAGlu pseudogenes with missing areas within their coding regions which are essential for transcription by RNA polymerase III. Within the region of DNA between the tRNALeu and tRNAAsp genes is a sequence which is 65% homologous to a region of the rat B1 element. The significance of this latter structure within the gene cluster is unknown.

Structure and evolution of a mouse tRNA gene cluster encoding tRNAAsp, tRNAGly and tRNAGlu and an unlinked, solitary gene encoding tRNAAsp

We have sequenced mouse tRNA genes from two recombinant lambda phage. An 1800 bp sequence from one phage contains 3 tRNA genes, potentially encoding tRNAAsp, tRNAGly, and tRNAGlu, separated by spacer sequences of 587 bp and 436 bp, respectively. The mouse tRNA gene cluster is homologous to a rat sequence (Sekiya et al., 1981, Nucleic Acids Res. 9, 2239-2250). The mouse and rat tRNAAsp and tRNAGly coding regions are identical. The tRNAGlu coding regions differ at two positions. The flanking sequences contain 3 non-homologous areas: a c. 100 bp insertion in the first mouse spacer, short tandemly repeated sequences in the second spacers and unrelated sequences at the 3' ends of the clusters. In contrast, most of the flanking regions are homologous, consisting of strings of consecutive, identical residues (5-17 bp) separated by single base differences and short insertions/deletions. The latter are often associated with short repeats. The homology of the flanking regions is c. 75%, similar to other murine genes. The second lambda clone contains a solitary mouse tRNAAsp gene. The coding region is identical to that of the clustered tRNAAsp gene. The 5' flanking regions of the two genes contain homologous areas (10-25 bp) separated by unrelated sequences. Overall, the flanking regions of the two mouse tRNAAsp genes are less homologous than those of the mouse and rat clusters.

Characterization and nucleotide sequence of a chicken gene encoding an opal suppressor tRNA and its flanking DNA segments

A naturally occurring opal suppressor serine tRNA has been purified from chicken liver and used as a probe to isolate the corresponding gene from a library of chicken DNA in bacteriophage lambda. This minor tRNA is encoded by a single-copy gene that is not part of a tRNA gene cluster. DNA sequence analysis of the gene and its flanking DNA segments shows that the gene is encoded in an 87-base-pair segment without intervening sequences and specifies a tRNA that reads the termination codon UGA. This gene has additional nucleotides in the 5' internal promoter region but has a normal 3' internal promoter sequence and the usual termination signal.

Using iodinated single-stranded M13 probes to facilitate rapid DNA sequence analysis--nucleotide sequence of a mouse lysine tRNA gene

From a recombinant lambda phage, we have determined a 387 bp sequence containing a mouse lysine tRNA gene. The putative lys tRNA (anticodon UUU) differs from rabbit liver lys tRNA at five positions. The flanking regions of the mouse gene are not generally homologous to published human and Drosophila lys tRNA genes. However, the mouse gene contains a 14 bp region comprising 13 A-T base pairs, 30-44 bp from the 5' end of the coding region. Cognate A-T rich regions are present in human and Drosophila genes. The coding region is flanked by two 11 bp direct repeats, similar to those associated with alu family sequences. The sequence was determined by a "walking" protocol that employs, as a novel feature, iodinated single-stranded M13 probes to identify M13 subclones which contain sequences partially overlapping and contiguous to an initially determined sequence. The probes can also be used to screen lambda phage and in Southern and dot blot experiments.

Genes for tRNALys5 from Drosophila melanogaster

The sequences of two cloned genes from Drosophila which hybridize with tRNALys5 are reported. One gene, in plasmid pDt39, has a sequence which corresponds to the sequence of tRNA. The other gene, in pDt59R, differs in three nucleotides pairs. Both plasmids are transcribed in vitro with extracts of Drosophila Kc cells to give full-sized tRNA precursors with four additional nucleotides at the 5'-end as well as truncated molecules containing 35 nucleotides. This premature termination occurs in a block of four T residues within the mature coding region. Sequences flanking the tRNA genes show little in common except for the blocks of five or more T-residues beyond the 3'-end of the gene. pDt39 hybridizes to 84AB on the polytene chromosomes of Drosophila and pDt59R hybridizes to 29A.

The minimum intragenic sequences required for promotion of eukaryotic tRNA gene transcription

Transcription of eukaryotic tRNA genes is controlled by two intragenic regions, the D-control region (which in the tRNA codes for the D-stem and -loop) and the T-control region (which in the tRNA codes for the T psi C loop). To determine whether these sequences alone are sufficient to promote tRNA gene transcription in vitro, the two control regions of a Drosophila tRNAArg gene were cloned separately from the context of the parental DNA (these constructions are called tRNA minigenes). The tRNA minigene that contains both intragenic control regions supports in vitro RNA synthesis in Xenopus laevis oocyte and HeLa cell transcription systems. The mutant which has deletions to nucleotide 7 within the mature tRNA coding region, pArg5.7, and minigenes derived from it do not support RNA synthesis in a Drosophila Kc cell transcription system. Xenopus and Hela extracts transcribe pArg5.7 albeit at reduced levels compared to the wild-type gene. The tRNA minigene that contained only the D-control region was not able to support RNA synthesis in any of these three transcription systems. A mutant tRNA gene comprising the 3' half of the tRNAArg gene similarly was not able to support RNA synthesis. These experiments show that the DNA sequence from nucleotides 7-58, which contains both intragenic control regions of the tRNA gene, possesses sufficient information to initiate specific transcription by RNA polymerase III in Xenopus and HeLa systems. The transcription efficiency of this tRNA minigene however is reduced to about 20% the transcription level of the wild type tRNA gene. This lowered level of transcriptional efficiency results from deleting the ends of the native tRNA gene and its adjacent flanking sequences. The affects of deleting 5' sequences are most pronounced in the Drosophila transcription system.

Isolation and nucleotide sequence of a mouse histidine tRNA gene

We have sequenced a 1307 base pair mouse genomic DNA fragment which contains a histidine tRNA gene. The sequence of the putative mouse histidine tRNA differs from the published sequence of sheep liver histidine tRNA by a single base change in the D-loop. It does not contain an unpaired 5' terminal G residue, as reported for Drosophila and sheep histidine tRNAs. The gene does not contain introns. The 3' flanking region contains a typical RNA polymerase III termination site of 6 consecutive T residues. 523 residues after the 3' end of the his tRNA coding region, the mouse DNA contains a sequence 72% homologous to part of the consensus sequence of the B1 (alu) family.

Glutamate tRNA genes are adjacent to 5S RNA genes in Drosophila and reveal a conserved upstream sequence (the ACT-TA box)

In Drosophila melanogaster at least six transfer RNA genes are located adjacent to the 3' end of the 5S RNA gene cluster. Three of these have been sequenced and identified as coding for glutamate tRNA4. In the chromosome they are arranged as tandem repeats on the same DNA strand and transcribed in the same direction as is 5S DNA, towards the centromere. We have also identified a sequence, the ACT-TA box, that is highly conserved among the polymerase III transcribed genes. Usually the sequence is located at 37 +/- 8 base pairs upstream from the first nucleotide of the structural gene. A similar sequence is also observed upstream of yeast and silkworm tRNA genes and the mitochondrial tRNA genes of mouse and humans.

Characterization of a rat tRNA gene cluster containing the genes for tRNAAsp, tRNAGly and tRNAGlu, and pseudogenes

The putative genes for tRNAGAUAsp(C), tRNAGGAGly(G) and tRNAGAGGlu are in a cluster on the rat chromosome and are present exclusively in a 3.3 kb region cleaved with a restriction endonuclease EcoRI. The cluster reiterates about 10 times on the haploid DNA. Four lambda clones each containing an independent repeating unit were isolated from a rat gene library. The studies on the cloned DNA revealed that the length of the repeating unit including the 3.3 kb EcoRI fragment was at least 13.5 kb. Nucleotide sequence analysis of the 3.3 kb DNA in the isolated clones showed sequence variations among the repeating units and incomplete genes for tRNAGly and tRNAGlu within the clusters.

Immunological method for mapping genes on Drosophila polytene chromosomes

A method is described for localizing DNA sequences hybridized in situ to Drosophila polytene chromosomes. This procedure utilizes a biotin-labeled analog of TTP that can be incorporated enzymatically into DNA probes by nick-translation. After hybridization in situ, the biotin molecules in the probe serve as antigens which bind affinity-purified rabbit antibiotin antibodies. The site of hybridization is then detected either fluorimetrically, by using fluorescein-labeled goat anti-rabbit IgG, or cytochemically, by using an anti-rabbit IgG antibody conjugated to horseradish peroxidase. When combined with Giemsa staining, the immunoperoxidase detection method provides a permanent record that is suitable for detailed cytogenetic analysis. This immunological approach offers four advantages over conventional autoradiographic procedures for detecting in situ hybrids: (i) the time required to determine the site of hybridization is decreased markedly, (ii) biotin-labeled probes are chemically stable and give reproducible results for many months; (iii) biotin-labeled probes appear to produce less background noise than do radiolabeled probes; and (iv) the resolving power is equal to and often greater than that achieved autoradiographically.

Human U1 RNA pseudogenes may be generated by both DNA- and RNA-mediated mechanisms

Analysis of cloned human genomic loci homologous to the small nuclear RNA U1 established that such sequences are abundant and dispersed in the human genome and that only a fraction represent bona fide genes. The majority of genomic loci bear defective gene copies, or pseudogenes, which contain scattered base mismatches and in some cases lack the sequence corresponding to the 3' end of U1 RNA. Although all of the U1 genes examined to date are flanked by essentially identical sequences and therefore appear to comprise a single multigene family, we present evidence for the existence of at least three structurally distinct classes of U1 pseudogenes. Class I pseudogenes had considerable flanking sequence homology with the U1 gene family and were probably derived from it by a DNA-mediated event such as gene duplication. In contrast, the U1 sequence in class II and III U1 pseudogenes was flanked by single-copy genomic sequences completely unrelated to those flanking the U1 gene family; in addition, short direct repeats flanked the class III but not the class II pseudogenes. We therefore propose that both class II and III U1 pseudogenes were generated by an RNA-mediated mechanism involving the insertion of U1 sequence information into a new chromosomal locus. We also noted that two other types of repetitive DNA sequences in eucaryotes, the Alu family in vertebrates and the ribosomal DNA insertions in Drosophila, bore a striking structural resemblance to the classes of U1 pseudogenes described here and may have been created by an RNA-mediated insertion event.

The genes coding for tRNA Tyr of Drosophila melanogaster: localization of determination of the gene numbers

Transfer RNA(Tyr) (anticodon G psi A) was isolated from Drosophila melanogaster by means of Sepharose 4B, RPC-5, and polyacrylamide gel electrophoresis. The rRNA was iodinated in vitro with Na125 I and hybridized in situ to salivary gland chromosomes from Drosophila. The genes of rRNA(Tyr) were localized in eight regions of the genome by autoradiography. Restriction enzyme analysis of genomic DNA indicated that the haploid Drosophila genome codes for about 23 tRNA(Tyr) genes. The regions 22F and 85A each contain four to five tRNA(Tyr) genes, whereas the regions 28C, 41AB, 42A, 42E, and 56D each contain two to three tRNA(Tyr) genes.