The gross anatomy of a tRNA gene cluster at region 42A of the D. melanogaster chromosome

Whole-genome haplotyping approaches and genomic medicine

Genomic information reported as haplotypes rather than genotypes will be increasingly important for personalized medicine. Current technologies generate diploid sequence data that is rarely resolved into its constituent haplotypes. Furthermore, paradigms for thinking about genomic information are based on interpreting genotypes rather than haplotypes. Nevertheless, haplotypes have historically been useful in contexts ranging from population genetics to disease-gene mapping efforts. The main approaches for phasing genomic sequence data are molecular haplotyping, genetic haplotyping, and population-based inference. Long-read sequencing technologies are enabling longer molecular haplotypes, and decreases in the cost of whole-genome sequencing are enabling the sequencing of whole-chromosome genetic haplotypes. Hybrid approaches combining high-throughput short-read assembly with strategic approaches that enable physical or virtual binning of reads into haplotypes are enabling multi-gene haplotypes to be generated from single individuals. These techniques can be further combined with genetic and population approaches. Here, we review advances in whole-genome haplotyping approaches and discuss the importance of haplotypes for genomic medicine. Clinical applications include diagnosis by recognition of compound heterozygosity and by phasing regulatory variation to coding variation. Haplotypes, which are more specific than less complex variants such as single nucleotide variants, also have applications in prognostics and diagnostics, in the analysis of tumors, and in typing tissue for transplantation. Future advances will include technological innovations, the application of standard metrics for evaluating haplotype quality, and the development of databases that link haplotypes to disease.

The evolution of tRNA genes in Drosophila

The structure and function of transfer RNA (tRNA) genes have been extensively studied for several decades, yet the general mechanisms controlling tRNA gene family evolution remain unclear, primarily because previous phylogenetics-based methods fail to distinguish between paralogs and orthologs that are highly similar in sequence. We have developed a system for identifying orthologs of tRNAs using flanking sequences to identify regions of conserved synteny and used it to annotate sets of orthologous tRNA genes across the 12 sequenced species of Drosophila. These data have allowed us to place the gains and losses of individual tRNA genes on each branch of the Drosophila tree and estimate rates of tRNA gene turnover. Our results show extensive rearrangement of the Drosophila tRNA gene complement over the last 60 My. We estimate a combined average rate of 2.18 ± 0.10 tRNA gene gains and losses per million years across the Drosophila lineage. We have identified 192 tRNAs that are ancestral to the genus, of which 157 are “core” tRNAs conserved in at least 11 of 12 extant species. We provide evidence that the core set of tRNA genes encode a nearly complete set of anticodons and have different properties from other “peripheral” tRNA genes, such as preferential location outside large tRNA clusters and higher sequence conservation. We also demonstrate that tRNA isoacceptor and alloacceptor changes by anticodon shifts have occurred several times in Drosophila, annotating 16 such events in functional tRNAs during the evolution of the genus.

Molecular analysis of the lethal(1)B214 region at the base of the X chromosome of Drosophila melanogaster

Approximately 50 kb of genomic DNA was isolated from polytene chromosome bands 19F1 and 2 of Drosophila melanogaster. Bands 19F1 and 2 are in the immediate vicinity of the beta-heterochromatin at the base of the X chromosome and encompass the little fly-like and lethal(1)B214 complementation groups. The cloned DNA consists of an approximately 21 kb stretch of unique or low copy number sequence that is bounded by repetitive elements interspersed with further unique sequences. The presence of repeated sequences is characteristic of regions within and adjacent to beta-heterochromatin. At least part of a tRNA gene cluster is present within the 50 kb of cloned DNA. The cloned region also produces at least 18 discrete size classes of developmentally regulated poly(A)+ RNA species. A 2 kb EcoRI fragment (E10), which lies in the 21 kb stretch of unique sequence, generates seven of these transcripts (of sizes 3.5, 3.35, 2.1, 2.0, 1.5, 1.2 and 1.0 kb) in wild-type flies. However, a small deletion of approximately 75 bp in E10 in a lethal(1)B214 mutant allele is associated with alterations in the production or processing of all seven of these transcripts. These data identify E10 sequences as belonging to the lethal(1)B214 gene and suggest that the wild-type lethal(1)B214 gene encodes multiple transcripts. Furthermore, no transcripts of the same size and having the same developmental profile as those generated by the wild-type E10 fragment were identified by probes covering the remainder of the cloned region. This suggests that at least the larger transcripts hybridizing to E10 are partly transcribed from sequences located outside the cloned region, which indicates that the lethal(1)B214 gene extends for more than 20 kb and contains other transcriptionally active sequences within it.

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.

Characterization of a tandemly repeated DNA sequence family originally derived by retroposition of tRNA(Glu) in the newt

A previous report from this laboratory showed that in vitro transcription of total genomic DNA of the newt Cynopus pyrrhogaster resulted in a discrete sized 8 S RNA, which represented highly repetitive and transcribable sequences with a glutamic acid tRNA-like structure in the newt genome. We isolated four independent clones from a newt genomic library and determined the complete sequences of three 2000 to 2400 base-pair PstI fragments spanning the 8 S RNA gene. The glutamic acid tRNA-related segment in the 8 S RNA gene contains the CCA sequence expected as the 3' terminus of a tRNA molecule. Further, the 11 nucleotides located 13 nucleotides upstream from one of the two transcription initiation sites of the 8 S RNA were found to be repeated in the region upstream from the termination site, suggesting that the original unit, which is shorter than the 8 S RNA, was retrotransposed via cDNA intermediates from the PolIII transcript. In the upstream region of the 8 S RNA gene, a 360 nucleotide unit containing the glutamic acid tRNA-related segment was found to be duplicated (clones NE1 and NE10) or triplicated (clone NE3). Except for the difference in the number of the 360 nucleotide unit, the three sequences of the 2000 to 2400 base-pair PstI fragment were essentially the same with only a few mutations and minor deletions. Inverse polymerase chain reaction and sequence determination of the products, together with a Southern hybridization experiment, demonstrated that the family consists of a tandemly repeated unit of 3300, 3700 or 4100 base-pairs. Thus during evolution, this family in the newt was created by retroposition via cDNA intermediates, followed by duplication or triplication of the 360 nucleotide unit and multiplication of the 3300 to 4100 base-pair region at the DNA level.

Nuclear tRNA(Tyr) genes are highly amplified at a single chromosomal site in the genome of Arabidopsis thaliana

We have examined the organization of tRNA(Tyr) genes in three ecotypes of Arabidopsis thaliana, a plant with an extremely small genome of 7 x 10(7) bp. Three tRNA(Tyr) gene-containing EcoRI fragments of 1.5 kb and four fragments of 0.6, 1.7, 2.5 and 3.7 kb were cloned from A. thaliana cv. Columbia (Col-O) DNA and sequenced. All EcoRI fragments except those of 0.6 and 2.5 kb comprise an identical arrangement of two tRNA(Tyr) genes flanked by a tRNA(Ser) gene. The three tRNA genes have the same polarity and are separated by 250 and 370 bp, respectively. The tRNA(Tyr) genes encode the known cytoplasmic tRNA(G psi ATyr). Both genes contain a 12 bp long intervening sequence. Densitometric evaluation of the genomic blot reveals the presence of at least 20 copies, including a few multimers, of the 1.5 kb fragment in Col-O DNA, indicating a multiple amplification of this unit. Southern blots of EcoRI-digested DNA from the other two ecotypes, cv. Landsberg (La-O) and cv. Niederzenz (Nd-O) also show 1.5 kb units as the major hybridizing bands. Several lines of evidence support the idea of a strict tandem arrangement of this 1.5 kb unit: (i) Sequence analysis of the EcoRI inserts of 2.5 and 0.6 kb reveals the loss of an EcoRI site between 1.5 kb units and the introduction of a new EcoRI site in a 1.5 kb dimer. (ii) Complete digestion of Col-O DNA with restriction enzymes which cleave only once within the 1.5 kb unit also produces predominantly 1.5 kb fragments. (iii) Partial digestion with EcoRI shows that the 1.5 kb fragments indeed arise from the regular spacing of the restriction sites.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

tRNAGlu(GAA) genes from the cellular slime mold Dictyostelium discoideum

The haploid genome of the cellular slime mold Dictyostelium discoideum contains at least 18 gene copies coding for a tRNAGlu(GAA). Using a combination of parasexual genetic analysis and molecular biology techniques, 14 of the 18 individual members of this gene family could be assigned to particular linkage groups. According ot this analysis four tRNAGlu genes are located on group I (C, H, I, K), two genes on group II (D,J), seven genes on either group III or VI (A, B, E, F, L, M, N), and one gene on group VII (G). Eight of the tRNAGlu(GAA) genes have been cloned and characterized. All genes are identical in that part of the gene which corresponds to the mature tRNA, thus representing true nonallelic members of this gene family. Different members of this gene family can be distinguished from each other because they reside on restriction fragments of different lengths and because each gene contains unique 5'- and 3'-flanking regions. Nevertheless, a certain degree of sequence conservation within these flanking regions is apparent for members of this gene family. According to in vivo expression analyses of individual genes in Saccharomyces cerevisiae, all isolated tRNAGlu(GAA) copies represent functional transcription units.

Effects of 5' flanking sequences and changes in the 5' internal control region on the transcription of rice tRNA % MathType!MTEF!2!1!+-% feaafiart1ev1aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn% hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr% 4rNCHbGeaGqiVu0Je9sqqrpepC0xbbL8F4rqqrFfpeea0xe9Lq-Jc9% vqaqpepm0xbba9pwe9Q8fs0-yqaqpepae9pg0FirpepeKkFr0xfr-x% fr-xb9adbaqaaeGaciGaaiaabeqaamaabaabaaqcKbay-haafaqabe% GabaaabaGaae4raiaabYgacaqG5baabaGaae4raiaaboeacaqGdbaa% aaaa!3CC7!\[\begin{array}{*{20}c} {{\text{Gly}}} \\ {{\text{GCC}}} \\ \end{array} \]

A stretch of 71 nucleotides in a 1.2 kilobase pair Pst I fragment of rice DNA was identified as tRNA% MathType!MTEF!2!1!+-% feaafiart1ev1aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn% hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr% 4rNCHbGeaGqiVu0Je9sqqrpepC0xbbL8F4rqqrFfpeea0xe9Lq-Jc9% vqaqpepm0xbba9pwe9Q8fs0-yqaqpepae9pg0FirpepeKkFr0xfr-x% fr-xb9adbaqaaeGaciGaaiaabeqaamaabaabaaqcaauaauaabeqace% aaaeaacaqGhbGaaeiBaiaabccacaqG5baabaGaae4raiaaboeacaqG% dbaaaaaa!3BE7!\[\begin{array}{*{20}c} {{\text{Gl y}}} \\ {{\text{GCC}}} \\ \end{array} \] gene by hybridization and nucleotide sequence analyses. The hybridization of genomic DNA with the tRNA gene showed that there are about 10 glycine tRNA genes per diploid rice genome. The 3' and 5' internal control regions, where RNA polymerase III and transcription factors bind, were found to be present in the coding sequence. The gene was transcribed into a 4S product in an yeast cell-free extract. The substitution of 5' internal control region with analogous sequences from either M13mp19 or M13mp18 DNA did not affect the transcription of the gene in vitro. The changes in three highly conserved nucleotides in the consensus 5' internal control region (RGYNNARYGG; R = purine, Y = pyrimidine, N = any nucleotide) did not affect transcription showing that these nucleotides are not essential for promotion of transcription. There were two 16 base pair repeats, 'TGTTTGTTTCAGCTTA' at -130 and -375 positions upstream from the start of the gene. Deletion of 5' flanking sequences including the 16 base pair repeat at -375 showed increased transcription indicating that these sequences negatively modulate the expression of the gene.

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.

Modulation of transcriptional activity and stable complex formation by 5'-flanking regions of mouse tRNAHis genes

We determined the nucleotide sequences of three mouse tRNAHis genes and a tRNAGly gene present in two different lambda clones. One lambda clone contained two tRNAHis genes 600 base pairs (bp) apart in opposite orientations. The other clone contained a tRNAHis and a tRNAGly gene 569 bp apart in the same orientation. The coding regions of the three tRNAHis genes were identical to sequenced mammalian tRNAHis if posttranscriptional modifications are not considered. Notably, the three tRNAHis genes and a fourth gene previously sequenced by us contained within the flanking regions, various amounts of short, conserved 5' leader sequences and 3' trailer sequences directly abutting the coding regions. Otherwise the flanking regions were not homologous. Deletion mutants of one of the tRNAHis genes were constructed which contained 228, 99, 9, and 3 bp of the wild-type 5'-flanking region, respectively. Deletion of 5'-flanking sequences from positions -9 to -4 reduced transcriptional activity substantially (ca. fivefold) in a HeLa cell S-100 lysate. This effect was independent of the vector sequences in the deletion clone, implying that the region from -4 to -9 of the intact gene contains a positive modulatory element for transcription in vitro. The deletion mutant containing 3 bp of wild-type 5'-flanking sequence also had a greatly reduced ability to inhibit the transcription of a second tRNA gene in a competition assay. Thus, the normal 5'-flanking region influences the ability of the gene to form stable complexes with transcription factors. These data further indicate that a mammalian transcription extract is sensitive to 5'-flanking-region effects if a suitable tRNA gene is assayed.

The nucleotide sequence, localization and transcriptional properties of a tRNALeuCUG gene from Drosophila melanogaster

The nucleotide sequence of a tRNALeuCUG gene from Drosophila melanogaster has been determined and compared with available tRNALeuCUG sequences from other eukaryotes, as well as with the tRNALeuUUG gene of D. melanogaster. The genomic location, determined by in situ hybridization, was found to be at site 66B on chromosome 3L. This localization probably places it within one of the known, but uncharacterized, clusters of tRNA genes in this organism. In addition, the transcriptional behaviour of this tRNALeuCUG gene in various in vitro systems is described and it seems that, although the gene is transcribed in all test systems, the very A + T-rich 5'-flanking sequence of this particular gene may be somewhat inhibitory to transcription in vitro.

Modulation of transcriptional activity and stable complex formation by 5'-flanking regions of mouse tRNAHis genes

We determined the nucleotide sequences of three mouse tRNAHis genes and a tRNAGly gene present in two different lambda clones. One lambda clone contained two tRNAHis genes 600 base pairs (bp) apart in opposite orientations. The other clone contained a tRNAHis and a tRNAGly gene 569 bp apart in the same orientation. The coding regions of the three tRNAHis genes were identical to sequenced mammalian tRNAHis if posttranscriptional modifications are not considered. Notably, the three tRNAHis genes and a fourth gene previously sequenced by us contained within the flanking regions, various amounts of short, conserved 5' leader sequences and 3' trailer sequences directly abutting the coding regions. Otherwise the flanking regions were not homologous. Deletion mutants of one of the tRNAHis genes were constructed which contained 228, 99, 9, and 3 bp of the wild-type 5'-flanking region, respectively. Deletion of 5'-flanking sequences from positions -9 to -4 reduced transcriptional activity substantially (ca. fivefold) in a HeLa cell S-100 lysate. This effect was independent of the vector sequences in the deletion clone, implying that the region from -4 to -9 of the intact gene contains a positive modulatory element for transcription in vitro. The deletion mutant containing 3 bp of wild-type 5'-flanking sequence also had a greatly reduced ability to inhibit the transcription of a second tRNA gene in a competition assay. Thus, the normal 5'-flanking region influences the ability of the gene to form stable complexes with transcription factors. These data further indicate that a mammalian transcription extract is sensitive to 5'-flanking-region effects if a suitable tRNA gene is assayed.

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.

Developmental variations in the splicing pattern of transcripts from the Drosophila gene encoding myosin alkali light chain result in different carboxyl-terminal amino acid sequences

The total sequence of the Drosophila melanogaster gene encoding the myosin light chain dissociated by alkali (MLC-ALK) has been determined. By sequence comparisons with an MLC-ALK cDNA clone and by S1 nuclease analyses, the pattern of introns and exons within the gene has been deduced. There are multiple polyadenylylation signals that can account for most of the observed heterogeneity in the lengths of mRNAs. In the 3' half of the gene, there are two alternative splicing patterns which result in mRNAs that translate to give proteins with two alternative 14 amino acid carboxyl-terminal sequences. There is developmental regulation of the selection of the above splicing sites. One splicing pattern produces an mRNA that translates into a protein used for both larval and adult musculature, whereas the other splicing pattern is used for the latter stage only.

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.

A Drosophila melanogaster transfer RNA gene cluster at the cytogenetic locus 90BC

We report the isolation and characterization of a 31 X 10(3) base-pair DNA segment containing a cluster of Drosophila melanogaster transfer RNA genes from the cytogenic locus 90BC. Seven distinct coding regions have been identified in a 15 X 10(3) base-pair DNA segment. These coding regions contain at least ten tRNA structural genes and include sequences encoding the following tRNAs: tRNAval, tRNAPro, tRNAAla and tRNAThr. We have determined the nucleotide sequence of six of these structural genes and their flanking regions. These genes do not contain intervening sequences nor do they encode the terminal CCA. The tRNA genes from the locus also appear to be functional when assayed in a Xenopus germinal vesicle in vitro transcriptional system.

Isolation of genomic clones homologous to transcribed sequences from human X chromosome

Several X chromosome DNA clones homologous to transcribed sequences were isolated from a human X chromosome library. The clones were selected for their ability to hybridize either with 32P-labeled human cDNA in the presence of an excess of unlabeled human repetitive DNA or with mouse fibroblast cDNA. The X chromosome specificity of these sequences was demonstrated by two criteria: A dosage effect was seen when the clones were hybridized to Southern blots of DNA from 1X and 5X cells, and they hybridized to DNA from mouse-human hybrid cells containing only the human X chromosome. The presence of transcribed sequences in these X clones was detected by hybridization with mouse cDNA or with human cDNA in the presence of unlabeled human repetitive sequences, by identifying restriction fragments which hybridize with cDNA but not with human repetitive DNA, and by hybridization with poly A+ RNA on Northern blots. These clones were mapped on the human X chromosomes using a panel of mouse-human somatic cell hybrids carrying various translocated human X chromosomes.

Drosophila melanogaster has only one myosin alkali light-chain gene which encodes a protein with considerable amino acid sequence homology to chicken myosin alkali light chains

A chimeric lambda DNA molecule containing the myosin alkali light-chain gene of Drosophila melanogaster was isolated. The encoded amino acid sequence was determined from the nucleic acid sequence of a cDNA homologous to the genomic clone. The identity of the encoded protein was established by two criteria: (i) sequence homology with the chicken alkali light-chain proteins and (ii) comparison of the two-dimensional gel electrophoretic pattern of the peptides synthesized by in vitro translation of hybrid-selected RNA to that of myosin alkali light-chain peptides extracted from Drosophila myofibrils. There is only one myosin alkali light-chain in D. melanogaster; its chromosomal location is region 98B . This gene is abundantly expressed during the development of larval as well as adult muscles. The Drosophila protein appears to contain one putative divalent cation-binding domain (an EF hand) as compared with the three EF hands present in chicken alkali light chains.

Drosophila melanogaster has only one myosin alkali light-chain gene which encodes a protein with considerable amino acid sequence homology to chicken myosin alkali light chains

A chimeric lambda DNA molecule containing the myosin alkali light-chain gene of Drosophila melanogaster was isolated. The encoded amino acid sequence was determined from the nucleic acid sequence of a cDNA homologous to the genomic clone. The identity of the encoded protein was established by two criteria: (i) sequence homology with the chicken alkali light-chain proteins and (ii) comparison of the two-dimensional gel electrophoretic pattern of the peptides synthesized by in vitro translation of hybrid-selected RNA to that of myosin alkali light-chain peptides extracted from Drosophila myofibrils. There is only one myosin alkali light-chain in D. melanogaster; its chromosomal location is region 98B . This gene is abundantly expressed during the development of larval as well as adult muscles. The Drosophila protein appears to contain one putative divalent cation-binding domain (an EF hand) as compared with the three EF hands present in chicken alkali light chains.

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.

Isolation and characterization of genomic mouse DNA clones containing sequences homologous to tRNAs and 5S rRNA

We have cloned and characterized three fragments of Balb/c mouse DNA which hybridize to mouse cell tRNAs. Fractionation of the tRNAs which hybridize to these clones reveals that two of the clones, lambda Mt-4A and lambda Mt-6A hybridize to only one or two tRNAs, while one clone, lambda Mt-4B, hybridizes to at least seven tRNAs. Two of the tRNAs were identified as tRNAProCCG and tRNAGlyGGA, and others have been identified as tRNAs which are selectively encapsidated into virions of murine leukemia virus and avian reticuloendotheliosis virus. The DNA sequences of putative genes for tRNAProCCG and tRNAGlyGGA, plus flanking regions, were determined. A clone of Balb/c mouse DNA which selectively hybridized to 5S rRNA was also isolated and partially characterized.

Two gene families clustered in a small region of the Drosophila genome

Three Drosophila genes that are clustered within 8 X 10(3) bases of DNA at the chromosomal region 44D have been identified and mapped, and the gene cluster entirely sequenced. The three genes are 55 to 60% homologous in DNA sequence. One gene contains an intron in its 5'-proximal protein coding sequence while the other two have none at this position; similarly, another gene has an intron in its 3'-proximal protein coding sequence which is not found in the other genes. All three genes are abundantly expressed together in Drosophila first, second, and early third instar larval stages and in adults, but they are not abundantly expressed in either embryonic, late third instar larval, or pupal stages. This gene family lies 11 X 10(3) bases away from another cluster containing four Drosophila larval cuticle protein genes plus a pseudogene. The cuticle genes are all abundantly expressed throughout third instar larval development. Thus, at least seven protein-coding genes and one pseudogene lie within 27 X 10(3) bases of DNA. Moreover, two small gene families can lie adjacent on a chromosome and exhibit different patterns of developmental regulation, even though individual genes within each clustered family are co-ordinately expressed.

A human tRNAGlu gene of high transcriptional activity

A mixture of low molecular weight RNAs, in which only tRNAs were radiolabelled, was used as a hybridisation probe to select for tRNA-like sequences within a bank of human genomic DNA in lambda Charon 4A. A restriction enzyme digest of one of the selected lambda Charon 4A recombinants contained two fragments (2.4 Kb & 1.8 Kb) which hybridised tRNA and which, when subcloned into pAT153, were transcribed in Xenopus oocyte nuclei. Analysis of the subcloned 2.4 Kb fragment, which was of remarkably high transcriptional activity, revealed the presence of a single gene for tRNAGlu in the middle of the fragment. The sequence immediately preceding the gene has the potential for forming a tRNA-like structure.

Isolation and characterization of three cloned fragments of human DNA coding for tRNAs and small nuclear RNA U1

Employing a human fetal liver library in lambda Charon 4A phage vector, we have isolated and characterized three clones of human DNA containing genes for tRNAs. One clone contains at least three tRNA genes (tRNALys, tRNAGln and tRNALeu) within 2 kb of each other. The other two clones contain two different single genes for tRNAAsn. One of these latter two DNAs also contains a gene for U1 small nuclear RNA.

The genes coding for 4 snRNAs of Drosophila melanogaster: localization and determination of gene numbers

Four small nuclear RNAs (snRNAs) have been isolated from Drosophila melanogaster flies. They have been characterized by base analysis, fingerprinting, and injection into Axolotl oocytes. The size of the molecules and the modified base composition suggest that the following correlations can be made: snRNA1 approximately U2-snRNA; snRNA2 approximately U3-snRNA; snRNA3 approximately U4-snRNA; snRNA4 approximately U6-snRNA. The snRNAs injected into Axolotl oocytes move into the nuclei, where they are protected from degradation. The genes coding for these snRNAs have been localized by "in situ" hybridization of 125-I-snRNAs to salivary gland chromosomes. Most of the snRNAs hybridize to different regions of the genome: snRNA1 to the cytological regions 39B and 40AB; snRNA2 to 22A, 82E, and 95C; snRNA3 to 14B, 23D, 34A, 35EF, 39B, and 63A; snRNA4 to 96A. The estimated gene numbers (Southern-blot analysis) are: snRNA1:3; snRNA2:7; snRNA3:7; snRNA4:1-3. The gene numbers correspond to the number of sites labeled on the polytene salivary gland chromosomes.

Sequences of four tRNA genes from Caenorhabditis elegans and the expression of C. elegans tRNALeu (anticodon IAG) in Xenopus oocytes

Four tRNA genes have been identified in cloned segments of Caenorhabditis elegans DNA by tRNA hybridisation and expression after injection into Xenopus laevis oocyte nuclei. From DNA sequencing these are (with DNA anticodon sequences) tRNAAsp (GTC), tRNALeu (AAG), tRNALys (CTT) and tRNAPro (TGG). Their flanking DNA sequences are compared. Two identical tRNALys (CTT) genes from different regions of the genome have quite unrelated 5' flanking sequences. The tRNA synthesised in Xenopus oocytes after injection of the tRNALeu cloned DNA has the modified anticodon IAG. The tRNALeu gene precursor transcript from injected oocytes has short 5' and 3' additional sequences and lacks certain of those modified bases found in the processed tRNA.

Genomic clones coding for some of the initial genes expressed during Drosophila development

Preblastoderm Drosophila embryos were made permeable and labeled in vivo with [32P]phosphate-containing medium. Cytoplasmic polyadenylylated RNA was extracted from these embryos and used to screen a library of Drosophila genomic DNA sequences cloned in phage lambda. Ten cloned sequences were selected for further study. These sequences were not complementary to mitochondrial DNA, nor did they contain the repeated nuclear genes coding for rRNA or histones. The cloned sequences each encode one or more unique genes expressed in preblastoderm embryos. RNA blot analysis indicated that some of these genes are also expressed at other times during embryogenesis. These results show that, in spite of the rapid nuclear divisions taking place during the preblastoderm stage, Drosophila nuclear genes are transcribed and that a subset of these genes show variable, stage-specific levels of expression during early embryogenesis.

Cloning and nucleotide sequencing of the bovine growth hormone gene

A gene coding for bovine growth hormone was isolated from a bovine genomic library. The nucleotide sequence of the coding regions of the gene was found to be identical with that of a nearly full-length growth hormone cDNA clone. The gene sequence is approximately 1800 bp in length and contains four intervening sequences. The second intervening sequence of 227 nucleotides does not contain a repetitive element similar to that observed in the rat growth hormone gene. A comparison of the 5' and 3' flanking and untranslated regions of the bovine, human and rat growth hormone genes revealed many areas of highly conserved sequence. Especially noteworthy was the observation that all three genes had a 38 nucleotide homologous sequence within their 5' flanking regions located about 100 bp upstream from their transcription initiation sites.

A rat tRNA gene cluster containing the genes for tRNAPro and tRNALys. Analysis of nucleotide sequences of the genes and the surrounding regions

A lambda clone carrying a rat DNA fragment of 11.9 kb was isolated from a rat gene library with total rat tRNA as a probe. Nucleotide sequence analysis revealed that the DNA fragment contained six tRNA genes, three for tRNAPro and three for tRNALys. Of the six genes all but one tRNAPro gene have the same polarity. Each tRNA gene is separated by a DNA region of 0.1 to 3.6 kb. The 5'-flanking regions of the six rat genes in the cluster do not have any significant sequence homology, but in the 3'-flanking region, each gene has a short T cluster, which is supposed to be a transcription termination signal.

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.

Localization of tRNA genes of Drosophila melanogaster by in situ hybridization

Six purified tRNAs labeled with 125I by chemical or enzymatic methods were hybridized to polytene chromosomes of Drosophila melanogaster. The main chromosomal regions of hybridization wer: tRNAGly(GGA), 58A, 84C, and 90E; tRNALeu(2), 44E, 66B5-8, and 79F; tRNASer(2b), 86A, 88A9-12, and 94A6-8; tRNAThr(3), 47F and 87B; tRNAThr(4), 93A1-2; and tRNATyr(1 gamma), 19F, 22F-23A, 41, 50C1-4 and 85A. At 50C the hybridization of tRNATyr(1 gamma) was polymorphic in the giant strains. When the hybridization of three valine isoacceptors studied previously was re-investigated, it was found that only one hybridization site, 90BC, was shared between tRNAVal(3b) and tRNAVal(4). tRNAVal(3a) did not have any sites in common with the other two.

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.

RNA-DNA hybridization analyses of tRNA-Val-3b in Drosophila melanogaster

Transfer RNA was extracted from 50-300 mg of adult flies and specifically labeled in vitro. The level of individual isoacceptors was quantitated by efficient annealing to Drosophila tRNA genes carried on recombinant DNA plasmids immobilized on nitrocellulose filters. The level of tRNAVal3b in the tRNA isolated from flies deficient in the major tRNAVal3b loci has been examined. The results show that deletion of the major tRNAVal3b loci resulted in a reduction of approximately 50% in the level of tRNAVal3b but did not produce the Minute phenotype; furthermore the effects of deficiencies at two loci were approximately additive.

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

We have isolated four segments of Drosophila melanogaster DNA that hybridize to homologous initiator tRNAMet. Three of the cloned fragments contain initiator tRNA genes, each of which can be transcribed in vitro. The fourth clone, pPW568, contains an initiator tRNA pseudogene which is not transcribed in vitro by RNA polymerase III. The pseudogene is contained in a 1.15 kb DNA fragment. This fragment has the characteristics of dispersed repetitive DNA and hybridizes in situ to at least 30 sites in the Drosophila genome. The arrangement of the initiator tRNA genes we have isolated, is different to that of other Drosophila tRNA gene families. The initiator tRNA genes are not clustered nor intermingled with other tRNA genes. They occur as single copies within an approximately 415-bp repeat segment, which is separated from other initiator tRNA genes by a mean distance of 17 kb. In situ hybridization to polytene chromosomes localizes these genes to the 61D region of the Drosophila genome. Hybridization analysis of genomic DNA indicates the presence of 8-9 non-allelic initiator tRNA genes in Drosophila melanogaster.

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.

The cuticle genes of drosophila: a developmentally regulated gene cluster

A 36 kilobase (kb) DNA segment of the Drosophila genome that contains several larval cuticle protein genes has been cloned and characterized. This segment maps at chromosomal locus 44D. It contains five genes, all of which are expressed at the same time of Drosophila development. Four of the genes are clustered within 7.9 kb of DNA and are abundantly expressed as poly(A)RNA in the epidermis of late third instar larvae but are not abundantly expressed in other developmental stages. A fifth gene lies 8 kb away from this cluster and is expressed at a much lower level in late third instar larval poly(A) RNA. Three of the four abundantly expressed genes have been shown to code for larval cuticle proteins; less decisive evidence indicates that the fourth gene also probably codes for a larval cuticle protein. Some of the genes are related in DNA sequence, and the proteins encoded in the cluster are related immunologically. Thus the cuticle genes encoded by the segment at 44D are members of a family of genes of common ancestry, which share the same pattern of developmental expression and reside in a small segment of the Drosophila genome.