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

cDNAs derived from primary and small cytoplasmic Alu (scAlu) transcripts

We have isolated and sequenced twenty-six cDNAs derived from primary Alu transcripts. Most cDNAs (22/26) sequenced end in multiple T residues, known to be at the termination for RNA polymerase III-directed transcripts. We conclude that these cDNAs were derived from authentic, RNA polymerase III-directed primary Alu transcripts. Sequence alignment of the cDNAs with Alu consensus sequences show that the cDNAs belong to different, previously described Alu subfamilies. The sequence variation observed in the 3' non-Alu regions of each of the cDNAs led us to conclude that they were derived from different genomic loci, thus demonstrating that multiple Alu loci are transcriptionally active. The subfamily distribution of the cDNAs suggests that transcriptional activity is biased towards evolutionarily younger Alu subfamilies, with a strong selection for the consensus sequence in the first 42 bases and the promoter B box. Sequence data from seven cDNAs derived from small cytoplasmic Alu (scAlu) transcripts, a processed form of Alu transcripts, also have a similar bias towards younger Alu subfamilies. About half of these cDNAs are due to processing or degradation, but the other half appear to be due to the formation of a cryptic RNA polymerase III termination signal in multiple loci. Using our sequence data, we have isolated a transcriptionally active genomic Alu element belonging to the Ya5 subfamily. In vitro transcription studies of this element suggest that its flanking sequences contribute to its transcriptional activity. The role of flanking sequences and other factors involved in transcriptional activity of Alu elements are discussed.

Transcriptional silencing of a tRNA1Gly copy from within a multigene family is modulated by distal cis elements

Individual copies of tRNA1Gly from within the multigene family in Bombyx mori could be classified based on in vitro transcription in homologous nuclear extracts into three categories of highly, moderately, or weakly transcribed genes. Segregation of the poorly transcribed gene copies 6 and 7, which are clustered in tandem within 425 base pairs, resulted in enhancement of their individual transcription levels, but the linkage itself had little influence on the transcriptional status. For these gene copies, when fused together generating a single coding region, transcription was barely detectable, which suggested the presence of negatively regulating elements located in the far flanking sequences. They exerted the silencing effect on transcription overriding the activity of positive regulatory elements. Systematic analysis of deletion, chimeric, and mutant constructs revealed the presence of a sequence element TATATAA located beyond 800 nucleotides upstream to the coding region acting as negative modulator, which when mutated resulted in high level transcription. Conversely, a TATATAA motif reintroduced at either far upstream or far downstream flanking regions exerted a negative effect on transcription. The location of cis-regulatory sequences at such farther distances from the coding region and the behavior of TATATAA element as negative regulator reported here are novel. These element(s) could play significant roles in activation or silencing of genes from within a multigene family, by recruitment or sequestration of transcription factors.

Developmental stage-specific regulation of Xenopus tRNA genes by an upstream promoter element

Typically the internal promoter elements of tRNA genes are necessary and sufficient to support transcription. Here a sequence element preceding a Xenopus tRNA gene is shown to be required for transcription in late stage, but not early stage oocyte extracts. The constitutive tyrD gene is expressed in both early and late oocyte extracts, whereas the early oocyte-specific tyrCooc gene is only expressed in early extracts. An upstream promoter element (URR), between positions -42 and -14 of the tyrD gene, mediates this differential expression. The URR is required for tyrD transcription in late oocyte extracts. Placing the URR upstream of the tyrCooc gene allows this gene to be transcribed in late extracts. The URR is irrelevant to transcription in early extracts; transcription of tyrD or tyrCooc requires only the internal promoter sequences. This indicates the polymerase III transcriptional machinery changes during oogenesis, resulting in a stringent upstream sequence requirement. Mutations within the URR are shown to alter the preferred site of initiation by RNA polymerase III. Shifting the position of the URR upstream by one-half helical turn also repositioned the site of initiation, suggesting the URR directs the placement of the initiation factor complex or polymerase itself.

Conserved signals in the 5' flanking region of eukaryotic nuclear tRNA genes

The statistical analysis of 5' flanking regions of eukaryotic tRNA genes was done. The analysis of nucleotides in the sequence of fungi and invertebrates showed a high content of A and T in the flanking regions versus coding regions where G and C dominate. In contrast to these results in vertebrates sequences the preferences of any nucleotide in flanking regions was not observed. The analysis of tetrads showed five conserved signals: TTGT, (T/A)(T/A)ATA, A(C/T)(C/A)A in the tRNA genes of fungi, (A/T)TGA of invertebrates and (A/T)GAG of vertebrates. The analysis of 3' flanking regions did not show any conserved signals except well known poly-T tracks.

The 5'-flanking sequence of the loach oocyte 5S rRNA gene contains a signal for effective transcription

Deletion mutants of loach oocyte 5S rRNA genes were injected and transcribed in vivo in the nuclei of loach (Misgurnus fossilis) and Xenopus laevis. A control region was found in the 5'-flanking sequence, the elimination of which greatly decreases in vivo transcription of 5S rRNA genes. This cis-acting element is located in the region between nt-18 and the transcription start point. We propose that the oocyte nucleus contains (a) specific transcriptional factor(s), NTFO, which interacts with the cis-acting element we described. We also propose that NTFO is inactivated in maturing oocytes when nucleoplasm interacts with oocyte cytoplasm after germinal vesicle breakdown. The residual activity of this factor(s) may be responsible for low-level synthesis of oocyte 5S rRNA at the beginning of embryogenesis. We consider the disappearance of NTFO during gastrulation to be responsible for the total inactivation of oocyte 5S rRNA genes in embryonic and somatic tissue.

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.

Localization of three DNA segments encompassing tRNA genes to human chromosomes 1, 5, and 16: proposed mechanism and significance of tRNA gene dispersion

The chromosomal locations of three cloned human DNA fragments encompassing tRNA genes have been determined by Southern analysis of human-rodent somatic cell hybrid DNAs with subfragments from these cloned genes and flanking sequences used as hybridization probes. These three DNA segments have been assigned to human chromosomes 1, 5, and 16, and homologous sequences are probably located on chromosome 14 and a separate locus on chromosome 1. These studies, combined with previous results, indicate that tRNA genes and pseudogenes are dispersed on at least seven different human chromosomes and suggest that these sequences will probably be found on most, if not all, human chromosomes. Short (8-12 nucleotide) direct terminal repeats flank many of the dispersed tRNA genes. The presence of these flanking repeats, combined with the dispersion of tRNA genes throughout the human genome, suggests that many of these genes may have arisen by an RNA-mediated retroposition mechanism. The possible functional significance of this gene dispersion is considered.

A human tRNA gene heterocluster encoding threonine, proline and valine tRNAs

A cluster of three tRNA genes encoding a tRNA(UGUThr), a tRNA(UGGPro), and a tRNA(AACVal), and two Alu-elements occur in a 6.0-kb human DNA fragment. The tRNA(Thr) gene is 2.7-kb upstream from the tRNA(Pro) gene, which is separated by 367 bp from the tRNA(Val) gene. One Alu-element actually overlaps the tRNA(Val) gene and is of opposite polarity to all three tRNA genes. All three tRNA genes are accurately transcribed in a homologous HeLa cell extract, since the ribonuclease T1 fingerprints of the tRNA transcripts are consistent with the nucleotide sequences of the tRNAs. The upstream region flanking the tRNA(Thr) gene has two tracts of alternating purine/pyrimidine residues potentially capable of adopting the Z-DNA conformation, and presumptive binding sites for two RNA polymerase II transcription factors. The tRNA(Thr) gene apparently has a substantially higher in vitro transcriptional efficiency than the other two tRNA genes in this cluster, and a tRNA(GCCGly) gene from another human DNA segment. Deletion constructs of the tRNA(Thr) gene retaining 272, 168, and 33 bp of original 5'-flanking DNA had about the same in vitro transcriptional efficiency, whereas that of the construct with only 2 bp of 5'-flanking human DNA was drastically reduced. The tRNA(Thr) gene constructs with 272 and 168 bp of original 5'-flanking DNA apparently reduce the transcriptional efficiencies of the proline and glycine tRNA genes, implicating the upstream region from the tRNA(Thr) gene as being crucial for its high transcriptional efficiency.

Flanking sequences are required for efficient transcription and stable complex formation for the human tRNAiMet3-coding gene

An analysis of 5' and 3' deletions of the human tRNAiMet3 gene has revealed upstream regions required for efficient transcription and stable complex formation in vitro. The 5' boundary of this essential region lies between nucleotides -39 to -18 (start point = + 1), and it has been shown that 3'-flanking sequences near the first termination site are also important for stable complex formation. The transcriptional efficiency of two non-allelic loci (TMET3 and TMET2) has been compared and TMET2 is more active. An analysis of chimeric (hybrid) genes indicates that much of the difference seen is due to 5'-flanking sequences and that there may be complex interactions between 5' and 3' sequences.

Genomic organization of human 5 S rDNA and sequence of one tandem repeat

An organization of human 5 S rDNA repeats is inferred from Southern analyses of restriction digests of genomic DNA fractionated by pulsed-field and conventional gel electrophoreses. A single unit of 2.2 kb is repeated approximately 90 times within a 200-kb fragment (defined by enzymes that do not cleave within individual units, i.e., EcoR1, BglII, HindIII, and PvuII); a comparable number of 5 S sequences are scattered elsewhere in the genome. A lambda clone containing six complete 5 S repeats was obtained from a human placental DNA library. One repeat contains 2231 bp and includes poly(dG-dT).(dC-dA), tracts of polypyrimidine, and an Alu sequence in the spacer region. Also, 5-S-hybridizing clones, containing DNA inserts with an average size of 250 kb, have been obtained as yeast artificial chromosomes. Thus far, four clones have been partially characterized and shown to be 5 S sequences from loci separate from the tandem repeat units.

Nucleotide sequence and transcription of a rat tRNA(Phe) gene and a neighboring Alu-like element

A bacteriophage gamma Ch4A clone containing a 22-kb rat DNA insert was isolated and found to contain a solitary tRNA(Phe)GAA gene and, 436 bp downstream of it, an Alu-like element. The nucleotide sequence of a 1141-bp DNA fragment containing these genes was determined. The rat tRNA(Phe)GAA gene, with the exception of an additional A in the extra arm, has a sequence identical to that of a rabbit liver tRNA(Phe). The Alu-like element belongs to the rodent B2 family of short interspersed repetitive nucleotide sequences. This repetitive element, B2Phe, is flanked by 12-bp direct repeats, contains an internal split promoter (block A and block B) for RNA polymerase III and is devoid of an A-rich segment at the 3' end. Like other members of the B2 family, the B2Phe element presents 64% sequence homology with rat serine tRNA and contains a serine (GCT) anticodon. Both tRNA(Phe)GAA gene and B2Phe element were found to be transcriptionally active in HeLa cell and Xenopus oocyte nuclear extracts. The tRNA(Phe) gene transcripts were processed during the course of transcription to form mature-size tRNA(Phe). The transcription efficiency of the B2Phe element was found to be an order of magnitude higher than that of the tRNA(Phe) gene. Competition experiments demonstrate that the B2Phe DNA can form a more stable transcription complex than the tRNA(Phe) gene and compete with it for binding of transcription factors.

Modulation of the phenotypic expression of a human serine tRNA gene by 5'-flanking sequences

Mammalian nonsense suppressors provide a model system to investigate structural and functional aspects of mammalian tRNAs and their genes in vivo. To assess the role that extragenic flanking sequences may have on the expression of mammalian tRNA genes in vivo, deletion/substitutions ending in the 5'-flanking sequence or 3'-flanking sequence of a cloned human serine amber suppressor tRNA gene were constructed. The phenotypic expression of these mutant genes was examined by transfection in mammalian cells and by measuring the efficiency with which they were able to suppress an amber (UAG) nonsense mutation in the Escherichia coli chloramphenicol acetyl transferase (cat) gene. Deletion of the 5'-flanking region up to nucleotide position -66 with respect to the first nucleotide of the coding region had no effect on levels of nonsense suppression as compared to the wild-type gene; however, deletion to -18 led to a 12-fold reduction in suppressor activity. Deletion up to -1 did not further reduce suppression efficiency. Deletion of the 3'-flanking region up to 9 nucleotides downstream from the consecutive T residue termination site resulted in only a slight reduction in functional tRNA expression. In in vivo competition studies, the -18 deletion clone was less able to compete out the activity of a second suppressor tRNA gene than was the wild-type corresponding gene, suggesting that the upstream region plays a role in the formation of active transcription complexes in vivo. These results imply that the human serine tRNA gene contains an upstream regulatory region located between positions -66 and -18 that plays a positive role in modulating expression of this gene in vivo.

Functional dissection of 5' and 3' extragenic control regions of human tRNA(Val) genes reveals two different regulatory effects

Two natural human tRNA(Val) genes, pHtV1 and pHtV3, differ in their transcription efficiency by an order of magnitude. The extragenic control regions (ECRs) responsible for this effect were compared with respect to the kinetics and thermodynamics of transcription complex formation. The 5' ECR of pHtV1 acts by increasing both the rate of stable complex formation and the equilibrium constant of association between tDNA and at least one transcription factor present in the stable complex. The stability of the preinitiation complexes is not affected by ECRs. For the formation of a stable preinitiation complex, we suggest a two-step mechanism, comprising (i) the ECR-controlled association of at least one transcription factor (TFIIIC) with the tDNA, and (ii) an ECR-independent conformational change of this tDNA-protein complex. The function of 3' ECRs could be discriminated from the 5' ECR-mediated effects by transcriptional analysis of two chimeric constructs derived from pHtV1 and pHtV3. Surprisingly, the pHtV1 3' ECR causes an eight-fold increase of transcription efficiency, although it has only minor influence on stable preinitiation complex formation. Instead, this ECR stimulates transcription by promoting the transition of the preinitiation complex into an activity synthesizing transcription complex. This novel function of a 3' ECR contributes an additional regulatory level for tRNA gene expression.

The transcriptional efficiency of clustered tRNA genes is affected by their position within the cluster

The transcription of a mouse genomic segment containing four tRNA genes, coding for a tRNA(Ala), a tRNA(Ile), a tRNA(Pro) and a tRNA(Lys), has been studied in a HeLa cell extract, demonstrating that differences among their transcriptional efficiencies are evident using as templates either the natural cluster or an equimolecular mixture of the four isolated genes. Nevertheless, the structure of the cluster influences the transcriptional efficiency of the clustered genes. In fact, a cis-acting inhibitory sequence has been located at about 400 bp downstream of the tRNA(Pro) coding sequence. Moreover rearrangements of the reciprocal position of the various tRNA genes within the cluster results in significant changes in the transcriptional rates of the individual transcriptional units.

Unrelated leader sequences can efficiently promote human tRNA gene transcription

The 5'-leader sequence of a human tRNA gene encoding the major tRNA(IACVa 1) species was replaced by several unrelated sequences of human and bacterial origin. Transcription in a HeLa cell extract revealed an extragenic control region (ECR) between positions -51 and -16. Competition assays demonstrate that the wild-type ECR acts as a positive modulator of transcription factor binding. The amount of active transcription complex formed is shown to be dependent on the ECR, whereas the stability of transcription complexes formed under the control of wild-type and mutant ECRs seems not to be affected. One bacterial DNA provided transcription controlling properties indistinguishable from those of the natural human leader sequence. The poor homology between these two sequences indicates that ECRs of human tRNA genes do not consist of highly conserved boxes like intragenic control regions, but of fairly individual DNA elements.