Transcription of class III genes in cell-free extracts from the nematode Caenorhabditis elegans

In vitro analysis of the sequences required for transcription of the Arabidopsis thaliana 5S rRNA genes

In vivo, we have already shown that only two of the 5S rDNA array blocks of the Arabidopsis thaliana genome produce the mature 5S rRNAs. Deletions and point mutations were introduced in an Arabidopsis 5S rDNA-transcribed region and its 5'- and 3'-flanks in order to analyse their effects on transcription activity. In vitro transcription revealed different transcription control regions. One control region essential for transcription initiation was identified in the 5'-flanking sequence. The major sequence determinants were a TATA-like motif (-28 to -23), a GC dinucleotide (-12 to -11), a 3-bp AT-rich region (-4 to -2) and a C residue at -1. They are important for both accurate transcription initiation and transcription efficiency. Transcription level was regulated by polymerase III (Pol III) re-initiation rate as in tRNA genes in which TATA-like motif is involved. Active 5S rDNA transcription additionally required an intragenic promoter composed of an A-box, an Intermediate Element (IE) and a C-box. Double-stranded oligonucleotides corresponding to different fragments of the transcribed region, used as competitors, revealed the main importance of internal promoter elements. A stretch of four T is sufficient for transcription termination. Transcription of Arabidopsis 5S rDNA requires 30 bp of 5'-flanking region, a promoter internal to the transcribed region, and a stretch of T for transcription termination.

5'-flanking sequences required for efficient transcription in vitro of 5S RNA genes, in the related nematodes Caenorhabditis elegans and Caenorhabditis briggsae

In the nematode C. elegans, we had previously observed apparent species specificity in 5S RNA transcription. We have now undertaken a further study of 5S RNA gene transcription in this organism and in the related nematode, C. briggsae; the latter was chosen because it might show evolutionarily conserved, functionally important features. Deletion mutagenesis and transcription in vitro, followed by more precise replacements of short blocks of 5' sequence, show that a short, TATA-like sequence at -25 is essential for efficient transcription in vitro of the 1.0-kb C. elegans 5S DNA repeat, and of both C. briggsae 0.7- and 1.0-kb 5S DNA repeats. Internal sequences within the 5S RNA gene appear to be required and can compete for limiting transcription components, whereas 5' flanking sequences do not. These observations suggest that the process of 5S RNA transcription is similar in these nematodes and other higher eukaryotes.

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

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

Purification and characterization of transcription factor IIIA from higher plants

Transcription factor IIIA (TF IIIA) binds and specifically activates transcription of eukaryotic 5S rRNA genes. It also forms a 7S ribonucleoprotein complex with mature 5S rRNA. Here, we describe the purification and properties of pTF IIIA from higher plants. The purified protein from tulip (Tulipa whittalii) has a molecular mass of about 40 kDa and also binds 5S rRNA and 5S rRNA genes. pTF IIIA also facilitates the transcription of a 5S rRNA gene in a HeLa cell extract.

Gene expression in the Caenorhabditis elegans dauer larva: developmental regulation of Hsp90 and other genes

Under conditions unfavorable to growth, the nematode Caenorhabditis elegans enters a developmentally arrested stage, the dauer larva. We have examined gene expression in the dauer larva and during recovery from the dauer stage. Run-on transcription assays with isolated nuclei reveal a depression of general RNA polymerase II transcription to 11-17% of that in other stages. Transcription of individual gene families (including actin, collagen, hsp70, and histone) is similarly depressed relative to actively growing stages. Dauer larvae are, however, capable of being induced for heat shock messages, indicating that they are competent to initiate and elongate transcripts. For most genes surveyed, reduced transcription in dauer larvae correlates with a decrease in message abundance. Hsp70 mRNA, however, is transcribed at lower rates but accumulates at levels comparable to those in other stages. Interestingly, dauer larvae are 15-fold enriched in a mRNA for a C. elegans hsp90 gene. Hsp90 mRNA accumulation is regulated at least in part by differential stability. Dauer larvae thus appear to have a unique pattern of gene expression. Upon placement in food, dauer larvae reenter the developmental pathway as late-stage larvae. Dauer recovery is accompanied by a temporally regulated sequence of gene expression. At least four distinct patterns of gene expression can be distinguished during exit from the dauer stage. Steady-state levels of hsp70 and polyubiquitin mRNA rise sharply within 75 min of recovery before declining by the fourth hour. Actin and histone mRNAs increase steadily following 2-4 hr of recovery, whereas myosin mRNA increases after 10 hr. In contrast, hsp90 mRNA declines sharply within the first 75 min of recovery. Changes in mRNA populations during dauer formation and exit may be physiologically relevant.

Specific transcription of an Acanthamoeba castellanii 5S RNA gene in homologous nuclear extracts

An RNA polymerase III in vitro transcription system has been developed from the protist Acanthamoeba castellanii. The system is dependent on a cloned 5S RNA gene and utilizes a nuclear extract which contains all the necessary protein components. The system is assembled from completely homologous components. Primer extension and RNA sequencing analysis confirm that the in vitro 5S RNA transcript is identical to the 5S RNA isolated from cells. The transcription complex forms unusually rapidly on the 5S RNA gene and is stable to challenge by excess competitor templates. Several 5' deletion mutants were constructed and indicate that the region upstream of -33 is dispensable. Deletion to +16 show the region between -33 and +16 to be required for transcription, a region outside the canonical internal control region.

Cloning and expression in vitro of a gene encoding tRNAArgACG from the nematode Caenorhabditis elegans

A gene (rtr-1) coding for the tRNAArgACG has been isolated and characterized from the nematode, Caenorhabditis elegans. The coding portion is not interrupted by an intron and is followed by a track of four thymidines associated with termination by RNA polymerase III. The predicted mature product is 76 nucleotides (nt) long including the CCA tail, and is specific for the most used Arg codon in C. elegans. The gene can be transcribed and processed in a homologous in vitro system. The 82-nt primary transcript begins at the first purine upstream from the mature tRNA 5' end and terminates after the first thymidine of the terminator signal.

Mutant Caenorhabditis elegans RNA polymerase II with a 20,000-fold reduced sensitivity to alpha-amanitin

A doubly mutant ama-1(m118m526) gene results in an RNA polymerase (Rpo) II that is unusually resistant to alpha-amanitin. Rpo II activity in isolated Caenorhabditis elegans cell nuclei is inhibited 50% by alpha-amanitin at a concentration of 150 micrograms/ml, making this enzyme 150 times more resistant to the toxin than Rpo II from the singly mutant allele, ama-1(m118), 20,000 times more resistant than the wild-type Rpo II, and about six times more resistant to amanitin than is Rpo III. It was determined that the SL1 spliced leader precursor is transcribed by Rpo II, and this transcript was used to measure Rpo II activity. The Rpo II activity is unstable in vitro, and the mutant strain has a temperature-sensitive sterile phenotype. The highly resistant double mutant was selected among four million progeny of the mutagenized ama-1(m118) parent by its ability to grow and reproduce in 200 micrograms/ml amanitin in the presence of a permeabilizing agent, Triton X-100.

Two highly conserved transcribed regions in the 5S DNA repeats of the nematodes Caenorhabditis elegans and Caenorhabditis briggsae

The 5S RNA genes of Caenorhabditis briggsae consist of approximately 65 copies of a 1 kb repeat unit and 20 copies of a related 0.7 kb repeat unit, organized in separate tandem clusters. DNA sequence comparisons with the 1kb 5S DNA repeat from the closely related nematode C. elegans show that the 5S RNA coding region is perfectly conserved. Both C. briggsae 1 kb and 0.7 kb repeats are also efficiently transcribed in vitro,suggesting that both represent functional 5S RNA genes. Surprisingly, a second block of 118 bp is also perfectly conserved between the 1 kb repeats,and is less well conserved in the 0.7 kb repeat. In C. elegans, this DNA is transcribed to produce and abundant 100 nt transcript (SL RNA) which participates in a trans-splicing process (Krause and Hirsh, Cell 49:753, 1987). This SL RNA region of the C. briggsae 1 kb 5S DNA repeat also appears to be transcribed in vivo, while the corresponding region of the 0.7 kb repeat is not.

Accurate and efficient RNA polymerase III transcription in a cell-free extract prepared from Ascaris suum embryos

High-speed supernatant (S100) extracts derived from homogenized Ascaris suum embryos efficiently transcribe added RNA polymerase III templates including cloned 5S rRNA genes of the filarial parasite Brugia malayi. Several criteria, including two-dimensional RNase T1 oligonucleotide fingerprint analysis, indicate that in vitro transcription is accurately initiated and terminated.

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.

Unusual sequences, homologous to 5S RNA, in ribosomal DNA repeats of the nematode Meloidogyne arenaria

There are sequences homologous to 5S ribosomal RNA in the ribosomal DNA (rDNA) repeats of the plant-parasitic nematode Meloidogyne arenaria. This is surprising, because in all other higher eukaryotes studied to date, the genes for 5S RNA are unlinked to and distinct from a tandem rDNA repeat containing the genes for 18S, 5.8S, and 28S ribosomal RNA. Previously, only prokaryotes and certain "lower eukaryotes" (protozoa and fungi) had been found to have both the larger rRNAs and 5S rRNA represented within a single DNA repeat. This has raised questions on the organization of these repeats in the earliest cell (progenote), and on subsequent evolutionary relationships between pro- and eukaryotes. Evidence is presented for rearrangements and deletions within Meloidogyne rDNA. The unusual life cycles (different levels of ploidy, reproduction by meiotic and mitotic parthenogenesis) of members of this genus might allow rapid fixation of any variants with introduced 5S RNA sequences. The 5S RNA sequences in Meloidogyne rDNA may not be expressed, but their presence raises important questions as to the evolutionary origins and stability of repeat gene families.

A trans-spliced leader sequence on actin mRNA in C. elegans

While determining the 5' ends of C. elegans actin mRNAs, we have discovered a 22 nucleotide spliced leader sequence. The leader sequence is found on mRNA from three of the four nematode actin genes. The leader also appears to be present on some, but not all, nonactin mRNAs. The actin mRNA leader sequence is identical to the first 22 nucleotides of a novel 100 nucleotide RNA transcribed adjacent, and in the opposite orientation, to the 5S ribosomal gene. The evidence suggests that the actin mRNA leader sequence is acquired from this novel nucleotide transcript by an intermolecular trans-splicing mechanism.