An upstream signal is required for in vitro transcription of Neurospora 5S RNA genes

Comparative analysis of the intergenic spacer regions and population structure of the species complex of the pathogenic yeast

Cryptococcus neoformans is an opportunistic basidiomycete responsible for the high incidence of cryptococcosis in patients with AIDS and in other immune-compromised individuals. This study, which focused on the molecular structure and genetic variability of the two varieties in the C. neoformans and Cryptococcus gattii species complex, employed sequence analysis of the intergenic spacer regions, IGSI and IGSII. The IGS region is the most rapidly evolving region of the rDNA families. The IGSI displayed the most genetic variability represented by nucleotide base substitutions and the presence of long insertions/deletions (indels). In contrast, the IGSII region exhibited less heterogeneity and the indels were not as extensive as those displayed in the IGSI region. Both intergenic spacers contained short, interspersed repeat motifs, which can be related to length polymorphisms observed between sequences. Phylogenetic analysis undertaken in the IGSI, IGSII and IGSI +5S rRNA + IGSII regions revealed the presence of six major phylogenetic lineages, some of which segregated into subgroups. The major lineages are represented by genotypes 1 (C. neoformans var. grubii), genotype 2 (C. neoformans var. neoformans), and genotypes 3, 4, 5 and 6 represented by C. gattii. Genotype 6 is a newly described IGS genotypic group within the C. neoformans species complex. With the inclusion of IGS subgenotypic groups, our sequence analysis distinguished 12 different lineages. Sequencing of clones, which was performed to determine the presence of multiple alleles at the IGS locus in several hybrid strains, yielded a single IGS sequence type per isolate, thus suggesting that the selected group of cloned strains was mono-allelic at this locus. IGS sequence analyses proved to be a powerful technique for the delineation of the varieties of C. neoformans and C. gattii at genotypic and subgenotypic levels.

The external promoter in the guinea pig 5S rRNA gene is different from the rodent promoter

The guinea pig has about 100 copies of the 5S rRNA gene per haploid genome and they are present in 2.1 kb tandem repeats. Three bona fide 5S rRNA genes and four pseudo genes were sequenced. The conserved external promoter (D box) found in rodents and primates is only partially present in the guinea pig. The "D box like" sequence in guinea pig only has eight of the 12 nucleotides in the conserved D box. The results are in accordance with investigations showing that the guinea pig is not a rodent. Conserved sequences in the non-transcribed spacer can therefore be useful in phylogenetic studies.

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.

Widespread use of TATA elements in the core promoters for RNA polymerases III, II, and I in fission yeast

In addition to directing transcription initiation, core promoters integrate input from distal regulatory elements. Except for rare exceptions, it has been generally found that eukaryotic tRNA and rRNA genes do not contain TATA promoter elements and instead use protein-protein interactions to bring the TATA-binding protein (TBP), to the core promoter. Genomewide analysis revealed TATA elements in the core promoters of tRNA and 5S rRNA (Pol III), U1 to U5 snRNA (Pol II), and 37S rRNA (Pol I) genes in Schizosaccharomyces pombe. Using tRNA-dependent suppression and other in vivo assays, as well as in vitro transcription, we demonstrated an obligatory requirement for upstream TATA elements for tRNA and 5S rRNA expression in S. pombe. The Pol III initiation factor Brf is found in complexes with TFIIIC and Pol III in S. pombe, while TBP is not, consistent with independent recruitment of TBP by TATA. Template commitment assays are consistent with this and confirm that the mechanisms of transcription complex assembly and initiation by Pol III in S. pombe differ substantially from those in other model organisms. The results were extended to large-rRNA synthesis, as mutation of the TATA element in the Pol I promoter also abolishes rRNA expression in fission yeast. A survey of other organisms' genomes reveals that a substantial number of eukaryotes may use widespread TATAs for transcription. These results indicate the presence of TATA-unified transcription systems in contemporary eukaryotes and provide insight into the residual need for TBP by all three Pols in other eukaryotes despite a lack of TATA elements in their promoters.

Effect of mutations in the upstream promoter on the transcription of human 5S rRNA genes

The human 5S rRNA gene has a 12-mer external promoter, the D box, localized about 30 bp upstream the coding sequence. By site directed mutagenesis 58 different D box promoter mutants were made. While some mutations in the D box allowed full transcription, other mutations decreased the transcriptional activity to 20-50% compared to the bona fide gene, showing the importance of this external promoter in transcription initiation. A number of maxi 5S rRNA genes were constructed from bona fide genes and D box mutated clones. Transfection of HeLa cells with maxi 5S rRNA genes showed that the D box is also important for 5S rRNA gene expression in vivo. Evidence from different eukaryotic cells suggests that expression of 5S rRNA genes is regulated by external promoters in addition to the internal control region.

Polymorphism at the ribosomal DNA spacers and its relation to breeding structure of the widespread mushroom Schizophyllum commune

The common split-gilled mushroom Schizophyllum commune is found throughout the world on woody substrates. This study addresses the dispersal and population structure of this fungal species by studying the phylogeny and evolutionary dynamics of ribosomal DNA (rDNA) spacer regions. Extensive sampling (n = 195) of sequences of the intergenic spacer region (IGS1) revealed a large number of unique haplotypes (n = 143). The phylogeny of these IGS1 sequences revealed strong geographic patterns and supported three evolutionarily distinct lineages within the global population. The same three geographic lineages were found in phylogenetic analysis of both other rDNA spacer regions (IGS2 and ITS). However, nested clade analysis of the IGS1 phylogeny suggested the population structure of S. commune has undergone recent changes, such as a long distance colonization of western North America from Europe as well as a recent range expansion in the Caribbean. Among all spacer regions, variation in length and nucleotide sequence was observed between but not within the tandem rDNA repeats (arrays). This pattern is consistent with strong within-array and weak among-array homogenizing forces. We present evidence for the suppression of recombination between rDNA arrays on homologous chromosomes that may account for this pattern of concerted evolution.

Two highly divergent 5S rDNA unit size classes occur in composite tandem array in European larch (Larix decidua Mill.) and Japanese larch (Larix kaempferi (Lamb.) Carr.)

The 5S ribosomal DNA unit structure and organization have been investigated in Larix decidua and Larix kaempferi using selective amplification of gene and spacer, sequence analysis and homologous probe hybridization. Two highly divergent unit size classes of approximately 650 and 870 bp were detected in both species. Sequence analysis in Larix decidua revealed that length variations occur in the middle spacer region and are the result of duplications (in the long spacers) and considerable sequence heterogeneity. Conversely, the transcribed region is of uniform length (120 bp), and the nucleotide sequence of one Larix decidua clone is similar to that reported for other gymnosperms. Sequence comparison of the larch spacers with two other Pinaceae species (Pinus radiata and Picea glauca) showed that the 5' and 3' regions flanking the gene (40 and 60 bp, respectively) are quite conserved, suggesting a regulatory role. Moreover, a small element of about 70 bp located in the middle spacer region was found to be common to the larch long units and the six Pinus radiata spacer clones previously sequenced (64% sequence identity). The short and long unit size classes are mainly organized in composite tandem array(s) with evidence of extensive zones of strict alternation in both species. Mechanisms underlying this unusual association of divergent units in larch 5S rDNA arrays are discussed.Key words: 5S rRNA genes, spacer variations, cluster organization, sequence comparison, Gymnosperms.

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.

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.

In vivo analyses of upstream promoter sequence elements in the 5 S rRNA gene from Saccharomyces cerevisiae

Upstream promoter elements of the Saccharomyces cerevisiae 5 S rRNA gene have been characterized by genomic DNase I "footprinting" and by in vivo mutational analyses using base substitutions and deletions. A high copy shuttle-vector was used to efficiently express the mutant 5 S rRNA genes in vivo and a structural mutation in the 5 S rRNA, which was previously shown to be functionally neutral but easily detected by gel electrophoresis, allowed for an accurate measure of gene expression. The results provide direct evidence for upstream regulatory elements which confirms a start site element (sse) from -1 to -8 and identifies a new independent upstream promoter element (upe) centered from about -17 to -20. In contrast to previous reports with reconstituted systems, both elements dramatically affect the efficiency of gene expression and suggest that the saturated conditions which are used in reconstituted studies mask sequence dependence; a dependency that could be physiologically significant and play a role in the regulation of 5 S rRNA expression. The footprint analyses support an extended region of protein interaction as recently observed in reconstituted systems but again provide evidence of significant structural rearrangements when the upstream sequence is changed.

RNA polymerase II/III transcription specificity determined by TATA box orientation

The TATA box sequence in eukaryotes is located about 25 bp upstream of many genes transcribed by RNA polymerase II (Pol II) and some genes transcribed by RNA polymerase III (Pol III). The TATA box is recognized in a sequence-specific manner by the TATA box-binding protein (TBP), an essential factor involved in the initiation of transcription by all three eukaryotic RNA polymerases. We have investigated the recognition of the TATA box by the Pol II and Pol III basal transcription machinery and its role in establishing the RNA polymerase specificity of the promoter. Artificial templates were constructed that contained a canonical TATA box as the sole promoter element but differed in the orientation of the 8-bp TATA box sequence. As expected, Pol II initiated transcription in unfractionated nuclear extracts downstream of the "forward" TATA box. In distinct contrast, transcription that initiated downstream of the "reverse" TATA box was carried out specifically by Pol III. Importantly, this effect was observed regardless of the source of the DNA either upstream or downstream of the TATA sequence. These findings suggest that TBP may bind in opposite orientations on Pol II and Pol III promoters and that opposite, yet homologous, surfaces of TBP may be utilized by the Pol II and Pol III basal machinery for the initiation of transcription.

Silkworm TFIIIA requires additional class III factors for commitment to transcription complex assembly on a 5S RNA gene

We find striking similarities in promoter structure and requirements for template commitment on 5S RNA and tRNA genes from silkworms. The promoters are nearly the same size (approximately 160 bp) and include flanking as well as internal sequences. To analyze the factor requirements for 5S RNA transcription complex assembly in a completely homologous system, we have isolated a silkworm fraction that is highly enriched for the 5S RNA-specific transcription factor, TFIIIA. Using this fraction, together with the other silkworm fractions, TFIIIB, TFIIIC, TFIIID and RNA polymerase III, we demonstrate that the requirements for 5S RNA transcription complex assembly are very similar to those previously established for a tRNA(C)(Ala) gene. Specifically, no individual factor fraction is sufficient for commitment of silkworm 5S RNA genes to transcription complex assembly. Rather, combinations of at least three factor fractions are required. Our observation that more than one subset of factors is competent for commitment suggests that silkworm 5S RNA genes further resemble tRNA(C)(Ala) genes in their ability to use multiple pathways for transcription complex formation.

Physical mapping of rRNA genes by fluorescent in-situ hybridization and structural analysis of 5S rRNA genes and intergenic spacer sequences in sugar beet (Beta vulgaris)

A digoxigenin-labelled 5S rDNA probe (pTa-794) and a rhodamine-labelled 18S-5.8S-25S rDNA probe (pTa71) were used for double-target in-situ hybridization to root-tip metaphase, prophase and interphase chromosomes of cultivated beet,Beta vulgaris L. After in-situ hybridization with the 18S-5.8S-25S rDNA probe, one major pair of sites was detected which corresponded to the secondary constriction at the end of the short arm of chromosome 1. The two rDNA chromosomes were often associated and the loci only contracted in late metaphase. In the majority of the metaphase plates analyzed, we found a single additional minor hybridization site with pTa71. One pair of 5S rRNA gene clusters was localized near the centromere on the short arm of one of the three largest chromosomes which does not carry the 18S-5.8S-25S genes. Because of the difficulties in distinguishing the very similarly-sizedB. vulgaris chromosomes in metaphase preparations, the 5S and the 18S-5.8S-25S rRNA genes can be used as markers for chromosome identification. TwoXbaI fragments (pXV1 and pXV2), comprising the 5S ribosomal RNA gene and the adjacent intergenic spacer, were isolated. The two 5S rDNA repeats were 349 bp and 351 bp long, showing considerable sequence variation in the intergenic spacer. The use of fluorescent in-situ hybridization, complemented by molecular data, for gene mapping and for integrating genetic and physical maps of beet species is discussed.

Conserved upstream sequence elements in plant 5S ribosomal RNA-encoding genes

As a basis for further comparative studies, nuclear 5S rRNA gene repeats from two plants of the Solanaceae family, tobacco (Nicotiana rustica) and tomato (Lycopersicon esculentum), were isolated and sequenced. The more abundant 5S rRNA gene repeat in tobacco is 430 bp long, while a second less common variant is 521 bp long. In contrast, the 5S rRNA gene repeat from tomato is only 355 bp long. The spacer sequences from these gene repeats, as well as from other published plant nuclear 5S rRNA genes, were compared for repeating or conserved sequence elements. The results indicate that often observed, but non-conserved, repeating sequence elements probably arise spontaneously by unequal crossover with no functional significance. However, three conserved sequence elements immediately upstream of the coding sequence; a C residue at -1, a G + C-rich element centered at -13, and an A + T-rich element centered at -26 resemble regulatory features which have been identified in other types of genes.

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.

Transcription of a yeast U6 snRNA gene requires a polymerase III promoter element in a novel position

Vertebrate genes coding for U6 small nuclear RNA are transcribed by RNA polymerase III (pol III), using only upstream promoter elements rather than the A and B block internal control regions typical of most pol III transcription units. We show that expression of the U6 gene from the yeast Saccharomyces cerevisiae has two unexpected features: it requires a B block promoter element, and this element is located in a novel position, 120 bp downstream of the coding region. In tRNA genes, the B block is the primary binding site for transcription factor (TF) IIIC, whose function is to promote the subsequent binding of TFIIIB. Both factors are thus implicated in yeast U6 gene transcription. We present a model of the U6 transcription complex based on the structure of yeast and vertebrate U6 promoters.

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.

Two complex regions, including a TATA sequence, are required for transcription by RNA polymerase I in Neurospora crassa

In order to define the RNA polymerase I transcriptional apparatus and how it might interact with regulatory signals, the DNA sequences necessary for 40S rRNA transcription in Neurospora crassa were determined. A systematic set of deletion, substitution and insertion mutations were assayed in a homologous in vitro system. The sequences required for transcription of the gene consist of two large domains (I and II) from -113 to -37, and -29 to +4, respectively. Complete deletion of either domain abolished transcription. Upstream sequences confer a small stimulation of transcription. Domain II includes a TATA sequence at -5 which is sensitive to a small (2 bp) substitution and which is conserved among the large rRNA genes of many organisms. Domain I includes a sequence, termed the 'Ribo box', which is also required for transcription of the Neurospora 5S rRNA genes (1), and which occurs in the 5' region of a Neurospora ribosomal protein gene. The 5S and 40S Ribo boxes are shown to be functionally interchangeable.

A yeast ARS-binding protein activates transcription synergistically in combination with other weak activating factors

ABFI (ARS-binding protein I) is a yeast protein that binds specific DNA sequences associated with several autonomously replicating sequences (ARSs). ABFI also binds sequences located in promoter regions of some yeast genes, including DED1, an essential gene of unknown function that is transcribed constitutively at a high level. ABFI was purified by specific binding to the DED1 upstream activating sequence (UAS) and was found to recognize related sequences at several other promoters, at an ARS (ARS1), and at a transcriptional silencer (HMR E). All ABFI-binding sites, regardless of origin, provided weak UAS function in vivo when examined in test plasmids. UAS function was abolished by point mutations that reduced ABFI binding in vitro. Analysis of the DED1 promoter showed that two ABFI-binding sites combine synergistically with an adjacent T-rich sequence to form a strong constitutive activator. The DED1 T-rich element acted synergistically with all other ABFI-binding sites and with binding sites for other multifunctional yeast activators. An examination of the properties of sequences surrounding ARS1 left open the possibility that ABFI enhances the initiation of DNA replication at ARS1 by transcriptional activation.

A yeast ARS-binding protein activates transcription synergistically in combination with other weak activating factors

ABFI (ARS-binding protein I) is a yeast protein that binds specific DNA sequences associated with several autonomously replicating sequences (ARSs). ABFI also binds sequences located in promoter regions of some yeast genes, including DED1, an essential gene of unknown function that is transcribed constitutively at a high level. ABFI was purified by specific binding to the DED1 upstream activating sequence (UAS) and was found to recognize related sequences at several other promoters, at an ARS (ARS1), and at a transcriptional silencer (HMR E). All ABFI-binding sites, regardless of origin, provided weak UAS function in vivo when examined in test plasmids. UAS function was abolished by point mutations that reduced ABFI binding in vitro. Analysis of the DED1 promoter showed that two ABFI-binding sites combine synergistically with an adjacent T-rich sequence to form a strong constitutive activator. The DED1 T-rich element acted synergistically with all other ABFI-binding sites and with binding sites for other multifunctional yeast activators. An examination of the properties of sequences surrounding ARS1 left open the possibility that ABFI enhances the initiation of DNA replication at ARS1 by transcriptional activation.

A natural case of RIP: degeneration of the DNA sequence in an ancestral tandem duplication

5S rRNA genes of Neurospora crassa are generally dispersed in the genome and are unmethylated. The xi-eta region of Oak Ridge strains represents an informative exception. Most of the cytosines in this region, which consists of a diverged tandem duplication of a 0.8-kilobase-pair segment including a 5S rRNA gene, appear to be methylated (E. U. Selker and J. N. Stevens, Proc. Natl. Acad. Sci. USA 82:8114-8118, 1985). Previous work demonstrated that the xi-eta region functions as a portable signal for de novo DNA methylation (E. U. Selker and J. N. Stevens, Mol. Cell. Biol. 7:1032-1038, 1987; E. U. Selker, B. C. Jensen, and G. A. Richardson, Science 238:48-53, 1987). To identify the structural basis of this property, we have isolated and characterized an unmethylated allele of the xi-eta region from N. crassa Abbott 4. The Abbott 4 allele includes a single 5S rRNA gene, theta, which is different from all previously identified Neurospora 5S rRNA genes. Sequence analysis suggests that the xi-eta region arose from the theta region by duplication of a 794-base-pair segment followed by 267 G.C to A.T mutations in the duplicated DNA. The distribution of these mutations is not random. We propose that the RIP process of N. crassa (E. U. Selker, E. B. Cambareri, B. C. Jensen, and K. R. Haack, Cell 51:741-752, 1987; E. U. Selker, and P. W. Garrett, Proc. Natl. Acad. Sci. USA 85:6870-6874, 1988; E. B. Cambareri, B. C. Jensen, E. Schabtach, and E. U. Selker, Science 244:1571-1575, 1989) is responsible for the numerous transition mutations and DNA methylation in the xi-eta region. A long homopurine-homopyrimidine stretch immediately following the duplicated segment is 9 base pairs longer in the Oak Ridge allele than in the Abbott 4 allele. Triplex DNA, known to occur in homopurine-homopyrimidine sequences, may have mediated the tandem duplication.

Genomic footprinting of a yeast tRNA gene reveals stable complexes over the 5'-flanking region

We have shown by genomic footprinting that the 5'-flanking region of the Saccharomyces cerevisiae tRNASUP53 gene is protected from DNase I digestion. The protected region has a 5' boundary at -40 (relative to the transcription initiation site) and extends into the coding region of the gene, with a 3' boundary at approximately +15. Although the DNase I protection over this region was much greater than at the A- and B-box internal promoters, point mutations within the A or B box that reduced transcription in vitro eliminated the upstream DNase I protection. This implies that formation of a stable complex over the 5'-flanking region is dependent on interaction of the gene with transcription factor IIIC but that stability of the complex may not require continued interaction with this factor. The DNase I protection under varied growth conditions further suggested that the upstream complex is composed of two or more components. The region over the transcription initiation site (approximately +15 to -10) was less protected in stationary-phase cultures, whereas the more upstream region (approximately -10 to -40) was protected in both exponential- and stationary-phase cultures.

A natural case of RIP: degeneration of the DNA sequence in an ancestral tandem duplication

5S rRNA genes of Neurospora crassa are generally dispersed in the genome and are unmethylated. The xi-eta region of Oak Ridge strains represents an informative exception. Most of the cytosines in this region, which consists of a diverged tandem duplication of a 0.8-kilobase-pair segment including a 5S rRNA gene, appear to be methylated (E. U. Selker and J. N. Stevens, Proc. Natl. Acad. Sci. USA 82:8114-8118, 1985). Previous work demonstrated that the xi-eta region functions as a portable signal for de novo DNA methylation (E. U. Selker and J. N. Stevens, Mol. Cell. Biol. 7:1032-1038, 1987; E. U. Selker, B. C. Jensen, and G. A. Richardson, Science 238:48-53, 1987). To identify the structural basis of this property, we have isolated and characterized an unmethylated allele of the xi-eta region from N. crassa Abbott 4. The Abbott 4 allele includes a single 5S rRNA gene, theta, which is different from all previously identified Neurospora 5S rRNA genes. Sequence analysis suggests that the xi-eta region arose from the theta region by duplication of a 794-base-pair segment followed by 267 G.C to A.T mutations in the duplicated DNA. The distribution of these mutations is not random. We propose that the RIP process of N. crassa (E. U. Selker, E. B. Cambareri, B. C. Jensen, and K. R. Haack, Cell 51:741-752, 1987; E. U. Selker, and P. W. Garrett, Proc. Natl. Acad. Sci. USA 85:6870-6874, 1988; E. B. Cambareri, B. C. Jensen, E. Schabtach, and E. U. Selker, Science 244:1571-1575, 1989) is responsible for the numerous transition mutations and DNA methylation in the xi-eta region. A long homopurine-homopyrimidine stretch immediately following the duplicated segment is 9 base pairs longer in the Oak Ridge allele than in the Abbott 4 allele. Triplex DNA, known to occur in homopurine-homopyrimidine sequences, may have mediated the tandem duplication.

Transcription factor IIIB generates extended DNA interactions in RNA polymerase III transcription complexes on tRNA genes

Transcription complexes that assemble on tRNA genes in a crude Saccharomyces cerevisiae cell extract extend over the entire transcription unit and approximately 40 base pairs of contiguous 5'-flanking DNA. We show here that the interaction with 5'-flanking DNA is due to a protein that copurifies with transcription factor TFIIIB through several steps of purification and shares characteristic properties that are normally ascribed to TFIIIB: dependence on prior binding of TFIIIC and great stability once the TFIIIC-TFIIIB-DNA complex is formed. SUP4 gene (tRNATyr) DNA that was cut within the 5'-flanking sequence (either 31 or 28 base pairs upstream of the transcriptional start site) was no longer able to stably incorporate TFIIIB into a transcription complex. The TFIIIB-dependent 5'-flanking DNA protein interaction was predominantly not sequence specific. The extension of the transcription complex into this DNA segment does suggest two possible explanations for highly diverse effects of flanking-sequence substitutions on tRNA gene transcription: either (i) proteins that are capable of binding to these upstream DNA segments are also potentially capable of stimulating or interfering with the incorporation of TFIIIB into transcription complexes or (ii) 5'-flanking sequence influences the rate of assembly of TFIIIB into stable transcription complexes.

Genomic footprinting of a yeast tRNA gene reveals stable complexes over the 5'-flanking region

We have shown by genomic footprinting that the 5'-flanking region of the Saccharomyces cerevisiae tRNASUP53 gene is protected from DNase I digestion. The protected region has a 5' boundary at -40 (relative to the transcription initiation site) and extends into the coding region of the gene, with a 3' boundary at approximately +15. Although the DNase I protection over this region was much greater than at the A- and B-box internal promoters, point mutations within the A or B box that reduced transcription in vitro eliminated the upstream DNase I protection. This implies that formation of a stable complex over the 5'-flanking region is dependent on interaction of the gene with transcription factor IIIC but that stability of the complex may not require continued interaction with this factor. The DNase I protection under varied growth conditions further suggested that the upstream complex is composed of two or more components. The region over the transcription initiation site (approximately +15 to -10) was less protected in stationary-phase cultures, whereas the more upstream region (approximately -10 to -40) was protected in both exponential- and stationary-phase cultures.

Transcription factor IIIB generates extended DNA interactions in RNA polymerase III transcription complexes on tRNA genes

Transcription complexes that assemble on tRNA genes in a crude Saccharomyces cerevisiae cell extract extend over the entire transcription unit and approximately 40 base pairs of contiguous 5'-flanking DNA. We show here that the interaction with 5'-flanking DNA is due to a protein that copurifies with transcription factor TFIIIB through several steps of purification and shares characteristic properties that are normally ascribed to TFIIIB: dependence on prior binding of TFIIIC and great stability once the TFIIIC-TFIIIB-DNA complex is formed. SUP4 gene (tRNATyr) DNA that was cut within the 5'-flanking sequence (either 31 or 28 base pairs upstream of the transcriptional start site) was no longer able to stably incorporate TFIIIB into a transcription complex. The TFIIIB-dependent 5'-flanking DNA protein interaction was predominantly not sequence specific. The extension of the transcription complex into this DNA segment does suggest two possible explanations for highly diverse effects of flanking-sequence substitutions on tRNA gene transcription: either (i) proteins that are capable of binding to these upstream DNA segments are also potentially capable of stimulating or interfering with the incorporation of TFIIIB into transcription complexes or (ii) 5'-flanking sequence influences the rate of assembly of TFIIIB into stable transcription complexes.

A discrete region centered 22 base pairs upstream of the initiation site modulates transcription of Drosophila tRNAAsn genes

We have studied the mechanism by which 5'-flanking sequences modulate the in vitro transcription of eucaryotic tRNA genes. Using deletion and linker substitution mutagenesis, we have found that the 5'-flanking sequences responsible for the different in vitro transcription levels of three Drosophila tRNA5Asn genes are contained within a discrete region centered 22 nucleotides upstream from the transcription initiation site. In conjunction with the A-box intragenic control region, this upstream transcription-modulatory region functions in the selection mechanism for the site of transcription initiation. Since the transcription-modulatory region directs the position of the start site and the actual sequence of the transcription-modulatory region determines the level of tRNAAsn gene transcription, the possibility is raised that the transcription-modulatory region directs a transcription initiation event similar to open complex formation at procaryotic promoters.

A discrete region centered 22 base pairs upstream of the initiation site modulates transcription of Drosophila tRNAAsn genes

We have studied the mechanism by which 5'-flanking sequences modulate the in vitro transcription of eucaryotic tRNA genes. Using deletion and linker substitution mutagenesis, we have found that the 5'-flanking sequences responsible for the different in vitro transcription levels of three Drosophila tRNA5Asn genes are contained within a discrete region centered 22 nucleotides upstream from the transcription initiation site. In conjunction with the A-box intragenic control region, this upstream transcription-modulatory region functions in the selection mechanism for the site of transcription initiation. Since the transcription-modulatory region directs the position of the start site and the actual sequence of the transcription-modulatory region determines the level of tRNAAsn gene transcription, the possibility is raised that the transcription-modulatory region directs a transcription initiation event similar to open complex formation at procaryotic promoters.

Transcription of the Drosophila melanogaster 5S RNA gene requires an upstream promoter and four intragenic sequence elements

Linker-scanning (LS) mutations were constructed spanning the length of the Drosophila melanogaster 5S RNA gene. In vitro transcription analysis of the LS 5S DNAs revealed five transcription control regions. One control region essential for transcription initiation was identified in the 5'-flanking sequence. The major sequence determinants of this upstream promoter region were located between coordinates -39 and -26 (-30 region), but important sequences extended to the transcription start site at position 1. Since mutations in the upstream promoter did not alter the ability of 5S DNA to sequester transcription factors into a stable transcription complex, it appears that this control region involved the interaction of RNA polymerase III. Active 5S DNA transcription additionally required the four intragenic control regions (ICRs) located between coordinates 3 and 18 (ICR I), 37 and 44 (ICR II), 48 and 61 (ICR III), and 78 and 98 (ICR IV). LS mutations in each ICR decreased the ability of 5S DNA to sequester transcription factors. ICR III, ICR IV, and the spacer sequence between were similar in sequence and position to the determinant elements of the multipartite ICR of Xenopus 5S DNA. The importance of ICR III and ICR IV in transcription initiation and in sequestering transcription factors suggests the presence of an activity in D. melanogaster similar to transcription factor TFIIIA of Xenopus laevis and HeLa cells. Transcription initiation of Drosophila 5S DNA was not eliminated by LS mutations in the spacer region even though these mutations reduced the ability of the TFIIIA-like activity to bind. The previously unidentified control regions ICR I and ICR II appear to be important for the interaction of a transcription factor activity, or multiple-factor activities, distinct from the TFIIIA-like activity. The interaction of this activity with ICR I directed the selection of the transcription start site.

Sequence differences upstream of the promoters are involved in the differential expression of the Xenopus somatic and oocyte 5S RNA genes

The Xenopus somatic and oocyte 5S RNA genes are differentially expressed in extracts of whole oocytes. In such extracts, sequence differences preceding the internal promoters significantly alter the relative activities of these genes. Following exchange of the sequences preceding the promoter, the activity of the somatic 5S gene decreased and that of the oocyte 5S gene increased. As a result, a 100 fold somatic transcriptional advantage was reduced to 5 fold. Analysis of deletion mutants showed that the relevant sequence differences are located between -34 and +37 relative to the initiation site. The observed transcriptional modulation is due both to sequence differences 5' to the initiation site and at positions 30 and 37 within the coding region.

Transcription of the Drosophila melanogaster 5S RNA gene requires an upstream promoter and four intragenic sequence elements

Linker-scanning (LS) mutations were constructed spanning the length of the Drosophila melanogaster 5S RNA gene. In vitro transcription analysis of the LS 5S DNAs revealed five transcription control regions. One control region essential for transcription initiation was identified in the 5'-flanking sequence. The major sequence determinants of this upstream promoter region were located between coordinates -39 and -26 (-30 region), but important sequences extended to the transcription start site at position 1. Since mutations in the upstream promoter did not alter the ability of 5S DNA to sequester transcription factors into a stable transcription complex, it appears that this control region involved the interaction of RNA polymerase III. Active 5S DNA transcription additionally required the four intragenic control regions (ICRs) located between coordinates 3 and 18 (ICR I), 37 and 44 (ICR II), 48 and 61 (ICR III), and 78 and 98 (ICR IV). LS mutations in each ICR decreased the ability of 5S DNA to sequester transcription factors. ICR III, ICR IV, and the spacer sequence between were similar in sequence and position to the determinant elements of the multipartite ICR of Xenopus 5S DNA. The importance of ICR III and ICR IV in transcription initiation and in sequestering transcription factors suggests the presence of an activity in D. melanogaster similar to transcription factor TFIIIA of Xenopus laevis and HeLa cells. Transcription initiation of Drosophila 5S DNA was not eliminated by LS mutations in the spacer region even though these mutations reduced the ability of the TFIIIA-like activity to bind. The previously unidentified control regions ICR I and ICR II appear to be important for the interaction of a transcription factor activity, or multiple-factor activities, distinct from the TFIIIA-like activity. The interaction of this activity with ICR I directed the selection of the transcription start site.

Sequence organization and putative regulatory elements in the 5S rRNA genes of two higher plants (Vigna radiata and Matthiola incana)

The tandemly arranged and clustered highly repeated 5S rRNA genes are investigated for two plants belonging to different higher plant families: Matthiola incana (Brassicaceae, Dilleniidae, Rosidae; 3600 5S rRNA genes/n) shows a homogeneous repeat size of 510 bp, whereas Vigna radiata (mung bean, former Phaseolus aureus, Fabaceae, Rosidae; approx. 4300 5S rRNA genes) has a repeat size of 215 bp. The mung-bean 5S rRNA coding region starts 5' with AGG and ends with CCT; Matthiola starts with GGG and ends with CCC. Striking is the strict occurrence of a 'TATA' box starting at nucleotide-28 similar to Neurospora crassa 5S rRNA genes. The 3' end is followed by CTTTT or GTTT stretches present in different numbers in the non-transcribed spacer suggesting a function in termination.

A common octamer motif binding protein is involved in the transcription of U6 snRNA by RNA polymerase III and U2 snRNA by RNA polymerase II

The structure of a Xenopus U6 gene promoter has been investigated. Three regions in the 5'-flanking sequences of the gene that are important for U6 expression are defined. Deletion of the first, between positions -156 and -280 relative to the site of transcription initiation, reduces transcription to roughly 5% of its original level. Deletion of the second, between -60 and -77, abolishes transcription. These regions contain not only functional but also sequence homology to the previously defined distal and proximal sequence elements (DSE and PSE) of the Xenopus U2 promoter, although U2 is transcribed by RNA polymerase II and U6 by RNA polymerase III. Competition experiments show that at least the distal sequence elements of the two promoters bind to a common factor both in vivo and in vitro. Part of the sequence recognized by this factor is the octamer motif (ATG-CAAAT). A sequence similar to the common RNA polymerase II TATA box is also shown to have an effect, albeit minor, on U6 transcription. The U6 coding region contains a good match to the A box, part of all previously characterized RNA polymerase III promoters. Deletion of this region has no apparent effect on the efficiency or accuracy of U6 transcription.

Transcription of Neurospora crassa 5 S rRNA genes requires a TATA box and three internal elements

The sequences required for transcription of Neurospora crassa 5S rRNA genes have been defined using a comprehensive set of deletion and substitution mutations introduced into two cloned genes. An upstream TATA box (consensus TCATAGA) located at -29 to -24, and three internal regions (D, A and C) localized to +19 to +30, +44 to +57 and +73 to +103, respectively, are absolutely required for transcription in vitro. The TATA box fixes the start point of transcription. The A and C regions correspond to the Xenopus 5S gene internal control region but the D region has no Xenopus homologue. The spacing of the three internal elements is very strict but the position of the TATA box can be varied by up to 16 base-pairs.

Xenopus tropicalis U6 snRNA genes transcribed by Pol III contain the upstream promoter elements used by Pol II dependent U snRNA genes

We have cloned and sequenced a 977bp DNA fragment, pXTU6-2, that represents the transcription unit for a Xenopus tropicalis U6 RNA gene. This basic repeating unit is reiterated ca.500-fold per haploid genome. Oocyte injections of pXTU6-2 led to the transcription of a mature-sized U6 RNA that, however, lacked internal 2'-O-methylations. These posttranscriptional modifications of U6 RNA might be cytoplasmic and could require its association with U4 RNA to be accomplished. The low alpha- amanitin sensitivity of U6 RNA synthesis in oocytes suggested that U6 RNA is transcribed by RNA polymerase III, consistent with features of the U6 RNA molecule which also contains a Box A- like intragenic control region. Inspection of X. tropicalis, mouse and human U6 DNA upstream sequences revealed the presence of a TATA box as well as of the proximal and enhancer (octamer motif) elements contained in snRNA genes transcribed by RNA polymerase II. We propose that U6 RNAs are synthesized by a specialized transcription complex consisting of RNA polymerase III and transcription factors, some of which are very likely shared with RNA polymerase II promoters.