A component of Drosophila RNA polymerase I promoter lies within the rRNA transcription unit

In and out of the rRNA genes: characterization of Pokey elements in the sequenced Daphnia genome

Background

Only a few transposable elements are known to exhibit site-specific insertion patterns, including the well-studied R-element retrotransposons that insert into specific sites within the multigene rDNA. The only known rDNA-specific DNA transposon, Pokey (superfamily: piggyBac) is found in the freshwater microcrustacean, Daphnia pulex. Here, we present a genome-wide analysis of Pokey based on the recently completed whole genome sequencing project for D. pulex.

Results

Phylogenetic analysis of Pokey elements recovered from the genome sequence revealed the presence of four lineages corresponding to two divergent autonomous families and two related lineages of non-autonomous miniature inverted repeat transposable elements (MITEs). The MITEs are also found at the same 28S rRNA gene insertion site as the Pokey elements, and appear to have arisen as deletion derivatives of autonomous elements. Several copies of the full-length Pokey elements may be capable of producing an active transposase. Surprisingly, both families of Pokey possess a series of 200 bp repeats upstream of the transposase that is derived from the rDNA intergenic spacer (IGS). The IGS sequences within the Pokey elements appear to be evolving in concert with the rDNA units. Finally, analysis of the insertion sites of Pokey elements outside of rDNA showed a target preference for sites similar to the specific sequence that is targeted within rDNA.

Conclusions

Based on the target site preference of Pokey elements and the concerted evolution of a segment of the element with the rDNA unit, we propose an evolutionary path by which the ancestors of Pokey elements have invaded the rDNA niche. We discuss how specificity for the rDNA unit may have evolved and how this specificity has played a role in the long-term survival of these elements in the subgenus Daphnia.

Sequence variation within the rRNA gene loci of 12 Drosophila species

Concerted evolution maintains at near identity the hundreds of tandemly arrayed ribosomal RNA (rRNA) genes and their spacers present in any eukaryote. Few comprehensive attempts have been made to directly measure the identity between the rDNA units. We used the original sequencing reads (trace archives) available through the whole-genome shotgun sequencing projects of 12 Drosophila species to locate the sequence variants within the 7.8-8.2 kb transcribed portions of the rDNA units. Three to 18 variants were identified in >3% of the total rDNA units from 11 species. Species where the rDNA units are present on multiple chromosomes exhibited only minor increases in sequence variation. Variants were 10-20 times more abundant in the noncoding compared with the coding regions of the rDNA unit. Within the coding regions, variants were three to eight times more abundant in the expansion compared with the conserved core regions. The distribution of variants was largely consistent with models of concerted evolution in which there is uniform recombination across the transcribed portion of the unit with the frequency of standing variants dependent upon the selection pressure to preserve that sequence. However, the 28S gene was found to contain fewer variants than the 18S gene despite evolving 2.5-fold faster. We postulate that the fewer variants in the 28S gene is due to localized gene conversion or DNA repair triggered by the activity of retrotransposable elements that are specialized for insertion into the 28S genes of these species.

Molecular characterization of the 5S ribosomal gene of the Bradysia hygida(Diptera:Sciaridae)

The rRNA genes are amongst the most extensively studied eukaryotic genes. They contain both highly conserved and rapidly evolving regions. The aim of this work was to clone and to sequence the Bradysia hygida 5S rDNA gene. A positive clone was sequenced and its 346 bp sequence was analyzed against the GenBank database. Sequence analysis revealed that the B. hygida 5S (Bh5S) rDNA gene is 120 bp long and is 87% identical to the aphid Acyrthosiphon magnoliae 5S rDNA gene. The Bh5S rDNA gene presents two unusual features: a GG pair at the 5' end of the gene sequence and the localization of the polyT signal immediately after the 3' end of the gene. In situ hybridization experiments revealed that the Bh5S rDNA gene is localized in the autosomal A chromosome.

The structure of a single unit of ribosomal RNA gene (rDNA) including intergenic subrepeats in the Australian bulldog ant Myrmecia croslandi (Hymenoptera: Formicidae)

A complete single unit of a ribosomal RNA gene (rDNA) of M. croslandi was sequenced. The ends of the 18S, 5.8S and 28S rRNA genes were determined by using the sequences of D. melanogaster rDNAs as references. Each of the tandemly repeated rDNA units consists of coding and non-coding regions whose arrangement is the same as that of D. melanogaster rDNA. The intergenic spacer (IGS) contains, as in other species, a region with subrepeats, of which the sequences are different from those previously reported in other insect species. The length of IGSs was estimated to be 7-12 kb by genomic Southern hybridization, showing that an rDNA repeating unit of M. croslandi is 14-19 kb-long. The sequences of the coding regions are highly conserved, whereas IGS and ITS (internal transcribed spacer) sequences are not. We obtained clones with insertions of various sizes of R2 elements, the target sequence of which was found in the 28S rRNA coding region. A short segment in the IGS that follows the 3' end of the 28S rRNA gene was predicted to form a secondary structure with long stems.

Functional analysis of diploid wheat rRNA promoter by transient expression

The rRNA gene promoter regions of three diploid wheats Triticum boeoticum Boiss, Triticum urartu Tum. ex Gandil, and Triticum monococcum L. have been sequenced and analyzed. It has been found that the rRNA promoter initiation regions of diploid wheats contain the sequences, which differ from the evolutionary conserved TATAGTAGG (+1 is underlined) motif of monocots. The transient expression assay in wheat protoplasts confirmed that cloned sequences are active promoters. Deletion analysis showed that the promoter sequence localized between -113 and +15 (relative to +1) is enough to direct RNA polymerase I-dependent transcription.

Common DNA structural features exhibited by eukaryotic ribosomal gene promoters

Nucleotide sequences of DNA regions containing eukaryotic ribosomal promoters were analysed using strategies designed to reveal sequence-directed structural features. DNA curvature, duplex stability and pattern of twist angle variation were studied by computer modelling. Although ribosomal promoters are known to lack sequence homology (unless very closely related species are considered), investigation of these structural characteristics uncovered striking homologies in all the taxonomic groups examined so far. This wide conservation of DNA structures, while DNA sequence is not conserved, suggests that the determined structures are fundamental for ribosomal promoter function. Moreover, this result agrees well with the recent observations showing that RNA polymerase I transcription factors have not evolved as intensively as previously suspected.

Structural analysis of two length variants of the rDNA intergenic spacer from Eruca sativa

Restriction enzyme analysis of the rRNA genes of Eruca sativa indicated the presence of many length variants within a single plant and also between different cultivars which is unusual for most crucifers studied so far. Two length variants of the rDNA intergenic spacer (IGS) from a single individual E. sativa (cv. Itsa) plant were cloned and characterized. The complete nucleotide sequences of both the variants (3 kb and 4 kb) were determined. The intergenic spacer contains three families of tandemly repeated DNA sequences denoted as A, B and C. However, the long (4 kb) variant shows the presence of an additional repeat, denoted as D, which is a duplication of a 224 bp sequence just upstream of the putative transcription initiation site. Repeat units belonging to the three different families (A, B and C) were in the size range of 22 to 30 bp. Such short repeat elements are present in the IGS of most of the crucifers analysed so far. Sequence analysis of the variants (3 kb and 4 kb) revealed that the length heterogeneity of the spacer is located at three different regions and is due to the varying copy numbers of repeat units belonging to families A and B. Length variation of the spacer is also due to the presence of a large duplication (D repeats) in the 4 kb variant which is absent in the 3 kb variant. The putative transcription initiation site was identified by comparisons with the rDNA sequences from other plant species.

In vitro transcription of Drosophila rRNA genes shows stimulation by a phorbol ester and serum

The phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) and serum both stimulate rapid increases in the transcription of Drosophila rRNA genes in vivo. Here we report that this stimulation is observed in in vitro transcription assays using nuclear extracts from cells treated with TPA or serum. Experiments in which extracts from TPA- or serum-treated cells were mixed with extracts from cells grown in serum-restricted medium showed that there was an increased RNA polymerase I (Pol I) activity present in the cell extracts from treated cells. We used a series of plasmids that had been deleted in the region 5' to the start site of rRNA transcription to determine which sequences were necessary to support the increased transcription seen in extracts from stimulated cells. DNA templates that contain sequences between -150 and +32 (with +1 as the Pol I transcription start site) show dramatic increases in transcription with TPA- and serum-stimulated cell extracts; however, templates that contain 5' sequences to -60 or -43 show at most one-third of the stimulation level of transcription in nuclear extracts from treated cells in comparison with untreated cell extracts. The 5' deletion to -34 abolishes the stimulation effect and drops the basal-level transcription by 20-fold. These results indicate that the regulation of Pol I transcription in Drosophila cells by serum and TPA requires two DNA elements, sequences from -150 to -60 (upstream control element) and sequences from -43 to -34 (a portion of the core promoter.

In vitro transcription of Drosophila rRNA genes shows stimulation by a phorbol ester and serum

The phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) and serum both stimulate rapid increases in the transcription of Drosophila rRNA genes in vivo. Here we report that this stimulation is observed in in vitro transcription assays using nuclear extracts from cells treated with TPA or serum. Experiments in which extracts from TPA- or serum-treated cells were mixed with extracts from cells grown in serum-restricted medium showed that there was an increased RNA polymerase I (Pol I) activity present in the cell extracts from treated cells. We used a series of plasmids that had been deleted in the region 5' to the start site of rRNA transcription to determine which sequences were necessary to support the increased transcription seen in extracts from stimulated cells. DNA templates that contain sequences between -150 and +32 (with +1 as the Pol I transcription start site) show dramatic increases in transcription with TPA- and serum-stimulated cell extracts; however, templates that contain 5' sequences to -60 or -43 show at most one-third of the stimulation level of transcription in nuclear extracts from treated cells in comparison with untreated cell extracts. The 5' deletion to -34 abolishes the stimulation effect and drops the basal-level transcription by 20-fold. These results indicate that the regulation of Pol I transcription in Drosophila cells by serum and TPA requires two DNA elements, sequences from -150 to -60 (upstream control element) and sequences from -43 to -34 (a portion of the core promoter.

Tumor suppressor genes

For the past decade, cellular oncogenes have attracted the attention of biologists intent on understanding the molecular origins of cancer. As the present decade unfolds, oncogenes are yielding their place at center stage to a second group of actors, the tumor suppressor genes, which promise to teach us equally important lessons about the molecular mechanisms of cancer pathogenesis.

The mouse ribosomal DNA promoter has more stringent requirements in vivo than in vitro

Using mouse ribosomal DNA templates bearing polymerase I terminators to prevent transcriptional interference (S. L. Henderson, K. Ryan, and B. Sollner-Webb, Genes Dev. 3:212-223, 1989) and facilitate promoter analysis in intact cells, we demonstrate that a -140 promoter domain (as well as the core region) is essential for appreciable levels of initiation in vivo. This in vivo polymerase I promoter can also be detected in vitro but only under very stringent conditions.

The mouse ribosomal DNA promoter has more stringent requirements in vivo than in vitro

Using mouse ribosomal DNA templates bearing polymerase I terminators to prevent transcriptional interference (S. L. Henderson, K. Ryan, and B. Sollner-Webb, Genes Dev. 3:212-223, 1989) and facilitate promoter analysis in intact cells, we demonstrate that a -140 promoter domain (as well as the core region) is essential for appreciable levels of initiation in vivo. This in vivo polymerase I promoter can also be detected in vitro but only under very stringent conditions.

Promoter variation in the ribosomal RNA genes in Drosophila melanogaster strains

The sequences of thirty D. melanogaster ribosomal DNA promoter regions have been determined. Fifteen of these were isolated from a wild population recently captured in North Wootten, England. The other fifteen were isolated from an inbred laboratory strain. The overall level of variation is almost twice as high in the North Wootten strain as in the inbred laboratory strain. Two mutations at nucleotides -17 and -21 relative to transcription start, fall directly within a region known to be transcriptionally important. The sequences are also compared to eight previously published sequences from another D. melanogaster strain, Oregon R. Two of these eight clones have a -17 mutation identical to the one found in this study, suggesting that this polymorphism is widespread. Strikingly, all eight of these clones carry two single base pair changes not found in any of the other thirty clones, indicating the extent with which promoter variants can be homogenized and fixed in a population. Polymorphisms show different levels of homogenization within the rDNA unit spacer repeats or between different arrays depending on the location of the polymorphism. This has implications for the evolution of the observed species-specific transcription of ribosomal RNA genes.

The promoters and spacers in the rDNAs of the melanogaster species subgroup of Drosophila

The spacer sequences of rDNAs of members of the melanogaster species subgroup of Drosophila (melanogaster, simulans, mauritiana, teissieri, and yakuba) have been compared. The external transcribed spacers (ETSs; the region encoding the 5' end of the primary transcript, upstream from the 18S sequences) are highly conserved between in D. melanogaster, D. simulans and D. mauritiana, whereas the more distantly related D. yakuba and D. teissieri differ in having apparent deletions of 22 and 27 bp, respectively, in this region. The divergence of nucleotide sequence upstream from the transcription start points is consistent with the established phylogeny of the five species. The sequences between bp positions -47 and +24 from the primary transcription start point show extremely little variation between each species. This is also the case for sequences between the approximate bp positions -140 to -125 and -85 to -70. This could indicate a functional importance not only of the sequences next to the transcription start point, but also of these upstream regions. An array of 240-bp repeats can be found at a comparable distance upstream from the transcription start point in each species. Matrix homology comparisons indicate that for each species not only is the sequence at the primary transcription start point duplicated within the 240-bp repeats as previously reported for D. melanogaster, but that this is part of a longer interrupted duplication which includes a region of strong similarity with the sequence between the approximate positions -105 to -65. This region is contained within one of the regions upstream from the transcription start point that is strongly conserved between the species. This sequence may therefore have functional significance not only for the transcription of the rRNA precursor, but also for transcription of the so-called NTS sequences which is now known to occur. The 240-bp arrays are themselves highly conserved within a species indicating that homogenisation mechanisms are operative. The divergence of these arrays between species is consistent with the phylogenetic tree. The 3' sequences of the primary transcription unit, now known to be RNA-processing sites, are also highly similar between the species. Immediately downstream from these sites there is little homology between the rDNA of the different species, until 95-bp tandem arrays are reached in each case.

Analysis of the Drosophila rDNA promoter by transient expression

We have examined the expression of the bacterial gene chloramphenicol acetyl transferase (CAT) under the control of the Drosophila rDNA promoter following transfection into Drosophila tissue culture cells. Constructs having an entire NTS, corresponding to approximately 3640 base pairs of upstream rDNA sequence, or constructs with 306 base pairs of upstream sequence respectively, are transcribed at 5 fold or 2 fold higher levels than a construct with 43 base pairs of upstream DNA. In co-transfection experiments, the construct with the entire NTS competes for transcription 20 fold more effectively than the construct with 306 base pairs of upstream sequence. Constructs having either 72 base pairs or 60 base pairs of upstream rDNA sequences, on the other hand, are transcribed very much less efficiently than constructs with either 306 bp or with only 43 bp of upstream DNA. These sequences, which reduce levels of rDNA transcription in the absence of additional upstream DNA, lie in a region in which the rDNA promoter differs from its duplications within the NTS.

Localization of the in vivo and in vitro transcription initiation site and comparative analysis of the flanking sequences in the two main size classes of Ascaris lumbricoides rDNA

An accurate in vitro transcription system which utilizes the cloned 8.8 and 8.4 kb size classes of Ascaris rRNA genes (pAlr8 and pAlr13) and two kinds of cellular extracts from Ascaris oogonia has been established. Both rDNA containing plasmids are efficiently transcribed in vitro by RNA polymerase I from a unique site of rDNA which corresponds to the in vivo initiation site. The in vitro transcription product has a triphosphorylated 5'-end and starts on a G localized 414 bp (pAlr8) upstream of the beginning of the mature 18S rRNA. The promoter region has been delimited by testing the in vitro template activity of a series of restriction fragments. The region essential for the accuracy of initiation is contained within nucleotides -72 to +65, but full efficiency of transcription requires the additional presence of the region from nucleotides +66 to +84. The sequences upstream from position -72 do not appear to modulate the efficiency of specific in vitro initiation. Furthermore, the sequences flanking the transcription initiation site from position -1500 to +570 have been determined in the two cloned representatives of the two rDNA main size classes.

Sequestration analysis for RNA polymerase I transcription factors with various deletion and point mutations reveals different functional regions of the mouse rRNA gene promoter

We compared the ability of various deletion and substitution mutants of the mouse rRNA gene promoter to bind essential factors required for accurate transcription initiation by RNA polymerase I. Different amounts of a competitor template were first incubated with a mouse cell extract containing the whole complement of factors and RNA polymerase I, and then a tester template was added for the second incubation. Transcription was started by adding nucleoside triphosphates (one labeled), and the accurate transcripts were determined on a gel. The results indicated that the ability of 5' deletion mutants to sequester essential factors decreased almost concurrently with the impairment of in vitro transcription activity, whereas when the promoter sequence was removed from the 3' side, the transcription activity decreased earlier and more drastically than the sequestration ability. Similar, though not identical, results were obtained by preincubation with fraction D separated on a phosphocellulose column, indicating that the major factor which was sequestered was TFID, the species-dependent transcription initiation factor that binds first to the promoter in the initiation reaction (H. Kato, M. Nagamine, R. Kominami, and M. Muramatsu, Mol. Cell. Biol. 6:3418-3427, 1986). Compilation of the data suggests that a region inside the 5' half of the core promoter (-40 to -1) is essential for the binding of TFID. The 3' half of the promoter (-1 to downstream) is not essential for the binding of TFID but is highly important for an efficient transcription initiation. A strong down-mutant with a one-base substitution at -16 (G to A) had a reduced ability to bind to TFID, whereas a null mutant with a single base substitution at -7 (G to A) showed a binding ability similar to that of the wild-type promoter when tested with whole-cell extract. This null mutant, however, could not sequester the TFID well when incubated with fraction D alone, suggesting that the binding of TFID with this mutant is unstable in the absence of another factor(s) present in cell extract. The factor is not TFIA, which binds after TFID, because the addition of fraction A containing TFIA did not cause TFID to bind to the mutant. The availability of different mutants having lesions at different steps of transcription initiation will provide a powerful tool for the dissection of the initiation reaction of the RNA gene.

Evolutionary divergence of promoters and spacers in the rDNA family of four Drosophila species. Implications for molecular coevolution in multigene families

The organization and sequence of the rDNA multigene family of four Drosophila species (melanogaster, orena, virilis and hydei) have been compared in order to understand the quality and quantity of the differences which are involved with interspecific divergence of promoters and the polymerase I complexes (molecular coevolution). Each species has an intergenic spacer (IGS) made up of subrepeats which contain duplications of the promoter. Major structural and point-mutational differences exist, most of which have been spread by unequal crossingover through the family and species. Structural differences involve the types, lengths and copy-number of the IGS subrepeats, and the lengths and position of "unique" regions between blocks of repeats. The 240 base-pair repeat array shared by D. melanogaster and D. orena has been replaced by a 220 base-pair repeat, and the 95 and 330 base-pair arrays are absent altogether in D. virilis and D. hydei. The length of the "unique" region between the 240/220 base-pair arrays and the start of transcription varies, with the unusual situation of the last of the 220 repeats ending at the external transcribed spacer (ETS) boundary in D. virilis. Other structural differences involve regions of high cryptic simplicity arising from slippage in D. virilis and D. hydei IGSs. Sequence analysis of IGS and the ETSs indicates that the rDNA is not uniformly divergent throughout its length. Apart from the genes, there are regions of relatively high conservation covering the promoter regions and at some but not all potential RNA processing sites. The conserved promoter regions are more extensive within each pair of species D. melanogaster versus D. orena and D. virilis versus D. hydei, in keeping with their phylogenetic distances. Slippage-like mechanisms are involved with large numbers of deletions/insertions that make up the ETS differences between the species. Patterns of shared mutations between IGS subrepeats indicate stages of transition during rDNA differentiation by continual homogenization. The simultaneous operation of different turnover mechanisms, at different periodicities and rates, generates a complex picture of reorganization, some of which would influence the process of molecular coevolution in the family.

Sequestration analysis for RNA polymerase I transcription factors with various deletion and point mutations reveals different functional regions of the mouse rRNA gene promoter

We compared the ability of various deletion and substitution mutants of the mouse rRNA gene promoter to bind essential factors required for accurate transcription initiation by RNA polymerase I. Different amounts of a competitor template were first incubated with a mouse cell extract containing the whole complement of factors and RNA polymerase I, and then a tester template was added for the second incubation. Transcription was started by adding nucleoside triphosphates (one labeled), and the accurate transcripts were determined on a gel. The results indicated that the ability of 5' deletion mutants to sequester essential factors decreased almost concurrently with the impairment of in vitro transcription activity, whereas when the promoter sequence was removed from the 3' side, the transcription activity decreased earlier and more drastically than the sequestration ability. Similar, though not identical, results were obtained by preincubation with fraction D separated on a phosphocellulose column, indicating that the major factor which was sequestered was TFID, the species-dependent transcription initiation factor that binds first to the promoter in the initiation reaction (H. Kato, M. Nagamine, R. Kominami, and M. Muramatsu, Mol. Cell. Biol. 6:3418-3427, 1986). Compilation of the data suggests that a region inside the 5' half of the core promoter (-40 to -1) is essential for the binding of TFID. The 3' half of the promoter (-1 to downstream) is not essential for the binding of TFID but is highly important for an efficient transcription initiation. A strong down-mutant with a one-base substitution at -16 (G to A) had a reduced ability to bind to TFID, whereas a null mutant with a single base substitution at -7 (G to A) showed a binding ability similar to that of the wild-type promoter when tested with whole-cell extract. This null mutant, however, could not sequester the TFID well when incubated with fraction D alone, suggesting that the binding of TFID with this mutant is unstable in the absence of another factor(s) present in cell extract. The factor is not TFIA, which binds after TFID, because the addition of fraction A containing TFIA did not cause TFID to bind to the mutant. The availability of different mutants having lesions at different steps of transcription initiation will provide a powerful tool for the dissection of the initiation reaction of the RNA gene.

Transcriptional role for the nontranscribed spacer of rat ribosomal DNA

In vitro transcription of the rat rRNA gene led to the identification of a region within a 3.4-kilobase fragment of the nontranscribed spacer (NTS) which significantly increased the transcription of rat ribosomal DNA. Promoter constructs containing this region were transcribed up to 17-fold more efficiently in vitro than templates with only 167 or 286 base pairs of NTS. This effect was also observed when the 3.4-kb fragment of the NTS was subcloned in the opposite orientation and 4 kb upstream of the promoter. The region responsible for the enhanced level of transcription was found between -286 and -1018. The results of order-of-addition experiments suggested that the enhanced level of transcription was the result of the formation of a stable complex between a trans-acting factor and the nontranscribed spacer. DNA-protein binding assays demonstrated that the same region of the NTS determined to have enhancer activity also specifically bound a proteinase K-sensitive factor present in nuclear extracts. The sequence of this region was not found to have any significant homology with the promoter of the rat rRNA gene. This is the first report to assign a transcriptional role to the NTS of a mammalian rRNA gene.

Upstream domains of the Xenopus laevis rDNA promoter are revealed in microinjected oocytes

The DNA sequences involved in promoting transcription of the Xenopus laevis rRNA genes were determined by microinjecting a series of deletion mutants into oocyte nuclei. A very small promoter region is sufficient to direct efficient transcription when templates are microinjected at high rDNA concentration, since 5'delta- 9 and 3'delta +6 templates are fully active. However, as the concentration of injected template is decreased, an increasing requirement for upstream domains, extending to nucleotide approximately -170, is observed. The major downstream border of the required region does not change. This apparently expanding 5' promoter border results from the fact that, as the rDNA concentration is decreased, transcription from templates lacking the upstream promoter domain falls off much more sharply than does transcription from a complete promoter. In fact, the deleted promoters are virtually inactive below a threshold rDNA concentration. It is indeed the rDNA concentration that is important, for coinjected vector DNA does not increase the level of transcription obtained from low concentrations of the 5' deletions. From these data we conclude that polymerase I transcription factors can recognize and initiate transcription from a small core promoter domain, but that sequences extending upstream to nucleotide approximately -170 increase the efficiency of initiation. A model is presented that could account for these results.

A transcription terminator located upstream of the mouse rDNA initiation site affects rRNA synthesis

Mouse ribosomal genes have a short sequence upstream of the transcription initiation site that is related in structure and function to the terminator boxes previously identified at the 3' end of the transcription unit. This upstream terminator recognizes the same protein factor as the 3'-terminal sites and is able to terminate RNA polymerase I transcription in vitro. S1 mapping and nucleolar run-on experiments reveal the presence of 5'-terminal spacer transcripts that are terminated at this site. These transcripts probably derive from spacer promoters, one of which has been identified approximately 2 kb upstream of the pre-rRNA start site. The interaction of a specific nuclear factor with the upstream terminator increases the efficiency of initiation, suggesting that transcription termination and initiation at the adjacent promoter work in an interrelated fashion.

Precise assignment of the heavy-strand promoter of mouse mitochondrial DNA: cognate start sites are not required for transcriptional initiation

Transcription of the heavy strand of mouse mitochondrial DNA starts from two closely spaced, distinct sites located in the displacement loop region of the genome. We report here an analysis of regulatory sequences required for faithful transcription from these two sites. Data obtained from in vitro assays demonstrated that a 51-base-pair region, encompassing nucleotides -40 to +11 of the downstream start site, contains sufficient information for accurate transcription from both start sites. Deletion of the 3' flanking sequences, including one or both start sites to -17, resulted in the initiation of transcription by the mitochondrial RNA polymerase from alternative sites within vector DNA sequences. This feature places the mouse heavy-strand promoter uniquely among other known mitochondrial promoters, all of which absolutely require cognate start sites for transcription. Comparison of the heavy-strand promoter with those of other vertebrate mitochondrial DNAs revealed a remarkably high rate of sequence divergence among species.

The core promoter of mouse rDNA consists of two functionally distinct domains

We have determined the sequences constituting the minimal promoter of mouse rDNA. A very small region immediately upstream of the transcription start site (from -1 to -39) is sufficient to direct correct transcription initiation. Sequences immediately downstream of the transcription start site (+1 to +11) increase the efficiency of transcription initiation. Point mutations within the core promoter have been generated and assayed for their effects on template activity and on interaction with the pol I specific transcription factor TIF-IB. The core promoter element appears to consist of two functionally different domains. The distal sequence motif from position -22 to -16 is recognized by factor TIF-IB. Mutations within this region lead to similar changes of both template activity and binding of TIF-IB. Two point mutations within the proximal sequence motif from -15 to -1 do not affect TIF-IB binding although they severely impair transcription initiation. It is suggested, that this proximal region plays a role in the assembly of functional transcription initiation complexes rather than in the primary binding of TIF-IB.

Precise assignment of the heavy-strand promoter of mouse mitochondrial DNA: cognate start sites are not required for transcriptional initiation

Transcription of the heavy strand of mouse mitochondrial DNA starts from two closely spaced, distinct sites located in the displacement loop region of the genome. We report here an analysis of regulatory sequences required for faithful transcription from these two sites. Data obtained from in vitro assays demonstrated that a 51-base-pair region, encompassing nucleotides -40 to +11 of the downstream start site, contains sufficient information for accurate transcription from both start sites. Deletion of the 3' flanking sequences, including one or both start sites to -17, resulted in the initiation of transcription by the mitochondrial RNA polymerase from alternative sites within vector DNA sequences. This feature places the mouse heavy-strand promoter uniquely among other known mitochondrial promoters, all of which absolutely require cognate start sites for transcription. Comparison of the heavy-strand promoter with those of other vertebrate mitochondrial DNAs revealed a remarkably high rate of sequence divergence among species.

Transient expression of Drosophila melanogaster rDNA promoter into cultured Drosophila cells

Recombinant plasmids that carry the bacterial CAT gene under the transcriptional control of the D. melanogaster rDNA promoter have been introduced by transfection into cultured Schneider II Drosophila cells and their template activity followed at the RNA and protein level. While no CAT enzyme activity is measurable 48 hrs after transfection, high levels of hybrid rRNA-CAT transcripts that originate at the authentic rRNA start site are detected by S1 mapping analysis. The interval -180/+34 of a rDNA transcriptional unit is sufficient to ensure faithful polymerase I transcription. However, the presence of a complete NTS (non transcribed spacer) region greatly enhances the transcriptional activity of exogenously added rDNA templates. Competition experiments between constructs carrying different amounts of NTS sequences indicate that spacer segments confer a transcriptional advantage efficiently attracting necessary transcription factors and/or polymerase I molecules.

Transcriptional role for the nontranscribed spacer of rat ribosomal DNA

In vitro transcription of the rat rRNA gene led to the identification of a region within a 3.4-kilobase fragment of the nontranscribed spacer (NTS) which significantly increased the transcription of rat ribosomal DNA. Promoter constructs containing this region were transcribed up to 17-fold more efficiently in vitro than templates with only 167 or 286 base pairs of NTS. This effect was also observed when the 3.4-kb fragment of the NTS was subcloned in the opposite orientation and 4 kb upstream of the promoter. The region responsible for the enhanced level of transcription was found between -286 and -1018. The results of order-of-addition experiments suggested that the enhanced level of transcription was the result of the formation of a stable complex between a trans-acting factor and the nontranscribed spacer. DNA-protein binding assays demonstrated that the same region of the NTS determined to have enhancer activity also specifically bound a proteinase K-sensitive factor present in nuclear extracts. The sequence of this region was not found to have any significant homology with the promoter of the rat rRNA gene. This is the first report to assign a transcriptional role to the NTS of a mammalian rRNA gene.

Upstream domains of the Xenopus laevis rDNA promoter are revealed in microinjected oocytes

The DNA sequences involved in promoting transcription of the Xenopus laevis rRNA genes were determined by microinjecting a series of deletion mutants into oocyte nuclei. A very small promoter region is sufficient to direct efficient transcription when templates are microinjected at high rDNA concentration, since 5'delta- 9 and 3'delta +6 templates are fully active. However, as the concentration of injected template is decreased, an increasing requirement for upstream domains, extending to nucleotide approximately -170, is observed. The major downstream border of the required region does not change. This apparently expanding 5' promoter border results from the fact that, as the rDNA concentration is decreased, transcription from templates lacking the upstream promoter domain falls off much more sharply than does transcription from a complete promoter. In fact, the deleted promoters are virtually inactive below a threshold rDNA concentration. It is indeed the rDNA concentration that is important, for coinjected vector DNA does not increase the level of transcription obtained from low concentrations of the 5' deletions. From these data we conclude that polymerase I transcription factors can recognize and initiate transcription from a small core promoter domain, but that sequences extending upstream to nucleotide approximately -170 increase the efficiency of initiation. A model is presented that could account for these results.

Expression of ribosomal insertion in Drosophila: sensitivity to intercalating drugs

Ribosomal insertions in Drosophila are transcribed at very low levels. The abundance of the most prominent 0.8 kb type 1 insertion transcript increased up to 60-fold when cultured cells were exposed to the DNA intercalating drug chloroquine. After injection of insertion-containing rDNA in circular form into Xenopus laevis oocytes an apparently identical 0.8 kb insertion transcript was synthesized, and its accumulation was stimulated several fold by coinjection of chloroquine or ethidium bromide. We suggest that ribosomal insertions are assembled in a chromatin conformation that lacks unconstrained torsional stress, accounting for the inactivity of these DNA regions; introduction of stress by intercalation results in activation of transcription from the insertion sequences.

A purified transcription factor (TIF-IB) binds to essential sequences of the mouse rDNA promoter

A transcription factor that is specific for mouse rDNA has been partially purified from Ehrlich ascites cells. This factor [designated transcription initiation factor (TIF)-IB] is required for accurate in vitro synthesis of mouse rRNA in addition to RNA polymerase I and another regulatory factor, TIF-IA. TIF-IB activity is present in extracts both from growing and nongrowing cells in comparable amounts. Prebinding competition experiments with wild-type and mutant templates suggest that TIF-IB interacts with the core control element of the rDNA promoter, which is located immediately upstream of the initiation site. The specific binding of TIF-IB to the RNA polymerase I promoter is demonstrated by exonuclease III protection experiments. The 3' border of the sequences protected by TIF-IB is shown to be on the coding strand at position -21 and on the noncoding strand at position -7. The results suggest that direct binding of TIF-IB to sequences in the core promoter element is the mechanism by which this factor imparts promoter selectivity to RNA polymerase I.

Characterization of the region around the start point of transcription of ribosomal RNA in the Chinese hamster

The initiation site for ribosomal RNA transcription in the Chinese hamster was identified and the sequence around and upstream determined. The start point region shows considerable homology with comparable regions in the mouse and rat. In the Chinese hamster, the region between bp -700 and -200 consists of imperfect repeats approximately 120-130 bp in length which are flanked by T-rich regions. The region within each repeat which is homologous with an adjacent repeat decreases in length as the start point is approached. The final promoter-proximal repeat preserves only an 11-bp region of the promoter-distal repeats. This short sequence, termed the repeat core, appears with a periodicity of about 120-130 bp in the Chinese hamster, and is conserved in both mouse and rat. In humans, a short repeated sequence occupies similar positions, suggesting that while complete 120-130-bp repeats are not a feature of all mammalian RNA polymerase I promoter-proximal r X DNA spacers, a short sequence repeating with approximate 120-130-bp periodicity may be such a feature.

Growth-dependent regulation of rRNA synthesis is mediated by a transcription initiation factor (TIF-IA)

Mouse RNA polymerase I requires at least two chromatographically distinct transcription factors (designated TIF-IA and TIF-IB) to initiate transcription accurately and efficiently in vitro. In this paper we describe the partial purification of TIF-IA by a four-step fractionation procedure. The amount or activity of TIF-IA fluctuates in response to the physiological state of the cells. Extracts from quiescent cells are incapable of specific transcription and do not contain detectable levels of TIF-IA. Transcriptionally inactive extracts can be restored by the addition of TIF-IA preparations that have been highly purified from exponentially growing cells. During the fractionating procedure TIF-IA co-purifies with RNA polymerase I, suggesting that it is functionally associated with the transcribing enzyme. We suggest that only those enzyme molecules that are associated with TIF-IA are capable to interact with TIF-IB and to initiate transcription.

The ribosomal RNA promoter of Acanthamoeba castellanii determined by transcription in a cell-free system

The DNA sequences required for faithful initiation of ribosomal RNA transcription were determined. BAL-31 digestion was used to modify the rDNA template by introducing deletions from its 3'- and 5'-ends. The resulting mutant DNAs were tested for template activity individually or in competition with wild type utilizing an in vitro transcription system from Acanthamoeba castellanii. The results identify the sequence extending from -31 to +8 to be absolutely required for transcription. In addition; when the region between -47 and -32 is left intact, transcription is augmented.

A complex control region of the mouse rRNA gene directs accurate initiation by RNA polymerase I

To determine the size and location of the mouse rDNA promoter, we constructed systematic series of deletion mutants approaching the initiation site from the 5' and 3' directions. These templates were transcribed in vitro under various conditions with S-100 and whole-cell extracts. Surprisingly, the size of the rDNA region that determines the level of transcription differed markedly, depending on the reaction conditions. In both kinds of cell extracts, the apparent 5' border of the promoter was at residue ca. -27 under optimal transcription conditions, but as reaction conditions became less favorable, the 5' border moved progressively out to residues -35, -39, and -45. The complete promoter, however, extends considerably further, for under other nonoptimal conditions, we observed major effects of promoter domains extending in the 5' direction to positions ca. -100 and -140. In contrast, the apparent 3' border of the mouse rDNA promoter was at residue ca. +9 under all conditions examined. We also show that the subcloned rDNA region from -39 to +9 contains sufficient information to initiate accurately and that the region between +2 and +9 can influence the specificity of initiation. These data indicate that, although the polymerase I transcription factors recognize and accurately initiate with only the sequences downstream of residue -40, sequences extending out to residue -140 greatly favor the initiation reaction; presumably, this entire region is involved in rRNA transcription in vivo.

Presence of a limited number of essential nucleotides in the promoter region of mouse ribosomal RNA gene

Point mutations are introduced into a mouse rDNA fragment containing the promoter region by a sodium bisulfite method and the mutants are tested for the ability of accurate transcription initiation in vitro. The results indicate that the change, G to A, at -7 completely eliminates the promoter activity, and those at -16 and at -25 decrease it to about 10% and 50%, respectively. On the other hand, the substitutions at +9, +4, -2, -9 and -39 do not alter the template activity significantly. It is concluded that there are limited but distinct nucleotides that are essential for the transcription initiation of this gene. This sort of absolute requirement for single specific bases is not reported in protein coding genes transcribed by RNA polymerase II. We propose that these rigid recognition signals which we have found are the molecular basis for the strong species-dependency of the transcription machinery of RNA polymerase I system. A model is presented in which a transcription factor interacts with the rDNA promoter from one side of the DNA double-helix with essential contacts at these bases.

Conserved arrangements of repeated DNA sequences in nontranscribed spacers of ciliate ribosomal RNA genes: evidence for molecular coevolution

We have analyzed the nucleotide sequences of the nontranscribed spacer (NTS) and transcription initiation and termination regions of the extrachromosomal rDNAs of the ciliated protozoans Tetrahymena thermophila and Glaucoma chattoni. The sequences surrounding the sites of transcription initiation and termination are highly conserved. The only extensive homologies of the NTS regions occur in five sets of dispersed repetitive sequences. Type I, II and III repeats in the 5' NTS are strongly conserved in sequence between Tetrahymena and Glaucoma in the case of the type I and III repeats, and in location relative to the transcription initiation site in the case of type I and II repeats. We identify two new repeat types, designated IV and V, in the 3' NTS. The sequence of type IV repeats, and the location relative to the transcription termination site of type IV and V repeats, are conserved. All five types of repeats are interspersed with nonconserved DNA sequences. These results suggest that the five repeat types in the 5' and 3' NTSs are important in rRNA gene function; the sequence organization, and the differing rates of divergence between species of the repeat types, provide strong evidence for their functional selection through the process of molecular coevolution.

A complex control region of the mouse rRNA gene directs accurate initiation by RNA polymerase I

To determine the size and location of the mouse rDNA promoter, we constructed systematic series of deletion mutants approaching the initiation site from the 5' and 3' directions. These templates were transcribed in vitro under various conditions with S-100 and whole-cell extracts. Surprisingly, the size of the rDNA region that determines the level of transcription differed markedly, depending on the reaction conditions. In both kinds of cell extracts, the apparent 5' border of the promoter was at residue ca. -27 under optimal transcription conditions, but as reaction conditions became less favorable, the 5' border moved progressively out to residues -35, -39, and -45. The complete promoter, however, extends considerably further, for under other nonoptimal conditions, we observed major effects of promoter domains extending in the 5' direction to positions ca. -100 and -140. In contrast, the apparent 3' border of the mouse rDNA promoter was at residue ca. +9 under all conditions examined. We also show that the subcloned rDNA region from -39 to +9 contains sufficient information to initiate accurately and that the region between +2 and +9 can influence the specificity of initiation. These data indicate that, although the polymerase I transcription factors recognize and accurately initiate with only the sequences downstream of residue -40, sequences extending out to residue -140 greatly favor the initiation reaction; presumably, this entire region is involved in rRNA transcription in vivo.

Efficient transcription of a protein-coding gene from the RNA polymerase I promoter in transfected cells

The activity of the mouse ribosomal promoter was examined after fusion to the gene coding for chloramphenicol acetyltransferase (CAT) and transfection into mouse cells. Very little CAT enzyme but high levels of CAT-specific RNA correctly initiated at the ribosomal DNA start site were synthesized. The amount of specific transcripts was neither influenced by long stretches of upstream spacer sequences nor by the insertion of the Moloney murine sarcoma virus enhancer. The deletion mutant pMr delta-39, which has been shown to be fully active in vitro, exhibited a 90% decrease in template activity in vivo. A mutant in which 22 base pairs of ribosomal DNA (between positions -35 and -14) were substituted by foreign DNA sequences proved transcriptionally inactive. The fusion genes were only transcribed in mouse cells, indicating that species-specific transcription factors are involved in ribosomal promoter recognition.

The major promoter element of rRNA transcription in yeast lies 2 kb upstream

Conventional genetic analysis of the transcription of rDNA in yeast is precluded because the genes are highly reiterated. As an alternative strategy to determine which sequences modulate transcription of pre-rRNA, a series of artificial rRNA genes containing a fragment of DNA from E. coli bacteriophage T7 were introduced into the yeast Saccharomyces cerevisiae. Correct transcription of the artificial genes was observed. Three regions of ribosomal spacer are found to affect transcription of rRNA. Sequences within 210 bp of the 5' terminus of 35S rRNA support low levels of transcription, but at multiple initiation points. Sequences from -210 to -2230 direct correct initiation and increase somewhat the efficiency of transcription. Most striking is that sequences from -2230 to -2420 stimulate transcription 15-fold. The function of this major promoter element is absolutely orientation-dependent but relatively independent of position. Its activity is blocked when an rRNA transcription termination sequence is placed between it and the site of initiation.

Transcription of a yeast ribosomal RNA minigene in Saccharomyces cerevisiae

A transcription system using intact yeast has been developed for investigating which sequences are implicated in the initiation of transcription of yeast rRNA genes. The system employs an rRNA minigene that consists of the initiation and termination sites for rRNA biosynthesis separated by approx. 700 base pairs of vector DNA in the Escherichia coli-yeast shuttle vector, pJDB207. Two recombinants containing this minigene were constructed; one retained all of the nontranscribed spacer DNA upstream from the initiation site, the other retained 208 base pairs of this DNA. Transcripts of this structurally unique minigene in RNA from yeast transformed with these recombinants were readily detected by nuclease S1 mapping. These transcripts were initiated at the site used by the host rRNA genes, were approx. 3-fold more abundant in the recombinant retaining all of the nontranscribed spacer and were less abundant when the yeast was not growing.

Comparison of the active and inactive chromatin structures of genes transcribed by RNA polymerases I and II

The coding sequences of the yeast 35S rDNA gene and of the yeast galactokinase gene both show clear staphylococcal nuclease nucleosome profiles under conditions in which the gene is inactive (galactokinase) or less active (rDNA). Under conditions of more active expression, the galactokinase gene shows marked smearing in the digestion profiles. The rDNA gene shows a qualitatively similar change in digestion patterns. There is a typical nucleosomal DNase I ladder on the coding sequences of both genes, regardless of the state of activity. In contrast to the coding sequences, the rDNA upstream region chromatin shows a nonnucleosomal profile. The nonnucleosomal character is more pronounced when the gene is more active. On the galactokinase upstream region chromatin, there is a nucleosomal structure, with some minor modifications, when the gene is inactive and a clear nonnucleosomal structure when the gene is expressed.

In vitro mutagenesis and transcriptional analysis of a mouse ribosomal promoter element

An RNA polymerase I control region essential for initiation of pre-rRNA transcription has been identified by mutagenesis in vitro of mouse rDNA (ribosomal RNA genes) and transcription in a cell-free system derived from Ehrlich ascites cells. Substitution of nucleotides between -35 and -14 by foreign DNA sequences caused a loss of template activity, which indicates that an important promoter element is located within this region. To identify the nucleotides essential for RNA polymerase I function, single and multiple point mutations within this control region were generated and the modified DNAs were assayed for template activity. The phenotypes of mutants in which C-to-T transitions have been introduced at positions -36, -31, -27, -22, -21, and -13 were identical to the wild type. Conversion of G to A at position -15 resulted in a 20% increase of promoter activity, whereas a G-to-A transition at -16 decreased transcription by 95%. Competition experiments between mutant and wild-type DNAs suggest that the guanine at -16, which is evolutionarily highly conserved, interacts with essential components of the transcription apparatus.

Determination of the promoter region of mouse ribosomal RNA gene by an in vitro transcription system

Sequences required for a faithful and efficient transcription of a cloned mouse ribosomal RNA gene (rDNA) are determined by testing a series of deletion mutants in an in vitro transcription system utilizing two kinds of mouse cellular extract. Deletion of sequences upstream of -40 or downstream of +52 causes only slight reduction in promoter activity as compared with the "wild-type" template. For upstream deletion mutants, the removal of a sequence between -40 and -35 causes a significant decrease in the capacity to direct efficient initiation. This decrease becomes more pronounced when the deletion reaches -32 and the sequence A-T-C-T-T-T, conserved among mouse, rat, and human rDNAs, is lost. Residual template activity is further reduced as more upstream sequence is deleted and finally becomes undetectable when the deletion is extended from -22 down to -17, corresponding to the loss of the conserved sequence T-A-T-T-G. As for downstream deletion mutants, the removal of the sequence downstream of +23 causes some (and further deletions up to +11 cause a more) serious decrease in template activity in vitro. These deletions involve other conserved sequences downstream of the transcription start site. However, the removal of the original transcription start site does not abolish the transcription initiation completely, provided that the whole upstream sequence is intact.