The mouse ribosomal gene terminator consists of three functionally separable sequence elements

A first look at the 'repeatome' of Benedenia humboldti, a major pathogen in yellowtail aquaculture: Repetitive element characterization, nuclear rRNA operon assembly, and microsatellite discovery

The monogenean Benedenia humboldti is a pathogen of the yellowtail Seriola lalandi in the South-Eastern Pacific ocean. Using low-coverage short Illumina 150bp pair-end reads sequencing, this study examines, for the first time, the 'repeatome' (= repetitive genomic elements), including the 45S ribosomal RNA DNA operon and microsatellites, in B. humboldti. Repetitive elements comprised a large fraction of the nuclear genome and a considerable proportion of them could not be assigned to known repeat element families. Taking into account only annotated repetitive elements, the most frequent belonged to the 45S ribosomal RNA operon or were classified as satellite DNA and Class I - Long Interspersed Nuclear Elements (LINEs) which were considerably more abundant than Class I - LTR elements. The ribosomal RNA gene operon in B. humboldti is comprised of, in the following order, a 5' ETS (length = 233 bp), ssrDNA (2082 bp), ITS1 (346 bp), 5.8S rDNA (150 bp), ITS2 (572 bp), lsrDNA (3887 bp), and a 3' ETS (1097 bp). A total of 15 SSRs were identified. These newly developed genomic resources will contribute to the better understanding of meta-population connectivity in this species, cryptic species in the genus, and will advance pest management strategies.

Genome survey sequencing of the Caribbean spiny lobster Panulirus argus: Genome size, nuclear rRNA operon, repetitive elements, and microsatellite discovery

BACKGROUND

Panulirus argus is an ecologically relevant species in shallow water hard-bottom environments and coral reefs and target of the most lucrative fishery in the greater Caribbean region.

METHODS

This study reports, for the first time, the genome size and nuclear repetitive elements, including the 45S ribosomal DNA operon, 5S unit, and microsatellites, of P. argus.

RESULTS

Using a k-mer approach, the average haploid genome size estimated for P. argus was 2.17 Gbp. Repetitive elements comprised 69.02% of the nuclear genome. In turn, 30.98% of the genome represented low- or single-copy sequences. A considerable proportion of repetitive sequences could not be assigned to known repeat element families. Taking into account only annotated repetitive elements, the most frequent belonged to Class I-LINE which were noticeably more abundant than Class I-LTR-Ty- 3/Gypsy, Class I-LTR-Penelope, and Class I-LTR-Ty-3/Bel-Pao elements. Satellite DNA was also abundant. The ribosomal operon in P. argus comprises, in the following order, a 5' ETS (length = 707 bp), ssrDNA (1,875 bp), ITS1 (736 bp), 5.8S rDNA (162 bp), ITS2 (1,314 bp), lsrDNA (5,387 bp), and 3' ETS (287 bp). A total of 1,281 SSRs were identified.

Nucleolar DNA: the host and the guests

Nucleoli are formed on the basis of ribosomal genes coding for RNAs of ribosomal particles, but also include a great variety of other DNA regions. In this article, we discuss the characteristics of ribosomal DNA: the structure of the rDNA locus, complex organization and functions of the intergenic spacer, multiplicity of gene copies in one cell, selective silencing of genes and whole gene clusters, relation to components of nucleolar ultrastructure, specific problems associated with replication. We also review current data on the role of non-ribosomal DNA in the organization and function of nucleoli. Finally, we discuss probable causes preventing efficient visualization of DNA in nucleoli.

Binding of the termination factor Nsi1 to its cognate DNA site is sufficient to terminate RNA polymerase I transcription in vitro and to induce termination in vivo

Different models have been proposed explaining how eukaryotic gene transcription is terminated. Recently, Nsi1, a factor involved in silencing of ribosomal DNA (rDNA), was shown to be required for efficient termination of rDNA transcription by RNA polymerase I (Pol I) in the yeast Saccharomyces cerevisiae. Nsi1 contains Myb-like DNA binding domains and associates in vivo near the 3' end of rRNA genes to rDNA, but information about which and how DNA sequences might influence Nsi1-dependent termination is lacking. Here, we show that binding of Nsi1 to a stretch of 11 nucleotides in the correct orientation was sufficient to pause elongating Pol I shortly upstream of the Nsi1 binding site and to release the transcripts in vitro. The same minimal DNA element triggered Nsi1-dependent termination of pre-rRNA synthesis using an in vivo reporter assay. Termination efficiency in the in vivo system could be enhanced by inclusion of specific DNA sequences downstream of the Nsi1 binding site. These data and the finding that Nsi1 blocks efficiently only Pol I-dependent RNA synthesis in an in vitro transcription system improve our understanding of a unique mechanism of transcription termination.

RNA polymerase I termination: Where is the end?

The synthesis of ribosomal RNA (rRNA) precursor molecules by RNA polymerase I (Pol I) terminates with the dissociation of the protein-DNA-RNA ternary complex. Based on in vitro results the mechanism of Pol I termination appeared initially to be rather conserved and simple until this process was more thoroughly re-investigated in vivo. A picture emerged that Pol I termination seems to be connected to co-transcriptional processing, re-initiation of transcription and, possibly, other processes downstream of Pol I transcription units. In this article, our current understanding of the mechanism of Pol I termination and how this process might be implicated in other biological processes in yeast and mammals is summarized and discussed. This article is part of a Special Issue entitled: Transcription by Odd Pols.

The Reb1-homologue Ydr026c/Nsi1 is required for efficient RNA polymerase I termination in yeast

Several DNA cis-elements and trans-acting factors were described to be involved in transcription termination and to release the elongating RNA polymerases from their templates. Different models for the molecular mechanism of transcription termination have been suggested for eukaryotic RNA polymerase I (Pol I) from results of in vitro and in vivo experiments. To analyse the molecular requirements for yeast RNA Pol I termination, an in vivo approach was used in which efficient termination resulted in growth inhibition. This led to the identification of a Myb-like protein, Ydr026c, as bona fide termination factor, now designated Nsi1 (NTS1 silencing protein 1), since it was very recently described as silencing factor of ribosomal DNA. Possible Nsi1 functions in regard to the mechanism of transcription termination are discussed.

Transcription termination by nuclear RNA polymerases

Gene transcription in the cell nucleus is a complex and highly regulated process. Transcription in eukaryotes requires three distinct RNA polymerases, each of which employs its own mechanisms for initiation, elongation, and termination. Termination mechanisms vary considerably, ranging from relatively simple to exceptionally complex. In this review, we describe the present state of knowledge on how each of the three RNA polymerases terminates and how mechanisms are conserved, or vary, from yeast to human.

Structural perspective on mutations affecting the function of multisubunit RNA polymerases

High-resolution crystallographic structures of multisubunit RNA polymerases (RNAPs) have increased our understanding of transcriptional mechanisms. Based on a thorough review of the literature, we have compiled the mutations affecting the function of multisubunit RNA polymerases, many of which having been generated and studied prior to the publication of the first high-resolution structure, and highlighted the positions of the altered amino acids in the structures of both the prokaryotic and eukaryotic enzymes. The observations support many previous hypotheses on the transcriptional process, including the implication of the bridge helix and the trigger loop in the processivity of RNAP, the importance of contacts between the RNAP jaw-lobe module and the downstream DNA in the establishment of a transcription bubble and selection of the transcription start site, the destabilizing effects of ppGpp on the open promoter complex, and the link between RNAP processivity and termination. This study also revealed novel, remarkable features of the RNA polymerase catalytic mechanisms that will require additional investigation, including the putative roles of fork loop 2 in the establishment of a transcription bubble, the trigger loop in start site selection, and the uncharacterized funnel domain in RNAP processivity.

Isolation of human NURF: a regulator of Engrailed gene expression

The modification of chromatin structure is an important regulatory mechanism for developmental gene expression. Differential expression of the mammalian ISWI genes, SNF2H and SNF2L, has suggested that they possess distinct developmental roles. Here we describe the purification and characterization of the first human SNF2L-containing complex. The subunit composition suggests that it represents the human ortholog of the Drosophila nucleosome-remodeling factor (NURF) complex. Human NURF (hNURF) is enriched in brain, and we demonstrate that it regulates human Engrailed, a homeodomain protein that regulates neuronal development in the mid-hindbrain. Furthermore, we show that hNURF potentiates neurite outgrowth in cell culture. Taken together, our data suggess a role for an ISWI complex in neuronal growth.

Ku antigen supports termination of mammalian rDNA replication by transcription termination factor TTF-I

A replication fork barrier at the 3'-end of mouse ribosomal RNA genes blocks bidirectional fork progression and limits DNA replication to the same direction as transcription. This barrier is an inherent property of a defined DNA-protein complex including transcription termination factor I, and specific protein-protein interactions occur between this factor and protein(s) of the replication machinery. Here we report that a second DNA-binding protein is essential for barrier activity. We have purified and functionally characterised the protein from HeLa cells. The final preparation contained two polypeptides with molecular masses of 70 and 86 kDa, respectively. Both polypeptides interact with a GC-stretch adjacent to the binding site of transcription termination factor I. The specificity of binding to the barrier DNA was demonstrated in an electrophoretic mobility shift assay. The biochemical properties of this protein resemble that of Ku antigen, a human nuclear DNA-binding heterodimer that is the target of autoimmune-antibodies in several autoimmune diseases. Recombinant Ku protein, purified as heterodimer from co-infected insect cells, is able to partially rescue the barrier activity in Ku-depleted HeLa cell extracts. These data demonstrate that transcription termination factor I and Ku act synergistically to prevent head-on collision between the replication and the transcription machinery.

Regulation of mammalian ribosomal gene transcription by RNA polymerase I

All cells, from prokaryotes to vertebrates, synthesize vast amounts of ribosomal RNA to produce the several million new ribosomes per generation that are required to maintain the protein synthetic capacity of the daughter cells. Ribosomal gene (rDNA) transcription is governed by RNA polymerase I (Pol I) assisted by a dedicated set of transcription factors that mediate the specificity of transcription and are the targets of the pleiotrophic pathways the cell uses to adapt rRNA synthesis to cell growth. In the past few years we have begun to understand the specific functions of individual factors involved in rDNA transcription and to elucidate on a molecular level how transcriptional regulation is achieved. This article reviews our present knowledge of the molecular mechanism of rDNA transcriptional regulation.

Termination of mammalian rDNA replication: polar arrest of replication fork movement by transcription termination factor TTF-I

A replication fork barrier (RFB) at the 3' end of eukaryotic ribosomal RNA genes blocks bidirectional fork progression and limits DNA replication to the same direction as transcription. We have reproduced the RFB in vitro in HeLa cell extracts using 3' terminal murine rDNA fused to an SV40 origin-based vector. The RFB is polar and modularly organized, requiring both the Sal box transcription terminator and specific flanking sequences. Mutations within the terminator element, depletion of the RNA polymerase I-specific transcription termination factor TTF-I, or deletion of the termination domain of TTF-I abolishes RFB activity. Thus, the same factor that blocks elongating RNA polymerase I prevents head-on collision between the DNA replication apparatus and the transcription machinery.

RNA polymerase I from S. cerevisiae depends on an additional factor to release terminated transcripts from the template

Terminated transcripts were generated at the ends of linearized DNA templates and at DNA-bound lac repressor by in vitro transcription with highly enriched or purified yeast RNA polymerase I (pol I). The release of the synthesized transcripts from the DNA was analyzed using immobilized DNA as template for the transcription reaction. An additional activity distinguishable from pol I was necessary to remove the terminated RNA from the template. Efficiency of transcript release could be improved if a thymidine-rich DNA fragment was located upstream of the transcriptional arrest caused by the DNA-bound lac repressor. The release activity interacted with different forms of polymerases, pol I able to initiate on the ribosomal gene promoter and pol I only active in non-specific transcription.

RNA polymerase I transcription termination: similar mechanisms are employed by yeast and mammals

Termination of RNA polymerase I (Pol I) transcription requires the interaction of a specific DNA binding factor with terminator elements downstream of the pre-rRNA coding region. Both the terminator elements and the respective termination factors are distinct in yeast and mammals, and differences in the mechanism of transcription termination have been postulated. We have compared in vitro transcription termination of yeast and mouse Pol I using both the murine factor TTF-I, and the yeast homolog Reb1p. We show that, similar to TTF-I, Reb1p was sufficient for pausing of Pol I from either species, but was unable to cause release of the nascent transcripts from the paused ternary complex. The deficiency of Reb1p to mediate transcript release from Pol I of either species was complemented by the recently characterized murine release factor. Thus, both yeast and mouse Pol I termination requires a trans-acting factor that, in conjunction with the T-rich flanking sequence, releases the transcripts and Pol I from the template. The observation that the murine factor causes dissociation of ternary transcription complexes arrested by Reb1p suggests that the mechanism of Pol I termination is highly conserved from yeast to mammals.

Termination as a factor in "quality control" during ribosome biogenesis

In eukaryotes, nascent rDNA and 5 S rRNA gene transcripts undergo 3'-end processing after termination. Mutations in which terminator sequences in these ribosomal RNA genes are deleted completely result in highly unstable transcripts, which are not properly processed and integrated into stable ribosome structure. Mutations that retard RNA processing by extending the 3' external transcribed spacer or by introducing additional secondary structure in the spacers have a similar effect on stable transcript integration. The results indicate that proper termination coupled with efficient rRNA processing acts as a "quality control" process, which helps to ensure that only normal rRNA precursors are effectively processed and assembled into active ribosomes.

Actinomycin D stimulates the transcription of rRNA minigenes transfected into mouse cells. Implications for the in vivo hypersensitivity of rRNA gene transcription

The in vivo hypersensitivity of eukaryotic rRNA gene transcription to actinomycin D has long been known, but this effect could not be reproduced in model systems and its molecular mechanisms remain uncertain. We studied the action of actinomycin D using mouse rRNA minigenes (with RNA polymerase I promoter and terminator signals), carrying truncated mouse or human rDNA inserts, which are faithfully transcribed upon transient transfection into mouse cells. Low concentrations (0.01-0.08 micrograms/ml) of actinomycin D caused within 1-2 h a 2-7-fold stimulation of the transcription of rRNA minigenes which is inversely related to the size of the rDNA transcript. With transcripts longer than 3 kb the effect was reversed and at 4 kb a practically complete inhibition of the formation of full-length transcripts was observed, accompanied, however, by an enhanced accumulation of unfinished rDNA transcripts. The dependence of actinomycin D action on transcript length was also observed with lacZ gene segments of different size inserted into the mouse rRNA minigenes. The transcription initiation of endogenous rRNA genes was also stimulated by the low doses of actinomycin D as indicated by the enhanced synthesis of unfinished rDNA transcripts (spanning mainly the 5' external transcribed spacer), whereas the synthesis of full-length transcripts was abolished. Removal of actinomycin D from the medium caused within 8-24 h a dramatic increase of the transcription from all rRNA minigenes tested. This stimulation was also inversely related to the size of the transcripts and varied from twofold to fivefold for the 3-4-kb transcripts to about 50-80-fold for the basic minigene transcript (395 nucleotides). The amount of endogenous aborted rDNA transcripts was also markedly increased, but the synthesis of full-length transcripts was not restored even 24 h after removal of the drug. The present results reproduce in a model cellular system the in vivo hypersensitivity of rRNA gene transcription to actinomycin D and reveal that the major factor involved is the size of the rRNA gene transcript. This effect requires only the basic rRNA gene promoter and terminator signals and does not depend on the G + C content of the RNA polymerase I transcripts. We suggest that at low concentrations, the intercalation of actinomycin D changes the conformation of DNA in the promoter region in a manner that stimulates the transcription of both endogenous and transfected rRNA genes.(ABSTRACT TRUNCATED AT 400 WORDS)

A model for transcription termination by RNA polymerase I

The transcription termination site for yeast RNA polymerase I requires not only an 11 bp binding site for Reb1p, but also about 46 bp of 5' flanking sequence. We propose that Reb1p bound to its site is part of a pause element, while the 5' flanking sequence contains a release element. Pausing requires little other than the DNA-binding domain of Reb1p and is not specific for polymerase I. The release element, however, can be polymerase specific. We propose a general model for eukaryotic transcription terminators in which termination occurs when a relatively nonspecific signal induces polymerase to pause in the context of a release element.

The mechanism of transcription termination by RNA polymerase I

Eukaryotic ribosomal gene transcription units are bordered at their 3' ends by short DNA sequences which specify site-specific termination by RNA polymerase I (polI). PolI terminators from yeast through to mammals appear to follow similar rules: they contain a site for a sequence-specific DNA-binding protein; they function only in one orientation; 3' ends are formed upstream of the binding site; and 5' flanking sequences influence the position and efficiency of 3' end formation. Recent progress in understanding the mechanism of RNA chain elongation by other polymerases suggests a model for polI termination in which termination is seen as one of the several outcomes possible when a polymerase encounters a pause site.

Limited proteolysis unmasks specific DNA-binding of the murine RNA polymerase I-specific transcription termination factor TTFI

Previously we have shown that nuclear extracts from mouse cells contain a heterogeneous group of polypeptides (p65, p80, p90, p100) which form distinct DNA-protein complexes on the 18 base-pair sequence element (termed Sal-box), which constitutes the murine rDNA transcription termination signal. These distinct proteins mediate cessation of RNA polymerase I (pol I) transcription elongation and release of the nascent RNA chains, indicating that they function as termination factor(s). Here, we report the biochemical analysis of the pol I-specific transcription termination factor TTFI. We show that the heterogeneity of TTFI is due to limited proteolysis of a larger, 130 kDa precursor protein (p130). The DNA-binding activity of p130 is strongly reduced as compared to the proteolytic derivatives, indicating that the DNA-binding domain is repressed within the full-length molecule. We have used limited proteolysis to purify and functionally characterize a TTFI core polypeptide (p50) which still specifically binds to the Sal-box target sequence and directs rDNA transcription termination. The equilibrium constant of purified p50 to bind specifically to DNA is 9 x 10(9) M-1. Additionally, we demonstrate that TTFI binds to DNA as a monomer and that binding induces DNA bending. This observation suggests that not only specific DNA-protein and protein-protein interactions but also conformational alterations of DNA may play a role in the termination process.

Stalling by RNA polymerase II in the polyomavirus intergenic region is dependent on functional large T antigen

RNA polymerase II encounters an elongation block and stalls in vivo during transcription of the late strand of polyomavirus DNA. In this study, we performed transcriptional run-on assays and localized the stalling site to a 164-nucleotide region (nt 11-175) that contains specific binding sites for polyomavirus large T antigen. The effect of large T antigen on elongation by RNA polymerase II through this region was examined in cells infected with a mutant polyomavirus (AT3-ts25E) which encodes a thermolabile large T antigen. Removal of functional large T antigen by shifting to the nonpermissive temperature (39 degrees) eliminated stalling by RNA polymerase in this region, although RNA polymerases transcribing other regions of the viral genome were unaffected. RNA polymerase resumed stalling when functional large T antigen was again allowed to accumulate by shifting back to the permissive temperature (32 degrees). We conclude that stalling by RNA polymerase II in vivo is dependent on the presence of functional large T antigen.

Primary structure of the non-transcribed spacer region and flanking sequences of the ribosomal DNA of Neurospora crassa and comparison with other organisms

The non-transcribed spacer (NTS) region of the rDNA of Neurospora crassa contains the transcription regulatory sequences. We isolated a 3.4 kb EcoRI fragment from wild type N.crassa rDNA and cloned in the plasmid pBR325 at the EcoRI site. The insert contains the entire NTS region along with the flanking sequences. Nucleotide sequencing of 3592 nt shows many interesting features like: the NTS region is rich in G+C content (65% G+C); it contains the conserved rRNA processing site 6 (with the nucleotide sequence motif GGTGCGAGAACCCGG, from nt residue 226 to 240, a characteristic feature of most eukaryotic rDNA nontranscribed spacer region); and the NTS region also contains the transcription termination site with the representative Sal I box (from nt residue 1469 to 1477). The potential sequences of transcription termination site are located 288 nt downstream from the end of 26S rRNA gene, and another sequence motif CTTCCT (from nt residue 512 to 517) shows similarity with the human transcription termination site T-2 of its pre-rRNA. Nucleotide sequence homology matrix analysis suggests its relatedness to Saccharomyces cerevisiae and not to human, mouse, rat, Drosophila, Xenopus, wheat, rice and cucumber NTS region. The phylogenetic implication of the NTS region and exploitation of N.crassa NTS rDNA clone to correlate the otherwise indistinguishable species of Neurospora and the correlation with other organisms has been discussed. To the best of our knowledge this is the first report where the nucleotide sequence of the entire NTS region of a filamentous fungus has been determined.

Specific interaction of the murine transcription termination factor TTF I with class-I RNA polymerases

The 18-base-pair sequence element AGGTCGACCAGTACTCCG (the Sal box) signals termination of mouse ribosomal gene transcription. This sequence is recognized by a sequence-specific DNA-binding protein, TTF I, which mediates the termination of transcription by RNA polymerase I (pol I). Subsequently, the ends of the primary transcripts are trimmed by 10 nucleotides in a sequence-dependent 3'-terminal processing reaction. We have now investigated whether TTF I bound to its target sequence will block elongation by any RNA polymerase by steric hindrance, or whether it is specific for elongation by pol I. The results demonstrate that TTF I directs transcription termination with RNA polymerase I from species as divergent as mouse and yeast, but fails to affect elongation by heterologous polymerases (eukaryotic RNA polymerases II and III, Escherichia coli or bacteriophage T3 RNA polymerase). By contrast, purified lac repressor bound to its operator sequence stops elongation by both RNA polymerase I and II.

Transcription of human ribosomal DNA may terminate at multiple sites

The termination of human pre-rRNA transcription has been investigated. The most abundant possible termination site was detected 360 bp downstream from the 28S gene, in front of the first SalI box of the rDNA spacer. This site, however, is partially bypassed during transcription, and three additional termination points were detected inside the heterogeneous region of the rDNA spacer. Later sites were mapped about 930, 1030 and 1110 bp downstream from the 3' end of the 28S rRNA gene. The authors suggest that the T clusters and pyrimidine-rich regions play an important role in the termination processes. They either may influence the efficiency of the SalI boxes in terminating the synthesis of pre-rRNAs or may serve as independent signals for the fail-safe termination of readthrough transcripts. In both cases transcription of human rDNA ceases at multiple sites.

A recombination hotspot in the LTR of a mouse retrotransposon identified in an in vitro system

The recombinational frequency between two long terminal repeat elements (LTR-IS) of a mouse retrotransposon was about 13 times higher, compared with that of two control DNA sequences in extracts from mouse testes, but not in extracts from ascites cells. Deletion of a 37 bp region from the LTR-IS element strongly suppresses its recombinational activity. This 37 bp region encompasses an area of potentially single-stranded DNA and interacts with at least two nuclear proteins. One of them binds sequence-specifically to single-stranded DNA and is present in both types of extracts. Another protein(s) binds to dsDNA at the motif TGGAAATCCCC and is absent in extracts from testes. Our results suggest that a cis-acting DNA sequence within the 504 bp LTR-IS element is responsible for its high recombinational activity in vitro, and they further support the previous suggestion that the LTR-IS elements are meiotic recombinational hotspots in vivo.

3'-end formation of mouse pre-rRNA involves both transcription termination and a specific processing reaction

We have studied the sequence requirements for 3'-end formation of rDNA transcripts in a cell-free system and show that the generation of correct ends of mouse pre-rRNA is brought about by a two-step process that involves a bona fide termination reaction, followed by a specific trimming of the primary transcript by 10 nucleotides. We show that termination of mouse ribosomal gene transcription by RNA polymerase I (pol I) takes place in front of an 18-bp DNA sequence element (the 'Sal box'), which was previously shown to function as termination signal. Termination of pol I transcription occurs at a fixed distance (11 bp) upstream of the Sal box, independent of the sequence of adjacent gene regions. The processing reaction, however, is strongly influenced by sequences flanking the termination signal at the 5' site. Substitution of a cluster of T residues by guanines within the region of 3'-end formation abolishes the 3'-terminal trimming of the primary transcript. Interestingly, this 3'-terminal processing event, which can be uncoupled from the termination reaction, requires both a correct 3' end and specific sequences in the 3'-terminal region of the primary transcript. Read-through transcripts generated in the extract system or by SP6 RNA polymerase are no substrate for the processing nuclease(s). Because the termination and processing activity can be separated chromatographically, the nucleolytic activity does not reside in TTF-I, the factor that binds to the Sal box and directs transcription termination.