Natural point mutations within rat rDNA transcription terminator elements reveal the functional importance of single bases for factor binding and 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.

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.

Initiation and termination of DNA replication in human rRNA genes

We have used the multicopy human rRNA genes as a model system to study replication initiation and termination in mammalian chromosomes. Enrichment for replicating molecules was achieved by isolating S-phase enriched populations of cells by centrifugal elutriation, purification of DNA associated with the nuclear matrix, and a chromatographic procedure that enriches for molecules containing single-stranded regions, a characteristic of replication forks. Two-dimensional agarose gel electrophoresis techniques were used to demonstrate that replication appears to initiate at multiple sites throughout most of the 31-kb nontranscribed spacer (NTS) of human ribosomal DNA but not within the 13-kb transcription unit or adjacent regulatory elements. Although initiation events were detected throughout the majority of the NTS, some regions may initiate more frequently than others. Termination of replication, the convergence of opposing replication forks, was found throughout the ribosomal DNA repeat units, and, in some repeats, specifically at the junction of the 3' end of the transcription unit and the NTS. This site-specific termination of replication is the result of pausing of replication forks near the sites of transcription termination. The naturally occurring multicopy rRNA gene family offers a unique system to study mammalian DNA replication without the use of chemical synchronization agents.

Initiation and termination of DNA replication in human rRNA genes

We have used the multicopy human rRNA genes as a model system to study replication initiation and termination in mammalian chromosomes. Enrichment for replicating molecules was achieved by isolating S-phase enriched populations of cells by centrifugal elutriation, purification of DNA associated with the nuclear matrix, and a chromatographic procedure that enriches for molecules containing single-stranded regions, a characteristic of replication forks. Two-dimensional agarose gel electrophoresis techniques were used to demonstrate that replication appears to initiate at multiple sites throughout most of the 31-kb nontranscribed spacer (NTS) of human ribosomal DNA but not within the 13-kb transcription unit or adjacent regulatory elements. Although initiation events were detected throughout the majority of the NTS, some regions may initiate more frequently than others. Termination of replication, the convergence of opposing replication forks, was found throughout the ribosomal DNA repeat units, and, in some repeats, specifically at the junction of the 3' end of the transcription unit and the NTS. This site-specific termination of replication is the result of pausing of replication forks near the sites of transcription termination. The naturally occurring multicopy rRNA gene family offers a unique system to study mammalian DNA replication without the use of chemical synchronization agents.

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.

An undecamer DNA sequence directs termination of human ribosomal gene transcription

Previously we have shown that a repetitive 18 bp sequence motif, the Sal box (AGGTCGACCAGA/TT/ANTCCG), present in the 3' terminal spacer of mouse rDNA constitutes a termination signal for RNA polymerase I (pol I). Similar sequence elements which are functionally analogous to the murine terminator are present in the spacer of human rDNA. However, the human termination signal is shorter encompassing only 11 bp (GGGTCGACCAG) which correspond to the proximal part of the mouse sequence. Two out of the five human Sal box elements are functionally inactive due to natural point mutations which damage factor binding. A similar sequence motif with a 10 of 11 base identity with the downstream terminators is located upstream of the human transcription initiation site. The upstream element interacts with the same factor(s) as the downstream terminators and is also capable to stop elongating human RNA polymerase I. Despite the human and mouse factors exert different electrophoretic mobilities in gel retardation assays, UV-crosslinking and proteolytic clipping experiments indicate that both the sizes and the tertiary structure of the Sal box binding proteins of both species are very similar. When bound to DNA, both the human and the mouse factor terminate transcription of pol I from the heterologous species. The results implicate that changes in signal sequences necessary for termination have been accompanied by compensatory changes in the DNA binding domain of the protein(s) interacting with the termination signal. In contrast, the protein-protein interactions between the termination factor and the transcribing RNA polymerase I appear to have been conserved during evolution.

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.

Sequences within the spacer region of yeast rRNA cistrons that stimulate 35S rRNA synthesis in vivo mediate RNA polymerase I-dependent promoter and terminator activities

Sequences within the spacer region of yeast rRNA cistrons stimulate synthesis of the major 35S rRNA precursor in vivo 10- to 30-fold (E. A. Elion and J. R. Warner, Cell 39:663-673, 1984). Spacer sequences that mediate this stimulatory activity are located approximately 2.2 kilobases upstream from sequences that encode the 5' terminus of the 35S rRNA precursor. By utilizing a centromere-containing plasmid carrying a 35S rRNA minigene, a 160-base-pair region of spacer rDNA was identified by deletion mapping that is required for efficient stimulation of 35S rRNA synthesis in vivo. A 22-base-pair sequence, previously shown to support RNA polymerase I-dependent selective initiation of transcription in vitro, was located 15 base pairs upstream from the 3' boundary of the stimulatory region. A 77-base pair region of spacer DNA that mediates transcriptional terminator activity in vivo was identified immediately downstream from the 5' boundary of the stimulatory region. Deletion mutations extending downstream from the 5' boundary of the 160-base-pair stimulatory region simultaneously interfere with terminator activity and stimulation of 35S rRNA synthesis from the minigene. The terminator region supported termination of transcripts initiated by RNA polymerase I in vivo. The organization of sequences that support terminator and promoter activities within the 160-base-pair stimulatory region is similar to the organization of rDNA gene promoters in higher organisms. Possible mechanisms for spacer-sequence-dependent stimulation of yeast 35S rRNA synthesis in vivo are discussed.

Transcription termination at the chicken beta H-globin gene

We characterized the transcription termination region of the chicken beta H-globin gene. First we located the region by nuclear runon transcription in vitro. Then we sequenced and subcloned it into a chloramphenicol acetyltransferase (CAT) expression vector for assay in vivo. The region of beta H termination contains two interesting elements located about 1 kilobase downstream of the beta H gene poly(A) site. Either element alone can block CAT expression if inserted between the promoter and the poly(A) site of the cat gene in pRSVcat. The first element in the termination region is an unusually large inverted repeat in the DNA (delta G = -71 kcal). The second element, 200 base pairs further downstream, is an RNA polymerase II promoter which directs transcription back upstream on the complementary strand. This transcription converges on and collides with that from the beta H gene at or near the inverted repeat where transcription from both directions stops. We propose that the inverted repeat is a strong pause site which positions the converging polymerases for mutual site-specific termination.

High initiation rates at the ribosomal gene promoter do not depend upon spacer transcription

We report experiments that test the model that in Xenopus laevis, RNA polymerase I is "handed over" in a conservative fashion from the T3 terminator to the adjacent gene promoter. We have introduced transcription-terminating lesions into the ribosomal DNA repeat by irradiating cultured cells with ultraviolet light. We used isolated nuclei to measure the effect of such lesions on transcription. UV damage sufficient to prevent all elongating RNA polymerase from reaching T3 from upstream had no adverse effect on the density of RNA polymerase at the very 5' end of the gene. We conclude that high rates of transcription initiation at the gene promoter do not depend upon polymerase passing from one repeat to the next or on polymerase initiating at the spacer promoters.

Sequences within the spacer region of yeast rRNA cistrons that stimulate 35S rRNA synthesis in vivo mediate RNA polymerase I-dependent promoter and terminator activities

Sequences within the spacer region of yeast rRNA cistrons stimulate synthesis of the major 35S rRNA precursor in vivo 10- to 30-fold (E. A. Elion and J. R. Warner, Cell 39:663-673, 1984). Spacer sequences that mediate this stimulatory activity are located approximately 2.2 kilobases upstream from sequences that encode the 5' terminus of the 35S rRNA precursor. By utilizing a centromere-containing plasmid carrying a 35S rRNA minigene, a 160-base-pair region of spacer rDNA was identified by deletion mapping that is required for efficient stimulation of 35S rRNA synthesis in vivo. A 22-base-pair sequence, previously shown to support RNA polymerase I-dependent selective initiation of transcription in vitro, was located 15 base pairs upstream from the 3' boundary of the stimulatory region. A 77-base pair region of spacer DNA that mediates transcriptional terminator activity in vivo was identified immediately downstream from the 5' boundary of the stimulatory region. Deletion mutations extending downstream from the 5' boundary of the 160-base-pair stimulatory region simultaneously interfere with terminator activity and stimulation of 35S rRNA synthesis from the minigene. The terminator region supported termination of transcripts initiated by RNA polymerase I in vivo. The organization of sequences that support terminator and promoter activities within the 160-base-pair stimulatory region is similar to the organization of rDNA gene promoters in higher organisms. Possible mechanisms for spacer-sequence-dependent stimulation of yeast 35S rRNA synthesis in vivo are discussed.

Transcription termination at the chicken beta H-globin gene

We characterized the transcription termination region of the chicken beta H-globin gene. First we located the region by nuclear runon transcription in vitro. Then we sequenced and subcloned it into a chloramphenicol acetyltransferase (CAT) expression vector for assay in vivo. The region of beta H termination contains two interesting elements located about 1 kilobase downstream of the beta H gene poly(A) site. Either element alone can block CAT expression if inserted between the promoter and the poly(A) site of the cat gene in pRSVcat. The first element in the termination region is an unusually large inverted repeat in the DNA (delta G = -71 kcal). The second element, 200 base pairs further downstream, is an RNA polymerase II promoter which directs transcription back upstream on the complementary strand. This transcription converges on and collides with that from the beta H gene at or near the inverted repeat where transcription from both directions stops. We propose that the inverted repeat is a strong pause site which positions the converging polymerases for mutual site-specific termination.