RNA polymerase II transcription termination is mediated specifically by protein binding to a CCAAT box sequence.

Connelly, Sheila; Manley, James L.

doi:10.1128/mcb.9.11.5254

Cited by 71 publications

(64 citation statements)

References 37 publications

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“…Inserts iii and iv are G/U-less poly(A) signals. Insert iii has two hexamers and was included because some poly(A) signals contain two closely spaced hexamers (Connelly and Manley 1988;Natalizio et al 2002). Insert iv contains a single hexamer and is identical to insert iii except that the upstream hexamer in insert iii was mutated.…”

Section: Resultsmentioning

confidence: 99%

“…At the same time, certain mutants in yeast that cannot cleave at the poly(A) site nevertheless undergo poly(A)-dependent termination (Sadowski et al 2003;Zhelkovsky et al 2006), suggesting that poly(A) site cleavage may not be a fundamental part of the poly(A)-dependent termination mechanism. In another example, the poly(A) signal in mammals can alone drive termination in a heterologous sequence background (Orozco et al 2002), yet in their native context, some poly(A) signals require auxiliary elements to effect termination (Connelly and Manley 1989;Dye and Proudfoot 2001;West et al 2006).…”

Section: Introductionmentioning

confidence: 99%

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The conserved AAUAAA hexamer of the poly(A) signal can act alone to trigger a stable decrease in RNA polymerase II transcription velocity

Nag¹,

Narsinh²,

Kazerouninia³

et al. 2006

RNA

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In vivo the poly(A) signal not only directs 39-end processing but also controls the rate and extent of transcription. Thus, upon crossing the poly(A) signal RNA polymerase II first pauses and then terminates. We show that the G/U-rich region of the poly(A) signal, although required for termination in vivo, is not required for poly(A)-dependent pausing either in vivo or in vitro. Consistent with this, neither CstF, which recognizes the G/U-rich element, nor the polymerase CTD, which binds CstF, is required for pausing. The only part of the poly(A) signal required to direct the polymerase to pause is the AAUAAA hexamer. The effect of the hexamer on the polymerase is long lasting-in many situations polymerases over 1 kb downstream of the hexamer continue to exhibit delayed progress down the template in vivo. The hexamer is the first part of the poly(A) signal to emerge from the polymerase and may play a role independent of the rest of the poly(A) signal in paving the way for subsequent events such as 39-end processing and termination of transcription.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The conserved AAUAAA hexamer of the poly(A) signal can act alone to trigger a stable decrease in RNA polymerase II transcription velocity

Nag¹,

Narsinh²,

Kazerouninia³

et al. 2006

RNA

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“…When cleavage occurs at the poly(A) polymerase site, Pol II continues to transcribe a now-uncapped downstream RNA. This RNA is subject to degradation by the 5Ј-3Ј exonuclease XRN-2; according to the torpedo model, termination occurs when the exonuclease collides with Pol II (11)(12)(13). Recently, a unified allosteric-torpedo model has been proposed to explain new experimental evidence in support of both the earlier models (14,15).…”

mentioning

confidence: 85%

Genes involved in pre-mRNA 3′-end formation and transcription termination revealed by a lin-15 operon Muv suppressor screen

Cui

Allen²,

Larsen³

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

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RNA polymerase II (Pol II) transcription termination involves two linked processes: mRNA 3-end formation and release of Pol II from DNA. Signals for 3 processing are recognized by a protein complex that includes cleavage polyadenylation specificity factor (CPSF) and cleavage stimulation factor (CstF). Here we identify suppressors encoding proteins that play roles in processes at the 3 ends of genes by exploiting a mutation in which the 3 end of another gene is transposed into the first gene of the Caenorhabditis elegans lin-15 operon. As expected, genes encoding CPSF and CstF were identified in the screen. We also report three suppressors encoding proteins containing a domain that interacts with the C-terminal domain of Pol II (CID). We show that two of the CID proteins are needed for efficient 3 cleavage and thus may connect transcription termination with RNA cleavage. Furthermore, our results implicate a serine/arginine-rich (SR) protein, SRp20, in events following 3-end cleavage, leading to termination of transcription.Caenorhabditis elegans operon ͉ RNA polymerase II C-terminal domain ͉ SRp20 ͉ CTD T ermination of RNA polymerase II (Pol II)-mediated transcription plays an important role in gene regulation and involves two linked processes: 3Ј-end formation and release of the Pol II from the DNA (1). Accordingly, termination of Pol II requires both the presence of an intact 3Ј-processing signal and several 3Ј-end processing factors including the cleavage and polyadenylation specificity factor (CPSF) and the cleavage stimulation factor (CstF) (2-6). Several of the polyadenylation factors are associated with the C-terminal domain (CTD) of the largest subunit of Pol II, which is known to be required for efficient 3Ј processing (7-10). Much is known about what is required for 3Ј-end processing, but which factors specifically act in transcription termination and how these factors cause the Pol II complex to terminate are not entirely clear. The known link between 3Ј-end formation and transcription termination has led to multiple models to explain transcription termination.Two such models have been proposed to explain the connection between 3Ј-end processing and transcription termination. One model, known as the ''allosteric'' model, proposes that termination is triggered by a conformational change of the Pol II complex that occurs on the emergence of the polyadenylation sequences (3). Another model, known as the ''torpedo'' model, proposes that termination is triggered subsequent to the cleavage event by the exonuclease XRN-2. When cleavage occurs at the poly(A) polymerase site, Pol II continues to transcribe a now-uncapped downstream RNA. This RNA is subject to degradation by the 5Ј-3Ј exonuclease XRN-2; according to the torpedo model, termination occurs when the exonuclease collides with Pol II (11-13). Recently, a unified allosteric-torpedo model has been proposed to explain new experimental evidence in support of both the earlier models (14,15).One commonality between the three models of termination is the obl...

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“…RNA polymerase II transcription termination occurs hundreds or thousands of nucleotides downstream of polyadenylation sites (7,13,14). Although there have been a number of reports of specific sequences which may act as termination sequences (15)(16)(17)(18)(19)(20)(21)(22)(23)(24)(25), in vivo, transcription termination often depends on 3'-end processing (9)(10)(11)(12)26). Mutations in the conserved polyadenylation AAUAAA signal of the mouse major 3-globin gene or the human globin gene, respectively (11,12), or mutations in both the AAUAAA hexanucleotide and the downstream GT-rich region of the SV40 early polyadenylation site (9) can inhibit polyadenylation as well as transcription termination.…”

Section: Introductionmentioning

confidence: 99%

Polyadenylation and transcription termination in gene constructs containing multiple tandem polyadenylation signals

1994

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The processes of pre-mRNA 3'-end cleavage and polyadenylation have been closely linked to transcription termination by RNA polymerase II. We have studied the relationship between polyadenylation and transcription termination in gene constructs containing tandem poly(A) signals, at least one of which is the inefficient polyomavirus late poly(A) site. When identical tandem viral signals were separated by fewer than 400 bp, they competed for polyadenylation. The upstream site was always chosen preferentially, but relative site choice was influenced by the distance between the signals. All of these constructs showed the same low level of transcription termination as wild type polyomavirus, which contains a single late poly(A) site. When tandem poly(A) signals were not identical, a stronger downstream signal could outcompete a weaker upstream signal for polyadenylation without altering the efficiency of transcription termination characteristic for use of the upstream signal. Thus, if a weak polyoma virus late poly(A) signal (associated with inefficient transcription termination) preceded a strong rabbit 3-globin signal (associated with efficient transcription termination), termination remained inefficient, but the distal signal was most often chosen for polyadenylation. These results are consistent with independent regulation of polyadenylation and transcription termination in this system and are discussed in light of current models for the dependence of transcription termination on a functional poly(A) site.

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RNA polymerase II transcription termination is mediated specifically by protein binding to a CCAAT box sequence.

Cited by 71 publications

References 37 publications

The conserved AAUAAA hexamer of the poly(A) signal can act alone to trigger a stable decrease in RNA polymerase II transcription velocity

The conserved AAUAAA hexamer of the poly(A) signal can act alone to trigger a stable decrease in RNA polymerase II transcription velocity

Genes involved in pre-mRNA 3′-end formation and transcription termination revealed by a lin-15 operon Muv suppressor screen

Polyadenylation and transcription termination in gene constructs containing multiple tandem polyadenylation signals

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