A Human RNA Polymerase II-containing Complex Associated with Factors Necessary for Spliceosome Assembly

Robert, François; Blanchette, Marco; Maës, Olivier; Chabot, Benoît; Coulombe, Benoit

doi:10.1074/jbc.m110516200

Cited by 47 publications

(127 citation statements)

References 40 publications

(47 reference statements)

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“…Association of these factors with the pol II CTD during transcription elongation would then facilitate the assembly of splicing and 3Ј-end processing complexes on nascent transcripts. Consistent with this model, several reports have described interactions between pre-mRNA processing factors and transcriptional activators (40), coactivators (41)(42)(43), and the holoenzyme (22,23). Thus, it is possible that increased splicing and cleavage levels promoted by transcriptional activators is the consequence of increased recruitment of pre-mRNA processing components to promoters.…”

Section: Discussionsupporting

confidence: 50%

“…The 3Ј-end cleavage polyadenylation stimulatory factor (CPSF) interacts with the general transcription factor TFIID during transcription initiation (21), as well as with the CTD (15), indicating that it is recruited to transcription initiation complexes prior to its role in cleavage. A number of splicing or splicing-related factors have recently been detected in association with holoenzyme complexes involved in transcription initiation, further suggesting that specific pre-mRNA processing components may be recruited to active genes at the stage of transcription initiation (22,23). Recent work has also shown that the type of promoter or activator used to drive transcription can influence the level of inclusion of alternative exons in transfected pre-mRNA reporters (24 -27), suggesting that events occurring as early as promoter recognition may play an important role in the regulation of splicing.…”

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confidence: 99%

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Transcriptional Activators Control Splicing and 3′-End Cleavage Levels

Rosonina

Bakowski

McCracken

et al. 2003

Journal of Biological Chemistry

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We have investigated whether transcriptional activators influence the efficiency of constitutive splicing and 3 -end formation, in addition to transcription levels. Remarkably, strong activators result in higher levels of splicing and 3 -cleavage than weak activators and can control the efficiency of these steps in pre-mRNA processing separately. The pre-mRNA processing stimulatory property of activators is dependent on their binding to promoters, but is not an indirect consequence of the levels of transcripts produced. Moreover, stimulation of splicing and cleavage by a strong activator operates by a mechanism that requires the carboxyl-terminal domain of RNA polymerase II. The splicing stimulatory property of activators was observed for unrelated transcripts and for separate introns within a transcript, indicating a possible general role for strong activators in facilitating pre-mRNA processing levels. The results suggest that the efficiency of constitutive splicing and 3 -end cleavage is closely coordinated with transcription levels by promoter-bound activators.The generation of mature mRNA involves the addition of an m 7 G cap at the 5Ј-end, splicing, and cleavage and polyadenylation at the 3Ј-end of precursor (pre-)mRNAs. Although these steps can occur in isolation of each other, the majority of pre-mRNA processing occurs as RNA polymerase II (pol II) 1 is transcribing. This is evident from numerous microscopy studies, in which the removal of most introns is observed to coincide with nascent transcript synthesis, as well as from more recent studies that demonstrate that transcription and pre-mRNA processing steps are physically coupled and can influence one another (1-3).The largest subunit of pol II contains a carboxyl-terminal domain (CTD), which in mammals consists of 52 repeats of the heptapeptide consensus sequence YSPTSPS (4, 5). Pol II at the stage of transcription initiation is associated with a large holoenzyme complex, which is recruited to promoters by sequence-specific transcriptional activators (6 -10). In some cases, stimulation of transcription by activators requires the CTD (11-13). Recent work has demonstrated that the CTD is also important for pre-mRNA processing. Truncation of the CTD in vivo reduces the efficiency of capping, splicing, and 3Ј-end formation (14 -16). Moreover, purified pol II, or the CTD itself, can stimulate splicing as well as the 3Ј-end processing of transcripts in vitro (17)(18)(19). Consistent with these results, factors involved in capping, splicing, and 3Ј-end formation have been found to interact with the CTD (1, 3, 20).It is not known at which stage of transcription different pre-mRNA processing components are recruited to transcription complexes, nor how CTD-associated components influence pre-mRNA processing. The 3Ј-end cleavage polyadenylation stimulatory factor (CPSF) interacts with the general transcription factor TFIID during transcription initiation (21), as well as with the CTD (15), indicating that it is recruited to transcription initiation complexes pr...

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Section: Discussionsupporting

confidence: 50%

mentioning

confidence: 99%

Transcriptional Activators Control Splicing and 3′-End Cleavage Levels

Rosonina

Bakowski

McCracken

et al. 2003

Journal of Biological Chemistry

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“…As a consequence, the RNAP II transcripts are efficiently directed into the spliceosome assembly pathway rather than into the inhibitory H complex. A number of spliceosomal proteins that associate with RNAP II or the CTD in vitro have been identified, including Prp40, SCAFs, PSF, p54, SR proteins and all of the spliceosomal small nuclear RNPs (snRNPs) (Mortillaro et al 1996;Yuryev et al 1996;Corden and Patturajan 1997;Kim et al 1997;Patturajan et al 1998;Morris and Greenleaf 2000;Tian 2001;Emili et al 2002;Robert et al 2002;Kameoka et al 2004;Phatnani and Greenleaf 2004), but a function for these proteins in coupling remains to be demonstrated.…”

Section: Discussionmentioning

confidence: 99%

Functional coupling of RNAP II transcription to spliceosome assembly

Das¹,

Dufu²,

Romney³

et al. 2006

Genes Dev.

102

115

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The pathway of gene expression in higher eukaryotes involves a highly complex network of physical and functional interactions among the different machines involved in each step of the pathway. Here we established an efficient in vitro system to determine how RNA polymerase II (RNAP II) transcription is functionally coupled to pre-mRNA splicing. Strikingly, our data show that nascent premessenger RNA (pre-mRNA) synthesized by RNAP II is immediately and quantitatively directed into the spliceosome assembly pathway. In contrast, nascent pre-mRNA synthesized by T7 RNA polymerase is quantitatively assembled into the nonspecific H complex, which consists of heterogeneous nuclear ribonucleoprotein (hnRNP) proteins and is inhibitory for spliceosome assembly. Consequently, RNAP II transcription results in a dramatic increase in both the kinetics of splicing and overall yield of spliced mRNA relative to that observed for T7 transcription. We conclude that RNAP II mediates the functional coupling of transcription to splicing by directing the nascent pre-mRNA into spliceosome assembly, thereby bypassing interaction of the pre-mRNA with the inhibitory hnRNP proteins.

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“…Their gentle technique allowed the recovery of a mixture of transcriptionally active RNAPII holoenzymes (Mr 2.4 MDa) containing all the general transcription factors from HeLa cells [12]. The protein composition of the different TFIIS-purified holoenzymes from HeLa cells was shown to consist of subunits from the spliceosome [19] and to vary according to cell cycle [22]. The changes in protein composition of TFIIS-purified holoenzymes during cell differentiation have not been addressed.…”

Section: Introductionmentioning

confidence: 99%

“…For example, RNAPII forms different holoenzymes capable of receiving and integrating cellular signals or modifing chromatin structure [13]. The diversity of complexes that interact with RNAPII span a vast spectrum of functions in transcription, genomic maintenance and splicing [14][15][16][17][18][19].…”

Section: Introductionmentioning

confidence: 99%

Proteomics of RNA polymerase II holoenzymes during P19 cardiomyogenesis

Maës

2007

Open Life Sciences

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Abstract:The embryonal carcinoma P19 model has allowed the elucidation of a role for several transcription factors in cell differentiation. Here, the regulation of the RNA polymerase II machinery has been explored through its association with multifunctional complexes involved in transcription. An interaction proteomics analysis of TFIIS-purified RNA polymerase II (RNAPII) holoenzymes during cardiomyogenesis is described. Modifications of protein complexes that may be associated with transcriptionally active and activator responsive RNAPII holoenzymes were detected in a serum and DMSO dependent manner. Subunits of the PAF1 and Mediator complexes were correlated with holoenzymes from non-differentiated and terminally differentiated P19 cultures respectively. Moreover, high levels of nucleolin were identified in all forms of holoenzymes by two-dimensional gel electrophoresis, and suggest that nucleolin could bind to RNAPII and TFIIS. Several proteins that were identified in the RNAPII holoenzymes are known to have functions in mRNA processing and may bind to nucleolin. A novel function for nucleolin is proposed as a possible pivotal platform between transcription, mRNA processing and export.

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A Human RNA Polymerase II-containing Complex Associated with Factors Necessary for Spliceosome Assembly

Cited by 47 publications

References 40 publications

Transcriptional Activators Control Splicing and 3′-End Cleavage Levels

Transcriptional Activators Control Splicing and 3′-End Cleavage Levels

Functional coupling of RNAP II transcription to spliceosome assembly

Proteomics of RNA polymerase II holoenzymes during P19 cardiomyogenesis

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