Francisco Navarro scite author profile

The unconventional prefoldin URI/RMP, in humans, and its orthologue in yeast, Bud27, have been proposed to participate in the biogenesis of the RNA polymerases. However, this role of Bud27 has not been confirmed and is poorly elucidated. Our data help clarify the mechanisms governing biogenesis of the three eukaryotic RNA pols. We show evidence that Bud27 is the first example of a protein that participates in the biogenesis of the three eukaryotic RNA polymerases and the first example of a protein modulating their assembly instead of their nuclear transport. In addition we demonstrate that the role of Bud27 in RNA pols biogenesis depends on Rpb5. In fact, lack of BUD27 affects growth and leads to a substantial accumulation of the three RNA polymerases in the cytoplasm, defects offset by the overexpression of RPB5. Supporting this, our data demonstrate that the lack of Bud27 affects the correct assembly of Rpb5 and Rpb6 to the three RNA polymerases, suggesting that this process occurs in the cytoplasm and is a required step prior to nuclear import. Also, our data support the view that Rpb5 and Rpb6 assemble somewhat later than the rest of the complexes. Furthermore, Bud27 Rpb5-binding but not PFD-binding domain is necessary for RNA polymerases biogenesis. In agreement, we also demonstrate genetic interactions between BUD27, RPB5, and RPB6. Bud27 shuttles between the nucleus and the cytoplasm in an Xpo1-independent manner, and also independently of microtubule polarization and possibly independently of its association with the RNA pols. Our data also suggest that the role of Bud27 in RNA pols biogenesis is independent of the chaperone prefoldin (PFD) complex and of Iwr1. Finally, the role of URI seems to be conserved in humans, suggesting conserved mechanisms in RNA pols biogenesis.

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Rsc4 Connects the Chromatin Remodeler RSC to RNA Polymerases

Soutourina

Floch

Gendrel

et al. 2006

Molecular and Cellular Biology

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RSC is an essential, multisubunit chromatin remodeling complex. We show here that the Rsc4 subunit of RSC interacted via its C terminus with Rpb5, a conserved subunit shared by all three nuclear RNA polymerases (Pol). Furthermore, the RSC complex coimmunoprecipitated with all three RNA polymerases. Mutations in the C terminus of Rsc4 conferred a thermosensitive phenotype and the loss of interaction with Rpb5. Certain thermosensitive rpb5 mutations were lethal in combination with an rsc4 mutation, supporting the physiological significance of the interaction. Pol II transcription of ca. 12% of the yeast genome was increased or decreased twofold or more in a rsc4 C-terminal mutant. The transcription of the Pol III-transcribed genes SNR6 and RPR1 was also reduced, in agreement with the observed localization of RSC near many class III genes. Rsc4 C-terminal mutations did not alter the stability or assembly of the RSC complex, suggesting an impact on Rsc4 function. Strikingly, a C-terminal mutation of Rsc4 did not impair RSC recruitment to the RSC-responsive genes DUT1 and SMX3 but rather changed the chromatin accessibility of DNases to their promoter regions, suggesting that the altered transcription of DUT1 and SMX3 was the consequence of altered chromatin remodeling.Transcription occurs in the crowded context of the nucleus in which genes are wrapped in chromatin. The first step in gene expression involves the modification and/or the remodeling of repressive chromatin by specialized complexes. For polymerase II (Pol II)-transcribed genes, these steps are followed by the recruitment of Mediator, the general transcription factors (GTFs) and the Pol II itself, although in an order that can vary from one promoter to another (9, 34). The pathway leading from silent chromatin to transcription by Pol I and Pol III has not been studied as thoroughly but is globally similar, with an additional contribution of cognate GTFs. In yeast and human cells, the Pol III-specific transcription factor TFIIIC has been found to be required for the proper nucleosomal organization of Pol III genes (4, 23, 32). In the case of Pol I transcription, the mammalian termination factor TTF-I is able to activate transcription by promoting chromatin remodeling in synergy with ATP-dependent cofactors in vitro (24). Transcription initiation is not the only step at which chromatin might interfere with transcription. Nucleosomes residing in the transcribed region can inhibit the movement of RNA polymerases during elongation. To contend with this, the FACT complex helps human Pol II transcribe through nucleosome-induced blocks (28, 38). These observations suggest that factors that relieve the repressive effect of nucleosomes might act in conjunction with the transcription machinery at the successive stages of the transcription cycle.The repressive effect of nucleosomes is overcome by two cooperative mechanisms. The first involves the covalent modification of the histones, including the acetylation of specific histone tail lysines by acetyl transferases (...

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Transposon activation is a major driver in the genome evolution of cultivated olive trees (Olea europaea L.)

et al. 2020

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The primary domestication of olive (Olea europaea L.) in the Levant dates back to the Neolithic period, around 6,000-5,500 BC, as some archeological remains attest.Cultivated olive trees are reproduced clonally, with sexual crosses being the sporadic events that drive the development of new varieties. In order to determine the genomic changes which have occurred in a modern olive cultivar, the genome of the Picual cultivar, one of the most popular olive varieties, was sequenced. Additional 40 cultivated and 10 wild accessions were re-sequenced to elucidate the evolution of the olive genome during the domestication process. It was found that the genome of the 'Picual' cultivar contains 79,667 gene models, of which 78,079 were protein-coding genes and 1,588 were tRNA. Population analyses support two independent events in olive domestication, including an early possible genetic bottleneck. Despite genetic

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Rpb4/7 facilitates RNA polymerase II CTD dephosphorylation

Allepuz-Fuster

Martínez-Fernández

Garrido-Godino

et al. 2014

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The Rpb4 and Rpb7 subunits of eukaryotic RNA polymerase II (RNAPII) participate in a variety of processes from transcription, DNA repair, mRNA export and decay, to translation regulation and stress response. However, their mechanism(s) of action remains unclear. Here, we show that the Rpb4/7 heterodimer in Saccharomyces cerevisiae plays a key role in controlling phosphorylation of the carboxy terminal domain (CTD) of the Rpb1 subunit of RNAPII. Proper phosphorylation of the CTD is critical for the synthesis and processing of RNAPII transcripts. Deletion of RPB4, and mutations that disrupt the integrity of Rpb4/7 or its recruitment to the RNAPII complex, increased phosphorylation of Ser2, Ser5, Ser7 and Thr4 within the CTD. RPB4 interacted genetically with genes encoding CTD phosphatases (SSU72, FCP1), CTD kinases (KIN28, CTK1, SRB10) and a prolyl isomerase that targets the CTD (ESS1). We show that Rpb4 is important for Ssu72 and Fcp1 phosphatases association, recruitment and/or accessibility to the CTD, and that this correlates strongly with Ser5P and Ser2P levels, respectively. Our data also suggest that Fcp1 is the Thr4P phosphatase in yeast. Based on these and other results, we suggest a model in which Rpb4/7 helps recruit and potentially stimulate the activity of CTD-modifying enzymes, a role that is central to RNAPII function.

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Rpb1 foot mutations demonstrate a major role of Rpb4 in mRNA stability during stress situations in yeast

Garrido-Godino

García-López

Garcı́a-Martı́nez

et al. 2016

Biochimica et Biophysica Acta (BBA) - Gene Regulatory Mechanism

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