Regulation of fission yeast cohesin by the Cyclin Dependent Kinase PeF1

Le complexe cohésine est un complexe protéique en forme d'anneau composé de quatre sous-unités essentielles très conservées: Smc1, Smc3, Rad21 et Scc3. Par sa capacité à encercler les molécules d’ADN, les cohésines participent à de nombreux processus cellulaires tels que la ségrégation des chromosomes, la signalisation et la réparation des dommages à l’ADN, la régulation de la transcription et l'organisation du génome. Pour assurer ces différentes fonctions biologiques les cohésines doivent être finement régulées à la fois dans le temps et l’espace. Ces régulations reposent en partie sur le contrôle de leur association à la chromatine (capture de l’ADN). Cela nécessite l'action d'un «facteur de chargement » composé de deux protéines conservées et essentielles, Mis4 et Ssl3 chez la levure S. pombe. Comment ce complexe régule la capture de l’ADN par l’anneau de cohésine dans l'espace et le temps demeure à ce jour très mal compris. Afin d’identifier des régulateurs de l’association des cohésines à la chromatine, nous avons réalisé un crible génétique visant à rechercher des suppresseurs de la mutation thermosensible mis4-367. Ce crible a conduit à l’identification de la Cyclin-Dependent Kinase Pef1 qui agit comme un régulateur négatif de la cohésion des chromatides soeurs en contrôlant vraisemblablement négativement l’association des cohésines à la chromatine. De forts arguments expérimentaux indiquent que Pef1 exerce sa fonction en régulant directement la phosphorylation de la sous-unité Rad21 du complexe cohésine. De façon intéressante, via un autre crible génétique, nous avons identifié la phosphatase Pph3/Psy2 qui joue un rôle dans l’établissement de la cohésion des chromatides soeurs en contrôlant la déphosphorylation de Rad21.Ensemble, ces données suggèrent que le contrôle de l’état de phosphorylation de la sous-unité Rad21 du complexe cohésine joue un rôle central dans le processus de cohésion chez la levure S. Pombe.Cohesin is a highly conserved ring-shaped protein complex made of four essential subunits: Psm1, Psm3, Rad21 and Psc3. By its ability to capture DNA molecules within its ring-like structure, cohesion plays a key role in many cellular processes such as chromosome segregation, DNA damage signalling and repair, transcriptional gene regulation and nuclear organization. To ensure all of its biological functions, cohesin must be tightly regulated in space and time. This regulation relies in part on the control of cohesin binding to chromatin (DNA capture). Cohesin recruitment to chromatin requires the action of a “loading complex” made of two conserved and essential proteins named Mis4 and Ssl3 in the fission yeast. How this complex regulates where and when DNA capture by the cohesin ring must occur remains poorly understood. To identify regulators of cohesin binding to chromatin we have performed a genetic screen for suppressors of the thermosensitive mutation mis4-367. This genetic screen has led to the identification of the cyclin-dependent-kinase Pef1 that acts as a negative regulator of sister chromatids cohesion may be bynegatively controlling cohesin binding to chromatin. Strong experimental evidences indicate that Pef1 exerts its function at least in part by directly phosphorylating the Rad21 subunit of the cohesin complex. Interestingly, a genetic screen made in parallel identified the Pph3/Psy2 phosphatase as implicated in the establishment of sister chromatid cohesion by regulating Rad21 dephosphorylation. Strikingly, the control of Rad21 phosphorylation status appears central to the cohesion process in the fission yeast S. pombe

Régulation des cohésines chez Schizosaccharomyces pombe par la Kinase Cycline Dépendante Pef1

Cohesin is a highly conserved ring-shaped protein complex made of four essential subunits: Psm1, Psm3, Rad21 and Psc3. By its ability to capture DNA molecules within its ring-like structure, cohesion plays a key role in many cellular processes such as chromosome segregation, DNA damage signalling and repair, transcriptional gene regulation and nuclear organization. To ensure all of its biological functions, cohesin must be tightly regulated in space and time. This regulation relies in part on the control of cohesin binding to chromatin (DNA capture). Cohesin recruitment to chromatin requires the action of a “loading complex” made of two conserved and essential proteins named Mis4 and Ssl3 in the fission yeast. How this complex regulates where and when DNA capture by the cohesin ring must occur remains poorly understood. To identify regulators of cohesin binding to chromatin we have performed a genetic screen for suppressors of the thermosensitive mutation mis4-367. This genetic screen has led to the identification of the cyclin-dependent-kinase Pef1 that acts as a negative regulator of sister chromatids cohesion may be bynegatively controlling cohesin binding to chromatin. Strong experimental evidences indicate that Pef1 exerts its function at least in part by directly phosphorylating the Rad21 subunit of the cohesin complex. Interestingly, a genetic screen made in parallel identified the Pph3/Psy2 phosphatase as implicated in the establishment of sister chromatid cohesion by regulating Rad21 dephosphorylation. Strikingly, the control of Rad21 phosphorylation status appears central to the cohesion process in the fission yeast S. pombe.Le complexe cohésine est un complexe protéique en forme d'anneau composé de quatre sous-unités essentielles très conservées: Smc1, Smc3, Rad21 et Scc3. Par sa capacité à encercler les molécules d’ADN, les cohésines participent à de nombreux processus cellulaires tels que la ségrégation des chromosomes, la signalisation et la réparation des dommages à l’ADN, la régulation de la transcription et l'organisation du génome. Pour assurer ces différentes fonctions biologiques les cohésines doivent être finement régulées à la fois dans le temps et l’espace. Ces régulations reposent en partie sur le contrôle de leur association à la chromatine (capture de l’ADN). Cela nécessite l'action d'un «facteur de chargement » composé de deux protéines conservées et essentielles, Mis4 et Ssl3 chez la levure S. pombe. Comment ce complexe régule la capture de l’ADN par l’anneau de cohésine dans l'espace et le temps demeure à ce jour très mal compris. Afin d’identifier des régulateurs de l’association des cohésines à la chromatine, nous avons réalisé un crible génétique visant à rechercher des suppresseurs de la mutation thermosensible mis4-367. Ce crible a conduit à l’identification de la Cyclin-Dependent Kinase Pef1 qui agit comme un régulateur négatif de la cohésion des chromatides soeurs en contrôlant vraisemblablement négativement l’association des cohésines à la chromatine. De forts arguments expérimentaux indiquent que Pef1 exerce sa fonction en régulant directement la phosphorylation de la sous-unité Rad21 du complexe cohésine. De façon intéressante, via un autre crible génétique, nous avons identifié la phosphatase Pph3/Psy2 qui joue un rôle dans l’établissement de la cohésion des chromatides soeurs en contrôlant la déphosphorylation de Rad21.Ensemble, ces données suggèrent que le contrôle de l’état de phosphorylation de la sous-unité Rad21 du complexe cohésine joue un rôle central dans le processus de cohésion chez la levure S. Pombe

Comparing NER approaches on French clinical text, with easy-to-reuse pipelines

International audienceThe task of Named Entity Recognition (NER) is central for leveraging the content of clinical texts in observational studies. Indeed, texts contain a large part of the information available in Electronic Health Records (EHRs). However, clinical texts are highly heterogeneous between healthcare services and institutions, between countries and languages, making it hard to predict how existing tools may perform on a particular corpus. We compared four NER approaches on three French corpora and share our benchmarking pipeline in an open and easy-to-reuse manner, using the medkit Python library. We include in our pipelines fine-tuning operations with either one or several of the considered corpora. Our results illustrate the expected superiority of language models over a dictionary-based approach, and question the necessity of refining models already trained on biomedical texts. Beyond benchmarking, we believe sharing reusable and customizable pipelines for comparing fast-evolving Natural Language Processing (NLP) tools is a valuable contribution, since clinical texts themselves can hardly be shared for privacy concerns

RNA-binding protein Mub1 and the nuclear RNA exosome act to fine-tune environmental stress response

The nuclear RNA exosome plays a key role in controlling the levels of multiple protein-coding and non-coding RNAs. Recruitment of the exosome to specific RNA substrates is mediated by RNA-binding co-factors. The transient interaction between co-factors and the exosome as well as the rapid decay of RNA substrates make identification of exosome co-factors challenging. Here, we use comparative poly(A)+ RNA interactome capture in fission yeast expressing three different mutants of the exosome to identify proteins that interact with poly(A)+ RNA in an exosome-dependent manner. Our analyses identify multiple RNA-binding proteins whose association with RNA is altered in exosome mutants, including the zinc-finger protein Mub1. Mub1 is required to maintain the levels of a subset of exosome RNA substrates including mRNAs encoding for stress-responsive proteins. Removal of the zinc-finger domain leads to loss of RNA suppression under non-stressed conditions, altered expression of heat shock genes in response to stress, and reduced growth at elevated temperature. These findings highlight the importance of exosome-dependent mRNA degradation in buffering gene expression networks to mediate cellular adaptation to stress

TAXN: Translate Align Extract Normalize, a multilingual extraction tool for clinical texts

International audienceSeveral studies have shown that about 80% of the medical information in an electronic health record is only available through unstructured data. Resources such as medical terminologies in languages other than English are limited and restrain the NLP tools. We propose here to leverage English based resources in other languages using a combination of translation, word alignment, entity extraction and term normalization (TAXN). We implement this extraction pipeline in an opensource library called "medkit". We demonstrate the interest of this approach through a specific use-case: enriching a phenotypic dictionary for post-acute sequelae in COVID-19 (PASC). TAXN proved to be efficient to propose new synonyms of UMLS terms using a corpus of 70 articles in French with 356 terms enriched with at least one validated new synonym. This study was based on freely available deeplearning models

A second Wpl1 anti-cohesion pathway requires dephosphorylation of fission yeast kleisin Rad21 by PP4

Cohesin mediates sister chromatid cohesion which is essential for chromosome segregation and repair. Sister chromatid cohesion requires an acetyl-transferase (Eso1 in fission yeast) counteracting Wpl1, promoting cohesin release from DNA. We report here that Wpl1 anti-cohesion function includes an additional mechanism. A genetic screen uncovered that Protein Phosphatase 4 (PP4) mutants allowed cell survival in the complete absence of Eso1. PP4 co-immunoprecipitated Wpl1 and cohesin and Wpl1 triggered Rad21 de-phosphorylation in a PP4-dependent manner. Relevant residues were identified and mapped within the central domain of Rad21. Phospho-mimicking alleles dampened Wpl1 anti-cohesion activity, while alanine mutants were neutral indicating that Rad21 phosphorylation would shelter cohesin from Wpl1 unless erased by PP4. Experiments in post-replicative cells lacking Eso1 revealed two cohesin populations. Type 1 was released from DNA by Wpl1 in a PP4-independent manner. Type 2 cohesin, however, remained DNA-bound and lost its cohesiveness in a manner depending on Wpl1-and PP4-mediated Rad21 de-phosphorylation. These results reveal that Wpl1 antagonizes sister chromatid cohesion by a novel pathway regulated by the phosphorylation status of the cohesin kleisin subunit

The CDK Pef1 and protein phosphatase 4 oppose each other for regulating cohesin binding to fission yeast chromosomes

International audienceCohesin has essential roles in chromosome structure, segregation and repair. Cohesin binding to chromosomes is catalyzed by the cohesin loader, Mis4 in fission yeast. How cells fine tune cohesin deposition is largely unknown. Here, we provide evidence that Mis4 activity is regulated by phosphorylation of its cohesin substrate. A genetic screen for negative regulators of Mis4 yielded a CDK called Pef1, whose closest human homologue is CDK5. Inhibition of Pef1 kinase activity rescued cohesin loader deficiencies. In an otherwise wild-type background, Pef1 ablation stimulated cohesin binding to its regular sites along chromosomes while ablating Protein Phosphatase 4 had the opposite effect. Pef1 and PP4 control the phosphorylation state of the cohesin kleisin Rad21. The CDK phosphorylates Rad21 on Threonine 262. Pef1 ablation, non-phosphorylatable Rad21-T262 or mutations within a Rad21 binding domain of Mis4 alleviated the effect of PP4 deficiency. Such a CDK/PP4-based regulation of cohesin loader activity could provide an efficient mechanism for translating cellular cues into a fast and accurate cohesin response

Transcription and chromatin-based surveillance mechanism controls suppression of cryptic antisense transcription

Phosphorylation of the RNA polymerase II C-terminal domain Y(1)S(2)P(3)T(4)S(5)P(6)S(7) consensus sequence coordinates key events during transcription, and its deregulation leads to defects in transcription and RNA processing. Here, we report that the histone deacetylase activity of the fission yeast Hos2/Set3 complex plays an important role in suppressing cryptic initiation of antisense transcription when RNA polymerase II phosphorylation is dysregulated due to the loss of Ssu72 phosphatase. Interestingly, although single Hos2 and Set3 mutants have little effect, loss of Hos2 or Set3 combined with ssu72Δ results in a synergistic increase in antisense transcription globally and correlates with elevated sensitivity to genotoxic agents. We demonstrate a key role for the Ssu72/Hos2/Set3 mechanism in the suppression of cryptic antisense transcription at the 3′ end of convergent genes that are most susceptible to these defects, ensuring the fidelity of gene expression within dense genomes of simple eukaryotes

Histone deacetylation promotes transcriptional silencing at facultative heterochromatin

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Elongation/Termination Factor Exchange Mediated by PP1 Phosphatase Orchestrates Transcription Termination

Summary: Termination of RNA polymerase II (Pol II) transcription is a key step that is important for 3′ end formation of functional mRNA, mRNA release, and Pol II recycling. Even so, the underlying termination mechanism is not yet understood. Here, we demonstrate that the conserved and essential termination factor Seb1 is found on Pol II near the end of the RNA exit channel and the Rpb4/7 stalk. Furthermore, the Seb1 interaction surface with Pol II largely overlaps with that of the elongation factor Spt5. Notably, Seb1 co-transcriptional recruitment is dependent on Spt5 dephosphorylation by the conserved PP1 phosphatase Dis2, which also dephosphorylates threonine 4 within the Pol II heptad repeated C-terminal domain. We propose that Dis2 orchestrates the transition from elongation to termination phase during the transcription cycle by mediating elongation to termination factor exchange and dephosphorylation of Pol II C-terminal domain. : Timely and efficient transcription termination is essential for release of functional mRNAs as well as for Pol II recycling. Kecman et al. demonstrate that the conserved PP1 phosphatase Dis2 regulates transcription termination in fission yeast by mediating elongation to termination factor exchange and by dephosphorylating Pol II C-terminal domain. Keywords: RNA polymerase II, C-terminal domain, CTD, PP1 phosphatase, transcription termination, CTD phosphorylation, Spt5, CTD interacting domain, CI