Ssu72 and Rtr1 Serine 5 Phosphates and Their Role in NNS and CPF Transcription Termination

Victorino, Jose Fabian

05 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Polyadenylation dependent transcription termination is dependent on the Cleavage and Polyadenylation Factor complex (CPF) which is essential for the termination and processing of mature RNA. Polyadenylation (PolyA) independent transcription termination is carried out by the NNS (Nrd1-Nab3-Sen1) termination pathway, which helps regulate termination and processing of non-coding RNA (ncRNA). The disruption of these pathways can impact expression of nearby genes, both protein coding and noncoding. Recruitment of termination pathway components is achieved through a domain unique to the largest subunit of RNA Polymerase II (RNAPII) referred to as the Cterminal domain (CTD), which contains a repeating heptad sequence, Y1S2P3T4S5P6S7, and acts as a docking site for transcription regulatory proteins. Ssu72 is a serine 5 phosphatase and an essential member of the CPF complex. Rtr1 is also a serine 5 phosphatase, but its mechanism of action is less well characterized. Both Rtr1 and Ssu72 regulate transcription machinery recruitment through control of the phosphorylation status of the CTD. My studies have focused on Rtr1 and Ssu72 mutants in yeast which show evidence of transcription termination related phenotypes. Chromatin immunoprecipitation of RNAPII followed by exonuclease treatment (ChIP-exo) studies provide evidence of RNAPII transcription continuing through termination sites at ncRNA genes as a result of a hyperactive Ssu72-L84F mutant, while an RTR1 knockout results in increased premature RNAPII transcription termination. Northern blots and RNA sequencing confirm premature transcription termination and decreased total RNA expression in the RTR1 knockout and increased length of ncRNA transcripts as well as total RNA expression in the Ssu72-L84F mutant. Mass spectrometry analysis has identified changes in the protein-protein interactions (PPI) within the CPF complex in the Ssu72-L84F mutant and decreased PPIs between different transcription machinery in RTR1 knockout cells. My results show that the CTD phosphatases Rtr1 and Ssu72 play unique roles in the regulation of RNAPII termination in eukaryotes. / 2020-11-19

Phosphatase

RNAPII

Rtr1

Ssu72

Termination

Transcription

Structural and Kinetic Characterization of RNA Polymerase II C-Terminal Domain Phosphatase Ssu72 and Development of New Methods for NMR Studies of Large Proteins

Werner-Allen, Jonathan

January 2011

<p>Ssu72 is a protein phosphatase that selectively targets phosphorylated serine residues at the 5th position (pS5) in the heptad repeats of the C-terminal domain (CTD) of RNA polymerase II, in order to regulate the CTD-mediated coupling between eukaryotic transcription and co-transcriptional events. The biological importance of Ssu72 is underscored by (1) the requirement of its activity for viability in yeast, and (2) the numerous phenotypes - affecting all three stages of the transcription cycle - that result from its mutation in yeast. Despite limited homology to the low molecular weight (LMW) subclass of protein tyrosine phosphatases (PTPs), several lines of evidence suggest that Ssu72 represents the founding member of a new class of enzymes, including its unique substrate specificity and an in vivo connection with the activity of proline isomerase Ess1.</p><p>The main focus of this thesis has been to structurally and kinetically characterize Ssu72, in order to define its relation to known enzyme families, to provide biochemical explanations for extant in vivo observations, and to allow future structure-guided investigations of its role in coordinating transcription with co-transcriptional events. To this end, we solved the structure of Ssu72 in complex with its pS5 CTD substrate, revealing an enzyme fold with unique structural features and a surprising substrate conformation with the pS5-P6 motif of the CTD adopting the cis configuration. Together with kinetic assays, the structure provides a new interpretation of the role of proline isomers in regulating the CTD phosphorylation state, with broad implications for CTD biology.</p><p>The second goal of this thesis has been to develop new methods for NMR studies of large proteins, which present unique challenges to conventional methods, including fast signal decay and severe signal degeneracy. The first of these new methods, the `just-in-time' HN(CA)CO, improves the sensitivity of a common backbone assignment experiment. The next two methods, the 4-D diagonal-suppressed TROSY-NOESY-TROSY and the 4-D time-shared NOESY, were designed for use with sparse sampling techniques that allow the acquisition of high-resolution, high-dimensionality datasets. These efforts culminate with global fold calculations for large proteins, including the 23 kDa Ssu72, with accurate and unambiguous automated assignment of NOE crosspeaks. We expect that the methods presented here will be particularly useful as the NMR community continues to push toward higher molecular weight targets.</p> / Dissertation

Biochemistry

cis proline

NMR

RNAPII CTD

SCRUB

sparse sampling

Ssu72

The impact of the termination override mutation on the activity of SSU72

McCracken, Neil Andrew

19 December 2016

Indiana University-Purdue University Indianapolis (IUPUI) / Ssu72, an RNA Pol II CTD phosphatase that is conserved across eukaryotes, has been reported to have a wide array of genetic and physical associations with transcription factors and complexes in RNA transcription. Catalytic mutants of Ssu72 are lethal across many eukaryotes, and mutations to non-catalytic sites in SSU72 phosphatase have been shown to lower function. One spontaneous mutation of the SSU72 gene in Saccharomyces cerevisiae (A to C nucleotide mutation resulting in an L84F mutation in the coded protein) was shown to have transcription termination deficiency (termination override or TOV). This SSU72 mutation was suggested by Loya et al. to cause a lowering of the phosphatase activity of the protein and consequently affect proper termination. In research reported herein, an investigation was completed through in-vitro and ex-vivo approaches with the goal of understanding the impact of the SSU72 TOV mutation on the observed phenotype in S. cerevisiae. It can be concluded from work presented in this report that the SSU72 TOV mutation does not cause a decrease in in-vitro phosphatase activity as compared to wild type. Evidence presented even suggests an increase in phosphatase activity as compared to wild type Ssu72. One model for the observed responses in transcription termination is that the phenylalanine substitution in Ssu72 leads to cooperative interactions with proline residues in the CTD. It is proposed that the corresponding increase in Ssu72 phosphatase activity limits RNA Pol II CTD association with termination factors, such as Nrd1, thus causing deficient transcription termination.

Ssu72

CTD

Transcription

L84F

L84A

RNA Polymerase II

Control of expression of human snRNA genes

Zaborowska, Justyna Katarzyna

January 2013

In humans, protein-coding genes and most small nuclear (sn)RNA genes are transcribed by RNA polymerase II (pol II).The carboxy-terminal domain (CTD) of the largest subunit of pol II possesses multiple heptapetide repeats of the consensus Tyr1-Ser2-Pro3-Thr4-Ser5-Pro6-Ser7. Phosphorylation of Ser2, Ser5 and Ser7 mediates the recruitment of transcription and RNA processing factors during the transcription cycle. There are notable differences between snRNA genes and protein-coding genes in terms of mechanisms controlling their expression. Pol II does not appear to make the transition to long-range productive elongation during transcription of snRNA genes, as happens during transcription of protein-coding genes. In addition, recognition of the snRNA gene-type specific 3' box RNA processing element requires initiation from an snRNA gene promoter. These characteristics may, at least in part, be driven by factors recruited to the promoter. Initiation of transcription of most human genes transcribed by pol II requires the formation of a preinitiation complex (PIC) comprising TFIIA, B, D, E, F and H and pol II. The general transcription factor, TFIID is composed of the TATA-binding protein and up to 13 TBP-associated factors (TAFs). Differences in the complement of TAFs might result in differential recruitment of elongation and RNA processing factors. It has already been shown that the promoters of some protein-coding genes do not recruit all the TAFs found in TFIID. Although TAF5, has been shown to be associated with pol II-transcribed snRNA genes, the full complement of TAFs associated with these genes remained unclear. Here I show, using a ChIP and siRNA-mediated knockdown approach, that the TBP/TAF complex on snRNA genes differs from that on protein-coding genes. Interestingly, the largest TAF, TAF1 and the core TAFs, TAF10 and TAF4 are not detected on snRNA genes. I propose that this snRNA gene-specific TAF subset plays a key role in gene-type-specific control of expression. In addition, in order to further understand the molecular mechanism underlying the differences between expression of protein-coding genes and snRNA genes, I have investigated the role of RNA pol II-associated protein 2 (RPAP2) in transcription of snRNA genes. Here I show that RPAP2 recognizes the phospho-Ser7 mark on the pol II CTD, siRNA mediated knockdown of RPAP2 causes defects in snRNA gene expression and that RPAP2 is a CTD Ser5 phosphatase. I also present my studies of the mechanism of inhibition of phospho-Ser2 by herpes simplex virus-1 (HSV-1) protein ICP22. Phosphorylation of Ser2 by the positive transcription elongation factor (P-TEFb) is associated with productive transcriptional elongation. However, P-TEFb is not required for elongation of transcription of snRNA genes, but functions only to activate 3' box-directed RNA processing. In addition, there are conflicting data as to whether Cdk9 is acting as a Ser2 kinase during transcription of pol II-transcribed snRNA genes. As ICP22 is thought to inhibit P-TEFb, this protein could provide an alternative means to study P-TEFb function in expression of snRNA genes.

572.8

Étude de la variante d’histone H2A.Z et du cycle de phosphorylation de l’ARN polymérase II chez Saccharomyces cerevisiae

Bataille, Alain R.

02 1900

La chromatine est plus qu’un système d’empaquetage de l’ADN ; elle est le support de toutes les réactions liées à l’ADN dans le noyau des cellules eucaryotes et participe au contrôle de l’accès de l’ARN polymérase II (ARNPolII) à l’ADN. Responsable de la transcription de tous les ARNm des cellules eucaryotes, l’ARNPolII doit, suivant son recrutement aux promoteurs des gènes, transcrire l’ADN en traversant la matrice chromatinienne. Grâce au domaine C-terminal (CTD) de sa sous-unité Rpb1, elle coordonne la maturation de l’ARNm en cours de synthèse ainsi que les modifications de la chromatine, concomitantes à la transcription. Cette thèse s’intéresse à deux aspects de la transcription : la matrice, avec la localisation de la variante d’histone H2A.Z, et la machinerie de transcription avec le cycle de phosphorylation du CTD de l’ARNPolII. Suivant l’introduction, le chapitre 2 de cette thèse constitue un protocole détaillé et annoté de la technique de ChIP-chip, chez la levure Saccharomyces cerevisiae. Cette technique phare dans l’étude in vivo des phénomènes liés à l’ADN a grandement facilité l’étude du rôle de la chromatine dans les phénomènes nucléaires, en permettant de localiser sur le génome les marques et les variantes d’histones. Ce chapitre souligne l’importance de contrôles adéquats, spécifiques à l’étude de la chromatine. Au chapitre 3, grâce à la méthode de ChIP-chip, la variante d’histone H2A.Z est cartographiée au génome de la levure Saccharomyces cerevisiae avec une résolution d’environ 300 paires de bases. Nos résultats montrent que H2A.Z orne un à deux nucléosomes au promoteur de la majorité des gènes. L’enrichissement de H2A.Z est anticorrélé à la transcription et nos résultats suggèrent qu’elle prépare la chromatine pour l’activation des gènes. De plus H2A.Z semble réguler la localisation des nucléosomes. Le chapitre suivant s’intéresse à la transcription sous l’angle de la machinerie de transcription en se focalisant sur le cycle de phosphorylation de l’ARN polymérase II. Le domaine C-terminal de sa plus large sous-unité est formé de répétitions d’un heptapeptide YSPTSPS dont les résidus peuvent être modifiés au cours de la transcription. Cette étude localise les marques de phosphorylation des trois résidus sérine de manière systématique dans des souches mutantes des kinases et phosphatases. Nos travaux confirment le profil universel des marques de phosphorylations aux gènes transcrits. Appuyés par des essais in vitro, ils révèlent l’interaction complexe des enzymes impliqués dans la phosphorylation, et identifient Ssu72 comme la phosphatase de la sérine 7. Cet article appuie également la notion de « variantes » des marques de phosphorylation bien que leur étude spécifique s’avère encore difficile. La discussion fait le point sur les travaux qui ont suivi ces articles, et sur les expériences excitantes en cours dans notre laboratoire. / Chromatin is more than just the eucaryotic DNA packaging system; it is the substrate of all reactions involving DNA in eukaryotic cells and actively regulates RNA Polymerase II (RNAPolII) access to DNA. Responsible for all mRNA transcription in eucaryotes, the RNAPolII must, following its recruitment to the pre-initiation complex, overcome the chromatin barrier in order to transcribe genes. The RNAPolII CTD allows for the co-transcriptional coordination of mRNA maturation and chromatin modifications. The work covered in this thesis addresses two aspects of transcription: the chromatin substrate, with the localization of H2A variant, H2A.Z, and the transcription complex with the phosphorylation cycle of the RNAPolII CTD. Following the introduction, chapter 2 constitutes a detailed and annotated Saccharomyces cerevisiae ChIP-chip protocol, from the culture to the hybridization of the array, with an emphasis on the proper controls required for chromatin study. This technique, extremely powerful for the in vivo study of all DNA transactions, leads to a better understanding of chromatin function in nuclear phenomena, thanks to the localization of histone variants and modifications. The third chapter maps the H2A.Z variant across the yeast genome at ~300 base pairs resolution using ChIP-chip. Our data shows that H2A.Z is incorporated into one or two promoter-bound nucleosomes at the majority of genes. H2A.Z enrichment is anticorrelated with transcription, and the results suggest that it configures chromatin structure to poise genes for transcriptional activation. Furthermore, we have shown that H2A.Z can regulate nucleosome positioning. The next chapter focuses on the transcription machinery and, more precisely, on the phosphorylation cycle of RNAPolII. The CTD contains repetitions of a heptapeptide (YSPTSPS) on which all serines are differentially phosphorylated along genes in a prescribed pattern during the transcription cycle. Here, we systematically profiled the location of the RNAPII phospho-isoforms in wild-type cells and mutants for most CTD modifying enzymes. The results provide evidence for a uniform CTD cycle across genes. Together with results from in vitro assays, these data reveal a complex interplay between the modifying enzymes, identify Ssu72 as the Ser7 phosphatase and show that proline isomerization is a key regulator of CTD dephosphorylation at the end of genes. Moreover, it reinforces the notion of variants of the phosphorylation marks, even though the exact nature of the variant is still difficult to identify. The discussion introduces the studies that followed this work, including new projects conceived in our lab.

Immunoprécipitation de la chromatine

Chromatine

H2A.Z

Transcription

ARN polymérase II

Chromatin Immunoprecipitation

Chromatin

RNA polymérase II

CTD

Kin28

Bur1

Ssu72

Fcp1

Étude de la variante d’histone H2A.Z et du cycle de phosphorylation de l’ARN polymérase II chez Saccharomyces cerevisiae

Bataille, Alain R.

02 1900

La chromatine est plus qu’un système d’empaquetage de l’ADN ; elle est le support de toutes les réactions liées à l’ADN dans le noyau des cellules eucaryotes et participe au contrôle de l’accès de l’ARN polymérase II (ARNPolII) à l’ADN. Responsable de la transcription de tous les ARNm des cellules eucaryotes, l’ARNPolII doit, suivant son recrutement aux promoteurs des gènes, transcrire l’ADN en traversant la matrice chromatinienne. Grâce au domaine C-terminal (CTD) de sa sous-unité Rpb1, elle coordonne la maturation de l’ARNm en cours de synthèse ainsi que les modifications de la chromatine, concomitantes à la transcription. Cette thèse s’intéresse à deux aspects de la transcription : la matrice, avec la localisation de la variante d’histone H2A.Z, et la machinerie de transcription avec le cycle de phosphorylation du CTD de l’ARNPolII. Suivant l’introduction, le chapitre 2 de cette thèse constitue un protocole détaillé et annoté de la technique de ChIP-chip, chez la levure Saccharomyces cerevisiae. Cette technique phare dans l’étude in vivo des phénomènes liés à l’ADN a grandement facilité l’étude du rôle de la chromatine dans les phénomènes nucléaires, en permettant de localiser sur le génome les marques et les variantes d’histones. Ce chapitre souligne l’importance de contrôles adéquats, spécifiques à l’étude de la chromatine. Au chapitre 3, grâce à la méthode de ChIP-chip, la variante d’histone H2A.Z est cartographiée au génome de la levure Saccharomyces cerevisiae avec une résolution d’environ 300 paires de bases. Nos résultats montrent que H2A.Z orne un à deux nucléosomes au promoteur de la majorité des gènes. L’enrichissement de H2A.Z est anticorrélé à la transcription et nos résultats suggèrent qu’elle prépare la chromatine pour l’activation des gènes. De plus H2A.Z semble réguler la localisation des nucléosomes. Le chapitre suivant s’intéresse à la transcription sous l’angle de la machinerie de transcription en se focalisant sur le cycle de phosphorylation de l’ARN polymérase II. Le domaine C-terminal de sa plus large sous-unité est formé de répétitions d’un heptapeptide YSPTSPS dont les résidus peuvent être modifiés au cours de la transcription. Cette étude localise les marques de phosphorylation des trois résidus sérine de manière systématique dans des souches mutantes des kinases et phosphatases. Nos travaux confirment le profil universel des marques de phosphorylations aux gènes transcrits. Appuyés par des essais in vitro, ils révèlent l’interaction complexe des enzymes impliqués dans la phosphorylation, et identifient Ssu72 comme la phosphatase de la sérine 7. Cet article appuie également la notion de « variantes » des marques de phosphorylation bien que leur étude spécifique s’avère encore difficile. La discussion fait le point sur les travaux qui ont suivi ces articles, et sur les expériences excitantes en cours dans notre laboratoire. / Chromatin is more than just the eucaryotic DNA packaging system; it is the substrate of all reactions involving DNA in eukaryotic cells and actively regulates RNA Polymerase II (RNAPolII) access to DNA. Responsible for all mRNA transcription in eucaryotes, the RNAPolII must, following its recruitment to the pre-initiation complex, overcome the chromatin barrier in order to transcribe genes. The RNAPolII CTD allows for the co-transcriptional coordination of mRNA maturation and chromatin modifications. The work covered in this thesis addresses two aspects of transcription: the chromatin substrate, with the localization of H2A variant, H2A.Z, and the transcription complex with the phosphorylation cycle of the RNAPolII CTD. Following the introduction, chapter 2 constitutes a detailed and annotated Saccharomyces cerevisiae ChIP-chip protocol, from the culture to the hybridization of the array, with an emphasis on the proper controls required for chromatin study. This technique, extremely powerful for the in vivo study of all DNA transactions, leads to a better understanding of chromatin function in nuclear phenomena, thanks to the localization of histone variants and modifications. The third chapter maps the H2A.Z variant across the yeast genome at ~300 base pairs resolution using ChIP-chip. Our data shows that H2A.Z is incorporated into one or two promoter-bound nucleosomes at the majority of genes. H2A.Z enrichment is anticorrelated with transcription, and the results suggest that it configures chromatin structure to poise genes for transcriptional activation. Furthermore, we have shown that H2A.Z can regulate nucleosome positioning. The next chapter focuses on the transcription machinery and, more precisely, on the phosphorylation cycle of RNAPolII. The CTD contains repetitions of a heptapeptide (YSPTSPS) on which all serines are differentially phosphorylated along genes in a prescribed pattern during the transcription cycle. Here, we systematically profiled the location of the RNAPII phospho-isoforms in wild-type cells and mutants for most CTD modifying enzymes. The results provide evidence for a uniform CTD cycle across genes. Together with results from in vitro assays, these data reveal a complex interplay between the modifying enzymes, identify Ssu72 as the Ser7 phosphatase and show that proline isomerization is a key regulator of CTD dephosphorylation at the end of genes. Moreover, it reinforces the notion of variants of the phosphorylation marks, even though the exact nature of the variant is still difficult to identify. The discussion introduces the studies that followed this work, including new projects conceived in our lab.

Immunoprécipitation de la chromatine

Chromatine

H2A.Z

Transcription

ARN polymérase II

Chromatin Immunoprecipitation

Chromatin

RNA polymérase II

CTD

Kin28

Bur1

Ssu72

Fcp1