The role of the peptidyl prolyl isomerase Rrd1 in the transcriptional stress response

Poschmann, Jeremie

08 1900

La régulation de la transcription est un processus complexe qui a évolué pendant des millions d’années permettant ainsi aux cellules de s’adapter aux changements environnementaux. Notre laboratoire étudie le rôle de la rapamycine, un agent immunosuppresseur et anticancéreux, qui mime la carence nutritionelle. Afin de comprendre les mécanismes impliqués dans la réponse a la rapamycine, nous recherchons des mutants de la levure Saccaromyces cerevisiae qui ont un phenotype altérée envers cette drogue. Nous avons identifié le gène RRD1, qui encode une peptidyl prolyl isomérase et dont la mutation rend les levures très résistantes à la rapamycine et il semble que se soit associé à une réponse transcriptionelle alterée. Mon projet de recherche de doctorat est d’identifier le rôle de Rrd1 dans la réponse à la rapamycine. Tout d’abord nous avons trouvé que Rrd1 interagit avec l’ARN polymérase II (RNAPII), plus spécifiquement avec son domaine C-terminal. En réponse à la rapamycine, Rrd1 induit un changement dans la conformation du domaine C-terminal in vivo permettant la régulation de l’association de RNAPII avec certains gènes. Des analyses in vitro ont également montré que cette action est directe et probablement liée à l’activité isomérase de Rrd1 suggérant un rôle pour Rrd1 dans la régulation de la transcription. Nous avons utilisé la technologie de ChIP sur micropuce pour localiser Rrd1 sur la majorité des gènes transcrits par RNAPII et montre que Rrd1 agit en tant que facteur d’élongation de RNAPII. Pour finir, des résultats suggèrent que Rrd1 n’est pas seulement impliqué dans la réponse à la rapamycine mais aussi à differents stress environnementaux, nous permettant ainsi d’établir que Rrd1 est un facteur d’élongation de la transcription requis pour la régulation de la transcription via RNAPII en réponse au stress. / Transcriptional regulation is a complex process that has evolved over millions of years of evolution. Cells have to sense environmental conditions and adapt to them by altering their transcription. Herein, we study the role of rapamycin, an immunosuppressant and anticancer molecule that mimics cellular starvation. To understand how the action of rapamycin is mediated, we analyzed gene deletion mutants in the yeast Saccharomyces cerevisiae that have an altered response to this drug. Deletion of RRD1, a gene encoding a peptidyl prolyl isomerase, causes strong resistance to rapamycin and this was associated with a role of Rrd1 in the transcriptional response towards rapamycin. The main focus of my PhD was therefore to unravel the role of Rrd1 in response to rapamycin. First, we discovered that Rrd1 interacts with RNA polymerase II (RNAPII), more specifically with its C-terminal domain and we showed that in response to rapamycin, Rrd1 alters the structure of this C-terminal domain. This phenomenon was confirmed to be directly mediated by Rrd1 in vitro, presumably through its peptidyl prolyl isomerase activity. Further, we demonstrated that Rrd1 is capable of altering the occupancy of RNAPII on genes in vivo and in vitro. With the use of ChIP on chip technology, we show that Rrd1 is actually a transcription elongation factor that is associated with RNAPII on actively transcribed genes. In addition, we demonstrate that Rrd1 is indeed required to regulate the expression of a large subset of genes in response to rapamycin. This data let us propose a novel mechanism by which Rrd1 regulates RNAPII during transcription elongation. Finally, we provide evidence that Rrd1 is not only required for an efficient response towards rapamycin but to a larger variety of environmental stress conditions, thus establishing Rrd1 as a transcriptional elongation factor required to fine tune the transcriptional stress response of RNAPII.

ARN polymérase II

rapamycine

peptidyl-prolyl isomérase

RNA polymerase II

rapamycin

peptidyl proly isomerase

transcription elongation

V-ATPase regulation of Hypoxia Inducible transcription Factors

Miles, Anna Louise

January 2018

Metazoans have evolved conserved mechanisms to promote cell survival under low oxygen tensions by initiating a transcriptional cascade centered on the action of Hypoxia Inducible transcription Factors (HIFs). In aerobic conditions, HIFs are inactivated by ubiquitin-proteasome-mediated degradation of their a subunit, which is dependent on prolyl hydroxylation by 2-oxoglutarate (2-OG) and Fe(II)-dependent prolyl hydroxylases (PHDs). In hypoxia, HIF-$\alpha$ is no longer hydroxylated and is therefore stabilised, activating a global transcriptional response to ensure cell survival. Interestingly, HIFs can also be activated in aerobic conditions, however the mechanisms of this oxygen-independent regulation are poorly understood. Here, I have explored the role of the vacuolar H+-ATPase (V-ATPase), the major proton pump for acidifying intracellular vesicles and facilitating lysosomal degradation, in regulating HIF-$\alpha$ turnover. Unbiased forward genetic screens in near-haploid human cells identified that disruption of the V-ATPase leads to activation of HIFs in aerobic conditions. Rather than preventing the lysosomal degradation of HIF-$\alpha$, I found that V-ATPase inhibition indirectly affects the canonical proteasome-mediated degradation of HIF-$\alpha$ isoforms by altering the intracellular iron pool and preventing HIF-$\alpha$ prolyl hydroxylation. In parallel, I characterised two putative mammalian V-ATPase assembly proteins, TMEM199 and CCDC115, identified by the forward genetic screen and subsequent mass spectrometry analysis. I confirmed that both TMEM199 and CCDC115 are required for V-ATPase function, and established assays to determine how TMEM199 and CCDC115 associate with components of the core V-ATPase complex. Lastly, to measure how V-ATPase activity leads to changes in the labile iron pool, I developed an endogenous iron reporter using CRISPR-Cas9 knock-in technology. This approach confirmed that iron homeostasis is impaired during V-ATPase inhibition, and demonstrated that exogenous ferric iron can restore the labile iron pool in a transferrin-independent manner. Together my studies highlight a crucial link between V-ATPase activity, iron homeostasis, and the hypoxic response pathway.

The role of the peptidyl prolyl isomerase Rrd1 in the transcriptional stress response

Poschmann, Jeremie

08 1900

La régulation de la transcription est un processus complexe qui a évolué pendant des millions d’années permettant ainsi aux cellules de s’adapter aux changements environnementaux. Notre laboratoire étudie le rôle de la rapamycine, un agent immunosuppresseur et anticancéreux, qui mime la carence nutritionelle. Afin de comprendre les mécanismes impliqués dans la réponse a la rapamycine, nous recherchons des mutants de la levure Saccaromyces cerevisiae qui ont un phenotype altérée envers cette drogue. Nous avons identifié le gène RRD1, qui encode une peptidyl prolyl isomérase et dont la mutation rend les levures très résistantes à la rapamycine et il semble que se soit associé à une réponse transcriptionelle alterée. Mon projet de recherche de doctorat est d’identifier le rôle de Rrd1 dans la réponse à la rapamycine. Tout d’abord nous avons trouvé que Rrd1 interagit avec l’ARN polymérase II (RNAPII), plus spécifiquement avec son domaine C-terminal. En réponse à la rapamycine, Rrd1 induit un changement dans la conformation du domaine C-terminal in vivo permettant la régulation de l’association de RNAPII avec certains gènes. Des analyses in vitro ont également montré que cette action est directe et probablement liée à l’activité isomérase de Rrd1 suggérant un rôle pour Rrd1 dans la régulation de la transcription. Nous avons utilisé la technologie de ChIP sur micropuce pour localiser Rrd1 sur la majorité des gènes transcrits par RNAPII et montre que Rrd1 agit en tant que facteur d’élongation de RNAPII. Pour finir, des résultats suggèrent que Rrd1 n’est pas seulement impliqué dans la réponse à la rapamycine mais aussi à differents stress environnementaux, nous permettant ainsi d’établir que Rrd1 est un facteur d’élongation de la transcription requis pour la régulation de la transcription via RNAPII en réponse au stress. / Transcriptional regulation is a complex process that has evolved over millions of years of evolution. Cells have to sense environmental conditions and adapt to them by altering their transcription. Herein, we study the role of rapamycin, an immunosuppressant and anticancer molecule that mimics cellular starvation. To understand how the action of rapamycin is mediated, we analyzed gene deletion mutants in the yeast Saccharomyces cerevisiae that have an altered response to this drug. Deletion of RRD1, a gene encoding a peptidyl prolyl isomerase, causes strong resistance to rapamycin and this was associated with a role of Rrd1 in the transcriptional response towards rapamycin. The main focus of my PhD was therefore to unravel the role of Rrd1 in response to rapamycin. First, we discovered that Rrd1 interacts with RNA polymerase II (RNAPII), more specifically with its C-terminal domain and we showed that in response to rapamycin, Rrd1 alters the structure of this C-terminal domain. This phenomenon was confirmed to be directly mediated by Rrd1 in vitro, presumably through its peptidyl prolyl isomerase activity. Further, we demonstrated that Rrd1 is capable of altering the occupancy of RNAPII on genes in vivo and in vitro. With the use of ChIP on chip technology, we show that Rrd1 is actually a transcription elongation factor that is associated with RNAPII on actively transcribed genes. In addition, we demonstrate that Rrd1 is indeed required to regulate the expression of a large subset of genes in response to rapamycin. This data let us propose a novel mechanism by which Rrd1 regulates RNAPII during transcription elongation. Finally, we provide evidence that Rrd1 is not only required for an efficient response towards rapamycin but to a larger variety of environmental stress conditions, thus establishing Rrd1 as a transcriptional elongation factor required to fine tune the transcriptional stress response of RNAPII.

ARN polymérase II

rapamycine

peptidyl-prolyl isomérase

RNA polymerase II

rapamycin

peptidyl proly isomerase

transcription elongation

Estudo fitoquímico e avaliação das atividades antimicrobiana, de inibição enzimática e antitumoral de Erythrina crista-galli nativa do RS / Phytochemical study and evaluation of antimicrobial, enzymatic inhibition and antitumor activities Erythrina crista-galli native from RS

Ávila, Janaína Medeiros de

05 September 2013

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / The phytochemical study of the crude extract hexane, methanol and fractions (acid ether, basic ether and basic acetate) from the stem bark of E. crista-galli (Fabaceae) resulted in the isolation of four compounds: The phytosterol stigmasterol (70), the triterpene lupeol (71) and the alkaloids erysotrine (1) and epierythratidine (50), usual in the genus Erythrina. The structures of the isolated metabolites were elucidated by 1H and 13C NMR uni and bidimensional, and compared with standard sample and data available in the literature. The extracts, fractions and isolated compounds were tested for their antimicrobial and antitumor front cancer cells HT29 (colorectal) activities, as well as regarding the capacity of inhibition of enzymes prolyl oligopeptidase, dipeptidil peptidase-VI and acetylcholinesterase. The crude methanolic extract, all fractions and individual compounds showed high antimicrobial activity mainly against Gram-positive and Gram-negative bacteria. The results were satisfactory in POP inhibition assays, when the crude methanolic extract and its fractions, mainly acid ether fraction, showed great inhibitor potential against this enzyme. For DPP-IV only the crude hexane extract was active. The in vitro antitumoral activity of the crude methanolic extract, basic fractions and the isolate alkaloids was investigated at different concentrations against the human colon cancer cell line HT-29 (PicoGreen dsDNA assay). The results suggest that the anti-proliferative effect of E. crista-galli extract on HT-29 cancer cells may be attributed, at least in part, to the presence of the erythrinian alkaloids 1 and 50. / O estudo fitoquímico do extrato bruto hexânico, metanólico e frações (éter ácida, éter básica e acetato básica) das cascas do caule de E. crista-galli (Fabaceae) resultou no isolamento de quatro compostos: o fitoesterol estigmasterol (70) e o triterpeno lupeol (71) além dos alcaloides erisotrina (1) e epieritratidina (50) usuais do gênero Erythrina. As estruturas dos metabólitos isolados foram elucidadas através de RMN 1H e 13C, uni e bidimensionais, além de comparação com amostra padrão quando existente e dados disponíveis na literatura. Os extratos, as frações e os compostos isolados foram testados quanto à sua atividade antimicrobiana, antitumoral frente a células cancerígenas HT29 (colorretal) e de inibição das enzimas POP, DPP-IV e AChE. Dentre as amostras testadas, o extrato bruto metanólico (EBM), suas frações (FEA, FEB e FAB) e compostos isolados apresentaram grande potencial antimicrobiano principalmente frente as bactérias Gram-positivas e Gram-negativas. Os resultados obtidos nos ensaios enzimáticos foram satisfatórios para a enzima POP, onde o EBM e suas frações, principalmente a fração éterea ácida (FEA), demonstraram grande potencial inibidor desta enzima. Para a DPP-IV apenas o extrato bruto hexânico (EBH) mostrou-se ativo. O efeito antitumoral da planta em questão também foi investigado e os resultados obtidos indicam que o EBM, a combinação das frações FEB e FAB e o alcaloide epieritratidina (50) possuem um grande efeito antiproliferativo frente às células do colorretal (HT29) após 72 horas de exposição.

Erythrina crista-galli

Fabaceae

Alcaloides

Atividades biológicas

Erythrina crista-galli

Fabaceae

Alkaloids

Antimicrobial activity

Enzymatic inhibition assay

Prolyl oligopeptidase

Dipeptidil peptidase-IV

Acetylcholinesterase

Antitumor activity