Investigating the role of the isomerase Rrd1/PTPA : from yeast to human

Chez Saccharomyces cerevisiae, les souches mutantes pour Rrd1, une protéine qui possède une activité de peptidyl prolyl cis/trans isomérase, montrent une résistance marquée à la rapamycine et sont sensibles au 4-nitroquinoline 1-oxide, un agent causant des dommages à l’ADN. PTPA, l’homologue de Rrd1 chez les mammifères, est reconnu en tant qu’activateur de protéine phosphatase 2A. Notre laboratoire a précédemment démontré que la surexpression de PTPA mène à l’apoptose de façon indépendante des protéines phosphatase 2A. La fonction moléculaire de Rrd1/PTPA était encore largement inconnue au départ de mon projet de doctorat. Mes recherches ont d’abord montré que Rrd1 est associé à la chromatine ainsi qu’à l’ARN polymérase II. L’analyse in vitro et in vivo par dichroïsme circulaire a révélé que Rrd1 est responsable de changements au niveau de la structure du domaine C-terminal de la grande sous-unité de l’ARN polymérase II, Rpb1, en réponse à la rapamycine et au 4-nitroquinoline 1-oxide. Nous avons également démontré que Rrd1 est requis pour modifier l’occupation de l’ARN polymérase II sur des gènes répondant à un traitement à la rapamycine. Finalement, nous avons montré que suite à un traitement avec la rapamycine, Rrd1 médie la dégradation de l’ARN polymérase II et que ce mécanisme est indépendant de l’ubiquitine. La dernière partie de mon projet était d’acquérir une meilleure connaissance de la fonction de PTPA, l’homologue de Rrd1 chez les mammifères. Nos résultats montrent que le «knockdown» de PTPA n’affecte pas la sensibilité des cellules à différentes drogues telles que la rapamycine, le 4-nitroquinoline 1-oxide ou le peroxyde d’hydrogène (H2O2). Nous avons également tenté d’identifier des partenaires protéiques pour PTPA grâce à la méthode TAP, mais nous ne sommes pas parvenus à identifier de partenaires stables. Nous avons démontré que la surexpression de la protéine PTPA catalytiquement inactive n’induisait pas l’apoptose indiquant que l’activité de PTPA est requise pour produire cet effet. Finalement, nous avons tenté d’étudier PTPA dans un modèle de souris. Dans un premier lieu, nous avons déterminé que PTPA était exprimé surtout au niveau des tissus suivants : la moelle osseuse, le thymus et le cerveau. Nous avons également généré avec succès plusieurs souris chimères dans le but de créer une souris «knockout» pour PTPA, mais l’allèle mutante ne s’est pas transférée au niveau des cellules germinales. Mes résultats ainsi que ceux obtenus par mon laboratoire sur la levure suggèrent un rôle général pour Rrd1 au niveau de la régulation des gènes. La question demeure toujours toutefois à savoir si PTPA peut effectuer un rôle similaire chez les mammifères et une vision différente pour déterminer la fonction de cette protéine sera requise pour adresser adéquatement cette question dans le futur.In Saccharomyces cerevisiae, mutants devoid of Rrd1, a protein possessing in vitro peptidyl prolyl cis/trans isomerase activity, display striking resistance to rapamycin and show sensitivity to the DNA damaging agent 4-nitroquinoline 1-oxide. PTPA, the mammalian homolog of Rrd1, has been shown to activate protein phosphatase 2A. Our laboratory previously found that overexpression of PTPA leads to apoptosis independently of PP2A. At the outset of my thesis work, the molecular function of Rrd1/PTPA was largely unknown. My work has shown that Rrd1 is associated with the chromatin and interacts with RNA polymerase II. In vitro and in vivo analysis with circular dichroism revealed that Rrd1 mediates structural changes of the C-terminal domain of the large subunit of RNA pol II, Rpb1, in response to rapamycin and 4-nitroquinoline 1-oxide. Consistent with this, we demonstrated that Rrd1 is required to alter RNA pol II occupancy on rapamycin responsive genes. We also showed that upon rapamycin exposure Rrd1 mediates the degradation of RNA polymerase II and that this mechanism is ubiquitin-independent. Another part of my work was to gain insight into the function of PTPA, the mammalian counterpart of Rrd1. PTPA knockdown did not affect sensitivity to rapamycin, 4-nitroquinoline 1-oxide or H2O2. We also attempted to find protein interaction partners for PTPA using tandem affinity purification, but no stable partners for PTPA were found. We also demonstrated that overexpression of a catalytically inactive PTPA mutant did not induce apoptosis, indicating that PTPA activity is required to produce this effect. Finally, we attempted to study PTPA in a mouse model. We first determined that PTPA was expressed in a tissue-specific manner and was most abundant in bone marrow, thymus and brain. We pursued creation of a knockout mouse and successfully generated chimeras, but the mutated allele was not transmitted to the germline. My data and other data from our laboratory regarding the yeast work suggest a general role for Rrd1 in regulation of gene transcription. Whether PTPA has a similar function in mammalian cells remains unknown, and a different vision of what the protein does in mammalian cells will be required to adequately address this question in the future

COVID-19 symptoms at hospital admission vary with age and sex: results from the ISARIC prospective multinational observational study

Background: The ISARIC prospective multinational observational study is the largest cohort of hospitalized patients with COVID-19. We present relationships of age, sex, and nationality to presenting symptoms. Methods: International, prospective observational study of 60 109 hospitalized symptomatic patients with laboratory-confirmed COVID-19 recruited from 43 countries between 30 January and 3 August 2020. Logistic regression was performed to evaluate relationships of age and sex to published COVID-19 case definitions and the most commonly reported symptoms. Results: ‘Typical’ symptoms of fever (69%), cough (68%) and shortness of breath (66%) were the most commonly reported. 92% of patients experienced at least one of these. Prevalence of typical symptoms was greatest in 30- to 60-year-olds (respectively 80, 79, 69%; at least one 95%). They were reported less frequently in children (≤ 18 years: 69, 48, 23; 85%), older adults (≥ 70 years: 61, 62, 65; 90%), and women (66, 66, 64; 90%; vs. men 71, 70, 67; 93%, each P < 0.001). The most common atypical presentations under 60 years of age were nausea and vomiting and abdominal pain, and over 60 years was confusion. Regression models showed significant differences in symptoms with sex, age and country. Interpretation: This international collaboration has allowed us to report reliable symptom data from the largest cohort of patients admitted to hospital with COVID-19. Adults over 60 and children admitted to hospital with COVID-19 are less likely to present with typical symptoms. Nausea and vomiting are common atypical presentations under 30 years. Confusion is a frequent atypical presentation of COVID-19 in adults over 60 years. Women are less likely to experience typical symptoms than men

Rrd1 isomerizes RNA polymerase II in response to rapamycin

International audienceBACKGROUND: In Saccharomyces cerevisiae, the immunosuppressant rapamycin engenders a profound modification in the transcriptional profile leading to growth arrest. Mutants devoid of Rrd1, a protein possessing in vitro peptidyl prolyl cis/trans isomerase activity, display striking resistance to the drug, although how Rrd1 activity is linked to the biological responses has not been elucidated.RESULTS: We now provide evidence that Rrd1 is associated with the chromatin and it interacts with RNA polymerase II. Circular dichroism revealed that Rrd1 mediates structural changes onto the C-terminal domain (CTD) of the large subunit of RNA polymerase II (Rpb1) in response to rapamycin, although this appears to be independent of the overall phosphorylation status of the CTD. In vitro experiments, showed that recombinant Rrd1 directly isomerizes purified GST-CTD and that it releases RNA polymerase II from the chromatin. Consistent with this, we demonstrated that Rrd1 is required to alter RNA polymerase II occupancy on rapamycin responsive genes.CONCLUSION: We propose as a mechanism, that upon rapamycin exposure Rrd1 isomerizes Rpb1 to promote its dissociation from the chromatin in order to modulate transcription

RNA polymerase II degradation in response to rapamycin is not mediated through ubiquitylation

International audienceIn Saccharomyces cerevisiae, the immunosuppressor rapamycin engenders the degradation of excessive RNA polymerase II leading to growth arrest but the regulation of this process is not known yet. Here, we show that this mechanism is dependent on the peptidyl prolyl cis/trans isomerase Rrd1. Strikingly this degradation is independent of RNA polymerase II polyubiquitylation and does not require the elongation factor Elc1. Our data reveal that there are at least two alternative pathways to degrade RNA polymerase II that depend on different type of stresses

Humanized mice for the study of infectious diseases.

Many of the pathogens that cause human infectious diseases do not infect rodents or other mammalian species. Small animal models that allow studies of the pathogenesis of these agents and evaluation of drug efficacy are critical for identifying ways to prevent and treat human infectious diseases. Immunodeficient mice engrafted with functional human cells and tissues, termed \u27humanized\u27 mice, represent a critical pre-clinical bridge for in vivo studies of human pathogens. Recent advances in the development of humanized mice have allowed in vivo studies of multiple human infectious agents providing novel insights into their pathogenesis that was otherwise not possible. Curr Opin Immunol 2013 Aug; 25(4):428-35

PGC-1 coactivators in β-cells regulate lipid metabolism and are essential for insulin secretion coupled to fatty acids

Objectives: Peroxisome proliferator-activated receptor γ coactivator 1 (PPARGCA1, PGC-1) transcriptional coactivators control gene programs important for nutrient metabolism. Islets of type 2 diabetic subjects have reduced PGC-1α expression and this is associated with decreased insulin secretion, yet little is known about why this occurs or what role it plays in the development of diabetes. Our goal was to delineate the role and importance of PGC-1 proteins to β-cell function and energy homeostasis. Methods: We investigated how nutrient signals regulate coactivator expression in islets and the metabolic consequences of reduced PGC-1α and PGC-1β in primary and cultured β-cells. Mice with inducible β-cell specific double knockout of Pgc-1α/Pgc-1β (βPgc-1 KO) were created to determine the physiological impact of reduced Pgc1 expression on glucose homeostasis. Results: Pgc-1α and Pgc-1β expression was increased in primary mouse and human islets by acute glucose and palmitate exposure. Surprisingly, PGC-1 proteins were dispensable for the maintenance of mitochondrial mass, gene expression, and oxygen consumption in response to glucose in adult β-cells. However, islets and mice with an inducible, β-cell-specific PGC-1 knockout had decreased insulin secretion due in large part to loss of the potentiating effect of fatty acids. Consistent with an essential role for PGC-1 in lipid metabolism, β-cells with reduced PGC-1s accumulated acyl-glycerols and PGC-1s controlled expression of key enzymes in lipolysis and the glycerolipid/free fatty acid cycle. Conclusions: These data highlight the importance of PGC-1s in coupling β-cell lipid metabolism to promote efficient insulin secretion