Hepatocyte-specific deletion of TIPARP, a negative regulator of the aryl hydrocarbon receptor, is sufficient to increase sensitivity to dioxin-induced wasting syndrome

Hutin, D., Tamblyn, L., Gomez, A., Grimaldi, Giulia, Soedling, H., Cho, T., Ahmed, S., Lucas, C., Kanduri, C., Grant, D.M., Matthews, J.

04 June 2018

Yes / The aryl hydrocarbon receptor (AHR) mediates the toxic effects of dioxin (2, 3, 7, 8-tetrachlorodibenzo-p-dioxin; TCDD), which includes thymic atrophy, steatohepatitis, and a lethal wasting syndrome in laboratory rodents. Although the mechanisms of dioxin toxicity remain unknown, AHR signaling in hepatocytes is necessary for dioxin-induced liver toxicity. We previously reported that loss of TCDD-inducible poly(adenosine diphosphate [ADP]-ribose) polymerase (TIPARP/PARP7/ARTD14), an AHR target gene and mono-ADP-ribosyltransferase, increases the sensitivity of mice to dioxin-induced toxicities. To test the hypothesis that TIPARP is a negative regulator of AHR signaling in hepatocytes, we generated Tiparpfl/fl mice in which exon 3 of Tiparp is flanked by loxP sites, followed by Cre-lox technology to create hepatocyte-specific (Tiparpfl/flCreAlb) and whole-body (Tiparpfl/flCreCMV; TiparpEx3−/−) Tiparp null mice. Tiparpfl/flCreAlb and TiparpEx3−/− mice given a single injection of 10 μg/kg dioxin did not survive beyond days 7 and 9, respectively, while all Tiparp+/+ mice survived the 30-day treatment. Dioxin-exposed Tiparpfl/flCreAlb and TiparpEx3−/− mice had increased steatohepatitis and hepatotoxicity as indicated by greater staining of neutral lipids and serum alanine aminotransferase activity than similarly treated wild-type mice. Tiparpfl/flCreAlb and TiparpEx3−/− mice exhibited augmented AHR signaling, denoted by increased dioxin-induced gene expression. Metabolomic studies revealed alterations in lipid and amino acid metabolism in liver extracts from Tiparpfl/flCreAlb mice compared with wild-type mice. Taken together, these data illustrate that TIPARP is an important negative regulator of AHR activity, and that its specific loss in hepatocytes is sufficient to increase sensitivity to dioxin-induced steatohepatitis and lethality. / This work was supported by Canadian Institutes of Health Research (CIHR) operating grants (MOP-494265 and MOP-125919), CIHR New Investigator Award, an Early Researcher Award from the Ontario Ministry of Innovation (ER10-07-028), an unrestricted research grant from the DOW Chemical Company, the Johan Throne Holst Foundation, Novo Nordic Foundation and the Norwegian Cancer Society to J.M.

Aryl hydrocarbon receptor

Wasting syndrome

ADP-ribosylation

2

3

7

8-tetrachlorodibenzo-p-dioxin

Exoenzyme S of Pseudomonas aeruginosa : cellular targets and interaction with 14-3-3 /

Yasmin, Lubna,

January 2007

Diss. (sammanfattning) Umeå : Univ., 2007. / Härtill 4 uppsatser.

Role of SIRT6 in Myofibroblast Cell Death

Subramanian, Veena

January 2016

Cardiovascular diseases are one of the leading causes of mortality. A common denominator across most of the cardiovascular diseases like diabetic cardiomyopathy, hypertrophic cardiomyopathy, myocardial infarction and dilated cardiomyopathy is the pathological remodelling of heart leading to fibrosis. Cardiac fibrosis is characterized by the excessive production and deposition of extracellular matrix components due to unwarranted proliferation of fibroblasts. Under normal conditions, following cardiac remodelling, my fibroblasts undergo programmed cell death. However, this does not happen under pathological conditions ultimately leading to fibrosis. Although the molecular events and signalling pathways that contribute to the development of cardiac fibrosis is well established, there are limited studies which try to understand the mechanisms by which fibroblasts persist and resist programmed cell death. Here we demonstrate that SIRT6, one of the members of sirtuin family of histone deacetylases, plays an important role in regulating my fibroblast cell death. When we analysed the mice hearts and isolated fibroblasts deficient in SIRT6, we observed increased expression of my fibroblast markers, suggesting that SIRT6 deficient hearts might have a high proportion of resident my fibroblasts. Also, when SIRT6 deficient fibroblasts were subjected to genotoxic stress, they showed reduced cell death and impaired mitochondrial to nuclear AIF translocation as compared to WT controls. An important regulator of AIF mediated cell death is the protein PARP-1. When we checked the expression levels of this protein under SIRT6 deficient conditions, it was found to be low. PARP-1 was also found to degrade faster under SIRT6 deficient conditions. Further qPCR analysis revealed that the transcript levels of PARP-1 were unaffected by SIRT6 suggesting that the regulation might not be at the transcriptional level. When we studied the acetylation of PARP-1 under SIRT6 deficient conditions we found the protein to be hypo-acetylated indicating a more complex mechanism of regulation.

Cardial Fibrosis

Sirtuins

SIRT6

Myofibroblast Cell Death

Histone Deacetylases

Poly(ADP-Ribose)Polymerase 1-PARP 1

Fibroblasts

Fibrosis

Microbiology and Cell Biology

Tumor necrosis factor-induced necroptosis is regulated by nicotinamide adenine dinucleotide in a sirtuin-dependent manner

Preyat, Nicolas

28 June 2013

Nicotinamide adenine dinucleotide (NAD+) represents a long-known key molecule in cellular metabolism. It was initially identified for its ability to convey electrons and protons between redox partners in multiple bioenergetic and biosynthetic reactions. In addition, NAD+ also serves as a substrate for NAD+-consuming enzymes such as sirtuins and poly ADP-ribose polymerases (PARPs). These latter enzymes catalyze dynamic post-translational modifications that control virtually every signaling pathway orchestrating cell fate. The aim of this work was to analyze the role of NAD+ in the context of programmed cell death mechanisms.<p>Our findings indicate that NAD+ is protective against DNA damage-induced cell death and FAS-induced apoptosis, while, unexpectedly, it promotes TNF-induced necroptosis, a regulated form of necrosis. Indeed raising NAD+ cellular levels sensitized culture cells to necroptosis, while NAD+ depletion protected cells from this form of cell death. Furthermore, specific silencing of NAD+-dependent sirtuins was also found to be protective against TNF-induced necroptosis. Consistently, a pharmacological pan-sirtuin inhibitor called cambinol protected cells from necroptosis. Then, as necroptosis represents a back-up mechanism that may have evolved in response to viral pathogens expressing anti-apoptotic proteins, we demonstrated in an in vitro model mimicking viral infection that pharmacological sirtuin inhibition protected cells from poly I:C-induced necroptotic cell death. In vivo, we demonstrated that cambinol partially protected kidney from necrosis after ischemia/reperfusion. We have also shown that enhancing liver NAD+ concentration via isonicotinamide increases the susceptibility of mice to systemic inflammatory response syndrome (SIRS). Moreover, our preliminary data show that isonicotinamide substantially improves the ability of cyclophosphamide to trigger the rejection of the murine mastocytoma P815 tumor cell line.<p>Collectively, our observations point to a role for NAD+ in the control of necroptosis in a sirtuin-dependent manner. These observations may bear relevance to the better understanding of the pathophysiological consequences of excessive production of the pro-inflammatory cytokine TNF and the control of viral infections and tumor progression/immunotherapy. & / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Biologie

Sciences exactes et naturelles

NAD (Coenzyme)

NAD-ADP-ribosyltransferase

Apoptosis

NAD (Coenzyme)

Poly (ADP-ribose) polymérase

Apoptose

Sirtuin

NAD

NAMPT

necroptosis

apoptosis

immunity

PARP12, a novel interferon stimulated gene potentially involved in the control of protein translation and innate immunity

Welsby, Iain

16 April 2012

Poly(ADP-ribose) polymerases belong to a family of proteins with 17 members in human beings. PARP1, the founding member of the family is a protein that synthesizes linear or branched polymers of ADP-ribose on itself or on target proteins. Different members of this family, that do not all possess ADP-ribosyl polymerase activity, are involved in the regulation of various cellular mechanisms. Some members of the family are particularly involved in the positive or negative control of the immune response. PARP1 is a key player in the regulation of inflammation, through its positive control of cell death and of proinflammatory cytokine production. On the other hand, the tankyrases (PARP5a and PARP5b) and PARP14 seem to regulate inflammatory responses in a negative fashion. PARP12 is a poorly characterized member of the family, whose expression is greatly increase following stimulation with type-I interferons, cytokines mainly involved in antiviral defences.<p>PARP12 is a protein that possesses three main domains: A putative RNA binding N-terminal domain composed of tandem CCCH zinc-fingers, a central WWE domain and a C-terminal PARP catalytic domain. In this work, we have shown that the expression of PARP12 is strictly-dependent on type-I interferons, that it possesses ADP-ribosyl transferase activity and that in can regulate the translation of messenger RNA into proteins. PARP12 can be found in stress granules, sites of storage of untranslated mRNAs, and is capable of directly inhibiting the translation of a reporter mRNA when tethered to it, in a manner dependent on its catalytic activity. Furthermore overexpression of wild-type PARP12, in contrast to overexpression of a mutant with no detectable catalytic activity (PARP12-G575W), leads to a general arrest of most cellular translation.<p>On the other hand, we have shown that PARP12 can activate the transcription of genes under the control of an NFκB-dependent promoter, especially when its zinc-fingers are deleted or mutated (PARP12ΔZnF). PARP12ΔZnF is located in structures that can enclose TRIF, RIP1, NEMO, p62/SQSTM1 and ubiquitin. These proteins have all possess an important role in the activation of NFκB signalling cascades. Moreover, we have shown that endogenous PARP12 is situated in ALIS (Aggresome-Like Induced Structures) in LPS-stimulated macrophages. These structures have a possible role in the presentation of antigens on class I major histocompatibility complexes, implying that PARP12 may be involved in the regulation of antigen presentation. <p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Biologie

NAD-ADP-ribosyltransferase

Immune response -- Regulation

Poly (ADP-ribose) polymérase

Réaction immunitaire -- Régulation

stress granules

peptide presentation

Immune regulation

translation regulation

Regulation of IgA Class Switch Recombination in the I.29μ B Cell Lymphoma by Cytokines and Inhibitors of Poly(ADP-ribose) Polymerase: A Thesis

Shockett, Penny E.

01 September 1993

Heavy chain isotype switch recombination is preceded by the appearance of RNA initiating 5' of the specific switch region which will undergo recombination. In an effort to understand the potential function of germline transcripts in switch recombination and the degree to which the regulation of germline transcripts correlates with the regulation of switching, we studied this process in the murine B-lymphoma cell line I.29μ, which in the presence of bacterial lipopolysaccharide (LPS) switches primarily to IgA and less frequently to IgE. Levels of α-germline transcripts initiating upstream of α switch (Sα) sequences are elevated in clones of this line which switch well as compared to clones which switch less frequently. TGFβ1 has been shown to increase α-germline transcripts and switching to IgA expression in LPS-stimulated murine splenic B-cells. We now demonstrate in I.29μ cells that TGFβ also increases switching to IgA and increases the level of α-germline transcripts 5 to 9 fold. Nuclear run-on analysis shows that this increase is at the level of transcription. Thus, TGFβ appears to direct switching to IgA by inducing transcription from the unrearranged Sα- CαDNA segment. Germline α RNA is quite stable in I.29μ cells, having a half life of about 3 to 5 hours, and we find only slight stabilization in the presence of TGFβ. Levels of ε-germline transcripts are not increased by TGFβ . IL-4, which modestly increases switching to IgA in I.29μ cells, slightly increases trancription of α-germline RNA. However, we present evidence suggesting that endogenously produced IL-4 may also act at additional levels to increase switching to IgA. IFNγ, which reduces IgA expression in these cells, also reduces the level of α-germline transcripts. IFNγ also reduces the level of ε-germline transcripts induced by IL-4. Our results support the hypothesis that the regulation of transcription of particular switch sequences by cytokines in turn regulates the specificity of recombination. In studies aimed at identifying other signalling pathways that promote class switching, we discovered that inhibitors of the nuclear enzyme poly(ADP-ribose) polymerase (PARP) increase lipopolysaccharide (LPS)-induced switching to IgA in the B cell lymphoma I.29μ and to IgG1 in LPS + IL-4-treated splenic B cells. PARP, which binds to and is activated by DNA strand breaks, catalyzes the removal of ADP-ribose from NAD+ and poly(ADP-ribosylation) of chromatin-associated acceptor proteins. This enzyme is believed to function in cellular processes involving DNA strand breaks as well as in modulating chromatin structure. In I.29μ cells, PARP inhibitors increase IgA switching by day 2 and cause a 5-fold average increase in switching on day 3 as assayed by immunofluorescence microscopy. The PARP inhibitor, nicotinamide, also causes a reduced intensity of hybridization of Cμ and Cα specific probes to genomic DNA fragments containing the expressed VDJ-Cμ and the unrearranged Sα - Cα segments, respectively, indicating that PARP inhibition increases rearrangment of these fragments. Induction of switching by PARP inhibitors is not mimicked by treatment with cAMP analogs or reduced by inhibitors of protein kinase A (PKA). Induction of switching by PARP inhibitors does not appear to involve increased levels of transcription of the unrearranged Cα gene, although TGFβ is required for optimal induction by PARP inhibitors, consistent with a requirement for transcription of the unrearranged CH gene. PARP inhibitors do not overcome the requirement for endogenously produced IL-4.

Immunoglobulin A

Immunoglobulin Switch Region

Lymphoma

B-Cell

ADP Ribose Transferases

Amino Acids, Peptides, and Proteins

Carbohydrates

Cells

Enzymes and Coenzymes

Genetic Phenomena

Hemic and Lymphatic Diseases

Immune System Diseases

Neoplasms

Allosteric communication within cancer therapeutic target PARP1 : mechanism of catalytic activation and modulation of allostery by inhibitors

Rouleau-Turcotte, Elise

08 1900

L’ADN contient l’information génétique essentielle au développement et au bon fonctionnement de tout organisme vivant. Cependant, l’ADN peut être endommagé ou modifié par une exposition régulière à différents facteurs tels que la lumière du soleil, la pollution, la radiation, etc. La cellule a ainsi développé des mécanismes de réparation très efficaces puisqu’un ADN sain est essentiel pour la santé d’un organisme. La protéine humaine PARP1 est une enzyme clé de la réparation de l’ADN. PARP1 détecte rapidement les dommages à l’ADN en s’y liant, ce qui stimule son activité catalytique. PARP1 catalyse la formation de chaînes d’ADP-ribose qui sont ajoutées à PARP1, ainsi que d’autres protéines, en tant que modification post-traductionnelle. Les chaînes d’ADP- ribose permettent la décondensation de la chromatine ainsi que le recrutement de facteurs de réparation à l’ADN endommagé. PARP1 possède plusieurs domaines régulateurs en plus de son domaine catalytique, le domaine catalytique lui-même se divisant en un domaine hélicoïdal (HD) ainsi qu’un domaine ADP- ribosyltransférase. L’augmentation de l’activité catalytique de PARP1, à la suite de sa liaison à l’ADN endommagé, implique qu’un signal allostérique se transmette à travers ses différents domaines. Le HD joue un rôle essentiel dans le relais de cette communication allostérique puisque c’est ultimement un changement de conformation du HD (i.e « ouverture ») qui révèle le site actif et active l’enzyme. De plus, il a été démontré que les inhibiteurs de PARP1 peuvent moduler l’affinité de l’enzyme pour l’ADN endommagé. Certains inhibiteurs peuvent ainsi provoquer la « capture » de l’ADN par PARP1, un phénomène qui requiert la présence du HD et qui est particulièrement toxique pour les cellules cancéreuses présentant des défauts de réparation de l’ADN. Pour cette raison, la mort cellulaire induite par les inhibiteurs de PARP1 est un traitement prometteur et quatre inhibiteurs sont déjà utilisés pour traiter le cancer des ovaires et du sein. Cependant, le mécanisme précis derrière la capture de l’ADN par PARP1 est encore nébuleux et nécessite de plus amples recherches. Puisque la capture de l’ADN par PARP1 requiert le relais d’un signal allostérique par le HD, et que l’ouverture du HD participe à cette communication, il est donc essentiel de comprendre les changements de conformations effectués par ce domaine. Nous avons ainsi obtenu pour la première fois une structure atomique de PARP1 en conformation active. Celle-ci montre que l’ouverture du HD amène la formation d’une interface additionnelle entre ce domaine et les autres domaines régulateurs de PARP1. Ainsi, entraver la formation de cette nouvelle interaction, par des mutations ponctuelles, diminue grandement l’activité catalytique de PARP1 lié à l’ADN, ce qui suggère que l’interface participe à la communication allostérique de l’enzyme. Tel que mentionné plus haut, les inhibiteurs de PARP1 peuvent moduler de manières différentes l’affinité de PARP1 pour les dommages à l’ADN et ainsi influencer distinctement la communication allostérique de l’enzyme. Nous avons caractérisé une nouvelle série d’inhibiteurs de PARP1 et évalué leur capacité à moduler l’affinité de PARP1 pour l’ADN endommagé. Nos travaux démontrent qu’un inhibiteur volumineux occupant le site actif n’augmentera pas nécessairement l’affinité de PARP1 pour les dommages à l’ADN. Leur capacité à favoriser la capture de l’ADN dépend plutôt de leur interaction avec la région du HD voisine au site actif. En résumé, nos travaux participent à l’amélioration des connaissances concernant l’activation catalytique de PARP1 et la communication allostérique. Une meilleure compréhension de l’allostérie de PARP1 permettra la conception de médicaments ayant la toxicité désirée pour tuer les cellules cancéreuses. / DNA contains the genetic instructions for the development and proper function of all living organisms. However, DNA can be broken and modified in harmful ways through daily exposures to exterior stresses such as sun light, pollution, radiation, etc. Since stable and undamaged DNA is essential for the health of an organism, cells have developed repair mechanisms to ensure that DNA damage is taken care of efficiently. The human protein PARP1 is a key enzyme that contributes to DNA repair. PARP1 rapidly detects DNA lesions which greatly stimulates its catalytic activity. PARP1 catalyzes the formation of chains of ADP-ribose that are attached covalently to PARP1 itself, or other target proteins, as a posttranslational modification. The chains of ADP-ribose allow for the recruitment of chromatin remodelling factors and repair factors to process the DNA lesions. PARP1 carries multiple regulatory domains in addition to its catalytic domain, with the catalytic domain itself composed of the helical domain (HD) and the ADP-ribosyltransferase fold. DNA damage binding greatly stimulates PARP1 catalytic activity, which requires that an allosteric signal is relayed across the enzyme’s domains. Interestingly, the HD has been found to play an essential role in the PARP1 allostery. The HD undergoes a change of conformation (i.e. opening) following PARP1 DNA damage binding which reveals the active site. Additionally, inhibitors binding the active site of the enzyme can modulate PARP1 DNA binding affinity. Some inhibitors can induce PARP1 DNA “trapping”, a phenomenon that requires the HD and appears particularly toxic to cancer cells bearing DNA repair deficiencies. Cell death induced by PARP1 inhibitors is a promising cancer treatment and four inhibitors have approval for clinical use against ovarian and breast cancers. However, the precise mechanism underlying PARP1 trapping on DNA is still unclear and requires further research. Since PARP1 trapping requires the presence of the HD, and that the HD opening is involved in relaying the allosteric signal, it remains essential to characterize its change of conformation. We have obtained for the first time atomic structures of PARP1 in a catalytically active state. Crystal structures show that the HD in open conformation forms an additional interdomain interface. Mutating this interface prevents PARP1 strong catalytic activation following DNA damage binding, suggesting that the allosteric communication is impaired. Additionally, these structures reveal how the HD active conformation leads to the reveal of the active site in the ART domain. As mentioned above, PARP1 inhibitors can modulate the enzyme’s DNA binding affinity and therefore impact its allosteric communication. We have characterized a series of novel inhibitors and tested their propensity to increase PARP1 DNA binding affinity. Our work highlights that bulky inhibitors that fill the active site will not necessarily promote PARP1 affinity for DNA lesions. Rather, it appears that inhibitors may trigger DNA trapping via their interaction with a neighboring region of the HD. Overall, our work deepens our understanding of PARP1 catalytic activation and allosteric communication. Properly understanding how PARP1 trapping occurs will help the design of specific drugs with the desired toxicity to kill cancer cells.

ADP-ribosyltransferase

DNA damage repair

Poly(ADP-ribose)

Structural biology

Cancer

PARP enzymes

ADP-ribosyltransférase

Enzyme PARP

Réparation de l'ADN

Biologie structurale

Biochemistry / Biochimie (UMI : 0487)

INVOLVEMENT OF SINGLE- AND DOUBLE-STRAND BREAK REPAIR PROCESSES IN BETA-LAPACHONE-INDUCED CELL DEATH

Bentle, Melissa Srougi

06 June 2007

No description available.

Poly(ADP-ribose) polymerase-1

DNA repair

Calcium

Non-homologous end-joining

Beta-Lapachone

Non-caspase-mediated cell death

ATP and NAD+ depletion

DNA damage

Rôle de la poly(ADP-ribose)polymérase dans les transformations hémorragiques induites par le rt-PA après une ischémie cérébrale / Role of poly (ADP-ribose) polymerase in hemorrhagic transformations induced by rt-PA after cerebral ischemia

El Amki, Mohamad

16 April 2013

Les accidents vasculaires cérébraux (AVC) constituent un problème majeur de santé publique, puisqu’ils représentent la 3ème cause de mortalité dans les pays industrialisés. À l’heure actuelle, l’activateur tissulaire du plasminogène recombinant (rt-PA) est le seul traitement pharmacologique à la phase aiguë des AVC ischémiques. Il s’agit d’un thrombolytique dont l’utilisation reste très limitée (<2% des patients). En effet, quand le rt-PA est administré au-delà de 4h30, aucune récupération fonctionnelle n’est observée chez le patient. De plus, les données cliniques et expérimentales ont montré que l’administration du rt-PA augmente fortement la survenue de transformations hémorragiques. Il apparaît donc indispensable de développer des stratégies permettant, d’une part, de s’opposer à ces transformations hémorragiques, et d’autre part, d’augmenter la fenêtre thérapeutique du rt-PA. Au vu de ces données, mon travail a consisté à préciser l’intérêt thérapeutique d’inhiber une enzyme, la poly(ADP-ribose)polymérase (PARP) pour s’opposer aux effets délétères du rt-PA au niveau vasculaire. Ces études ont été menées sur un modèle d’ischémie cérébrale thromboembolique réalisé chez la souris, consistant en une injection de thrombine dans l’artère cérébrale moyenne. Dans un 1er temps, nous avons caractérisé ce modèle, récemment décrit dans la littérature (2007) et nouveau dans notre laboratoire. Nos travaux ont montré pour la première fois que, dans ce modèle, le rt-PA à la dose de 0,9 mg/kg (dose utilisée chez l’homme) reproduit fidèlement les « 2 visages » du thrombolytique en clinique : la thrombolyse précoce (30 min après l’ischémie) est associée à des effets bénéfiques, en réduisant le déficit neurologique, le volume de la lésion et l’œdème cérébral, alors que l’administration tardive de rt-PA (4h après l’ischémie) entraîne une aggravation des transformations hémorragiques et une perte de l’amélioration fonctionnelle. Dans un 2ème temps, nous avons étudié l’implication de la PARP dans les transformations hémorragiques induites par l’administration tardive de rt-PA. Le traitement par le PJ34(1 et 3 mg/kg), un puissant inhibiteur de cette enzyme, réduit la dégradation des protéines de jonction de la barrière hémato-encéphalique et les transformations hémorragiques induites par le rt-PA. De plus, le PJ34 s’oppose non seulement à la toxicité vasculaire du rt-PA, mais réduit également le déficit neurologique, le volume de la lésion et l’œdème cérébral. En conclusion, l’ensemble de ce travail montre que l’inhibition de la PARP prolonge la fenêtre thérapeutique du rt-PA et permet une thrombolyse « sécurisée ». Cette stratégie pourrait être mise en place de manière précoce après l’ischémie (avant même l’arrivée du patient à l’hôpital) et augmenter le nombre de patients pouvant bénéficier d’une thrombolyse. / Stroke is the third leading cause of death worldwide and a major cause of disability. Tissue plasminogen activator (rt-PA) is the only approved treatment in the United States and Europe for acute ischemic stroke. Clinical data show that beyond its therapeutic time window (4.5 hours after stroke onset), rt-PA exerts no more neuroprotective effects. Furthermore, clinical data showed that rt-PA increases the hemorrhagic transformations. Therefore, there is a critical need to develop a novel drug that can reduce rt-PA’s deleterious effects and extend its therapeutic window. The aim of the present study was to examine whether Poly(ADP-ribose)polymerase (PARP) mediates the hemorrhagic transformations induced by rt-PA administration. We used a mouse model of thromboembolic stroke, which consists of a microinjection of thrombin in the middle cerebral artery. First, we showed that in the mouse thrombin stroke model, the "human" dose of rt-PA exhibits effects close to those observed in clinic. Later, we showed PARP is implicated in the vascular toxicity of rt-PA after cerebral ischemia. PJ34, a PARP inhibitor, preserves the blood brain barrier integrity, reduces rt-PA-induced hemorrhagic transformations, improves neurological outcomes and reduces brain infarction and edema. In conclusion, this work showed that PARP inhibitors could be relevant candidates to extend the therapeutic time window of rt-PA after stroke without increasing the risk of hemorrhagic transformations.

Souris

Ischémie cérébrale

Thrombine

Rt-PA

Transformations hémorragiques

Poly(ADP-ribose)polymérase

Barrière hémato-encéphalique

PJ34

Lésion cérébrale

Déficit neurologique

Mouse

Ischemic stroke

Thrombin

Rt-PA

Hemorrhagic transformations

Poly(ADP-ribose)polymerase

Blood-brain barrier

PJ34

Brain Injury

Neurological deficit

616.81061

L’activation de la sirtuin 1 : une nouvelle stratégie neuroprotectrice pour le stress oxydant cérébral in vivo ? Implication dans les effets bénéfiques de l’inhibition de la poly(ADP-ribose)polymérase par le 3-aminobenzamide / Sirtuin 1 activation : a neuroprotective strategy for in vivo cerebral oxidative stress ? Involvement of SIRT1 in the beneficial effects of poly(ADP-ribose)polymerase inhibition

Gueguen, Cindy

07 June 2013

Le stress oxydant (SO) est un mécanisme commun à l’ischémie cérébrale et au traumatisme crânien qui entraîne notamment l’hyperactivation délétère de la poly(ADP-ribose)polymérase (PARP), une enzyme NAD+-dépendante. Cette dernière est impliquée dans le déficit neurologique et la lésion cérébrale consécutifs à ces pathologies. In vitro, l’hyperactivation de la PARP diminue le taux cérébral de NAD+, son substrat, et l’activité de la sirtuin 1 (SIRT1), une enzyme également NAD+-dépendante. L’activation de la SIRT1 est bénéfique au cours d’un SO in vitro. Si les effets bénéfiques de l’inhibition de la PARP ont été démontrés in vivo au cours d’un SO cérébral, l’implication de la SIRT1 ainsi que son rôle dans les effets de l’inhibition de la PARP n’ont pas été explorés. Dans la première partie de ce travail, nous avons mis en évidence qu’un modèle de SO cérébral induit in vivo chez le rat par une injection intrastriatale de malonate entraîne un SO prolongé, un déficit neurologique et une activation de la PARP associée à une diminution du NAD+. Dans la deuxième partie de ce travail, nous avons montré que le 3-aminobenzamide (3AB), un inhibiteur de la PARP, ne permet pas de s’opposer à la chute du NAD+ dans ce modèle, ce qui suggère que le NAD+ pourrait être consommé par d’autres enzymes NAD+-dépendantes, dont la SIRT1. L’inhibition de la PARP par le 3AB a permis d’augmenter le rapport activité/expression nucléaire de la SIRT1 et a entraîné sa translocation cytoplasmique au cours du SO. Un prétraitement par le SRT1720, un activateur spécifique de la SIRT1, diminue le déficit neurologique et la lésion striatale 6 heures après le SO cérébral, ce qui suggère que l’activation de la SIRT1 est bénéfique dans les conséquences d’un SO cérébral in vivo. L’association de l’inhibiteur de la PARP avec l’activateur de la SIRT1 (3AB+SRT1720) n’a pas potentialisé les effets protecteurs de chaque monothérapie. L’EX527, un inhibiteur de la SIRT1, ne modifie pas le déficit et la lésion. En revanche, l’association de l’inhibiteur de la PARP avec l’inhibiteur de la SIRT1 (3AB+EX527) supprime la récupération neurologique ainsi que la réduction de la lésion, induites par l’inhibition de la PARP seule (3AB). Ces données suggèrent que l’activation de la SIRT1 est impliquée dans les effets bénéfiques de l’inhibition de la PARP in vivo au cours d’un SO cérébral. En conclusion, l’ensemble de ce travail a permis une meilleure caractérisation de la PARP et de la SIRT1 au cours d’un SO cérébral in vivo. La SIRT1 pourrait constituer une cible pharmacologique pour le traitement des pathologies cérébrales au cours desquelles un SO est présent. De plus, nous avons montré que les effets bénéfiques de l’inhibition de la PARP sur les conséquences fonctionnelles et histologiques induites par le SO cérébral sont liés à l’activation de la SIRT1. / Oxidative stress (OS) is involved in cerebral ischemia and traumatic brain injury and results in deleterious activation of poly(ADP-ribose)polymerase (PARP), an NAD+-dependant enzyme. PARP is implicated in neurological deficit and brain injury post-ischemia and post-trauma. In vitro, PARP overactivation reduced both brain NAD+ levels, its substrate, and activity of sirtuin 1 (SIRT1), an other NAD+-dependant enzyme. SIRT1 activation is beneficial during in vitro OS. Even if the beneficial effects of PARP inhibition have been demonstrated, SIRT1 involvement during in vivo cerebral OS and its role in the beneficial effects of PARP inhibition have not been studied.In the first part, we demonstrated that in vivo cerebral OS induced by intrastriatal injection of malonate in rat promoted prolonged OS, neurological deficit, PARP activation and NAD+ decrease. In the second part, we showed that 3-aminobenzamide (3AB), a PARP inhibitor, did not reduce NAD+ loss, suggesting that NAD+ could be consumed by other NAD+-dependant enzymes, including SIRT1. The PARP inhibitor increased the nuclear SIRT1 activity/expression ratio and induced its cytoplasmic translocation during OS. SRT1720, a specific SIRT1 activator, reduced both neurological deficit and striatal lesion 6 hours after cerebral OS, suggesting that SIRT1 activation is beneficial on in vivo OS consequences. The combination of the PARP inhibitor with the SIRT1 activator (3AB + SRT1720) did not potentiate the neuroprotective effects of each strategy. EX527, a SIRT1 inhibitor, did not affect OS-induced deficit and lesion. However, association of the PARP inhibitor with the SIRT1 inhibitor (3AB + EX527) suppressed the neurological recovery and the reduction of lesion induced by 3AB alone. Our data suggested that SIRT1 activation is involved in the neuroprotective effects of PARP inhibition during in vivo cerebral OS. In conclusion, our work led to a better characterization of PARP and SIRT1 during in vivo cerebral OS. SIRT1 is a potential pharmacological target for the treatment of brain pathologies in which OS is present. In addition, SIRT1 activation is involved in the beneficial effects of PARP inhibition on functional and histological cerebral OS consequences

Stress oxydant cérébral

Sirtuin 1 (SIRT1)

Poly(ADP-ribose)polymérase (PARP)

3-aminobenzamide (3AB)

SRT1720

EX527

NAD+

Déficit neurologique

Lésion cérébrale

Cerebral oxidative stress

Sirtuin 1 (SIRT1)

Poly(ADP-ribose)polymerase (PARP)

3-aminobenzamide (3AB)

SRT1720

EX527

NAD+

Neurological deficit

Brain lesion

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