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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
41

Glial glucocorticoid geceptors in parkinsonism / Récepteurs des glucocorticoïdes gliaux dans le parkinsonisme

Maatouk, Layal 09 October 2015 (has links)
L'inflammation chronique relayée par la glie activée contribue à la dégénérescence des neurones dopaminergiques (ND) au cours de la maladie de Parkinson (MP). L'étendue des dégâts cellulaires provoqués par la réaction inflammatoire dépend de l'efficacité des mécanismes régulateurs de l'inflammation. Les glucocorticoïdes endogènes sont des régulateurs puissants de l'inflammation agissant via le récepteur des glucocorticoïdes (GR). Notre équipe a récemment montré le rôle central du GR microglial dans la régulation de la mort neuronale dont la sévérité est corrélée à l'intensité et la durée de l'inflammation. Mon projet de thèse a été d'étudier le rôle des GR microglial et astrocytaire dans la régulation des réponses inflammatoires au cours de la dégénerescence des ND. Dans la première partie de ma thèse, nous avons effectué une analyse transcriptomique comparative de microglie ex vivo isolée de souris traitées au MPTP (modèle de parkinsonisme) et avons identifié des gènes régulés par le GR microglial, potentiellement impliqués dans l'inflammation chronique. Dans la deuxième partie de ma thèse, nous avons mis en évidence la régulation par le GR microglial de la mort neuronale induite par l'activation de TLR9. L'ADN mitochondrial endogène peut engendrer la mort neuronale en activant le TLR9, en cas de dysfonction du GR microglial. Dans la troisième partie de mon travail, nous avons démontré que le GR astrocytaire régule la survie des ND en modulant l'expression de gènes pro-inflammatoires et l'activité excessive des hémicanaux à connexine 43. Globalement, les GR microglial et astroglial jouent des rôles essentiels dans la régulation de l'inflammation aigue et chronique. / Chronic inflammation, mounted by activated glia, contributes to dopamine neuron (DN) loss, a major hallmark of Parkinson’s disease. It can be postulated that the extent of DN injury inflicted by inflammation is affected by the efficacy of regulatory mechanisms. The activation of hypothalamic–pituitary–adrenal axis results in release of glucocorticoids, which activate glucocorticoid receptor (GR). GR exerts adaptive responses including resolution of inflammation to restore the homeostatic state. We previously demonstrated the role of microglial GR in regulating the intensity and duration of inflammation, which influences DN survival. My thesis was centered on dissecting the roles of microglial and astrocytic GR during DN degeneration in experimental Parkinsonism. In the first part of my thesis, we conducted comparative transcriptome experiments of ex vivo microglia acutely isolated from mice treated with MPTP (model of parkinsonism) and identified genes and pathways in microglia regulated by GR, potentially involved in chronic inflammation in PD. In the second part of my thesis, we found that microglial GR regulates Toll-Like Receptor 9-induced DN loss by regulating the lysosomal compartment and demonstrated that diminished sensitivity of GR in microglia creates a permissive environment for TLR9 activation by endogenous mitochondrial DNA to become lethal for DNs. In the third part of my work, we showed that during DN degeneration, astrocytic GR regulates inflammatory gene expression and prevents connexin-43 hemichannel activity that contributes to DN loss. Overall, both microglial and astrocytic GR play essential roles in regulating chronic and acute inflammation.
42

Interaction of Xenobiotics with the Glucocorticoid Hormone System <i>in vitro</i>

Johansson, Maria January 2002 (has links)
<p>Persistent environmental pollutants were examined for their interaction with the glucocorticoid hormone system. The focus was placed on interference with the glucocorticoid synthesis and the glucocorticoid-signalling pathway in various <i>in vitro</i> test systems.</p><p>Several aryl methyl sulphones competitively inhibited CYP11B1 activity in mouse adrenocortical Y1 cells. The DDT metabolite, 3-methylsulphonyl-2,2’-bis(4-chlorophenyl)-1,1’-dichloroethene (3-MeSO<sub>2</sub>-DDE) had a higher affinity to the enzyme than the endogenous substrate, 11-deoxycorticosterone. In fact, 3-MeSO<sub>2</sub>-DDE (K<sub>i</sub> 1.6 μM) was almost as potent as the drug metyrapone (K<sub>i</sub> 0.8 μM), a well-known inhibitor of the enzyme. 3-MeSO<sub>2</sub>-DDE inhibited CYP11B1 activity in human adrenocortical H295R carcinoma cells, and at higher concentrations the CYP21 activity. The human H295R cell line seems to be a useful test system for studies of enzyme activities and could be used to screen endocrine disrupting chemicals interfering with the glucocorticoid hormone synthesis.</p><p>Several chiral PCB methyl sulphones and the fungicide tolylfluanid proved to be antagonists to the glucocorticoid receptor (GR) in rat hepatoma cells and/or Chinese hamster ovary cells stable transformed with a human GR and a responsive reporter vector. The 4-methylsulphonyl-2,3,6,2’,4’,5’-hexachlorobiphenyl (4-MeSO<sub>2</sub>-CB149) enantiomers had similar antagonistic effect on the GR. Co-exposure of substances led to additive inhibitory effects on glucocorticoid-regulated protein synthesis in rat hepatoma cells. In general, 4-substituted but not 3-substituted methylsulphonyl-PCBs interacted with the glucocorticoid hormone system.</p><p>In the environment, humans and wildlife are constantly exposed to a wide range of chemicals. Considering the effects of these substances via mechanisms of actions described in this thesis, interference of xenobiotics with the glucocorticoid hormone system deserves further attention. In conclusion, environmental pollutants can interact with the glucocorticoid hormone system <i>in vitro</i>, yet the effects of the tested substances on this hormone system remain to be established <i>in vivo.</i></p>
43

Hormonal Regulation of the Human CYP27A1 and CYP7B1 Genes

Tang, Wanjin January 2007 (has links)
<p>CYP27A1 and CYP7B1 are widely expressed in various human tissues and are two key enzymes involved in the pathways for conversion of cholesterol to bile acids. Also, CYP27A1 is involved in bioactivation of vitamin D3 and CYP7B1 plays a role in 7alpha-hydroxylation of dehydroepiandrosterone and other steroids. Both enzymes have been reported to be relevant to prostate cell proliferation. The current study examines the hormonal regulation of CYP27A1 and CYP7B1.</p><p>CYP7B1 was shown to be regulated by estrogens and androgens in human embryonic kidney HEK293 and prostate cancer LNCaP cells. Quantitation of CYP7B1 mRNA in adult and fetal human tissues showed markedly higher CYP7B1 mRNA levels in fetal tissues compared with the corresponding adult ones, except in the liver. This indicates a tissue-specific, developmental regulation of CYP7B1 and suggests an important function for this enzyme in fetal life. CYP7B1 regulation by estrogens may be of importance in fetal development and in other processes where CYP7B1 is involved, including cholesterol homeostasis, cellular proliferation, and CNS function. The regulation of CYP7B1 by sex hormones also suggests an important role for CYP7B1 in balancing prostate hormone levels in human cells. </p><p>Results show that CYP27A1 can be regulated by dexamethasone, growth hormone, IGF-1, PMA, estrogens and androgens in liver-derived HepG2 cells. Dexamethasone, growth hormone and IGF-1 stimulated the promoter and endogenous activity of CYP27A1, whereas thyroid hormones and PMA inhibited CYP27A1. The regulatory effects of estrogens and androgens are different depending on the cell types. Thus, the results imply that human CYP27A1 gene is a target for estrogens and androgens, and the expression of CYP27A1 may be affected by endogenous sex hormones and pharmacological compounds with estrogenic or androgenic effects. </p><p>The mechanism for the dexamethasone-induced effect on the human CYP27A1 promoter was examined. A GRE was identified important for GR-mediated regulation of CYP27A1 transcriptional activity. </p>
44

Interaction of Xenobiotics with the Glucocorticoid Hormone System in vitro

Johansson, Maria January 2002 (has links)
Persistent environmental pollutants were examined for their interaction with the glucocorticoid hormone system. The focus was placed on interference with the glucocorticoid synthesis and the glucocorticoid-signalling pathway in various in vitro test systems. Several aryl methyl sulphones competitively inhibited CYP11B1 activity in mouse adrenocortical Y1 cells. The DDT metabolite, 3-methylsulphonyl-2,2’-bis(4-chlorophenyl)-1,1’-dichloroethene (3-MeSO2-DDE) had a higher affinity to the enzyme than the endogenous substrate, 11-deoxycorticosterone. In fact, 3-MeSO2-DDE (Ki 1.6 μM) was almost as potent as the drug metyrapone (Ki 0.8 μM), a well-known inhibitor of the enzyme. 3-MeSO2-DDE inhibited CYP11B1 activity in human adrenocortical H295R carcinoma cells, and at higher concentrations the CYP21 activity. The human H295R cell line seems to be a useful test system for studies of enzyme activities and could be used to screen endocrine disrupting chemicals interfering with the glucocorticoid hormone synthesis. Several chiral PCB methyl sulphones and the fungicide tolylfluanid proved to be antagonists to the glucocorticoid receptor (GR) in rat hepatoma cells and/or Chinese hamster ovary cells stable transformed with a human GR and a responsive reporter vector. The 4-methylsulphonyl-2,3,6,2’,4’,5’-hexachlorobiphenyl (4-MeSO2-CB149) enantiomers had similar antagonistic effect on the GR. Co-exposure of substances led to additive inhibitory effects on glucocorticoid-regulated protein synthesis in rat hepatoma cells. In general, 4-substituted but not 3-substituted methylsulphonyl-PCBs interacted with the glucocorticoid hormone system. In the environment, humans and wildlife are constantly exposed to a wide range of chemicals. Considering the effects of these substances via mechanisms of actions described in this thesis, interference of xenobiotics with the glucocorticoid hormone system deserves further attention. In conclusion, environmental pollutants can interact with the glucocorticoid hormone system in vitro, yet the effects of the tested substances on this hormone system remain to be established in vivo.
45

Hormonal Regulation of the Human CYP27A1 and CYP7B1 Genes

Tang, Wanjin January 2007 (has links)
CYP27A1 and CYP7B1 are widely expressed in various human tissues and are two key enzymes involved in the pathways for conversion of cholesterol to bile acids. Also, CYP27A1 is involved in bioactivation of vitamin D3 and CYP7B1 plays a role in 7alpha-hydroxylation of dehydroepiandrosterone and other steroids. Both enzymes have been reported to be relevant to prostate cell proliferation. The current study examines the hormonal regulation of CYP27A1 and CYP7B1. CYP7B1 was shown to be regulated by estrogens and androgens in human embryonic kidney HEK293 and prostate cancer LNCaP cells. Quantitation of CYP7B1 mRNA in adult and fetal human tissues showed markedly higher CYP7B1 mRNA levels in fetal tissues compared with the corresponding adult ones, except in the liver. This indicates a tissue-specific, developmental regulation of CYP7B1 and suggests an important function for this enzyme in fetal life. CYP7B1 regulation by estrogens may be of importance in fetal development and in other processes where CYP7B1 is involved, including cholesterol homeostasis, cellular proliferation, and CNS function. The regulation of CYP7B1 by sex hormones also suggests an important role for CYP7B1 in balancing prostate hormone levels in human cells. Results show that CYP27A1 can be regulated by dexamethasone, growth hormone, IGF-1, PMA, estrogens and androgens in liver-derived HepG2 cells. Dexamethasone, growth hormone and IGF-1 stimulated the promoter and endogenous activity of CYP27A1, whereas thyroid hormones and PMA inhibited CYP27A1. The regulatory effects of estrogens and androgens are different depending on the cell types. Thus, the results imply that human CYP27A1 gene is a target for estrogens and androgens, and the expression of CYP27A1 may be affected by endogenous sex hormones and pharmacological compounds with estrogenic or androgenic effects. The mechanism for the dexamethasone-induced effect on the human CYP27A1 promoter was examined. A GRE was identified important for GR-mediated regulation of CYP27A1 transcriptional activity.
46

The Role of Corticosteroids in Nitrogen Excretion of the Gulf Toadfish (Opsanus beta)

Rodela, Tamara 03 May 2011 (has links)
In contrast to most teleost fish that are ammoniotelic, the gulf toadfish (Opsanus beta) is both facultatively ureogenic and ureotelic. In vivo pharmacological manipulations were used to show that lowering circulating cortisol levels or blocking glucocorticoid receptors (GR) enhanced both urea excretion and urea pulse size. These findings demonstrated that changes in pulsatile urea excretion in the toadfish are mediated by the permissive action of cortisol through GRs. Measurement of urea transport across isolated basolateral gill membranes revealed a cortisol-sensitive carrier mechanism. Cortisol infusion in vivo significantly reduced urea transport capacity, suggesting that cortisol inhibits the recruitment of urea transport proteins (UT) to the basolateral membrane to ultimately decrease the size of the urea pulse in toadfish. A 1.2 kb fragment of the upstream transcription start site for the toadfish urea transporter (tUT) gene was isolated and in silico analysis revealed the presence of several putative glucocorticoid response element (GRE) half sites. Toadfish provided with this regulatory sequence in a reporter gene construct showed increased reporter gene transcription driven by cortisol. The data indicated that cortisol-mediated upregulation of tUT mRNA by GREs may be necessary to maintain tUT activity. Four Rhesus (Rh) glycoproteins (Rhag, Rhbg, Rhcg1, Rhcg2) were isolated from toadfish; these sequences grouped with those of other vertebrates coding for membrane channels that transport ammonia. In vivo increases in circulating cortisol reduced branchial Rh glycoprotein expression and decreased ammonia excretion. These changes were accompanied by cortisol-induced increases in glutamine synthetase activity, an enzyme that captures ammonia for urea synthesis. Taken together, the data indicated that cortisol reduces the loss by branchial excretion of ammonia, instead favouring biochemical pathways that convert ammonia to urea. This thesis confirms that nitrogen excretion in toadfish is controlled and regulated in fashions unlike those in other teleosts. The results demonstrate the importance of the GR signaling pathway in mediating changes in both urea and ammonia transport through molecular mechanisms. As a whole, the data provide a new understanding of branchial nitrogen excretion in the gulf toadfish and enhance our evolutionary perspective of the integrated biological systems involved in nitrogen excretion in fish.
47

The Role of Corticosteroids in Nitrogen Excretion of the Gulf Toadfish (Opsanus beta)

Rodela, Tamara 03 May 2011 (has links)
In contrast to most teleost fish that are ammoniotelic, the gulf toadfish (Opsanus beta) is both facultatively ureogenic and ureotelic. In vivo pharmacological manipulations were used to show that lowering circulating cortisol levels or blocking glucocorticoid receptors (GR) enhanced both urea excretion and urea pulse size. These findings demonstrated that changes in pulsatile urea excretion in the toadfish are mediated by the permissive action of cortisol through GRs. Measurement of urea transport across isolated basolateral gill membranes revealed a cortisol-sensitive carrier mechanism. Cortisol infusion in vivo significantly reduced urea transport capacity, suggesting that cortisol inhibits the recruitment of urea transport proteins (UT) to the basolateral membrane to ultimately decrease the size of the urea pulse in toadfish. A 1.2 kb fragment of the upstream transcription start site for the toadfish urea transporter (tUT) gene was isolated and in silico analysis revealed the presence of several putative glucocorticoid response element (GRE) half sites. Toadfish provided with this regulatory sequence in a reporter gene construct showed increased reporter gene transcription driven by cortisol. The data indicated that cortisol-mediated upregulation of tUT mRNA by GREs may be necessary to maintain tUT activity. Four Rhesus (Rh) glycoproteins (Rhag, Rhbg, Rhcg1, Rhcg2) were isolated from toadfish; these sequences grouped with those of other vertebrates coding for membrane channels that transport ammonia. In vivo increases in circulating cortisol reduced branchial Rh glycoprotein expression and decreased ammonia excretion. These changes were accompanied by cortisol-induced increases in glutamine synthetase activity, an enzyme that captures ammonia for urea synthesis. Taken together, the data indicated that cortisol reduces the loss by branchial excretion of ammonia, instead favouring biochemical pathways that convert ammonia to urea. This thesis confirms that nitrogen excretion in toadfish is controlled and regulated in fashions unlike those in other teleosts. The results demonstrate the importance of the GR signaling pathway in mediating changes in both urea and ammonia transport through molecular mechanisms. As a whole, the data provide a new understanding of branchial nitrogen excretion in the gulf toadfish and enhance our evolutionary perspective of the integrated biological systems involved in nitrogen excretion in fish.
48

The Role of Corticosteroids in Nitrogen Excretion of the Gulf Toadfish (Opsanus beta)

Rodela, Tamara 03 May 2011 (has links)
In contrast to most teleost fish that are ammoniotelic, the gulf toadfish (Opsanus beta) is both facultatively ureogenic and ureotelic. In vivo pharmacological manipulations were used to show that lowering circulating cortisol levels or blocking glucocorticoid receptors (GR) enhanced both urea excretion and urea pulse size. These findings demonstrated that changes in pulsatile urea excretion in the toadfish are mediated by the permissive action of cortisol through GRs. Measurement of urea transport across isolated basolateral gill membranes revealed a cortisol-sensitive carrier mechanism. Cortisol infusion in vivo significantly reduced urea transport capacity, suggesting that cortisol inhibits the recruitment of urea transport proteins (UT) to the basolateral membrane to ultimately decrease the size of the urea pulse in toadfish. A 1.2 kb fragment of the upstream transcription start site for the toadfish urea transporter (tUT) gene was isolated and in silico analysis revealed the presence of several putative glucocorticoid response element (GRE) half sites. Toadfish provided with this regulatory sequence in a reporter gene construct showed increased reporter gene transcription driven by cortisol. The data indicated that cortisol-mediated upregulation of tUT mRNA by GREs may be necessary to maintain tUT activity. Four Rhesus (Rh) glycoproteins (Rhag, Rhbg, Rhcg1, Rhcg2) were isolated from toadfish; these sequences grouped with those of other vertebrates coding for membrane channels that transport ammonia. In vivo increases in circulating cortisol reduced branchial Rh glycoprotein expression and decreased ammonia excretion. These changes were accompanied by cortisol-induced increases in glutamine synthetase activity, an enzyme that captures ammonia for urea synthesis. Taken together, the data indicated that cortisol reduces the loss by branchial excretion of ammonia, instead favouring biochemical pathways that convert ammonia to urea. This thesis confirms that nitrogen excretion in toadfish is controlled and regulated in fashions unlike those in other teleosts. The results demonstrate the importance of the GR signaling pathway in mediating changes in both urea and ammonia transport through molecular mechanisms. As a whole, the data provide a new understanding of branchial nitrogen excretion in the gulf toadfish and enhance our evolutionary perspective of the integrated biological systems involved in nitrogen excretion in fish.
49

Class I Lysine Deacetylases Facilitate Glucocorticoid-Mediated Gene Activation and Repression

Patrick, Nina M. January 2015 (has links)
Lysine acetyltransferases (KATs) and lysine deacetylases (KDACs) are known to cooperate with the glucocorticoid receptor (GR) to regulate transcription. The current model of GR-mediated transcription classifies KATs as coactivators as they acetylate histones to form an open chromatin conformation and casts KDACs as corepressors that deacetylate histones and condense chromatin. Our recent studies have challenged this long-standing model. In the current study, we show that KDACs act as versatile coregulators, facilitating both the onset and maintenance of GC-induced transcriptional activation and repression. Through siRNA depletion studies, we define KDAC1 as the predominant Class I KDAC for efficient transactivation of a majority of the GR-target genes tested. KDACs 1 and 2 co-operate with each other to activate and repress a few target genes, however KDAC2 alone is not sufficient for activation or repression of the genes, thus questioning the functional redundancy of KDACs 1 and 2. Additionally, we found that there is a unique population of KDAC2 that does not associate with KDAC1 in our cell line. Through a series of siRNA depletion studies, steroid receptor coactivator proteins (SRCs) were shown to be dispensable for GC-induced gene activation and SRC2 was not required for Dex-induced transcriptional repression. We performed ChIP assays to address the mechanism by which Class I KDACs facilitate transactivation and transrepression. At GC-activated genes we found that KDACs are constitutively present at the gene enhancers and that KDAC inhibition does not affect the binding of GR or SRC proteins to chromatin. However, KDACs do influence the histone methylation status of H3K4 at GREs of activated genes and TSSs of repressed genes. To explain the change in the methylation status of this marker, we depleted LSD1, the specific demethylase for mono- and demethylation of H3K4, and found that LSD1 action is required for GC-mediated transrepression. However it is unlikely that KDAC inhibition impairs GR transactivation through effects on LSD1. Glucocorticoid signaling regulates multiple vital biological processes. Glucocorticoids play a major role in regulating carbohydrate, protein and lipid metabolism. They increase hepatic gluconeogenesis to maintain blood glucose concentration in the fasting state. GCs also act as potent anti-inflammatory molecules, stimulate lung maturation in the developing fetus, and affect bone metabolism. Additionally, excess or deficiency of GCs can lead to a variety of psychological abnormalities, indicating their role in CNS functions. Our results indicate that pharmaceutical modulation of KDACs may impair proper glucocorticoid signaling and disrupt vital biological processes. Other steroid hormone receptors function similarly to GR in regulating gene expression and could also be impacted by KDAC inhibition, thus suggesting serious physiological implications in patients. Therefore, the possibility of endocrine modulation should be taken into account when using KDAC inhibitors in the clinic.
50

Dissecting the functional and morphological contributions of the glucocorticoid receptor gene in neural progenitor cells of the hippocampus / Dissection des rôles fonctionnels et morphologiques du récepteur des glucocorticoïdes dans les précurseurs neuronaux de l'hippocampe

Wong, Alana Tamar 30 September 2014 (has links)
La libération d'hormones glucocorticoïdes (GC), en réponse au stress, est un mécanisme important du contrôle de la neurogenèse chez l'adulte. Une question non résolue est de savoir si ces hormones agissent directement sur les précurseurs neuronaux (NPCs) ou indirectement, en agissant sur d'autres types cellulaires, modifiant la libération de facteurs de croissance ou l'activité de réseaux neuronaux. Afin de répondre à cette question, nous avons développé un modèle murin dans lequel le gène du récepteur des GC (GR) est invalidé, de façon inductible, dans les précurseurs neuraux adultes. Nous avons montré qu'en présence ou en absence du GR, un traitement chronique avec des GC affecte de façon similaire la différentiation et la survie des neurones nés chez l'adulte. L'effet connu des GC sur la suppression de la neurogenèse adulte n'est donc pas du à une action directe de ces hormones sur les NPCs. L'absence du GR n'affecte pas non plus le comportement des souris mutantes lorsque les GC circulent à un niveau de base. En revanche, un traitement chronique avec des GC induit chez les animaux contrôles un phénotype anxieux (observé dans les tests de novelty-suppressed feeding, light/dark box, and elevated O-maze) alors que les animaux mutés sont préservé de ce changement comportemental. De façon similaire, un traitement chronique avec des GC facilite l'apprentissage des souris contrôles lors d'un test d'apprentissage par la peur. L'invalidation du gène GR dans les NPC bloque cet effet. L'apprentissage des souris. Ces résultats précisent le rôle du GR dans le contrôle de la neurogenèse dans l'hippocampe adulte et dans la modulation des comportements de type anxieux. / Stress hormones are known as one of the strongest and most ecologically relevant mediators of adult neurogenesis. A lingering question in adult neurogenesis is whether these hormones, known as glucocorticoids (CG), act directly on neural progenitor cells (NPCs), or indirectly through secreted factors or changes in network activity. To address these unknowns, we generated a transgenic mouse model whose GC receptors (GRs) could be inducibly inactivated specifically in NPCs. We investigated the effect of this cell-specific GR knockout model on hippocampal survival and differentiation and found them to be similarly affected by chronic GC treatment compared to controls. This implies that GC-suppressed neurogenesis and its impact on morphology is indirect, and GR in other cells may be mediating the effects. Furthermore, mice with GR inactivation in newborn neurons behaved similarly to controls in all tasks observed under basal levels of GC. When mice were chronically treated with GC, however, controls exhibited an anxious phenotype, whereas transgenic mice behaved like untreated control groups in all anxiety measures except latency to feed in NSF. Neither GC nor inactivation of GR in adult-born neurons altered depression-like behaviors in the forced swim test, nor percent freezing in contextual fear discrimination. Lastly, we found that GC increased the rate of learning in 1-trial contextual fear conditioning, an effect not mediated by reducing GR signaling in the neurogenic pool. These results highlight the functional contributions of adult neurogenesis as well as how their GRs mediate anxiety-relevant behaviors irrespective of suppressed neurogenesis.

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