Endocrine and molecular regulation of ovarian antral follicular wave emergence and growth in sheep

Seekallu, Srinivas

21 October 2009

In sheep, large ovarian antral follicles grow in waves with a periodicity of every 4 to 5 days; each wave is initiated by a peak in serum concentrations of follicle stimulating hormone (FSH). In the present thesis, follicular data and hormone estimations acquired from daily ultrasonography and blood samples, respectively, were used to study mechanisms regulating the number of follicular waves per estrous cycle. Using additional approaches such as implants releasing estradiol-17â and or progesterone, immunization against gonadotropin releasing hormone (GnRH), and injections of GnRH, the role of pulsed luteinizing hormone (LH) secretion and FSH peaks in follicular wave emergence and growth and the dependency of FSH peaks on pulsed GnRH secretion, were studied in sheep. The viability of aged follicles was also addressed.<p> The results of the present studies showed that ewes with three or four waves per cycle had cycles of the same length. The inter-wave interval was longer for the first and the last or ovulatory wave of the cycle in three compared to four wave cycles. The length of the lifespan and regression phase of the largest follicle of a wave declined across the cycle as FSH peak concentration and amplitude decreased. The maximum follicular diameter of the largest follicle growing in the first wave and the last or ovulatory wave of the cycle was greater compared to other waves of the cycle. Treatment of anestrous ewes with estradiol releasing implants alone completely abolished pulsed LH secretion and suppressed follicular wave development; however, FSH secretion was only minimally affected and the pool of small follicles was not affected. When pulsed secretion of LH was restored by frequent injections of GnRH, follicular waves were re-established. Treatment of anestrous ewes with implants releasing estradiol and progesterone, decreased FSH peak amplitude and abolished LH pulses and follicular waves; the size of the pool of small follicles increased. Immunization against GnRH in anestrous ewes abolished pulsatile LH secretion and suppressed follicular wave emergence; however, FSH peaks continued to occur for several weeks. In cyclic ewes, creating an LH pulse frequency typical of the follicular phase, during the luteal phase of the cycle by giving GnRH, increased maximum diameter of the largest follicle in a wave and serum concentrations of estradiol and progesterone. The enhanced growth of follicles in a wave blocked the next expected FSH peak and its associated follicular wave. Decreasing LH pulse frequencies lower than the minimal frequency seen in the luteal phase, by implants releasing progesterone, did not affect the growth of follicular waves.<p> It was previously demonstrated that treatment of non-prolific WWF ewes with Prostaglandin F2á (PGF2á) and medroxy progesterone acetate (MPA) increased the ovulation rate by adding ovulations from the penultimate wave in addition to the final wave of the cycle; however, fertility was not improved. In the last study of my thesis, we collected follicles, with an extended lifespan, from the penultimate wave of the cycle in ewes given the PGF2á and MPA treatment. We compared their quality with follicles from the final wave of the cycle by looking at the expression of markers of follicular development. The results showed that theca cells of follicles from the final wave had significantly higher mRNA expression for vascular endothelial growth factor (VEGF) compared to follicles from the penultimate wave. Granulosa cells of follicles from the final wave had significantly higher mRNA expression for connexion 43 (Cx43) compared to follicles from the penultimate wave. Protein expression for Cx43, proliferating cell nuclear antigen (PCNA) and Factor VIII was greater in follicles from the final compared to the penultimate wave.<p> We concluded from the present studies that: 1) the mechanism that makes a three wave or four wave cycle is unclear; 2) some level of pulsatile LH secretion is required for an FSH peak to trigger emergence of follicular waves in anestrous ewes; 3) progesterone enhances the inhibitory effects of estradiol on FSH secretion in anestrous ewes, suppressing specifically FSH peak amplitude; 4) an endogenous rhythm may exist that drives the peaks in FSH secretion independent of secretory products from the follicles growing in a wave and pulsed GnRH secretion; 5) follicular waves in ewes, when exposed to an LH pulse frequency similar to the follicular phase, during the luteal phase of the cycle, when serum progesterone concentrations are high, can grow and function like ovulatory follicles growing in the follicular phase of the cycle; 6) expression of some markers of vascularization/ angiogenesis, gap-junctional communication and cell proliferation, appeared to be decreased in follicles from the penultimate compared to the final wave of an estrous cycle, when the lifespan of follicles from the penultimate wave was extended such that they were present in the ovary with follicles from the final wave of the cycle.

Penultimate wave

Final wave

Factor VIII

Proliferating cell nuclear antigen

Connexin 43

Endothelial nitric oxide synthase

Vascular endothelial growth factor

Progesterone

Estradiol

Ovary

Follicular Waves

Sheep

Follicle-stimulating hormone

Luteinizing hormone

Three wave cycles

Four wave cycles

Endothelial TRPV4 dysfunction in a streptozotocin-diabetic Rat Model

Shamsaldeen, Yousif

January 2016

Diabetes mellitus is a complex disease characterised by chronic hyperglycaemia due to compromised insulin synthesis and secretion, or decreased tissue sensitivity to insulin, if not all three conditions. Endothelial dysfunction is a common complication in diabetes in which endothelium-dependent vasodilation is impaired. The aim of this study was to examine the involvement of TRPV4 in diabetes endothelial dysfunction. Male Charles River Wistar rats (350-450 g) were injected with 65mg/kg streptozotocin (STZ) intraperitoneally. STZ-injected rats were compared with naïve rats (not injected with STZ) or control rats (injected with 10ml/kg of 20mM citrate buffer, pH 4.0-4.5), if not both. Rats with blood glucose concentrations greater than 16mmol/L were considered to be diabetic. As the results revealed, STZ-diabetic rats showed significant endothelial dysfunction characterised by impaired muscarinic-induced vasodilation, as well as significant impairment in TRPV4-induced vasodilation in aortic rings and mesenteric arteries. Furthermore, STZ-diabetic primary aortic endothelial cells (ECs) showed a significant reduction in TRPV4-induced intracellular calcium ([Ca2+]i) elevation. TRPV4, endothelial nitric oxide synthase (eNOS), and caveolin-1 (CAV-1) were also significantly downregulated in STZ-diabetic primary aortic ECs and were later significantly restored by in vitro insulin treatment. Methylglyoxal (MGO) was significantly elevated in STZ-diabetic rat serum, and nondiabetic aortic rings incubated with MGO (100μM) for 12 hours showed significant endothelial dysfunction. Moreover, nondiabetic primary aortic ECs treated with MGO (100μM) for 5 days showed significant TRPV4 downregulation and significant suppression of 4-α-PDD-induced [Ca2+]i elevation, which was later restored by L-arginine (100μM) co-incubation. Incubating nondiabetic aortic rings with MGO (100μM) for 2 hours induced a spontaneous loss of noradrenaline-induced contractility persistence. Moreover, MGO induced significant [Ca2+]i elevation in Chinese hamster ovary cells expressing rat TRPM8 channels (rTRPM8), which was significantly inhibited by AMTB (1-5μM). Taken together, TRPV4, CAV-1, and eNOS can form a functional complex that is downregulated in STZ-diabetic aortic ECs and restored by insulin treatment. MGO elevation might furthermore contribute to diabetes endothelial dysfunction and TRPV4 downregulation. By contrast, MGO induced the loss of contractility persistence, possibly due to MGO's acting as a TRPM8 agonist.

616.4

Estudo dos efeitos da solução salina hipertônica nas alterações microcirculatórias e no desenvolvimento do processo inflamatório em modelo de morte encefálica em ratos / Study of hypertonic saline solution effects on microcirculatory alterations and development of the inflammatory process in a rat brain death model

Cristiano de Jesus Correia

06 February 2018

INTRODUÇÂO: A morte encefálica (ME) induz instabilidade hemodinâmica com hipoperfusão microcirculatória, desencadeando inflamação e disfunção de órgãos. OBJETIVO: Este estudo teve como objetivo investigar os efeitos da solução salina hipertônica (SH) 7,5% na evolução da resposta inflamatória no tecido mesentérico de ratos submetidos à ME. MÉTODOS: Ratos Wistar machos foram anestesiados e ventilados mecanicamente. A ME foi induzida pela insuflação rápida de um balão posicionado na cavidade intracraniana (Fogart 4F). Os ratos foram divididos aleatoriamente em: 1) Falso-operado, ratos submetidos aos procedimentos cirúrgicos e trepanação (FO, n=17); 2) Controle, ratos tratados com solução salina isotônica (NaCl 0,9%, 4 mL/kg) imediatamente após ME (CO, n=17); 3) Solução hipertônica 1, ratos tratados com solução hipertônica (NaCl 7,5%, 4 mL/kg) imediatamente após ME (SH1, n=17); 4) Solução hipertônica 60, ratos tratados com solução hipertônica 60 min após ME (SH60, n=17). Três horas após a indução da ME ou o término do procedimento cirúrgico para os animais do grupo FO, foram coletados os seguintes dados: (a) perfusão mesentérica, fluxo sanguíneo e interações leucócito-endotélio no mesentério, pela técnica de microscopia intravital; (b) expressão de proteínas de óxido nítrico sintase endotelial (eNOS), endotelina-1, P-selectina e molécula de adesão intercelular (ICAM)-1, por imunohistoquímica; (c) expressão gênica de eNOS e endotelina-1, por reação em cadeia da polimerase em tempo real (PCR); (d) concentrações séricas de citocinas, quimiocinas e corticosterona por meio de enzimaimunoensaio (ELISA). RESULTADOS: Todos os grupos submetidos a ME apresentaram um comportamento semelhante da pressão arterial, sendo observado um pico hipertensivo, seguido de período de hipotensão, logo após a insuflação do cateter intra-craniano. A proporção de pequenos vasos perfundidos foi diminuída no grupo CO (46%) em comparação com FO (74%, p=0,0039). A SH foi capaz de restaurar a proporção de vasos perfundidos (SH1=71%, p=0,0018). Não houve diferenças no fluxo sanguíneo mesentérico entre os grupos. A expressão proteica de eNOS aumentou significativamente em ratos com SH (SH1 e SH60, p=0,0002) em comparação ao grupo CO. Resultados semelhantes foram observados em relação à endotelina-1 (p < 0,0001). Não houve diferenças na expressão gênica de eNOS e endotelina-1. O aumento no número de leucócitos \"rollers\" (p=0,0015) e migrados (p=0,0063) foi observado no grupo CO em comparação com FO. Ratos com SH demonstraram redução significativa em todos os parâmetros da interação leucócito-endotélio. Com relação às moléculas de adesão, a expressão de ICAM-1 estava elevada no grupo CO em comparação com o FO, enquanto que o tratamento com SH diminuiu a expressão de ICAM-1 (SH1 e SH60, p=0,0002). CONCLUSÕES: O emprego da solução salina hipertônica melhorou a perfusão mesentérica, influenciou positivamente o metabolismo do óxido nítrico e reduziu a inflamação no mesentério, com diminuição da adesão e migração leucocitária, em ratos submetidos a ME / BACKGROUND: Brain death (BD) induces hemodynamic instability with microcirculatory hypoperfusion leading to increased organ inflammation and dysfunction. OBJETIVE: To investigate the effects of 7.5% hypertonic saline solution (HS) on the course of the inflammatory response in rats submitted to BD. METHODS: Male Wistar rats were anesthetized and mechanically ventilated. BD was induced by rapid inflation of intracranial balloon catheter (Fogart 4F). Rats were randomly divided in: 1) Sham-operated, rats submitted only to trepanation (SH, n=17); 2) Control, rats treated with normal saline solution (NaCl 0.9%, 4 mL/kg) immediately after BD (CO, n=17); 3) Hypertonic solution 1, rats treated with hypertonic solution (NaCl 7.5%, 4 mL/kg) immediately after BD (HS1, n=17); 4) Hypertonic solution 60, rats treated with hypertonic solution 60 min after BD (HS60, n=17). Hundred eighty minutes thereafter the following experiments were performed: (a) mesenteric perfusion, blood flow, and leukocyte-endothelial interactions, by intravital microscopy; (b) protein expression of endothelial nitric oxide synthase (eNOS), endothelin-1, P-selectin, and intercellular cell adhesion molecule (ICAM)-1, by immunohistochemistry; (c) gene expression of eNOS, and endothelin-1, by real-time polymerase chain reaction (PCR); (d) serum concentrations of cytokines, chemokines and corticosterone by enzyme-linked immunosorbent assay (ELISA). RESULTS: All BD groups presented similar hypertensive peak followed by hypotension. The proportion of perfused small vessels was decreased in CO group (46%) compared to SH (74%, p=0.0039). HS was able to restore the proportion of perfused vessels (HS1=71%, p=0.0018). There were no differences in mesenteric blood flow between groups. eNOS protein expression significantly increased in rats given HS (HS1, and HS60, p=0.0002). Similar results were observed regarding endothelin-1 (p < 0.0001). There were no differences in eNOS and endothelin-1 gene expression. Increased numbers of rolling (p=0.0015) and migrated (p=0.0063) leukocytes were observed in CO group compared to SH. Rats given HS demonstrated an overall reduction in leukocyte-endothelial interactions. Levels of ICAM-1 increased in CO group compared to SH, and decreased in HS-treated groups (p=0.0002). CONCLUSIONS: Hypertonic saline improves mesenteric perfusion, increased eNOS and endothelin-1 protein expression, and reduced inflammation by decreasing leukocyte adhesion and migration in BD rats

Endotelina-1

Inflamação

Interações leucócito-endotélio

Microcirculação

Morte encefálica

Óxido nítrico sintase endotelial

Ratos Wistar

Solução salina hipertônica

Brain death

Endothelial nitric oxide synthase

Endothelin-1

Inflammation

Leukocyte-endothelium interactions

Microcirculation

Saline solution hypertonic

Wistar rats

Stress oxydatif cérébrovasculaire et rupture de la barrière hémato-encéphalique dans le syndrome de Wernicke-Korsakoff expérimental

Beauchesne, Élizabeth

03 1900

Le syndrome de Wernicke-Korsakoff (SWK) est un désordre neuropsychiatrique causé par la déficience en thiamine (DT). Dans la DT expérimentale comme dans le SWK, on observe une mort neuronale et des hémorragies dans certaines régions précises du diencéphale et du tronc cérébral. Les lésions diencéphaliques du SWK sont particulièrement sévères et entraînent souvent des séquelles amnésiques permanentes. Le lien entre la dysfonction métabolique induite par la DT et la mort neuronale n’est pas connu. Des rapports précédents ont démontré que la perméabilité de la barrière hémato-encéphalique (BHE) était altérée et ce, précédant l’apparition du dommage neuronal, suggérant un rôle critique de la dysfonction vasculaire. Les jonctions serrées (JS) interendothéliales, la base anatomique de la BHE, constituent un réseau moléculaire incluant l’occludin et les zonula occludens (ZOs). Cette thèse démontre une perte d’expression et une altération de la morphologie de ces protéines en relation avec la dysfonction de la BHE dans le thalamus de souris déficientes en thiamine, fournissant une explication pour la présence d’hémorragies. Le stress oxydatif peut entraîner des dommages directs aux protéines des JS et interférer avec leurs mécanismes de régulation. De plus, l’oxyde nitrique (NO) peut induire la métalloprotéinase matricielle-9 (MMP-9) impliquée dans la dégradation de ces protéines. L’endothélium vasculaire cérébral (EVC) semble être une source importante de NO dans la DT, l’expression de l’oxyde nitrique synthase endothéliale (eNOS) étant sélectivement induite dans les régions vulnérables. Le NO peut réagir avec les espèces réactives oxygénées et former du peroxynitrite, entraînant un stress oxydatif/nitrosatif endothélial. Les résultats présentés démontrent que la délétion du gène de eNOS prévient le stress oxydatif/nitrosatif cérébrovasculaire, l’extravasation des immunoglobulins G (IgGs) et l’altération de l’occludin et des ZOs dans le thalamus de souris déficientes en thiamine. De plus, cette délétion prévient l’induction de l’expression de MMP-9 dans l’EVC. Des résultats similaires ont été obtenus avec l’antioxydant N-acétylcystéine (NAC). Les mécanismes précis par lesquels les espèces réactives altèrent les protéines des JS sont inconnus. Caveolin-1, une composante majeure du caveolæ de l’EVC, est impliquée dans la régulation de l’expression des protéines des JS, et celle-ci est modulée par le stress oxydatif/nitrosatif; l’altération de l’expression de caveolin-1 a été récemment associée à la rupture de la BHE. Les résultats présentés démontrent que l’expression de caveolin-1 est sélectivement altérée dans l’EVC du thalamus de souris déficientes en thiamine, coïcidant avec la rupture de la BHE, et démontrent que la normalisation de l’expression de caveolin-1 par le NAC est associée avec l’atténuation du dommage à la BHE. Pris ensemble, ces résultats démontrent un rôle central du stress oxydatif/nitrosatif cérébrovasculaire, particulièrement celui provenant de eNOS, dans l’altération des JS de la BHE via des dommages directs et via l’induction de MMP-9 et de caveolin-1. Cette rupture de la BHE contribue par conséquent à la mort neuronale dans le thalamus, puisque la prévention des altérations cérébrovasculaires par la délétion du gène de eNOS et le NAC atténue significativement la mort neuronale. L’administration précoce d’antioxydants en combinaison avec la thiamine devrait donc être une considération importante pour le traitement du SWK. / Wernicke-Korsakoff syndrome (WKS) is a neuropsychiatric disorder caused by thiamine deficiency (TD). In experimental TD as in WKS, neuronal cell death and hemorrhages are observed in specific diencephalic and brainstem areas. Diencephalic lesions in WKS are especially severe and often lead to permanent amnesic symptoms. The link between TD-induced metabolic dysfunction and neuronal cell death is unknown. Previous reports have shown that blood-brain barrier (BBB) permeability was impaired and that this occurred prior to the onset of neuronal damage, suggesting a critical role for vascular dysfunction. Interendothelial tight junctions (TJs), the anatomical basis of the BBB, constitute a molecular network comprising occludin and zonula occludens (ZOs). This thesis shows a loss of expression and alterations in the morphology of these proteins in relation to BBB dysfunction in the thalamus of thiamine-deficient mice, providing an explanation for the presence of hemorrhages. Oxidative stress can lead to direct oxidative damage to TJ proteins and interfere with their regulation mechanisms. Also, nitric oxide (NO) can induce matrix metalloproteinase-9 (MMP-9) involved in the degradation of these proteins. Cerebral vascular endothelium (CVE) seems to be an important source of NO in TD, since endothelial nitric oxide synthase (eNOS) expression is selectively induced in vulnerable areas. NO can react with reactive oxygen species and form peroxynitrite, leading to endothelial oxidative/nitrosative stress. Results have show that eNOS gene deletion prevents cerebrovascular oxidative/nitrosative stress, immunoglobulins G (IgGs) extravasation and occludin and ZOs alterations in the thalamus of thiamine-deficient mice. Also, eNOS gene deletion prevents the induction of MMP-9 in CVE. Similar results have been obtained with the antioxidant N-acetylcysteine (NAC). Precise mechanisms by which reactive species alter TJ proteins are unknown. Caveolin-1, a major component of CVE caveolæ, is involved in the regulation of TJ protein expression, and is modulated by oxidative/nitrosative stress; alteration in caveolin-1 expression has been recently associated with BBB breakdown. The present results show that caveolin-1 expression is selectively altered in CVE of the thalamus of thiamine-deficient mice, and show that normalization of caveolin-1 expression by NAC is associated with the attenuation of BBB damage. Taken together, these results demonstrate a central role for cerebrovascular oxidative/nitrosative stress, especially coming from eNOS, in BBB TJ protein alterations via direct damage and via induction of MMP-9 and caveolin-1. As a result, BBB breakdown contributes to neuronal cell death in the thalamus, since prevention of cerebrovascular alterations by eNOS gene deletion and NAC significantly attenuates neuronal cell death. Early administration of antioxidants combined with thiamine should therefore be an important consideration for the treatment of WKS.

Syndrome de Wernicke-Korsakoff

Déficience en thiamine

Barrière hémato-encéphalique

Occludin

Zonula occludens

Oxyde nitrique synthase endothéliale

Stress oxydatif/nitrosatif

Métalloprotéinase matricielle-9

Caveolin-1

Mort neuronale

Wernicke-Korsakoff syndrome

Thiamine deficiency

Blood-brain barrier

Endothelial nitric oxide synthase

Oxidative/nitrosative stress

Matrix metalloproteinase-9

Neuronal cell death

Mechanismen der Urocortin-II-induzierten Stimulation der NO-Produktion in isolierten Kaninchen-Ventrikelmyozyten / The mechanisms of Urocortin II-induced nitric oxide production in isolated rabbit cardiac myocytes

Walther, Stefanie

10 March 2010

No description available.

610 Medizin, Gesundheit

Medicine

Urocortin II

Kardiomyozyte

Stickstoffmonoxid

endotheliale NO-Synthase

Akt

Proteinkinase A

cross talk

Urocortin II

cardiac myocyte

nitric oxide

endothelial nitric oxide synthase

Akt

protein kinase A

cross talk

44.85

42.17

MED 411: Kardiologie

Stress oxydatif cérébrovasculaire et rupture de la barrière hémato-encéphalique dans le syndrome de Wernicke-Korsakoff expérimental

Beauchesne, Élizabeth

03 1900

Le syndrome de Wernicke-Korsakoff (SWK) est un désordre neuropsychiatrique causé par la déficience en thiamine (DT). Dans la DT expérimentale comme dans le SWK, on observe une mort neuronale et des hémorragies dans certaines régions précises du diencéphale et du tronc cérébral. Les lésions diencéphaliques du SWK sont particulièrement sévères et entraînent souvent des séquelles amnésiques permanentes. Le lien entre la dysfonction métabolique induite par la DT et la mort neuronale n’est pas connu. Des rapports précédents ont démontré que la perméabilité de la barrière hémato-encéphalique (BHE) était altérée et ce, précédant l’apparition du dommage neuronal, suggérant un rôle critique de la dysfonction vasculaire. Les jonctions serrées (JS) interendothéliales, la base anatomique de la BHE, constituent un réseau moléculaire incluant l’occludin et les zonula occludens (ZOs). Cette thèse démontre une perte d’expression et une altération de la morphologie de ces protéines en relation avec la dysfonction de la BHE dans le thalamus de souris déficientes en thiamine, fournissant une explication pour la présence d’hémorragies. Le stress oxydatif peut entraîner des dommages directs aux protéines des JS et interférer avec leurs mécanismes de régulation. De plus, l’oxyde nitrique (NO) peut induire la métalloprotéinase matricielle-9 (MMP-9) impliquée dans la dégradation de ces protéines. L’endothélium vasculaire cérébral (EVC) semble être une source importante de NO dans la DT, l’expression de l’oxyde nitrique synthase endothéliale (eNOS) étant sélectivement induite dans les régions vulnérables. Le NO peut réagir avec les espèces réactives oxygénées et former du peroxynitrite, entraînant un stress oxydatif/nitrosatif endothélial. Les résultats présentés démontrent que la délétion du gène de eNOS prévient le stress oxydatif/nitrosatif cérébrovasculaire, l’extravasation des immunoglobulins G (IgGs) et l’altération de l’occludin et des ZOs dans le thalamus de souris déficientes en thiamine. De plus, cette délétion prévient l’induction de l’expression de MMP-9 dans l’EVC. Des résultats similaires ont été obtenus avec l’antioxydant N-acétylcystéine (NAC). Les mécanismes précis par lesquels les espèces réactives altèrent les protéines des JS sont inconnus. Caveolin-1, une composante majeure du caveolæ de l’EVC, est impliquée dans la régulation de l’expression des protéines des JS, et celle-ci est modulée par le stress oxydatif/nitrosatif; l’altération de l’expression de caveolin-1 a été récemment associée à la rupture de la BHE. Les résultats présentés démontrent que l’expression de caveolin-1 est sélectivement altérée dans l’EVC du thalamus de souris déficientes en thiamine, coïcidant avec la rupture de la BHE, et démontrent que la normalisation de l’expression de caveolin-1 par le NAC est associée avec l’atténuation du dommage à la BHE. Pris ensemble, ces résultats démontrent un rôle central du stress oxydatif/nitrosatif cérébrovasculaire, particulièrement celui provenant de eNOS, dans l’altération des JS de la BHE via des dommages directs et via l’induction de MMP-9 et de caveolin-1. Cette rupture de la BHE contribue par conséquent à la mort neuronale dans le thalamus, puisque la prévention des altérations cérébrovasculaires par la délétion du gène de eNOS et le NAC atténue significativement la mort neuronale. L’administration précoce d’antioxydants en combinaison avec la thiamine devrait donc être une considération importante pour le traitement du SWK. / Wernicke-Korsakoff syndrome (WKS) is a neuropsychiatric disorder caused by thiamine deficiency (TD). In experimental TD as in WKS, neuronal cell death and hemorrhages are observed in specific diencephalic and brainstem areas. Diencephalic lesions in WKS are especially severe and often lead to permanent amnesic symptoms. The link between TD-induced metabolic dysfunction and neuronal cell death is unknown. Previous reports have shown that blood-brain barrier (BBB) permeability was impaired and that this occurred prior to the onset of neuronal damage, suggesting a critical role for vascular dysfunction. Interendothelial tight junctions (TJs), the anatomical basis of the BBB, constitute a molecular network comprising occludin and zonula occludens (ZOs). This thesis shows a loss of expression and alterations in the morphology of these proteins in relation to BBB dysfunction in the thalamus of thiamine-deficient mice, providing an explanation for the presence of hemorrhages. Oxidative stress can lead to direct oxidative damage to TJ proteins and interfere with their regulation mechanisms. Also, nitric oxide (NO) can induce matrix metalloproteinase-9 (MMP-9) involved in the degradation of these proteins. Cerebral vascular endothelium (CVE) seems to be an important source of NO in TD, since endothelial nitric oxide synthase (eNOS) expression is selectively induced in vulnerable areas. NO can react with reactive oxygen species and form peroxynitrite, leading to endothelial oxidative/nitrosative stress. Results have show that eNOS gene deletion prevents cerebrovascular oxidative/nitrosative stress, immunoglobulins G (IgGs) extravasation and occludin and ZOs alterations in the thalamus of thiamine-deficient mice. Also, eNOS gene deletion prevents the induction of MMP-9 in CVE. Similar results have been obtained with the antioxidant N-acetylcysteine (NAC). Precise mechanisms by which reactive species alter TJ proteins are unknown. Caveolin-1, a major component of CVE caveolæ, is involved in the regulation of TJ protein expression, and is modulated by oxidative/nitrosative stress; alteration in caveolin-1 expression has been recently associated with BBB breakdown. The present results show that caveolin-1 expression is selectively altered in CVE of the thalamus of thiamine-deficient mice, and show that normalization of caveolin-1 expression by NAC is associated with the attenuation of BBB damage. Taken together, these results demonstrate a central role for cerebrovascular oxidative/nitrosative stress, especially coming from eNOS, in BBB TJ protein alterations via direct damage and via induction of MMP-9 and caveolin-1. As a result, BBB breakdown contributes to neuronal cell death in the thalamus, since prevention of cerebrovascular alterations by eNOS gene deletion and NAC significantly attenuates neuronal cell death. Early administration of antioxidants combined with thiamine should therefore be an important consideration for the treatment of WKS.

Syndrome de Wernicke-Korsakoff

Déficience en thiamine

Barrière hémato-encéphalique

Occludin

Zonula occludens

Oxyde nitrique synthase endothéliale

Stress oxydatif/nitrosatif

Métalloprotéinase matricielle-9

Caveolin-1

Mort neuronale

Wernicke-Korsakoff syndrome

Thiamine deficiency

Blood-brain barrier

Endothelial nitric oxide synthase

Oxidative/nitrosative stress

Matrix metalloproteinase-9

Neuronal cell death

Nitric oxide signalling in astrocytes

Wang, Xuewei

06 1900

Dans le cerveau, les astrocytes sont les cellules gliales les plus abondantes et elles jouent divers rôles, y compris le maintien des synapses tripartites et la régulation du débit sanguin cérébral (DSC). Le monoxyde d’azote (NO) est une molécule de signal endogène qui a un impact sur la régulation de l'activité synaptique et du DSC. Des études antérieures ont démontré que le NO est produit dans les cellules endothéliales et les neurones par la synthase du monoxyde d’azote endothéliale (eNOS) et neuronale (nNOS), respectivement. Cependant, la source de production de NO dans les astrocytes reste incertaine. Par conséquent, nous proposons que la voie de signalisation NOS constitutive puisse coexister dans les astrocytes et puisse être activée par différents neurotransmetteurs. L'objectif de cette thèse est d'identifier les sources et les activateurs de la production de NO dans les astrocytes corticaux de la souris. L'identification des isoformes constitutives de NOS effectuée au moyen de la microscopie électronique et d'immunohistochimie a révélé l’expression des eNOS et nNOS dans les astrocytes. Des préparations de culture d'astrocytes et de tranches de cerveau marquées avec du diacétate de 4-amino-5-méthylamino-2',7'-difluorescéine (DAF-FM), un indicateur de NO perméable aux cellules qui devient imperméable une fois à l’intérieur ont été réalisées. Cette fonctionnalité a été mise à profit pour évaluer la production de NO exclusivement dans les astrocytes en utilisant la microscopie confocale à uni- et multi-photons. De plus, des agonistes cholinergiques ou glutamatergiques qui ont la capacité d’augmenter la concentration de Ca2+ intracellulaire peuvent induire une production du NO in vitro et ex vivo dans les astrocytes, qui est supprimée en présence de l'inhibiteur de NOS non sélectif, L-NG -Nitro-arginine. Fait intéressant, la réponse NO à l’acétylcholine était absente chez les souris eNOS-/-, tandis que l'acide trans-1-aminocyclopentane-1,3-dicarboxylique (t-ACPD) a peu affecté la production de NO chez les souris nNOS-/-. Ces résultats impliquent que les eNOS et nNOS astrocytaires peuvent être déclenchés par des cascades d'activation distinctes (cholinergique et glutamatergique métabotrope). En outre, les études sur la mobilisation cytosolique du Ca2+ indiquent l'importance du réticulum endoplasmique comme réservoir de Ca2+ pour la production de NO, et suggèrent aussi une voie de signalisation astrocytaire qui, une fois activée par le t- ACPD, provoque l'efflux de Ca2+ médié par le récepteur à la ryanodine, qui à son tour active les nNOS adjacents et conduit à la production de NO. Par ailleurs, la superfusion de préparations in vitro et ex vivo avec du N-Méthyl-D-aspartate (NMDA) a provoqué une augmentation du NO tant dans les souris eNOS-/- que nNOS-/-, ce qui indique l'implication des eNOS et nNOS astrocytaires. La production de NO a été atténuée par l'inhibition du complexe PSD-95 / nNOS ce qui suggère que le récepteur NMDA astrocytaire rend fonctionnelle la cassette de signalisation NR2B/PSD-95/nNOS. En conclusion, nos résultats démontrent que : i) les astrocytes corticaux expriment à la fois eNOS et nNOS; ii) la nNOS cytosolique colocalise avec les récepteurs 2 et 3 de la ryanodine, alors que les nNOS membranaires colocalisent avec le récepteur NMDA contenant le NR2B; iii) la stimulation neuronale a la capacité d'induire la production de NO par les eNOS et nNOS astrocytaires par des voies de signalisation différentes; iv) l'activation des nNOS cytosoliques nécessite une activation des récepteurs à la ryanodine. Collectivement, ces données suggèrent une production de NO compartimentée et spécifique après une stimulation neuronale probablement dans le but de réguler finement et de façon polarisée les fonctions astrocytaires. Ce travail fournit un nouvel aperçu des conséquences physiologiques pour les fonctions neuronales et vasculaires et améliore notre compréhension de la fonction NO astrocytaire dans le cerveau. / In the brain, astrocytes are the most abundant glial cells and play various roles including maintenance of tripartite synapses and regulation of CBF. An endogenous signal molecule that has a potential to have an effect on regulation of both synaptic activity and CBF is nitric oxide (NO). Previous studies have demonstrated that NO is produced in endothelial cells and neurons by endothelial nitric oxide synthase (eNOS) and neuronal nitric oxide synthase (nNOS), respectively. However, the source of NO production in astrocyte remains uncertain. Therefore, we propose that constitutive NOS signalling pathways may exist in astrocyte and can be activated by different neurotransmitters. The aim of this thesis is to identify the sources and activators of NO production in mouse cortical astrocytes. Identification of constitutive NOS isoforms done by means of electron microscopy and immunohistochemistry revealed the expression of both eNOS and nNOS in astrocytes. All preparations were performed in astrocyte cultures and brain slice preparations labeled with 4- amino-5-methylamino-2',7'-difluorescein (DAF-FM) diacetate, a cell-permeant NO indicator that becomes cell-impermeable once inside cells. Therefore, I took advantage of this feature to evaluate NO production exclusively in astrocytes using single and multi-photon confocal microscopy. We then tested whether cholinergic and glutamatergic agonists that have the capacity to increase intracellular Ca2+ concentration can induce an increase in astrocytic NO. Both in vitro and ex vivo, NO production levels indicate that cholinergic and glutamatergic stimulations can induce astrocytic NO increases, which was abolished by the non-selective NOS inhibitor L- NG -Nitro-arginine. Moreover, the NO response to ACh was absent in eNOS-/- mice, while trans-1-aminocyclopentane-1,3-dicarboxylic acid (t-ACPD) barely affected NO production in nNOS-/- mice. These results imply that astrocytic eNOS and nNOS can be triggered discretely by distinct activation cascades (cholinergic and metabotropic glutamatergic). Furthermore, studies on cytosolic Ca2+ mobilization point out the importance of the endoplasmic reticulum (ER) Ca2+ as key in the mechanism of NO production, and suggests a signalling pathway that t-ACPD causes IP3Rs to elicit RyRs-mediated Ca2+ efflux, which in turn, activates adjacent nNOS and leads to NO production. Furthermore, superfusion of in vitro and ex vivo preparations with N-Methyl-D-aspartate (NMDA) evoked an increase in NO in eNOS-/- and nNOS-/- mice. The NO production was attenuated through removal of PSD-95/nNOS complex. This result posits that astrocytic NMDA receptor may comprise the functional NR2B/PSD- 95/nNOS signalling cassette. In conclusion, our findings demonstrate that: i) cortical astrocytes express both eNOS and nNOS; ii) nNOS colocalizes with ryanodine receptor 2 and 3, whereas membrane nNOS colocalizes with NR2B-containing NMDA receptor; iii) neuronal stimulation has the capacity of inducing eNOS- and nNOS-produced NO in astrocytes via different activation signalling; iv) activation of cytosolic nNOS requires the activation of ryanodine receptors. Collectively, these data suggest a compartmentalized and specific NO production following neuronal stimulation probably for a fine and polarized regulation of astrocytic functions. This work provides new insight into physiological consequences for neuronal and vascular functions and ameliorates our understanding of astrocytic NO function in the brain.

Monoxide d’azote

Nitric oxide

Endothelial nitric oxide synthase

Synthase du monoxyde d’azote neuronale

Neuronal nitric oxide synthase

Astrocyte

Pieds astrocytaires

Astrocytic endfoot

Microdomains

Cholinergique

Cholinergic

Glutamatergique

Glutamatergic

Cortex somatosensoriel

Somatosensory cortex

Function of Vascular Endothelial Cells in Aging and Hypothermia: Clinical Implications

Osama, Mohammad

January 2018

No description available.

Aging

Alternative Medicine

Cellular Biology

Chemistry

Developmental Biology

Endocrinology

Environmental Science

Environmental Studies

Epidemiology

Health Care

Health Sciences

Immunology

Medicine

Microbiology

Molecular Biology

Molecular Chemistry

Molecules

Nanoscience

Nanotechnology

Neurobiology

Neurology

Neurosciences

Organic Chemistry

Organismal Biology

Oncology

Pharmaceuticals

Pharmacology

Pharmacy Sciences

Physiology

Polymer Chemistry

Sports Medicine

Toxicology

Therapy

Zoology

Aging, Therapeutic hypothermia

Caucasian Americans

African Americans

Asian Americans

Endothelial nitric oxide synthase

NADPH ox

Human umbilical vein endothelial cells

VAS2870

PEG-SOD

L-arginine

Angiotensin II

L-arginine

Clinical implications