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Prenatal Ionizing Radiation Exposure Effects on Cardiovascular Health and Disease in C57Bl MiceSreetharan, Shayenthiran 11 1900 (has links)
Ionizing radiation exposure during pregnancy raises concerns of potentially harmful effects for both the mother and the unborn child. Fetal programming involves permanent changes in offspring phenotype due to stress experienced in-utero. This phenomenon has been well characterized in cardiometabolic disorders such as hypertension. The effects of prenatal ionizing radiation exposure on offspring cardiovascular endpoints following birth were studied in a mouse model. Pregnant wildtype C57Bl/6J mice were irradiated on day 15 of pregnancy with whole-body 137Cs gamma radiation at nominal doses of 5, 10, 50, 100, 300 or 1000 mGy. Post-natal measurements of offspring weight and blood pressure were completed. In female pups, blood pressure was significantly increased at 300 mGy and heart rate significantly decreased at 1000 mGy. Female pups were growth restricted over the study period at 50, 100 and 1000 mGy. Growth restriction in male pups was only observed at the highest dose of 1000 mGy. Unintended effects on the study measures caused by transportation of pregnant mothers to the irradiation facility were most evident in male offspring with increased blood pressure and heart rate and decreased body size. These unintended effects caused by transportation may have been attenuated with the 10 mGy in-utero exposure. Overall, these results suggest that prenatal radiation effects in mice are both dose- and gender-dependent, with even fairly low doses demonstrating (potentially adaptive) effects. There is a need for further study to better characterize the mechanism of this response. / Thesis / Master of Science (MSc)
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Evaluation of mitochondrial function in a model of developmental programming of hypertension associated with transient neonatal oxygen exposureAnstey, Zachary 08 1900 (has links)
UNE EXPOSITION NÉONATALE À L’OXYGÈNE MÈNE À DES MODIFICATIONS DE LA FONCTION MITOCHONDRIALE CHEZ LE RAT ADULTE
Introduction: L’exposition à l’oxygène (O2) des ratons nouveau-nés a des conséquences à l’âge adulte dont une hypertension artérielle (HTA), une dysfonction vasculaire, une néphropénie et des indices de stress oxydant. En considérant que les reins sont encore en développement actif lors des premiers jours après la naissance chez les rats, jouent un rôle clé dans le développement de l’hypertension et qu’une dysfonction mitochondriale est associé à une augmentation du stress oxydant, nous postulons que les conditions délétères néonatales peuvent avoir un impact significatif au niveau rénal sur la modulation de l’expression de protéines clés du fonctionnement mitochondrial et une production mitochondriale excessive d’espèces réactives de l’ O2.
Méthodes: Des ratons Sprague-Dawley sont exposés à 80% d’O2 (H) ou 21% O2 (Ctrl) du 3e au 10e jr de vie. En considérant que plusieurs organes des rats sont encore en développement actif à la naissance, ces rongeurs sont un modèle reconnu pour étudier les complications d’une hyperoxie néonatale, comme celles liées à une naissance prématurée chez l’homme. À 4 et à 16 semaines, les reins sont prélevés et les mitochondries sont extraites suivant une méthode d’extraction standard, avec un tampon contenant du sucrose 0.32 M et différentes centrifugations. L’expression des protéines mitochondriales a été mesurée par Western blot, tandis que la production d’ H202 et les activités des enzymes clés du cycle de Krebs ont été évaluées par spectrophotométrie. Les résultats sont exprimés par la moyenne ± SD.
Résultats: Les rats mâles H de 16 semaines (n=6) présentent une activité de citrate synthase (considéré standard interne de l’expression protéique et de l’abondance mitochondriales) augmentée (12.4 ± 8.4 vs 4.1 ± 0.5 μmole/mL/min), une diminution de l’activité d’aconitase (enzyme sensible au redox mitochondrial) (0.11 ± 0.05 vs 0.20 ± 0.04 μmoles/min/mg mitochondrie), ainsi qu’une augmentation dans la production de H202 (7.0 ± 1.3 vs 5.4 ± 0.8 ρmoles/mg protéines mitochondriales) comparativement au groupe Ctrl (n=6 mâles et 4 femelles). Le groupe H (vs Ctrl) présente également une diminution dans l’expression de peroxiredoxin-3 (Prx3) (H 0.61±0.06 vs. Ctrl 0.78±0.02 unité relative, -23%; p<0.05), une protéine impliquée dans l’élimination d’ H202, de l’expression du cytochrome C oxidase (Complexe IV) (H 1.02±0.04 vs. Ctrl 1.20±0.02 unité relative, -15%; p<0.05), une protéine de la chaine de respiration mitochondriale, tandis que l’expression de la protéine de découplage (uncoupling protein)-2 (UCP2), impliquée dans la dispersion du gradient proton, est significativement augmentée (H 1.05±0.02 vs. Ctrl 0.90±0.03 unité relative, +17%; p<0.05). Les femelles H (n=6) (vs Ctrl, n=6) de 16 semaines démontrent une augmentation significative de l’activité de l’aconitase (0.33±0.03 vs 0.17±0.02 μmoles/min/mg mitochondrie), de l’expression de l’ATP synthase sous unité β (H 0.73±0.02 vs. Ctrl 0.59±0.02 unité relative, +25%; p<0.05) et de l’expression de MnSOD (H 0.89±0.02 vs. Ctrl 0.74±0.03 unité relative, +20%; p<0.05) (superoxide dismutase mitochondriale, important antioxidant), tandis que l’expression de Prx3 est significativement réduite (H 1.1±0.07 vs. Ctrl 0.85±0.01 unité relative, -24%; p<0.05). À 4 semaines, les mâles H (vs Ctrl) présentent une augmentation significative de l’expression de Prx3 (H 0.72±0.03 vs. Ctrl 0.56±0.04 unité relative, +31%; p<0.05) et les femelles présentent une augmentation significative de l’expression d’UCP2 (H 1.22±0.05 vs. Ctrl 1.03±0.04 unité relative, +18%; p<0.05) et de l’expression de MnSOD (H 1.36±0.01 vs. 1.19±0.06 unité relative, +14%; p<0.05).
Conclusions: Une exposition néonatale à l’O2 chez le rat adulte mène à des indices de dysfonction mitochondriale dans les reins adultes, associée à une augmentation dans la production d’espèces réactives de l’oxygène, suggérant que ces modifications mitochondriales pourraient jouer un rôle dans l’hypertension artérielle et d’un stress oxydant, et par conséquent, être un facteur possible dans la progression vers des maladies cardiovasculaires.
Mots-clés: Mitochondries, Reins, Hypertension, Oxygène, Stress Oxydant, Programmation / EVALUATION OF MITOCHONDRIAL FUNCTION IN A MODEL OF DEVELOPMENTAL PROGRAMMING OF HYPERTENSION ASSOCIATED WITH TRANSIENT NEONATAL OXYGEN EXPOSURE
Introduction: Rats exposed to oxygen (O2) as newborns suffer complications in adulthood, including: arterial hypertension, vascular dysfunction, nephropenia and indices of oxidative stress. Although the rats are born at term, their organ development is equivalent to that of a preterm fetus, allowing organs of interest such as the kidney to be compared to premature infants. Given that impaired nephrogenesis or reduced nephron numbers has been shown to promote the development of hypertension and mitochondrial dysfunction is associated with increased oxidative stress, we hypothesised that exposure to high oxygen concentrations in the neonatal period would significantly impact the expression and activity of key proteins involved in renal mitochondrial function and lead to an excessive production of reactive oxygen species by the mitochondria.
Methods: Sprague-Dawley rat pups were exposed to 80% O2 (Hyperoxic (H) group; O2 exposed) or 21% O2 (Control (Ctrl) group) from day 3 to day 10 of life. At 4 and 16 weeks of age, kidneys were rapidly excised and the mitochondria isolated following a standard protocol; with a buffer containing 0.32 M sucrose and differential centrifugations. Expression of mitochondrial proteins was assessed by Western blot, whereas the release of hydrogen peroxide (H202), activities of key citric acid cycle enzymes and mitochondrial swelling were assessed by spectrophotometry. Results are expressed as the means ± SE. Both male and female offspring were studied.
Results: In male H rats at 16 weeks of age (n=6), citrate synthase activity (internal standard and measure of relative mitochondrial abundance) was significantly increased (12.4 ± 8.4 vs 4.1 ± 0.5 μmole/mL/min), whereas aconitase activity (sensitive to ROS) was significantly decreased (0.11 ± 0.05 vs 0.20 ± 0.04 μmoles/min/mg mitochondria) and H202 release was significantly increased (7.0 ± 1.3 vs 5.4 ± 0.8 ρmoles/mg mitochondrial protein) compared to the controls (Ctrl, n=6 males and 4 females). The H group (vs Ctrl) also demonstrated a reduction in the expression of peroxiredoxin-3 (Prx3) (H 0.61±0.06 vs. Ctrl 0.78±0.02 relative units, -23%; p<0.05), a protein involved in the elimination of H202 and in the expression of cytochrome C oxidase (Complex IV) (H 1.02±0.04 vs. Ctrl 1.20±0.02 relative units, -15%; p<0.05), a protein in the mitochondrial respiratory chain, whereas the expression of uncoupling protein-2 (UCP2), a protein involved in dissipating the proton gradient, was significantly increased (H 1.05±0.02 vs. Ctrl 0.90±0.03 relative units, +17%; p<0.05). Female H rats (n=6) (vs Ctrl, n=6) at 16 weeks of age demonstrated a significant increase in aconitase activity (0.33±0.03 vs 0.17±0.02 μmoles/min/mg mitochondria), in the expression of ATP synthase β subunit (H 0.73±0.02 vs. Ctrl 0.59±0.02 relative units, +25%; p<0.05) (involved in ATP production) and in the expression of MnSOD (H 0.89±0.02 vs. Ctrl 0.74±0.03 relative units, +20%; p<0.05) (mitochondrial antioxidant involved in scavenging superoxide), whereas Prx3 expression was significantly reduced (H 1.1±0.07 vs. Ctrl 0.85±0.01 relative units, -24%; p<0.05 ). In male H rats (vs Ctrl) at 4 weeks of age, the expression of Prx3 was significantly increased (H 0.72±0.03 vs. Ctrl 0.56±0.04 relative units, +31%; p<0.05). Female H rats (vs Ctrl) at 4 weeks of age demonstrated a significant increase in the expression of UCP2 (H 1.22±0.05 vs. Ctrl 1.03±0.04 relative units, +18%; p<0.05) and in the expression of MnSOD (H 1.36±0.01 vs. 1.19±0.06 relative units, +14%; p<0.05).
Conclusion: The findings of this study demonstrate that transient oxygen exposure in the neonatal rat modifies protein expression, enzymatic activity and leads to indices of mitochondrial dysfunction (increase in ROS) in the adult kidney; these adverse changes in the mitochondria were more pronounced in adult males than in females. Overall, these findings, suggest that impaired mitochondrial function is associated with and could play a role in the development of arterial hypertension, oxidative stress and cardiovascular disease associated with transient neonatal hyperoxic stress.
Keywords: Mitochondria, Hypertension, Kidneys, Developmental Programming, Oxygen, ROS
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Impact du stress hyperoxique en période néonatale sur la structure vasculaire : implication des phénomènes de sénescence et rôle possible dans la programmation développementale de l'hypertension artérielle / Consequences of Neonatal Hyperoxia on Vascular Structure : Premature Senescence and Possible Role in Developmental Programming of HypertensionHuyard, Fanny 26 September 2013 (has links)
Ce projet traite de la programmation développementale de l'hypertension artérielle (HTA) à travers des influences néonatales précoces pouvant moduler le développement vasculaire. Les bébés prématurés présentent des défenses antioxydantes diminuées comparés aux nouveau-nés à terme et sont exposés à la naissance à des concentrations élevées en oxygène (O2) engendrant la production d'espèces réactives de l'O2 (ERO). Les conséquences vasculaires à long terme de dommages liés aux ERO en période néonatale et les mécanismes impliqués sont très partiellement compris. Les précédents résultats du laboratoire ont montré qu'un stress hyperoxique néonatal conduit chez le rat adulte à de l'HTA, une dysfonction endothéliale et une rigidité artérielle, éléments de vieillissement vasculaire. Nous émettons l'hypothèse qu'un stress hyperoxique néonatale conduit à long terme à l'altération de la structure vasculaire et à un vieillissement vasculaire précoce. Nous avons démontré une diminution de la prolifération cellulaire, une capacité angiogénique altérée, des dommages à l'ADN et une augmentation de l'expression de protéines de sénescences (des indices de sénescence cellulaire) au-delà de la période néonatale suite à une exposition brève à l'O2 au niveau vasculaire dans un modèle animal (ratons Sprague-Dawley exposés à 80 % d'O2 du 3ème au 10ème jour de vie comparés à des ratons restés à l'air ambiant) et cellulaire (cellules musculaires lisses d'aortes thoraciques d'embryon de rat exposées à 40% O2 pendant 24h ou 48h, puis remises en normoxie pendant 96h). De plus, des altérations des composants de la structure vasculaire indiquant un remodelage vasculaire aortique ont été mises en évidence. Ces changements précèdent tous l'HTA et la dysfonction vasculaire observées dans le modèle animal à l'âge adulte et pourraient y contribuer. L'étude de jeunes adultes nés < 29 semaines comparés à des jeunes adultes nés à terme indique une augmentation de marqueurs de rigidité artérielle (indices d'un vieillissement vasculaire précoce) chez la population prématurée. L'ensemble des résultats démontre un vieillissement vasculaire précoce après une exposition néonatale transitoire à un stress hyperoxique permettant une meilleure compréhension des mécanismes physiopathologiques impliqués dans la survenue des troubles vasculaires retrouvés chez l'adulte et contribue à la mise en place de moyens de prévention chez des patients prématurés / The scope of this thesis is developmental programming of arterial high blood pressure (HBP) hypertension through early neonatal stimuli that may alter vascular development. Premature newborns have decreased antioxidant defenses compared to term babies and are exposed upon birth to high oxygen (O2) concentration, causing reactive oxygen species (ROS) production. Long term vascular consequences of ROS related damage during the neonatal period and the mechanisms involved remain unknown. Recent data from the laboratory show that neonatal hyperoxic stress leads in adult rat to HBP, endothelial dysfunction and arterial rigidity, characteristic features of vascular aging. We hypothesize that a neonatal hyperoxic stress leads to long term vascular structure alteration explained by an early aging of the vascular system. We showed a decreased proliferation rate, an altered angiogenic capacity, as well as long term DNA damage and increased expression of senescence proteins at a vascular level following O2 exposure in the animal (male Sprague-Dawley pups kept at 80% O2 from postnatal days 3 to 10 vs. rats remained in room air) and cellular models (embryonic vascular smooth muscle cells from rat thoracic aorta exposed to 40% O2 for 24h or 48h followed by 96h recovery in control conditions). In addition, alterations of vascular structure components indicating vascular remodeling was shown before the onset of the HBP at adult age. Those changes precede the HBP and vascular dysfunction observed in our animal model at adult age and could contribute to them. Study of young adults born before 29 weeks vs. young adults born at term showed that young adults born preterm present indices of arterial stiffness vs. term controls. Results of the present thesis demonstrate a major role of premature vascular aging in the surge of vascular diseases in adulthood and contribute to a better understanding of the patho-physiological mechanisms involved and could put into practice new prevention strategies among preterm patients
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Maternal Stress, Breastmilk IGF-1, and Offspring Growth among Breastfeeding Mothers-Infant Pairs in the Tampa Bay AreaGottfredson, Lauren Michelle 01 January 2015 (has links)
Background: Maternal stress during utero has been shown to have negative health consequences on the offspring, including low birth weight and increased risk of adult disease. Variation in breastmilk may act as an environmental cue of maternal stress and continue to program the infant during early life. This research aimed to explore the role of breastmilk on developmental programming of the infant. Specifically, to examine how breastmilk may act as a medium for the exposure of stress between the mother and the offspring, and see if variation in insulin like growth factor-1 (IGF-1) a potential mechanism for the relationship.
Methods: Survey-interviews, anthropometrics of the mother and offspring (height and weight), and breastmilk samples were collected for 31 breastfeeding mother-offspring pairs in the Tampa Bay area. Breastmilk was analyzed for IGF-1 and fat content. Maternal stress was measured through the PSS-10 and two self-reported ten-point stress scales. Offspring length for age and weight for age Z-scores were calculated using LMS equation.
Results: PPS-10 score was negatively correlated with child length for age and weight for age Z-scores. Child length for age and weight for age Z-scores were also negatively correlated with the breastmilk fat variables (creamatocrit percent, fat g/dL, and kcal/dL). No relationships were found between breastmilk IGF-1 and offspring length for age, weight for age, or maternal stress. Conclusions: Results indicate that maternal stress may negatively impact offspring growth. However, more research is necessary to better understand if or how breastmilk fat may act as a mechanism to mediate offspring growth due to maternal stress. This sample had low levels and prevalence of detectable IGF-1, which likely contributed to the lack of statistical relationships.
Further research using lower dilutions and larger samples sizes is necessary to better explore the potential role of breastmilk IGF-1 on offspring growth and/or its relationship to maternal stress.
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AN INVESTIGATION OF PERINATAL POLYCHLORINATED BIPHENYL EXPOSURE ON BODY COMPOSITION AND GLUCOSE HOMEOSTASISRashid, Cetewayo S 01 January 2013 (has links)
Recent advancements have uncovered environmental contributions to obesity and diabetes etiology. In fact, perinatal malnutrition resulting in low birth weight (LBW) has been shown to correlate with later life obesity and impaired glucose tolerance in aged offspring. LBW can result from a myriad of developmental perturbations including macronutrient restriction, hypoxia, maternal stress and toxin exposure.
Polychlorinated biphenyls (PCBs) are ubiquitous environmental pollutants that bioaccumulate in the food chain resulting in dietary exposure in humans. Maternal and cord blood PCB levels are inversely associated with birth weight, and recent studies indicate that perinatal exposures to PCBs contribute to gender-specific obesity development in children. PCBs have also been shown to enter breast milk resulting in direct exposure in early postnatal life. Therefore, we hypothesized that perinatal PCB exposure cause developmental blight resulting in decreased birth weight and increased adiposity and glucose intolerance with aging. We found that mice perinatally exposed to PCBs did not differ in birth weight, but exhibited sex-specific effects on adiposity. Females perinatally exposed to PCBs were significantly more obese at 7 weeks of age while male offspring exhibited no difference in fat mass but had decreased lean mass compared to controls. With aging, the differences in females dissipated while the male offspring decreased lean mass persisted. Male offspring perinatally exposed to PCBs displayed impaired glucose tolerance at 7 weeks of age but normalized over time, while the females were glucose intolerant only after 6 months of age. This impairment of glucose tolerance was not attributed to insulin resistance. These data illustrate time-dependent and sex-specific perturbations of maternal PCB exposure on offspring body composition and glucose homeostasis.
As the liver is a major facilitator in glucose homeostasis and xenobiotic detoxification, we investigated PCB-induced alterations in hepatic gene expression and found attenuated expression of glycolytic genes and increased expression of detoxifying and antioxidant genes in both PCB-exposed maternal and offspring livers. Taken together, these data demonstrate a role for perinatal pollutant exposure in the etiology of glucose intolerance. Further studies are required to elucidate the mechanisms causing sex-specific modulation of body composition and glucose intolerance.
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Programming of the paternal nucleus for embryonic developmentTeperek, Marta January 2016 (has links)
Historically, sperm has been considered merely as a carrier of genetic material at fertilisation. However, it is known that sperm supports embryonic development better than other cell types, suggesting that it might also have additional important, non-genetic contributions to embryonic development. The work described in this dissertation focuses on identifying the molecular determinants of developmental programming of sperm. First, the development of embryos derived from sperm and spermatids, immature precursors of sperm was compared. Sperm-derived embryos developed significantly better than spermatid-derived embryos. Further research aiming to identify the reasons for the developmental advantage of sperm led to the identification of proteins that are present specifically in sperm and not in spermatids. Moreover, egg factors which are preferentially incorporated into the sperm, but not into the spermatid chromatin were identified with the use of egg extracts, suggesting that the chromatin of sperm could be programmed to interact with the components of the egg. Subsequently, the reasons for developmental failure of spermatid-derived embryos were investigated. By comparing the sperm with spermatids it was shown that the programming of sperm to support efficient development is linked to its special ability to regulate expression of developmentally-important embryonic genes, and not to its ability to support DNA replication or rRNA production. Further characterisation of the sperm and spermatid chromatin with the use of genome-wide sequencing allowed me to link the correct regulation of gene expression in the embryo with a certain combination of epigenetic marks in the sperm, but not in the spermatid chromatin. Finally, it is shown that enzymatic removal of epigenetic modifications at fertilisation leads to misregulation of gene expression. This therefore suggests that epigenetic information contained in parental genomes at fertilisation is required for a proper regulation of embryonic transcription. My results support the hypothesis that the sperm is not only a carrier of genetic material, but also provides the embryo with epigenetic information for regulation of transcription after fertilisation. I believe that these findings advance our current understanding of the nature and mechanisms of sperm programming for embryonic development, and are important contributions to the emerging field of transgenerational inheritance of epigenetic traits in general.
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Investigating the impact of maternal diet on offspring immune function / Maternal Diet and Offspring Immune FunctionChouvalov, Anastasia V. January 2021 (has links)
Maternal obesity has significant consequences on the lifelong health of the developing child and rising global incidences make it one of the most common comorbidities during pregnancy. Offspring of obese mothers are at an increased risk of hospitalization for respiratory infections throughout childhood, which predispose these children to non-communicable respiratory diseases in later life. Animal models of maternal high fat diet (mHFD) feeding have observed common inflammatory outcomes with obesogenic models, but the effect on offspring varies with timing of the nutritional challenge and diet composition across studies. These studies demonstrate significant alterations to circulating and lung specific immune cells but the sequence of events that link maternal diet to these fetal outcomes are unclear, nor have they been tested in the context of a bacterial respiratory infection. Streptococcus pneumonaie is the most common causative pathogen of bacterial pneumonia and meningitis, making it of high clinical relevance. We aimed to investigate the effect of a mHFD (45% kcal from fat) during gestation and lactation, on offspring outcome and recovery from Streptococcus pneumoniae infection. Immunophenotyping, both before and after infection, revealed a hypo-inflammatory phenotype in circulating monocytes of the mHFD offspring with a decreased capacity to both initiate and terminate inflammatory responses. These offspring had significantly higher bacterial counts in lung tissues during infection and sustained cellular inflammation in survivors. In this thesis, we present foundational work on the detrimental influence of excess maternal nutrition on offspring immune function and infection outcomes, which may be involved in susceptibility to inflammatory and chronic disease in later life. A better understanding of this deep and lasting influence of the maternal environment will allow us to target preconception health as a form of harm reduction, informing stake holders and institutions to direct efforts towards DOHaD knowledge translation. / Thesis / Master of Science (MSc)
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The Effects of Muddy Conditions on the Cow Herd's Net Energy Requirements and Subsequent Calf GrowthNickles, Kirsten R. 25 August 2022 (has links)
No description available.
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Impact du stress hyperoxique en période néonatale sur la structure vasculaire : implication des phénomènes de sénescence et rôle possible dans la programmation développementale de l'hypertension artérielleHuyard, Fanny 05 1900 (has links)
Réalisé en cotutelle avec l'Université de Lorraine (France) / Ce projet traite de la programmation développementale de l’hypertension artérielle (HTA) à travers des influences néonatales précoces pouvant moduler le développement vasculaire. Les bébés prématurés présentent des défenses antioxydantes diminuées comparés aux nouveau-nés à terme et sont exposés à la naissance à des concentrations élevées en oxygène (O2) engendrant la production d’espèces réactives de l’O2 (ERO). Les conséquences vasculaires à long terme de dommages liés aux ERO en période néonatale et les mécanismes impliqués sont très partiellement compris. Les précédents résultats du laboratoire ont montré qu’un stress hyperoxique néonatal conduit chez le rat adulte à de l’HTA, une dysfonction endothéliale et une rigidité artérielle, éléments de vieillissement vasculaire. Nous émettons l'hypothèse qu'un stress hyperoxique néonatale conduit à long terme à l'altération de la structure vasculaire et à un vieillissement vasculaire précoce.
Nous avons démontré une diminution de la prolifération cellulaire, une capacité angiogénique altérée, des dommages à l’ADN et une augmentation de l’expression de protéines de sénescences (des indices de sénescence cellulaire) au-delà de la période néonatale suite à une exposition brève à l’O2 au niveau vasculaire dans un modèle animal (ratons Sprague-Dawley exposés à 80 % d’O2 du 3ème au 10ème jour de vie comparés à des ratons restés à l’air ambiant) et cellulaire (cellules musculaires lisses d'aortes thoraciques d'embryon de rat exposées à 40% O2 pendant 24h ou 48h, puis remises en normoxie pendant 96h). De plus, des altérations des composants de la structure vasculaire indiquant un remodelage vasculaire aortique ont été mises en évidence. Ces changements précèdent tous l’HTA et la dysfonction vasculaire observées dans le modèle animal à l’âge adulte et pourraient y contribuer. L’étude de jeunes adultes nés < 29 semaines comparés à des jeunes adultes nés à terme indique une augmentation de marqueurs de rigidité artérielle (indices d’un vieillissement vasculaire précoce) chez la population prématurée.
L’ensemble des résultats démontre un vieillissement vasculaire précoce après une exposition néonatale transitoire à un stress hyperoxique permettant une meilleure compréhension des mécanismes physiopathologiques impliqués dans la survenue des troubles vasculaires retrouvés chez l’adulte et contribue à la mise en place de moyens de prévention chez des patients prématurés. / The scope of this thesis is developmental programming of arterial high blood pressure (HBP) hypertension through early neonatal stimuli that may alter vascular development. Premature newborns have decreased antioxidant defenses compared to term babies and are exposed upon birth to high oxygen (O2) concentration, causing reactive oxygen species (ROS) production. Long term vascular consequences of ROS related damage during the neonatal period and the mechanisms involved remain unknown. Recent data from the laboratory show that neonatal hyperoxic stress leads in adult rat to HBP, endothelial dysfunction and arterial rigidity, characteristic features of vascular aging. We hypothesize that a neonatal hyperoxic stress leads to long term vascular structure alteration explained by an early aging of the vascular system.
We showed a decreased proliferation rate, an altered angiogenic capacity, as well as long term DNA damage and increased expression of senescence proteins at a vascular level following O2 exposure in the animal (male Sprague-Dawley pups kept at 80% O2 from postnatal days 3 to 10 vs. rats remained in room air) and cellular models (embryonic vascular smooth muscle cells from rat thoracic aorta exposed to 40% O2 for 24h or 48h followed by 96h recovery in control conditions). In addition, alterations of vascular structure components indicating vascular remodeling was shown before the onset of the HBP at adult age. Those changes precede the HBP and vascular dysfunction observed in our animal model at adult age and could contribute to them. Study of young adults born before 29 weeks vs. young adults born at term showed that young adults born preterm present indices of arterial stiffness vs. term controls.
Results of the present thesis demonstrate a major role of premature vascular aging in the surge of vascular diseases in adulthood and contribute to a better understanding of the patho-physiological mechanisms involved and could put into practice new prevention strategies among preterm patients.
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Impact de la prématurité et de la restriction de croissance fœtale sur les voies de signalisation corticostéroïdes rénales : adaptation néonatale et programmation fœtale de l’hypertension artérielle / Impact of Prematurity and Fetal Growth Restriction on Renal Corticosteroid Signaling Pathways : Neonatal Adaptation and Fetal Programming of High Blood PressureDumeige, Laurence 02 December 2019 (has links)
La prématurité et la restriction de croissance fœtale (RCF) sont deux pathologies néonatales fréquentes, qui ont en commun des difficultés d'adaptation à la naissance, avec le développement d'une tubulopathie chez le prématuré, et le développement d'une hypertension artérielle (HTA) a l'âge adulte. L’objectif de ce travail était d’évaluer l'implication des voies de signalisation corticostéroïdes rénales dans la survenue de ces complications dans un modèle murin de prématurité induite par des lipopolysaccharides, et un modèle de RCF par exposition périnatale a la dexaméthasone. Dans ce travail nous avons montré que ces deux pathologies programment la survenue d’une HTA à l’âge adulte chez les mâles, associée à des altérations franches de la signalisation corticostéroïde rénale en période périnatale et une augmentation de la sensibilité rénale aux glucocorticoïdes à l’âge adulte. Dans le modèle de prématurité, nous avons identifié la transmission transgénérationelle d’anomalies de régulation de la pression artérielle chez les mâles jusqu’à la 3ème génération de souris, associée à une hypométhylation du promoteur de GILZ et une augmentation d’expression de GILZ. Notre étude a permis l’identification de potentiels mécanismes moléculaires impliqués dans la programmation fœtale de l’HTA, sur plusieurs générations, ce qui pourrait aboutir à une meilleure prise en charge des patients nés prématurés ou avec une RCF, et de leurs descendants. / Preterm birth and fetal growth restriction (IUGR) are prevalent neonatal diseases, which both induce poor perinatal adaptation, including the development of tubulopathy in premature infants, and the development of high blood pressure in adults. The objective of this work was to evaluate the involvement of renal corticosteroid signaling pathways in the development of these complications in a lipopolysaccharide-induced mouse model of preterm birth, and a dexamethasone-induced model of IUGR. In this work, we have shown that these two pathologies program the development of hypertension in former preterm and IUGR male mice, associated with strong alterations of renal corticosteroid signaling in the perinatal period, and an increase in renal sensitivity to glucocorticoids in adulthood. Moreover, we have identified a transgenerational inheritance of altered blood pressure regulation induced by preterm birth, in males, up to the 3rd generation of mice, associated with GILZ promoter hypomethylation and increased GILZ expression.Our study has identified potential molecular mechanisms involved in the fetal programming of hypertension, over several generations. These findings could facilitate better management of patients born prematurely
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