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431	Der Einfluss körperlichen Ausdauertrainings auf die HDL-Funktion bei Patienten mit chronischer Herzinsuffizienz Noack, Friederike 09 May 2016 (has links) (PDF) Die chronische Herzinsuffizienz gehört zu den häufigsten internistischen Krankheitsbildern in Europa. Eine wichtige Rolle in der Therapie der chronischen Herzinsuffizienz spielt das moderate körperliche Ausdauertraining. HDL ist als Vasoprotektor bekannt und ist in der Lage, über die Regulation der endothelialen Stickstoffmonoxidsynthase (eNOS) die Dilatationsfähigkeit von Gefäßen zu regulieren. Da eine gestörte Endothelfunktion verbunden mit einer geringeren eNOS-Expression einen wichtigen Aspekt in der Pathophysiologie der Herzinsuffizienz darstellt, war das Ziel dieser Arbeit zunächst, die HDL-induzierte eNOS-Aktivierung und NO-Produktion in Endothelzellen bei chronisch Herzinsuffizienten mit der von Gesunden zu vergleichen. Des Weiteren wurde der Einfluss körperlichen Ausdauertrainings auf die HDL-Funktion bei chronischer Herzinsuffizienz untersucht. Dafür wurde HDL jeweils aus Blutserum von herzgesunden Probanden und Herzinsuffizienten vor und nach körperlichem Ausdauertraining isoliert. Damit wurden humane aortale Endothelzellen inkubiert und anschließend mittels Western Blot die HDL-induzierte Phosphorylierung der endothelialen Stickstoffmonoxidsynthase (Regulation der eNOS-Aktivierung), der Proteinkinase C-βII sowie der p70S6K ermittelt. Des Weiteren wurde ESR-spektroskopisch die HDL-induzierte NO-Produktion in Endothelzellen gemessen. Letztendlich bestand die Frage, worin der Unterschied zwischen HDL von Gesunden und HDL von Herzinsuffizienten besteht, der die funktionalen Differenzen erklären kann. Dazu wurde die Menge des HDL-gebundenen Malondialdehyds ermittelt. Die Endothelfunktion wurde sonographisch als Fluss-vermittelte Vasodilatation bestimmt. Die Ergebnisse der Untersuchungen belegen, dass die HDL-induzierte eNOS-Aktivierung bei Patienten mit chronischer Herzinsuffizienz im Vergleich zu Gesunden vermindert ist. Des Weiteren kann der Einfluss von HDL auf die eNOS-Aktivierung durch körperliches Ausdauertraining bei Patienten mit chronischer Herzinsuffizienz verbessert werden. Die Verbesserung der HDL-induzierten NO-Produktion korreliert dabei mit der verbesserten Fluss-vermittelten Vasodilatation. Als Unterschied zwischen HDL von Gesunden und dem von chronisch Herzinsuffizienten konnte bei den Letztgenannten eine höhere Menge von gebundenem Malondialdehyd nachgewiesen werden. HDL Endothelfunktion Herzinsuffizienz Ausdauertraining HDL heart failure exercise training endothelial dysfunction ddc:610
432	Mechanisms by which p53 Regulates Radiation-induced Carcinogenesis and Myocardial Injury Lee, Chang-Lung January 2012 (has links) <p>Radiation therapy can cause acute toxicity and long-term side effects in normal tissues. Because part of the acute toxicity of radiation is due to p53-mediated apoptosis, blocking p53 during irradiation can protect some normal tissues from acute radiation injury and might improve the therapeutic ratio of radiation therapy. However, the mechanisms by which p53 regulates late effects of radiation are not well understood. Here, I utilized genetically engineered mouse models to dissect the role of p53 in regulating two of the most clinically significant late effects of radiation: radiation-induced carcinogenesis and radiation-induced myocardial injury. </p><p> It has been well characterized that mice with one allele of p53 permanently deleted are sensitized to radiation-induced cancer. Therefore, temporary inhibition of blocking p53 during irradiation could promote malignant transformation. Experiments with mice lacking functional p53 in which p53 protein can be temporarily restored during total-body irradiation (TBI) suggest that the radiation-induced p53 response does not contribute to p53-mediated tumor suppression. Here, I performed reciprocal experiments and temporarily turned p53 off during TBI using transgenic mice with reversible RNA interference against p53. I found that temporary knockdown of p53 during TBI not only ameliorated acute hematopoietic toxicity, but in both Kras wild-type and tumor-prone KrasLA1 mice also prevented lymphoma development. Mechanistic studies show that p53 knockdown during TBI improves survival of hematopoietic stem and progenitor cells (HSPCs), which maintains HSPC quiescence and prevents accelerated repopulation of surviving cells. Moreover, using an in vivo competition assay I found that temporary knockdown of p53 during TBI maintains the fitness of p53 wild-type HSPCs to prevent the expansion of irradiated mutant cells. Taken together, our data demonstrate that p53 functions during TBI to promote lymphoma formation by facilitating the expansion of irradiated HSPCs with adaptive mutations. </p><p> p53 functions in the heart to promote myocardial injury after multiple types of stress, including ischemic injury, pressure overload and doxorubicin-induced oxidative stress. However, how p53 regulates radiation-induced myocardial injury, which develops after radiation therapy, is not well understood. Here, I utilized the Cre-loxP system to demonstrate that p53 functions in endothelial cells to protect mice from myocardial injury after a single dose of 12 Gy or 10 daily fractions of 3 Gy whole-heart irradiation (WHI). Mice in which both alleles of p53 are deleted in endothelial cells succumbed to heart failure after WHI due to myocardial necrosis, systolic dysfunction and cardiac hypertrophy. Moreover, the onset of cardiac dysfunction was preceded by alterations in myocardial vascular permeability and density. Mechanistic studies using primary cardiac endothelial cells (CECs) irradiated in vitro indicate that p53 signals to cause a mitotic arrest and protects CECs against radiation-induced mitotic catastrophe. Furthermore, mice lacking the cyclin-dependent kinase inhibitor p21, which is a transcriptional target of p53, are also sensitized to myocardial injury after 12 Gy WHI. Together, our results demonstrate that the p53/p21 axis functions to prevent radiation-induced myocardial injury in mice. Our findings raise the possibility that when combining radiation therapy with inhibitors of p53 or other components of the DNA damage response that regulate mitotic arrest, patients may experience increased radiation-related heart disease. </p><p> Taken together, our results demonstrate crucial but distinct roles of p53 in regulating late effects of radiation: p53-mediated apoptosis promotes radiation-induced lymphomagenesis, but p53-mediated cell cycle arrest prevents radiation-induced myocardial injury. These findings indicate that p53 may generally play a protective role from radiation, particularly at high doses, in cells where p53 activation is uncoupled from the induction of the intrinsic pathway of apoptosis. Therefore, selectively inhibiting p53-mediated apoptosis may be a promising approach to ameliorate acute radiation toxicity without exacerbating late effects of radiation.</p> / Dissertation Cellular biology Endothelial cells Lymphoma Mouse models Myocardial injury p53 Radiation
433	Human Epithelial Cells Discriminate between Commensal and Pathogenic Interactions with Candida albicans Rast, Timothy J., Kullas, Amy L., Southern, Peter J., Davis, Dana A. 18 April 2016 (has links) The commensal fungus, Candida albicans, can cause life-threatening infections in at risk individuals. C. albicans colonizes mucosal surfaces of most people, adhering to and interacting with epithelial cells. At low concentrations, C. albicans is not pathogenic nor does it cause epithelial cell damage in vitro; at high concentrations, C. albicans causes mucosal infections and kills epithelial cells in vitro. Here we show that while there are quantitative dose-dependent differences in exposed epithelial cell populations, these reflect a fundamental qualitative difference in host cell response to C. albicans. Using transcriptional profiling experiments and real time PCR, we found that wild-type C. albicans induce dose-dependent responses from a FaDu epithelial cell line. However, real time PCR and Western blot analysis using a high dose of various C. albicans strains demonstrated that these dose-dependent responses are associated with ability to promote host cell damage. Our studies support the idea that epithelial cells play a key role in the immune system by monitoring the microbial community at mucosal surfaces and initiating defensive responses when this community is dysfunctional. This places epithelial cells at a pivotal position in the interaction with C. albicans as epithelial cells themselves promote C. albicans stimulated damage. TOLL-LIKE RECEPTORS ENDOTHELIAL-CELLS PATHWAY INFECTIONS ADHERENCE PROMOTER BINDING GENES SHOCK LINE
434	THREE-DIMENSIONAL ENDOTHELIAL SPHEROID-BASED INVESTIGATION OF PRESSURE-SENSITIVE SPROUT FORMATION Song, Min 01 January 2016 (has links) This study explored hydrostatic pressure as a mechanobiological parameter to control in vitro endothelial cell tubulogenesis in 3-D hydrogels as a model microvascular tissue engineering approach. For this purpose, the present investigation used an endothelial spheroid model, which we believe is an adaptable microvascularization strategy for many tissue engineering construct designs. We also aimed to identify the operating magnitudes and exposure times for hydrostatic pressure-sensitive sprout formation as well as verify the involvement of VEGFR-3 signaling. For this purpose, we used a custom-designed pressure system and a 3-D endothelial cell spheroid model of sprouting tubulogenesis. We report that an exposure time of 3 days is the minimum duration required to increase endothelial sprout formation in response to 20 mmHg. Notably, exposure to 5 mmHg for 3 days was inhibitory for endothelial spheroid lengths without affecting sprout numbers. Moreover, endothelial spheroids exposed to 40 mmHg also inhibited sprouting activity by reducing sprout numbers without affecting sprout lengths. Finally, blockade of VEGFR-3 signaling abolished the effects of the 20-mmHg stimuli on sprout formation. Based on these results, VEGFR-3 dependent endothelial sprouting appears to exhibit a complex pressure dependence that one may exploit to control microvessel formation. Mechanotransduction Angiogenesis Lymphangiogenesis Tissue Engineering Vascular Endothelial Growth Factor Microcirculation Biomechanics and Biotransport
435	NEUROPILIN IN THE VASCULAR SYSTEM: MECHANISTIC BASIS OF ANGIOGENESIS Guo, Hou-Fu 01 January 2014 (has links) The vascular system is critical for maintaining homeostasis in all vertebrates. Structural studies of Neuropilin (Nrp), an essential angiogenic receptor, have defined its role in regulating angiogenesis, the formation of new vessels from the existing vasculature. Utilizing biochemical and biophysical tools we describe the ability of Nrp to function as a co-receptor for the VEGFR receptor tyrosine kinase. Two families of Nrp-1 ligands, Vascular Endothelial Growth Factor A (VEGF-A) and Semaphorin3F (Sema3F), physically compete for binding to the Nrp-1 b1 domain, and have opposite roles. VEGF-A is a potent pro-angiogenic cytokine while Sema3F is an angiogenesis inhibitor. Using coupled structural and functional studies, we have discovered the basis for potent competitive binding of Sema3F to Nrp1 requires engagement of two distinct binding sites. These data provide a basis for understanding the rational design of novel high affinity Nrp-1 inhibitor. VEGF receptor coupling endothelial cells semaphorin X-ray crystallography Biochemistry Structural Biology
436	Characterization of VEGF-C and its clinical relevance in lymphangiogenesis of papillary thyroid carcinoma Yu, Xiaomin, 虞曉敏 January 2007 (has links) published_or_final_version / abstract / Surgery / Doctoral / Doctor of Philosophy Vascular endothelial growth factors. Lymphatic metastasis. Lymphatics - Cancer. Thyroid gland - Cancer.
437	CARDIORESPIRATORY RESPONSES IN HEALTHY-WEIGHT AND OBESE WOMEN AND CHILDREN Easley, Elizabeth Ann 01 January 2013 (has links) A criterion method to evaluate cardiorespiratory health is measuring peak oxygen consumption (VO2 peak) from a maximal graded exercise test (GXT). While VO2 peak is a valuable measure, heart rate recovery (HRRec) and endothelial function (EF) also describe cardiorespiratory health and fitness. The purpose of this study was to investigate whether differences exist in VO2 peak, HRRec, and EF between healthy-weight (HW) and obese (OB) women and children and to determine if there were significant correlations among these variables. A total of 60 women and children participated in this study. Anthropometric, body composition, resting heart rate and blood pressure (BP) were measured. EF was evaluated to determine the reactive hyperemia index (RHI). Finally, each subject performed a graded exercise test (GXT) to determine VO2 peak. Following the GXT, the subjects’ recovery responses were monitored for 5 minutes. A factorial MANOVA was used to evaluate differences between obesity status and age in relative VO2 peak and relative HRRec. The MANOVA resulted in a significant (p < 0.001) main effect for obesity status and age, but there was no interaction effect. HW individuals had a greater relative VO2 peak compared to OB individuals. Children had a greater relative VO2 peak and HRRec compared to adults. Absolute VO2 peak and absolute HRRec were examined using univariate ANOVAs. Women had greater absolute VO2 peak values compared to children (p2 peak and absolute HRRec, relative HRRec, and RHI. Relative VO2 peak was significantly correlated to RHI. Absolute HRRec was correlated with relative HRRec and RHI. Relative HRRec was correlated with RHI. Lack of significant differences in HRRec and EF across adiposity levels were likely due to the obese, but otherwise healthy population recruited for this study. Age affected the response to all variables included in this study. Obesity children cardiorespiratory fitness heart rate recovery endothelial function Exercise Science
438	Models of coupled smooth muscleand endothelial cells Shaikh, Mohsin Ahmed January 2011 (has links) Impaired mass transfer characteristics of blood borne vasoactive species such as ATP in regions such as an arterial bifurcation have been hypothesized as a prospective mechanism in the aetiology of atherosclerotic lesions. Arterial endothelial (EC) and smooth muscle cells (SMC) respond differentially to altered local hemodynamics and produce coordinated macro-scale responses via intercellular communication. Using a computationally designed arterial segment comprising large populations of mathematically modelled coupled ECs & SMCs, we investigate their response to spatial gradients of blood borne agonist concentrations and the effect of micro-scale driven perturbation on the macro-scale. Altering homocellular (between same cell type) and heterocellular (between different cell types) intercellular coupling we simulated four cases of normal and pathological arterial segments experiencing an identical gradient in the concentration of the agonist. Results show that the heterocellular calcium (Ca2+) coupling between ECs and SMCs is important in eliciting a rapid response when the vessel segment is stimulated by the agonist gradient. In the absence of heterocellular coupling, homocellular Ca2+ coupling between smooth muscle cells is necessary for propagation of Ca2+ waves from downstream to upstream cells axially. Desynchronized intracellular Ca2+ oscillations in coupled smooth muscle cells are mandatory for this propagation. Upon decoupling the heterocellular membrane potential, the arterial segment looses the inhibitory effect of endothelial cells on the Ca2+ dynamics of underlying smooth muscle cells. The full system comprising hundreds of thousands of coupled nonlinear ordinary differential equations simulated on the massively parallel Blue Gene architecture. The use of massively parallel computational architectures shows the capability of this approach to address macro-scale phenomena driven by elementary micro-scale components of the system. smooth muscle cells endothelial cells calcium dynamics blue gene/L arterial coupled cells macroscale phenomena
439	Homogenised models of Smooth Muscle and Endothelial Cells. Shek, Jimmy January 2014 (has links) Numerous macroscale models of arteries have been developed, comprised of populations of discrete coupled Endothelial Cells (EC) and Smooth Muscle Cells (SMC) cells, an example of which is the model of Shaikh et al. (2012), which simulates the complex biochemical processes responsible for the observed propagating waves of Ca2+ observed in experiments. In a 'homogenised' model however, the length scale of each cell is assumed infinitely small while the population of cells are assumed infinitely large, so that the microscopic spatial dynamics of individual cells are unaccounted for. We wish to show in our study, our hypothesis that the homogenised modelling approach for a particular system can be used to replicate observations of the discrete modelling approach for the same system. We may do this by deriving a homogenised model based on Goldbeter et al. (1990), the simplest possible physiological system, and comparing its results with those of the discrete Shaikh et al. (2012), which have already been validated with experimental findings. We will then analyse the mathematical dynamics of our homogenised model to gain a better understanding of how its system parameters influence the behaviour of its solutions. All our homogenised models are essentially formulated as partial differential equations (PDE), specifically they are of type reaction diffusion PDEs. Therefore before we begin developing the homogenised Goldbeter et al. (1990), we will first analyse the Brusselator PDE with the goal that it will help us to understand reaction diffusion systems better. The Brusselator is a suitable preliminary study as it shares two common properties with reaction diffusion equations: oscillatory solutions and a diffusion term. homogenised PDE endothelial cells smooth muscle cells computational models numerical models reaction diffusion equations
440	Cigarette Smoke Extract-Induced Injury in Alveolar Cells in Model Systems Downs, Charles January 2011 (has links) Cigarette smoke contributes to many diseases. The actions of second and third hand smoke, which have implications for non-smokers and the very young, are just beginning to be appreciated. The overarching hypothesis of this project is that cigarette smoke has different injurious actions on alveolar cells based on chronological age. The purpose here was to learn more about the susceptibility of alveolar cells to cigarette smoke extract (CSE)- induced injury by performing studies on pulmonary alveolar and endothelial cells derived from neonatal, young, and old rats. The aims involved: 1. Developing cell culture models to study age-related effects of cigarette smoke on alveolar type I cells and microvascular endothelial cells from the lung, and 2. Using these models to examine the effects of CSE on markers of oxidative stress, inflammation and aging in alveolar cells harvested from neonatal, young and old rats. Descriptive and experimental studies involved using a variety of cell culture, biochemical and molecular techniques, including gene expression arrays. The most significant findings were that: 1. primary proliferating alveolar type I cells were used to develop novel cell culture model systems, including single culture, co-culture and three-dimensional cultures that were used to study the effects of CSE; 2. Hydrogen peroxide production by endothelial cells was markedly reduced by co-culturing with AT I cells; 3. Gene expression profiling of oxidative stress-specific pathways suggest that genes responsible for both stopping production of H2O2 or mopping-up H2O2 are involved; and 4. Cigarette smoke shortens telomeres of cells from neonates, but unexpectedly preserves telomere length of cells from young and old rats. Data from telomeric pathway-specific gene expression arrays suggest that there are age-related differences in response to gene expression to CSE. The significant conclusions are: 1. Contrary to prior observations, alveolar type I cells demonstrate prolonged proliferative capacity; 2. Alveolar type I cells likely play an important role in ameliorating CSE-induced oxidative stress; and 3. Neonatal alveolar cells may be more susceptible to the deleterious effects of CSE including telomere shortening. These novel model systems and observations provide new ways to study cigarette smoke-associated lung dysfunction. Injury Microvascular endothelial cell Rat Nursing Alveolar type I Cells Cigarette Smoke

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