Global ETD Search

71	The Role of RELA (p65) in Regulation of NF-kappaB Homeostasis: Implications for Atherosclerosis Wasal, Karanvir 04 January 2012 (has links) The NF-κB/Rel family of transcription factors and IκB inhibitors play a key role in regulation of gene expression in inflammation and immunity. Previous studies from our laboratory suggested that steady-state levels of p65 and other NF-κB components in the normal mouse aorta determine the magnitude of NF-κB target gene expression in response to pro-inflammatory stimuli, however, the mechanism(s) by which steady-state levels of NF-κB components are set is not clear. This study aims at elucidating the mechanisms behind NF-κB homeostasis and how that affects atherosclerosis susceptibility. In HeLa cells and HUVEC, siRNA silencing of p65 correlated with reduced steady-state expression of a subset of NF-κB/Rel and IκB genes at the transcriptional and post-transcriptional levels, respectively, in addition to reducing TNFα-induced NF-κB/Rel and IκB gene expression. This correlation was also observed in atherosclerosis-susceptible mouse aortic endothelium suggesting the role of p65 in modulating NF-κB homeostasis and affecting atherosclerosis susceptibility. Inflammation Nuclear factor-kappaB Gene expression endothelial cells 0982
72	Coating Collagen Modules with Fibronectin Increases in vivo HUVEC Survival and Vessel Formation through the Suppression of Apoptosis Cooper, Thomas 13 January 2010 (has links) Modular tissue engineering is a novel approach to creating scalable, self-assembling three-dimensional tissue constructs with inherent vascularisation. Under initial methods, the subcutaneous implantation of human umbilical vein endothelial cell (HUVEC)-covered collagen modules in immunocompromised mice resulted in significant host inflammation and limited HUVEC survival. Subsequently, a minimally-invasive injection technique was developed to minimize surgery-related inflammation, and cell death was attributed to extensive apoptosis within 72 hours of implantation. In confirmation of in vitro results, coating collagen modules with fibronectin (Fn) was shown in vivo to reduce short-term HUVEC apoptosis by nearly 40%, while increasing long-term HUVEC survival by 30% to 45%. Consequently, a 100% increase in the number of HUVEC-lined vessels was observed with Fn-coated modules, as compared to collagen-only modules, at 7 and 14 days post-implantation. Furthermore, vessels appeared to be perfused with host erythrocytes by day 7, and vessel maturation and stabilization was evident by day 14. modular tissue engineering endothelial cells apoptosis extracellular matrix fibronectin 0541
73	The Effects of Steady Laminar Shear Stress on Aortic Valve Cell Biology Butcher, Jonathan Talbot 06 November 2004 (has links) Aortic valve disease (AVD) affects millions of people of all ages around the world. Current treatment for AVD consists of valvular replacement with a non-living prosthetic valve, which is incapable of growth, self-repair, or remodeling. While tissue engineering has great promise to develop a living heart valve alternative, success in animal models has been limited. This may be attributed to the fact that understanding of valvular cell biology has not kept pace with advances in biomaterial development. Aortic valve leaflets are exposed to a complex and dynamic mechanical environment unlike any in the vasculature, and it is likely that native endothelial and interstitial cells respond to mechanical forces differently from other vascular cells. The objective of this thesis was to compare valvular cell phenotype to vascular cell phenotype, and assess the influence of steady shear stress on valvular cell biology. This thesis demonstrates that valvular endothelial cells respond differently to shear than vascular endothelial cells, by aligning perpendicular to the direction of steady shear stress, and by the differential regulation of hundreds of genes in both static and fluid flow environments. Valvular interstitial cells expressed a combination of contractile and synthetic phenotypes not mimicked by vascular smooth muscle cells. Two three-dimensional leaflet models were developed to assess cellular interactions and the influences of steady laminar shear stress. Valvular co-culture models exhibited a physiological response profile, while interstitial cell-only constructs behaved more pathologically. Steady shear stress enhanced physiological functions of valvular co-cultures, but increased pathological response of interstitial cell-only constructs. These results showed that valvular cells, whether cultured separately or together, behaved distinctly different from vascular cells. It was also determined that shear stress alone cannot induce tissue remodeling to more resemble native valve leaflets. The leaflet models developed in this thesis can be used in future experiments to explore valvular cell biology, assess the progression of certain forms AVD, and develop targeted diagnostic and therapeutic strategies to hopefully eliminate the need for valvular replacement entirely. Microarray Interstitial cells Aortic valve Shear stress Endothelial cells
74	The Effects of Sickle Erythrocytes on Endothelial Permeability Brown, Lola A. 18 April 2005 (has links) Sickle cell anemia is a hematological disorder that is caused by a single point mutation in the beta-globin chain of hemoglobin. It results in several complications related to the small and large vessels in patients with the disease. Large vessel complications include cerebral infarcts, which are observed in children under ten years old. The mechanism behind this complication is not completely understood. It is the goal of this project to begin to understand the role sickle erythrocytes may play in causing endothelial dysfunction as a precursor to sickle related complications. The hypothesis of this work is that exposure of large vessel endothelium to sickle erythrocytes causes an increase in endothelial permeability through loosening of adherens junctions. In the first goal of this work, bovine aortic endothelial cells (BAECs) are grown on coverslips and exposed to sickle erythrocytes for 5 minutes and either immediately fixed or incubated in 30 minutes and then fixed. Immunofluorescent studies labeling VE cadherin show changes in VE cadherin dynamics, suggesting sickle erythrocytes may be involved in this observation. Next, BAECs were grown on transwell inserts and exposed to sickle erythrocytes for 5 minutes. The erythrocytes are washed off and the BAEC are incubated with 10,000 MW dextran conjugated to lucifer yellow or FITC-BSA or to determine BAEC permeability. When dextran is used as the test molecule, endothelial permeability did not show a significant change from baseline. However, when BSA is used as the test molecule, increases in endothelial permeability are observed. Explanations into the differences between the transport mechanisms of the two molecules are discussed. These experiments show changes in VE cadherin localization due to sickle erythrocyte exposure. This may cause increases in endothelial permeability and an experimental model and preliminary studies are performed. This study provides potential mechanisms to explain the changes in VE cadherin localization and provide suggestions for further studies to test the effect of sickle erythrocytes on endothelial permeability. This work provides a strong foundation for continuing studies on the effects of sickle erythrocytes on endothelial dysfunction within the confines of sickle related complications. Permeability coefficient VE cadherin Stroke Endothelial cells Sickle cell anemia
75	The development of an in vitro flow simulation device to study the effects of arterial shear stress profiles on endotheilial cells Coleman, Sarah Elizabeth 13 July 2005 (has links) Mechanical forces are important regulators of cell function in many tissues including, for example, bone and components of the cardiovascular system. The endothelial lining of blood vessels has been shown to respond in an atheroprotective manner to unidirectional, laminar flow-induced shear stress and in an atherogenic manner to oscillating and low levels of shear. We have developed a cone and plate shear apparatus to simulate fluid shear stress on endothelial cells in vitro. The significant feature of this apparatus is that, unlike other in vitro flow systems, it accurately produces varying levels of shear stress, consistent with those created in vivo during the cardiac cycle. Flow characteristics of this system were verified by computational fluid dynamics (CFD) and laser Doppler velocimetry (LDV). Cellular responses were monitored by cell morphology and protein expression. These responses are consistent with in vivo responses as well as previous work using other in vitro flow systems. Endothelial cells Flow simulation Atherosclerosis Laminar flow Shear stress
76	Upregulation of Hypoxia-Inducible Genes in Endothelial Cells to Create Artificial Vasculature Schonberger, Robert Brian 15 November 2006 (has links) This study explored the possibility that upregulation of Hypoxia Inducible Factor-1 (Hif-1)-responsive genes in Human Umbilical Vein Endothelial Cells (HUVEC) would promote and stabilize HUVEC formation into inchoate vascular beds within artificial collagen gels. This experiment was designed to explore the above possibility by sub-cloning Hif-1[alpha], the related chimeric construct Hif-1[alpha]/VP16, and the marker gene dsRed into retroviral expression vectors, producing retroviral vectors containing these genes, and stably transducing HUVEC using these retroviruses. Transduced HUVEC were to be observed in cell culture as well as after implantation into artificial collagen gels that have previously supported vascular bed formation by HUVEC. Our results show, preliminarily, that HUVEC transduced with Hif-1[alpha]/VP16 go into cell-cycle arrest. Attempts to transduce HUVEC with Hif-1[alpha] failed to achieve high enough transduction efficiency to determine the cells angiogenic potential. This study concluded that more experiments need to be conducted to better characterize the effects of hypoxia-responsive gene upregulation in controlling HUVEC angiogenesis and cell-cycle signaling and that straightforward transduction of HUVEC by Hif-1[alpha]/VP16 is probably not sufficient, in itself, to induce in vitro vascular bed formation. hypoxia-inducible factor 1 up-regulation umbilical veins endothelial cells
77	Synergistic effects of dental pulp stem cells and endothelial cells in pulp regeneration Dissanayaka, Waruna Lakmal January 2014 (has links) Regeneration of the tissues to replace diseased, missing and traumatized dentin/pulp requires combining the recent progress in stem cell and tissue engineering research. Dental pulp stem cells (DPSCs) are considered as a promising population of cells in regenerative dentistry and shown to be able to produce dentin/pulp-like tissues following implantation in-vivo. Securing a good blood supply is critical in pulp regeneration, however, this is a challenging task due to the unique structure of the tooth, the anatomy of which permits only a microcirculatory system via a very small apical opening (<0.3-1mm). This limitation raises the need to develop novel methods to enhance angiogenesis during pulp regeneration. It was shown that DPSCs reside in the microvasculature region of the dental pulp and interact with perivascular cells. Therefore, endothelial cells could be a major source of modulators of pulp-dentin development and angiogenesis. If a pulp tissue substitute with pre-formed endothelial network could be engineered in-vitro, it would not only gain rapid anastomosis with host vasculature but also regulate DPSC function in pulp regeneration. In this study, for the first time, synergistic effects of DPSCs and human umbilical vein endothelial cells (HUVECs) on osteo/odontogenic differentiation and angiogenesis were investigated using two-dimensional and three-dimensional direct co-culture systems. Furthermore, the potential of three-dimensional DPSC constructs prevascularized with HUVECs in dental pulp regeneration in-vivo was exmined. HUVECs promoted odonto/osteogenic differentiation of DPSCs in direct two-dimensional co-cultures in-vitro. Further, addition of DPSCs stabilized the pre-existing vessel-like structures formed by HUVECs and increased the longevity of these structures on matrigel in-vitro. Using two different systems, scaffold-free self-assembling microtissue spheroids and peptide hydrogel scaffold, the interactions of DPSCs and HUVECs in three-dimensional cultures were investigated. The results demonstrated that DPSCs can self assemble into three-dimensional microtissue spheroids when cultured alone or with HUVECs. DPSCs promoted survival and vascular structure formation by HUVECs both in scaffold-free microtissue spheroids and peptide hydrogel scaffold. In contrast, HUVECs, when cultured alone, neither formed vascular structures nor survived in either of the 3D systems. The latter phenomenon was attributable to vascular endothelial growth factor secreted by DPSCs, a major factor responsible for endothelial function. Co-cultures also showed enhanced odonto/osteogenic differentiation in both three-dimensional microtissue spheroid and peptide hydrogel scaffold systems. Following implantation of tooth-root fragments filled with three-dimensional DPSC constructs into the subcutaneous space of immunodefficient mice, vascularised pulp-like tissue was regenerated within the root canals. Compared to DPSC-only group, DPSC/HUVEC co-culture groups showed higher vascularisation, extracellular matrix formation and mineralization in regenerated tissue. More importantly, HUVEC-lined vascular lumens were observed in regenerated tissues suggesting the successful integration of in-vitro formed pre-vascular structures to the host vasculature. In summary, the findings suggest that DPSCs and HUVECs display significant synergy during odonto/osteogenic differentiation and angiogenesis when co-cultured either in two-dimensional or three-dimensional culture systems. Unravelling these fundamental behavioural patterns of DPSCs provides novel insights into the process of pulp regeneration, leading to new avenues for more effective therapies in regenerative endodontics. / published_or_final_version / Dentistry / Doctoral / Doctor of Philosophy Stem cells Dental pulp Endothelial cells Tissue engineering
78	Effects of bioactive constituents of Astragalus membranaceus on the proliferation of colon cancer and endothelial cells Liu, Wing-yee, 廖穎宜 January 2014 (has links) Uncontrolled cell growth may lead to pathological conditions such as cancer. During the progression of cancer, cancer cells stimulate endothelial cells for angiogenesis to support their growth and migration. Previous studies suggest that Astragalus membranaceus, of which the dried root [Astragali Radix] is used as a traditional Chinese medicine, and its bioactive components, astragalus saponins (AST), astragaloside IV (AS IV) and isoflavonoid calycosin, inhibit cancer growth. The present study aimed to examine whether or not these components inhibit the growth and/or metastasis of colon cancer cells and/or angiogenesis of endothelial cells, and to determine the possible mechanisms involved. The growth of HCT 116 colon cancer cells and human umbilical vein endothelial cells (HUVEC) after 72 hours incubation with AST (1 to 25 μg/ml), AS IV (0.5 to 100 μM) or calycosin (10 to 200 μM) were detected with thiazolyl blue tetrazolium bromide assay. Wound healing migration and tube formation assays were used to examine the metastatic and angiogenic potential of HCT 116 cells and HUVEC. Moreover, the expressions of apoptotic [B-cell lymphoma 2 and procaspase-3] and metastasis/angiogenesis-related proteins [matrix metalloproteinase (MMP)-2, MMP-9 and vascular endothelial growth factor (VEGF)] were measured with Western immunoblotting. To investigate the potential mechanism(s) through which astragalus components affect the proliferation and/or migration of HCT 116 cells and HUVEC, the activities of mitogen-activated protein (MAP) kinases [extracellular signal-regulated kinase 1 and 2 (ERK1/2), p38 MAP kinase (p38) and c-Jun amino-terminal kinases] were studied by measuring the expressions of their phosphorylated and total proteins with Western immunoblotting. Calycosin (200 μM) inhibited the growth of HCT 116 cells without affecting that of HUVEC. While it inhibited the migration of both cell types, it stimulated tube formation only in HUVEC. In HCT 116 cells, calycosin downregulated the expressions of procaspase-3, VEGF, MMP-2 and MMP-9 proteins, inhibited ERK1/2 but activated p38. These effects of calycosin were not observed in HUVEC. Neither AST nor AS IV had any significant effects on the parameters studied in HCT 116 cells. AST also showed no effect in HUVEC; AS IV, at 100 μM, appeared to increase the number of tube formation by HUVEC. In conclusion, the present findings suggest that AST has no significant effect on both cancer and endothelial cells while AS IV may promote angiogenesis without any direct action in colon cancer cells. In colon cancer cells, calycosin induces apoptosis, possibly through activation of caspase-3 and p38, and inhibits metastasis, possibly by downregulating MMP-2 and MMP-9, and inhibiting ERK1/2. However, in endothelial cells, the effect of calycosin is not conclusive as it promotes tube formation but inhibits migration. These findings provide the pharmacological basis for the use of Astragali Radix in the treatment of colon cancer, and the scientific evidence for a therapeutic potential of calycosin in the management of this disorder. Further studies are needed to verify the effect of calycosin on endothelial cells. In order to better mimic the clinical situation, the interaction between cancer and endothelial cells [for example, tumor-induced angiogenesis] needs to be taken into consideration. / published_or_final_version / Pharmacology and Pharmacy / Master / Master of Philosophy Colon (Anatomy) - Cancer Endothelial cells
79	Role of Hedgehog Signaling on Endothelial Vascular Patterning Moran, Carlos M. January 2010 (has links) During embryonic vasculogenesis, endothelial cells form in the mesoderm , assemble into cord-like structures and then undergo tube formation. Previous studies have shown that signaling by members of the hedgehog family of secreted growth factors is essential for normal development of embryonic blood vessels. Embryos lacking hedgehog function show the presence of abundant endothelial cells but the cells fail to assemble into vascular cords and lumenized endothelial tubes do not form. At present it is not known whether active hedgehog signaling is required for both cord and tube formation or only for the initial step. To address this question, we have used small molecule inhibitors and agonists to the alter activity of the hedgehog signaling pathway in the chick embryo. If development is allowed to proceed until endothelial cells of the future dorsal aortae have assembled into cords, subsequent inhibition of hedgehog signaling, using cyclopamine, does not prevent aortal cells from forming endothelial tubes, however, it does lead to a reduction in cross sectional area of the aorta and to a loss of density of the adjacent vascular plexus. In contrast, activation of the hedgehog pathway with SAG leads to formation of enlarged aortae and increased density of the plexus. Very little, if any, of the observed effects are due to differences in number of endothelial cells in the treated embryos. Examination of endothelial cells during vascular plexus formation shows that inhibition of hedgehog signaling with cyclopamine inhibits formation of filopodia while treatment with SAG increases the number of filopodial extensions. These studies show that hedgehog signaling levels must be tightly regulated for normal vascular patterning to be achieved. cardiovascular chick development endothelial cells hedgehog vascular patterning VEGF
80	Theiler's virus-induced apoptosis in cerebrovascular endothelial cells. Nayak, Mamatha Somanath 30 September 2004 (has links) Theiler's murine encephalomyelitis virus (TMEV) is classified as a Cardiovirus in the Picornaviridae family. An enteric virus, TMEV, spreads within the mouse population by the fecal-oral route. The neurovirulent GDVII strain of Theiler's virus causes a fatal encephalitis in all strains of mice following intra-cranial infection of the virus. Persistent BeAn strain of Theiler's virus causes a demyelinating disease in susceptible strains of mice, which is similar to the human disease - Multiple Sclerosis (MS). Although a well-recognized model for MS, the route of entry of the virus into the central nervous system (CNS) following natural infection has not been well understood. One of the proposed portals of entry includes the blood-brain barrier (BBB). This report indicates the ability of both the neurovirulent and the persistent strains of Theiler's virus to induce apoptosis in the functional units of the BBB - the cerebrovascular endothelial cells (CVE) both in vitro and in vivo. Induction of apoptosis in CVE was demonstrated by Annexin staining, electron microscopy, DNA fragmentation assay, Hoechst staining and by caspase-3 staining. Corresponding to results by other authors, GDVII is a stronger inducer of apoptosis in CVE compared to BeAn. Induction of apoptosis is dependent on the MOI of the virus. UV-inactivated virus is not capable of inducing apoptosis and induction of apoptosis appears to be an internal event not requiring activation of death receptors. Determining the pathway of induction of apoptosis by TMEV in CVE indicated the involvement of a Ca2+ dependent pathway for apoptosis - the calpain pathway. Involvement of calpain in apoptosis has been reported in MS. Induction of apoptosis in CVE in vivo was also demonstrated following the intra-peritoneal inoculation of Theiler's virus. Induction of apoptosis in CVE following Theiler' virus infection could lead to a breach of the BBB and entry of inflammatory cells as well as virus into the central nervous system. This finding could aid understanding the neuropathogenesis of Theiler's virus. Theiler's virus Apoptosis Cerebrovascular endothelial cells Multiple Sclerosis

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