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The regulation of polarised growth in the pathogenic form of Candida albicansStewart, Elaine January 1988 (has links)
The dimorphic yeast <i>Candida albicans</i> is capable of growth in a budding yeast form and in a mycelial form. Growing in the yeast form in the digestive and vaginal tracts it normally presents no problems to the host; however, when the dimorphic transition takes place and mycelial growth is initiated, symptoms of candidiasis manifest in the host tissues. This thesis studies the control of the dimorphic response and investigates some of the cellular changes which accompany it. Germ tube formation was induced in a defined amino acids/salts medium. Temperature, pH and culture density were critical factors in stimulating the dimorphic response. Different percentages of term tube formation were recorded for eight different strains of <i>C. albicans</i>. Each strain also acidified the growth medium to a different extent; this was correlated to the extent of filamentation of each strain. Internal pH changes were monitored using the weak and technique and <sup>31</sup>P nuclear magnetic resonance spectroscopy during bud and germ tube formation. In mycelial cells there was an initial increase in internal pH from 6.8 to around 8.0, followed by a gradual decrease to neutrality at the actual time of germ tube emergence. Cells in the budding form of growth did not exhibit such a marked increase in cytoplasmic alkalinisation. Mutant strains which were unable to produce germ tubes did not show cytoplasmic alkalinisation under conditions which would normally promote mycelial growth. Activation of the plasmamembrane ATPase may account for this increase in internal pH since diethylstilboestrol inhibited cytoplasmic alkalinisation and germ tube formation without affecting cell viability. Weak bases induced artificially, a rise in internal pH which was accompanied by germ tube formation. Potassium ions were found to enter cells as protons were expelled at the initiation of mycelial growth. Lactic acid prevented any rise in internal pH during germ tube formation. It also collapsed the ΔpH of the cells preventing growth by bud or germ tube formation. This may relate to the observation that endogenous <i>Lactobacilli</i> compete with <i>C. albicans</i> in the vagina and may explain why topically applied live yoghurt cultures soothe vaginal candidiasis. Transport of methionine was found not to be significantly different in cells induced to the budding or mycelial form. Transport or arginine and glutamate was induced by growing cells in the presence of these amino acids. The amino acid pool levels changed during the dimorphic process in <i>C. albicans</i>. A rapid increase in the pool level was shown within the first hour of both bud and hyphal growth followed by a gradual decrease. Little or no evidence was found in support of the hypothesis that the formation of hyphae is a response to nutrient starvation.
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Dab2 plays a role in the post-endocytic trafficking of VEGFR2Inamdar, Shivangi Makarand 01 December 2015 (has links)
Angiogenesis is a crucial process under both physiological and pathological conditions. Vascular endothelial growth factor (VEGF) A and its cognate receptor, vascular endothelial growth factor receptor 2 (VEGFR2) are key regulators of angiogenesis. Plasma membrane (PM) levels of VEGFR2 are regulated by de novo synthesis, and by both exocytic and endocytic trafficking. VEGF-binding to VEGFR2 induces phosphorylation of key tyrosine residues located in the cytosolic domain of the receptor, followed by clathrin-mediated endocytosis and signal transduction leading to vascular morphogenesis. Disabled protein 2 (Dab2) is a cytosolic, clathrin-adaptor protein that is known to regulate endocytosis of certain cell surface receptors. Studies of Dab2 function have revealed its role in the development of embryonic vasculature. However, the mechanism of Dab2 function, particularly in conjunction with endosomal VEGFR2, remains poorly understood. Our results show that Dab2 interacts with VEGFR2 and that upon VEGF stimulation the two proteins co-localize within Rab5-positive early endosomes. Knockdown of Dab2 reduces levels of VEGF-induced phosphorylation of VEGFR2 at residue Y1175. This is significant because phosphorylation of VEGFR2-Y1175 is crucial for pro-angiogenic signal transduction. Moreover, knockdown of Dab2 causes an increased trafficking of VEGFR2 to late endosomes (LE). Finally, this altered VEGFR2 trafficking following Dab2 knockdown has major functional consequences for endothelial cells, as they are unable to undergo morphogenesis into tube-like structures in an in vitro assay of angiogenesis. Collectively, our data show that Dab2 plays a crucial role in VEGFR2 trafficking in the endocytic system and this impacts receptor signaling and endothelial cell morphogenesis during angiogenesis.
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The Angiogenic Functions and Signaling of Delta-Like 1 Homologue Extracellular Domain in Endothelial CellsChang, Tzu-Ting 22 August 2007 (has links)
Delta-like 1 Homologue (DLK1), a transmembrane protein of 383 amino acids, belongs to a family of epidermal growth factor (EGF)-like repeat-containing proteins that include Notch/Delta/Serrate, which are involved in cell fate determination. DLK1 is also known as preadipocyte factor-1, pG2, and FA-1, which are identical or polymorphic products of a single gene. Structural analysis revealed that DLK1 consists of an extracellular domain with six EGF-like repeats, a transmembrane domain, and an intracellular domain. The extracellular EGF-like region of DLK1 (DLK1-EC) can be released to the medium by the action of tumor necrosis factor alpha converting enzyme (TACE). DLK1 participates in various differentiation processes including adipogenesis, hematopoiesis, and adrenal gland differentiation. Besides, DLK1 overexpression was observed in patients with biliary atresia and in glioblastoma. Recently, the extracellular domain of thrombomodulin, which also contains six EGF¡Vlike structures, has been delineated to stimulate angiogenesis in vitro and in vivo. This prompted us to investigate whether DLK1-EC played a role in angiogenesis. To test such hypothesis, recombinant DLK1-EC was expressed and purified in E. coli. Adding DLK1-EC recombinant protein inhibited the adipogenesis of adipocytes-derived stem cells in a dose-dependent manner. Despite marginal effect on matrix-metalloproteinase secretion, exogenous DLK1-EC significantly stimulated the proliferation, motility and tube-forming capability of cultured endothelial cells. Above all, implantation of DLK1-EC-containing hydron pellets induced cornea neovascularization in a dose-dependent manner. Western blot analysis revealed that exogenous DLK1-EC induced angiogenesis through Notch1 activating downstream gene Hes1 and subsequently signaling such as Akt/eNOS, p38 MAPK, and ERK pathway to perform its function. Indeed, blockade of Notch1 signaling using £^-secretase inhibitor leads to decreased angiogenesis and inhibits DLK1 EC-induced
endothelial cell tubular formation in vitro and in vivo. These findings indicate that
DLK1-EC induced Notch1 activation mediated by £^-secretase and tansactivation
Akt/eNOS pathway and that Notch1 is critical for DLK1 EC-induced angiogenesis.
These results may bring further insights into the physiological and pathological
functions of DLK1
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Gene Transfer of Angiogenesis Inhibitor Vasostatin for Suppression of Hepatocellular CarcinomaChien, Hsin-Fan 22 August 2007 (has links)
Hepatocellular carcinoma (HCC) is one of the most prevalent cancers worldwide. Current therapeutic approaches for HCC including surgical resection and trans-arterial embolization (TAE) remain largely ineffective, underscoring the need for development of novel therapeutic strategies. Because HCC is high vascularized, continuous administration angiogenesis inhibitor using gene therapy approach may facilitate long-term blockade tumor vasculature, thereby perturbing the growth of HCC. Vasostatin 112 (VS112) encodes an alternatively spliced fragment of angiogenesis inhibitor vasostatin, which encompasses residues 1-64 and 133-180 of calreticulin. In this study, recombinant adenovirus encoding VS112 (Ad-VS112) was generated to evaluate its potential for suppression of orthotopic Novikoff hepatoma in syngenic Sprague-Dawley (SD) rats. Adenovirus-mediated VS112 overexpression significantly inhibited the migration and tube formation of endothelial cells, indicating the anti-angiogenic potency of VS112 gene delivery. However, VS112 overexpression had no influence on the viability of N1-S1 Novikoff hepatoma cells. To investigate the prophylactic effect of VS112 expression on hepatoma growth, N1-S1 cells were infected with Ad-VS112 or adenovirus encoding green fluorescent protein (Ad-GFP) then implanted into the liver of SD rats. After 14 days, rats implanted with VS112-expressing showed significantly reduced incidence and size of hepatoma compared with those implanted with Ad-GFP-infected cells. To investigate the therapeutic efficacy of VS112 gene delivery, the SD rats were implanted with N1-S1 cells on day 0, treated with adenovirus vectors (2 x 1010 plaques forming units) via intravenous route on day 1, then sacrificed on day 14 to monitor hepatoma growth. By measuring tumor weight, it was found that Ad-VS112-treated rats exhibited significantly decreased tumor burden compared with control groups, which was in accordance with their lower serum GOT level. Histological analysis revealed a significant reduction of vWF-positive blood vessels in Ad-VS112-treated tumors, which was accompanied with a decrease in Ki-67-positive proliferating cells and an increase in TUNEL-positive apoptotic cells. Moreover, the expression of pro-inflammatory nuclear factor kappa B (NF£eB) and cyclooxgenase II (COXII) was also effectively attenuated in Ad-VS112-treated hepatoma. In conclusion, prior or post VS112 gene delivery potently suppresses the growth of orthotopic hepatoma,thereby holding promises for future treatment of HCC.
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A genetic screen in Drosophila reveals the roles of ArfGEF Gartenzwerg in tube morphogenesisWang, Shuoshuo 11 September 2012 (has links)
Biological tubes possessing a curvilinear form and a hollow interior exist in most multicellular eukaryotes. In Eumetazoa, the tubes usually comprise an eminently complex network and enable the transport and exchange of fluids and gases between tissues and organs, but also between organisms and their environment. Thus, tubular structures are both morphologically and physiologically integral parts of the animals.
Based on a genetic screen for novel factors involved in heart tube differentiation and morphogenesis in Drosophila, the identified mutants were subdivided into several classes: cardiac hyperplasia (kuz and mam, both involved in the Notch-dependent cardiomyocyte specification, Publication 1); impaired cytokinesis (pav and tum, both components of the centralspindlin complex); a single ptc mutant showing a “truncated” heart (Publication 2); and a single loss-of-function mutant displaying reduced lumen diameter in epithelial tubes and perturbed secretion of ECM-components. The latter allele was mapped to the gene locus gartenzwerg (garz) that encodes a large ArfGEF. Due to its novelty, garz was selected as a central part of the thesis (Publication 3).
Although garz seems to be expressed ubiquitously, its transcripts are abundant in active secreting cells of tubular structures. Moreover, mutations of garz abolish Golgi-integrity, cause massive retention of secretory cargo in the ER and arrest the apical transport of lipids and ECM molecules. As a consequence, lumen of the salivary glands and trachea fail to expand and show a decreased diameter. The observed phenotypes in tracheal network and salivary glands phenocopy those of COPI/COPII-subunits as well as actin-dependent secretion mutants, suggesting the underlying mechanism might be common. Thus, it is supposed that proper tubulogenesis needs Garz for initiation of the Arf1-COPI machinery. Furthermore, Golgi-based post-translational modifications, targeted sorting of vesicles, outward transport of proteins, or directed membrane delivery all depend on the secretory pathway, and such processes are essential in establishing polarized cells which build the tubular structures. In conclusion, this mechanism seems to be neither restricted to tubulogenesis nor specific to Drosophila. Due to the presence of garz homologues in every eukaryotic genomes, the Arf1/COPI based secretory pathway may play a universal role in metazoan development.
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The Role of Shb in Angiogenesis, FGF and VEGF Signalling in Endothelial CellsHolmqvist, Kristina January 2004 (has links)
<p>Angiogenesis is defined as the formation of new capillary blood vessels from pre-existing ones. This process involves several steps including: migration, proliferation and differentiation of endothelial cells into blood vessels. Angiogenesis is initiated by binding of specific growth factors, such as vascular endothelial growth factor (VEGF) and fibroblast growth factor (FGF), to their cell surface receptors. Shb is a ubiquitously expressed adaptor protein with the ability to bind several tyrosine kinase receptors. My aim has been to identify the role of Shb in FGF- and VEGF-signalling in endothelial cells. Shb was found to be phosphorylated in a Src-dependent manner upon both FGF- and VEGF-stimulation. This was confirmed using fibroblasts overexpressing temperature sensitive v-Src. Furthermore, Shb-induced cell spreading on collagen of immortalised brain endothelial (IBE) cells was also Src-dependent. FGF stimulation led to a direct association between Shb and FAK, which was mediated by the phosphotyrosine binding domain of Shb. IBE cells overexpressing wild-type or R522K Shb (inactive SH2 domain) displayed increased FAK activation on collagen.</p><p>The SH2-domain of Shb was found to bind to tyrosine 1175 in the VEGFR-2 in a phosphotyrosine dependent manner using PAE cells expressing VEGFR-2. Furthermore, by use of siRNA, Shb knock-down experiments revealed that Shb regulates FAK activity, cellular migration and stress fiber formation in response to VEGF stimulation of VEGFR-2. In summary, Shb binds to both FGFR-1 and VEGFR-2 and regulates the activity of FAK and thereby stress fiber formation and cellular migration, which are necessary for formation of new blood vessels. IBE cells with an inactive SH2 domain of Shb displayed disorganised formation of tubular structures in the tube formation assay, while overexpression of wild-type Shb led to accelerated tubular morphogenesis.</p><p>Taken together, my data show that the adaptor protein Shb plays an important role in the process angiogenesis, in response to angiogenic tyrosine kinase receptors, by interacting with FAK and regulating spreading, stress fiber formation and cellular migration.</p>
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The Role of Shb in Angiogenesis, FGF and VEGF Signalling in Endothelial CellsHolmqvist, Kristina January 2004 (has links)
Angiogenesis is defined as the formation of new capillary blood vessels from pre-existing ones. This process involves several steps including: migration, proliferation and differentiation of endothelial cells into blood vessels. Angiogenesis is initiated by binding of specific growth factors, such as vascular endothelial growth factor (VEGF) and fibroblast growth factor (FGF), to their cell surface receptors. Shb is a ubiquitously expressed adaptor protein with the ability to bind several tyrosine kinase receptors. My aim has been to identify the role of Shb in FGF- and VEGF-signalling in endothelial cells. Shb was found to be phosphorylated in a Src-dependent manner upon both FGF- and VEGF-stimulation. This was confirmed using fibroblasts overexpressing temperature sensitive v-Src. Furthermore, Shb-induced cell spreading on collagen of immortalised brain endothelial (IBE) cells was also Src-dependent. FGF stimulation led to a direct association between Shb and FAK, which was mediated by the phosphotyrosine binding domain of Shb. IBE cells overexpressing wild-type or R522K Shb (inactive SH2 domain) displayed increased FAK activation on collagen. The SH2-domain of Shb was found to bind to tyrosine 1175 in the VEGFR-2 in a phosphotyrosine dependent manner using PAE cells expressing VEGFR-2. Furthermore, by use of siRNA, Shb knock-down experiments revealed that Shb regulates FAK activity, cellular migration and stress fiber formation in response to VEGF stimulation of VEGFR-2. In summary, Shb binds to both FGFR-1 and VEGFR-2 and regulates the activity of FAK and thereby stress fiber formation and cellular migration, which are necessary for formation of new blood vessels. IBE cells with an inactive SH2 domain of Shb displayed disorganised formation of tubular structures in the tube formation assay, while overexpression of wild-type Shb led to accelerated tubular morphogenesis. Taken together, my data show that the adaptor protein Shb plays an important role in the process angiogenesis, in response to angiogenic tyrosine kinase receptors, by interacting with FAK and regulating spreading, stress fiber formation and cellular migration.
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